Abstract: Acute myeloid leukemia (AML) has not benefited from innovative immunotherapies, mainly because of the lack of actionable immune targets. Novel tumor-specific antigens (TSAs) shared by a large proportion of AML cells are described herein. Most of the TSAs described herein derives from aberrantly expressed unmutated genomic sequences, such as intronic and intergenic sequences, which are not expressed in normal tissues. Nucleic acids, compositions, cells and vaccines derived from these TSAs are described. The use of the TSAs, nucleic acids, compositions, cells and vaccines for the treatment of leukemia such as AML is also described.

Abstract: T cells, notably CD8 T cells, are known to be essential players in tumor eradication as the presence of tumor-infiltrating lymphocytes (TILs) in several cancers positively correlates with a good prognosis. To eliminate tumor cells, CD8 T cells recognize tumor antigens, which are MHC I-associated peptides present at the surface of tumor cells, with no or very low expression on normal cells. Described herein a proteogenomic approach using RNA-sequencing data from cancer and normal-matched mTEChi samples in order to identify non-tolerogenic tumor-specific antigens derived from (i) coding and non-coding regions of the genome, (ii) non-synonymous single-base mutations or short insertion/deletions and more complex rearrangements as well as (iii) endogenous retroelements, which works regardless of the sample's mutational load or complexity.

Abstract: T cells, notably CD8 T cells, are known to be essential players in tumor eradication as the presence of tumor-infiltrating lymphocytes (TILS) in several cancers positively correlates with a good prognosis. To eliminate tumor cells, CD8 T cells recognize tumor antigens, which are MHC I-associated peptides present at the surface of tumor cells, with no or very low expression on normal cells. Described herein a proteogenomic approach using RNA-sequencing data from cancer and normal-matched mTEChi samples in order to identify non-tolerogenic tumor-specific antigens derived from (i) coding and non-coding regions of the genome, (ii) non-synonymous single-base mutations or short insertion/deletions and more complex rearrangements as well as (iii) endogenous retroelements, which works regardless of the sample's mutational load or complexity.

Abstract: Acute lymphoblastic leukemia (ALL) has not benefited from innovative immunotherapies, mainly because of the lack of actionable immune targets. Novel tumor-specific antigens (TSAs) specifically expressed by ALL cells are described herein. Most of the TSAs described herein derives from aberrantly expressed unmutated genomic sequences, such as intronic and intergenic sequences, which are not expressed in normal tissues. Nucleic acids, compositions, cells, antibodies and vaccines derived from these TSAs are described. The use of the TSAs, nucleic acids, compositions, antibodies, cells and vaccines for the treatment of leukemia such as ALL is also described.

Abstract: T cells, notably CD8 T cells, are known to be essential players in tumor eradication as the presence of tumor-infiltrating lymphocytes (TILS) in several cancers positively correlates with a good prognosis. To eliminate tumor cells, CD8 T cells recognize tumor antigens, which are MHC I-associated peptides present at the surface of tumor cells, with no or very low expression on normal cells. Described herein a proteogenomic approach using RNA-sequencing data from cancer and normal-matched mTEChi samples in order to identify non-tolerogenic tumor-specific antigens derived from (i) coding and non-coding regions of the genome, (ii) non-synonymous single-base mutations or short insertion/deletions and more complex rearrangements as well as (iii) endogenous retroelements, which works regardless of the sample's mutational load or complexity.

Abstract: Minor histocompatibility antigens (MiHAs) binding to certain human leukocyte antigen (HLA) alleles are described. These MiHAs were selected based on two features: (i) they are encoded by loci with a minor allele frequency (MAF) of at least 0.05; and (ii) they have adequate tissue distribution. Compositions, nucleic acids and cells related to these MiHAs are also described. The present application also discloses the use of these MiHAs, and related compositions, nucleic acids and cells, in applications related to cancer immunotherapy, for example for the treatment of hematologic cancers such as leukemia.

Abstract: Novel minor histocompatibility antigens (MiHAs) are described. These novel MiHAs were selected based on two features: (i) they are encoded by loci with a minor allele frequency (MAF) of at least 0.05; and (ii) they have adequate tissue distribution. Compositions, nucleic acids and cells related to these novel MiHAs are also described. The present application also discloses the use of these novel MiHAs, and related compositions, nucleic acids and cells, in applications related to cancer immunotherapy, for example for the treatment of hematologic cancers such as leukemia.

