This application claims priority from U.S. Provisional Application No. 61/064,904 filed Apr. 2, 2008, the entire content of which is incorporated herein by reference.
This invention was made with government support under Grant No. AI-06779801 awarded by the National Institutes of Health. The government has certain rights in the invention.
TECHNICAL FIELD The present invention relates, in general, to gene expression profiles, and in particular, to a peripheral blood gene expression profile of an environmental exposure, ionizing radiation. The invention further relates to methods of screening patients for radiation exposure based on gene expression profiling and to kits suitable for use in such methods.
BACKGROUND Invasive procedures are often required for accurate screening and diagnosis of common medical conditions (Boolchand et al, Ann. Intern. Med. 145:654-659 (2006)). Examination of the peripheral blood often suffices to establish certain diagnoses, such as chronic lymphocytic leukemia (Damle et al, Blood Epub Ahead of Print (2007)), which afflicts the circulating lymphocyte directly. Measurement of total white blood cell counts and the WBC differential (e.g. neutrophils, lymphocytes, monocytes) is routinely performed in medical practice and can facilitate many diagnoses (e.g. bacterial or viral infection). Recently, it has been suggested that gene expression profiling of peripheral blood cells, particularly lymphocytes, can serve as sensitive tool to assess for the presence of certain diseases, such as systemic lupus erythematosus, rheumatoid arthritis, neurologic disease, viral and bacterial infections, breast cancer, atherosclerosis and environmental exposures, including tobacco smoke (Mandel et al, Lupus 15:451-456 (2006), Heller et al, Proc. Natl. Acad. Sci. USA 94:2150-2155 (1997), Edwards et al, Mol. Med. 13:40-58 (2007), Baird, Stroke 38:694-698 (2007), Rubins et al, Proc. Natl. Acad. Sci. USA 101:15190-15195 (2004), Martin et al, Proc. Natl. Acad. Sci. USA 98:2646-2651 (2001), Patino et al, Proc. Natl. Acad. Sci. USA 102:3423-3428 (2005), Lampe et al, Cancer Epidemiol. Biomarkers Prev. 13:445-453 (2004), Ramilo et al, Blood 109:2066-2077 (2007)). Results from these studies suggest that patterns of gene expression within circulating PB cells can distinguish individuals afflicted by these conditions from those who are not (Mandel et al, Lupus 15:451-456 (2006), Heller et al, Proc. Natl. Acad. Sci. USA 94:2150-2155 (1997), Edwards et al, Mol. Med. 13:40-58 (2007), Baird, Stroke 38:694-698 (2007), Rubins et al, Proc. Natl. Acad. Sci. USA 101:15190-15195 (2004), Martin et al, Proc. Natl. Acad. Sci. USA 98:2646-2651 (2001), Patino et al, Proc. Natl. Acad. Sci. USA 102:3423-3428 (2005), Lampe et al, Cancer Epidemiol. Biomarkers Prev. 13:445-453 (2004), Ramilo et al, Blood 109:2066-2077 (2007)). It has, therefore, been suggested that PB gene expression profiling has potential utility in the screening for diseases and environmental exposures.
Any consideration of applying PB gene expression profiles for the detection of disease or environmental exposures requires a determination of the impact of PB cellular composition, time, gender, and genotype on PB gene expression (Lampe et al, Cancer Epidemiol. Biomarkers Prev. 13:445-453 (2004), Ramilo et al, Blood 109:2066-2077 (2007), Whitney et al, Proc. Natl. Acad. Sci. USA 101:1896-1901 (2003), Yan et al, Science 297:1143 (2002)). Additionally, it is unclear whether PB gene expression profiles that have been associated with various medical conditions are specific for that phenotype, or rather reflect a generalized response to genotoxic stress. Examination of the specificity of PB gene expression profiles in response to different stimuli and the durability of these signatures over time is critical to the translation of this strategy into clinical practice.
Ionizing radiation represents a particularly important environmental hazard, which, at lowest dose exposures, causes little acute health effects (Kaiser, Science 302:378 (2003)) and, at higher dose exposures, can cause acute radiation syndrome and death (Wasalenko et al, Ann. Int. Med. 140:1037-1051 (2004), Mettler et al, N. Engl. J. Med. 346:1554-1561 (2002), Dainiak, Exp. Hematol. 30:513-528 (2002)). Numerous studies have been performed to attempt to understand the biologic effects of ionizing radiation in humans. Specific mutations in p53 and HPRT have been identified in somatic cells from survivors of the Hiroshima and Nagasaki atomic bombings (Iwamoto et al, J. Natl. Canc. Inst. 90:1167-1168 (1998), Hirai et al, Mutant Res. 329:183-196 (1995), Takeshima et al, Lancet 342:1520-1521 (1993), Neel et al, Annu. Rev. Genet. 24:327-362 (1990)).
Gene expression analyses have been performed on human tumor cells, cell lines, and peripheral blood from small numbers of irradiated patients in order to identify specific genes that are involved in the response to radiation injury (Jen et al, Genome Res. 13:2092-2100 (2003), Amundson et al, Radiat. Res. 154:342-346 (2000), Amundson et al, Radiat. Res. 156:657-661 (2001), Falt et al, Carcinogenesis 24:1837-1845 (2003), Amundson et al, Cancer Res. 64:6368-6371 (2004)). Recently, public health focus has centered on the development of capabilities to accurately screen large numbers of people for radiation exposure in light of the anticipated use of radiological or nuclear materials by terrorists to produce “dirty bombs” or “improvised nuclear devices” (Wasalenko et al, Ann. Int. Med. 140:1037-1051 (2004), Mettler et al, N. Engl. J. Med. 346:1554-1561 (2002), Dainiak, Exp. Hematol. 30:513-528 (2002)).
A method of screening humans for environmental exposure has been suggested. This method relies on the identification of patterns of gene expression, or metagenes in PB cells that accurately distinguish between irradiated and non-irradiated individuals (Dressman et al, PLoS Med. 4:690-701 (2007)). Metagenes can be identified in the PB that distinguish different levels of exposure with an accuracy of 96% (Dressman et al, PLoS Med. 4:690-701 (2007)).
The present invention results, at least in part, from studies designed to evaluate the specificity of PB gene expression signatures and to determine the influence of genetic variation and time on the performance of the signature. The results of these studies indicate that this approach represents a viable strategy for identifying environmental exposures and one that can be employed for screening populations of affected individuals.
SUMMARY OF THE INVENTION The present invention relates generally to gene expression profiles. More specifically, the invention relates to PB gene expression profile of an environmental exposure, ionizing radiation. The invention further relates to a method of screening patients for radiation exposure based on gene expression profiling and to kits suitable for use in such methods.
Objects and advantages of the present invention will be clear from the description that follows.
BRIEF DESCRIPTION OF THE DRAWINGS FIGS. 1A and 1B. Peripheral blood gene expression profiles distinguish irradiated mice within a heterogeneous population (FIG. 1A) A heat map of a 25 gene profile that can predict radiation status. The figure is sorted by dosage (0 cGy, 50 cGy, 200 cGy, and 1000 cGy). High expression is depicted as red, and low expression is depicted as blue. (FIG. 1B) A graph of the predicted capabilities of the irradiation signature across all mice (including C57Bl6 and BALB/c strains, males and females and 3 sampling time points) versus a control, non irradiated sample. All predicted probabilities for the controls are listed.
FIGS. 2A-2C. Impact of sex on murine irradiation profiles (FIG. 2A) Heat map images illustrating expression pattern of genes selected for classifying control, non-irradiated mice versus 50 cGy, 200 cGy, or 1000 cGy irradiated mice within female (top) and male C57Bl6 mice (bottom). (FIG. 2B) Heat map images illustrating expression pattern of genes found in the female C57Bl6 strain or male C57Bl6 strain predicting the irradiation status of the opposite sex at dosage 50 cGy, 200 cGy, 1000 cGy. High expression is depicted as red, and low expression is depicted as blue. (FIG. 2C) A leave-one-out cross-validation analysis of the classification for control (blue) versus 50 cGy (black), 200 cGy (green), and 1000 cGy (red) for the female C57Bl6 (squares) and male C57Bl6 (circles) samples is shown. The control probabilities for each prediction are shown.
FIGS. 3A-3C. Impact of genotype on murine irradiation profiles. (FIG. 3A) Heat map images illustrating expression pattern of genes selected for classifying control, non-irradiated samples versus 50 cGy, 200 cGy, 1000 cGy irradiated samples between female C57Bl6 strain (top) and female BALB/c strain (bottom). (FIG. 3B) Heat map images illustrating expression pattern of genes developed in one strain as predicting the other strain (C57Bl6 or BALB/c). High expression is depicted as red and low expression is depicted as blue. (FIG. 3C) A leave-one-out cross-validation analysis of the classification for control versus 50 cGy (black), 200 cGy (green), and 1000 cGy (red) for the female BALB/c (open-circles) and female C57Bl6 (closed circles) samples is shown. The control probabilities for each prediction are shown. BK represents the application of female C57Bl6 metagenes to predict the status of female BALB/c mice, and BC represents using female BALB/c mice metagenes to predict the status of female C57Bl6 mice.
FIGS. 4A-4C. Impact of time on murine irradiation profiles. (FIG. 4A) Heat map images illustrating expression pattern of genes selected for classifying control, non-irradiated samples versus 50 cGy, 200 cGy, 1000 cGy irradiated samples at time points 6 hr, 24 hr, and 7 days. (FIG. 4B) Heat map images illustrating expression pattern of genes found in the 6 hr time point as applied to the dosages 50 cGy, 200 cGy, 1000 cGy at 24 hr and 7 day time points. High expression is depicted as red, and low expression is depicted as blue. (FIG. 4C) A leave-one-out cross-validation analysis of the classification for control (blue) versus 50 cGy (black), 200 cGy (green), and 1000 cGy (red) for the time points 6 hr (circles), 24 hr (squares), and 7 days (triangles) is shown. The control probabilities for each prediction are shown.
FIGS. 5A and 5B. Peripheral blood profiles of irradiation and LPS-treatment are highly specific. (FIG. 5A) Heat maps representing unique metagene profiles are shown which were utilized to distinguish 3 different levels of irradiation (left) and to distinguish LPS-treatment (right) in C57Bl6 mice. (FIG. 5B) The graph at left represents the predictive capabilities of the PB irradiation signatures in the female C57Bl6 mice in predicting dosage profiles at 50 cGy (black), 200 cGy (green), and 1000 cGy (red); the middle graph represents the predictive capabilities of the irradiation signatures when validated against the LPS-treated samples (squares); at right, the LPS signature was validated against the C57Bl6 irradiated mice and the predicted probabilities for 50 cGy (black), 200 cGy (green), and 1000 cGy (red) are shown.
FIGS. 6A-6D. PB metagene profiles of human radiation exposure and chemotherapy treatment are accurate and specific relative to each other. (FIG. 6A) The heat map on the left depicts the expression profiles of genes (rows) selected to discriminate the human samples (columns); high expression is depicted as red, and low expression is depicted as blue. A leave-one-out cross-validation assay (FIG. 6C) demonstrated that the PB metagene of radiation was capable of distinguishing healthy donors (black), non-irradiated patients (gray), irradiated patients (red), pre-chemotherapy treatment patients (green), and post-chemotherapy patients (blue). A ROC curve analysis was used to define a cut-off for sensitivity and specificity of the predictive model of radiation. The dotted line represents this threshold of sensitivity and specificity. (FIG. 6B) The heatmap on the left depicts an expression profile of chemotherapy treatment that distinguishes chemotherapy-treated versus untreated patients. A leave-one-out cross-validation assay (FIG. 6D) demonstrated that this PB metagene of chemotherapy treatment could accurately distinguish pre-chemotherapy patients (green), chemotherapy-treated patients (blue), healthy individuals (black), pre-irradiated patients (gray) and irradiated patients (red).
DETAILED DESCRIPTION OF THE INVENTION The present invention results, at least in part, from the demonstration that exposure to ionizing radiation induces a pronounced and characteristic alteration in PB gene expression. The PB expression profile disclosed herein provides basis for a method of screening a heterogeneous human population, for example, in the event of a radiological or nuclear event.
A gene expression profile that distinguishes radiation status in humans is set forth in Table 7. As described in the Example that follows, a supervised binary regression analysis identified this metagene profile of 25 genes that can be used to distinguish irradiated from non-irradiated individuals. The PB samples used to establish the profile in Table 7 were collected 6 hours following irradiation (see Table 6 for details of exposure).
The invention relates to a method screening patients for radiation exposure by collecting PB from the patients and isolating mononuclear cells therefrom. RNA can be extracted from the mononuclear cells using standard techniques, including those described in the Example below. The extracted RNA can be amplified and suitable probes prepared (see Example and Dressman et al, PLoS Med. 4:690-701 (2007)). Gene expression levels can then be determined using, for example, microarray techniques (see Example and Dressman et al, PLoS Med. 4:690-701 (2007)).
A patient that displays the gene expression profile set forth in Table 7 is a patient that has been exposed to radiation (e.g., about 6 hours prior to PB collection). While the 25 genes set forth in Table 7 constitute one signature suitable for use is distinguishing radiation status, the invention also includes methods based on the use of signatures comprising the following: H200000088, H200008365, H200011577, H200014719, H200016323, H300000421, H300003103, H300010830, H300015667, H300019371, H300020858, H300021118, H300022025. Other subsets of the signature set forth in Table 7 (e.g., comprising at least 5 or at least 10 genes) are potentially suitable for use in accordance with the present invention.
While the PB expression profile described herein is highly predictive of radiation status, sex differences can contribute to characteristically distinct PB molecular responses to radiation, for example at low exposure levels (e.g., about 50 cGy). Accordingly, use of gender specific assays can be advantageous, for example, at low levels of exposure.
As shown in the Example that follows, the time of PB collection following radiation exposure does not significantly impact the accuracy of PB signatures to predict radiation status or distinguish different levels of exposure. While time as a single variable does not lessen the accuracy in distinguishing irradiated from non-irradiated individuals, the content of the genes which comprise the PB signature can change as a function of time. Thus, while PB predictors of radiation exposure can change over time, PB signatures can continuously be identified (e.g., through 7 days) that are highly accurate at predicting radiation status and distinguishing different levels of exposure.
The invention also relates to reagents and kits suitable for use in practicing the above-described methods. Kit components can vary, however, examples of components include an array probe of nucleic acids in which the genes listed in Table 7, or subset thereof, are represented. A variety of different array formats or known in the art with a variety of probe structures, subset components and attachment technologies. Representative array structures include those described in U.S. Pat. Nos. 5,143,854; 5,288,644; 5,342,633; 5,432,049; 5,470,710; 5,492,806; 5,503,980; 5,510,270; 5,525,464; 5,547,839; 5,580,732; 5,661,028; 5,800,992; WO 95/21265; WO 96/31622; WO 97/10365; WO 97/27317; EP 373203 and EP 785280 (see also U.S. Published Appln. No. 20060141493). Kits of the invention can also include specific primers designed to selectively amplify the genes in Table 7, or subset thereof. Gene specific primers and methods of using same are described in U.S. Pat. No. 5,994,076. The kits can also include additional reagents, e.g., dNTPs and/or rNTPs, buffers, enzymes, etc.
