Ribosomal DNA variations in Erianthus, a wild sugarcane relative (Andropogoneae-Saccharinae)

Variation at the 18S+26S and 5S ribosomal DNA loci was assessed on 62 Erianthus Michx. clones, representing 11 species, and 15 clones from two Saccharum L. species used as a reference. Genus-specific markers for Erianthus Michx. sect. Ripidium Henrard (Old World species) were identified. Ribosomal DNA units in Erianthus sect. Ripidium exhibited an additional BamHI site compared to Saccharum, and 5S units showed length and restriction-site differences between Erianthus and Saccharum. These markers will be useful to follow introgression in Saccharum x Erianthus hybrids. Six ribosomal units (for 18+26S genes) were revealed in Erianthus sect. Ripidium, differing by restriction-site positions and/or length. These results provided new information on species relationships and evolution within the genus Erianthus. The Indonesian and Indian forms of E. arundinaceus (Retz.) Jeswiet gave different restriction patterns, which were similar to those of E. bengalense (Retz.) R. C. Bharadwaja and E. procerus (Roxb.) Raizade, respectively. The two 2n=20 species, E. ele-phantinus Hook.f. and E. ravennae (L.) P. Beauv., could also be differentiated at this locus. Two of the New World Erianthus species studied, E. rufipilus (Steud.) Griseb. and E. longisetosus Andersson, appeared more like Erianthus sect. Ripidium, whereas E. trinii Hack, and E. brevibardis Michx. showed patterns consistent with Miscanthus sinensis Andersson and S. spontaneum L., respectively. Finally, the comparison of rDNA restriction maps among Erianthus sect. Ripidium, Saccharum, sorghum and maize, led to unexpected conclusions concerning the relationships between the different genera and the position of Erianthus in the Saccharum complex.     

Phylogenetic analysis of organellar DNA sequences in the Andropogoneae: Saccharinae

To study the phylogenetics of sugarcane (Saccharum officinarum L.) and its relatives we sequenced four loci on cytoplasmic genomes (two chloroplast and two mitochondrial) and analyzed mitochondrial RFLPs generated using probes for COXI, COXII, COXIII, Cob, 18S+5S, 26S, ATPase 6, ATPase 9, and ATPase (D'Hont et al. 1993). Approximately 650 bp of DNA in the intergenic spacer region between rbcL and atpB and approximately 150 bp from the chloroplast 16S rDNA through the intergenic spacer region tRNA^val gene were sequenced. In the mitochondrial genome, part of the 18S rRNA gene and approximately 150 bp from the 18S gene 3 end, through an intergenic spacer region, to the 5S rRNA gene were sequenced. No polymorphisms were observed between maize, sorghum, and Saccharum complex members for the mitochondrial 18S internal region or for the intergenic tRNA^val chloroplast locus. Two polymorphisms (insertion-deletion events, indels) were observed within the 18S-5S mitochondrial locus, which separated the accessions into three groups: one containing all of the Erianthus, Eccoilopus, Imperata, Sorghum, and 1 Miscanthus species; a second containing Saccharum species, Narenga porphyrocoma, Sclerostachya fusca, and 1 presumably hybrid Miscanthus sp. from New Guinea; and a third containing maize. Eighteen accessions were sequenced for the intergenic region between rbcL and atpB, which was the most polymorphic of the regions studied and contained 52 site mutations and 52 indels, across all taxa. Within the Saccharum complex, at most 7 site mutations and 16 indels were informative. The maternal lineage of Erianthus/Eccoilopus was nearly as divergent from the remaining Saccharum complex members as it was from sorghum, in agreement with a previous study. Sequences from the rbcL-atpB spacer were aligned with GENBANK sequences for wheat, rice, barley, and maize, which were used as outgroups in phylogenetic analyses. To determine whether limited intra-complex variability was caused by under sampling of taxa, we used seven restriction enzymes to digest the PCR-amplified rbcL-atpB spacer of an additional 36 accessions within the Saccharum complex. This analysis revealed ten restriction sites (none informative) and eight length variants (four informative). The small amount of variation present in the organellar DNAs of this polyploid complex suggests that either the complex is very young or that rates of evolution between the Saccharum complex and outgroup taxa are different. Other phylogenetic information will be required to resolve systematic relationships within the complex. Finally, no variation was observed in commercial sugarcane varieties, implying a world-wide cytoplasmic monoculture for this crop.     

