Investigation of morphogenesis of inflorescence and determination of the nature of inheritance of “supernumerary spikelets” trait of bread wheat (Triticum aestivum L.) mutant line

Using C-banding and FISH methods, the karyotype of MC1611 induced mutant of bread wheat, which develop additional spikelets at a rachis node (trait “supernumerary spikelets”) was characterized. It was determined that the mutant phenotype is not associated with aneuploidy and major chromosomal rearrangements. The results of genetic analysis showed that supernumerary spikelets of the line are caused by a mutation of the single Bh-D.1 gene, influenced by the genetic background. The mutation causes abnormalities of inflorescence morphogenesis associated with the development of ectopic spikelet meristems in place of floral meristems in the basal part of the spikelets, causing the appearance of additional spikes at a rachis node. The mutant phenotype suggests that the Bh-D gene determines the fate of the lateral meristems in ear, which develops as floral meristem and gives rise to floral organs in wild-type inflorescences. In the bh-D.1 mutant, the floral meristem identity is impaired. The characterized mutant can be used in further studies on molecular genetic basis of development of wheat inflorescence.     

Genome differentiation in Aegilops. 3. Evolution of the D-genome cluster

 Six polyploid Aegilops species containing the D genome were studied by C-banding and fluorescence in situ hybridization (FISH) using clones pTa71 (18S-5.8S-26S rDNA), pTa794 (5S rDNA), and pAs1 (non-coding repetitive DNA sequence) as probes. The C-banding and pAs1-FISH patterns of Ae. cylindrica chromosomes were identical to those of the parental species. However, inactivation of the NOR on chromosome 5D with a simultaneous decrease in the size of the pTa71-FISH site was observed. The N^v and D^v genomes of Ae. ventricosa were somewhat modified as compared with the N genome of Ae. uniaristata and the D genome of Ae. tauschii. Modifications included minor changes in the C-banding and pAs1-FISH patterns, complete deletion of the NOR on chromosome 5D^v, and the loss of several minor 18S-5.8S-26S rDNA loci on N^v genome chromosomes. According to C-banding and FISH analyses, the D^cr1 genome of Ae. crassa is more similar to the D^v genome of Ae. ventricosa than to the D genome of Ae. tauschii. Mapping of the 18S-5.8S-26S rDNA and 5S rDNA loci by multicolor FISH suggests that the second (X^cr) genome of tetraploid Ae. crassa is a derivative of the S genome (section Emarginata of the Sitopsis group). Both genomes of Ae. crassa were significantly modified as the result of chromosomal rearrangements and redistribution of highly repetitive DNA sequences. Hexaploid Ae. crassa and Ae. vavilovii arose from the hybridization of chromosomal type N of tetraploid Ae. crassa with Ae. tauschii and Ae. searsii, respectively. Chromosomal type T1 of tetraploid Ae. crassa and Ae. umbellulata were the ancestral forms of Ae. juvenalis. The high level of genome modification in Ae. juvenalis indicates that it is the oldest hexaploid species in this group. The occurrence of hexaploid Ae. crassa was accompanied by a species-specific translocation between chromosomes 4D^cr1 and 7X^cr. No chromosome changes relative to the parental species were detected in Ae. vavilovii, however, its intraspecific diversity was accompanied by a translocation between chromosomes 3X^cr and 3D^cr1. Received July 24, 2001 Accepted October 1, 2001     

Construction and molecular and cytogenetic analyses of euploid (2n = 42) and telocentric addition (2n = 42 + 2t) alloplasmic lines (Hordeum marinum subsp gussoneanum)-Triticum aestivum

Individual plants from the BC1F5 and BC1F6 backcross progenies of barley--wheat (= H. geniculatum All.) (2n = 28) x T. aestivum L. (2n = 42)] and the BC1F6 progeny of their amphiploids were used to obtain alloplasmic euploid (2n = 42) lines L-28, L-29, and L-49 and alloplasmic telocentric addition (2n = 42 + 2t) lines L-37, L-38, and L-50. The lines were examined by genomic in situ hybridization (GISH), microsatellite analysis, chromosome C-banding, and PCR analysis of the mitochondrial 18S/5S repeat. Lines L-29 and L-49 were characterized by substitution of wild barley chromosome 7H1 for common wheat chromosome 7D. In line L-49, common wheat chromosomes 1B, 5D, and 7D were substituted with homeologous barley chromosomes. Lines L-37, L-38, and L-50 each contained a pair of telocentric chromosomes, which corresponded to barley chromosome arm 7H'L. All lines displayed heteroplasmy for the mitochondrial 18S/5S locus; i.e., both barley and wheat sequences were found.     

Comparative analysis of diploid species of Avena l. using cytogenetic and biochemical markers: Avena canariensis baum et fedak and A. longiglumis dur

The diploid oat species containing the A genome of two types (Al and Ac) were studied by electrophoresis of grain storage proteins (avenins), chromosome C-banding, and in situ hybridization with probes pTa71 and pTa794. The karyotypes of the studied species displayed similar C-banding patterns but differed in size and morphology of several chromosomes, presumably, resulting from structural rearrangements that took place during the divergence of A genomes from a common ancestor. In situ hybridization demonstrated an identical location of the 45S and 5S rRNA gene loci in Avena canariensis and A. longiglumis similar to that in the A. strigosa genome. However, the 5S rDNA locus in A. longiglumis (5S rDNA1) was considerably decreased in the chromosome 3A1 long arm. The analysis demonstrated that these oat species were similar in the avenin component composition, although individual accessions differed in the electrophoretic mobilities of certain components. A considerable similarity of A. canariensis and A. longiglumis to the Avena diploid species carrying the As genome variant was demonstrated.     

