Genome ancestry mosaics reveal multiple and cryptic contributors to cultivated banana

Martin, Guillaume; Cardi, Céline; Sarah, Gautier; Ricci, Sébastien; Jenny, Christophe; Fondi, Emmanuel; Perrier, Xavier; Glaszmann, Jean-Christophe; D’Hont, Angélique; Yahiaoui, Nabila

doi:10.1111/tpj.14683

Cited by 57 publications

(99 citation statements)

References 44 publications

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“…These observations confirm close genetic relationship between both groups of edible bananas as noted previously (Raboin et al, 2005. According to Martin et al (2017Martin et al ( , 2020, 2n gamete donor, which contributed to the origin of dessert banana clones with AAA genomes, including 'Cavendish' and 'Gros Michel', belongs to the Mchare (Mlali) sub-group. The genome of this ancient sub-group, which probably originated somewhere around Java, Borneo and New Guinea, but today is only found in East Africa, is based on zebrina / microcarpa and banksii subspecies (Perrier et al, 2009).…”

Section: Chromosome Painting Confirmed a Small Genetic Difference Betsupporting

confidence: 86%

“…This agrees with the results obtained by genotyping using molecular markers(Christelová et al, 2017). Most recently, complex hybridization scheme of Mchare bananas was supported also by application of transcriptomic data for identification of specific SNPs in 23 Musa species and edible cultivars(Martin et al, 2020).Genome structure and origin of cultivated triploid Musa clonesPlantains are an important group of triploid starchy bananas with AAB genome constitution, which originated after hybridization between M. acuminata and M. balbisiana.As expected, chromosome painting in '3 Hands Planty', 'Amou' and 'Obino l'Ewai' cultivars revealed B-genome specific translocation of 8 Mb segment from the long arm of chromosome 3 to the long arm of chromosome 1. Unlike the B-genome chromosome set, the two Agenome chromosome sets of plantains lacked any detectable translocation.…”

supporting

confidence: 85%

“…We observed reciprocal translocation between chromosomes 3 and 8, which is typical for (Carreel et al, 2002, Li et al, 2013, Kitavi et al, 2016, Němečková et al, 2018, Martin et al, 2020. origin.…”

Section: Chromosome Painting Confirmed a Small Genetic Difference Betsupporting

confidence: 53%

“…Fusion of unreduced gametes produced by diploid edible and partially sterile cultivars with normal haploid gametes from fertile diploid (Simmonds, 1962, Carreel et al, 1994, Raboin et al, 2005 would give rise to triploids. The number one export dessert banana type Cavendish as well as other important dessert bananas, such as Gros Michel and Pome types, originated according to this scenario by hybridization of a diploid representative of subgroup 'Mchare' (originally named 'Mlali') (AA genome; zebrina / microcarpa and banksii ascendance) which served as a donor of an unreduced diploid gamete with haploid gamete of 'Khai' (malaccensis ascendance) (Perrier et al, 2009, Perrier et al, 2019, Martin et al, 2020.…”

Section: Introductionmentioning

confidence: 99%

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Chromosome painting in cultivated banana and their wild relatives (Musaspp.) reveals differences in chromosome structure

Šimoníková

Němečková

Čížková

et al. 2020

Preprint

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Edible banana cultivars are diploid, triploid or tetraploid hybrids which originated by natural cross hybridization between subspecies of diploid Musa acuminata, or between M. acuminata and diploid M. balbisiana. Participation of two wild diploid species M. schizocarpa and M. textilis was also indicated by molecular studies. Fusion of gametes with structurally different chromosome sets may give rise to progenies with structural chromosome heterozygosity and reduced fertility due to aberrant chromosome pairing and unbalanced chromosome segregation. Only a few translocations have been classified on the genomic level so far and a comprehensive molecular cytogenetic characterization of cultivars and species of the family Musaceae is still lacking. FISH with chromosome-arm specific oligo painting probes was used for comparative karyotype analysis in a set of wild Musa species and edible banana clones. The results revealed large differences in chromosome structure discriminating individual accessions and permitted identification of putative progenitors of cultivated clones.