In vitro propagation of a Saccharum officinarum (L.) and Sclerostachya fusca (Roxb.) A. Camus hybrid

Summary Callus induction and plant differentiation were obtained in an intergeneric hybrid of Saccharum officinarum and Sclerostachya fusca. The sub clones showed morphological variation. Chromosome numerical variation was not observed but structural aberrations were noticed in some sub clones. The study indicates the use of tissue culture technique for inducing intergeneric gene transfer in Saccharum hybrids.     

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

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. Received: 7 March 1999 / Accepted: 25 March 1999     

Characterisation of the double genome structure of modern sugarcane cultivars (Saccharum spp.) by molecular cytogenetics

Cultivated sugarcane clones (Saccharum spp., 2n=100 to 130) are derived from complex interspecific hybridizations between the speciesS. officinarum andS. spontaneum. Using comparative genomic DNA in situ hybridization, we demonstrated that it is possible to distinguish the chromosomes contributed by these two species in an interspecific F1 hybrid and a cultivated clone, R570. In the interspecific F1 studied, we observed n+n transmission of the parental chromosomes instead of the peculiar 2n+n transmission usually described in such crosses. Among the chromosomes of cultivar R570 (2n=107–115) about 10% were identified as originating fromS. spontaneum and about 10% were identified as recombinant chromosomes between the two speciesS. officinarum andS. spontaneum. This demonstrated for the first time the occurrence of recombination between the chromosomes of these two species. The rDNA sites were located by in situ hybridization in these two species and the cultivar R570. This supported different basic chromosome numbers and chromosome structural differences between the two species and provided a first bridge between physical and genetical mapping in sugarcane.     

Phylogenetic analysis of chloroplast restriction enzyme site mutations in the Saccharinae Griseb. subtribe of the Andropogoneae Dumort. tribe

Chloroplast (cp) DNA from 32 genotypes representing eight genera and 19 species from the Andropogoneae tribe was analyzed using 15 restriction enzymes and Southern hybridization with 12 cpDNA probes that span the complete rice chloroplast genome. Six of the genera, Saccharum, Miscanthus, Erianthus, Narenga, Eccoilopus, and Sclerostachya, are part of the Saccharinae subtribe, whereas the other two, Zea and Sorghum, were used as outgroups. Narenga, Miscanthus, Erianthus, and Sclerostachya are presumed to have been involved in the evolution of Saccharum officinarum (noble or high sucrose sugarcane) via S. spontaneum and S. robustum. Southern hybridization with the rice cpDNA probes surveyed approximately 3% of the S. officinarum Black Cheribon genome and yielded 62 restriction site mutations (18 informative) that were analyzed using cladistic parsimony and maximum likelihood. These site mutations placed the 32 genotypes into nine different chloroplast groups; seven from within the Saccharinae subtribe and the two outgroups (maize and Sorghum). Phylogenetic inferrence under various assumptions showed that the maternal lineages of Narenga, Miscanthus, Sclerostachya, and Saccharum formed a monophyletic group. This group displayed little variation. On the other hand, 5 of 6 Erianthus species and Eccoilopus longisetosus formed a separate group. The Old World Erianthus/Eccoilopus chloroplast was very different from that of the rest of the Saccharum complex members and was slightly more related to that of Sorghum bicolor. Placement of these Erianthus/Eccoilopus genotypes was, therefore, in conflict with analyses based on morphology. Surprisingly, Erianthus trinii, a New World species, had the same restriction sites as did one Miscanthus sinensis. One Miscanthus sp. from New Guinea that has a very high chromosome number (2n=192) had the same restriction sites as the majority of the Saccharum genus, suggesting that introgression between these genera occurs in the wild. The Saccharum genus was separated into two clades by single site mutation: one containing S. spontaneum, and the other containing all of the remaining Saccharum species and all 8 commerical hybrids (from various regions of the world). A physical map of the chloroplast of Saccharum officinarum Black Cheribon was constructed using 5 restriction enzymes.     

