Florence Paulet

Construction of a composite sorghum genome map and comparison with sugarcane, a related complex polyploid

Abstract A sorghum composite linkage map was constructed with two recombinant inbred line populations using heterologous probes already mapped on maize and sugarcane. This map includes 199 loci revealed by 188 probes and distributed on 13 linkage groups. A comparison based on 84 common probes was performed between the sorghum composite map and a map of a sugarcane (Saccharum spp.) cultivar being developed and presently comprising 10 tentative linkage groups. A straight synteny was observed for 2 pairs of linkage groups; in two cases, 1 sorghum linkage group corresponded to 2 or 3 sugarcane linkage groups, respectively; in two cases 1 sugarcane link- age group corresponded to 2 separate sorghum linkage groups; for 2 sorghum linkage groups, no complete correspondance was found in the sugarcane genome. In most cases loci appeared to be colinear between homoeologous chromosomal segments in sorghum and sugarcane. These results are discussed in relation to published data on sorghum genomic maps, with specific reference to the genetic organization of sugarcane cultivars, and they, illustrate how investigations on relatively simple diploid genomes as sorghum will facilitate the mapping of related polyploid species such as sugarcane.

Genomic distribution and characterization of EST-derived resistance gene analogs (RGAs) in sugarcane.

A large sugarcane EST (expressed sequence tag) project recently gave us access to 261,609 EST sequences from sugarcane, assembled into 81,223 clusters. Among these, we identified 88 resistance gene analogs (RGAs) based on their homology to typical pathogen resistance genes, using a stringent BLAST search with a threshold e-value of e−50. They included representatives of the three major groups of resistance genes with NBS/LRR, LRR or S/T KINASE domains. Fifty RGAs showed a total of 148 single-dose polymorphic RFLP markers, which could be located on the sugarcane reference genetic map (constructed in cultivar R570, 2n=~115). Fifty-five SSR loci corresponding to 134 markers in R570 were also mapped to enable the classification of the various haplotypes into homology groups. Several RGA clusters were found. One cluster of two LRR-like loci mapped close to the only disease resistance gene known so far in sugarcane, which confers resistance to common rust. Detailed sequence comparison between two NBS/LRR RGA clusters in relation to their orthologs in rice and maize suggests their polyphyletic origins, and indicates that the degree of divergence between paralogous RGAs in sugarcane can be larger than that from an ortholog in a distant species.

Molecular diversity and genome structure in modern sugarcane varieties

SummaryRFLP analysis was performed on 40 sugarcane cultivated varieties. Twenty-two maize low copy DNA clones located on different regions of the 10 maize chromosomes were used as probes to survey variability among the sugarcane varieties. A total of 425 fragments, 411 of which were polymorphic, were identified for 22 probe/enzyme combinations. Each variety displayed an average of 7.28 fragments per combination, revealing the complex polyploid origin of modern sugarcane varieties. The average genetic similarity between sugarcane varieties was 0.61. Although cultivated varieties appear closely related to S. officinarum clones, the genes of S. spontaneum seem to constitute the principal component of varietal diversity. A very weak global structuring among the 40 varieties is observed, in agreement with the profuse exchanges of parental materials between sugarcane breeding stations. Traces of linkage disequilibrium can be attributed to the distribution of S. spontaneum chromosomes among sugarcane varieties. The possibility of using modern varieties as a population for detecting associations between molecular markers and agronomic traits is suggested.

Molecular investigation of the genetic base of sugarcane cultivars

Abstract Molecular diversity was analysed among 162 clones of sugarcane using DNA restriction fragment length polymorphism (RFLP). One hundred and nine of them were modern cultivars of interspecific origin; most of them were bred in Barbados or in Mauritius. Fifty three were from Saccharum officinarum species, which is the major source of genes in modern cultivars, prevailing over the part of the genome incorporated from the wild species Saccharum spontaneum. Twelve low-copy nuclear DNA probes scattered over the genome were used in combination with one or two restriction enzymes. A total of 399 fragments was identified, 386 of which were polymorphic. Each sugarcane clone displayed a high number of fragments per probe/enzyme combination, illustrating the polyploid constitution of the genome. Among the S. officinarum clones, those from New Guinea had the largest variability and encompassed that present among clones collected from the Indonesian Islands and those known to have been involved in the parentage of modern cultivars. This is in agreement with the hypothesis that New Guinea is the centre of origin of this species. The clones from New Caledonia formed a separate group and could correspond to S. officinarum clones modified through introgression with other members of the ‘Saccharum complex’. Despite the low number of S. officinarum clones used for breeding cultivars, more than 80% of the markers present in the whole S. officinarum sample were also found in modern cultivars due probably to a high heterozygosity related to polyploidy. Among the cultivars, the two main groups, originating from Barbados and Mauritius, were clearly separated. This appeared essentially due to S. spontaneum alleles present in Mauritian cultivars and absent in Barbadan ones, probably in relation to the regular use of early generation interspecific hybrids in the breeding program employed in Mauritius.

Oligoclonal interspecific origin of 'North Indian' and 'Chinese' sugarcanes.

Sugarcanes consist of several groups of complex polyploid forms. The origin of ‘North Indian’ and ‘Chinese’ sugarcanes (referred to as S. barberi and S. sinense) was investigated using genomic in-situ hybridization (GISH), detection of species-specific repeated sequences and RFLP. GISH proved their interspecific hybrid origin. Together with the distribution of species-specific repeated sequences and earlier RFLP data, the results show that both taxa are derived from interspecific hybridization between S. officinarum and S. spontaneum and that no other genus has been directly involved. RFLP indicates that the clones are clustered into a few groups, each derived from a single interspecific hybrid that has subsequently undergone a few somatic mutations. These groups correspond quite well with those already defined based on morphological characters and chromosome numbers. However, the calculated genetic similarities do not support the existence of two distinct taxa. The ‘North Indian’ and ‘Chinese’ sugarcanes represent a set of horticultural groups rather than established species.

