The Effect of Parental Genotypes of Rye Lines on the Development of Quantitative Traits in Primary Octoploid Triticale: Spike Fertility

The number of seeds and seed setting in the main spike were studied in primary octoploid triticale obtained from crosses between the common wheat cultivar Chinese Spring and 66 inbred rye lines. In some rye lines, the mutations of self-fertility were identified in the S, Z, or T incompatibility loci. The number of seeds was determined under controlled self-pollination of the main spike. In the set of triticale examined, each trait exhibited high variation. Hence, the rye lines were suggested to carry gene alleles both increasing and decreasing these traits in triticale. All the traits studied were significantly influenced by environmental conditions. Ten triticale lines were identified, which had the largest seed setting under self-pollination. Seven out of ten samples with the high number of seeds carried mutations in the Tlocus and in the three samples, the unidentified self-fertility mutations were present. The triticale lines with mutations in theS and Z loci displayed much lower self-fertility on average. The ways and means of identifying and mapping the rye gene responsible for distinctions between the triticale quantitative traits are discussed.     

Prospects of using self-fertility in breeding rye populations varieties

The advances in rye hybrid breeding are due to the use of self-fertile forms. Rye self-fertility is determined by mutations in one of the three gametophytic loci (S, Z, and T), which control the reaction of incompatibility. Attempts to construct synthetic populations by combining self-fertile forms selected by general combining ability failed because of high-rate selfing. A breeding scheme was proposed to include crosses of a line carrying a self-fertility mutation in the S locus with the population subject to improvement, selfing of the resulting hybrids, selection and intermating of the best inbred progenies, and subsequent elimination of the self-fertility mutation from the breeding material with the use of the Prx7 allozyme marker. The scheme can be employed in improvement of the existing rye varieties, their differentiation into populations differing in end use, and construction and improvement of complementary gene pools in hybrid breeding. To facilitate the implementation of the scheme, an original instrument was designed for high-throughput isozyme analysis.     

Analysis of the effects of parental genotypes of rye lines on the development of quantitative traits in primary octaploid triticale. Plant height

When breeding the primary spring octoploid triticale derived from crosses of various inbred rye lines to wheat Chinese Spring, the effects of the rye genotype and growth conditions on the plant height and proportion of the first, second, and final (pedicle) internodes to the entire stem length were studied. Two triticale groups were examined: homozygotes for the dominant (Ddw1) and recessive (ddw1) alleles of the gene responsible for short stem in rye. In the short stem triticale lines carrying the Ddw1 alleles, the plants were 20 cm shorter on average than those in the ddw1-carrying lines, and the distribution of the two triticale groups overlapped significantly. In both groups, the lines significantly differing in plant height could be differentiated, because of allelic diversity of the additional genes controlling this trait along with the Ddw gene. In most triticale lines, especially in the Ddw1-carrying ones, the plant height was much reduced under unfavorable growth conditions. At the same time, a short-stem line was isolated, which is characterized by ecological plasticity, like the maternal wheat cultivar. In the triticale studied, the stem structure depended on the short-stem rye genotype. The two-year study showed that in the triticale carrying the dominant allele of this gene, the first internode is significantly extended, whereas the upper (pedicle) internode is reduced, which increases plant lodging resistance. The differences revealed between the rye lines as well as their effect on the quantitative triticale traits are discussed in view of a variant of the hybridological analysis, which had been previously proposed for identification and mapping of the correspondent rye genes.     

Physical mapping of the 5S rRNA multigene family in 6x triticale and rye: identification of a new rye locus.

In situ hybridization was used to physically map the 5S rRNA multigene family in three selected lines of hexaploid triticale and five lines of diploid rye. Using this technique, evidence for a new locus on the 3RS arm of the three triticale lines was first obtained, as well as confirmation of the presence of 5S rRNA loci on wheat and rye chromosomes of homoeologous groups 1 and 5. The new locus on the 3RS arm was confirmed in two lines of rye, Secale cereale L., although it was not present in the other rye varieties studied. We propose that the new 5S rRNA locus be referred to as 5SDna-R3.     

