Abstract: The present invention relates to novel nucleic acid molecules, called aptamers, that bind specifically to a small molecule fluorophore and thereby enhance the fluorescence signal of the fluorophore upon exposure to radiation of suitable wavelength. Molecular complexes formed between the novel fluorophores, novel nucleic acid molecules, and their target molecules are described, and the use of multivalent aptamer constructs as fluorescent sensors for target molecules of interest are also described.

Abstract: This invention relates to a method of characterizing the modified base status of a transcriptome, which involves contacting a transcriptome comprising one or more modified bases with an antibody specific to the modified bases under conditions effective to bind the antibody to the modified bases; isolating, from the transcriptome, a pool of RNA transcripts to which the antibody binds; and identifying isolated RNA transcripts that are present in a higher abundance in the isolated pool relative to the transcriptome, where each of said isolated RNA transcripts that are present in a higher abundance in the isolated pool together characterize the modified base status of the transcriptome. Also disclosed are a method of diagnosis or prognosis of a disease, a method of determining the effect of a treatment on modified base levels in RNA, and a kit for characterizing the modified base status of a transcriptome.

Abstract: The present invention relates to novel nucleic acid molecules, called aptamers, that bind specifically to a small molecule fluorophore and thereby enhance the fluorescence signal of the fluorophore upon exposure to radiation of suitable wavelength. Molecular complexes formed between the novel fluorophores, novel nucleic acid molecules, and their target molecules are described, and the use of multivalent aptamer constructs as fluorescent sensors for target molecules of interest are also described.

Abstract: The present invention relates to novel nucleic acid molecules, called aptamers, that bind specifically to a small molecule fluorophore and thereby enhance the fluorescence signal of the fluorophore upon exposure to radiation of suitable wavelength. Molecular complexes formed between the novel fluorophores, novel nucleic acid molecules, and their target molecules are described, and the use of multivalent aptamer constructs as fluorescent sensors for target molecules of interest are also described.

Abstract: The present invention relates to novel fluorophores and their use in combination with novel nucleic acid molecules, called aptamers, that bind specifically to the fluorophore and thereby enhance the fluorescence signal of the fluorophore upon exposure to radiation of suitable wavelength. Molecular complexes formed between the novel fluorophores, novel nucleic acid molecules, and their target molecules are described, and the use of multivalent aptamer constructs as fluorescent sensors for target molecules of interest are also described.

Abstract: The invention relates to expressing proteins in the axons of mammalian polypeptide in neuronal axons, viruses that can be used deliver nucleic acids of the invention into neuronal axons, as well as methods for doing so. Thus, the invention provides pharmaceutical compositions comprising viruses of the invention, as well as their use in methods of treating injured axons or conditions associated with aberrant axon growth or function.

Abstract: The invention provides a method to C-terminally label proteins in a complex sample and identify those proteins, e.g., using mass spectrometry.

Abstract: The invention relates to particular ubiquitination epitopes, antibodies that specifically recognize and bind to ubiquitinated proteins and peptides (particularly after the ubiquitin is removed by proteolytic cleavage) and to methods of using these epitopes and antibodies.

Abstract: Many of the effects of nitric oxide are mediated by the direct modification of cysteine residues resulting in an adduct called a nitrosothiol. A method to detect proteins which contain nitrosothiols involves several steps. Nitrosylated cysteines are converted to tagged cysteines. Tagged proteins can then be detected, for example, by immunoblotting and/or can be purified by affinity chromatography. The method is applicable to the detection of S-nitrosylated proteins in cell lysates following in vitro S-nitrosylation, as well as to the detection of endogenous S-nitrosothiols in selected protein substrates.

Abstract: Many of the effects of nitric oxide are mediated by the direct modification of cysteine residues resulting in an adduct called a nitrosothiol. A method to detect proteins which contain nitrosothiols involves several steps. Nitrosylated cysteines are converted to tagged cysteines. Tagged proteins can then be detected, for example, by immunoblotting and/or can be purified by affinity chromatography. The method is applicable to the detection of S-nitrosylated proteins in cell lysates following in vitro S-nitrosylation, as well as to the detection of endogenous S-nitrosothiols in selected protein substrates.

Abstract: An nNOS associated protein designated PIN-1 (Protein Inhibitor of nNOS) has been identified. It physically interacts with nNOS and inhibits its activity. Multiple lines of evidence indicate that PIN-1 is a regulator of nNOS: it is physiologically associated with nNOS, and it inhibits its catalytic activity. The extraordinary evolutionary conservation of PIN-1 and preliminary evidence that it interacts with multiple proteins, suggests that it may be a major biological regulatory protein influencing numerous physiological processes.

Abstract: Nitric oxide (NO) produced by neuronal nitric oxide synthase (nNOS) is important for N-methyl-D-aspartate (NMDA) receptor-dependent neurotransmitter release, neurotoxicity, and cyclic-GMP elevations. The coupling of NMDA receptor-mediated calcium influx and nNOS activation is postulated to be due to a physical coupling of the receptor and the enzyme by an intermediary adaptor protein PSD95, through a unique PDZ-PDZ domain interaction between PSD95 and nNOS. Here we report the identification of a novel nNOS associated protein, CAPON, which is highly enriched in brain and has numerous colocalizations with nNOS. CAPON interacts with the NNOS PDZ domain through its C-terminus. CAPON competes with PSD95 for interaction with nNOS, and overexpression of CAPON results in a loss of PSD95/nNOS complexes in transfected cells. CAPON influences nNOS by regulating its ability to associate with PSD95/NMDA receptor complexes.

Abstract: An nNOS associated protein designated PIN-1 (Protein Inhibitor of nNOS) has been identified. It physically interacts with nNOS and inhibits its activity. Multiple lines of evidence indicate that PIN-1 is a regulator of nNOS: it is physiologically associated with nNOS, and it inhibits its catalytic activity. The extraordinary evolutionary conservation of PIN-1 and preliminary evidence that it interacts with multiple proteins, suggests that it may be a major biological regulatory protein influencing numerous physiological processes.