To investigate the functional role of different ␣ 1 -adrenergic receptor (␣ 1 -AR) subtypes in vivo, we have applied a gene targeting approach to create a mouse model lacking the ␣ 1b -AR (␣ 1b ؊͞؊). Reverse transcription-PCR and ligand binding studies were combined to elucidate the expression of the ␣ 1 -AR subtypes in various tissues of ␣ 1b ؉͞؉ and ؊͞؊ mice. Total ␣ 1 -AR sites were decreased by 98% in liver, 74% in heart, and 42% in cerebral cortex of the ␣ 1b ؊͞؊ as compared with ؉͞؉ mice. Because of the large decrease of ␣ 1 -AR in the heart and the loss of the ␣ 1b -AR mRNA in the aorta of the ␣ 1b ؊͞؊ mice, the in vivo blood pressure and in vitro aorta contractile responses to ␣ 1 -agonists were investigated in ␣ 1b ؉͞؉ and ؊͞؊ mice. Our findings provide strong evidence that the ␣ 1b -AR is a mediator of the blood pressure and the aorta contractile responses induced by ␣ 1 agonists. This was demonstrated by the finding that the mean arterial blood pressure response to phenylephrine was decreased by 45% in ␣ 1b ؊͞؊ as compared with ؉͞؉ mice. In addition, phenylephrine-induced contractions of aortic rings also were decreased by 25% in ␣ 1b ؊͞؊ mice. The ␣ 1b -AR knockout mouse model provides a potentially useful tool to elucidate the functional specificity of different ␣ 1 -AR subtypes, to better understand the effects of adrenergic drugs, and to investigate the multiple mechanisms involved in the control of blood pressure.
The Achilles heel of ligand-based NMR screening methods is their failure to detect high-affinity ligands and molecules that bind covalently to the receptor. We have developed a novel approach for performing high-throughput screening with NMR spectroscopy that overcomes this limitation. The method also permits detection of potential high-affinity molecules that are only marginally soluble, thus significantly enlarging the diversity of compounds amenable to NMR screening. The techniques developed utilize transverse and/or selective longitudinal relaxation parameters in combination with competition binding experiments. Mathematical expressions are derived for proper setup of the NMR experiments and for extracting an approximate value of the binding constant for the identified ligand from a single-point measurement. With this approach it is possible to screen thousands of compounds in a short period of time against protein or DNA and RNA fragments. The methodology can also be applied for screening plant and fungi extracts.
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