Janus kinases (Jaks) play an important role in signal transduction via cytokine receptors. Tyk2 is a Janus kinase, and we developed tyk2-deficient mice to study the requirement for tyk2 in vivo. Tyk2-deficient mice show no overt developmental abnormalities; however, they display a lack of responsiveness to a small amount of IFNalpha, although a high concentration of IFNalpha can fully transduce its signal even in the absence of tyk2. Furthermore, IL-12-induced T cell function is defective in these mice. In contrast, these mice respond normally to IL-6 and IL-10, both of which activate tyk2 in vitro. These observations demonstrate that tyk2 plays only a restricted role in mediating IFNalpha-dependent signaling while being required in mediating IL-12-dependent biological responses.
Two complementary DNA's, encoding the complete sequences of 671 and 673 amino acids for subspecies of rat brain protein kinase C, were expressed in COS 7 cells. The complementary DNA sequence analysis predicted that the two enzymes are derived from different ways of splicing and differ from each other only in the short ranges of their carboxyl-terminal regions. Both enzymes showed typical characteristics of protein kinase C that responded to Ca2+, phospholipid, and diacylglycerol. The enzymes showed practically identical physical and kinetic properties and were indistinguishable from one of the several subspecies of protein kinase C that occurs in rat brain but not in untransfected COS 7 cells. Partial analysis of the genomic structure confirmed that these two subspecies of protein kinase C resulted indeed from alternative splicing of a single gene.
Three types of protein kinase C, designated types I, II, and III, were purified from rat brain cytosol, and have been shown to correspond to the cDNA clones gamma, beta, and alpha, respectively. Their relative activities in the whole brain tissue were roughly 26, 49, and 25% with H1 histone as a substrate. Type II enzyme was an unequal mixture of two subspecies (roughly 1:7) encoded by beta I and beta II sequences which differ from each other only in a short range of their carboxyl-terminal end regions. Although the three types have closely similar structures, they showed slightly different modes of activation and kinetic properties. Type I enzyme was less sensitive to diacylglycerol but was significantly activated by low concentrations of free arachidonic acid. Type II enzyme exhibited substantial activity without elevated Ca2+ levels, and responded well to diacylglycerol and, to some extent, arachidonic acid. The type III enzyme responded to diacylglycerol as well as to arachidonic acid. The mode of activation of the enzyme by arachidonic acid required elevated levels of Ca2+ but not phospholipid. In the presence of phospholipid, phorbol esters could activate all three types in a manner similar to diacylglycerol. Among various phospholipids tested, phosphatidylserine was the most effective for all three types. Type III enzyme was most sensitive to 1-stearoyl-2-arachidonylglycerol for activation. Conversely, type I enzyme was activated most efficiently by synthetic permeable diacylglycerols, such as 1,2-didecanoylglycerol and 1,2-dioctanoylglycerol. Many heavy metal ions exerted variable and distinct effects on the catalytic activities of these three types.(ABSTRACT TRUNCATED AT 250 WORDS)
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