Certain aspects of the invention can be described in greater detail in the non-limiting Example that follows. (See also Dressman et al, PLoS Med. 4:690-701 (2007)).
Example Experimental Details Murine Irradiation Study Ten to 11 week old male and female C57Bl6 and female BALB/c mice (Jackson Laboratory, Bar Harbor, Me.) were housed at the Duke Cancer Center Isolation Facility under regulations approved by the Duke University Animal Care and Use Committee. Between 5-10 mice/group were given total body irradiation (TBI) with a Cs137 source at an average of 660 cGy/min at doses of 50, 200, or 1000 cGy as previously described (Dressman et al, PLoS Med. 4:690-701 (2007)). Six hours, 24 hours, or 7 days post-TBI, approximately 500 μl peripheral blood was collected by retro-orbital bleed from both irradiated and control mice. PB mononuclear cells (PB MNCs) were isolated for total RNA extractions. Total RNA was extracted with Qiagen RNAeasy Mini Kits as previously described (Dressman et al, PLoS Med. 4:690-701 (2007)). RNA quality was assayed using an Agilent Bioanalyzer 2100 (Agilent Technologies, Inc., Palo Alto, Calif.).
Murine LPS Study Ten C57Bl6 female mice were given intraperitoneal injections of a 100 μg of lipopolysaccharide endotoxin (LPS) from E. coli 055:B5 (Sigma-Aldrich, St. Louis, Mo.) to induce sepsis syndrome as previously described (Hick et al, J. Immunol. 177:169-176 (2006)). Peripheral blood was collected 6 h later from treated and control mice, and RNA was processed as described in the irradiation studies.
Human Irradiation and Chemotherapy Treatment Studies With approval from the Duke University Institutional Review Board (IRB), between 5-12 mL of peripheral blood was collected from patients prior to and 6 hrs following total body irradiation with 150 to 200 cGy as part of their pre-transplantation conditioning (Dressman et al, PLoS Med. 4:690-701 (2007)). For additional comparison, peripheral blood was obtained from healthy volunteers and an additional cohort of patients prior to and 6 hrs following the initiation of alkylator-based chemotherapy alone (without radiotherapy). All patients and healthy volunteers who participated in this study provided written informed consent prior to enrollment, as per the Duke IRB guidelines. PB MNCs and total RNA were isolated from the blood using the identical methods as described for collection of murine cells and RNA.
DNA Microarrays Mouse and human oligonucleotide arrays were printed at the Duke Microarray Facility using Operon's Mouse Genome Oligo sets (version 3.0 and version 4.0) and Operon's Human Genome Oligo set (version 3.0 and version 4.0). Data generated from Operon's Mouse and Human version 3 was previously described (Dressman et al, PLoS Med. 4:690-701 (2007)). Operon's Mouse Genome Oligo set (version 4.0) (https://www.operon.com/arrays/oligosets_mouse.php) contains 35,852 oligonucleotide probes representing 25,000 genes and approximately 38,000 transcripts. Operon's Human Genome Oligo set (version 4.0) (https://www.operon.com/arrays/oligosets_human.php) contains 35,035 oligonucleotide probes, representing approximately 25,100 unique genes and 39,600 transcripts. In order to compare across versions of the Operon oligo sets, Operon provided a map that matched the probes from both versions and only those oligonucleotides that overlapped between versions 3.0 and 4.0 were used in the analysis.
RNA and Microarray Probe Preparation and Hybridization Briefly, MNCs were pelleted, and total RNA was isolated using the RNAeasy mini spin column (Dressman et al, PLoS Med. 4:690-701 (2007)). Total RNA from each sample (mouse or human) and the universal reference RNA (Universal Human or Mouse Reference RNA, Stratagene, http://www.stratagene.com) were amplified and used in probe preparation as previously described (Dressman et al, PLoS Med. 4:690-701 (2007)). The sample (mouse or human) was labeled with Cy5 and the reference (mouse or human) was labeled with Cy3. The reference RNA allows for the signal for each gene to be normalized to its own unique factor allowing comparisons of gene expression across multiple samples. This serves as a normalization control for two-color microarrays and an internal standardization for the arrays. Amplification, probe preparation and hybridization protocols were performed as previously described (Dressman et al, PLoS Med. 4:690-701 (2007)) and each condition examined had multiple replicates analyzed (n=3-18 per mouse condition and n=18-36 per human condition). Detailed protocols are available on the Duke Microarray Facility web site (http://microarray.genome.duke.edu/services/spotted-arrays/protocols).
Data Processing and Statistical Analysis Genespring GX 7.3 (Agilent Technologies) was used to perform initial data filtering in which spots whose signal intensities below 70 in either the Cy3 or Cy5 channel were removed. For each analysis, only those samples in that analysis were used in the filtering process. To compare data from previously published results (Dressman et al, PLoS Med. 4:690-701 (2007)), only those probes were used that mapped to each other across the version 3.0 and version 4.0 arrays. To then account for missing values, PAM software (http://www-stat.stanford.edu/˜tibs/PAM/) was used to impute missing values. k-nearest neighbor was used where missing values were imputed using a k-nearest neighbor average in gene space. In the analysis approach in which all samples were included, lowess normalization of the data followed by batch effect removal using 2-way mixed model ANOVA (Partek Incorporated) was performed. Gene expression profiles of dose response were used in a supervised analysis using binary regression methodologies as described previously (Dressman et al, PLoS Med. 4:690-701 (2007)). Prediction analysis of the expression data was performed using MATLAB software as previously described (Dressman et al, PLoS Med. 4:690-701 (2007)). When predicting levels of radiation exposure, gene selection and identification is based on training the data and finding those genes most highly correlated to response. Each signature summarizes its constituent genes as a single expression profile and is here derived as the first principal component of that set of genes (the factor corresponding to the largest singular value), as determined by a singular value decomposition. Given a training set of expression vectors (of values across metagenes) representing two biological states, a binary probit regression model is estimated using Bayesian methods. Bayesian fitting of binary probit regression models to the training data then permits an assessment of the relevance of the metagene signatures in within-sample classification, and estimation and uncertainty assessments for the binary regression weights mapping metagenes to probabilities of radiation exposure. To internally validate the predictive capacity of the metagene profiles, leave-one-out cross validation studies were performed as previously described (Dressman et al, PLoS Med. 4:690-701 (2007)). A leave one out cross validation involves removing one sample from the dataset, using the remaining samples to develop the model, and then predicting the status of the held out sample. This is then repeated for each sample in the dataset. This approach was utilized as previously described (Dressman et al, PLoS Med. 4:690-701 (2007)). A ROC curve analysis was used to define a cut-off for sensitivity and specificity in the predictive models of radiation. Genes found to be predictive of radiation dose were characterized utilizing an in-house program, GATHER (http://meddb01.duhs.duke.edu/gather/). GATHER quantifies the evidence supporting the association between a gene group and an annotation using a Bayes factor (Pournara et al, BMC Bioinformatics 23:1-20 (2007)). All microarray data files can be found at http://data.cgt.duke.edu/ChuteRadiation.php and at gene expression omnibus website (GEO [http://www.ncbi.nlm.nih.gov/geo], accession number GSE10640).
Results PB gene expression signatures predict ionizing radiation exposure in a heterogeneous population
In a previous study, it was demonstrated that PB collected from a single strain and gender of mice, at a single time point, contained patterns of gene expression that predicted both prior radiation exposure and distinguished different levels of radiation exposure with a high degree of accuracy (Dressman et al, PLoS Med. 4:690-701 (2007)). In this study, a determination was made as to whether PB gene expression signatures could be identified that predict radiation exposure status within a population that was heterogeneous for genotype, gender and time of sampling. It was found that a clear pattern of gene expression could be identified within this heterogeneous population of mice that distinguished non-irradiated animals from those irradiated with 50 cGy, 200 cGy, and 1000 cGy (FIG. 1A). To verify that these patterns did indeed represent genes reflecting exposure to radiation, a leave-one-out cross-validation analysis was used to assess the ability of the pattern to predict the relevant samples (FIG. 1B). The results demonstrate that the pattern selected for distinguishing control animals from those irradiated at various doses has the capacity to predict the status of the samples. The accuracies of prediction of the non-irradiated samples, the 50 cGy-, 200 cGy- and 1000 cGy-irradiated samples were 92%, 78%, 91% and 100%, respectively.
Sex Differences Impact the Accuracy of Gene Expression Signatures of Radiation A determination was then made as to the extent to which variables within a heterogeneous population can limit the accuracy of PB gene expression profiling. In order to address the impact of sex difference, healthy adult male and female C57Bl6 mice were irradiated with 50 cGy, 200 cGy, and 1000 cGy and PB was collected at 6 hours post-irradiation, along with PB from non-irradiated control mice (n=7-10 per group). Patterns of gene expression could be identified in the PB of both male and female mice that appeared to distinguish radiation exposure status (FIG. 2A). When the PB signatures from the male C57Bl6 mice were tested against the female PB samples, the heat map analysis suggested less distinction between the non-irradiated and irradiated profiles (FIG. 2B). Comparable effects were observed when the female PB signatures were applied against male PB samples. A leave-one-out cross-validation analysis demonstrated that the male and female PB signatures of radiation were 100% accurate in predicting the radiation status of PB samples from mice of the same sex (FIG. 2C). The male PB signatures also were 100% accurate in predicting the status of the female mice. However, the female PB signatures were less accurate in distinguishing the non-irradiated from 50 cGy irradiated male mice, with improved accuracy in predicting non-irradiated samples from male mice irradiated with higher doses of radiation (200 cGy and 1000 cGy; FIG. 2C). The basis for the observed differences in predicting the radiation status of mice across gender differences may be a function of the distinct sets of genes which are represented in the predictors of radiation exposure in males and females (Table S1). Less than 15% of the genes overlapped between the PB metagenes of males and females at each dose of radiation.
TABLE 1
Genes that distinguish radiation responses in male and female C57Bl6 mice. Operon
Oligo ID can be queried in the OMAD database (http://omad.operon.com)
Operon Gene
OligoID Symbol RefSeq Genbank Description
MALES
50 Gy
M200013484 9030617O03Rik NM_145448 BC021385 —
M200000800 Ccng1 NM_009831 AB005559 CYCLIN G1 (CYCLIN G]
M200004687 Dda3-pending NM_019976 AK041835 DIFFERENTIAL DISPLAY AND ACTIVATED BY
P53; P53-REGULATED DDA3.
M200003784 Bax NM_007527 L22472 APOPTOSIS REGULATOR BAX, MEMBRANE
ISOFORM ALPHA.
M200007794 Wig1 NM_009517 AF012923 WILD-TYPE P53-INDUCED GENE 1.
M200016031 Polk NM_012048 AB040764 POLYMERASE (DNA DIRECTED), KAPPA; DINB
HOMOLOG 1 (E. COLI); DNA DAMAGE-
INDUCIBLE PROETIN B; DNA DAMAGE-
INDUCIBLE PROTEIN B; POLYMERASE (DNA
DIRECTED) KAPPA.
M200000935 Gcdh NM_008097 U18992 GLUTARYL-COA DEHYDROGENASE.
MITOCHONDRIAL PRECURSOR
(EC 1.3.99.7) (GCD).
M300010491 D030041N15Rik NM_153416 BC018191 ALADIN (ADRACALIN).]
M200003481 2210412K09Rik NM_029814 BC006947 —
M200006137 Stinp NM_021897 AY034612 STRESS INDUCED PROTEIN; THYMUS
EXPRESSED ACIDIC PROTEIN.
M300008376 Pon2 NM_008896 L48514 SERUM PARAOXONASE/ARYLESTERASE 2
(EC 3.1.1.2) (EC 3.1.8.1) (PON 2) (SERUM
ARYLDIAKYLPHOSPHATASE 2) (A-ESTERASE
2) (AROMATIC ESTERASE 2).]
M200006229 Dstn NM_019771 AB025406 DESTRIN (ACTIN-DEPOLYMERIZING FACTOR)
(ADF).
M300013831 Myo15 NM_010862 AB014510 MYOSIN XV (UNCONVENTIONAL MYOSIN-15).
M200009374 2310045N01Rik NM_008578 AK009829 MYOCYTE-SPECIFIC ENHANCER FACTOR 2B.
M200015906 5530601I19Rik NM_027797 BC022756 —
M200004993 Ifi47 NM_008330 M63630 INTERFERON GAMMA INDUCIBLE PROTEIN;
INTERFERON GAMMA INDUCIBLE PROTEIN,
47 KDA
M200006667 D11Ertd619e NM_026538 AK011136 PROBABLE ATP-DEPENDENT 61 KDA
NUCLEOLAR RNA HELICASE.
M200013613 Gnrpx-pending — BC005565 —
M300020474 — — — —
M200004237 Ris2 NM_026014 AK028287 RETROVIRAL INTEGRATION SITE 2;
RETROVIRAL INTEGRATION SITE 1.
M200005712 Hexb NM_010422 U07741 BETA-HEXOSAMINIDASE BETA CHAIN
PRECURSOR (EC 3.2.1.52) (N-ACETYL-BETA-
GLUCOSAMINIDASE) (BETA-N-
ACETYLHEXOSAMINIDASE)
(HEXOSAMINIDASE B).
M200000599 Pps NM_008916 AK054436 PUTATIVE PHOSPHATASE; PI-5-
PHOSPHATASE RELATED; PUTATIVE PI-5-
PHOSPHATASE. [
M200014192 — NM_053193 AF322193 CLEAVAGE AND POLYADENYLATION
SPECIFICITY FACTOR, 160 KDA SUBUNIT
(CPSF 160 KDA SUBUNIT).
M200004343 4833412N02Rik NM_029020 AK030624 —
M200002381 Fanca NM_016925 AF178934 FANCONI ANEMIA, COMPLEMENTATION
GROUP A.
200 Gy
M200013484 9030617O03Rik NM_145448 BC021385 —
M200000800 Ccng1 NM_009831 AB005559 CYCLIN G1 (CYCLIN G).
M200016031 Polk NM_012048 AB040764 POLYMERASE (DNA DIRECTED), KAPPA; DINB
HOMOLOG 1 (E. COLI); DNA DAMAGE-
INDUCIBLE PROETIN B; DNA DAMAGE-
INDUCIBLE PROTEIN B; POLYMERASE (DNA
DIRECTED) KAPPA.
M200007794 Wig1 NM_009517 AF012923 WILD-TYPE P53-INDUCED GENE 1.
M300006854 Sec8 NM_009148 BC034644 EXOCYST COMPLEX COMPONENT SEC8.
[Source: SWISSPROT; Acc: O35382]
M200006137 Stinp NM_021897 AY034612 STRESS INDUCED PROTEIN; THYMUS
EXPRESSED ACIDIC PROTEIN.
M200007477 2310047O13Rik NM_024185 BC027202 —
M300020474 — — — —
M200003982 Golga5 NM_013747 AF026274 GOLGI AUTOANTIGEN, GOLGIN
SUBFAMILY A, 5.
M300020472 — — — —
M200004045 AI504353 NM_153419 BC008121 GLUTAMATE RICH WD REPEAT PROTEIN
GRWD.]