Protein polymorphism in sugarcane revealed by two-dimensional gel analysis

Summary In order to identify molecular markers for the analysis of the sugarcane genome, proteins extracted from apical segments of shoot tissues were resolved by a combination of equilibrium (IEF) and nonequilibrium (NEPHGE) two-dimensional polyacrylamide gel electrophoresis. A number of taxa of the Saccharum complex group (Saccharum species and the related genera of Andropogoneae) with presumed contributions to the sugarcane genome were surveyed. Protein profiles were compared to a reference map consisting of 1,482 protein spots from the noble cane,Saccharum officinarum L. Fifty-three polypeptides, representing about 3.6% of the total resolved spots, showed interspecific variation, whereas 78 polypeptides, about 5.3% of the total, showed intergeneric variation. Of the total polymorphic protein spots, qualitative (presence/absence) variation was more prevalent among the wild than among the cultivated species of the genusSaccharum, but the quantitative (spot intensity) variation was similar for both groups. The population of protein spots showing qualitative and quantitative variations was similar among the related genera of Andropogoneae. These polymorphic proteins can be used in genetic and evolutionary studies of the sugarcane genome.     

Phylogenetics of Miscanthus,Saccharum and related genera (Saccharinae,Andropogoneae, Poaceae) based on DNA sequences from ITS nuclear ribosomal DNA and plastid trnLintron and trnL-F intergenic spacers

DNA sequences were used to assess the monophyly and inter-relationships of Miscanthus, Saccharum and related genera in the Saccharum complex. Three DNA regions were sequenced, including the trnL intron and the trnL-F intergenic spacer of the plastid genome and the ITS region of nuclear ribosomal DNA (nrDNA). Because it was more variable, the ITS region proved most suitable for phylogenetic reconstruction at this level, and the results indicate that Miscanthus s.l. and Saccharum s.l. are polyphyletic. A set of species from Saccharum section Ripidium (clade a) do not group closely with any members of Saccharum s.l.. A number of Miscanthus species from eastern or south-eastern Asia represent a monophyletic group with a basic chromosome number of 19 (clade b), but the other species from Africa and the Himalayas are clearly excluded. There is support for a monophyletic Saccharum s.s. clade including S. officinarum and S. spontaneum that is sister to Miscanthus s.s (clade c). There is no evidence to support the division of some Saccharum s.l. into the genera currently known as Erianthus and Narenga. Saccharum contortum (=Erianthus contortus), S. narenga (=Narenga porphyrocoma) and Erianthus rockii, group more closely with Miscanthus fuscus, a species from the Himalayas and also with the African Miscanthus s.l. species (=Miscanthidium, clade d). Electronic Publication     

甘蔗与斑茅BC1分子鉴定、抗黑穗病和花叶病初步评价

为了解甘蔗(Saccharum)与斑茅(Erianthus arundinaceus)杂交后代作为抗病亲本的利用价值,通过特异引物PCR鉴定出78份甘蔗与斑茅杂交BC_1真实杂种;通过人工接种花叶病毒和黑穗病菌,初步评价了甘蔗和斑茅杂交BC_1的抗病表现。结果表明,甘蔗和斑茅杂交BC_1的抗花叶病具有普遍性,而黑穗病抗性则出现分离。初步筛选出BC_1无性系YCE01-48、YCE01-71、YCE01-105、YCE01-125、YCE02-184和YCE01-118可同时抗花叶病和黑穗病,有望成为甘蔗杂交利用的高抗病源亲本。     

Complete chloroplast genomes of Saccharum spontaneum,Saccharum officinarum and Miscanthus floridulus (Panicoideae: Andropogoneae) reveal the plastid view on sugarcane origins

