[Correlations of sister chromatids cohesion complexes distribution with histones H3 and H4 modifications].

The formulation of "histone code" theory brings active investigations of the role of histone modifications and other supramolecular factors of DNA condensation in transcription regulation. In this work, we have analyzed the localization of methylated histones on 9, 36 and 79 lysines, hyperacetylated H4 histone, and subunits of cohesion complex DRAD21 relatively of Drosophila melanogaster polytene chromosomes chromatin condensation. We propose the hypotheses of a cascade regulation of transcription activity defined by histone modifications and the adaptive role of sister chromatids cohesion in the transcription of high active and extensive genes.

[Functional characteristics of the individual genomic condensin binding sites of Saccharomyces cerevisiae using minichromosome mitotic segregation stability model].

Proper chromatin compaction in mitosis (condensation) is required for equal chromosome distribution and precise genetic information inheritance. Protein complex named condensin is responsible for the mitotic condensation, it also individualizes chromosomes, and ensures chromatin separation between sister chromatids in mitosis as well as proper mitotic spindle tension. Mitotic condensin function depends on recognition of the specific binding sites on the chromosome. Mechanism of condensin binding on the individual sites of the mitotic chromosomes, as well as molecular anatomy of these sites remains to be unclear. Even less known is how condensin binding on the individual sites helps separating chromosomes in anaphase. In current paper using minichromosome test, we analyze seven individual condensin binding sites in Saccharomyces cerevisiae found in previous all-genome CHIP on CHIP screening in our lab. This approach allowed us to find out what was the individual contribution of condensin binding sites in securing mitotic stability of the minichromosomes.

The promyelocytic leukemia protein stimulates SUMO conjugation in yeast.

The promyelocytic leukemia gene was first identified through its fusion to the gene encoding the retinoic acid receptor alpha (RARalpha) in acute promyelocytic leukemia (APL) patients. The promyelocytic leukemia gene product (PML) becomes conjugated in vivo to the small ubiquitin-like protein SUMO-1, altering its behavior and capacity to recruit other proteins to PML nuclear bodies (PML-NBs). In the NB4 cell line, which was derived from an APL patient and expresses PML:RARalpha, we observed a retinoic acid-dependent change in the modification of specific proteins by SUMO-1. To dissect the interaction of PML with the SUMO-1 modification pathway, we used the budding yeast Saccharomyces cerevisiae as a model system through expression of PML and human SUMO-1 (hSUMO-1). We found that PML stimulated hSUMO-1 modification in yeast, in a manner that was dependent upon PML's RING-finger domain. PML:RARalpha also stimulated hSUMO-1 conjugation in yeast. Interestingly, however, PML and PML:RARalpha differentially complemented yeast Smt3p conjugation pathway mutants. These findings point toward a potential function of PML and PML:RARalpha as SUMO E3 enzymes or E3 regulators, and suggest that fusion of RARalpha to PML may affect this activity.

[Localization of cohesin complexes of polytene chromosomes of Drosophila melanogaster located on interbands]. / Lokalizatsiia kompleksov kogezii v politennykh khromosomakh Drosophila melanogaster sviazana s mezhdiskami.

The distribution of cohesin complex in polytene chromosomes of Drosophila melanogaster was studied. Cohesin is a complicated protein complex which is regulated by the DRAD21 subunit. Using immunostaining for DRAD21p, the cohesins were shown to be preferentially located in the interband regions. This specificity was not characteristic for puffs, where uniform staining was observed. The presence of a few brightly fluorescent regions (five to ten per chromosome arm) enriched with cohesin complexes was shown. Some of these regions had permanent location, and the others, variable location. No antibody binding was detected in the chromocenter. Immunostaining of interphase nuclei of neuroblasts revealed large cohesin formations. On the polytene chromosomes of D. melanogaster, the Drad21 gene was mapped to the chromocentric region (81) of the L arm of chromosome 3.

Saccharomyces cerevisiae SMT4 encodes an evolutionarily conserved protease with a role in chromosome condensation regulation.

In a search for regulatory genes affecting the targeting of the condensin complex to chromatin in Saccharomyces cerevisiae, we identified a member of the adenovirus protease family, SMT4. SMT4 overexpression suppresses the temperature-sensitive conditional lethal phenotype of smc2-6, but not smc2-8 or smc4-1. A disruption allele of SMT4 has a prominent chromosome phenotype: impaired targeting of Smc4p-GFP to rDNA chromatin. Site-specific mutagenesis of the predicted protease active site cysteine and histidine residues of Smt4p abolishes the SMT4 function in vivo. The previously uncharacterized SIZ1 (SAP and Miz) gene, which encodes a protein containing a predicted DNA-binding SAP module and a Miz finger, is identified as a bypass suppressor of the growth defect associated with the SMT4 disruption. The SIZ1 gene disruption is synthetically lethal with the SIZ2 deletion. We propose that SMT4, SIZ1, and SIZ2 are involved in a novel pathway of chromosome maintenance.

