Interferon research: impact on understanding transcriptional control.

Celebrations are certainly in order for the 50th anniversary of the Isaacs/Lindenmann discovery of interferon as a secreted substance of probable cellular origin that conferred resistance to at least four viruses of distinctly different character--influenza, Sendai, Newcastle's disease, and vaccinia. Personal pride, excusable, I hope, leads me to recall also that following the trail of how interferon works its magic led 15 years ago this year to the discovery of the STATs and their activation by the Jak kinases. These later findings were stimulated by and in turn further stimulated an ever deepening interest in how transcription figured in changing cell behavior. Here are presented some further reflections on these topics.

Essential role of STAT3 in postnatal survival and growth revealed by mice lacking STAT3 serine 727 phosphorylation.

A large number of extracellular polypeptides bound to their cognate receptors activate the transcription factor STAT3 by phosphorylation of tyrosine 705. Supplemental activation occurs when serine 727 is also phosphorylated. STAT3 deletion in mice leads to embryonic lethality. We have produced mice with alanine substituted for serine 727 in STAT3 (the SA allele) to examine the function of serine 727 phosphorylation in vivo. Embryonic fibroblasts from SA/SA mice had approximately 50% of the transcriptional response of wild-type cells. However, SA/SA mice were viable and grossly normal. STAT3 wild-type/null (+/-) animals were also normal and were interbred with SA/SA mice to study SA/- mice. The SA/- mice progressed through gestation, showing 10 to 15% reduced birth weight, three-fourths died soon after birth, and the SA/- survivors reached only 50 to 60% of normal size at 1 week of age. The lethality and decreased growth were accompanied by altered insulin-like growth factor 1 (IGF-1) levels in serum, establishing a role for the STAT3 serine phosphorylation acting through IGF-1 in embryonic and perinatal growth. The SA/- survivors have decreased thymocyte number associated with increased apoptosis, but unexpectedly normal STAT3-dependent liver acute phase response. These animals offer the opportunity to study defined reductions in the transcriptional capacity of a widely used signaling pathway.

Stats: transcriptional control and biological impact.

Extracellular proteins bound to cell-surface receptors can change nuclear gene expression patterns in minutes, with far-reaching consequences for development, cell growth and homeostasis. The signal transducer and activator of transcription (STAT) proteins are among the most well studied of the latent cytoplasmic signal-dependent transcription-factor pathways. In addition to several roles in normal cell decisions, dysregulation of STAT function contributes to human disease, making the study of these proteins an important topic of current research.

A Drosophila PIAS homologue negatively regulates stat92E.

Transcriptional activation by, and therefore the physiologic impact of, activated tyrosine-phosphorylated STATs (signal transducers and activators of transcription) may be negatively regulated by proteins termed PIAS (protein inhibitors of activated stats), as shown by previous experiments with mammalian cells in culture. Here, by using the genetic modifications in Drosophila, we demonstrate the in vivo functional interaction of the Drosophila homologues stat92E and a Drosophila PIAS gene (dpias). To this end we use a LOF allele and conditionally overexpressed dpias in JAK-STAT pathway mutant backgrounds. We conclude that the correct dpias/stat92E ratio is crucial for blood cell and eye development.

Functional importance of Stat3 tetramerization in activation of the alpha 2-macroglobulin gene.

A tetrameric Stat3 complex was found to be essential in transfection experiments for maximal interleukin-6-inducible activation of alpha2-macroglobulin gene promoter. Stable tetramer formation of purified phosphorylated Stat3 was dependent on protein.protein interaction involving the N-terminal domain of Stat3. The functional importance of tetramer formation was shown by the decreased levels of transcriptional activation associated with hypomorphic mutations in N-terminal residues.

Antiviral response in cells containing Stat1 with heterologous transactivation domains.

The STATs (signal transducers and activators of transcription), latent cytoplasmic transcription factors, are activated by binding of extracellular polypeptides to cell surface receptors. Dimerization, accumulation in the nucleus, and transcriptional inductions of specific genes then occur. The COOH terminus of the STATs acts as a transcriptional activation domain (TAD). Stat1, one of seven mammalian STAT genes, forms a homodimer after activation by gamma interferon and induces transcription of a number of genes. These induced genes in turn produce the antiviral state. In the present experiments we used a Stat1-deficient cell line complemented with Stat1 or various fusion constructs in which the wild-type Stat1 TAD was replaced by other TADs to test the possibility that a specific activating domain was necessary for the induction of the antiviral response. We found that a wide variety of TADs with different activation potential appended to the Stat1 COOH terminus could substitute for the wild-type protein in inducing the antiviral state.

