Diane Watling

Receptors for interferons and other cytokines signal through the action of associated protein tyrosine kinases of the JAK family and latent cytoplasmic transcription factors of the STAT family. Genetic and biochemical analysis of interferon signaling indicates that activation of STATs by interferons requires two distinct JAK family kinases. Loss of either of the required JAKs prevents activation of the other JAK and extinguishes STAT activation. These observations suggest that JAKs provide interferon receptors with a critical catalytic signaling function and that at least two JAKs must be incorporated into an active receptor complex. JAK and STAT proteins are also activated by ligands such as platelet-derived growth factor (PDGF), which act through receptors that possess intrinsic protein tyrosine kinase activity, raising questions about the role of JAKs in signal transduction by this class of receptors. Here, we show that all three of the ubiquitously expressed JAKs--JAK1, JAK2, and Tyk2--become phosphorylated on tyrosine in both mouse BALB/c 3T3 cells and human fibroblasts engineered to express the PDGF-beta receptor. All three proteins are also associated with the activated receptor. Through the use of cell lines each lacking an individual JAK, we find that in contrast to interferon signaling, PDGF-induced JAK phosphorylation and activation of STAT1 and STAT3 is independent of the presence of any other single JAK but does require receptor tyrosine kinase activity. These results suggests that the mechanism of JAK activation and JAK function in signaling differs between receptor tyrosine kinases and interferon receptors.

Cell lines that are mutated in interferon (IFN) responses have been critical in establishing an essential role for the JAK family of nonreceptor tyrosine kinases in interferon signalling. Mutant gamma1A cells have previously been shown to be complemented by overexpression of JAK2. Here, it is shown that these cells carry a defect in, and can also be complemented by, the beta-subunit of the IFN-gamma receptor, consistent with the hypothesis that the mutation in these cells affects JAK2-receptor association. In contrast, mutant gamma2A cells lack detectable JAK2 mRNA and protein. By using gamma2A cells, the role of various domains and conserved tyrosine residues of JAK2 in IFN-gamma signalling was examined. Individual mutation of six conserved tyrosine residues, mutation of a potential phosphatase binding site, or mutation of the arginine residue in the proposed SH2-like domain had no apparent effect on signalling in response to IFN-gamma. Results with deletion mutants, however, indicated that association of JAK2 with the IFN-gammaR2 subunit requires the amino-terminal region but not the pseudokinase domain. Consistent with this, in chimeras with JAK1, the JAK2 amino-terminal region was required for receptor association and STAT1 activation. Conversely, a JAK1-JAK2 chimera with the amino-terminal domains of JAK1 linked to the pseudokinase and kinase domains of JAK2 is capable of reconstituting JAK-STAT signalling in response to IFN-alpha and -gamma in mutant U4C cells lacking JAK1. The specificity of the JAKs may therefore lie mainly in their structural interaction with different receptor and signalling proteins rather than in the substrate specificity of their kinase domains.

(NZB x NZW)F1 mice spontaneously develop an autoimmune syndrome characterized by a fatal immune complex glomerulonephritis. Administration of monoclonal antibodies specific for an I region gene product (I-Az) of the H-2 haplotype associated with susceptibility to glomerulonephritis in these animals produced a remission in female mice with established renal disease. The results demonstrated that anti-I-A therapy stabilized the level of proteinuria and increased the 1-yr survival rate from 10% to greater than 90% in treated animals relative to control mice. These findings may ultimately have therapeutic potential for the treatment of systemic lupus erythematosus.