M200002527 Cnbp NM_013493 U20326 CELLULAR NUCLEIC ACID BINDING PROTEIN
(CNBP).]
M200014192 — NM_053193 AF322193 CLEAVAGE AND POLYADENYLATION
SPECIFICITY FACTOR. 160 KDA SUBUNIT
(CPSF 160 KDA SUBUNIT).]
M300000277 2310004L02Rik NM_025504 AK009150 —
M200012890 Smarca4 — BC026672 —
M200005377 Itpr3 NM_080553 Z71174 INOSITOL 1,4,5-TRISPHOSPHATE RECEPTOR
TYPE 3 (TYPE 3 INOSITOL 1,4,5-
TRISPHOSPHATE RECEPTOR) (TYPE 3 INSP3
RECEPTOR) (IP3 RECEPTOR ISOFORM 3)
(INSP3R3) (FRAGMENT). [
M200002473 Acas2l NM_080575 AK088244 ACETYL-COA SYNTHETASE 2-LIKE; ACETYL-
COENZYME A SYNTHETASE 2.
M300011684 Pold1 NM_011131 AF024570 DNA POLYMERASE DELTA CATALYTIC
SUBUNIT (EC 2.7.7.7).
M300009152 Tpst1 NM_013837 AF038008 PROTEIN-TYROSINE SULFOTRANSFERASE 1
(EC 2.8.2.20) (TYROSYLPROTEIN
SULFOTRANSFERASE-1) (TPST-1).
M200014327 Bcar3 NM_013867 BC023930 BREAST CANCER ANTI-ESTROGEN
RESISTANCE3
M300013112 — — J00595 IG LAMBDA-2 CHAIN C REGION.
M200006566 Gga2 — AK004632 —
M300007254 — NM_172900 — —
M200009317 Scd1 NM_009127 BC007474 ACYL-COA DESATURASE 1 (EC 1.14.19.1)
(STEAROYL-COA DESATURASE 1) (FATTY
ACID DESATURASE 1) (DELTA(9)-
DESATURASE 1).
M200001144 Cd79b NM_008339 AF002279 B-CELL ANTIGEN RECEPTOR COMPLEX
ASSOCIATED PROTEIN BETA-CHAIN
PRECURSOR (B-CELL-SPECIFIC
GLYCOPROTEIN B29) (IMMUNOGLOBULIN-
ASSOCIATED B29 PROTEIN) (IG-BETA)
(CD79B).
M200004687 Dda3-pending NM_019976 AK041835 DIFFERENTIAL DISPLAY AND ACTIVATED BY
P53; P53-REGULATED DDA3.
M300020088 — — — —
M300004256 Fth NM_010239 M24509 FERRITIN HEAVY CHAIN (FERRITIN H
SUBUNIT).
M300014099 Actl NM_013798 AF195094 ACTIN-LIKE.
M300020371 — — — —
M200006851 — NM_026467 — RIBOSOMAL PROTEIN S27-LIKE.
M300015889 — — — —
M300019801 — — — —
M300018553 — — — —
M300021441 — — — —
M300015305 — — — —
M300019335 Gapd NM_008084 AK002273 GLYCERALDEHYDE 3-PHOSPHATE
DEHYDROGENASE (EC 1.2.1.12) (GAPDH).
M300020777 — — — —
M200003258 Cox8a NM_007750 U37721 CYTOCHROME C OXIDASE POLYPEPTIDE VIII-
LIVER, MITOCHONDRIAL PRECURSOR (EC
1.9.3.1).
M300014515 — — — —
M300018314 — — — —
M200001083 Hspa9a NM_010481 AK002634 STRESS-70 PROTEIN, MITOCHONDRIAL
PRECURSOR (75 KDA GLUCOSE REGULATED
PROTEIN) (GRP 75) (PEPTIDE-BINDING
PROTEIN 74) (PBP74) (P66 MOT) (MORTALIN).
M300018559 — — — —
M300012796 Hmgn1 NM_008251 X53476 NONHISTONE CHROMOSOMAL PROTEIN
HMG-14 (HIGH-MOBILITY GROUP
NUCLEOSOME BINDING DOMAIN 1).
M200000777 G3bp-pending NM_013716 AB001927 RAS-GTPASE-ACTIVATING PROTEIN BINDING
PROTEIN 1 (GAP SH3-DOMAIN BINDING
PROTEIN 1) (G3BP-1).
M300021668 — — — —
M300002115 Xpo1 NM_134014 BC025628 EXPORTIN 1, CRM1 HOMOLOG; EXPRESSED
SEQUENCE AA420417.
M300017554 4930415K17Rik NM_133687 BC016207 —
M300004265 Ms4a1 NM_007641 AK017903 B-CELL SURFACE PROTEIN CD20 HOMOLOG
(B-CELL DIFFERENTIATION ANTIGEN LY-44).
M200001144 Cd79b NM_008339 AF002279 B-CELL ANTIGEN RECEPTOR COMPLEX
ASSOCIATED PROTEIN BETA-CHAIN
PRECURSOR (B-CELL-SPECIFIC
GLYCOPROTEIN B29) (IMMUNOGLOBULIN-
ASSOCIATED B29 PROTEIN) (IG-BETA)
(CD79B).
1000 Gy
M200007547 Phlda3 NM_013750 BC023408 PLECKSTRIN HOMOLOGY-LIKE DOMAIN,
FAMILY A, MEMBER 3; TDAG/LPL HOMOLOG 1.
M200016031 Polk NM_012048 AB040764 POLYMERASE (DNA DIRECTED), KAPPA; DINB
HOMOLOG 1 (E. COLI); DNA DAMAGE-
INDUCIBLE PROETIN B; DNA DAMAGE-
INDUCIBLE PROTEIN B; POLYMERASE (DNA
DIRECTED) KAPPA.
M200004687 Dda3-pending NM_019976 AK041835 DIFFERENTIAL DISPLAY AND ACTIVATED BY
P53; P53-REGULATED DDA3.
M200007578 Cdkn1a NM_007669 U24173 CYCLIN-DEPENDENT KINASE INHIBITOR 1
(P21) (CDK-INTERACTING PROTEIN 1)
(MELANOMA DIFFERENTIATION ASSOCIATED
PROTEIN).
M200007794 Wig1 NM_009517 AF012923 WILD-TYPE P53-INDUCED GENE 1.
M200015712 3300002K07Rik NM_152809 BC033601 —
M300000277 2310004L02Rik NM_025504 AK009150 —
M300003012 — — — —
M200009576 Recc1 NM_011258 U15037 ACTIVATOR 1 140 KDA SUBUNIT
(REPLICATION FACTOR C LARGE SUBUNIT)
(A1 140 KDA SUBUNIT) (RF-C 140 KDA
SUBUNIT) (ACTIVATOR 1 LARGE SUBUNIT)
(A1-P145) (DIFFERENTIATION SPECIFIC
ELEMENT BINDING PROTEIN) (ISRE-BINDING
PROTEIN).
M300011684 Pold1 NM_011131 AF024570 DNA POLYMERASE DELTA CATALYTIC
SUBUNIT (EC 2.7.7.7).
M300010073 — — — —
M200004560 — NM_026942 — —
M200005905 — — BC022623 —
M200002473 Acas2l NM_080575 AK088244 ACETYL-COA SYNTHETASE 2-LIKE; ACETYL-
COENZYME A SYNTHETASE 2.
M200006174 0610039P13Rik NM_028752 BC021548 —
M200014932 Swap70 NM_009302 AF053974 SWAP COMPLEX PROTEIN; SWAP COMPLEX
PROTEIN, 70 KDA.
M200006566 Gga2 — AK004632 —
M200000662 Dtx1 NM_008052 AB015422 DELTEX 1 HOMOLOG (DROSOPHILA);
FRACTIONATED X-IRRADIATION INDUCED
TRANSCRIPT 1.
M300007360 — — — —
M300013112 — — J00595 IG LAMBDA-2 CHAIN C REGION.
M300004265 Ms4a1 NM_007641 AK017903 B-CELL SURFACE PROTEIN CD20 HOMOLOG
(B-CELL DIFFERENTIATION ANTIGEN LY-44).
M300007254 — NM_172900 — —
M300000491 — — AF287275 IG LAMBDA-1 CHAIN V REGION PRECURSOR.
M200009317 Scd1 NM_009127 BC007474 ACYL-COA DESATURASE 1 (EC 1.14.19.1)
(STEAROYL-COA DESATURASE 1) (FATTY
ACID DESATURASE 1) (DELTA(9)-
DESATURASE 1).
M200001144 Cd79b NM_008339 AF002279 B-CELL ANTIGEN RECEPTOR COMPLEX
ASSOCIATED PROTEIN BETA-CHAIN
PRECURSOR (B-CELL-SPECIFIC
GLYCOPROTEIN B29) (IMMUNOGLOBULIN-
ASSOCIATED B29 PROTEIN) (IG-BETA)
(CD79B).
FEMALES
50 Gy
M300002291 — — — —
M200004687 Dda3-pending NM_019976 AK041835 DIFFERENTIAL DISPLAY AND ACTIVATED BY
P53; P53-REGULATED DDA3.
M200000800 Ccng1 NM_009831 AB005559 CYCLIN G1 (CYCLIN G)
M300016629 — — — —
M300020491 — — U38498 GUANINE NUCLEOTIDE-BINDING PROTEIN
G(I)/G(S)/G(O) GAMMA-5 SUBUNIT.
M300015969 — — — —
M200006491 Pgls NM_025396 BC006594 6-PHOSPHOGLUCONOLACTONASE.
M300010063 — — — —
M300016018 — NM_023133 — RIBOSOMAL PROTEIN S19.
M200002378 S100a13 NM_009113 BC005687 S100 CALCIUM-BINDING PROTEIN A13.
M300019659 — — — —
M300019012 — — — —
M300009287 — — — —
M300002125 — — — —
M300008077 Ei24 NM_007915 U41751 ETOPOSIDE-INDUCED PROTEIN 2.4.
M200006774 2400001E08Rik NM_025605 BC020142 —
M300008474 D10Jhu81e NM_138601 AB041855 —
M200000096 B3Gat3 NM_024256 BC002103 GALACTOSYLGALACTOSYLXYLOSYLPROTEIN
3-BETA-GLUCURONOSYLTRANSFERASE 3 (EC
2.4.1.135) (BETA-1,3-
GLUCURONYLTRANSFERASE 3)
(GLUCURONOSYLTRANSFERASE-I) (GLCAT-I)
(UDP-GLCUA: GAL BETA-1,3-GAL-R
GLUCURONYLTRANSFERASE) (GLCUAT-I).
M300000948 — — AA277150 CLATHRIN COAT ASSEMBLY PROTEIN AP17
(CLATHRIN COAT ASSOCIATED PROTEIN
AP17) (PLASMA MEMBRANE ADAPTOR AP-2
17 KDA PROTEIN) (HA2 17 KDA SUBUNIT)
(CLATHRIN ASSEMBLY PROTEIN 2
SMALL CHAIN).
M300001725 — NM_175015 AA275923 ATP SYNTHASE LIPID-BINDING PROTEIN,
MITOCHONDRIAL PRECURSOR (EC 3.6.3.14)
(ATP SYNTHASE PROTEOLIPID P3) (ATPASE
PROTEIN 9) (ATPASE SUBUNIT C).
M300006374 Psmc2 — BC005462 26S PROTEASE REGULATORY SUBUNIT 7
(MSS1 PROTEIN).
M300005124 5730454B08Rik NM_144530 BC005786 —
M200000777 G3bp-pending NM_013716 AB001927 RAS-GTPASE-ACTIVATING PROTEIN BINDING
PROTEIN 1 (GAP SH3-DOMAIN BINDING
PROTEIN 1) (G3BP-1).
M200003749 — — — —
M300018559 — — — —
200 Gy
M200004687 Dda3-pending NM_019976 AK041835 DIFFERENTIAL DISPLAY AND ACTIVATED BY
P53; P53-REGULATED DDA3.
M300020088 — — — —
M300004256 Fth NM_010239 M24509 FERRITIN HEAVY CHAIN (FERRITIN H
SUBUNIT).
M300014099 Actl NM_013798 AF195094 ACTIN-LIKE.
M300020371 — — — —
M200006851 — NM_026467 — RIBOSOMAL PROTEIN S27-LIKE.
M300015889 — — — —
M300019801 — — — —
M300018553 — — — —
M300021441 — — — —
M300015305 — — — —
M300019335 Gapd NM_008084 AK002273 GLYCERALDEHYDE 3-PHOSPHATE
DEHYDROGENASE (EC 1.2.1.12) (GAPDH).
M300020777 — — — —
M200003258 Cox8a NM_007750 U37721 CYTOCHROME C OXIDASE POLYPEPTIDE VIII-
LIVER, MITOCHONDRIAL PRECURSOR (EC 1.9.3.1).
M300014515 — — — —
M300018314 — — — —
M200001083 Hspa9a NM_010481 AK002634 STRESS-70 PROTEIN, MITOCHONDRIAL
PRECURSOR (75 KDA GLUCOSE REGULATED
PROTEIN) (GRP 75) (PEPTIDE-BINDING
PROTEIN 74) (PBP74) (P66 MOT) (MORTALIN).
M300018559 — — — —
M300012796 Hmgn1 NM_008251 X53476 NONHISTONE CHROMOSOMAL PROTEIN
HMG-14 (HIGH-MOBILITY GROUP
NUCLEOSOME BINDING DOMAIN 1).
M200000777 G3bp-pending NM_013716 AB001927 RAS-GTPASE-ACTIVATING PROTEIN BINDING
PROTEIN 1 (GAP SH3-DOMAIN BINDING
PROTEIN 1) (G3BP-1).
M300021668 — — — —
M300002115 Xpo1 NM_134014 BC025628 EXPORTIN 1, CRM1 HOMOLOG; EXPRESSED
SEQUENCE AA420417.
M300017554 4930415K17Rik NM_133687 BC016207 —
M300004265 Ms4a1 NM_007641 AK017903 B-CELL SURFACE PROTEIN CD20 HOMOLOG
(B-CELL DIFFERENTIATION ANTIGEN LY-44).
M200001144 Cd79b NM_008339 AF002279 B-CELL ANTIGEN RECEPTOR COMPLEX
ASSOCIATED PROTEIN BETA-CHAIN
PRECURSOR (B-CELL-SPECIFIC
GLYCOPROTEIN B29) (IMMUNOGLOBULIN-
ASSOCIATED B29 PROTEIN) (IG-BETA)
(CD79B).
1000 Gy
M200004687 Dda3-pending NM_019976 AK041835 DIFFERENTIAL DISPLAY AND ACTIVATED BY
P53; P53-REGULATED DDA3.
M300008077 Ei24 NM_007915 U41751 ETOPOSIDE-INDUCED PROTEIN 2.4.
M300011848 — NM_173445 — —
M300020371 — — — —
M300019400 — — — —
M300019801 — — — —
M300014889 Gapd NM_008084 AK002273 GLYCERALDEHYDE 3-PHOSPHATE
DEHYDROGENASE (EC 1.2.1.12) (GAPDH).
M300019335 Gapd NM_008084 AK002273 GLYCERALDEHYDE 3-PHOSPHATE
DEHYDROGENASE (EC 1.2.1.12) (GAPDH).
