Literature DB >> 24926053

Draft Genome Sequence of Colletotrichum sublineola, a Destructive Pathogen of Cultivated Sorghum.

Riccardo Baroncelli¹, José María Sanz-Martín¹, Gabriel E Rech¹, Serenella A Sukno¹, Michael R Thon².

Abstract

Colletotrichum sublineola is a filamentous fungus that causes anthracnose disease on sorghum. We report a draft whole-genome shotgun sequence and gene annotation of the nuclear genome of this fungus using Illumina sequencing.

Entities: Chemical Species

Year: 2014 PMID： 24926053 PMCID： PMC4056296 DOI： 10.1128/genomeA.00540-14

Source DB: PubMed Journal: Genome Announc

GENOME ANNOUNCEMENT

Sorghum (Sorghum bicolor) is an important cultivated crop and is used as a staple food, as animal fodder, and as a biofuels feedstock. One of the most important diseases that affects sorghum crops is sorghum anthracnose, caused by the ascomycete fungus Colletotrichum sublineola, which can cause a reduction in grain size as well as yield losses of more than 50% under epidemic conditions (1). Colletotrichum sublineola is also closely related to C. graminicola (2), a causal agent of maize anthracnose, and is therefore useful for comparative genomics of the two species to uncover the evolutionary mechanisms of speciation, host specificity, and pathogenicity. Colletotrichum sublineola strain TX430BB was isolated from sorghum in College Station, TX, USA (3). Total genomic DNA was purified using the method of Baek and Kenerley (4) and sequenced using 100-bp paired-end reads on an Illumina HiSeq 2000, and the sequence reads (4.32 Gbp; average coverage, 91.93×) were assembled using Velvet version 1.2.07 (5). The draft genome of C. sublineola consists of 1,625 sequence scaffolds with a total length of 46.75 Mbp (N50=70,717 bp, and N90=13,454 bp), 52.70% G+C content, and a maximum scaffold size of 423,147 bp. The mitochondrial genome was identified by performing BLAST searches of the contigs in a database of mitochondrial genomes of other fungi, resulting in the identification and removal of 6 contigs. The completeness of the assembly was assessed using CEGMA v2.4 (6), which estimated the genome sequence to be 98.39% complete. The nuclear genome was annotated using the MAKER pipeline (7). Overall, 12,699 protein-coding gene models were predicted in the nuclear genome. Using WoLF PSORT (8) we identified 1,820 proteins that are predicted to be extracellular (14.33% of the proteome). Based on BLAST searches (e-value threshold of 1e−3) of the extracellular proteins, 168 (9.23% of the secretome) do not have any sequence similarity to proteins in C. graminicola, and of those 168 proteins, 70 (3.85% of the secretome) do not have any sequence similarity to proteins in other Colletotrichum species (2, 9–11). However, only 60 secreted proteins are unique to C. sublineola when compared to the nr database with BLAST. These species-specific extracellular proteins may be effectors, proteins that have important roles in modulating the plant’s immune system and in host specialization. In this study we present a draft genome sequence from a member of C. sublineola, a destructive pathogen of cultivated sorghum. The sequence represents a new resource that will be useful for further research into the biology, ecology, and evolution of this key pathogen.

Nucleotide sequence accession numbers.

This whole-genome shotgun sequencing project has been deposited at GenBank under the accession no. JMSE00000000. The version described in this paper is JMSE00000000.1.

9 in total

1. CEGMA: a pipeline to accurately annotate core genes in eukaryotic genomes.

Authors: Genis Parra; Keith Bradnam; Ian Korf
Journal: Bioinformatics Date: 2007-03-01 Impact factor: 6.937

2. Velvet: algorithms for de novo short read assembly using de Bruijn graphs.

Authors: Daniel R Zerbino; Ewan Birney
Journal: Genome Res Date: 2008-03-18 Impact factor: 9.043

3. Global aspects of pacC regulation of pathogenicity genes in Colletotrichum gloeosporioides as revealed by transcriptome analysis.

Authors: Noam Alkan; Xiangchun Meng; Gilgi Friedlander; Eli Reuveni; Serenella Sukno; Amir Sherman; Michael Thon; Robert Fluhr; Dov Prusky
Journal: Mol Plant Microbe Interact Date: 2013-11 Impact factor: 4.171

4. The arg2 gene of Trichoderma virens: cloning and development of a homologous transformation system.

Authors: J M Baek; C M Kenerley
Journal: Fungal Genet Biol Date: 1998-02 Impact factor: 3.495

5. Comparative genomic and transcriptomic analyses reveal the hemibiotrophic stage shift of Colletotrichum fungi.

Authors: Pamela Gan; Kyoko Ikeda; Hiroki Irieda; Mari Narusaka; Richard J O'Connell; Yoshihiro Narusaka; Yoshitaka Takano; Yasuyuki Kubo; Ken Shirasu
Journal: New Phytol Date: 2012-12-17 Impact factor: 10.151

