Goosecoid promotes head organizer activity by direct repression of Xwnt8 in Spemann's organizer.

Formation of the vertebrate body plan is controlled by discrete head and trunk organizers that establish the anteroposterior pattern of the body axis. The Goosecoid (Gsc) homeodomain protein is expressed in all vertebrate organizers and has been implicated in the activity of Spemann's organizer in Xenopus. The role of Gsc in organizer function was examined by fusing defined transcriptional regulatory domains to the Gsc homeodomain. Like native Gsc, ventral injection of an Engrailed repressor fusion (Eng-Gsc) induced a partial axis, while a VP16 activator fusion (VP16-Gsc) did not, indicating that Gsc functions as a transcriptional repressor in axis induction. Dorsal injection of VP16-Gsc resulted in loss of head structures anterior to the hindbrain, while axial structures were unaffected, suggesting a requirement for Gsc function in head formation. The anterior truncation caused by VP16-Gsc was fully rescued by Frzb, a secreted Wnt inhibitor, indicating that activation of ectopic Wnt signaling was responsible, at least in part, for the anterior defects. Supporting this idea, Xwnt8 expression was activated by VP16-Gsc in animal explants and the dorsal marginal zone, and repressed by Gsc in Activin-treated animal explants and the ventral marginal zone. Furthermore, expression of Gsc throughout the marginal zone inhibited trunk formation, identical to the effects of Frzb and other Xwnt8 inhibitors. A region of the Xwnt8 promoter containing four consensus homeodomain-binding sites was identified and this region mediated repression by Gsc and activation by VP16-Gsc, consistent with direct transcriptional regulation of Xwnt8 by Gsc. Therefore, Gsc promotes head organizer activity by direct repression of Xwnt8 in Spemann's organizer and this activity is essential for anterior development.

TGF-beta signals and a pattern in Xenopus laevis endodermal development.

We have analyzed two gene products expressed in the early endoderm of Xenopus laevis: Xlhbox-8, a pancreas-specific transcription factor and intestinal fatty acid binding protein (IFABP), a marker of small intestinal epithelium. Expression of the pancreas marker relies on cell signaling mediated by both the TGF-beta and FGF classes of secreted peptide growth factors, whereas, expression of the more posterior small intestinal marker does not. Endodermal explants devoid of mesoderm express both markers in a regionalized manner. Cortical rotation is required for the expression of the more anterior marker, Xlhbox-8, but not for the small intestinal marker, IFABP. These findings suggest that endodermal patterning is dependent, in part, on the same events and signals known to play important roles in mesodermal development. Furthermore, inhibition of TGF-beta signaling in the endoderm leads to ectopic expression of both mesodermal and ectodermal markers, suggesting the TGF-beta signaling may play a general role in the segregation of the three embryonic germ layers.

Biochemical and biological analysis of Mek1 phosphorylation site mutants.

Recently, we described the constitutive activation of Mek1 by mutation of its two serine phosphorylation sites. We have now characterized the biochemical properties of these Mek1 mutants and performed microinjection experiments to investigate the effect of an activated Mek on oocyte maturation. Single acidic substitution of either serine 218 or 222 activated Mek1 by 10-50 fold. The double acidic substitutions, [Asp218, Asp222] and [Asp218, Glu222], activated Mek1 over 6000-fold. The specific activity of the [Asp218, Asp222] and [Asp218, Glu222] Mek1 mutants, 29 nanomole phosphate per minute per milligram, is similar to that of wild-type Mek1 activated by Raf-1 in vitro. Although the mutants with double acidic substitutions could not be further activated by Raf-1, three of those with single acidic substitution were activated by Raf-1 to the specific activity of activated wild-type Mek1. Injection of the [Asp218, Asp222] Mek1 mutant into Xenopus oocytes activated both MAP kinase and histone H1 kinase and induced germinal vesicle breakdown, an effect that was only partially blocked by inhibition of protein synthesis. These data provide a measure of Mek's potential to influence cell functions and a quantitative basis to assess the biological effects of Mek1 mutants in a variety of circumstances.

ISGF3, the transcriptional activator induced by interferon alpha, consists of multiple interacting polypeptide chains.

Interferon-stimulated gene factor 3 (ISGF3) is the ligand-dependent transcriptional activator that, in response to interferon treatment, is assembled in the cell cytoplasm, is translocated to the nucleus, and binds the consensus DNA site, the interferon-stimulated response element. We have purified ISGF3 and identified its constituent proteins: a DNA-binding protein of 48 kDa and three larger polypeptides (84, 91, and 113 kDa), which themselves do not have DNA-binding activity. The multisubunit structure of ISGF3 most likely reflects its participation in receiving a ligand-dependent signal, translocating to the nucleus, and binding to DNA to activate transcription.

Interferon-alpha regulates nuclear translocation and DNA-binding affinity of ISGF3, a multimeric transcriptional activator.

