Differential rRNA genes expression in bread wheat and its inheritance

The expression of the ribosomal RNA (rRNA) genes from rye, located within the nucleolus organizer regions (NORs), is repressed by cytosine methylation in wheat x rye hybrids and in triticale, as consequence of nucleolar dominance. Our previous study revealed that bread wheat cultivars with a maximum number of four Ag-NORs presented high level of rDNA cytosine methylation when compared to others with a maximum of six Ag-NORs. In order to evaluate the inheritance of the Ag-NORs number and NOR methylation patterns, we produced F₁ hybrids between bread wheat cultivars with four Ag-NORs and bread wheat cultivars with six Ag-NORs (in the direct and reciprocal senses). The F₂ progenies of these F₁ hybrids were also evaluated for the NOR number and methylation patterns. Parent bread wheat cultivars with a maximum of four Ag-NORs after treated with 5-azacytidine evidenced a maximum of six Ag-NORs per metaphase cell and a maximum of six nucleoli per interphase nucleus, confirming that the expression of the rRNA genes in bread wheat is related to cytosine methylation. Most of the F₁ hybrids showed a maximum number of four or six Ag-NORs, similarly to that of the female parent suggesting a non-mendelian inheritance, while other hybrids presented four or six Ag-NORs in both senses of the cross. The F₁ NOR methylation patterns showed some fragments common to their parents but also novel fragments suggesting genomic and/or chromosome rearrangements after hybridization. Despite the different NOR patterns among the parents, an invariable NOR pattern was found among the F₁ plants suggesting a tendency to stability, which was also transmitted to the F₂. The F₂ progenies showed plants with a maximum of four, five and/or six Ag-NORs. The ratio of plants with four, five and/or six Ag-NORs per F₂ progeny was variable and did not follow any specific mendelian proportion. These results allowed us to suggest that the inheritance of the number of Ag-NORs by the F₁ and F₂ plants did not follow any mendelian inheritance and were not correlated to NOR methylation patterns in contrast to what was verified for their parents.     

Cytogenetic and molecular characterization of almond trees treated with plant biostimulants or boron-based fertilizers

Plant Growth Regulation - Almond is highly produced in the NE of Portugal, where late frosts during flowering, low precipitation, and high temperature in summer affect productivity and quality....     

Morphological, yield, cytological and molecular characterization of a bread wheat X tritordeum F1 hybrid

The morphological, yield, cytological and molecular characteristics of bread wheat X tritordeum F₁ hybrids (2n =6x = 42; AABBDH^ch) and their parents were analysed. Morphologically, these hybrids resembled the wheat parent. They were slightly bigger than both parents, had more spikelets per spike, and tillered more profusely. The hybrids are self-fertile but a reduction of average values of yield parameters was observed. For the cytological approach we used a double-target fluorescencein situ hybridization performed with total genomic DNA fromHordeum chilense L. and the ribosomal sequence pTa71. This technique allowed us to confirm the hybrid nature and to analyse chromosome pairing in this material. Our results showed that the expected complete homologous pairing (14 bivalents plus 14 univalents) was only observed in 9.59% of the pollen mother cells (PMCs) analysed. Some PMCs presented autosyndetic pairing of Hch and A, B or D chromosomes. The average number of univalents was higher in the wheat genome (6.8) than in the Hch genome (5.4). The maximum number of univalents per PMC was 20. We only observed wheat multivalents (one per PMC) but the frequency of trivalents (0.08) was higher than that of quadrivalents (0.058). We amplified 50 RAPD bands polymorphic between the F₁ hybrid and one of its parents, and 31 ISSR polymorphic bands. Both sets of markers proved to be reliable for DNA fingerprinting. The complementary use of morphological and yield analysis, molecular cytogenetic techniques and molecular markers allowed a more accurate evaluation and characterization of the hybrids analysed here.     

Molecular cytogenetic analysis of durum wheat x tritordeum hybrids.

Southern and in situ hybridization were used to examine the chromosome constitution, genomic relationships, repetitive DNA sequences, and nuclear architecture in durum wheat x tritordeum hybrids (2n = 5x = 35), where tritordeum is the fertile amphiploid (2n = 6x = 42) between Hordeum chilense and durum wheat. Using in situ hybridization, H. chilense total genomic DNA hybridized strongly to the H. chilense chromosomes and weakly to the wheat chromosomes, which showed some strongly labelled bands. pHcKB6, a cloned repetitive sequence isolated from H. chilense, enabled the unequivocal identification of each H. chilense chromosome at metaphase. Analysis of chromosome disposition in prophase nuclei, using the same probes, showed that the chromosomes of H. chilense origin were in individual domains with only limited intermixing with chromosomes of wheat origin. Six major sites of 18S-26S rDNA genes were detected on the chromosomes of the hybrids. Hybridization to Southern transfers of restriction enzyme digests using genomic DNA showed some variants of tandem repeats, perhaps owing to methylation. Both techniques gave complementary information, extending that available from phenotypic, chromosome morphology, or isozyme analysis, and perhaps are useful for following chromosomes or chromosome segments during further crossing of the lines in plant breeding programs.     

