Project description:Leishmania major Genome sequencing

Project description:Leishmania major: Sir2rp3 overexpressor vs wild-type

Project description:Leishmania major selfing analysis

Project description:Leishmania major promastigote ChIP-chip: TBP, SNAP50, acetylH3

Project description:Comparative Genomic Hybridization of Leishmania major SbIII resistant mutants and L. major WT

Project description:The genomic DNAs of strains JPCM5 and 263 of L. infantum, strains LV39 and Friedlin of L. major and strains Parrot-TarII and S125 of L. tarentolae were used in comparative genomic hybridizations to reveal the intra-species and inter-species gene content, and to validate L. tarentolae Parrot-TarII genome sequencing results. Leishmania (Sauroleishmania) tarentolae was first isolated in the lizard Tarentola mauritanica. This species is not known to be pathogenic to humans but is often used as a model organism for molecular analyses or protein overproduction. The Leishmania tarentolae Parrot-TarII strain genome sequence was resolved by high-throughput sequencing technologies. The L. tarentolae genome was first assembled de novo and then aligned against the reference L. major Friedlin genome to facilitate contig positioning and annotation, providing a 23-fold coverage of the genome. This is the first non-pathogenic to humans kinetoplastid protozoan genome to be described, and it provides an opportunity for comparison with the completed genomes of the pathogenic Leishmania species. A high synteny was observed in de novo assembled contigs between all sequenced Leishmania species. A number of limited chromosomal regions diverged between L. tarentolae and L. infantum, while remaining syntenic with L. major. Globally, over 90% of the L. tarentolae gene content was shared with the other Leishmania species. There were 250 L. major genes absent from L. tarentolae, and interestingly these missing genes were primarily expressed in the intracellular amastigote stage of the pathogenic parasites. This implies that L. tarentolae may have impaired ability to survive as an intracellular parasite. In contrast to other Leishmania genomes, two gene families were expanded in L. tarentolae, namely the leishmanolysin (GP63) and a gene related to the promastigote surface antigen (PSA31C). Overall, L. tarentolae appears to have a gene content more adapted to the insect stage rather than the mammalian one. This may partly explain its inability to replicate within mammalian macrophages and its suspected preferred life style as promastigote in the lizards.

Project description:Kinetoplastid-specific histone variant functions are conserved in Leishmania major

Project description:Murine bone marrow derived macrophages were infected with Leishmania major or Leishmania donovania promastigotes, allowed to phagocytose latex beads or not treated. Gene expression profiles were compared to identify i) the effect of Leishmania infection; ii) the differences in effects between L. major and L. donovani; and iii) the effect of pahgocytosis of latex beads.

Project description:We sought to identify nuclease-hypersensitive sites and to quantify nucleosome positions in an effort to identify cis-regulatory elements in the protozoan parasite Leishmania major. Using micrococcal nuclease digestion of chromatin (MNAse-seq), we report that few nuclease hypersensitive sites are present within the presumed regions of RNA polymerase II-mediated transcription initiation, and that similar numbers of nuclease hypersensitive sites were found in control datasets. However, utilizing an independent approach (FAIRE), we observe that a heterogeneous population of nuclease hypersensitive sites are present in and around these regions, and that nucleosomes within these regions are susceptible to MNAse overdigestion.

Project description:Leishmania major isolate:HUM1 Genome sequencing