The interaction of interferon-alpha (IFN-alpha) with a specific cell-surface receptor elicits physiological changes that rely on rapid transcriptional activation of a group of IFN-alpha-stimulated genes (ISGs). The IFN-stimulated response element (ISRE), a conserved regulatory element of all ISGs, is the target for transcriptional activation by the positive regulator IFN-stimulated gene factor-3 (ISGF3). We reported previously that post-translational activation of ISGF3 in the cytoplasm of IFN-alpha-treated cells requires two cytoplasmic activities (ISGF3 alpha and ISGF3 gamma) to produce an ISRE-binding complex that accumulates in the nucleus. In this study, we show that these activities are actually distinct subunits of the ISGF3 complex, which associate through noncovalent interaction. Sedimentation analysis, protein renaturation, and photoaffinity cross-linking of enriched preparations of cytoplasmic ISGF3 alpha and ISGF3 gamma and of nuclear ISGF3 demonstrated that ISGF3 gamma was a 48-kD polypeptide with intrinsic, low-affinity DNA-binding activity. Four polypeptides of 48, 84, 91, and 113 kD bound to the ISRE in vitro; the larger three polypeptides most likely compose the ISGF3 alpha component. These ISGF3 alpha polypeptides were unable to bind DNA alone but formed a DNA-binding complex in conjunction with ISGF3 gamma. The resulting heteromeric complex had the same ISRE-binding specificity as the individual ISGF3 gamma polypeptide but approximately 25-fold higher affinity. Whereas ISGF3 gamma partitioned between the cytoplasm and nucleus in unstimulated cells, ISGF3 alpha was stimulated to translocate to the nucleus only following IFN-alpha treatment, resulting in preferential nuclear accumulation of both ISGF3 alpha and ISGF3 gamma as a stable ISGF3-ISRE complex. This regulated nuclear translocation of an activated transcription factor subunit maintained the specificity and rapidity of the IFN-alpha signaling pathway.

Purification and cloning of interferon-stimulated gene factor 2 (ISGF2): ISGF2 (IRF-1) can bind to the promoters of both beta interferon- and interferon-stimulated genes but is not a primary transcriptional activator of either.

Interferon-stimulated gene factor 2 (ISGF2) was purified from HeLa cells treated with alpha interferon. The factor, a single polypeptide of 56 kilodaltons (kDa), bound both to the central 9 base pairs of the 15-base-pair interferon-stimulated response element (ISRE) that is required for transcriptional activation of interferon-stimulated genes and to the PRD-I regulatory element of the beta interferon gene. ISGF2 was a phosphoprotein, and dephosphorylation in vitro reduced its DNA-binding activity. However, conditions that changed the amount of ISGF2 did not change the phosphorylated isoforms in vivo. ISGF2 in unstimulated cells existed in trace amounts and was induced by both alpha interferon and gamma interferon as well as by virus infection. Plasmid-bearing Escherichia coli clones encoding ISGF2 were selected with antibody against purified ISGF2. Sequence analysis revealed that the ISGF2 protein was the same as that encoded by the cDNA clone IRF-1, which has been claimed to activate transcription of interferon genes. We show that transcription of the ISGF2 gene was induced by alpha interferon, gamma interferon, and double-stranded RNA. However, ISGF2 was neither necessary nor sufficient for induced transcription of the beta interferon gene, while the factor NF kappa B was clearly involved.

Synergistic interaction between interferon-alpha and interferon-gamma through induced synthesis of one subunit of the transcription factor ISGF3.

Interferon-alpha (IFN alpha) and interferon-gamma (IFN gamma) each induce in susceptible target cells a state of resistance to viral replication and reduced cellular proliferation, presumably through different mechanisms: these two polypeptides are unrelated by primary sequence and act through distinct cell-surface receptors to induce expression of largely non-overlapping sets of genes. However, acting in concert, they can produce synergistic interactions leading to mutual reinforcement of the physiological response. In HeLa cells, this synergistic response was initiated by cooperative induction of IFN alpha stimulated genes (ISGs). These normally quiescent genes were rapidly induced to high rates of transcription following exposure of cells to IFN alpha. Although they were only negligibly responsive to IFN gamma, combined treatment of cells with IFN gamma followed by IFN alpha resulted in an approximately 10-fold increase in ISG transcription. ISG transcription is dependent upon ISGF3, a positive transcription factor specific for a cis-acting regulatory element in ISG promoters. IFN gamma treatment induced increased synthesis of latent ISGF3, which was subsequently activated in response to IFN alpha to form approximately 10-fold higher levels than detected in cells treated with IFN alpha alone. ISGF3 is composed of two distinct polypeptide components, synthesis of one of which was induced by IFN gamma, increasing its cellular abundance from limiting concentrations to a level which allowed formation of at least 10 times as much active ISGF3. Cell lines vary in their constitutive levels of the inducible component of ISGF3 and in the ability of IFNs to increase its synthesis.(ABSTRACT TRUNCATED AT 250 WORDS)

Cytoplasmic activation of ISGF3, the positive regulator of interferon-alpha-stimulated transcription, reconstituted in vitro.

The signal transduction pathway through which interferon-alpha (IFN alpha) stimulates transcription of a defined set of genes involves activation of DNA-binding factors specific for the IFN alpha-stimulated response element (ISRE). IFN-stimulated gene factor-3 (ISGF3), the positive regulator of transcription, was derived in response to IFN alpha treatment from preexisting protein components that were activated first in the cell cytoplasm prior to appearance in the nucleus. Nuclear translocation of ISGF3 required several minutes and could be inhibited by NaF. Formation of active ISGF3 was mimicked in vitro by mixing cytoplasmic extracts from IFN alpha-stimulated cells with extracts of cells treated to contain high amounts of the unactivated factor. Active ISGF3 was found to be formed from association of two latent polypeptide precursors that were distinguished biochemically by differential sensitivity to N-ethyl maleimide. One precursor was modified in response to IFN alpha occupation of its cell-surface receptor, thus enabling association with the second subunit. The resulting complex then was competent for nuclear translocation and binding to ISRE. Cytoplasmically localized transcription factor precursors thus serve as second messengers to translate directly an extracellular signal into specific transcriptional activity in the nucleus.