Yasushi Saka

Fission yeast cut3 and cut14, members of a ubiquitous protein family, are required for chromosome condensation and segregation in mitosis.

Fission yeast temperature‐sensitive mutants cut3‐477 and cut14‐208 fail to condense chromosomes but small portions of the chromosomes can separate along the spindle during mitosis, producing phi‐shaped chromosomes. Septation and cell division occur in the absence of normal nuclear division, causing the cut phenotype. Fluorescence in situ hybridization demonstrated that the contraction of the chromosome arm during mitosis was defective. Mutant chromosomes are apparently not rigid enough to be transported poleward by the spindle. Loss of the cut3 protein by gene disruption fails to maintain the nuclear chromatin architecture even in interphase. Both cut3 and cut14 proteins contain a putative nucleoside triphosphate (NTP)‐binding domain and belong to the same ubiquitous protein family which includes the budding yeast Smc1 protein. The cut3 mutant was suppressed by an increase in the cut14+ gene dosage. The cut3 protein, having the highest similarity to the mouse protein, is localized in the nucleus throughout the cell cycle. Plasmids carrying the DNA topoisomerase I gene partly suppressed the temperature sensitive phenotype of cut3‐477, suggesting that the cut3 protein might be involved in chromosome DNA topology.

Fission yeast cut5+, required for S phase onset and M phase restraint, is identical to the radiation-damage repair gene rad4+

Fission yeast cut5 mutants cause cytokinesis in the absence of normal nuclear division. We show here that cut5+ is required for both the onset of S phase and the restraint of M phase before the completion of S phase. The primary defects in cut5 mutants occur prior to S phase, but cells suffer lethal damage during M phase. Mitosis and cytokinesis occur in the presence of hydroxyurea or in the double mutant cdc10-cut5 (the cdc10 mutation alone blocks progression from G1 to S). Gene cloning shows that cut5+ is identical to the fission yeast rad4+ gene, which is similar to human XRCC1. The rad4+/cut5+ gene is unique in its positive role for replication/repair and in its negative role for mitosis/cytokinesis. We propose a single/twin chromatid marking model for rad4+/cut5+ function in cell cycle control.

A mechanism regulating the onset of Sox2 expression in the embryonic neural plate.

In vertebrate embryos, the earliest definitive marker for the neural plate, which will give rise to the entire central nervous system, is the transcription factor Sox2. Although some of the extracellular signals that regulate neural plate fate have been identified, we know very little about the mechanisms controlling Sox2 expression and thus neural plate identity. Here, we use electroporation for gain- and loss-of-function in the chick embryo, in combination with bimolecular fluorescence complementation, two-hybrid screens, chromatin immunoprecipitation, and reporter assays to study protein interactions that regulate expression of N2, the earliest enhancer of Sox2 to be activated and which directs expression to the largest part of the neural plate. We show that interactions between three coiled-coil domain proteins (ERNI, Geminin, and BERT), the heterochromatin proteins HP1α and HP1γ acting as repressors, and the chromatin-remodeling enzyme Brm acting as activator control the N2 enhancer. We propose that this mechanism regulates the timing of Sox2 expression as part of the process of establishing neural plate identity.

Fission yeast cut5 links nuclear chromatin and M phase regulator in the replication checkpoint control.

Fission yeast temperature‐sensitive cut5 (cell untimely torn) mutants are defective in initiation and/or elongation of DNA replication but allow mitosis and cell division at a restrictive temperature. We show that the cut5 protein (identical to rad4) (i) is an essential component of the replication checkpoint system but not the DNA damage checkpoint, and (ii) negatively regulates the activation of M phase kinase at mitotic entry. Even if the replication checkpoint has been activated previously, cut5 mutations allow mitosis and cell division after shift to 36 degrees C. Transcription of cut5+ is not under the control of the START gene cdc10+. The cut5 protein is enriched in the nucleus, consisting of repeating domains. An essential domain which resembles the proto‐oncoprotein Ect2 has a strong negative effect on the entry into mitosis when overexpressed. Expression of the cut5 mutant phenotype requires the function of the M phase regulator genes cdc2+, cdc25+ and cdc13+. The cut5 protein forms a novel, essential link between DNA synthesis and M phase activation in the replication checkpoint control pathway.

Nuclear accumulation of Smad complexes occurs only after the midblastula transition in Xenopus

Activin and the Nodal-related proteins induce mesendodermal tissues during Xenopus development. These signals act through specific receptors to cause the phosphorylation, at their carboxyl termini, of Smad2 and Smad3. The phosphorylated Smad proteins form heteromeric complexes with Smad4 and translocate into the nucleus to activate the transcription, after the midblastula transition, of target genes such as Xbra and goosecoid (gsc). In this paper we use bimolecular fluorescence complementation (BiFC) to study complex formation between Smad proteins both in vivo and in response to exogenous proteins. The technique has allowed us to detect Smad2-Smad4 heteromeric interactions during normal Xenopus development and Smad2 and Smad4 homo- and heteromers in isolated Xenopus blastomeres. Smad2-Smad2 and Smad2-Smad4 complexes accumulate rapidly in the nuclei of responding cells following Activin treatment, whereas Smad4 homomeric complexes remain cytoplasmic. When cells divide, Smad2-Smad4 complexes associate with chromatin, even in the absence of ligand. Our observation that Smad2-Smad4 complexes accumulate in the nucleus only after the midblastula transition, irrespective of the stage at which cells were treated with Activin, may shed light on the mechanisms of developmental timing.

