Project description:Genome duplication in Leishmania major relies on DNA replication outside S phase

Project description:Faithful inheritance of the large eukaryotic genomes requires the orchestrated activation of multiple DNA replication origins. Although origin activation is mechanistically conserved among eukaryotes, how replication origins are specified and selected for activation in each S-phase seem to differ across the model systems studied. Here we provide a complete analysis of the nucleosomal landscape and replication programme of the human parasite Leishmania major, building on a better evolutionary understanding of replication organization in Eukarya. We found that active transcription is a driving force for the nucleosomal organization of L. major genome, and that both the spatial and the temporal programme of DNA replication can be explained as associated to RNA polymerase kinetics, without the need to invoke specific regulatory mechanisms. This simple scenario likely provides these organisms with the flexibility and robustness to deal with the continuous environmental changes that impose alterations in their genetic programmes during their parasitic life cycle stages. Our findings also suggest that coupling replication initiation to transcription elongation could be an ancient solution used by eukaryotic cells for origin maintenance

Project description:Faithful inheritance of the large eukaryotic genomes requires the orchestrated activation of multiple DNA replication origins. Although origin activation is mechanistically conserved among eukaryotes, how replication origins are specified and selected for activation in each S-phase seem to differ across the model systems studied. Here we provide a complete analysis of the nucleosomal landscape and replication programme of the human parasite Leishmania major, building on a better evolutionary understanding of replication organization in Eukarya. We found that active transcription is a driving force for the nucleosomal organization of L. major genome, and that both the spatial and the temporal programme of DNA replication can be explained as associated to RNA polymerase kinetics, without the need to invoke specific regulatory mechanisms. This simple scenario likely provides these organisms with the flexibility and robustness to deal with the continuous environmental changes that impose alterations in their genetic programmes during their parasitic life cycle stages. Our findings also suggest that coupling replication initiation to transcription elongation could be an ancient solution used by eukaryotic cells for origin maintenance Replication intitiation sites were defined using two replicates of short nascent strands of increasing sizes (F4 and F5) purified through three rounds of Lambda-exonuclease digestion, and a genomic DNA control (Ctrl). Nucleosome landscape was determined using two replicates of mononucleosomal-DNA derived from MNase-digested chromatin

Project description:Gamma-glutamylcysteine synthetase encoded by GSH1 is the rate-limiting enzyme in the biosynthesis of glutathione and trypanothione in Leishmania. Attempts to generate GSH1 null mutants by gene disruption failed in Leishmania infantum. Removal of even a single allele invariably led to the generation of an extra copy of GSH1, maintaining two intact wild-type alleles. In the second and even third round of inactivation, the markers integrated at the homologous locus but always preserved two intact copies of GSH1. We probed into the mechanism of GSH1 duplication. GSH1 is subtelomeric on chromosome 18 and Southern blot analysis indicated that a 10-kb fragment flanked by 466-bp direct repeated sequences was duplicated in tandem on the same chromosomal allele each time GSH1 was targeted. Polymerase chain reaction analysis and sequencing confirmed the generation of novel junctions created at the level of the 466-bp repeats consequent to locus duplication. In loss of heterozygosity attempts, the same repeated sequences were utilized for generating extrachromosomal circular amplicons. Our results are consistent with break-induced replication as a mechanism for the generation of this regional polyploidy to compensate for the inactivation of an essential gene. This chromosomal repeat expansion through repeated sequences could be implicated in locus duplication in Leishmania.

Project description:RAD6 is known to suppress duplication-mediated gross chromosomal rearrangements (GCRs) but not single-copy sequence mediated GCRs. Here, we found that the RAD6- and RAD18-dependent post-replication repair (PRR) and the RAD5-, MMS2-, UBC13-dependent error-free PRR branch acted in concert with the replication stress checkpoint to suppress duplication-mediated GCRs formed by homologous recombination (HR). The Rad5 helicase activity, but not its RING finger, was required to prevent duplication-mediated GCRs, although the function of Rad5 remained dependent upon modification of PCNA at Lys164. The SRS2, SGS1, and HCS1 encoded helicases appeared to interact with Rad5, and epistasis analysis suggested that Srs2 and Hcs1 act upstream of Rad5. In contrast, Sgs1 likely functions downstream of Rad5, potentially by resolving DNA structures formed by Rad5. Our analysis is consistent with models in which PRR prevents replication damage from becoming double strand breaks (DSBs) and/or regulates the activity of HR on DSBs.

Project description:Transcriptional analysis of the drug resistant strain L. major MTX60.4 compared to the wild-type strain LV39 The full-genome DNA microarrays includes one 70-oligonucleotides probe for each gene of L.major LV39 Keywords: drug resistance

Project description:Leishmania major Genome sequencing

Project description:Base J represses genes at the end of polycistronic gene clusters in Leishmania major by promoting RNAP II termination [small RNA-seq]

Project description:Transcriptional analysis of Leishmania major methotrexate resistant strains using full-genome DNA microarrays

Project description:Base J represses genes at the end of polycistronic gene clusters in Leishmania major by promoting RNAP II termination [RNA-seq]