Constitutively activated Stat3 protects fibroblasts from serum withdrawal and UV-induced apoptosis and antagonizes the proapoptotic effects of activated Stat1.

Stats1 and 3 (signal transducers and activators of transcription) can be activated simultaneously, although not necessarily to the same degree or duration, by the interaction of cells with the same polypeptide ligand (EGF, PDGF, or high concentrations of IL-6, for example). However, these two Stat proteins can mediate opposing effects on cell growth and survival. Stat1 activation slows growth and promotes apoptosis. In contrast, activated Stat3 can protect cells from apoptosis. Furthermore, a constitutively active form of Stat3, Stat3-C (bridged by S-S linkages between cysteines instead of phosphotyrosines) can induce cellular transformation of fibroblasts. We have determined that fibroblasts transformed by Stat3-C are more resistant to proapoptotic stimuli than nontransformed cells. Also, to examine the potential opposing roles in apoptosis of Stat1 and Stat3, we studied the cervical carcinoma-derived cell line, Me180, which undergoes Stat1-dependent, IFN gamma-induced apoptosis. Me180 cells that express Stat3-C are protected against IFN gamma-mediated apoptosis.

The role of STATs in transcriptional control and their impact on cellular function.

The STAT proteins (Signal Transducers and Activators of Transcription), were identified in the last decade as transcription factors which were critical in mediating virtually all cytokine driven signaling. These proteins are latent in the cytoplasm and become activated through tyrosine phosphorylation which typically occurs through cytokine receptor associated kinases (JAKs) or growth factor receptor tyrosine kinases. Recently a number of non-receptor tyrosine kinases (for example src and abl) have been found to cause STAT phosphorylation. Phosphorylated STATs form homo- or hetero-dimers, enter the nucleus and working coordinately with other transcriptional co-activators or transcription factors lead to increased transcriptional initiation. In normal cells and in animals, ligand dependent activation of the STATs is a transient process, lasting for several minutes to several hours. In contrast, in many cancerous cell lines and tumors, where growth factor dysregulation is frequently at the heart of cellular transformation, the STAT proteins (in particular Stats 1, 3 and 5) are persistently tyrosine phosphorylated or activated. The importance of STAT activation to growth control in experiments using anti-sense molecules or dominant negative STAT protein encoding constructs performed in cell lines or studies in animals lacking specific STATs strongly indicate that STATs play an important role in controlling cell cycle progression and apoptosis. Stat1 plays an important role in growth arrest, in promoting apoptosis and is implicated as a tumor suppressor; while Stats 3 and 5 are involved in promoting cell cycle progression and cellular transformation and preventing apoptosis. Many questions remain including: (1) a better understanding of how the STAT proteins through association with other factors increase transcription initiation; (2) a more complete definition of the sets of genes which are activated by different STATs and (3) how these sets of activated genes differ as a function of cell type. Finally, in the context of many cancers, where STATs are frequently persistently activated, an understanding of the mechanisms leading to their constitutive activation and defining the potential importance of persistent STAT activation in human tumorigenesis remains. Oncogene (2000).

Interacting regions in Stat3 and c-Jun that participate in cooperative transcriptional activation.

Independent but closely spaced DNA binding sites for Stat3 and c-Jun are required for maximal enhancer function in a number of genes, including the gene encoding the interleukin-6 (IL-6)-induced acute-phase response protein, alpha(2)-macroglobulin. In addition, a physical interaction of Stat3 with c-Jun, based on yeast two-hybrid interaction experiments, has been reported. Here we confirm the existence of an interaction between Stat3 and c-Jun both in vitro, with recombinant proteins, and in vivo, during transient transfection. Using fragments of both proteins, we mapped the interactive sites to the C-terminal region of c-Jun and to two regions in Stat3, within the coiled-coil domain and in a portion of the DNA binding domain distant from DNA contact sites. In transient-transfection experiments with the alpha(2)-macroglobulin enhancer, Stat3 and c-Jun cooperated to yield maximal enhancer function. Point mutations of Stat3 within the interacting domains blocked both physical interaction of Stat3 with c-Jun and their cooperation in IL-6-induced transcription directed by the alpha(2)-macroglobulin enhancer. While the amino acid sequences and the three-dimensional structures of Stat3 and Stat1 cores are very similar, fragments of Stat1 failed to bind c-Jun in vitro. Although Stat1 binds in vitro to the gamma interferon gene response (GAS) element in the alpha(2)-macroglobulin enhancer, Stat1 did not stimulate transcription, nor did Stat1 and c-Jun cooperate in driving transcription controlled by the alpha(2)-macroglobulin enhancer.