Sugarcane (Saccharum hybrid cultivar) ranks among the world's top 10 food crops and annually provides 60–70% of the sugar produced worldwide. Despite its economic importance there has been no large-scale systematics study of genus Saccharum and the existing model of sugarcane origins has remained largely unchallenged for almost 50 years. For the first time, we have assembled the complete plastid genomes of Miscanthus floridulus (first report for this genus), Saccharum spontaneum and Saccharum officinarum allowing us to elucidate the phylogenetic origins of Saccharum s.s. species. We demonstrate that Saccharum s.s. is divided into four species, with S. spontaneum diverging from the remainder of the genus about 1.5 million years ago and S. robustum diverging 750,000 years ago. Two separate lineages, one leading to S. officinarum and the other leading to modern hybrid cultivars diverged from S. robustum 640,000 years ago. These findings overturn all previous hypotheses on sugarcane origins, demonstrating that sugarcane's antecedents could not have arisen by human action. All modern cultivars share a common Polynesian origin, whereas Old World canes, S. barberi and S. sinense, cluster as a distinct S. officinarum lineage. This makes modern cultivars a distinct species of genus Saccharum, and we formally propose the name Saccharum cultum for the ancestor of all lineages currently classified as Saccharum hybrid cultivars.     

A simple and efficient method for DNA extraction from grapevine cultivars andVitis species

A quick, simple, and reliable method for the extraction of DNA from grapevine species, hybrids, andAmpelopsis brevipedunculata (Vitaceae) has been developed. This method, based on that of Doyle and Doyle (1990), is a CTBA-based extraction procedure modified by the use of NaCl to remove polysaccharides and PVP to eliminate polyphenols during DNA purification. The method has also been used successfully for extraction of total DNA from other fruit species such as apple (Malus domestica), apricot (Prunus armeniaca), cherry (Prunus avium), peach (Prunus persica), plum (Prunus domestica), and raspberry (Rubus idaeus). DNA yield from this procedure is high (up to 1 mg/g of leaf tissue). DNA is completely digestible with restriction endonucleases and amplifiable in the polymerase chain reaction (PCR), indicating freedom from common contaminating compounds.     

Single-Strand Conformational Polymorphism of EST-SSRs: A Potential Tool for Diversity Analysis and Varietal Identification in Sugarcane

Sugarcane (Saccharum spp.) has a large complex polyploid genome. Assay of molecular variation in the expressed component of its genome has relevance to the analysis of genetic diversity, variety identification and introgression of agronomically useful genes present in different members of the Saccharum complex. The present study was designed to evaluate single-strand conformational polymorphism (SSCP) as a potential tool to detect genetic variation in the expressed sequence tag (EST) derived microsatellites. Twenty primer pairs obtained from EST libraries and one designed from soluble acid invertase gene sequence were used to characterise 21 clones belonging to four different Saccharum species and 22 sugarcane varieties/genotypes. All the markers, including the two, which were reported monomorphic even at the interspecific level in an automated fragment analysis system in a previous study, could be successfully converted into polymorphic ones using SSCP analysis. A broad range of variation could be revealed by this technique. The Saccharum spp. clones could be grouped into distinct clusters, confirming the species relationships postulated earlier using morphological, biochemical and molecular methods. The polymorphic markers could also differentiate all the 22 sugarcane varieties from each other. This is a first report that demonstrates the usefulness of SSCP technique, in obtaining polymorphic microsatellite markers developed from EST sequences for various genetic and breeding applications, in this polyploid species.     

