Dimer stability as a determinant of differential DNA binding activity of Stat3 isoforms

Stat3alpha and Stat3beta are two Stat3 isoforms with marked quantitative differences in their DNA binding activities. To examine the molecular basis of the differential DNA binding activities, we measured DNA binding strength and dimer stability, two possible mechanisms responsible for these differences. Stat3alpha and Stat3beta showed no difference in DNA binding strength, i.e. they had similar association and dissociation rates for DNA binding. However, competition analyses performed with dissociating reagents including an anti-phosphotyrosine antibody, SH2 domain protein, and a phosphopeptide demonstrated that Stat3beta dimers are more stable than Stat3alpha dimers. We report here that dimer stability of activated forms plays a critical role in determining DNA binding activity of Stat3 isoforms. We found that C-terminal deletions of Stat3alpha increased both DNA binding activity and dimer stability of Stat3alpha. Our findings suggest that the acidic C-terminal region of Stat3alpha does not interfere with the DNA binding of activated Stat3alpha dimers, but destabilizes the dimeric forms of Stat3alpha. We propose that dimer stability described in vitro may be the underlying mechanism of in vivo stability of activated Stat3 proteins, regulating dephosphorylation of tyrosine 705.     

Signal transduction pathways regulated by prolactin and Src result in different conformations of activated Stat5b

Stat5 is activated by a broad spectrum of cytokines, as well as non-receptor tyrosine kinases, such as Src. In this study, the DNA binding properties of the two closely related Stat5 proteins, Stat5a and Stat5b, induced either by prolactin (Prl) or by Src were analyzed by electrophoretic mobility shift assays using several different Stat5 binding sites. Src-induced Stat5b-DNA binding complexes consistently displayed a slightly faster mobility than those induced by Prl, as well as differences in their ability to be supershifted by anti-Stat5 antibodies. IP-Westerns performed using specific antibodies directed at the N and C termini of Stat5b suggested that depending on the activating stimulus, Stat5b exhibited different conformations, which influenced antibody accessibility at its C terminus. These conformational differences may in part be due to differential effects of Prl and Src on Stat5b tyrosine phosphorylation, since Src induced several additional sites of tyrosine phosphorylation of Stat5b at residues other than Tyr-699, including Tyr-724 and Tyr-679. The latter Tyr-679 is conserved in all mammalian Stat5bs, but is not present in Stat5a. A Stat 5bY679F mutant induced by Src kinase exhibited an altered pattern of nuclear localization as compared with wild-type Stat5b. Furthermore, this mutation inhibited v-Src-induced cyclin D1-luciferase reporter activity in transient transfection assays performed in Stat5a/b-deficient MEFs, suggesting that Tyr-679 phosphorylation may play a role in v-Src induced proliferation. Thus, depending on the signal transduction pathway responsible for activation, different conformations of activated Stat5 may result in selective biological responses.     

Protein Tyrosine Phosphatases,TC-PTP,SHP1, and SHP2, Cooperate in Rapid Dephosphorylation of Stat3 in Keratinocytes Following UVB Irradiation

Stat3 is initially dephosphorylated in murine keratinocytes in response to UVB irradiation. Treatment with Na₃VO₄ desensitized keratinocytes to UVB-induced apoptosis with the recovery of phosphorylated Stat3 protein levels, implying that a protein tyrosine phosphatase (PTP) is involved in this mechanism. In the current work, we report that three PTPs including TC45 (the nuclear form of TC-PTP), SHP1, and SHP2 are involved in this rapid dephosphorylation of Stat3 in keratinocytes induced by UVB irradiation. Dephosphorylation of Stat3 was increased rapidly after UVB irradiation of cultured keratinocytes. Knockdown of TC-PTP, SHP1, or SHP2 using RNAi showed that these PTPs are likely responsible for most of the rapid Stat3 dephosphorylation observed following UVB irradiation. The level of phosphorylated Stat3 was significantly higher in keratinocytes transfected with TC-PTP, SHP1, or SHP2 siRNA in the presence or absence of UVB compared with keratinocytes transfected with control siRNA. TC45 was mainly localized in the cytoplasm of keratinocytes and translocated from cytoplasm to nucleus upon UVB irradiation. Stat3 dephosphorylation was associated with nuclear translocation of TC45. Further studies revealed that knockdown of all three phosphatases, using RNAi, prevented the rapid dephosphorylation of Stat3 following UVB irradiation. In mouse epidermis, the level of phosphorylated Stat3 was initially decreased, followed by a significant increase at later time points after UVB exposure. The levels of Stat3 target genes, such as cyclin D1 and c-Myc, followed the changes in activated Stat3 in response to UVB irradiation. Collectively, these results suggest that three phosphatases, TC45, SHP1, and SHP2, are primarily responsible for UVB-mediated Stat3 dephosphorylation and may serve as part of an initial protective mechanism against UV skin carcinogenesis.     