Positioning the nodule,the hormone dictum

The formation of a nitrogen-fixing nodule involves two diverse developmental processes in the legume root: infection thread initiation in epidermal cells and nodule primordia formation in the cortex. Several plant hormones have been reported to positively or negatively regulate nodulation. These hormones function at different stages in the nodulation process and may facilitate the coordinated development of the epidermal and cortical developmental programs that are necessary to allow bacterial infection into the developing nodule. In this paper, we review and discuss how the tissue specific nature of hormonal action dictates where, when and how a nodule is formed.Key words: nodulation, hormone regulation, epidermis, cortex     

Analysis of 5S rDNA changes in synthetic allopolyploids Triticum x Aegilops

By the example of three synthetic allopolyploids: Aegilops sharonensis x Ae. umbellulata (2n =28), Triticum urartu x Ae. tauschii (2n =28), T. dicoccoides x Ae. tauschii (2n =42) the 5S rDNA changes at the early stage of allopolyploidization were investigated. Using fluorescent in situ hybridization (FISH), the quantitative changes affecting the separate loci of one of the parental genomes were revealed in plants of S3 generation of each hybrid combination. Souther hybridization with genomic DNA of allopolyploid T. urartu x Ae. tauschii (TMU38 x TQ27) revealed lower intensity of the fragments from Ae. tauschii compared with the T. urartu fragments. It may be confirmation of the reduction of signal on 1D chromosome that was revealed in this hybrid using FISH. Both appearance of a new 5S rDNA fragments and full disappearance of fragments from parental species were not showed by Southern hybridization, as well as PCR-analysis of 5-15 plants of S2-S3 generations. The changes were not found under comparison of primary structure of nine 5S rDNA sequences of allopolyploid TMU38 x TQ27 with analogous sequences from parental species genomes. The observable similarity by FISH results of one of the studied synthetic allopolyploids with natural allopolyploid of similar genome composition indicates the early formation of unique for each allopolyploid 5S rDNA organization.     

Introduction to plant genomics]

The success in complete sequencing of "small" genomes and development of new technologies which sharply accelerate processes of cloning and sequencing made real an intensive development of plant genomics and complete sequencing of DNA of some species. It is assumed that the success in plant genomics will result in revolutionary changes in biotechnology and plant breeding. However, the enormous size of genomes (tens of billions bp), their extraordinary enrichment in repetitive sequences, and allopolyploidy (the presence in a nucleus of several related but not identical genomes) force us to think that only few "basic" will undergo complete sequencing, whereas the genome investigations in other species will follow principles of comparative genomics. By the present time, complete sequencing of the Arabidopsis genome (125 Mbp) is completed and that of the rice genome (about 430 Mbp) is close to its end. Studying other plant genomes, including those economically valuable, already began on the basis of these investigations. Peculiarities of plant genomes make extraordinarily important the knowledge on plant chromosomes which, in its turn, requires expansion of investigations in this direction and development of new chromosome technologies, including the DNA-sparing methods of high-resolution banding.     

Analysis of intraspecific diversity of cultivated emmer Triticum dicoccum (Schrank.) Schuebl using C-banding technique

Ninety-four lines of Triticum dicoccum isolated from 86 wheat accessions from Vavilov All-Russia Research Institute of Plant Industry (VIR, Russia) and INRA (Clermont-Ferrand, France) germ-plasm collections were studied using C-banding technique. Visual comparison of karyotypes of different accessions was performed to establish genetic relationships and evaluate features inherent for ecological--geographical groups. The level of C-banding polymorphism in the whole sample of tetraploid emmer proved to be relatively low. The diversity within groups was mostly higher than the differences between them. The material studied contained 39 lines carrying 16 different types of chromosomal rearrangements including single and multiple translocations and inversions. The level of translocation polymorphism was comparable with that detected earlier for polyploid wheat species. The frequencies of individual translocation types varied from 18 (T7A:5B) to 1 (nine types). Analysis of the distribution of the most frequent translocations & A:5B suggested that it has significant adaptive value on the territory of Europe. Similarity of the C-banding patterns of European emmer and the accessions with the same translocation of the Asian origin points to their possible common origin. The occurrence of the same translocation in several T. dicoccoides accessions from Syria and Lebanon may indicate that such forms of wild emmer could have taken part in the origin of cultivate emmer from Western Europe. Similarity of the C-banding patterns of some chromosomes of European emmer and spelt could serve as an indirect evidence of their close genetic relationships.     

Chromosomal Passports Provide New Insights into Diffusion of Emmer Wheat

Emmer wheat, Triticum dicoccon schrank (syn. T. dicoccum (schrank) schÜbl.), is one of the earliest domesticated crops, harboring a wide range of genetic diversity and agronomically valuable traits. The crop, however, is currently largely neglected. We provide a wealth of karyotypic information from a comprehensive collection of emmer wheat and related taxa. In addition to C-banding polymorphisms, we identified 43 variants of chromosomal rearrangements in T. dicoccon; among them 26 (60.4%) were novel. The T7A:5B translocation was most abundant in Western Europe and the Mediterranean. The plant genetic resources investigated here might become important in the future for wheat improvement. Based on cluster analysis four major karyotypic groups were discriminated within the T. dicoccon genepool, each harboring characteristic C-banding patterns and translocation spectra: the balkan, asian, european and ethiopian groups. We postulate four major diffusion routes of the crop and discuss their migration out of the Fertile Crescent considering latest archaeobotanical findings.