A nuclear protein tyrosine phosphatase is required for the inactivation of Stat1.

The Stat1 activation-inactivation cycle involves phosphorylation of Stat1 in the cytoplasm, translocation to the nucleus, and then a return of the protein to the cytoplasm in a dephosphorylated state. However, the intracellular site of Stat1 dephosphorylation has not been determined. As receptor signaling declines, the flow of activated Stat1 molecules should be to the site of their dephosphorylation. We found that upon receptor-Janus kinase inactivation, either gradual or abruptly induced by staurosporine treatment, the flow of Stat1 was from cytoplasm to the nucleus and the nucleus was the final compartment in which phosphorylated Stat1 was detected. N-terminal mutants of Stat1, previously shown to remain phosphorylated for a longer time than wild-type Stat1, were able to enter the nucleus and were not inactivated in the presence of staurosporine, directly demonstrating that these mutations affect phosphatase access and/or activity during the normal dephosphorylation of Stat1. In the presence of sodium vanadate, a phosphatase inhibitor, phosphorylated Stat1 accumulated in the nucleus as the total amount of Stat1 in the cytoplasm declined to low levels. We conclude that the nucleus is the site of Stat1 inactivation and that dephosphorylation is required for the rapid nuclear export of Stat1.

Stat3 as an oncogene.

STATs are latent transcription factors that mediate cytokine- and growth factor-directed transcription. In many human cancers and transformed cell lines, Stat3 is persistently activated, and in cell culture, active Stat3 is either required for transformation, enhances transformation, or blocks apoptosis. We report that substitution of two cysteine residues within the C-terminal loop of the SH2 domain of Stat3 produces a molecule that dimerizes spontaneously, binds to DNA, and activates transcription. The Stat3-C molecule in immortalized fibroblasts causes cellular transformation scored by colony formation in soft agar and tumor formation in nude mice. Thus, the activated Stat3 molecule by itself can mediate cellular transformation and the experiments focus attention on the importance of constitutive Stat3 activation in human tumors.

The linker domain of Stat1 is required for gamma interferon-driven transcription.

Upon binding of gamma interferon (IFN-gamma) to its receptor, the latent transcription factor Stat1 becomes phosphorylated, dimerizes, and enters the nucleus to activate transcription. In response to IFN-alpha, Stat1 binds to Stat2 in a heterodimer that recruits p48, an IRF family member, to activate transcription. A number of functional domains of the STATs, including a C-terminal transactivation domain, a dimerization domain, and an SH2 domain, are known. However, the highly conserved residues between the DNA binding and SH2 domains (463 to 566), recently christened the linker domain on the basis of crystallographic studies, have remained without a known function. In the present study, we report that KE544-545AA point mutants in Stat1 abolish transcriptional responses to IFN-gamma but not to IFN-alpha. We further show that this mutant Stat1 undergoes normal phosphorylation, nuclear translocation, and DNA binding. Taken together with recent structural evidence, these results suggest that the linker domain acts as a critical contact point during the construction of a Stat1-driven transcriptional complex.

The significance of tetramerization in promoter recruitment by Stat5.