Functional dissection of in vivo interchromosome association in Saccharomyces cerevisiae.

Homologue pairing mediates both recombination and segregation of chromosomes at meiosis I. The recognition of nucleic-acid-sequence homology within the somatic nucleus has an impact on DNA repair and epigenetic control of gene expression. Here we investigate interchromosomal interactions using a non-invasive technique that allows tagging and visualization of DNA sequences in vegetative and meiotic live yeast cells. In non-meiotic cells, chromosomes are ordered in the nucleus, but preferential pairing between homologues is not observed. Association of tagged chromosomal domains occurs irrespective of their genomic location, with some preference for similar chromosomal positions. Here we describe a new phenomenon that promotes associations between sequence-identical ectopic tags with a tandem-repeat structure. These associations, termed interchromosome trans-associations, may underlie epigenetic phenomena.

Structural maintenance of chromosomes (SMC) proteins: conserved molecular properties for multiple biological functions.

The evolutionarily-conserved eukaryotic SMC (structural maintenance of chromosomes) proteins are ubiquitous chromosomal components in prokaryotes and eukaryotes. The eukaryotic SMC proteins form two kind of heterodimers: the SMC1/SMC3 and the SMC2/SMC4 types. These heterodimers constitute an essential part of higher order complexes, which are involved in chromatin and DNA dynamics. The two most prominent and best-characterized complexes are cohesin and condensin, necessary for sister chromatid cohesion and chromosome condensation. Here we discuss these functions together with additional roles in gene dosage compensation and DNA recombination.

SMC proteins and chromosome structure.

The structure of chromosomes is largely determined by chromosome-associated proteins. Members of the SMC (structural maintenance of chromosomes) family play an important role in both prokaryotic and eukaryotic chromosome structure and dynamics. SMC proteins are involved in chromosome condensation, sister-chromatid cohesion, sex-chromosome dosage compensation, genetic recombination and DNA repair. There have been major advances recently in understanding the function of SMC proteins--including the identification of biochemical activities of SMC-containing protein complexes and the realization that individual SMC proteins might link seemingly unrelated aspects of chromosomal metabolism.

Subcellular localization of Bacillus subtilis SMC, a protein involved in chromosome condensation and segregation.

We have investigated the subcellular localization of the SMC protein in the gram-positive bacterium Bacillus subtilis. Recent work has shown that SMC is required for chromosome condensation and faithful chromosome segregation during the B. subtilis cell cycle. Using antibodies against SMC and fluorescence microscopy, we have shown that SMC is associated with the chromosome but is also present in discrete foci near the poles of the cell. DNase treatment of permeabilized cells disrupted the association of SMC with the chromosome but not with the polar foci. The use of a truncated smc gene demonstrated that the C-terminal domain of the protein is required for chromosomal binding but not for the formation of polar foci. Regular arrays of SMC-containing foci were still present between nucleoids along the length of aseptate filaments generated by depleting cells of the cell division protein FtsZ, indicating that the formation of polar foci does not require the formation of septal structures. In slowly growing cells, which have only one or two chromosomes, SMC foci were principally observed early in the cell cycle, prior to or coincident with chromosome segregation. Cell cycle-dependent release of stored SMC from polar foci may mediate segregation by condensation of chromosomes.

SMC2, a Saccharomyces cerevisiae gene essential for chromosome segregation and condensation, defines a subgroup within the SMC family.

We characterized the SMC2 (structural maintenance of chromosomes) gene that encodes a new Saccharomyces cerevisiae member of the growing family of SMC proteins. This family of evolutionary conserved proteins was introduced with identification of SMC1, a gene essential for chromosome segregation in budding yeast. The analysis of the putative structure of the Smc2 protein (Smc2p) suggests that it defines a distinct subgroup within the SMC family. This subgroup includes the ScII, XCAPE, and cut14 proteins characterized concurrently. Smc2p is a nuclear, 135-kD protein that is essential for vegetative growth. The temperature-sensitive mutation, smc2-6, confers a defect in chromosome segregation and causes partial chromosome decondensation in cells arrested in mitosis. The Smc2p molecules are able to form complexes in vivo both with Smc1p and with themselves, suggesting that they can assemble into a multimeric structure. In this study we present the first evidence that two proteins belonging to two different subgroups within the SMC family carry nonredundant biological functions. Based on genetic, biochemical, and evolutionary data we propose that the SMC family is a group of prokaryotic and eukaryotic chromosomal proteins that are likely to be one of the key components in establishing the ordered structure of chromosomes.