M300000465 2610301D06Rik NM_026007 AK014277 ELONGATION FACTOR 1-GAMMA (EF-1-
GAMMA) (EEF-1B GAMMA).
M300019589 — — — —
M300012879 — — AK007389 SMALL NUCLEAR RIBONUCLEOPROTEIN SM
D2 (SNRNP CORE PROTEIN D2) (SM-D2).
M300002970 5730420B22Rik NM_172597 AK017582 —
M300021668 — — — —
M300011495 — — BG088667 SESTRIN 1 (P53-REGULATED PROTEIN PA26).
M300017752 — — AF516285 ANTI-VIPASE LIGHT CHAIN VARIABLE REGION
(FRAGMENT).
M300007254 — NM_172900 — —
M200006566 Gga2 — AK004632 —
M200006174 0610039P13Rik NM_028752 BC021548 —
M200000312 Ly6d NM_010742 L40419 LYMPHOCYTE ANTIGEN LY-6D PRECURSOR
(THYMOCYTE B CELL ANTIGEN) (THB).
M200000320 Pou2af1 NM_011136 U43788 POU DOMAIN CLASS 2, ASSOCIATING
FACTOR 1 (B-CELL-SPECIFIC COACTIVATOR
OBF-1) (OCT BINDING FACTOR 1) (BOB-1)
(BOB1) (OCA-B).
M200001703 Cd19 NM_009844 M84372 B-LYMPHOCYTE ANTIGEN CD19 PRECURSOR
(B-LYMPHOCYTE SURFACE ANTIGEN B4)
(LEU-12) (DIFFERENTIATION ANTIGEN CD19).
M200000715 BB219290 NM_145141 AF426462 FC RECEPTOR HOMOLOG EXPRESSED IN B
CELLS; FC RECEPTOR RELATED PROTEIN X.
M200002822 Blnk NM_008528 AJ298054 B-CELL LINKER; LYMPHOCYTE ANTIGEN 57.
M200001144 Cd79b NM_008339 AF002279 B-CELL ANTIGEN RECEPTOR COMPLEX
ASSOCIATED PROTEIN BETA-CHAIN
PRECURSOR (B-CELL-SPECIFIC
GLYCOPROTEIN B29) (IMMUNOGLOBULIN-
ASSOCIATED B29 PROTEIN) (IG-BETA)
(CD79B).
M200009317 Scd1 NM_009127 BC007474 ACYL-COA DESATURASE 1 (EC 1.14.19.1)
(STEAROYL-COA DESATURASE 1) (FATTY
ACID DESATURASE 1) (DELTA(9)-
DESATURASE 1).
TABLE 2
Genes that overlap between mouse groups. Operon Oligo ID can
be queried in the OMAD database (http://omad.operon.com)
Operon Gene
OligoID Symbol RefSeq Genbank Description
SEX
C57Bl6 M and C57Bl6 F
M vs F 59 cGy
M200000800 Ccng1 NM_009831 AB005559 CYCLIN G1 (CYCLIN G)
M200004687 Dda3 NM_019976 AK041835 DIFFERENTIAL DISPLAY AND ACTIVATED BY
P53; P53-REGULATED DDA3.
M vs F 200 cGy
M200001144 Cd79b NM_008339 AF002279 B-CELL ANTIGEN RECEPTOR COMPLEX
ASSOCIATED PROTEIN BETA-CHAIN
PRECURSOR (B-CELL-SPECIFIC
GLYCOPROTEIN B29) (IMMUNOGLOBULIN-
ASSOCIATED B29 PROTEIN) (IG-BETA)
(CD79B).
M vs F 1000 cGy
M200001144 Cd79b NM_008339 AF002279 B-CELL ANTIGEN RECEPTOR COMPLEX
ASSOCIATED PROTEIN BETA-CHAIN
PRECURSOR (B-CELL-SPECIFIC
GLYCOPROTEIN B29) (IMMUNOGLOBULIN-
ASSOCIATED B29 PROTEIN) (IG-BETA)
(CD79B).
M200004687 Dda3 NM_019976 AK041835 DIFFERENTIAL DISPLAY AND ACTIVATED BY
P53; P53-REGULATED DDA3.
M200009317 Scd1 NM_009127 BC007474 ACYL-COA DESATURASE 1 (EC 1.14.19.1)
(STEAROYL-COA DESATURASE 1) (FATTY
ACID DESATURASE 1) (DELTA(9)-
DESATURASE 1).
M200006566 Gga2 — AK004632 —
M200006174
M300007254
GENOTYPE
C57Bl6 F and BALB/c F
Bl vs BA 50 cGy
M200000800 Ccng1 NM_009831 AB005559 CYCLIN G1 (CYCLIN G)
M200004687 Dda3 NM_019976 AK041835 DIFFERENTIAL DISPLAY AND ACTIVATED BY
P53; P53-REGULATED DDA3.
M300008077 Ei24 NM_007915 U41751 ETOPOSIDE-INDUCED PROTEIN 2.4.
Bl vs BA 200 cGy
M200004687 Dda3 NM_019976 AK041835 DIFFERENTIAL DISPLAY AND ACTIVATED BY
P53; P53-REGULATED DDA3.
Bl vs BA 1000 cGy
M200004687 Dda3 NM_019976 AK041835 DIFFERENTIAL DISPLAY AND ACTIVATED BY
P53; P53-REGULATED DDA3.
TIME
Within C57Bl6 F
6 hr vs 24 hr 50 cGy
None
6 hr vs 24 hr 200 cGy
None
6 hr vs 24 hr 1000 cGy
None
6 hr vs 7 d 50 cGy
None
6 hr vs 7 d 200 cGy
None
24 h vs 7 d 50 cGy
M300000165 Lgals1 NM_008495 AK004298 GALECTIN-1 (BETA-GALACTOSIDE-BINDING
LECTIN L-14-I) (LACTOSE-BINDING LECTIN 1)
(S-LAC LECTIN 1)
24 h vs 7 d 200 cGy
None
Impact of Genotype on Prediction of Radiation Status Since the human population is genetically diverse, an examination was next made to determine whether gene expression signatures of radiation exposure could accurately predict the status of mice across different genotypes. PB was collected from C57Bl6 and BALB/c mice at 6 hours following 50 cGy, 200 cGy or 1000 cGy. It was possible to identify patterns of gene expression which appeared to distinguish the different levels of radiation from the non-irradiated controls within each strain (FIG. 3A). However, when the PB gene expression signatures from C57Bl6 mice were tested against BALB/c mice, and vice versa, the gene expression profiles were less distinct (FIG. 3B). A leave-one-out cross-validation analysis was then performed in which gene expression profiles from C57Bl6 mice were tested against PB from BALB/c mice and found that the metagene predictors of radiation from C57Bl6 mice displayed 100% accuracy in predicting the status of non-irradiated and irradiated BALB/c mice (FIG. 3C). Similarly, application of the PB metagene profiles of radiation generated in BALB/c mice demonstrated 100% accuracy in distinguishing non-irradiated and irradiated C57Bl6 mice. Interestingly, less than 20% of the genes represented within the PB predictors from C57Bl6 mice and BALB/c mice overlapped (Table 3, Table 2), but both predictors were highly accurate in predicting the radiation status of the different strain of mice. Dda3, a p53-inducible gene, which participates in suppression of cell growth (Hsieh et al, Oncogene 21:3050-3057 (2002)), was represented in both strains at all radiation doses.
TABLE 3
Genes that distinguish radiation responses in BALB/c mice. Operon Oligo
ID can be queried in the OMAD database (http://omad.operon.com)
Operon Gene
OligoID Symbol RefSeq Genbank Description
50 Gy
M200013484 9030617O03Rik NM_145448 BC021385 —
M200004687 Dda3-pending NM_019976 AK041835 DIFFERENTIAL DISPLAY AND ACTIVATED BY
P53; P53-REGULATED DDA3.
M300000487 Bax NM_007527 L22472 APOPTOSIS REGULATOR BAX, MEMBRANE
ISOFORM ALPHA.
M300006855 Sec8 NM_009148 BC034644 EXOCYST COMPLEX COMPONENT SEC8.
M300001199 — — BC002257 —
M200000800 Ccng1 NM_009831 AB005559 CYCLIN G1 (CYCLIN G).
M200016031 Polk NM_012048 AB040764 POLYMERASE (DNA DIRECTED), KAPPA; DINB
HOMOLOG 1 (E. COLI); DNA DAMAGE-
INDUCIBLE PROETIN B; DNA DAMAGE-
INDUCIBLE PROTEIN B; POLYMERASE (DNA
DIRECTED) KAPPA.
M200003784 Bax NM_007527 L22472 APOPTOSIS REGULATOR BAX, MEMBRANE
ISOFORM ALPHA.
M200007547 Phlda3 NM_013750 BC023408 PLECKSTRIN HOMOLOGY-LIKE DOMAIN,
FAMILY A, MEMBER 3; TDAG/LPL HOMOLOG 1.
M300010491 D030041N15Rik NM_153416 BC018191 ALADIN (ADRACALIN).
M200006364 Dcxr NM_026428 AK004023 DIACETYL/L-XYLULOSE REDUCTASE.
M300007324 2700083B06Rik NM_026531 BC022614 —
M300000486 Bax NM_007527 L22472 APOPTOSIS REGULATOR BAX, MEMBRANE
ISOFORM ALPHA.
M200007794 Wig1 NM_009517 AF012923 WILD-TYPE P53-INDUCED GENE 1.
M300008077 Ei24 NM_007915 U41751 ETOPOSIDE-INDUCED PROTEIN 2.4.
M300003395 Ly6e NM_008529 U47737 LYMPHOCYTE ANTIGEN LY-6E PRECURSOR
(THYMIC SHARED ANTIGEN-1) (TSA-1) (STEM
CELL ANTIGEN 2).
M200003474 D730042P09Rik NM_144543 AB080370 THYMOCYTE PROTEIN THY28.
M200012250 Scd2 NM_009128 M26270 ACYL-COA DESATURASE 2 (EC 1.14.19.1)
(STEAROYL-COA DESATURASE 2) (FATTY
ACID DESATURASE 2) (DELTA(9)-
DESATURASE 2).
M200000655 Tnfrsf6 NM_007987 S56486 TUMOR NECROSIS FACTOR RECEPTOR
SUPERFAMILY MEMBER 6 PRECURSOR (FASL
RECEPTOR) (APOPTOSIS-MEDIATING
SURFACE ANTIGEN FAS) (APO-1 ANTIGEN)
(CD95).
M200008006 2410089B13Rik — AK010745 —
M200000279 Ly6e NM_008529 U47737 LYMPHOCYTE ANTIGEN LY-6E PRECURSOR
(THYMIC SHARED ANTIGEN-1) (TSA-1) (STEM
CELL ANTIGEN 2).
M200000354 ORF21 NM_145482 BC029101 —
M300002140 D11Ertd603e NM_026023 AK004388 —
M300002232 Ppm1d NM_016910 AF200464 PROTEIN PHOSPHATASE 2C DELTA ISOFORM
(EC 3.1.3.16) (PP2C-DELTA) (P53-INDUCED
PROTEIN PHOSPHATASE 1) (PROTEIN
PHOSPHATASE MAGNESIUM- DEPENDENT 1
DELTA).
M300002800 Zfp369 — BC036565 NEUROTROPHIN RECEPTOR INTERACTING
FACTOR 2.
200 Gy
M200004687 Dda3-pending NM_019976 AK041835 DIFFERENTIAL DISPLAY AND ACTIVATED BY
P53; P53-REGULATED DDA3.
M300020088 — — — —
M300004256 Fth NM_010239 M24509 FERRITIN HEAVY CHAIN (FERRITIN H
SUBUNIT).
M300014099 Actl NM_013798 AF195094 ACTIN-LIKE.
M300020371 — — — —
M200006851 — NM_026467 — RIBOSOMAL PROTEIN S27-LIKE.
M300015889 — — — —
M300019801 — — — —
M300018553 — — — —
M300021441 — — — —
M300015305 — — — —
M300019335 Gapd NM_008084 AK002273 GLYCERALDEHYDE 3-PHOSPHATE
DEHYDROGENASE (EC 1.2.1.12) (GAPDH).
M300020777 — — — —
M200003258 Cox8a NM_007750 U37721 CYTOCHROME C OXIDASE POLYPEPTIDE VIII-
LIVER, MITOCHONDRIAL PRECURSOR (EC
1.9.3.1).
M300014515 — — — —
M300018314 — — — —
M200001083 Hspa9a NM_010481 AK002634 STRESS-70 PROTEIN, MITOCHONDRIAL
PRECURSOR (75 KDA GLUCOSE REGULATED
PROTEIN) (GRP 75) (PEPTIDE-BINDING
PROTEIN 74) (PBP74) (P66 MOT) (MORTALIN).
M300018559 — — — —
M300012796 Hmgn1 NM_008251 X53476 NONHISTONE CHROMOSOMAL PROTEIN HMG-14
(HIGH-MOBILITY GROUP NUCLEOSOME
BINDING DOMAIN 1).
M200000777 G3bp-pending NM_013716 AB001927 RAS-GTPASE-ACTIVATING PROTEIN BINDING
PROTEIN 1 (GAP SH3-DOMAIN BINDING
PROTEIN 1) (G3BP-1).
M300021668 — — — —
M300002115 Xpo1 NM_134014 BC025628 EXPORTIN 1, CRM1 HOMOLOG; EXPRESSED
SEQUENCE AA420417.
M300017554 4930415K17Rik NM_133687 BC016207 —
M300004265 Ms4a1 NM_007641 AK017903 B-CELL SURFACE PROTEIN CD20 HOMOLOG
(B-CELL DIFFERENTIATION ANTIGEN LY-44).
M200001144 Cd79b NM_008339 AF002279 B-CELL ANTIGEN RECEPTOR COMPLEX
ASSOCIATED PROTEIN BETA-CHAIN
PRECURSOR (B-CELL-SPECIFIC
GLYCOPROTEIN B29) (IMMUNOGLOBULIN-
ASSOCIATED B29 PROTEIN) (IG-BETA)
(CD79B).
1000 Gy
M200004687 Dda3-pending NM_019976 AK041835 DIFFERENTIAL DISPLAY AND ACTIVATED BY
P53; P53-REGULATED DDA3.
M300008077 Ei24 NM_007915 U41751 ETOPOSIDE-INDUCED PROTEIN 2.4.
M300011848 — NM_173445 — —
M300020371 — — — —
M300019400 — — — —
M300019801 — — — —
M300014889 Gapd NM_008084 AK002273 GLYCERALDEHYDE 3-PHOSPHATE
DEHYDROGENASE (EC 1.2.1.12) (GAPDH).
M300019335 Gapd NM_008084 AK002273 GLYCERALDEHYDE 3-PHOSPHATE
DEHYDROGENASE (EC 1.2.1.12) (GAPDH).
M300000465 2610301D06Rik NM_026007 AK014277 ELONGATION FACTOR 1-GAMMA
(EF-1-GAMMA) (EEF-1B GAMMA).
M300019589 — — — —
M300012879 — — AK007389 SMALL NUCLEAR RIBONUCLEOPROTEIN SM
D2 (SNRNP CORE PROTEIN D2) (SM-D2).