Abstract: Novel minor histocompatibility antigens (MiHAs) are described. These novel MiHAs were selected based on two features: (i) they are encoded by loci with a minor allele frequency (MAF) of at least 0.05; and (ii) they have adequate tissue distribution. Compositions, nucleic acids and cells related to these novel MiHAs are also described. The present application also discloses the use of these novel MiHAs, and related compositions, nucleic acids and cells, in applications related to cancer immunotherapy, for example for the treatment of hematologic cancers such as leukemia.

Abstract: A novel method for human minor histocompatibility antigen (MiHA) discovery, novel MiHAs identified using this method, as well as uses of the novel MiHAs, are described. One of the features of the novel method is the inclusion of personalized translated transcriptome and/or exome in the database used for peptide identification by mass spectroscopy (MS). Candidate MiHAs are identified by comparing the personalized transcriptome and/or exome to a reference genome and/or to the transcriptome and/or exome of an HLA-matched subject.

Abstract: Novel minor histocompatibility antigens (MiHAs) are described. These novel MiHAs were selected based on two features: (i) they are encoded by loci with a minor allele frequency (MAF) of at least 0.05; and (ii) they have adequate tissue distribution. Compositions, nucleic acids and cells related to these novel MiHAs are also described. The present application also discloses the use of these novel MiHAs, and related compositions, nucleic acids and cells, in applications related to cancer immunotherapy, for example for the treatment of hematologic cancers such as leukemia.

Abstract: A novel method for human minor histocompatibility antigen (MiHA) discovery, novel MiHAs identified using this method, as well as uses of the novel MiHAs, are described. One of the features of the novel method is the inclusion of personalized translated transcriptome and/or exome in the database used for peptide identification by mass spectroscopy (MS). Candidate MiHAs are identified by comparing the personalized transcriptome and/or exome to a reference genome and/or to the transcriptome and/or exome of an HLA-matched subject.

Abstract: A novel method for human minor histocompatibility antigen (MiHA) discovery, novel MiHAs identified using this method, as well as uses of the novel MiHAs, are described. One of the features of the novel method is the inclusion of personalized translated transcriptome and/or exome in the database used for peptide identification by mass spectroscopy (MS). Candidate MiHAs are identified by comparing the personalized transcriptome and/or exome to a reference genome and/or to the transcriptome and/or exome of an HLA-matched subject.

Abstract: Methods of assessing and reducing risk of graft versus host disease (GVHD) based on gene expression profiling are described, as well as methods of selecting a suitable transplant donor. Corresponding reagents and kits are also described.

Abstract: A novel method for human minor histocompatibility antigen (MiHA) discovery, novel MiHAs identified using this method, as well as uses of the novel MiHAs, are described. One of the features of the novel method is the inclusion of personalized translated transcriptome and/or exome in the database used for peptide identification by mass spectroscopy (MS). Candidate MiHAs are identified by comparing the personalized transcriptome and/or exome to a reference genome and/or to the transcriptome and/or exome of an HLA-matched subject.

Abstract: Methods of assessing and reducing risk of graft versus host disease (GVHD) based on gene expression profiling are described, as well as methods of selecting a suitable transplant donor. Corresponding reagents and kits are also described.

Abstract: Methods of assessing and reducing risk of graft versus host disease (GVHD) based on gene expression profiling are described, as well as methods of selecting a suitable transplant donor. Corresponding reagents and kits are also described.

Abstract: Methods of assessing and reducing risk of graft versus host disease (GVHD) based on gene expression profiling are described, as well as methods of selecting a suitable transplant donor. Corresponding reagents and kits are also described.

Abstract: Methods of assessing and reducing risk of graft versus host disease (GVHD) based on gene expression profiling are described, as well as methods of selecting a suitable transplant donor. Corresponding reagents and kits are also described.

Abstract: Methods of assessing and reducing risk of graft versus host disease (GVHD) based on gene expression profiling are described, as well as methods of selecting a suitable transplant donor. Corresponding reagents and kits are also described.

Abstract: The T lineage differentiative potential of lymphoid progenitor cells in the lymph nodes is thwarted by the absence of Wnt signaling, resulting in blockade of the DN1?DN2 transition with accumulation of pre-DN2 cells. Wnt4 transcripts are deficient in the lymph nodes relative to the thymus. When cultured with stromal cells expressing thymus-like amounts of Wnt4 transcripts, lymphoid progenitor cells expand vigorously and generate single-positive T cells. Wnt4 can be used to promote the differentiation of lymphoid progenitors into cells such as T lymphocytes.