Saccharum species as horticultural classes

 Sugarcane, commonly referred to as Saccharum officinarum, is currently divided into six species, two of them are wild and four exist only in cultivation. The two wild species and three of the cultivated ones are interfertile and have produced the interspecific hybrids that constitute the sugarcane of commerce. All species are represented by wide ranges of intergrades preserved as clones through vegetative propagation. Species are separated by variable floral characters, sugar content, chromosome numbers and epidermal hair groups. Floral characteristics are sometimes useful with clones that flower, sugar is present in widely overlapping ranges and is highly influenced by environment, chromosome numbers range from 36 to 170 in the genus and range widely within species, and some epidermal hair groups are more quantitative than qualitative. Molecular techniques show that Saccharum spontaneum is distinctly different from the other species in cytoplasmic DNA, and cluster analyses of nuclear DNA support the difference. Not only are the species interfertile but chromosomal pairing and recombination have been demonstrated, as has the possibility that some Saccharum species are hybrids of others. Taken together, these observations suggest that there is little basis for the present separation and that the six species should more properly consist of two: one being S. spontaneum, based on molecular data, and the other S. officinarum including the other four species and all interspecific hybrids. Received: 20 December 1997 / Accepted: 5 June 1998     

Exploitation of conserved intron scanning as a tool for molecular marker development in the Saccharum complex

This study investigated the potential of the conserved intron scanning approach to develop molecular markers for genes involved in lignin biosynthesis among members of the Saccharum complex and a distantly related Imperata species. Five intron-flanking primer sets targeting genes encoding five lignin biosynthetic enzymes??phenylalanine ammonia lyase (PAL), 4-coumarate coenzyme A ligase (4-CL), caffeoyl-CoA 3-O-methyltransferase (CCoAOMT), cinnamoyl-CoA reductase (CCR) and peroxidase (POX)??were designed based on the sequence analysis between sugarcane expressed sequence tags (ESTs) and Sorghum bicolor orthologs. Nucleotide sequence analyses of the amplicons of PAL, 4-CL and CCoAOMT orthologs revealed the presence of single nucleotide polymorphisms (SNPs) and insertions?Cdeletions (INDELs) in the target introns as well as (CT)-simple sequence repeats (SSRs) in CCoAOMT orthologs. The SSR marker screening against fifty-nine accessions of the Saccharum complex and an Imperata species confirmed that the identified SSR markers were highly polymorphic among Saccharum and Erianthus species. PCR-restriction fragment length polymorphism (PCR?CRFLP) and cleaved amplified polymorphic sequence (CAPS) marker screening of 4-CL and CCoAOMT orthologs developed genus-specific molecular markers that confirmed the intergeneric hybridization status of Saccharum Fiji hybrids. The current study showed that the conserved intron scanning strategy is applicable to multiple copy genes of polyploid monocots. The conserved intron scanning approach provides a novel way of investigating DNA polymorphisms among species within the Saccharum complex and has the potential to help in the development of marker-assisted selection in intergeneric hybrids.     

Reliable and rapid discrimination of congeneric species by mtDNA SNP analysis by multiplex PCR: application on three Trachurus and two Mullus fish species as model cases

We present a reliable, time-saving, and cost-effective multiplex PCR assay for discriminating congeneric species. Three fish species of the genus Trachurus and two of the genus Mullus served as model cases. Our multiplex PCR method interrogates species-specific diagnostic mitochondrial single nucleotide polymorphisms (mtSNPs). We selected two sets of mtSNPs that are organized in two multiplex systems for the Trachurus and the Mullus species, respectively. In both systems, all individuals tested could be safely assigned to one of the three Trachurus or two Mullus species. This novel SNP typing system offers a convenient and robust DNA profiling system suitable for large-scale identification of commercial fish species, for species with cryptic larvae or during juvenile stages, as well as for wildlife forensics. Handling editor: Christian Sturmbauer     

DNA fingerprint variation in some blackberry species (Rubus subg.Rubus,Rosaceae)

We have analysed samples from Sweden, Denmark, and Germany of six facultatively apomictic blackberry species to investigate the accordance between a taxonomy based on morphological characters on the one hand, and distribution of genetic variation estimated by DNA fingerprinting on the other hand. DNA fingerprint variation was found to be quite restricted in all species investigated. The first taxonomic group included three species related toRubus nessensis, two being characterized by one very widespread DNA fingerprint in all three countries and a few rare ones, whereas the third species differed between Sweden and Germany. The second taxonomic group included species related toR. gracilis. Two of these species exhibited very similar DNA fingerprints, whereas the third species deviated clearly. The utilization of DNA fingerprinting as a tool in taxonomy is discussed; most likely this method could become a useful complement to morphology, especially in plant groups with reduced levels of genetic recombination.     