M300002970 5730420B22Rik NM_172597 AK017582 —
M300021668 — — — —
M300011495 — — BG088667 SESTRIN 1 (P53-REGULATED PROTEIN PA26).
M300017752 — — AF516285 ANTI-VIPASE LIGHT CHAIN VARIABLE REGION
(FRAGMENT).
M300007254 — NM_172900 — —
M200006566 Gga2 — AK004632 —
M200006174 0610039P13Rik NM_028752 BC021548 —
M200000312 Ly6d NM_010742 L40419 LYMPHOCYTE ANTIGEN LY-6D PRECURSOR
(THYMOCYTE B CELL ANTIGEN) (THB).
M200000320 Pou2af1 NM_011136 U43788 POU DOMAIN CLASS 2, ASSOCIATING FACTOR
1 (B-CELL-SPECIFIC COACTIVATOR OBF-1)
(OCT BINDING FACTOR 1) (BOB-1) (BOB1)
(OCA-B).
M200001703 Cd19 NM_009844 M84372 B-LYMPHOCYTE ANTIGEN CD19 PRECURSOR
(B-LYMPHOCYTE SURFACE ANTIGEN B4)
(LEU-12) (DIFFERENTIATION ANTIGEN CD19).
M200000715 BB219290 NM_145141 AF426462 FC RECEPTOR HOMOLOG EXPRESSED IN B
CELLS; FC RECEPTOR RELATED PROTEIN X.
M200002822 Blnk NM_008528 AJ298054 B-CELL LINKER; LYMPHOCYTE ANTIGEN 57.
M200001144 Cd79b NM_008339 AF002279 B-CELL ANTIGEN RECEPTOR COMPLEX
ASSOCIATED PROTEIN BETA-CHAIN
PRECURSOR (B-CELL-SPECIFIC
GLYCOPROTEIN B29) (IMMUNOGLOBULIN-
ASSOCIATED B29 PROTEIN) (IG-BETA)
(CD79B).
M200009317 Scd1 NM_009127 BC007474 ACYL-COA DESATURASE 1 (EC 1.14.19.1)
(STEAROYL-COA DESATURASE 1) (FATTY
ACID DESATURASE 1) (DELTA(9)-
DESATURASE 1).
The Impact of Time on PB Gene Expression Signatures of Irradiation PB responses to environmental exposures may change over time as a function of changes in PB cellular composition and cellular responses themselves. Patterns of gene expression were identified in the PB of C57Bl6 female mice at 6 hrs, 24 hrs and 7 days post-irradiation which appeared to distinguish the 3 different levels of radiation versus non-irradiated mice (FIG. 4A). When the PB metagene profiles of radiation exposure generated from the 6 hr time point were applied against PB samples from mice at the 24 hr and 7 day time points post-irradiation, the profiles appeared less distinct (FIG. 4B). A leave-one-out cross-validation analysis demonstrated that the PB metagene profiles from each time point predicted each dose of radiation with 100% accuracy (FIG. 4C). Next, a leave-one-out cross-validation analysis was performed using the metagene profiles from the 6 hr time point against each of the PB samples from mice at 24 hr and 7 day time points and the 6 hr metagene profiles demonstrated 100% accuracy in predicting the radiation status of the 24 hr and 7 day time point samples (FIG. 4C). Of note, the 7 day time point following 1000 cGy exposure could not be analyzed since it was not possible to collect sufficient RNA from these PB samples to allow gene array hybridization to be performed. Although it was found that time did not impact the accuracy of PB gene expression profiles in predicting radiation status, the lists of genes which comprised these PB signatures changed significantly over 7 days (Table 4). No genes were found in common between the 6 hr predictors and the 24 hr or 7 day PB signatures of radiation in 50 cGy-, 200 cGy-, or 1000 cGy-treated mice (Table 2). A single gene, Galectin 1 (Lgals1), a carbohydrate binding protein that is involved in the induction of cell death (Valenzuela et al, Cancer Res. 67:6155-6162 (2007)), was found in common between the 24 hr and 7 day predictors of 50 cGy.
TABLE 4
Genes that distinguish the impact of time in C57Bl6 mice. Operon Oligo
ID can be queried in the OMAD database (http://omad.operon.com)
Operon Gene
Oligo ID Symbol RefSeq Genbank Description
Female C57Bl6 6 hr 50 cGy
M300002291 — — — —
M200004687 Dda3- NM_019976 AK041835 DIFFERENTIAL DISPLAY AND ACTIVATED BY
pending P53; P53-REGULATED DDA3.
M200000800 Ccng1 NM_009831 AB005559 CYCLIN G1 (CYCLIN G).
M300016629 — — — —
M300020491 — — U38498 GUANINE NUCLEOTIDE-BINDING PROTEIN
G(I)/G(S)/G(O) GAMMA-5 SUBUNIT.
M300015969 — — — —
M300010063 — — — —
M300016018 — NM_023133 — RIBOSOMAL PROTEIN S19.
M200002378 S100a13 NM_009113 BC005687 S100 CALCIUM-BINDING PROTEIN A13.
M300019659 — — — —
M300014141 V1rc22 NM_134177 AY065478 VOMERONASAL 1 RECEPTOR, C22.
M300020488 — — V00754 HISTONE H3.4 (EMBRYONIC).
M300019012 — — — —
M300014338 — — — —
M300009287 — — — —
M300002125 — — — —
M300008077 Ei24 NM_007915 U41751 ETOPOSIDE-INDUCED PROTEIN 2.4.
M200006774 2400001E08 NM_025605 BC020142 —
Rik
M300008474 D10Jhu81e NM_138601 AB041855 —
M200000096 B3Gat3 NM_024256 BC002103 GALACTOSYLGALACTOSYLXYLOSYLPROTEIN
3-BETA-GLUCURONOSYLTRANSFERASE 3
(EC 2.4.1.135) (BETA-1,3-
GLUCURONYLTRANSFERASE 3)
(GLUCURONOSYLTRANSFERASE-I) (GLCAT-I)
(UDP-GLCUA: GAL BETA-1,3-GAL-R
GLUCURONYLTRANSFERASE) (GLCUAT-I).
M300006374 Psmc2 — BC005462 26S PROTEASE REGULATORY SUBUNIT 7
(MSS1 PROTEIN).
M300005124 5730454B08 NM_144530 BC005786 —
Rik
M200000777 G3bp- NM_013716 AB001927 RAS-GTPASE-ACTIVATING PROTEIN BINDING
pending PROTEIN 1 (GAP SH3-DOMAIN BINDING
PROTEIN 1) (G3BP-1).
M200003749 — — — —
M300018559 — — — —
Female C57Bl6 6 hr 200 cGy
M200004687 Dda3- NM_019976 AK041835 DIFFERENTIAL DISPLAY AND ACTIVATED BY
pending P53; P53-REGULATED DDA3.
M300020088 — — — —
M300004256 Fth NM_010239 M24509 FERRITIN HEAVY CHAIN (FERRITIN H
SUBUNIT).
M300014099 Actl NM_013798 AF195094 ACTIN-LIKE.
M300020371 — — — —
M200006851 — NM_026467 — RIBOSOMAL PROTEIN S27-LIKE.
M300015889 — — — —
M300019801 — — — —
M300018553 — — — —
M300021441 — — — —
M300015305 — — — —
M300019335 Gapd NM_008084 AK002273 GLYCERALDEHYDE 3-PHOSPHATE
DEHYDROGENASE (EC 1.2.1.12) (GAPDH).
M300020777 — — — —
M200003258 Cox8a NM_007750 U37721 CYTOCHROME C OXIDASE POLYPEPTIDE VIII-
LIVER, MITOCHONDRIAL PRECURSOR
(EC 1.9.3.1).
M300014515 — — — —
M300018314 — — — —
M200001083 Hspa9a NM_010481 AK002634 STRESS-70 PROTEIN, MITOCHONDRIAL
PRECURSOR (75 KDA GLUCOSE REGULATED
PROTEIN) (GRP 75) (PEPTIDE-BINDING
PROTEIN 74) (PBP74) (P66 MOT) (MORTALIN).
M300018559 — — — —
M300012796 Hmgn1 NM_008251 X53476 NONHISTONE CHROMOSOMAL PROTEIN
HMG-14 (HIGH-MOBILITY GROUP
NUCLEOSOME BINDING DOMAIN 1).
M200000777 G3bp- NM_013716 AB001927 RAS-GTPASE-ACTIVATING PROTEIN BINDING
pending PROTEIN 1 (GAP SH3-DOMAIN BINDING
PROTEIN 1) (G3BP-1).
M300021668 — — — —
M300002115 Xpo1 NM_134014 BC025628 EXPORTIN 1, CRM1 HOMOLOG; EXPRESSED
SEQUENCE AA420417.
M300017554 4930415K17 NM_133687 BC016207 —
Rik
M300004265 Ms4a1 NM_007641 AK017903 B-CELL SURFACE PROTEIN CD20 HOMOLOG
(B-CELL DIFFERENTIATION ANTIGEN LY-44).
M200001144 Cd79b NM_008339 AF002279 B-CELL ANTIGEN RECEPTOR COMPLEX
ASSOCIATED PROTEIN BETA-CHAIN
PRECURSOR (B-CELL-SPECIFIC
GLYCOPROTEIN B29) (IMMUNOGLOBULIN-
ASSOCIATED B29 PROTEIN) (IG-BETA)
(CD79B).
Female C57Bl6 6 hr 1000 cGy
M200004687 Dda3- NM_019976 AK041835 DIFFERENTIAL DISPLAY AND ACTIVATED BY
pending P53; P53-REGULATED DDA3.
M300008077 Ei24 NM_007915 U41751 ETOPOSIDE-INDUCED PROTEIN 2.4.
M300011848 — NM_173445 — —
M300020371 — — — —
M300019852 — — — —
M300019400 — — — —
M300019801 — — — —
M300014889 Gapd NM_008084 AK002273 GLYCERALDEHYDE 3-PHOSPHATE
DEHYDROGENASE (EC 1.2.1.12) (GAPDH).
M300000465 2610301D06 NM_026007 AK014277 ELONGATION FACTOR 1-GAMMA
Rik (EF-1-GAMMA) (EEF-1B GAMMA).
M300019589 — — — —
M300012879 — — AK007389 SMALL NUCLEAR RIBONUCLEOPROTEIN SM
D2 (SNRNP CORE PROTEIN D2) (SM-D2).
M300006168 — NM_177045 — —
M300002970 5730420B22 NM_172597 AK017582 —
Rik
M200009547 Mybbp1a NM_016776 U63648 MYB BINDING PROTEIN (P160) 1A; NUCLEAR
PROTEIN P160.
M300021668 — — — —
M300011495 — — BG088667 SESTRIN 1 (P53-REGULATED PROTEIN PA26).
M300017752 — — AF516285 ANTI-VIPASE LIGHT CHAIN VARIABLE REGION
(FRAGMENT).
M300007254 — NM_172900 — —
M200006566 Gga2 — AK004632 —
M200006174 0610039P13 NM_028752 BC021548 —
Rik
M200000312 Ly6d NM_010742 L40419 LYMPHOCYTE ANTIGEN LY-6D PRECURSOR
(THYMOCYTE B CELL ANTIGEN) (THB).
M200000320 Pou2af1 NM_011136 U43788 POU DOMAIN CLASS 2, ASSOCIATING
FACTOR 1 (B-CELL-SPECIFIC COACTIVATOR
OBF-1) (OCT BINDING FACTOR 1) (BOB-1)
(BOB1) (OCA-B).
M200002822 Blnk NM_008528 AJ298054 B-CELL LINKER; LYMPHOCYTE ANTIGEN 57.
M200001144 Cd79b NM_008339 AF002279 B-CELL ANTIGEN RECEPTOR COMPLEX
ASSOCIATED PROTEIN BETA-CHAIN
PRECURSOR (B-CELL-SPECIFIC
GLYCOPROTEIN B29) (IMMUNOGLOBULIN-
ASSOCIATED B29 PROTEIN) (IG-BETA)
(CD79B).
M200009317 Scd1 NM_009127 BC007474 ACYL-COA DESATURASE 1 (EC 1.14.19.1)
(STEAROYL-COA DESATURASE 1) (FATTY
ACID DESATURASE 1) (DELTA(9)-
DESATURASE 1).
Female C57Bl6 24 hr 50 cGy
M300005062 BC027756 NM_145991 AK080861 —
M200005746 1110020J08 NM_025394 AK003864 —
Rik
M200003036 Nprl2- NM_018879 BC026548 G21 PROTEIN.
pending
M200004472 Slc25a1 NM_153150 BC037087 SOLUTE CARRIER FAMILY 25, MEMBER 1;
DIGEORGE SYNDROME GENE J; SOLUTE
CARRIER FAMILY 25 (MITOCHONDRIAL
CARRIER; CITRATE TRANSPORTER)
MEMBER 1; TRICARBOXYLATE TRANSPORT
PROTEIN PRECURSOR.
M200006750 2410104I19R NM_133691 BC010601 —
ik
M200009777 Aco2 NM_080633 BC004645 ACONITASE 2, MITOCHONDRIAL.
M200007587 E130307M08 NM_026530 BC017625 —
Rik
M200002043 Mcmd6 NM_008567 D86726 DNA REPLICATION LICENSING FACTOR MCM6
(MIS5 HOMOLOG).
M200005598 Cdk9 NM_130860 AF327431 CYCLIN-DEPENDENT KINASE 9.
M200006108 Coro1b NM_011778 AK008947 CORONIN 1B (CORONIN 2).
M300012497 Rbms2 NM_019711 AK054482 RNA BINDING MOTIF, SINGLE STRANDED
INTERACTING PROTEIN 2; SCR3.
M200003074 Psmd3 NM_009439 BC003197 26S PROTEASOME NON-ATPASE
REGULATORY SUBUNIT 3 (26S PROTEASOME
REGULATORY SUBUNIT S3) (PROTEASOME
SUBUNIT P58) (TRANSPLANTATION ANTIGEN
P91A) (TUM-P91A ANTIGEN).
M300013135 — — BC034540 —
M300019447 — — BC027368 —
M200009417 Mt2 — K02236 METALLOTHIONEIN-II (MT-II).
M300021033 Lgals3 — X16074 GALECTIN-3 (GALACTOSE-SPECIFIC LECTIN
3) (MAC-2 ANTIGEN) (IGE-BINDING PROTEIN)
(35 KDA LECTIN) (CARBOHYDRATE BINDING
PROTEIN 35) (CBP 35) (LAMININ-BINDING
PROTEIN) (LECTIN L-29) (L-34 GALACTOSIDE-
BINDING LECTIN).
M300004485 P4hb — J05185 PROTEIN DISULFIDE ISOMERASE
PRECURSOR (PDI) (EC 5.3.4.1) (PROLYL 4-
HYDROXYLASE BETA SUBUNIT) (CELLULAR
THYROID HORMONE BINDING PROTEIN) (P55)
(ERP59).
M200012720 — — BC008093 EUKARYOTIC TRANSLATION INITIATION
FACTOR 5A (EIF-5A) (EIF-4D) (REV- BINDING
FACTOR).