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Section: Chromosome Painting Confirmed a Small Genetic Difference Betsupporting

confidence: 86%

supporting

confidence: 85%

Section: Chromosome Painting Confirmed a Small Genetic Difference Betsupporting

confidence: 53%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Chromosome painting in cultivated banana and their wild relatives (Musaspp.) reveals differences in chromosome structure

Šimoníková

Němečková

Čížková

et al. 2020

Preprint

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show abstract

“…In cultivated bananas, the chromosome structures of allopolyploid hybrids were explored allowing to clarify the path that led to their creation (Baurens et al 2019;Cenci et al 2019Cenci et al , 2020. Current efforts focus on resolving the mosaic structure of cultivated banana by looking at the ancestral contribution of the different M. acuminata subspecies along chromosomes (Martin et al 2020). This information will be of particular importance for breeders requesting material.…”

Section: Deciphering the Evolutionary History Of The Cropmentioning

confidence: 99%

Safeguarding and using global banana diversity: a holistic approach

houwe¹,

Chase

Sardos

et al. 2020

CABI Agric Biosci

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The CGIAR genebank International Musa Germplasm Transit Centre (ITC) currently holds 1617 banana accessions from 38 countries as an in vitro collection, backed-up by a cryopreserved collection to safeguard global Musa diversity in perpetuity. The ITC also serves as a vital safety backup and transit centre for national banana genebanks and ensures that germplasm is clean of pests and diseases and freely available under the International Treaty on Plant Genetic Resources for Food and Agriculture. In more than 35 years of activity, the ITC has distributed over 18,000 banana accession samples to researchers and farmers in 113 countries. Ex situ conservation of vegetatively-propagated crops such as banana poses very particular challenges. Maintaining the ITC genebank is labor intense and costly. Efficiencies are sought through research and development of techniques on detecting viruses, the genetic integrity of accessions, and on innovative means of safeguarding banana diversity, such as conserving populations of wild species by seed banking. Although the conservation of global banana diversity is the main objective of the ITC, significant value comes from its holistic approach to better understand and promote its germplasm through numerous research activities and resources. Techniques for morphological and molecular characterization serve to identify and describe the collection, while also determining what gaps should be filled by collecting missions with national partners. The evaluation of desirable agronomic traits inherent in Musa spp. are investigated by a high-throughput phenotyping platform, which helps breeding programs to select cultivars resistant or tolerant to biotic and abiotic stresses. Genomic and bioinformatic studies of several banana wild relatives greatly enhance our understanding of Musa genetic diversity, links to important phenotypic traits and bring new methods for management of the collection. Collectively, these research activities produce enormous amounts of data that require curation and dissemination to the public. The two information systems at the ITC, Musa Genebank Management System and the Musa Germplasm Information System, serve to manage the genebank activities and to make public germplasm-related data for over 30 banana collections worldwide, respectively. By implementing the 10-year workplan set out in the Global Strategy for the Conservation and Use of Musa Genetic Resources, the network MusaNet supports Musa researchers and stakeholders, including the ITC, and most importantly, links to the world’s banana-producing countries via three regional banana networks.

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Filling the gaps in gene banks: Collecting, characterizing, and phenotyping wild banana relatives of Papua New Guinea

Eyland

Breton²,

Sardos³

et al. 2020

Crop Science

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Since natural habitats are disappearing fast, there is an urgent need to collect, characterize, and phenotype banana (Musa spp.) crop wild relatives to identify unique genotypes with specific traits that fill the gaps in our gene banks. We report on a collection mission in Papua New Guinea carried out in 2019. Seed containing bunches were collected from Musa peekelii ssp. angustigemma (N.W.Simmonds) Argent (3), M. schizocarpa N. W. Simmonds (4), M. balbisiana Colla (3), M. acuminata ssp. banksii (F. Muell.) Simmonds (14), M. boman Argent (3), M. ingens Simmonds (2), M. maclayi ssp. maclayi F.Muell. ex Mikl.-Maclay (1), and M. lolodensis Cheesman (1). This material, together with the seeds collected during a previous mission in 2017, form the basis for the development of a wild banana seed bank. For characterization and phenotyping, we focused on the most ubiquitous indigenous species of Papua New Guinea: M. acuminata ssp. banksii, the ancestor of most edible bananas. We calculated that the median genomic dissimilarity of the M. acuminata ssp. banksii accessions was 4% and that they differed at least 5% from accessions present in the International Transit Centre, the world's largest banana gene bank. High-throughput phenotyping revealed drought avoidance strategies with significant differences

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Genome ancestry mosaics reveal multiple and cryptic contributors to cultivated banana

Cited by 57 publications

References 44 publications

Chromosome painting in cultivated banana and their wild relatives (Musaspp.) reveals differences in chromosome structure

Chromosome painting in cultivated banana and their wild relatives (Musaspp.) reveals differences in chromosome structure

Safeguarding and using global banana diversity: a holistic approach

Filling the gaps in gene banks: Collecting, characterizing, and phenotyping wild banana relatives of Papua New Guinea

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