Franc-Christophe Baurens

The banana (Musa acuminata) genome and the evolution of monocotyledonous plants.

Bananas (Musa spp.), including dessert and cooking types, are giant perennial monocotyledonous herbs of the order Zingiberales, a sister group to the well-studied Poales, which include cereals. Bananas are vital for food security in many tropical and subtropical countries and the most popular fruit in industrialized countries. The Musa domestication process started some 7,000 years ago in Southeast Asia. It involved hybridizations between diverse species and subspecies, fostered by human migrations, and selection of diploid and triploid seedless, parthenocarpic hybrids thereafter widely dispersed by vegetative propagation. Half of the current production relies on somaclones derived from a single triploid genotype (Cavendish). Pests and diseases have gradually become adapted, representing an imminent danger for global banana production. Here we describe the draft sequence of the 523-megabase genome of a Musa acuminata doubled-haploid genotype, providing a crucial stepping-stone for genetic improvement of banana. We detected three rounds of whole-genome duplications in the Musa lineage, independently of those previously described in the Poales lineage and the one we detected in the Arecales lineage. This first monocotyledon high-continuity whole-genome sequence reported outside Poales represents an essential bridge for comparative genome analysis in plants. As such, it clarifies commelinid-monocotyledon phylogenetic relationships, reveals Poaceae-specific features and has led to the discovery of conserved non-coding sequences predating monocotyledon–eudicotyledon divergence.

Molecular breeding in the genus Musa: a strong case for STMS marker technology

Musa species are among the tallest monocotyledons and include major food-producing species. The principal cultivars, derived from two major species Musa acuminata (‘A’ genome) and Musa balbisiana (‘B’ genome), are polyploid hybrids (mainly AAA, AAB and ABB triploids), medium to highly sterile, parthenocarpic and clonally propagated. Bananas and plantains are crops to which molecular breeding is expected to have a positive impact. In order to better understand banana genetics, more knowledge has to be accumulated about the complex genome structure of hybrids and cultivars. Therefore, the aim of our work is to develop molecular markers that are codominant, reliable, universal, highly polymorphic and that are applicable to collaborative Musa germplasm genotyping and mapping. Two size-selected genomic libraries have been screened for the presence of simple sequence repeats (SSR). Our data demonstrate that SSR are readily applicable to the study of Musa genetics. Our comprehensive analyses of a significant number of banana sequence tagged microsatellite sites (STMS) will add to our knowledge on the structure and phylogeny of genomes of the Musa species, and suggest that microsatellites be used as anchor markers for a banana genetic core map. Additional markers, such as e.g. CAPS have also been tested in order to increase the detection of polymorphisms exceeding that revealed by STMS technology. The utility of PCR-derived markers for collaborative genetic analyses of the banana genome, and the transferability of streamlined’ laboratory techniques and data analysis to Developing Countries are discussed.

The Complete Chloroplast Genome of Banana (Musa acuminata, Zingiberales): Insight into Plastid Monocotyledon Evolution

Background Banana (genus Musa) is a crop of major economic importance worldwide. It is a monocotyledonous member of the Zingiberales, a sister group of the widely studied Poales. Most cultivated bananas are natural Musa inter-(sub-)specific triploid hybrids. A Musa acuminata reference nuclear genome sequence was recently produced based on sequencing of genomic DNA enriched in nucleus. Methodology/Principal Findings The Musa acuminata chloroplast genome was assembled with chloroplast reads extracted from whole-genome-shotgun sequence data. The Musa chloroplast genome is a circular molecule of 169,972 bp with a quadripartite structure containing two single copy regions, a Large Single Copy region (LSC, 88,338 bp) and a Small Single Copy region (SSC, 10,768 bp) separated by Inverted Repeat regions (IRs, 35,433 bp). Two forms of the chloroplast genome relative to the orientation of SSC versus LSC were found. The Musa chloroplast genome shows an extreme IR expansion at the IR/SSC boundary relative to the most common structures found in angiosperms. This expansion consists of the integration of three additional complete genes (rps15, ndhH and ycf1) and part of the ndhA gene. No such expansion has been observed in monocots so far. Simple Sequence Repeats were identified in the Musa chloroplast genome and a new set of Musa chloroplastic markers was designed. Conclusion The complete sequence of M. acuminata ssp malaccensis chloroplast we reported here is the first one for the Zingiberales order. As such it provides new insight in the evolution of the chloroplast of monocotyledons. In particular, it reinforces that IR/SSC expansion has occurred independently several times within monocotyledons. The discovery of new polymorphic markers within Musa chloroplast opens new perspectives to better understand the origin of cultivated triploid bananas.

A new image of plantain diversity assessed by SSR, AFLP and MSAP markers

Using both SSR and AFLP markers, the genetic diversity of 30 plantains constituting a representative sample of the phenotypic diversity was assessed. The results confirmed a very narrow genetic base of this cultivar group. SSR and AFLP data support the hypothesis that these cultivars may have arisen from vegetative multiplication of a single seed. MSAP were used to survey cytosine methylation status at CCGG sites in order to obtain an alternative source of diversity data. A higher degree of polymorphism was revealed allowing the classification of the samples into three clusters. No correlation was observed between the phenotypic classification and methylation diversity. Implications for breeding programs are discussed.