M200006860 — NM_010312 U38505 GUANINE NUCLEOTIDE-BINDING PROTEIN
G(I)/G(S)/G(T) BETA SUBUNIT 2 (TRANSDUCIN
BETA CHAIN 2) (G PROTEIN BETA 2 SUBUNIT).
M300011574 — — — —
M300015461 — — — —
M300021713 — — — —
M200009655 Cct6a NM_009838 AB022159 T-COMPLEX PROTEIN 1, ZETA SUBUNIT (TCP-
1-ZETA) (CCT-ZETA) (CCT-ZETA- 1).
M300004979 Fn1 — BC004724 —
M200014015 Lgals1 NM_008495 AK004298 GALECTIN-1 (BETA-GALACTOSIDE-BINDING
LECTIN L-14-I) (LACTOSE-BINDING LECTIN 1)
(S-LAC LECTIN 1) (GALAPTIN) (14 KDA
LECTIN).
Female C57Bl6 24 hr 200 cGy
M300010249 Txk NM_013698 L35268 TYROSINE-PROTEIN KINASE TXK (EC
2.7.1.112) (PTK-RL-18) (RESTING
LYMPHOCYTE KINASE).
M300010028 — — BC026557 SIMILAR TO PTD015 PROTEIN.
M200009777 Aco2 NM_080633 BC004645 ACONITASE 2, MITOCHONDRIAL.
M200005598 Cdk9 NM_130860 AF327431 CYCLIN-DEPENDENT KINASE 9.
M200000327 Cct7 NM_007638 AB022160 T-COMPLEX PROTEIN 1, ETA SUBUNIT (TCP-
1-ETA) (CCT-ETA).
M200003578 Bpnt1 NM_011794 AF125043 BISPHOSPHATE 3′-NUCLEOTIDASE 1.
M200002251 Akr1b8 NM_008012 U04204 ALDOSE REDUCTASE-RELATED PROTEIN 1
(EC 1.1.1.21) (AR) (ALDEHYDE REDUCTASE)
(VAS DEFERENS ANDROGEN-DEPENDENT
PROTEIN) (MVDP) (ALDO-KETO REDUCTASE
FAMILY 1 MEMBER B7).
M200012683 Acat2 — BC012496 T-COMPLEX PROTEIN (TCP-1X) (FRAGMENT).
M300002824 Hnrpk NM_025279 BC006694 HETEROGENEOUS NUCLEAR
RIBONUCLEOPROTEIN K (HNRNP K) (65 KDA
PHOSPHOPROTEIN).
M200007603 0610009O03 NM_026660 AK089055 —
Rik
M200006373 Nars — AK013880 —
M200002442 Cdk4 NM_009870 X65069 CELL DIVISION PROTEIN KINASE 4 (EC 2.7.1.-)
(CYCLIN-DEPENDENT KINASE 4) (PSK-J3)
(CRK3).
M200006712 Shmt2 NM_028230 BC004825 —
M200002501 Lrp1 NM_008512 AF367720 LOW DENSITY LIPOPROTEIN RECEPTOR-
RELATED PROTEIN 1; LOW DENSITY
LIPOPROTEIN RECEPTOR RELATED
PROTEIN; LOW DENSITY LIPOPROTEIN
RECEPTOR RELATED PROTEIN 1.
M200006860 — NM_010312 U38505 GUANINE NUCLEOTIDE-BINDING PROTEIN
G(I)/G(S)/G(T) BETA SUBUNIT 2 (TRANSDUCIN
BETA CHAIN 2) (G PROTEIN BETA 2 SUBUNIT).
M300004485 P4hb — J05185 PROTEIN DISULFIDE ISOMERASE
PRECURSOR (PDI) (EC 5.3.4.1) (PROLYL 4-
HYDROXYLASE BETA SUBUNIT) (CELLULAR
THYROID HORMONE BINDING PROTEIN) (P55)
(ERP59).
M200012927 Angptl2 NM_011923 AF125176 ANGIOPOIETIN-RELATED PROTEIN 2
PRECURSOR (ANGIOPOIETIN-LIKE 2).
M300011172 — — — —
M200002468 Alad NM_008525 X13752 DELTA-AMINOLEVULINIC ACID
DEHYDRATASE (EC 4.2.1.24)
(PORPHOBILINOGEN SYNTHASE) (ALADH).
M300004916 Col3a1 — X57983 COLLAGEN ALPHA 1(III) CHAIN PRECURSOR.
M200000033 Idb3 NM_008321 M60523 DNA-BINDING PROTEIN INHIBITOR ID-3 (ID-
LIKE PROTEIN INHIBITOR HLH 462).
M200003353 Anxa1 NM_010730 M24554 ANNEXIN I (LIPOCORTIN I) (CALPACTIN II)
(CHROMOBINDIN 9) (P35) (PHOSPHOLIPASE
A2 INHIBITORY PROTEIN).
M200014015 Lgals1 NM_008495 AK004298 GALECTIN-1 (BETA-GALACTOSIDE-BINDING
LECTIN L-14-I) (LACTOSE-BINDING LECTIN 1)
(S-LAC LECTIN 1) (GALAPTIN) (14 KDA
LECTIN).
M200000992 Bgn NM_007542 Y11758 BIGLYCAN PRECURSOR (BONE/CARTILAGE
PROTEOGLYCAN I) (PG-S1).
M200003310 AU044919 — BC010327 IG GAMMA-2B CHAIN C REGION, MEMBRANE-
BOUND FORM.
Female C57Bl6 24 hr 1000 cGy
M300000233 Capns1 NM_009795 BC018352 CALCIUM-DEPENDENT PROTEASE. SMALL
SUBUNIT (CALPAIN REGULATORY SUBUNIT)
(CALCIUM-ACTIVATED NEUTRAL
PROTEINASE) (CANP).
M300001059 D0H8S2298E — BC024492 REPRODUCTION 8 (DNA SEGMENT, HUMAN
S2298E).
M300013845 Atpaf2 NM_145427 BC013607 ATP SYNTHASE MITOCHONDRIAL F1
COMPLEX ASSEMBLY FACTOR 2.
M300004022 Ermelin- NM_139143 AB071697 ENDOPLASMIC RETICULUM MEMBRANE
pending PROTEIN; EXPRESSED SEQUENCE AI853222.
M200004159 Nono NM_023144 AK013444 NON-POU-DOMAIN-CONTAINING, OCTAMER
BINDING PROTEIN; NON-POU-DOMAIN-
CONTAINING, OCTAMER-BINDING PROTEIN.
M200003982 Golga5 NM_013747 AF026274 GOLGI AUTOANTIGEN, GOLGIN SUBFAMILY A, 5.
M200000385 Slc1a7 NM_009201 D85044 NEUTRAL AMINO ACID TRANSPORTER B
(INSULIN-ACTIVATED AMINO ACID
TRANSPORTER) (ASC-LIKE NA(+)
DEPENDENT NEUTRAL AMINO ACID
TRANSPORTER ASCT2).
M300006374 Psmc2 — BC005462 26S PROTEASE REGULATORY SUBUNIT 7
(MSS1 PROTEIN).
M200004383 Cse1l NM_023565 AF301152 IMPORTIN-ALPHA RE-EXPORTER
(CHROMOSOME SEGREGATION 1-LIKE
PROTEIN) (CELLULAR APOPTOSIS
SUSCEPTIBILITY PROTEIN).
M200005955 1810019E15 — AK007546 —
Rik
M200005912 Narg1 NM_053089 BC030167 NMDA RECEPTOR-REGULATED GENE 1; N-
TERMINAL ACEYLTRANSFERASE 1.
M200001798 Lbr NM_133815 BC042522 LAMIN B RECEPTOR; ICHTHYOSIS.
M200015331 AV278559 NM_134152 AB071194 —
M300022323 — — — —
M300021610 — — — —
M300017722 — NM_024266 X62482 40S RIBOSOMAL PROTEIN S25.
M200003662 Hprt NM_013556 K01514 HYPOXANTHINE-GUANINE
PHOSPHORIBOSYLTRANSFERASE (EC
2.4.2.8) (HGPRT) (HGPRTASE) (HPRT B).
M300004429 Blnk NM_008528 AJ222814 B-CELL LINKER; LYMPHOCYTE ANTIGEN 57.
M300018162 — — — —
M300013112 — — J00595 IG LAMBDA-2 CHAIN C REGION.
M300011693 — — — —
M300000425 Rps11 NM_013725 AK005147 40S RIBOSOMAL PROTEIN S11.
M300017758 — NM_027015 — RIBOSOMAL PROTEIN S27.
M300004265 Ms4a1 NM_007641 AK017903 B-CELL SURFACE PROTEIN CD20 HOMOLOG
(B-CELL DIFFERENTIATION ANTIGEN LY-44).
M300020997 — — — —
Female C57Bl6 day 7 50 cGy
M300007861 Gypa NM_010369 M73815 GLYCOPHORIN.
M200006628 W64236 NM_144805 BC019416 —
M300005566 Capn3 NM_007601 AF091998 CALPAIN 3 LARGE SUBUNIT (EC 3.4.22.17)
(CALPAIN L3) (CALPAIN P94, LARGE
SUBUNIT) (CALCIUM-ACTIVATED NEUTRAL
PROTEINASE 3) (CANP 3) (MUSCLE-SPECIFIC
CALCIUM-ACTIVATED NEUTRAL PROTEASE 3
LARGE SUBUNIT).
M200001376 Gp5 NM_008148 Z69595 PLATELET GLYCOPROTEIN V PRECURSOR
(GPV) (CD42D).
M200005863 Nup210 NM_018815 AF113751 NUCLEOPORIN 210; NUCLEAR PORE
MEMBRANE GLYCOPROTEIN 210; NUCLEAR
PORE MEMBRANE PROTEIN 210.
M200007831 4933407D05 NM_029748 AK016715 —
Rik
M200001259 Cnih NM_009919 AF022811 CORNICHON HOMOLOG.
M200000413 Hdgf NM_008231 BC021654 HEPATOMA-DERIVED GROWTH FACTOR
(HDGF).
M200003736 Prdx4 NM_016764 U96746 PEROXIREDOXIN 4 (EC 1.11.1.-) (PRX-IV)
(THIOREDOXIN PEROXIDASE AO372)
(THIOREDOXIN-DEPENDENT PEROXIDE
REDUCTASE A0372) (ANTIOXIDANT ENZYME
AOE372).
M300003493 — — BC028899 PEPTIDYL-PROLYL CIS-TRANS ISOMERASE
LIKE 2 (EC 5.2.1.8) (PPIASE) (ROTAMASE)
(CYCLOPHILIN-60) (CYCLOPHILIN-LIKE
PROTEIN CYP-60).
M300020830 — — — —
M200004428 0610016L08 NM_029787 BC032013 DIAPHORASE 1 (NADH).
Rik
M200006257 2610312E17 NM_027432 AK050391 —
Rik
M200009010 AI840044 NM_144895 BC022921 —
M300001264 1810036I24R NM_026210 AK077277 —
ik
M300013796 Shc1 NM_011368 U15784 SHC TRANSFORMING PROTEIN.
M300021114 9130413I22R NM_026242 AB041651 —
ik
M300018312 — — — —
M300003187 — — — —
M300001659 Kpna2 NM_010655 BC006720 IMPORTIN ALPHA-2 SUBUNIT (KARYOPHERIN
ALPHA-2 SUBUNIT) (SRP1-ALPHA) (RAG
COHORT PROTEIN 1) (PENDULIN) (PORE
TARGETING COMPLEX 58 KDA SUBUNIT)
(PTAC58) (IMPORTIN ALPHA P1).
M300011584 — — — —
M300018684 Kpna2 NM_010655 BC006720 IMPORTIN ALPHA-2 SUBUNIT (KARYOPHERIN
ALPHA-2 SUBUNIT) (SRP1-ALPHA) (RAG
COHORT PROTEIN 1) (PENDULIN) (PORE
TARGETING COMPLEX 58 KDA SUBUNIT)
(PTAC58) (IMPORTIN ALPHA P1).
M300005759 Ube2v1 — BC019372 SIMILAR TO UBIQUITIN-CONJUGATING
ENZYME E2 VARIANT 1 (EC 6.3.2.19)
(UBIQUITIN-PROTEIN LIGASE) (UBIQUITIN
CARRIER PROTEIN).
M200014015 Lgals1 NM_008495 AK004298 GALECTIN-1 (BETA-GALACTOSIDE-BINDING
LECTIN L-14-I) (LACTOSE-BINDING LECTIN 1)
(S-LAC LECTIN 1) (GALAPTIN) (14 KDA
LECTIN).
M200000746 Calr NM_007591 M92988 CALRETICULIN PRECURSOR (CRP55)
(CALREGULIN) (HACBP) (ERP60).
Female C57Bl6 day 7 200 Gy
M200004758 Blvrb NM_144923 BC027279 BILIVERDIN REDUCTASE B (FLAVIN
REDUCTASE (NADPH)).
M300003852 Treml1- — AK017256 —
pending
M300007590 — NM_172479 — —
M300005240 Mgst3 NM_025569 BC029669 MICROSOMAL GLUTATHIONE S-
TRANSFERASE 3.
M200000621 Gpc4 NM_008150 X83577 GLYPICAN-4 PRECURSOR (K-GLYPICAN).
M300006292 1810017F10 NM_025452 AK008935 BETA-CASEIN-LIKE.
Rik
M300004473 4833406P10 — AF404774 ACTIN-BINDING LIM PROTEIN 1 MEDIUM
Rik ISOFORM.
M300005665 2010011I20R NM_025912 BC016210 —
ik
M200015276 Pep4 NM_008820 D82983 XAA-PRO DIPEPTIDASE (EC 3.4.13.9) (X-PRO
DIPEPTIDASE) (PROLINE DIPEPTIDASE)
(PROLIDASE) (IMIDODIPEPTIDASE)
(PEPTIDASE 4).
M300000073 Myf5 NM_008656 X56182 MYOGENIC FACTOR MYF-5.
M300002998 Nisch NM_022656 AF315344 NISCHARIN; IMIDAZOLINE RECEPTOR I-1-LIKE
PROTEIN.
M300008241 1110005A05 NM_025372 AK003451 —
Rik
M300002598 — — AF206023 ANTI-MYOSIN IMMUNOGLOBULIN HEAVY
CHAIN VARIABLE REGION (FRAGMENT).
M200004350 — — BC024401 SIMILAR TO DC12 PROTEIN.
M300007147 — — — —
M200009417 Mt2 — K02236 METALLOTHIONEIN-II (MT-II).
M300022215 — — — —
M200014231 Supt16h NM_033618 AF323667 SUPPRESSOR OF TY 16 HOMOLOG;
SUPPRESSOR OF TY 16 HOMOLOG
(S. CEREVISIAE).
M300016699 — — AK011630 —
M300015461 — — — —
M300006903 — NM_007624 — CHROMOBOX HOMOLOG 3 (DROSOPHILA
HP1 GAMMA); HETEROCHROMATIN PROTEIN
1 GAMMA.
M300002502 Pnn NM_008891 Y08701 PININ; DNA SEGMENT, CHR 12, ERATO DOI
512, EXPRESSED.
