Abstract: Recombinant bacterial triple-helical collagen-like proteins comprising two or more repetitive sequences of Gly-Xaa-Yaa yielding high-stability polymeric constructs without the need for post-translational modifications and which may incorporate one or more functional domains of biological or structural importance.

Abstract: Recombinant bacterial triple-helical collagen-like proteins comprising two or more repetitive sequences of Gly-Xaa-Yaa yielding high-stability polymeric constructs without the need for post-translational modifications and which may incorporate one or more functional domains of biological or structural importance. The polymers are capable of high-yield production for a variety of applications.

Abstract: Recombinant bacterial triple-helical collagen-like proteins comprising two or more repetitive sequences of Gly-Xaa-Yaa yielding high-stability polymeric constructs without the need for post-translational modifications and which may incorporate one or more functional domains of biological or structural importance.

Abstract: The present invention provides the multifunctional biological and biochemical sensor technology based on ZnO nanostructures. The ZnO nanotips serve as strong DNA or protein molecule binding sites to enhance the immobilization. Patterned ZnO nanotips are used to provide conductivity-based biosensors. Patterned ZnO nanotips are also used as the gate for field-effect transistor (FET) type sensors. Patterned ZnO nanotips are integrated with SAW or BAW based biosensors. These ZnO nanotip based devices operate in multimodal operation combining electrical, acoustic and optical sensing mechanisms. The multifunctional biosensors can be arrayed and combined into one biochip, which will enhance the sensitivity and accuracy of biological and biochemical detection due to strong immobilization and multimodal operation capability. Such biological and biochemical sensor technology are useful in detection of RNA-DNA, DNA-DNA, protein-protein, protein-DNA and protein-small molecules interaction.

Abstract: The present invention provides the multifunctional biological and biochemical sensor technology based on ZnO nanostructures. The ZnO nanotips serve as strong DNA or protein molecule binding sites to enhance the immobilization. Patterned ZnO nanotips are used to provide conductivity-based biosensors. Patterned ZnO nanotips are also used as the gate for field-effect transistor (FET) type sensors. Patterned ZnO nanotips are integrated with SAW or BAW based biosensors. These ZnO nanotip based devices operate in multimodal operation combining electrical, acoustic and optical sensing mechanisms. The multifunctional biosensors can be arrayed and combined into one biochip, which will enhance the sensitivity and accuracy of biological and biochemical detection due to strong immobilization and multimodal operation capability. Such biological and biochemical sensor technology are useful in detection of RNA-DNA, DNA-DNA, protein-protein, protein-DNA and protein-small molecules interaction.

Abstract: The present invention provides the multifunctional biological and biochemical sensor technology based on ZnO nanostructures. The ZnO nanotips serve as strong DNA or protein molecule binding sites to enhance the immobilization. Patterned ZnO nanotips are used to provide conductivity-based biosensors. Patterned ZnO nanotips are also used as the gate for field-effect transistor (FET) type sensors. Patterned ZnO nanotips are integrated with SAW or BAW based biosensors. These ZnO nanotip based devices operate in multimodal operation combining electrical, acoustic and optical sensing mechanisms. The multifunctional biosensors can be arrayed and combined into one biochip, which will enhance the sensitivity and accuracy of biological and biochemical detection due to strong immobilization and multimodal operation capability. Such biological and biochemical sensor technology are useful in detection of RNA-DNA, DNA-DNA, protein-protein, protein-DNA and protein-small molecules interaction.

Abstract: The present invention provides a novel gene, IAP, which encodes a soluble protein that is involved in the initiation of an inflammatory cytokine response and which may interact with the anti-inflammatory IL-13. The protein of the present invention may be involved as a central mediator in ischemia, reperfusion, asthma and other inflammation-induced pathological conditions. The invention relates to methods for using isolated polypeptides and polynucleotides, for detecting the early onset of chronic asthma, psoriasis, stroke, ischemia, reperfusion, leishmaniasis, helminthiasis, hypoxia, or other causes of renal, liver or heart failure in a mammal, where increased cytokine activity is known to play a role.

Abstract: A transgenic animal, the genome of which comprises a transgene for superoxide dismutase (SOD), erythrocyte-glutathione peroxidase (GPE), or plasma-glutathione peroxidase (GPP), is disclosed. A double transgenic animal comprising the transgenes for both SOD and GPE is also disclosed. Methods for making the transgenic animals are disclosed. Both the SOD gene and the two GP genes code for proteins which control the level of reactive oxidative species (ROS) which accumulate in cells as a result of metabolism. Cell lines from both SOD and GP transgenic animals and methods for use of the transgenic animals as models are also disclosed.

Abstract: The inhibition of proteins synthesis by an antisense RNA-tRNA complex which is capable of inhibiting translation is described. Under certain conditions, growth of organisms is inhibited by inhibition of non-specific translation by an antisense RNA construct to a tRNA target. In vitro, cell-free inhibition of viral protein translation is described. Transformed microorganisms are disclosed. The invention has applicability in the control of cell growth, such as viruses, bacteria, infected cells, or tumor cells. The invention is useful in animal and plant fields.