Diploid ancestors of triploid export banana cultivars: molecular identification of 2n restitution gamete donors and n gamete donors

The origin of triploid export banana cultivars was investigated. They all belong to Cavendish and Gros Michel subgroups of triploid clones and have a monospecific Musa acuminata origin. The appearance of these cultivars is thought to be result of hybridization between partially sterile diploid cultivars producing non reduced gametes and fertile diploids producing normal haploid gametes. To trace these diploid ancestors we compared the RFLP patterns, revealed by 36 probe/enzyme combinations, of 176 diploid clones representing the worldwide available variability with that of clones from the Cavendish and Gros Michel subgroups. This lead us to the identification of the common putative diploid ancestor of cultivars from Cavendish and Gros Michel subgroups which contributed to triploid cultivar formation through the production of 2n restitution gametes. For cultivars of Gros Michel subgroup we also propose a normal gamete donor that may have complemented the triploid allele set.

Genomics of Banana and Plantain (Musa spp.), Major Staple Crops in the Tropics

This chapter on Musa (banana and plantain) genomics covers the latest information on activities and resources developed by the Global Musa Genomics Consortium. Section 4.1 describes the morphology of the plant, its socio-economical importance and usefulness as an experimental organism. Section 4.2 describes the complexity of Musa taxonomy and the importance of genetic diversity. Section 4.3 details the genetic maps which have recently been developed and those that are currently being developed. Section 4.4 presents the five BAC libraries which are now publicly available from the Musa Genome Resource Centre and can be distributed in various forms under a material transfer agreement. Section 4.5 gives an overview of cytogenetics and genome organization, showing that the genus Musa has a quite high proportion of repetitive DNA; the discovery of the first para-retrovirus integrated in the genome makes it unique. Section 4.6 explains the first attempts to sequence the genome by BAC end sequencing, whole BAC sequencing, and reduced representation sequencing. Section 4.7 addresses functional genomics with the description of cDNA libraries, gene validation using gene trapping, mutation induction and tilling techniques, as well as genetic transformation. Section 4.8 draws overall conclusions. This chapter demonstrates that by organizing the Global Musa Genomics Consortium (currently comprising 33 member institutions from 23 countries), duplication of effort can be minimized and the results of Musa genomics research are rapidly made accessible to taxonomists, breeders and the biotechnology community.

Use of competitive PCR to assay copy number of repetitive elements in banana

Abstract Banana is one of the most important sub- tropical fruit crops. Genetic improvement by traditional breeding strategies is difficult and better knowledge of genomic structure is needed. Repeated sequences are powerful markers for genetic fingerprinting. The method proposed here to determine the copy number of nuclear repetitive elements is based on competitive reverse transcription-polymerase chain reaction and can also be used for quantifying cytosolic sequences. The reliability of this method was investigated on crude preparations of total DNA. Variations due to the heterogeneity of crude DNA extracts showed that a single locus reference is needed for accurate quantification. A mapped microsatellite locus was used to normalize copy number measurements. Copy number assay of repetitive elements using this method clearly distinguishes between the two banana subspecies investigated: Musa acuminata spp. banskii and M. acuminata spp. malaccensis. Two repetitive sequence families, pMaCIR1115 and pA9-26, were assayed that cover up to 1% of the M. acuminata genome. Their copy number varied up to six fold between the two subspecies. Furthermore, sequence quantification showed that mitochondrial genomes are present in crude leaf-extracted banana DNA at up to 40 copies per cell.

Development of expressed sequence tag and expressed sequence tag-simple sequence repeat marker resources for Musa acuminata.

Many varieties of banana (Musa acuminata) lack resistance to biotic stresses. An EST collection was developed, including transcripts expressed in banana-Mycosphaerella fijiensis interactions. Developed polymorphic gene-derived SSR markers are applicable for genetic mapping, diversity characterization and marker assisted breeding.

Inter-Alu PCR like genomic profiling in banana

Alu sequences are a major repetitive element of the primate genome. To date Alu sequences have seldom been reported in plant genomes. We report here an inter-Alu PCR like genomic profiling in banana using a single primer designed from a human Alu sequence. The different Musa species involved in the complex genome of banana cultivars can thus be discriminated. The use of this technique for monitoring germplasm or genotyping cultivars is discussed.

Assessment of a species-specific element (Brep 1) in banana

Abstract The nuclear genome of wild-type banana accessions was investigated for repetitive elements. We report here the occurrence, in the banana genome, of a sequence family of species-specific repetitive elements: Brep 1. This sequence family is distributed throughout the Musaceae with various copy numbers. The two species Musa acuminata and M. schizocarpa carry the highest copy numbers in contrast to M. balbisiana and tested representatives of different other sections. PCR primers were defined in the core consensus sequence for specific amplifications, which allow representatives of this sequence family to be easily detected in wild and cultivated banana clones. Sequence data were analysed and hypotheses on the evolution of banana cultivars from the wild-type banana clones are discussed.