M200000746 Calr NM_007591 M92988 CALRETICULIN PRECURSOR (CRP55)
(CALREGULIN) (HACBP) (ERP60).
M200009655 Cct6a NM_009838 AB022159 T-COMPLEX PROTEIN 1, ZETA SUBUNIT (TCP-
1-ZETA) (CCT-ZETA) (CCT-ZETA- 1).
M300011584 — — — —
Specificity of PB Signatures In addition to inter-individual variations (Whitney et al, Proc. Natl. Acad. Sci. USA 101:1896-1901 (2003)), human populations are heterogeneous with respect to health status and medical conditions. Therefore, it is critical to determine whether PB gene expression profiles of radiation response are specific to radiation exposure itself or whether these signatures are potentially confounded by other genotoxic stresses. The choice was made to compare the PB gene expression response to ionizing radiation exposure with that of gram-negative bacterial sepsis, since this syndrome can be expected to induce similar multiorgan toxicity as is observed following radiation injury (Wasalenko et al, Ann. Int. Med. 140:1037-1051 (2004), Mettler et al, N. Engl. J. Med. 346:1554-1561 (2002), Dainiak, Exp. Hematol. 30:513-528 (2002), Inoue et al, FASEB J. 20:533-535 (2006)). A pattern of gene expression could be identified which effectively distinguished female C57B16 mice treated with Escherichia coli-derived lipopolysaccharide (LPS), experiencing sepsis syndrome, from untreated female C57B16 mice (FIG. 5A). Applying a leave-one-out cross-validation analysis, it was found that the PB signature for 50 cGy irradiation in C57B16 mice correctly predicted the status of all LPS-treated C57B16 mice as non-irradiated, suggesting robust specificity of the signature for low level (50 cGy) irradiation and sepsis syndrome (FIG. 5B). The PB signatures for 200 cGy and 1000 cGy also correctly predicted the LPS-treated mice as non-irradiated, although these probabilities were less robust than the application of the 50 cGy signature (FIG. 5B). The PB signature of LPS-treatment also correctly predicted the status of all irradiated mice as “non-LPS treated” (FIG. 5B, right). These data indicate that the PB gene expression profiles of radiation response and bacterial sepsis are quite specific and able to distinguish one condition from the other with a high level of accuracy. No overlap was observed between the genes which comprised the PB signature of LPS-sepsis and the PB signatures of radiation exposure in C57Bl6 mice (Table 5).
TABLE 5
Genes that distinguish LPS treatment in C57Bl6 mice. Operon Oligo
ID can be queried in the OMAD database (http://omad.operon.com)
Operon Gene
Oligo ID Symbol RefSeq Genbank Description
M200003295 Saa3 NM_011315 M17792 SERUM AMYLOID A-3 PROTEIN PRECURSOR.
M300009870 Ccl12 NM_011331 AF065938 SMALL INDUCIBLE CYTOKINE A12 PRECURSOR
(CCL12) (MONOCYTE CHEMOTACTIC PROTEIN 5)
(MCP-5) (MCP-1 RELATED CHEMOKINE).
M300005418 Il1rn NM_031167 S64082 INTERLEUKIN-1 RECEPTOR ANTAGONIST PROTEIN
PRECURSOR (IL-1RA) (IL-1RN) (IRAP).
M200001838 Upp NM_009477 D44464 URIDINE PHOSPHORYLASE (EC 2.4.2.3) (UDRPASE).
M200000053 Fcgr1 NM_010186 BC025535 HIGH AFFINITY IMMUNOGLOBULIN GAMMA FC
RECEPTOR I PRECURSOR (FC-GAMMA RI) (FCRI)
(IGG FC RECEPTOR I).
M200004157 9130009C22 NM_027835 AF374384 —
Rik
M300005305 Lcn2 — X81627 NEUTROPHIL GELATINASE-ASSOCIATED LIPOCALIN
PRECURSOR (NGAL) (P25) (SV-40 INDUCED 24P3
PROTEIN) (LIPOCALIN 2).
M300006479 Bst1 NM_009763 D31788 ADP-RIBOSYL CYCLASE 2 PRECURSOR (EC 3.2.2.5)
(CYCLIC ADP-RIBOSE HYDROLASE 2) (CADPR
HYDROLASE 2) (BONE MARROW STROMAL ANTIGEN
1) (BST- 1) (BP-3 ALLOANTIGEN) (ANTIGEN BP3).
M200004765 Gbp2 NM_010260 AF077007 GUANYLATE NUCLEOTIDE BINDING PROTEIN 2.
M300005673 Zbp1 NM_021394 BC020033 Z-DNA BINDING PROTEIN 1 (TUMOR STROMA AND
ACTIVATED MACROPHAGE PROTEIN DLM-1).
M300005674 Zbp1 NM_021394 BC020033 Z-DNA BINDING PROTEIN 1 (TUMOR STROMA AND
ACTIVATED MACROPHAGE PROTEIN DLM-1).
M300001891 Gp49b NM_013532 U05264 MAST CELL SURFACE GLYCOPROTEIN GP49B
PRECURSOR.
M300005166 Ifi204 NM_008329 M31419 INTERFERON-ACTIVATABLE PROTEIN 204 (IFI-204)
(INTERFERON-INDUCIBLE PROTEIN P204).
M200005576 Usp18 NM_011909 AF069502 UBL CARBOXYL-TERMINAL HYDROLASE 18 (EC 3.1.2.-)
(UBL THIOLESTERASE 18) (ISG15-SPECIFIC
PROCESSING PROTEASE) (43 KDA ISG15-SPECIFIC
PROTEASE).
M300020771 — — — —
M300011591 — NM_172893 BC024579 —
M200007439 Gtpi-pending NM_019440 AJ007972 INTERFERON-G INDUCED GTPASE.
M300012693 — — — —
M300012210 — — — —
M200014281 2010008K16R NM_027320 BC008158 INTERFERON-INDUCED 35 KDA PROTEIN HOMOLOG
ik (IFP 35).
M300009340 — NM_145481 BC021340 —
M200004564 Nte NM_015801 AF173829 NEUROPATHY TARGET ESTERASE; SWISS CHEESE.
M300000152 Araf NM_009703 D00024 A-RAF PROTO-ONCOGENE SERINE/THREONINE-
PROTEIN KINASE (EC 2.7.1.-).
M200006264 — NM_176831 — —
M300000077 D15Ertd417e NM_144811 BC021398 CHROMOBOX PROTEIN HOMOLOG 6.
PB Signatures of Radiation and Chemotherapy are Specific in Humans In order to extend the analysis of PB signature specificity to humans, PB was collected from a population of healthy individuals (n=18), patients who had undergone total body irradiation as conditioning prior to hematopoietic stem cell transplantation (n=47) and patients who had undergone alkylator-based chemotherapy conditioning alone (n=41). RNA of sufficient quality was available from 18 healthy donor samples, 36 pre-irradiated patients, 34 post-irradiated patients, 36 pre-chemotherapy treatment patients and 32 post-chemotherapy patients (Table 6). A supervised binary regression analysis identified a metagene profile of 25 genes that distinguished the healthy individuals and the non-irradiated patients from the irradiated patients (FIG. 6A). A leave-one-out cross validation analysis demonstrated that this PB predictor of human radiation response was 100% accurate in predicting the healthy individuals and the non-irradiated patients and 91% accurate at predicting the irradiated patients (FIG. 6A).
TABLE 6
Donor Patient Characteristics
Characteristic Number
Samples analyzed n = 18 healthy donors
n = 36 patients pre-radiotherapy
n = 34 patients post-radiotherapy
n = 36 patients pre-chemotherapy
n = 32 patients post-chemotherapy
Patient/Donor Age 47.9 years (mean)
Diagnoses MDS/AML (n = 23)
ALL (n = 8)
Multiple myeloma (n = 20)
Non-Hodgkin's Lymphoma (n = 20)
Hodgkin's Disease (n = 6)
Myeloproliferative disorder (n = 7)
Scleroderma (n = 3)
Sickle cell disease (n = 1)
Prior radiotherapy n = 15
Prior chemotherapy n = 82
Transplantation type Non-myeloablative allogeneic/200 cGy (n = 24)
Myeloablative allogeneic/1350 cGy (n = 15)
Myeloablative autologous/1200 cGy (n = 8)
Chemotherapy allogeneic (n = 19)
Chemotherapy autologous (n = 22)
Patients undergoing either TBI-based or chemotherapy-based conditioning followed by allogeneic or autologous stem cell transplantation were eligible for enrollment. PB samples were collected prior to and 6 hours following either 200 cGy total body irradiation (non-myeloablative conditioning) or the first fraction (150 cGy) of total body irradiation (myeloablative conditioning). MDS = myelodysplastic syndrome, AML = acute myelogenous leukemia, ALL = acute lymphocytic leukemia
In order to test the specificity of this PB signature of human radiation response, its accuracy was next tested in predicting the status of patients who had undergone chemotherapy treatment alone. This signature correctly predicted 89% of the non-irradiated, pre-chemotherapy patients as non-irradiated and 75% of the chemotherapy-treated patients as non-irradiated (FIG. 6A). Interestingly, 2 of the post-chemotherapy patients had a prior history of total lymphoid irradiation and both of these were mispredicted as “irradiated”, suggesting perhaps that a durable molecular response to radiation was evident in these patients. Considering the entire population, the overall accuracy of the PB predictor of radiation was 90%. Within the chemotherapy-treated patients, a PB signature could be identified that appeared to distinguish untreated patients from chemotherapy-treated patients (FIG. 6B). A leave-one-out cross-validation analysis demonstrated that this PB signature of chemotherapy treatment was 81% accurate at distinguishing the untreated patients and 78% accurate at predicting the chemotherapy-treated patients (FIG. 6B). Furthermore, the chemotherapy metagene profile demonstrated 100% accuracy in predicting the status of healthy individuals, 92% accuracy in predicting the non-irradiated patients, and 62% accuracy in predicting the PB samples from irradiated patients as not having received chemotherapy (FIG. 6B). The overall accuracy of the PB predictor of chemotherapy-treatment was 81%. Interestingly, no overlapping genes were identified between the PB signature of radiation and the PB signature of chemotherapy treatment (Tables 7 and 8). It is also worth noting that all 12 of the post-irradiation patients whose status was mispredicted by the PB chemotherapy signature had received prior chemotherapy in the treatment of their underlying disease.
TABLE 7
Genes that distinguish radiation status in humans. Operon Oligo
ID can be queried in the OMAD database (http://omad.operon.com)
Operon Gene
Oligo_ID Symbol RefSeq Genbank Description
H200000088 XPC NM_004628 X65024 DNA-REPAIR PROTEIN COMPLEMENTING
XP-C CELLS (XERODERMA PIGMENTOSUM
GROUP C COMPLEMENTING PROTEIN)
(P125)
H200001266 — NM_017792 AK000380 —
H200002100 — NM_024556 BC001340 —
H200002529 — NM_032324 AF416713 —
H200004865 — NM_006828 AL834463 DJ467N11.1 PROTEIN
H200006009 GTF3A NM_002097 U14134 TRANSCRIPTION FACTOR IIIA (FACTOR A)
(TFIIIA)
H200006598 PCNA NM_002592 BC000491 PROLIFERATING CELL NUCLEAR ANTIGEN
(PCNA) (CYCLIN)
H200008365 CDKN1A NM_000389 BC013967 CYCLIN-DEPENDENT KINASE INHIBITOR 1
(P21) (CDK-INTERACTING PROTEIN 1)
(MELANOMA DIFFERENTIATION
ASSOCIATED PROTEIN 6) (MDA-6)
H200011100 PPM1D NM_003620 BC033893 PROTEIN PHOSPHATASE 2C DELTA
ISOFORM (PP2C-DELTA) (P53- INDUCED
PROTEIN PHOSPHATASE 1) (PROTEIN
PHOSPHATASE MAGNESIUM- DEPENDENT 1
DELTA)
H200011577 — NM_018247 AK001718 —
H200014322 — — BC009552 CGI-203
H200014719 ACTA2 NM_001613 X60732 ACTIN, AORTIC SMOOTH MUSCLE (ALPHA-
ACTIN 2)
H200016323 — NM_152240 BC002896 P53 TARGET ZINC FINGER PROTEIN
ISOFORM 1; ZINC FINGER PROTEIN WIG1;
WIG-1/PAG608 PROTEIN
H200017549 TIMM8B NM_012459 BC000711 MITOCHONDRIAL IMPORT INNER
MEMBRANE TRANSLOCASE SUBUNIT TIM8 B
(DEAFNESS DYSTONIA PROTEIN 2) (DDP-
LIKE PROTEIN)
H300000421 — NM_016399 BC002638 PROTEIN 15E1.1 (PROTEIN HSPC132)
H300003103 — — — —
H300003151 MOAP1 NM_022151 BC015044 MODULATOR OF APOPTOSIS 1; MAP-1
PROTEIN; PARANEOPLASTIC ANTIGEN
LIKE 4
H300010830 — NM_022767 BC005164 —
H300015667 — NM_022767 BC005164 —
H300018970 — NM_014454 AK001886 SESTRIN 1 (P53-REGULATED PROTEIN PA26)
H300019371 DDB2 NM_000107 BC000093 DNA DAMAGE BINDING PROTEIN 2
(DAMAGE-SPECIFIC DNA BINDING PROTEIN
2) (DDB P48 SUBUNIT) (DDBB) (UV-DAMAGED
DNA-BINDING PROTEIN 2) (UV-DDB 2)
H300020184 C19orf2 NM_003796 AB006572 RNA POLYMERASE II SUBUNIT 5-MEDIATING
PROTEIN (RPB5-MEDIATING PROTEIN)
H300020858 HNRPDL NM_005463 BC011714 HETEROGENEOUS NUCLEAR
RIBONUCLEOPROTEIN D-LIKE; A + U-RICH
ELEMENT RNA BINDING FACTOR
H300021118 BBC3 NM_014417 AF354655 BCL2 BINDING COMPONENT 3; BCL-2
BINDING COMPONENT 3; PUMA/JFY1
PROTEIN; BCL-2 BINDING COMPONENT 3
H300022025 BAX NM_138763 U19599 BAX PROTEIN, CYTOPLASMIC ISOFORM
DELTA
TABLE 8
Genes that distinguish chemotherapy treatment in humans. Operon Oligo
ID can be queried in the OMAD database (http://omad.operon.com)
Operon Gene
oligo_ID Symbol RefSeq Genbank Description
H200001454 FKBP5 NM_004117 U42031 FK506-BINDING PROTEIN 5 (EC 5.2.1.8) (PEPTIDYL-
PROLYL CIS-TRANS ISOMERASE) (PPIASE)
(ROTAMASE) (51 KDA FK506-BINDING PROTEIN)
(FKBP- 51) (54 KDA PROGESTERONE RECEPTOR-
ASSOCIATED IMMUNOPHILIN) (FKBP54) (P54) (FF1
ANTIGEN) (HSP90-BINDING IMMUNOPHILIN)
H200002954 SAP30 NM_003864 BC016757 SIN3 ASSOCIATED POLYPEPTIDE P30; SIN3-
ASSOCIATED POLYPEPTIDE, 30 KD
H200004993 SOCS1 NM_003745 AB000676 SUPPRESSOR OF CYTOKINE SIGNALING 1 (SOCS-1)
(JAK-BINDING PROTEIN) (JAB) (STAT INDUCED STAT
INHIBITOR 1) (SSI-1) (TEC-INTERACTING PROTEIN 3)
(TIP-3)
H200002479 CRAMP1L — AB037847 —
H200020334 — NM_006372 AY034482 NS1-ASSOCIATED PROTEIN 1
H200002535 — NM_018034 BC025315 —
H200002231 UVRAG NM_003369 AB012958 UV RADIATION RESISTANCE-ASSOCIATED GENE
PROTEIN (P63)
H200002230 — NM_005475 AJ012793 LYMPHOCYTE SPECIFIC ADAPTER PROTEIN LNK
(SIGNAL TRANSDUCTION PROTEIN LNK)
(LYMPHOCYTE ADAPTER PROTEIN)
H300001588 ASGR1 NM_001671 AB070933 ASIALOGLYCOPROTEIN RECEPTOR 1 (HEPATIC
LECTIN H1) (ASGPR) (ASGP-R)
H300001821 BLVRA NM_000712 AC005189 BILIVERDIN REDUCTASE A PRECURSOR (EC 1.3.1.24)
(BILIVERDIN-IX ALPHA- REDUCTASE)
H200001397 RAI17 — AB033050 —
H300008401 TRAF3 NM_003300 U15637 TNF RECEPTOR ASSOCIATED FACTOR 3 (CD40
RECEPTOR ASSOCIATED FACTOR 1) (CRAF1) (CD40
BINDING PROTEIN) (CD40BP) (LMP1 ASSOCIATED
PROTEIN) (LAP1) (CAP-1)
H300022877 LILRB1 NM_006669 AF009221 LEUKOCYTE IMMUNOGLOBULIN-LIKE RECEPTOR,
SUBFAMILY B (WITH TM AND ITIM DOMAINS),
MEMBER 1; LEUKOCYTE IMMUNOGLOBULIN-LIKE
RECEPTOR 1; CD85 ANTIGEN
H300018428 BID NM_001196 BC022072 BH3 INTERACTING DOMAIN DEATH AGONIST (BID)
H300022441 — — AL360143 —
H200014949 HMOX1 NM_002133 X14782 HEME OXYGENASE 1 (EC 1.14.99.3) (HO-1)
H200006902 TIEG NM_005655 AF050110 TRANSFORMING GROWTH FACTOR-BETA-INDUCIBLE
EARLY GROWTH RESPONSE PROTEIN 1 (TGFB-
INDUCIBLE EARLY GROWTH RESPONSE PROTEIN 1)
(TIEG-1) (KRUEPPEL-LIKE FACTOR 10)
H200001600 NOTCH2 NM_024408 U77493 NEUROGENIC LOCUS NOTCH HOMOLOG PROTEIN 2
PRECURSOR (NOTCH 2) (HN2)
H300007970 ZFP36L1 NM_004926 BC018340 BUTYRATE RESPONSE FACTOR 1 (TIS11B PROTEIN)
(EGF-RESPONSE FACTOR 1) (ERF-1)
H300019724 IFI30 NM_006332 AF097362 GAMMA-INTERFERON INDUCIBLE LYSOSOMAL THIOL