6. Lifestyle transitions in plant pathogenic Colletotrichum fungi deciphered by genome and transcriptome analyses.

Authors: Richard J O'Connell; Michael R Thon; Stéphane Hacquard; Stefan G Amyotte; Jochen Kleemann; Maria F Torres; Ulrike Damm; Ester A Buiate; Lynn Epstein; Noam Alkan; Janine Altmüller; Lucia Alvarado-Balderrama; Christopher A Bauser; Christian Becker; Bruce W Birren; Zehua Chen; Jaeyoung Choi; Jo Anne Crouch; Jonathan P Duvick; Mark A Farman; Pamela Gan; David Heiman; Bernard Henrissat; Richard J Howard; Mehdi Kabbage; Christian Koch; Barbara Kracher; Yasuyuki Kubo; Audrey D Law; Marc-Henri Lebrun; Yong-Hwan Lee; Itay Miyara; Neil Moore; Ulla Neumann; Karl Nordström; Daniel G Panaccione; Ralph Panstruga; Michael Place; Robert H Proctor; Dov Prusky; Gabriel Rech; Richard Reinhardt; Jeffrey A Rollins; Steve Rounsley; Christopher L Schardl; David C Schwartz; Narmada Shenoy; Ken Shirasu; Usha R Sikhakolli; Kurt Stüber; Serenella A Sukno; James A Sweigard; Yoshitaka Takano; Hiroyuki Takahara; Frances Trail; H Charlotte van der Does; Lars M Voll; Isa Will; Sarah Young; Qiandong Zeng; Jingze Zhang; Shiguo Zhou; Martin B Dickman; Paul Schulze-Lefert; Emiel Ver Loren van Themaat; Li-Jun Ma; Lisa J Vaillancourt
Journal: Nat Genet Date: 2012-08-12 Impact factor: 38.330

7. MAKER2: an annotation pipeline and genome-database management tool for second-generation genome projects.

Authors: Carson Holt; Mark Yandell
Journal: BMC Bioinformatics Date: 2011-12-22 Impact factor: 3.307

8. WoLF PSORT: protein localization predictor.

Authors: Paul Horton; Keun-Joon Park; Takeshi Obayashi; Naoya Fujita; Hajime Harada; C J Adams-Collier; Kenta Nakai
Journal: Nucleic Acids Res Date: 2007-05-21 Impact factor: 16.971

9. Draft Genome Sequence of Colletotrichum acutatum Sensu Lato (Colletotrichum fioriniae).

Authors: Riccardo Baroncelli; Surapareddy Sreenivasaprasad; Serenella A Sukno; Michael R Thon; Eric Holub
Journal: Genome Announc Date: 2014-04-10

9 in total

14 in total

1. Evolutionary Analysis of Pectin Lyases of the Genus Colletotrichum.

Authors: Alicia Lara-Márquez; Ken Oyama; María G Zavala-Páramo; Maria G Villa-Rivera; Ulises Conejo-Saucedo; Horacio Cano-Camacho
Journal: J Mol Evol Date: 2017-10-25 Impact factor: 2.395

2. Draft Whole-Genome Sequence of the Biocontrol Agent Trichoderma harzianum T6776.

Authors: Riccardo Baroncelli; Giulia Piaggeschi; Lisa Fiorini; Edoardo Bertolini; Antonio Zapparata; Mario Enrico Pè; Sabrina Sarrocco; Giovanni Vannacci
Journal: Genome Announc Date: 2015-06-11

3. Structure-function characterization reveals new catalytic diversity in the galactose oxidase and glyoxal oxidase family.

Authors: DeLu Tyler Yin; Saioa Urresti; Mickael Lafond; Esther M Johnston; Fatemeh Derikvand; Luisa Ciano; Jean-Guy Berrin; Bernard Henrissat; Paul H Walton; Gideon J Davies; Harry Brumer
Journal: Nat Commun Date: 2015-12-18 Impact factor: 14.919

4. Draft whole-genome sequence of the Diaporthe helianthi 7/96 strain, causal agent of sunflower stem canker.

Authors: Riccardo Baroncelli; Felice Scala; Mariarosaira Vergara; Michael R Thon; Michelina Ruocco
Journal: Genom Data Date: 2016-11-11

5. Genome sequencing and comparative genomics reveal a repertoire of putative pathogenicity genes in chilli anthracnose fungus Colletotrichum truncatum.

Authors: Soumya Rao; Madhusudan R Nandineni
Journal: PLoS One Date: 2017-08-28 Impact factor: 3.240

6. Genus-Wide Comparative Genome Analyses of Colletotrichum Species Reveal Specific Gene Family Losses and Gains during Adaptation to Specific Infection Lifestyles.

Authors: Pamela Gan; Mari Narusaka; Naoyoshi Kumakura; Ayako Tsushima; Yoshitaka Takano; Yoshihiro Narusaka; Ken Shirasu
Journal: Genome Biol Evol Date: 2016-05-22 Impact factor: 3.416

7. Gene family expansions and contractions are associated with host range in plant pathogens of the genus Colletotrichum.

Authors: Riccardo Baroncelli; Daniel Buchvaldt Amby; Antonio Zapparata; Sabrina Sarrocco; Giovanni Vannacci; Gaétan Le Floch; Richard J Harrison; Eric Holub; Serenella A Sukno; Surapareddy Sreenivasaprasad; Michael R Thon
Journal: BMC Genomics Date: 2016-08-05 Impact factor: 3.969

8. Identification of the Main Regulator Responsible for Synthesis of the Typical Yellow Pigment Produced by Trichoderma reesei.

Authors: Christian Derntl; Alice Rassinger; Ewald Srebotnik; Robert L Mach; Astrid R Mach-Aigner
Journal: Appl Environ Microbiol Date: 2016-09-30 Impact factor: 4.792

9. Draft Genome Sequence of Colletotrichum falcatum - A Prelude on Screening of Red Rot Pathogen in Sugarcane.

Authors: Rasappa Viswanathan; Chandrasekaran Naveen Prasanth; Palaniyandi Malathi; Amalraj Ramesh Sundar
Journal: J Genomics Date: 2016-01-30

10. The Colletotrichum acutatum Species Complex as a Model System to Study Evolution and Host Specialization in Plant Pathogens.

Authors: Riccardo Baroncelli; Pedro Talhinhas; Flora Pensec; Serenella A Sukno; Gaetan Le Floch; Michael R Thon
Journal: Front Microbiol Date: 2017-10-11 Impact factor: 5.640