A screen for targets of the Xenopus T-box gene Xbra.

Brachyury (T), a member of the T-box gene family, is essential for the formation of posterior mesoderm and notochord in vertebrate development. Expression of the Xenopus homologue of Brachyury, Xbra, causes ectopic ventral and lateral mesoderm formation in animal cap explants and co-expression of Xbra with Pintallavis, a forkhead/HNF3beta-related transcription factor, induces notochord. Although eFGF and the Bix genes are thought to be direct targets of Xbra, no other target genes have been identified. Here, we describe the use of hormone-inducible versions of Xbra and Pintallavis to construct cDNA libraries enriched for targets of these transcription factors. Five putative targets were isolated: Xwnt11, the homeobox gene Bix1, the zinc-finger transcription factor Xegr-1, a putative homologue of the antiproliferative gene BTG1 called Xbtg1, and BIG3/1A11, a gene of unknown function. Expression of Xegr-1 and Xbtg1 is controlled by Pintallavis alone as well as by a combination of Xbra and Pintallavis. Overexpression of Xbtg1 perturbed gastrulation and caused defects in posterior tissues and in notochord and muscle formation, a phenotype reminiscent of that observed with a dominant-negative version of Pintallavis called Pintallavis-En(R). The Brachyury-inducible genes we have isolated shed light on the mechanism of Brachyury function during mesoderm formation. Specification of mesodermal cells is regulated by targets including Bix1-4 and eFGF, while gastrulation movements and perhaps cell division are regulated by Xwnt11 and Xbtg1.

A mechanism for the sharp transition of morphogen gradient interpretation in Xenopus

BackgroundOne way in which positional information is established during embryonic development is through the graded distribution of diffusible morphogens. Unfortunately, little is known about how cells interpret different concentrations of morphogen to activate different genes or how thresholds are generated in a morphogen gradient.ResultsHere we show that the concentration-dependent induction of the T-box transcription factor Brachyury (Xbra) and the homeobox-containing gene Goosecoid (Gsc) by activin in Xenopus can be explained by the dynamics of a simple network consisting of three elements with a mutual negative feedback motif that can function to convert a graded signal (activin) into a binary output (Xbra on and Gsc off, or vice versa). Importantly, such a system can display sharp thresholds. Consistent with the predictions of our model, Xenopus ectodermal cells display a binary response at the single cell level after treatment with activin.ConclusionThis kind of simple network with mutual negative feedback might provide a general mechanism for selective gene activation in response to different levels of a single external signal. It provides a mechanism by which a sharp boundary might be created between domains of different cell types in response to a morphogen gradient.

Coupling of DNA replication and mitosis by fission yeast rad4/cut5

SUMMARY The fission yeast cut5+ (identical to rad4+) gene is essential for S phase. Its temperature-sensitive (ts) mutation causes mitosis while S phase is inhibited: dependence of mitosis upon the completion of S phase is abolished. If DNA is damaged in mutant cells, however, cell division is arrested. Thus the checkpoint control system for DNA damage is functional, while that for DNA synthesis inhibition is not in the cut5 mutants. Transcription of the cut5+ gene is not under the direct control of cdc10+, which encodes a transcription factor for the START of cell cycle. The transcript level does not change during the cell cycle. The protein product has four distinct domains and is enriched in the nucleus. Its level does not alter during the cell cycle. The N-domain is important for cut5 protein function: it is essential for complementation of ts cut5 mutations and its overexpression blocks cell division. Furthermore, it resembles the N-terminal repeat domain of proto-oncoprotein Ect2, which, in the C-domain, contains a regulator-like sequence for small G proteins. We discuss a hypothesis that the cut5 protein is an essential component of the checkpoint control system for the completion of DNA synthesis. The restraint of mitosis until the completion of S phase is mediated by the cut5 protein, which can sense the state of chromosome duplication and negatively interacts with M phase regulators such as cdc25 and cdc2.

Visualizing protein interactions by bimolecular fluorescence complementation in Xenopus.

Bimolecular fluorescence complementation (BiFC) provides a simple and direct way to visualise protein-protein interactions in vivo and in real-time. In this article, we describe methods by which one can implement this approach in embryos of the South African claw-toed frog Xenopus laevis. We have made use of Venus, an improved version of yellow fluorescent protein (YFP), so as to achieve rapid detection of protein interactions. To suppress spontaneous interactions between the N- and C-terminal fragments of Venus, a point mutation (T153M) was introduced into the N-terminal fragment. We have used this reagent to monitor signalling by members of the transforming growth factor type beta family in cells of the Xenopus embryo.

Understanding how morphogens work

In this article, we describe the mechanisms by which morphogens in the Xenopus embryo exert their long-range effects. Our results are consistent with the idea that signalling molecules such as activin and the nodal-related proteins traverse responding tissue not by transcytosis or by cytonemes but by movement through the extracellular space. We suggest, however, that additional experiments, involving real-time imaging of morphogens, are required for a real understanding of what influences signalling range and the shape of a morphogen gradient.