The fission yeast clade, comprising Schizosaccharomyces pombe, S. octosporus, S. cryophilus and S. japonicus, occupies the basal branch of Ascomycete fungi and is an important model of eukaryote biology. A comparative annotation of these genomes identified a near extinction of transposons and the associated innovation of transposon-free centromeres. Expression analysis established that meiotic genes are subject to antisense transcription during vegetative growth, suggesting a mechanism for their tight regulation. In addition, trans-acting regulators control new genes within the context of expanded functional modules for meiosis and stress response. Differences in gene content and regulation also explain why, unlike the Saccharomycotina, fission yeasts cannot use ethanol as a primary carbon source. These analyses elucidate the genome structure and gene regulation of fission yeast and provide tools for investigation across the Schizosaccharomyces clade.
Structure chromosome (SMC) proteins organize the core of cohesin, condensin and Smc5-Smc6 complexes. The Smc5-Smc6 complex is required for DNA repair, as well as having another essential but enigmatic function. Here, we generated conditional mutants of SMC5 and SMC6 in budding yeast, in which the essential function was affected. We show that mutant smc5-6 and smc6-9 cells undergo an aberrant mitosis in which chromosome segregation of repetitive regions is impaired; this leads to DNA damage and RAD9-dependent activation of the Rad53 protein kinase. Consistent with a requirement for the segregation of repetitive regions, Smc5 and Smc6 proteins are enriched at ribosomal DNA (rDNA) and at some telomeres. We show that, following Smc5-Smc6 inactivation, metaphase-arrested cells show increased levels of X-shaped DNA (Holliday junctions) at the rDNA locus. Furthermore, deletion of RAD52 partially suppresses the temperature sensitivity of smc5-6 and smc6-9 mutants. We also present evidence showing that the rDNA segregation defects of smc5/smc6 mutants are mechanistically different from those previously observed for condensin mutants. These results point towards a role for the Smc5-Smc6 complex in preventing the formation of sister chromatid junctions, thereby ensuring the correct partitioning of chromosomes during anaphase.
The developmental program of cell-type switching of S. pombe requires a strand-specific imprinting event at the mating-type locus (mat1). Imprinting occurs only when mat1 is replicated in a specific direction and requires several trans-acting factors. This work shows (1) that the factors swi1p and swi3p act by pausing the replication fork at the imprinting site; and (2) that swi1p and swi3p are involved in termination at the mat1-proximal polar-terminator of replication (RTS1). A genetic screen to identify termination factors identified an allele that separated pausing/imprinting and termination functions of swip. These results suggest that swi1p and swi3p promote imprinting in novel ways both by pausing replication at mat1 and by terminating replication at RTS1.
The LAGLIDADG and HNH families of site-specific DNA endonucleases encoded by viruses, bacteriophages as well as archaeal, eucaryotic nuclear and organellar genomes are characterized by the sequence motifs 'LAGLIDADG' and 'HNH', respectively. These endonucleases have been shown to occur in different environments: LAGLIDADG endonucleases are found in inteins, archaeal and group I introns and as free standing open reading frames (ORFs); HNH endonucleases occur in group I and group II introns and as ORFs. Here, statistical models (hidden Markov models, HMMs) that encompass both the conserved motifs and more variable regions of these families have been created and employed to characterize known and potential new family members. A number of new, putative LAGLIDADG and HNH endonucleases have been identified including an intein-encoded HNH sequence. Analysis of an HMM-generated multiple alignment of 130 LAGLIDADG family members and the three-dimensional structure of the I- Cre I endonuclease has enabled definition of the core elements of the repeated domain (approximately 90 residues) that is present in this family of proteins. A conserved negatively charged residue is proposed to be involved in catalysis. Phylogenetic analysis of the two families indicates a lack of exchange of endonucleases between different mobile elements (environments) and between hosts from different phylogenetic kingdoms. However, there does appear to have been considerable exchange of endonuclease domains amongst elements of the same type. Such events are suggested to be important for the formation of elements of new specficity.
The fission yeast Schizosaccharomyces pombe normally has haploid cells of two mating types, which differ at the chromosomal locus mat1. After two consecutive asymmetric cell divisions, only one in four 'grand-daughter' cells undergoes a 'mating-type switch', in which genetic information is transferred to mat1 from the mat2-P or mat3-M donor loci. This switching pattern probably results from an imprinting event at mat1 that marks one sister chromatid in a strand-specific manner, and is related to a site-specific, double-stranded DNA break at mat1. Here we show that the genetic imprint is a strand-specific, alkali-labile DNA modification at mat1. The DNA break is an artefact, created from the imprint during DNA purification. We also propose and test the model that mat1 is preferentially replicated by a centromere-distal origin(s), so that the strand-specific imprint occurs only during lagging-strand synthesis. Altering the origin of replication, by inverting mat1 or introducing an origin of replication, affects the imprinting and switching efficiencies in predicted ways. Two-dimensional gel analysis confirmed that mat1 is preferentially replicated by a centromere-distal origin(s). Thus, the DNA replication machinery may confer different developmental potential to sister cells.