Stat5a and Stat5b are rapidly activated by a wide range of cytokines and growth factors, including interleukin-2 (IL-2). We have previously shown that these signal transducers and activators of transcription (STAT proteins) are key regulatory proteins that bind to two tandem gamma interferon-activated site (GAS) motifs within an IL-2 response element (positive regulatory region III [PRRIII]) in the human IL-2Ralpha promoter. In this study, we demonstrate cooperative binding of Stat5 to PRRIII and explore the molecular basis underlying this cooperativity. We demonstrate that formation of a tetrameric Stat5 complex is essential for the IL-2-inducible activation of PRRIII. Stable tetramer formation of Stat5 is mediated through protein-protein interactions involving a tryptophan residue conserved in all STATs and a lysine residue in the Stat5 N-terminal domain (N domain). The functional importance of tetramer formation is shown by the decreased levels of transcriptional activation associated with mutations in these residues. Moreover, the requirement for STAT protein-protein interactions for gene activation from a promoter with tandemly linked GAS motifs can be relieved by strengthening the avidity of protein-DNA interactions for the individual binding sites. Taken together, these studies demonstrate that a dimeric but tetramerization-deficient Stat5 protein can activate only a subset of target sites. For functional activity on a wider range of potential recognition sites, N-domain-mediated oligomerization is essential.

A single amino acid substitution in the v-Eyk intracellular domain results in activation of Stat3 and enhances cellular transformation.

The receptor tyrosine kinase Eyk, a member of the Axl/Tyro3 subfamily, activates the STAT pathway and transforms cells when constitutively activated. Here, we compared the potentials of the intracellular domains of Eyk molecules derived from c-Eyk and v-Eyk to transform rat 3Y1 fibroblasts. The v-Eyk molecule induced higher numbers of transformants in soft agar and stronger activation of Stat3; levels of Stat1 activation by the two Eyk molecules were similar. A mutation in the sequence Y933VPL, present in c-Eyk, to the v-Eyk sequence Y933VPQ led to increased activation of Stat3 and increased transformation efficiency. However, altering another sequence, Y862VNT, present in both Eyk molecules to F862VNT markedly decreased transformation without impairing Stat3 activation. These results indicate that activation of Stat3 enhances transformation efficiency and cooperates with another pathway to induce transformation.

Ser727-dependent recruitment of MCM5 by Stat1alpha in IFN-gamma-induced transcriptional activation.

Stat1alpha is a latent cytoplasmic transcription factor activated in response to interferon-gamma (IFN-gamma). The C-terminal 38 amino acids of Stat1alpha are required to trigger transcription and therefore may possibly serve as a transcription activation domain (TAD). Here we show that the C-terminus of Stat1alpha is an independent TAD which can interact with a specific group of nuclear proteins. Mutation of the Stat1 Ser727 and Leu724 decreases its transcriptional activity and affinity for the nuclear proteins. One of the interacting proteins was identified as MCM5, a member of the mini-chromosome maintenance (MCM) family involved in DNA replication. Both in vitro and in vivo interaction of Stat1alpha and MCM5 were demonstrated. Furthermore, the in vitro interaction required Ser727 and was enhanced by its phosphorylation. Transient over-expression of MCM5 enhanced transcriptional activation by Stat1alpha in a Ser727-dependent manner. Finally, changes in the level of nuclear localized MCM5 during the cell cycle correlated with the changes in transcriptional response to IFN-gamma acting through Stat1alpha. These results strongly suggest that MCM5 is recruited through interaction with Stat1alpha in a Ser727- and Leu724-dependent manner to play a role in optimal transcriptional activation.

Studies of IFN-induced transcriptional activation uncover the Jak-Stat pathway.

Sharing the Milstein Award with George R. Stark and Ian M. Kerr in the fall of 1997 brought this invitation to record personal reflections on our experiments concerning the mechanisms of action of interferon. Our work and that of the Kerr and Stark laboratories uncovered the Jak-Stat pathway through which signals from cell surface receptors reach genes in the cell nucleus. This review concentrates on that to which I can speak most reliably, that is, experiments done by my young colleagues at Rockefeller University.

Epidermal growth factor-induced growth inhibition requires Stat1 activation.

Epidermal growth factor (EGF) is a mitogen for most epithelial cells. Paradoxically, the growth of some cultured cell lines, containing high numbers of EGF receptors, are inhibited by EGF. Here we demonstrate that growth inhibition by EGF in several cell lines correlates with the activation of the signal transducer and activator of transcription (Stat) 1. In contrast, in normal fibroblasts and several cell lines that are growth stimulated by EGF, we observed no or very transient activation of Stat1. A causal association between Stat1 activation by EGF and growth inhibition was suggested by the expression of a dominant-negative Stat1 in A431 cells, resulting in the loss of Stat1 DNA binding and concomitant resistance to growth inhibition by EGF. We conclude that, in the cells examined, EGF-induced arrest of growth requires activated Stat1.