Potential of Start Codon Targeted (SCoT) markers for DNA fingerprinting of newly synthesized tritordeums and their respective parents

Hexaploid tritordeum (H^chH^chAABB; 2n?=?42) results from the cross between Hordeum chilense (H^chH^ch; 2n?=?14) and cultivated durum wheat (Triticum turgidum ssp. durum (AABB; 2n?=?28). Morphologically, tritordeum resembles the wheat parent, showing promise for agriculture and wheat breeding. Start Codon Targeted (SCoT) polymorphism is a recently developed technique that generates gene-targeted markers. Thus, we considered it interesting to evaluate its potential for the DNA fingerprinting of newly synthesized hexaploid tritordeums and their respective parents. In this study, 60 SCoT primers were tested, and 18 and 19 of them revealed SCoT polymorphisms in the newly synthesized tritordeum lines HT27 and HT22, respectively, and their parents. An analysis of the presence/absence of bands among tritordeums and their parents revealed three types of polymorphic markers: (i) shared by tritordeums and one of their parents, (ii) exclusively amplified in tritordeums, and (iii) exclusively amplified in the parents. No polymorphism was detected among individuals of each parental species. Three SCoT markers were exclusively amplified in tritordeums of lines HT22 and HT27, being considered as polyploidization-induced rearrangements. About 70 % of the SCoT markers of H. chilense origin were not transmitted to the allopolyploids of both lines, and most of the SCoTs scored in the newly synthesized allopolyploids originated from wheat, reinforcing the potential use of tritordeum as an alternative crop.     

Genetic Diversity in Old Portuguese Durum Wheat Cultivars Assessed by Retrotransposon-Based Markers

Retrotransposon-based markers, such as the inter-retrotransposon-amplified polymorphism (IRAP) and the retrotransposon microsatellite-amplified polymorphism (REMAP) are highly informative, multilocus, and reveal insertional polymorphisms among plant individuals. These markers have been used for evolutionary studies, genetic diversity assessment, DNA fingerprinting, genetic mapping linkage, and for the detection of genetic rearrangements induced by polyploidization. In this study, we used IRAP and REMAP markers to assess the genetic diversity among 51 old Portuguese durum wheat cultivars belonging to 27 botanical varieties and to define their genetic relationships. Five IRAP and four REMAP primer combinations were used. IRAP markers revealed 66.3% of polymorphism and an average of 18.4 bands per primer combination which ranged in size from 450 to 3,100?bp. The REMAP technique allowed the detection of 86.36% of inter-cultivar polymorphism and an average of 11 bands per primer combination. The molecular weight of the REMAP bands ranged from 250 to 2,750?bp. The durum wheat cultivars analyzed here belong to 27 botanical varieties of the subspecies Triticum turgidum subsp. turgidum L. [syn. T. turgidum] and Triticum turgidum L. subsp. durum [syn. T. durum] (Desf.) Husn.. Our results showed that the genetic variability assessed by both the IRAP and REMAP markers did not allow the clustering of the durum wheat cultivars according to their taxonomical criteria (subspecies or botanical variety) or homonymy. Nonetheless, these markers were useful for the assessment of genetic diversity at the individual level, for the definition of genetic relationships among cultivars, and for estimation of the genetic structure of the Old collection under analysis. The achieved data could be valuable for future experiments of DNA fingerprinting, genetic improvement, and germplasm conservation in wheat.     

Genetic Diversity and Variation Among Botanical Varieties of Old Portuguese Wheat Cultivars Revealed by ISSR Assays

Inter-simple sequence repeats (ISSRs) were used for genetic diversity analyses of an Old Portuguese wheat collection. Eighteen primers produced 96.3 and 98.5% of ISSR polymorphism in bread and durum wheat cultivars, respectively. The unweighted pair group method with arithmetical averages (UPGMA) phenogram clearly split all cultivars based on their species/ploidy, reflecting a defined genetic structure. ISSRs revealed high genetic diversity at interspecific, intraspecific, and intercultivar levels. Thirty-three exclusive ISSR markers were found. Cultivars were clustered according to their botanical varieties and, in a few cases, with their homonym(s). No statistically significant differences were found between genetic diversity parameters of durum and bread wheat, probably due to high intraspecific diversity. Similar analyses were performed among botanical varieties, and their relationships were defined. Cladograms resembled UPGMA clustering. This highly genetically diverse Old wheat collection will be conserved and maintained, and it could be further used in breeding programs to widen the narrow genetic basis of modern wheat varieties and to avoid the loss of rare and unique alleles.     

Chromosome identification and nuclear architecture in triticale tritordeum F1 hybrids

In situ hybridization with cloned, repetitive DNA probes andtotal genomic DNA enables the parental origin of all chromosomesto be established in metaphases of triticale tritordeum F¹hybrids (2n=6x=42). Nuclei contain seven chromosomes of Hordeumchilense origin, seven from Secale cereale and 28 of wheat origin.When used as a probe, total genomic rye DNA labelled the ryechromosomes strongly and uniformly along their lengths, withbrighter regions coincident with the terminal heterochromatin.The probe labelled the wheat-origin chromosomes weakly and wasalmost undetectable on the H. chilense-origin chromosomes. Incontrast, under the same conditions, H. chilense DNA hybridizedstrongly to the H. chilense- and, with intermediate strength,to the S. cereale-origin chromosomes, excluding the subtelomericheterochromatin: it hybridized only weakly to the wheat chromosomes,in some experiments revealing characteristic bands on wheatchromosomes. Cloned repetitive DNA probes from rye and H. chilensewere used as probes to identify the linkage groups of all oftheir own-species chromosomes. Analysis of hybridization patternsof various probes to prophase and interphase nuclei indicatedthat there are many non-random features in the localizationof both repetitive DNA and whole chromosomes, although generalpatterns of nuclear organization have yet to emerge. Both theparticular lines used and the techniques developed here arelikely to be valuable for production and characterization ofplant breeding material. Key words: In situ hybridization, triticale, cytogenetics, plant breeding, Hordeum chilense