The Effect of Parental Genotypes of Rye Lines on the Development of Quantitative Traits in Primary Octoploid Triticale: Plant Height

When breeding the primary spring octoploid triticale derived from crosses of various inbred rye lines to wheat Chinese Spring, the effects of the rye genotype and growth conditions on the plant height and proportion of the first, second, and final (pedicle) internodes to the entire stem length were studied. Two triticale groups were examined: homozygotes for the dominant (Ddw1) and recessive (ddw1) alleles of the gene responsible for short stem in rye. In the short stem triticale lines carrying the Ddw1 alleles, the plants were 20 cm shorter on average than those in the ddw1-carrying lines, and the distribution of the two triticale groups overlapped significantly. In both groups, the lines significantly differing in plant height could be differentiated, because of allelic diversity of the additional genes controlling this trait along with the Ddw gene. In most triticale lines, especially in theDdw1-carrying ones, the plant height was much reduced under unfavorable growth conditions. At the same time, a short-stem line was isolated, which is characterized by ecological plasticity, like the maternal wheat cultivar. In the triticale studied, the stem structure depended on the short-stem rye genotype. The two-year study showed that in the triticale carrying the dominant allele of this gene, the first internode is significantly extended, whereas the upper (pedicle) internode is reduced, which increases plant lodging resistance. The differences revealed between the rye lines as well as their effect on the quantitative triticale traits are discussed in view of a variant of the hybridological analysis, which had been previously proposed for identification and mapping of the correspondent rye genes.     

Loss of chromosomes 2R and 5RS in octoploid triticale selected for agronomic traits

The advanced lines of octoploid triticale which have been bred for nearly a half century in China show significant improvements in agronomic traits such as plant height, fertility, threshability, maturity and seed plumpness, although no intentional cytological selection had been performed. In this study, eight primary and six advanced lines were analyzed by fluorescence and genomic in situ hybridization to elucidate their chromosome constitutions. In the advanced lines, about 70% of the plants examined had 2n = 56 chromosomes (range: 50 to 58). Almost all advanced lines, however, had lost rye chromosome 2R and the short arm of 5R (5RS). The exceptions were lines Y1005 and Y4683: The former had lost only the 2R chromosome and the latter only 5RS. The reduction of rye chromosomes was compensated by an extra pair of 2D or A-genome (possibly 2A) chromosomes in plants with 2n = 56. This suggests that the loss of 2R and 5RS chromosomes contributes to the improvement of octoploid triticale. Since the plants with chromosome 2R are non-free threshing and chromosome 2D of synthetic wheat is known to carry the Tg (tenacious glumes) gene, it is possible that chromosome 2R carries a gene affecting the threshability, and we carried out selection to remove it. We also discuss the possible relationshipbetween 5RS and the genetic stability of octoploid triticale.     

Analysis of linkage between biochemical and morphological markers of 1R-, 2R-, and 5R-chromosomes in rye with autofertility mutations in main incompatibility loci

In F2 hybrids between self-sterile plants of the Volkhova cultivar and self-fertile lines with established self-fertility mutations (sf-mutations) at the major incompatibility loci S (1R), Z (2R), and T (5R), the effect of sf-mutations on the inheritance of secalin-encoding, isozyme, and morphological markers located on the same chromosomes was investigated. Linkage between loci Prx7 and S and locus Sec3 coding for high-molecular-weight secalins on chromosome 1R was shown for the first time The frequency of recombination between Prx7 and Sec3 and between S and Sec3 was 29.1 +/- 4.8% and 30.9 +/- 7.0%, respectively. Independent inheritance of locus Z and isozyme markers of chromosome 2R, Est3/5 and beta-Glu, from locus Sec2 encoding 75-kDa gamma-secalins was shown; in hybrids, the recombination frequency between Est3/5 and locus Z varied from 19.2 +/- 8.1 to 50%. Independent inheritance of morphological (Ddw and Hs) and isozyme markers (Est4, Est6/9, and Aco2) of chromosome 5R from locus T located on the same chromosome was demonstrated.     