A novel sequence in the coiled-coil domain of Stat3 essential for its nuclear translocation

Stat3 is activated by cytokines and growth factors via specific tyrosine phosphorylation, dimerization, and nuclear translocation. However, the mechanism involved in its nuclear translocation is unclear. In this study, by systematic deletion and site-directed mutagenesis we identified Arg-214/215 in the alpha-helix 2 region of the coiled-coil domain of Stat3 as a novel sequence element essential for its nuclear translocation, stimulated by epidermal growth factor as well as by interleukin-6. Furthermore, we identified Arg-414/417 in the DNA binding domain as also required for the nuclear localization of Stat3. This sequence element corresponds to Lys-410/413 of Stat1, a reported sequence for Stat1 nuclear translocation. On the other hand, Leu-411 of Stat3, corresponding to Leu-407 of Stat1, a necessary residue for Stat1 nuclear transport, is not essential for Stat3 nuclear import. The mutant of Arg-214/215 or Arg-414/417 was shown to be tyrosyl-phosphorylated normally but failed to enter the nucleus in response to epidermal growth factor or interleukin-6. The defect, however, can be rescued by the wild-type Stat3 but cannot be compensated by these two mutants. Mutations on Arg-414/417, but not Arg-214/215, destroy the DNA binding activity of Stat3. Our data for the first time identified a sequence element located in the coiled-coil domain that is involved in the ligand-induced nuclear translocation of Stat3. This novel sequence together with a conserved sequence element in the DNA binding domain coordinates to mediate the nuclear translocation of Stat3.     

Regulation of Stat3 nuclear import by importin alpha5 and importin alpha7 via two different functional sequence elements

Regulated import of STAT proteins into the nucleus through the nuclear pores is a vital event. We previously identified Arg214/215 in the coiled-coil domain and Arg414/417 in the DNA binding domain involved in the ligand-induced nuclear translocation of Stat3. In this study, we investigated the mechanism for Stat3 nuclear transport. We report here that among five ubiquitously expressed human importin alphas, importin alpha5 and alpha7, but not importin alpha1, alpha3, and alpha4, bind to Stat3 upon cytokine stimulation. Similar results were observed for Stat1, but not for Stat5a and 5b, which were unable to interact with any of the importin alphas. The C-terminus of importin alpha5 is necessary but not sufficient for Stat3 binding. Truncation mutant of Stat3 (aa1-320) that contains Arg214/215 exhibits specific binding to importin alpha5, and an exclusive nuclear localization. Point mutations of Arg214/215 in this mutant destroy importin alpha5 binding and its nuclear localization. In contrast, the truncation mutant (aa320-770) including Arg414/417 fails to interact with importin alpha5 and is localized in the cytoplasm. However, both sequence elements are necessary for the full-length Stat3's interaction with importin alpha5. These results suggest that Arg214/215 is likely the binding site for importin alpha5, whereas Arg414/417 may not be involved in the direct binding, but necessary for maintaining the proper conformation of Stat3 dimer for importin binding. A model for Stat3 nuclear translocation is proposed based on these data.     

Interleukin-3 signals through multiple isoforms of Stat5.

The interleukin (IL)-3 family of cytokines mediates its numerous effects on myeloid growth and maturation by binding a family of related receptors. It has been shown recently that IL-3 induces the activation of two distinct cytoplasmic signal transducing factors (STFs) that are likely to mediate the induction of immediate early genes. In immature myeloid cells, IL-3 activates STF-IL-3a, which comprises two tyrosine-phosphorylated DNA binding proteins of 77 and 80 kDa. In mature myeloid cells, IL-3 and granulocyte-macrophage colony-stimulating factor activate STF-IL-3b, which consists of a 94 and 96 kDa tyrosine-phosphorylated DNA binding protein. Peptide sequence data obtained from the purified 77 and 80 kDa proteins (p77 and p80) indicate that they are closely related but are encoded by distinct genes. Both peptide and nucleotide sequence data demonstrate that these two proteins are the murine homologs of ovine mammary gland factor (MGF)/Stat5. The peptide data also indicate that p77 and p80 are phosphorylated on tyrosine 699, a position analogous to the tyrosine that is phosphorylated in Stat1 and Stat2 in response to interferon. Additionally, antiserum raised against bacterially expressed p77/p80 recognizes the 94 and 96 kDa protein components of STF-IL-3b, suggesting that these may be additional isoforms of Stat5. These studies indicate that the IL-3 family of ligands is able to activate multiple isoforms of the signal transducing protein Stat5.