Inteins are protein-splicing elements, most of which contain conserved sequence blocks that define a family of homing endonucleases. Like group I introns that encode such endonucleases, inteins are mobile genetic elements. Recent crystallography and computer modeling studies suggest that inteins consist of two structural domains that correspond to the endonuclease and the protein-splicing elements. To determine whether the bipartite structure of inteins is mirrored by the functional independence of the protein-splicing domain, the entire endonuclease component was deleted from the Mycobacterium tuberculosis recA intein. Guided by computer modeling studies, and taking advantage of genetic systems designed to monitor intein function, the 440-aa Mtu recA intein was reduced to a functional mini-intein of 137 aa. The accuracy of splicing of several mini-inteins was verified. This work not only substantiates structure predictions for intein function but also supports the hypothesis that, like group I introns, mobile inteins arose by an endonuclease gene invading a sequence encoding a small, functional splicing element.Inteins are protein-splicing elements that exist as in-frame fusions with flanking protein sequences called exteins. Inteins are self-splicing at the protein level, with their excision being coupled to extein ligation (1-3). Most of the inteins that have been described are in the 400-to 500-aa range with little absolute sequence conservation among the elements (4, 5). However, Cys or Ser residues are required at the amino termini of both the intein and the second extein, and a His and Asn are present at the carboxy terminus of the intein (Fig. 1A Top). Most inteins contain eight conserved sequence blocks (A-H), two of these being the LAGLIDADG motifs (blocks C and E) that define a family of intron-homing endonucleases (refs. 4 and 5; Fig. 1 A). Consistent with the occurrence of these motifs, several inteins have been shown to have site-specific endonuclease activity (6), and PI-SceI, the VMA1 intein of Saccharomyces cerevisiae, is capable of homing into a cognate inteinless allele (7). The sporadic distribution of inteins in all three biological kingdoms is consistent with their being mobile elements.Endonuclease genes have been assumed to be invasive genetic elements that colonized group I introns, converting them into mobile genetic elements (8-11). Similarly, mobile inteins appear to be derived from invasive endonuclease genes. Recent structural studies indeed suggest that the proteinsplicing and endonuclease domains are separate and that their two activities may have evolved independently. First, the crystal structure of PI-SceI has recently been solved (12). This 454-aa protein is folded into two distinct structural domains. Second, hidden Markov models have been used to define two conserved functional domains of inteins, corresponding to independent endonuclease and splicing modules, separated by nonconserved spacer regions of variable lengths (ref. 13; J.Z.D., A. Klar, M. J. Moser, W. R. H...
The Swi1 and Swi3 proteins are required for mat1 imprinting and mating-type switching in Schizosaccharomyces pombe, where they mediate a pause of leading-strand replication in response to a lagging-strand signal. In addition, Swi1 has been demonstrated to be involved in the checkpoint response to stalled replication forks, as was described for the Saccharomyces cerevisiae homologue Tof1. This study addresses the roles of Swi1 and Swi3 during a replication process perturbed by the presence of template bases alkylated by methyl methanesulfonate (MMS). Both the swi1 and swi3 mutations have additive effects on MMS sensitivity and on the MMS-induced damage checkpoint response when combined with chk1 and cds1, but they are nonadditive with hsk1. Cells with swi1, swi3, or hsk1 mutations are also defective in slowing progression through S phase in response to MMS damage. Moreover, swi1 and swi3 strains show increased levels of genomic instability even in the absence of exogenously induced DNA damage. Chromosome fragmentation, increased levels of singlestranded DNA, increased recombination, and instability of replication forks stalled in the presence of hydroxyurea are observed, consistent with the possibility that the replication process is affected in these mutants. In conclusion, Swi1, Swi3, and Hsk1 act in a novel S-phase checkpoint pathway that contributes to replication fork maintenance and to survival of alkylation damage.
Mating-type switching in Schizosaccharomyces pombe involves a strand-specific, alkali-labile imprint at the mat1 (mating-type) locus. The imprint is synthesized during replication in a swi1, swi3, and polymerase ␣ (swi7) dependent manner and is dependent on mat1 being replicated in a specific direction. Here we show that the direction of replication at mat1 is controlled by a cis-acting polar terminator of replication (RTS1). Two-dimensional gel analysis of replication intermediates reveals that RTS1 only terminates replication forks moving in the centromere-distal direction. A genetic analysis shows that RTS1 optimizes the imprinting process. Transposing the RTS1 element to the distal side of mat1 abolishes imprinting of the native mat1 allele but restores imprinting of an otherwise unimprinted inverted mat1 allele. These data provide conclusive evidence for the "direction of replication model" that explains the asymmetrical switching pattern of S. pombe, and identify a DNA replication-arrest element implicated in a developmental process. Such elements could play a more general role during development and differentiation in higher eukaryotes by regulating the direction of DNA replication at key loci.
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