Molecular markers as a complementary tool in risk assessments: quantifying interspecific gene flow from triticale to spring wheat and durum wheat

Triticale is being considered as a bioindustrial crop in Canada using genetic modification. Because related spring wheat (Triticum aestivum) and durum wheat (T. durum) may exhibit synchronous flowering and grow in proximity, determination of interspecific gene flow when triticale is the pollen donor is necessary to evaluate potential risk. Pollen-mediated gene flow risk assessments generally rely on phenotypic markers to detect hybridization but DNA markers could be powerful and less ambiguous in quantifying rare interspecific gene flow. Six cultivars representing four species [spring wheat, durum wheat, triticale and rye (Secale cereale)] were screened with 235 spring wheat and 27 rye SSR markers to evaluate transferability and polymorphism. Fifty-five polymorphic markers were used in conjunction with morphological characterization to quantify interspecific gene flow from a blue aleurone (BA) triticale line to two spring wheat cultivars (AC Barrie and AC Crystal) and one durum wheat cultivar (AC Avonlea). Approximately 1.9 Million seeds from small plot experiments were visually screened in comparison with known hybrid seed. In total 2031 putative hybrids were identified and 448 germinated. Morphological analysis of putative hybrid plants identified five hybrids while molecular analysis identified 11 hybrids and two were common to both. Combined, 14 hybrids were confirmed: 10 spring wheat × triticale (0.0008 % of harvested seed): seven AC Barrie × BA triticale (0.001 %) and three AC Crystal × BA triticale (0.0005 %); and four durum wheat × triticale (0.0006 %). The occurrence of rare hybrids does not present a substantial risk to the development of GM triticale.     

Prospects of using self-fertility in breeding rye populations varieties

The advances in rye hybrid breeding are due to the use of self-fertile forms. Rye self-fertility is determined by mutations in one of the three gametophytic loci (S, Z, and T), which control the reaction of incompatibility. Attempts to construct synthetic populations by combining self-fertile forms selected by general combining ability failed because of high-rate selfing. A breeding scheme was proposed to include crosses of a line carrying a self-fertility mutation in the S locus with the population subject to improvement, selfing of the resulting hybrids, selection and intermating of the best inbred progenies, and subsequent elimination of the self-fertility mutation from the breeding material with the use of the Prx7 allozyme marker. The scheme can be employed in improvement of the existing rye varieties, their differentiation into populations differing in end use, and construction and improvement of complementary gene pools in hybrid breeding. To facilitate the implementation of the scheme, an original instrument was designed for high-throughput isozyme analysis.     

Early Inbreeding Depression and Pollen Competition inCalluna vulgaris(L.) Hull.

We investigated whether partial self-sterility inCalluna vulgarisresultsfrom abortion of selfed offspring owing to inbreeding depressionor a late-acting self-incompatibility mechanism, and whetherself-pollen interferes with normal functioning of cross-pollen.Self-pollination resulted in 75% less seed set than cross-pollination.Self-pollen tubes reached ovaries and penetrated ovules as oftenas those of cross-pollen. Following self-pollination, examinationof the size of undeveloped seeds showed that at least 70% resultedfrom ovule fertilization and arrest of development occurredat various stages. All self-pollinated plants produced seedsand self-fertility varied among plants. These results indicatethat the reduced seed set observed in self-pollination is morelikely the result of inbreeding depression rather than a late-actingself-incompatibility system. The fecundity component of inbreedingdepression was high (0.762). Seed set was reduced by an averageof 40% when self-pollen was mixed with cross-pollen, comparedto pure cross-pollination. Using genetic markers, we found about20% of seeds resulted from self-pollination in mixed-pollinatedfruits.C. vulgarisis likely to experience self-pollination innature and our data suggest this will reduce the number of ovulesthat might otherwise mature after cross-pollination.Copyright1999 Annals of Botany Company Calluna vulgaris(heather), self-pollination, pollen tube, ovule fertilization, early inbreeding depression, pollen interference.     