High mitochondrial diversity in geographically widespread butterflies of Madagascar: A test of the DNA barcoding approach

The standardized use of mitochondrial cytochrome c oxidase subunit I (COI) gene sequences as DNA barcodes has been widely promoted as a high-throughput method for species identification and discovery. Species delimitation has been based on the following criteria: (1) monophyletic association and less frequently (2) a minimum 10× greater divergence between than within species. Divergence estimates, however, can be inflated if sister species pairs are not included and the geographic extent of variation within any given taxon is not sampled comprehensively. This paper addresses both potential biases in DNA divergence estimation by sampling range-wide variation in several morphologically distinct, endemic butterfly species in the genus Heteropsis, some of which are sister taxa. We also explored the extent to which mitochondrial DNA from the barcode region can be used to assess the effects of historical rainforest fragmentation by comparing genetic variation across Heteropsis populations with an unrelated forest-associated taxon Saribia tepahi. Unexpectedly, generalized primers led to the inadvertent amplification of the endosymbiont Wolbachia, undermining the use of universal primers and necessitating the design of genus-specific COI primers alongside a Wolbachia-specific PCR assay. Regardless of the high intra-specific genetic variation observed, most species satisfy DNA barcoding criteria and can be differentiated in the nuclear phylogeny. Nevertheless, two morphologically distinguishable candidate species fail to satisfy the barcoding 10× genetic distance criterion, underlining the difficulties of applying a standard distance threshold to species delimitation. Phylogeographic analysis of COI data suggests that forest fragmentation may have played an important role in the recent evolutionary diversification of these butterflies. Further work on other Malagasy taxa using both mitochondrial and nuclear data will provide better insight into the role of historical habitat fragmentation in species diversification and may potentially contribute to the identification of priority areas for conservation.     

Relationships betweenOryza species (Poaceae) based on 5S DNA sequences

Relationships between 9Oryza species, covering 6 different genomes, have been studied using hybridization and nucleotide sequence information from the5S Dna locus. Four to five units of the major size class of 5S DNA in each species, 55 units in all, were cloned and sequenced. Both hybridization and sequence data confirmed the basic differences between the A and B, C, D genome species suggested by morphological and cytological data. The 5S DNA units of the A genome species were very similar, as were the ones from the B, C, and D genome-containing species. The 5S DNA ofO. australiensis (E genome) grouped with the B, C, D cluster, while the units ofO. brachyantha (F genome) were quite different and grouped away from all other species. 5S DNA units fromO. minuta, O. latifolia, O. australiensis, andO. brachyantha hybridized strongly, and preferentially, to the genomic DNA from which the units were isolated and hence could be useful as species/genome specific probes. The 5S DNA units fromO. sativa, O. nivara, andO. rufipogon provided A genome-specific probes as they hybridized preferentially to A genome DNA. The units fromO. punctata andO. officinalis displayed weaker preferential hybridization toO. punctata DNA, possibly reflecting their shared genome (C genome).     

RFLP analysis for species separation in the generaBipolaris andCurvularia

Restriction fragment length polymorphism (RFLP) of the total DNA ofBipolaris andCurvularia species was analysed using arbitrarily chosen genomic clones of DNA fromCurvularia lunata andBipolaris maydis as probes. Clear differences among species in both genera, resulting in different banding positions, were obtained with some probe-enzyme combinations. Intraspecific polymorphism in banding positions with these probe-enzyme combinations was slight. These analyses allow discrimination between the species. DNA fingerprinting with intrageneric probes is a potentially useful tool for species separation and identification inBipolaris andCurvularia when coupled with another characteristic such as conidial morphology.Curvularia aeria comb. nov. was proposed forCurvularia lunata var.aeria on the basis of differences in RFLP banding patterns and differences in conidial morphology.