Cryopreservation of apices of in vitro plantlets of sugarcane (Saccharum sp. hybrids) using encapsulation/dehydration

SummaryA cryopreservation process using encapsulation/dehydration was set up for apices sampled on in vitro plantlets of sugarcane. After dissection, apices were cultured for one day on standard medium and then encapsulated in medium with 3% alginate. Optimal conditions comprised preculture for 2 days in liquid medium with 250 g.l−1 sucrose, desiccation for 6 hours under the laminar flow or for 10–11 hours with silicagel followed by rapid freezing and slow thawing. Survival after freezing in liquid nitrogen ranged between 38 and 91% for the 5 varieties experimented. Cryopreservation did not modify the electrophoretic profiles for aminoleucine peptidases and amylases with plants of the variety Co 6415.

Application of synteny across Poaceae to determine the map location of a sugarcane rust resistance gene

Abstract A major rust resistance gene has been identified in a self-progeny of the sugarcane cultivar R570. Until now, this gene was known to be linked to a marker revealed by the sugarcane probe CDSR29 but unassigned to any linkage group of the current genetic map. We used synteny relationships between sugarcane and three other grasses in an attempt to saturate the region around this rust resistance gene. Comparison of sugarcane, sorghum, maize and rice genetic maps led to the identification of homoeologous chromosome segments at the extremity of sorghum linkage group D, rice linkage group 2, maize linkage group 4 and in the centromeric region of maize linkage group 5. One hundred and eighty-four heterologous probes were selected and tested for cross-hybridization with sugarcane DNA; 106 produced a good hybridization signal and were hybridized on 88 individuals of the R570 selfed progeny. Two hundred and seventeen single-dose markers were added to the R570 genetic map, of which 66% mapped to linkage group VII, together with the rust resistance gene. This gene has now been mapped to the end of a co-segregating group consisting of 19 RFLP markers. None of the mapped loci were located closer to the gene than CDSR29. The gene thus appears to reside at the edge of a ’’synteny cluster’’ used to describe the different grass genomes.

Comparative genome analysis between several tropical grasses

The availability of molecular markers allowed comparing genetic maps between distinct taxa. Among the Poaceae (grasses) family, species as divergent as rice, wheat and maize show collinearity within wide regions along the whole genome. This opens the way for the integration of knowledge across all grasses and the development of molecular tools of general interest using the simple genome of rice. Many agronomically important tropical grasses belong to two major sub-families. Comparisons between maize, sorghum and sugarcane, three members of the Andropogoneae tribe, are briefly reviewed. One example of a particular genome region is used for extending the comparison to rice and illustrating various applications of comparative genome mapping.

Inter-Alu-like species-specific sequences in the Saccharum complex

Abstract Alu sequences constitute the most abundant family of short interspersed nuclear elements, SINEs, in the primate genome. The Alu-PCR method, which consists of amplification between Alu sequences, is usually applied in human genetics to provide polymorphic markers. Here we report the presence of Alu-like sequences in sugarcane and related species by applying the Alu-PCR-like method. Amplifications using a PCR primer defined in conserved regions of Alu human sequences lead to specific complex multiband profiles in all the Saccharum and related genera clones surveyed. The isolation and characterisation of the amplified genus-specific inter-Alu-like fragments allowed us to isolate repeated sequences that are specific for different genera of the Saccharum complex: MsCIR2 from Miscanthus, EaCIR6 and EaCIR7 from Erianthus, and SrCIR2 from Saccharum. Two PCR diagnostic tests were developed from the inter-Alu-like sequences MsCIR2 and EaCIR6, and proved efficient in identifying intergeneric hybrids Saccharum×Miscanthus or Saccharum×Erianthus, respectively. The present study illustrates how the Alu-PCR-like method could help investigating the origin of amphiploid species and monitoring introgression in plants.

Somatic Embryogenesis in Sugarcane (Saccharum Species)

Sugarcane is the name given to sacchariferous, cultivated species and descendants of interspecific hybrids in the genus Saccharum, fafnily Graminae, tribe Andropogonae. Saccharum species are highly polyploid with no known diploid form. A basic chromosome number has not yet been firmly established, but is estimated in the range of 5–10 (Stevenson 1965). Until the late 1800s, sugarcane varieties belonged mostly to S officinarum (2n = 8x = 80), the “noble” cane originating from New Guinea, and also to S sinense (2n = 106−120) and S. barberi (2n = 80−120). Interspecific crosses between S officinarum and S. spontaneum, followed by two or three backcrossings to the noble cane — a process called nobilization — yielded the first modern commercial varieties(Saccharum ssp.) in the early 1900s in Java and later in India (Daniels and Roach 1987). The original hybrids were, in turn, crossed with each other to produce new commercial varieties. The limited genetic basis of the original hybridizations, which according to Arceneaux (1967) involved no more than 20 noble clones and fewer than 10 S. spontaneum derivatives, led various countries to reinitiate nobilization work in the early 1960s in order to transfer specific, desirable characters, such as disease resistance, from wild germplasm to commercial hybrids (Berding and Roach 1987). Current breeding goals are to develop cultivars with increased sugar yield and resistance to diseases (smut, mosaic, rust, leaf scald) and insects.