CEP3 encodes a centromere protein of Saccharomyces cerevisiae.

We have designed a screen to identify mutants specifically affecting kinetochore function in the yeast Saccharomyces cerevisiae. The selection procedure was based on the generation of "synthetic acentric" minichromosomes. "Synthetic acentric" minichromosomes contain a centromere locus, but lack centromere activity due to combination of mutations in centromere DNA and in a chromosomal gene (CEP) encoding a putative centromere protein. Ten conditional lethal cep mutants were isolated, seven were found to be alleles of NDC10 (CEP2) encoding the 110-kD protein of yeast kinetochore. Three mutants defined a novel essential gene CEP3. The CEP3 product (Cep3p) is a 71-kD protein with a potential DNA-binding domain (binuclear Zn-cluster). At nonpermissive temperature the cep3 cells arrest with an undivided nucleus and a short mitotic spindle. At permissive temperature the cep3 cells are unable to support segregation of minichromosomes with mutations in the central part of element III of yeast centromere DNA. These minichromosomes, when isolated from cep3 cultures, fail to bind bovine microtubules in vitro. The sum of genetic, cytological and biochemical data lead us to suggest that the Cep3 protein is a DNA-binding component of yeast centromere. Molecular mass and sequence comparison confirm that Cep3p is the p64 component of centromere DNA binding complex Cbf3 (Lechner, 1994).

SMC1: an essential yeast gene encoding a putative head-rod-tail protein is required for nuclear division and defines a new ubiquitous protein family.

The smc1-1 mutant was identified initially as a mutant of Saccharomyces cerevisiae that had an elevated rate of minichromosome nondisjunction. We have cloned the wild-type SMC1 gene. The sequence of the SMC1 gene predicts that its product (Smc1p) is a 141-kD protein, and antibodies against Smc1 protein detect a protein with mobility of 165 kD. Analysis of the primary and putative secondary structure of Smc1p suggests that it contains two central coiled-coil regions flanked by an amino-terminal nucleoside triphosphate (NTP)-binding head and a conserved carboxy-terminal tail. These analyses also indicate that Smc1p is an evolutionary conserved protein and is a member of a new family of proteins ubiquitous among prokaryotes and eukaryotes. The SMC1 gene is essential for viability. Several phenotypic characteristics of the mutant alleles of smc1 gene indicate that its product is involved in some aspects of nuclear metabolism, most likely in chromosome segregation. The smc1-1 and smc1-2 mutants have a dramatic increase in mitotic loss of a chromosome fragment and chromosome III, respectively, but have no increase in mitotic recombination. Depletion of SMC1 function in the ts mutant, smc1-2, causes a dramatic mitosis-related lethality. Smc1p-depleted cells have a defect in nuclear division as evidenced by the absence of anaphase cells. This phenotype of the smc1-2 mutant is not RAD9 dependent. Based upon the facts that Smc1p is a member of a ubiquitous family, and it is essential for yeast nuclear division, we propose that Smc1p and Smc1p-like proteins function in a fundamental aspect of prokaryotic and eukaryotic cell division.

A direct selection procedure for isolating yeast mutants with an impaired segregation of artificial minichromosomes.

The nondisjunction of artificial yeast minichromosomes (2:0 segregation events) during mitosis is accompanied by the appearance of cells containing more than one copy of the minichromosome. A mathematical simulation of this process has demonstrated that under certain conditions, a nondisjunction of the minichromosomes may result in their accumulation in a considerable portion of the cell population. An increase in the copy number of artificial minichromosomes as a result of impaired segregation has been used to develop a new experimental procedure for directly selecting yeast mutants showing an impaired segregation of artificial minichromosomes during mitosis. Four new genes, AMC1, AMC2, AMC3, and AMC4, which control the segregation of artificial minichromosomes in mitosis, have been identified (AMC3 and AMC4 are mapped to chromosome IV and VII, respectively). Mutations in the genes AMC1-AMC4 also affect the mitotic transmission of natural chromosomes. We suggest that the genes AMC1, AMC2, AMC3, and AMC4 control the segregation of natural chromosomes in yeast.