REDUCTASE PRECURSOR (GAMMA-INTERFERON-
INDUCIBLE PROTEIN IP-30)
H200004653 — — AB033073 —
H300012785 WARS NM_004184 X67928 TRYPTOPHANYL-TRNA SYNTHETASE (EC 6.1.1.2)
(TRYPTOPHAN-TRNA LIGASE) (TRPRS) (IFP53)
(HWRS)
H200010704 CPVL NM_031311 BC016838 SERINE CARBOXYPEPTIDASE VITELLOGENIC-LIKE
H200017278 SCO2 NM_005138 AL021683 SCO2 PROTEIN HOMOLOG, MITOCHONDRIAL
PRECURSOR
H200005078 — NM_006344 D50532 MACROPHAGE LECTIN 2 (CALCIUM DEPENDENT)
Summarizing, numerous studies now highlight the power of gene expression profiling to characterize the biological phenotype of complex diseases. The potential clinical utility of gene expression profiles has been shown in cancer research, in which the identification of patterns of gene expression within tumors has led to the characterization of tumor subtypes, prognostic categories and prediction of therapeutic response (Potti et al, N. Engl. J. Med. 355:570-580 (2006), Cheng et al, J. Clin. Oncol. 24:4594-4602 (2006), Potti et al, Nat. Med. 12:1294-1300 (2006), Nevins et al, Nat. Rev. Genet. 8:601-609 (2007), Alizadeh et al, Nature 403:503-511 (2000)). Beyond analysis of tumor tissues, it has also been suggested that gene expression profiling of the peripheral blood can provide indication of infections, cancer, heart disease, allograft rejection, environmental exposures and as a means of biological threat detection (Mandel et al, Lupus 15:451-456 (2006), Heller et al, Proc. Natl. Acad. Sci. USA 94:2150-2155 (1997), Edwards et al, Mol. Med. 13:40-58 (2007), Baird, Stroke 38:694-698 (2007), Rubins et al, Proc. Natl. Acad. Sci. USA 101:15190-15195 (2004), Martin et al, Proc. Natl. Acad. Sci. USA 98:2646-2651 (2001), Patino et al, Proc. Natl. Acad. Sci. USA 102:3423-3428 (2005), Lampe et al, Cancer Epidemiol. Biomarkers Prev. 13:445-453 (2004), Ramilo et al, Blood 109:2066-2077 (2007), Horwitz et al, Circulation 110:3815-3821 (2004), Lin et al, Clinic Chem. 49:1045-1049 (2003)). While the concept of PB cells as sentinels of disease is not new, it remains unclear whether PB gene expression profiles that have been associated with various conditions are specific for those diseases or rather reflect a common molecular response to a variety of genotoxic stresses. Given the dynamic nature of the cellular composition of PB blood (Whitney et al, Proc. Natl. Acad. Sci. USA 101:1896-1901 (2003)) and the complexity of cellular responses over time (Whitney et al, Proc. Natl. Acad. Sci. USA 101:1896-1901 (2003)), the durability of PB signatures over time is also uncertain and could affect the diagnostic utility of this approach for public health screening.
A purpose of the studies described above was to address the capacity for PB gene expression profiles to distinguish an environmental exposure, in this case ionizing radiation, versus other medical conditions and to examine the impact of time, gender and genotype on the accuracy of these profiles. It was found that PB gene expression signatures can be identified which accurately predict irradiated from non-irradiated mice and distinguish different levels of radiation exposure, all within a heterogeneous population with respect to gender, genotype and time from exposure. These results suggest the potential for PB gene expression profiling to be applied successfully in the screening for an environmental exposure. Previous studies have indicated that inter-individual variation in gene expression occurs within healthy individuals (Whitney et al, Proc. Natl. Acad. Sci. USA 101:1896-1901 (2003)) and may therefore limit the accuracy of PB gene expression profiling to detect diseases or exposures. The results provided here demonstrate that the environmental exposure tested here, ionizing radiation, induced a pronounced and characteristic alteration in PB gene expression such that a PB expression profile was highly predictive of radiation status in a population with variable gender, genotype and time of analysis. From a practical standpoint, these data suggest the potential utility of this approach for biodosimetric screening of a heterogeneous human population in the event of a purposeful or accidental radiological or nuclear event (Wasalenko et al, Ann. Int. Med. 140:1037-1051 (2004), Mettler et al, N. Engl. J. Med. 346:1554-1561 (2002), Dainiak, Exp. Hematol. 30:513-528 (2002)).
This study revealed that sex differences can impact the accuracy of this approach, particularly in distinguishing mice exposed to lower dose irradiation from non-irradiated controls. These results imply that aspects of the PB response to ionizing radiation are specified by sex-associated genes. Whitney et al (Proc. Natl. Acad. Sci. USA 101:1896-1901 (2003)) previously showed that sex differences were associated with variation in PB autosomal gene expression in healthy individuals. The instant study suggests that sex differences may contribute to characteristically distinct PB molecular responses to environmental stress (radiation) and the accuracy of PB gene expression profiling for medical screening can be affected by sex. These sex-related differences in PB response to ionizing radiation are perhaps illustrated by the fact that only 2 genes overlapped between the male and female PB signatures of 50 cGy (Ccng1 and Dda3).
Interestingly, differences in genotype did not significantly impact the accuracy of the PB gene expression signatures to distinguish radiation response such that PB signatures from C57Bl6 mice displayed 100% accuracy in predicting the status of BALB/c mice and vice versa. This observation demonstrates that, while genotype differences can account for some variation in PB gene expression (Whitney et al, Proc. Natl. Acad. Sci. USA 101:1896-1901 (2003)), the alterations in PB gene expression induced by 3 different levels of radiation exposure are such that PB expression profiling is highly accurate in distinguishing all irradiated mice across different genotypes. Very few genes were found in common between the 2 strains of mice at each level of radiation exposure, indicating that diverse sets of genes contribute to the PB response to radiation and that unique sets of genes can be identified which are predictive of radiation response.
The time of PB collection following radiation exposure had no significant impact on the accuracy of PB signatures to predict radiation status or distinguish different levels of exposure. First, the accuracy of PB signatures to predict radiation status and distinguish different levels of radiation exposure did not decay over time. Second, when we applied a PB signature from a single time point (6 hrs) against PB samples collected from mice at other time points (24 hr and 7 days), the accuracy of the prediction remained 100% in all cases. Therefore, time as a single variable did not lessen the accuracy of this approach to distinguish irradiated from non-irradiated animals. However, the content of the genes which comprised the PB signatures changed significantly as a function of time and <20% of the genes overlapped between the PB signatures of radiation at 6 hr, 24 hr, and 7 days. Taken together, these data indicate that PB predictors of radiation response do change over time, but PB signatures can continuously be identified through 7 days that are highly accurate at predicting radiation status and distinguishing different levels of radiation exposure. From a practical perspective, these results suggest that the application of a single reference set of “radiation response” genes would be unlikely to provide the most sensitive screen for radiation exposure over time. Conversely, reference lists of PB genes that are specific for different time points could be applied in the screening for radiation exposure provided that the time of exposure was known.
A critical question to be addressed in the development of PB gene expression profiling to detect medical conditions or exposures is the specificity of PB gene expression changes in response to genotoxic stresses. The PB signatures of 3 different doses of radiation displayed 100% accuracy in identifying septic animals as non-irradiated and the PB signature of sepsis was also 100% accurate in identifying irradiated mice as non-septic. These results demonstrate specificity in the PB responses to ionizing radiation and sepsis. These data also provide in vivo validation of a prior report by Boldrick et al (Proc. Natl. Acad. Sci. USA 99:972-977 (2002)) in which human PB mononuclear cells were found to have a stereotypic response to LPS exposure in vitro and specific alterations in gene expression were observed in response to different strains of bacteria (Boldrick et al, Proc. Natl. Acad. Sci. USA 99:972-977 (2002)). Ramilo et al. also recently reported that distinct patterns of PB gene expression can be identified among patients with different bacterial infections (Ramilo et al, Blood 109:2066-2077 (2007)). No genes were found to be in common between the PB signatures of radiation exposure and the PB signature of gram negative sepsis. Taken together, the results demonstrate that the in vivo PB molecular responses to ionizing radiation and bacterial sepsis are quite distinct and can be utilized to distinguish one condition from the other with a high level of accuracy.
The analyses of expression signatures in human patients demonstrated that it is possible to utilize PB gene expression profiles to distinguish individuals who have been exposed to an environmental hazard, ionizing radiation, within a heterogeneous human population with a high level of accuracy. It will be important to further test the accuracy of this PB predictor of human radiation exposure in a human population exposed to lower dose irradiation (e.g. 0.1-1 cGy), as might be expected via occupational exposures (e.g. radiology technicians, nuclear power plant workers) (Seierstad et al, Radiat. Prot. Dosimetry 123:246-249 (2007), Moore et al, Radiat. Res. 148:463-475 (1997), Einstein et al, Circulation 116:1290-1305 (2007)). A potential pitfall in the clinical application of PB gene expression profiling would be that variations in PB gene expression in people would be such that it might be difficult to distinguish the effects of a given exposure or medical condition from expected background alterations in gene expression (Whitney et al, Proc. Natl. Acad. Sci. USA 101:1896-1901 (2003)). However, Whitney et al (Proc. Natl. Acad. Sci. USA 101:1896-1901 (2003)) showed that the alterations in PB gene expression observed in patients with lymphoma or bacterial infection was significantly greater than the relatively narrow variation observed in healthy individuals (Whitney et al, Proc. Natl. Acad. Sci. USA 101:1896-1901 (2003)). This study confirms that PB gene expression profiles can be successfully applied to detect a specific exposure in a heterogeneous human population and that inter-individual differences in PB gene expression do not significantly confound the utility of this approach.
It was also shown that unique PB gene expression profiles can be identified which distinguish chemotherapy-treated patients versus patients who had not received chemotherapy with an overall accuracy of 81% and 78%, respectively. Similar to the PB signature of radiation, the PB signature of chemotherapy demonstrated accuracy and specificity in distinguishing healthy individuals and pre-irradiated patients (100% and 92% accuracy, respectively). However, the accuracy of the PB signature of chemotherapy was more limited when tested against patients who received radiation conditioning (62%). This observation provides the basis for further investigation as to which families of genes may be represented in both the PB molecular response to radiation and chemotherapy. However, since all 12 of the post-irradiation patients whose status was mispredicted by the PB chemotherapy signature had received combination chemotherapy within the prior year, the true specificity of this PB signature of chemotherapy cannot be addressed via this comparison. Additional patients are currently being enrolled to this study who have not undergone prior chemotherapy to further test the specificity of a PB metagene of chemotherapy treatment.
Peripheral blood is a readily accessible source of tissue which has the potential to provide a window to the presence of disease or exposures. Early studies applying PB gene expression analysis have demonstrated that this approach is sensitive for the detection of patterns of gene expression in association with a variety of medical conditions (Mandel et al, Lupus 15:451-456 (2006), Heller et al, Proc. Natl. Acad. Sci. USA 94:2150-2155 (1997), Edwards et al, Mol. Med. 13:40-58 (2007), Baird, Stroke 38:694-698 (2007), Rubins et al, Proc. Natl. Acad. Sci. USA 101:15190-15195 (2004), Martin et al, Proc. Natl. Acad. Sci. USA 98:2646-2651 (2001), Patino et al, Proc. Natl. Acad. Sci. USA 102:3423-3428 (2005), Lampe et al, Cancer Epidemiol. Biomarkers Prev. 13:445-453 (2004), Ramilo et al, Blood 109:2066-2077 (2007), Whitney et al, Proc. Natl. Acad. Sci. USA 101:1896-1901 (2003), Dressman et al, PLoS Med. 4:690-701 (2007)). It remains to be determined whether PB gene expression profiles can be successfully applied in medical practice or public health screening for the early detection of specific diseases or environmental exposures. The present results demonstrate that PB gene expression profiles can be identified in mice and humans which are specific, accurate over time, and not confounded by inter-individual differences.
All documents and other information sources cited above are hereby incorporated in their entirety by reference.