We have expressed, purified, and analyzed the iron-containing superoxide dismutase (FeSOD) of Escherichia coli with mutations directed at tyrosine position 34 to introduce phenylalanine (SODY34F), serine (SODY34S), or cysteine (SODY34C). FeSOD and mutant enzymes were purified from SOD-deficient cells using a GST-FeSOD fusion protein intermediate which was subsequently cleaved with thrombin and repurified. Specific activities were measured using the xanthine-xanthine oxidase method and gave 3148 u/mg for wild-type FeSOD. The SODY34S mutation virtually inactivates the enzyme (42 u/mg); mutation to cysteine greatly reduces activity (563 u/mg), but the SODY34F mutant retains nearly 40% of the activity of wild type (1205 u/mg). Fusion protein intermediates were also shown to be active and were demonstrated to protect SOD-deficient E. coli cells from the induced effects of oxidative stress, with growth rates directly proportional to the specific activities of the expressed mutant enzymes. SODY34F exhibited decreased thermal stability, reduced activity at high pH, and a pronounced increase in sensitivity to the inhibitor sodium azide compared with wild-type FeSOD. These results suggest that tyrosine at position 34 is multifunctional and plays a structural role (probably through hydrogen bonding to glutamine at position 69) in maintaining the integrity of the active site, a stabilizing role at high pH, and a steric role in obstructing access to the active site of both substrate and inhibitor molecules.
Two genes encoding manganese superoxide dismutase (sod-2 and sod-3) have been identified in the nematode Caenorhabditis elegans. Each gene is composed of five exons, and intron positions are identical; however, intron sizes and sequences are not the same. The predicted protein sequences are 86.3% homologous (91.8% conservative), and the cDNAs are only 75.2% homologous. Both deduced protein sequences contain the expected N-terminal mitochondrial transit peptides. Reverse transcriptase polymerase chain reaction analysis shows that both genes are expressed under normal growth conditions and that their RNA transcripts are trans-spliced to the SL-1 leader sequence. The latter result together with Northern blot analysis indicate that both genes have mono-cistronic transcripts. The sod-3 gene was mapped to chromosome X, and the location of sod-2 was confirmed to be chromosome I. Polymerase chain reaction was used to amplify the cDNA regions encoding the predicted mature manganese superoxide dismutase proteins and each was cloned and expressed to high levels in Escherichia coli cells deficient in cytosolic superoxide dismutases. Both proteins were shown to be active in E. coli, providing similar protection against methyl viologen-induced oxidative stress. The expressed enzymes, which were not inhibited by hydrogen peroxide or cyanide, are dimeric, show quite different electrophoretic mobilities and isoelectric points, but exhibit comparable specific activities.
The human muscarinic M 2 receptor is a functionally important membrane-bound protein that is negatively coupled to adenylyl cyclase and is widely expressed in a range of tissues, including cardiac myocytes, prejunctional cholinergic nerve endings, and smooth muscle. In the airways, M 2 receptors are constitutively expressed on airway smooth muscle (ASM) and, in contrast to muscarinic M 3 receptors, continue to be expressed during primary culture (1). Muscarinic M 2 receptors play an important role in the control of ASM cAMP regulation, being responsible for acetylcholine-mediated inhibition of adenyl cyclase activity. This action ameliorates in part the relaxant effect of agents such as isoproterenol in the airways (2).Despite the cloning of the human muscarinic M 2 receptor gene several years ago (3, 4) the elements important for tran-
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