Genetic interactions between wheat and rye genomes in triticale

Summary Six primary triticale lines were produced from two advanced breeding lines of Triticum durum and three inbred genotypes of Secale cereale. The wheat and rye parents and the triticale derivatives were crossed in all possible combinations within each species group. Chiasma and univalent frequency of parents and hybrids were determined. The primary triticale lines had more univalents and less chiasmata per pollen mother cell than the corresponding wheat and rye parents together. The parental wheat F₁ exhibited negative heterosis for chiasma frequency whereas all rye hybrids had much higher chiasma frequencies than their inbred parents. Triticale F₁s generally showed lower chiasma frequencies and more univalents than their parents, but the degree of pairing failure was dependent upon which of the parental species within the triticale, wheat or rye, was in the heterozygous state. F₁s with heterozygous wheat genome only showed the least reduction in chiasma number (presumably caused by gene actions within the wheat genome), while F₁s with heterozygous rye genome showed high reduction in chiasma frequency and an increase in pairing failure (induced by negative interactions between the heterozygous rye and the wheat genome in triticale). A high correlation was found between the frequency of undisturbed pollen mother cells and the frequency of aneuploids in the subsequent generation. A higher number of aneuploids occurred in those populations which were heterozygous for the rye genome.     

The influence of the rye genome on expression of heat shock proteins in triticale

Summary The heat shock protein profiles from Secale cereale L. cv Imperial, Triticum aestivum L. cv Chinese Spring, S. cereale x T. aestivum amphiploid, and the seven disomic S. cereale addition lines to T. aestivum were used to compare the wheat, rye, and triticale Heat Shock Protein profiles and to study the influence of the rye genome on heat shock protein expression in triticale. Three-day-old seedlings were heat shocked for 2 h at 40 °C in the presence of ³⁵S-methionine, and polypeptides from root tissues were subjected to one- or two-dimensional gel electrophoresis. The wheat and rye heat shock protein profiles each consisted of > 150 heat shock proteins, of which 94 were sufficiently reproducible to construct a standard map. There were 11 unique rye heat shock proteins compared to 22 unique wheat heat shock proteins. The triticale heat shock protein profile resembled the rye parent more than the wheat parent. There were 22 heat shock proteins expressed uniquely by wheat that were not expressed in triticale. Rye chromosomes 1 and 3 exhibited a substantial repressive influence on the expression of 95% of the unique wheat heat shock proteins in triticale, while rye chromosome 4 appeared to have the least repressive influence on expression of the unique wheat heat shock proteins in triticale.Mention of a trade name or proprietary product does not constitute a guarantee, warranty, or recommendation of the product by the United States Department of Agriculture or the University of Missouri and does not imply its approval to the exclusion of other products that may be suitable     

白菜与甘蓝之间体细胞杂交种获得与遗传特性鉴定

为拓宽白菜育种的基因资源,改良白菜品质,以白菜(Brassica campestris,2n=20,AA)和甘蓝(B.oleracea L.var.capitata,2n=18,CC)的子叶和下胚轴为材料分离、制备原生质体。采用40%聚乙二醇(Polyethylene glycol,PEG)进行原生质体融合。融合细胞在以0.3 mol/L蔗糖、0.3 mol/L葡萄糖为渗透稳定剂,附加1.0 mg/L 2,4-D+0.5 mg/L 6-苄氨基嘌呤(6-BA)+0.1 mg/L 1-萘乙酸(NAA)+1.0 mg/L激动素(Kinetin,Kin)的改良K8p培养基中培养并诱导细胞分裂。小愈伤组织经增殖培养后在MS+0.2 mg/L玉米素(Zeatin,ZEA)+1 mg/L 6-BA+0.5 mg/L Kin+0.4 mg/L NAA的固体分化培养基上诱导出不定芽。30 d后再转入MS基本培养基,获得完整的再生植株。将生根的植株转移到花盆,并对其杂种性质进行形态学、细胞学和分子生物学鉴定。结果表明,经细胞融合分裂出的320个愈伤组织中,获得了35棵再生植株,其再生率达10.94%。形态学观察显示,绝大多数再生植株的叶面积较大,株型和叶型为两种杂交亲本的中间型,部分植株的叶片浓绿、肥厚。染色体计数结果显示,36.4%的再生植株染色体数为2n=38;36.4%的再生植株的染色体数为2n=58 60;27.2%的再生植株的染色体数为2n=70 76,超过两个融合亲本的染色体数的总和。流式细胞仪测定DNA含量显示,再生植株DNA含量变化比较大,其结果与染色体鉴定结果相吻合。随机扩增多态性DNA(Randomamplified polymorphic DNA,RAPD)和基因组原位杂交(Genomic in situ hybridization,GISH)分析结果证明再生植株具有双亲基因组。体细胞杂种花粉育性比较低,杂交、回交后其育性逐渐获得恢复,与白菜回交后代逐渐恢复了育性。通过体细胞杂交和回交、杂交获得了形态变化广泛的个体,为白菜的品种育种提供多样的种质资源。     

