Project description:Metschnikowia zobellii (a marine yeast)

Project description:Metschnikowia zobellii (a marine yeast) genome assembly, gsMetZobe1, alternate haplotype

Project description:Metschnikowia zobellii (a marine yeast), genomic and transcriptomic data

Project description:Metschnikowia zobellii overview

Project description:This is genome-scale metabolic model of Candida albicans as the representative yeast species for the clade CUG-Ser1. This model was generated through homology search using a fungal pan-GEM largely based on Yeast8 for Saccharomyces cerevisiae, in addition to manual curation. This model has been produced by the Yeast-Species-GEMs project from Sysbio (www.sysbio.se). This is model version 1.0.0 accompanying the publication (DOI: 10.15252/msb.202110427), currently hosted on BioModels Database and identified by MODEL2109130014. Further curations of this model will be tracked in the GitHub repository: https://github.com/SysBioChalmers/Yeast-Species-GEMs Models for species of the same clade includes: Babjeviella inositovora; Candida albicans; Candida auris; Candida carpophila; Candida dubliniensis; Hyphopichia homilentoma; Candida intermedia; Candida orthopsilosis; Candida parapsilosis; Candida sojae; Suhomyces tanzawaensis; Yamadazyma tenuis; Candida tropicalis; Clavispora lusitaniae; Debaryomyces hansenii; Hyphopichia burtonii; Lodderomyces elongisporus; Metschnikowia aberdeeniae; Metschnikowia arizonensis; Metschnikowia bicuspidata var. bicuspidata; Metschnikowia borealis; Metschnikowia bowlesiae; Metschnikowia cerradonensis; Metschnikowia continentalis; Metschnikowia dekortorum; Metschnikowia drakensbergensis; Metschnikowia hamakuensis; Metschnikowia hawaiiensis; Metschnikowia hibisci; Metschnikowia ipomoeae; Metschnikowia kamakouana; Metschnikowia kipukae; Metschnikowia lochheadii; Metschnikowia matae var. matae; Metschnikowia matae var. maris; Metschnikowia mauinuiana; Metschnikowia proteae; Metschnikowia santaceciliae; Metschnikowia shivogae; Metschnikowia similis; Meyerozyma guilliermondii; Millerozyma acaciae; Priceomyces haplophilus; Scheffersomyces lignosus; Scheffersomyces stipitis; Spathaspora arborariae; Spathaspora girioi; Spathaspora gorwiae; Spathaspora hagerdaliae; Spathaspora passalidarum; Wickerhamia fluorescens; Priceomyces medius; Candida athensensis; Candida schatavii; Candida restingae; Aciculoconidium aculeatum; Kodamaea laetipori; Danielozyma ontarioensis; Candida oregonensis; Candida fructus; Candida corydali; Cephaloascus albidus; Cephaloascus fragrans; Suhomyces pyralidae; Suhomyces canberraensis; Suhomyces emberorum; Teunomyces kruisii; Teunomyces gatunensis; Teunomyces cretensis; Yamadazyma nakazawae; Priceomyces carsonii; Priceomyces castillae; Candida fragi; Hyphopichia heimii; Candida blattae; Yamadazyma philogaea; Yamadazyma scolyti; Meyerozyma caribbica; Kurtzmaniella cleridarum; Kodamaea ohmeri; Candida rhagii; Candida gotoi; Candida heveicola; Debaryomyces prosopidis; Debaryomyces nepalensis; Debaryomyces maramus; Candida hawaiiana; Debaryomyces subglobosus; Debaryomyces fabryi; Candida tammaniensis; Candida wancherniae; Candida ascalaphidarum; Candida golubevii; Candida gorgasii. These models are available in the zip file. To cite BioModels, please use: V Chelliah et al; BioModels: ten-year anniversary. Nucleic Acids Res 2015; 43 (D1): D542-D548. To the extent possible under law, all copyright and related or neighbouring rights to this encoded model have been dedicated to the public domain worldwide. Please refer to MIT License for more information.

Project description:Metschnikowia zobellii NRRLY-5387 Standard Draft genome sequencing

Project description:This work explores the biochemical responses of surface wonds of fruit to yeast pathogens. Results indicate that significant expression changes occur following wounding and yeast application compared to wounded controls. These changes included a range of defense-related oxidative, signalling and secondary metabolism genes. Three reps each of control (grapefruit peel) and grapefruit peel following Metschnikowia fructicola treatment.

Project description:Metschnikowia yeast species genome sequencing and assembly

Project description:Here, we report the high-throughput profiling of histone modification (H3K9me2) in fission yeast Schizosaccharomyces pombe. We generated genome-wide H3K9me2 maps of fission yeast mutants in swo1-26 (temperature sensitive, ts) cells at 25℃ and 37℃. We find that H3K9me2 enrichment at heterochromatin regions, especially at the mating-type locus and subtelomeres, is compromised, suggesting heterochromatin assembly defects.

Project description:Occupancy profiling of Shelterin components in fission yeast. Facultative heterochromatin regulates gene expression, but its assembly is poorly understood. Previously, we identified facultative heterochromatin islands in the fission yeast genome and found that RNA elimination machinery promotes island assembly at meiotic genes. Here, we report that Taz1, a component of the telomere protection complex Shelterin, is required to assemble heterochromatin islands at regions corresponding to late replication origins that are sites of double-strand break formation during meiosis. The loss of Taz1 and other Shelterin subunits, including Ccq1 that interacts with Clr4/Suv39h, abolishes heterochromatin at late origins and causes defective silencing of associated genes. Moreover, the late origin regulator Rif1 affects heterochromatin at Taz1-dependent islands and subtelomeric regions. We uncover a connection between heterochromatin and replication control, and show that heterochromatin factors affect timing of replication. These analyses implicate Shelterin in facultative heterochromatin assembly at late origins, which has important implications for the maintenance of genome stability and gene regulation.