Mutations in Barley Row Type Genes Have Pleiotropic Effects on Shoot Branching

Cereal crop yield is determined by different yield components such as seed weight, seed number per spike and the tiller number and spikes. Negative correlations between these traits are often attributed to resource limitation. However, recent evidence suggests that the same genes or regulatory modules can regulate both inflorescence branching and tillering. It is therefore important to explore the role of genetic correlations between different yield components in small grain cereals. In this work, we studied pleiotropic effects of row type genes on seed size, seed number per spike, thousand grain weight, and tillering in barley to better understand the genetic correlations between individual yield components. Allelic mutants of nine different row type loci (36 mutants), in the original spring barley varieties Barke, Bonus and Foma and introgressed in the spring barley cultivar Bowman, were phenotyped under greenhouse and outdoor conditions. We identified two main mutant groups characterized by their relationships between seed and tillering parameters. The first group comprises all mutants with an increased number of seeds and significant change in tiller number at early development (group 1a) or reduced tillering only at full maturity (group 1b). Mutants in the second group are characterized by a reduction in seeds per spike and tiller number, thus exhibiting positive correlations between seed and tiller number. Reduced tillering at full maturity (group 1b) is likely due to resource limitations. In contrast, altered tillering at early development (groups 1a and 2) suggests that the same genes or regulatory modules affect inflorescence and shoot branching. Understanding the genetic bases of the trade-offs between these traits is important for the genetic manipulation of individual yield components.     

Influence of selfing and maternal effects on life-cycle traits and dispersal ability in the herb Hypochaeris radicata (Asteraceae)

The ecological and evolutionary implications of dispersal are many. Pollination type and maternal effects may affect plant fitness traits, including life-cycle traits as well as dispersal ability. This study investigated the joint influence of pollination type and maternal effects on both life-cycle traits and dispersal ability in the herb Hypochaeris radicata . We conducted experimental crosses to obtain selfed and outcrossed progeny. Individual seeds and their pappuses were measured to determine seed terminal velocity. Seed size was also used to assess maternal effects. Selfing dramatically decreased seed set, indicating that H. radicata is self-incompatible. However, the few selfed seeds produced outperformed outcrossed seeds in seed size and flowering probability, surely as a result of an effective reallocation of resources among selfed seeds. None of the life-cycle traits was affected by seed size, the estimate of maternal effects. Selfed seeds were larger and bore a smaller pappus than outcrossed seeds. As a result, dispersal ability was lower for selfed than outcrossed seeds. Several factors, such as the low proportion of plants that produced selfed seeds, the low number of selfed seeds produced per plant, and the lack of self-fertility mechanisms might act in concert to prevent the evolution of selfing in H. radicata .  © 2004 The Linnean Society of London, Botanical Journal of the Linnean Society , 2004, 146 , 163–170.     

Molecular analysis of the triticale lines with different Vrn gene systems using microsatellite markers and hybridization in situ

Hexaploid triticale (x Triticosecale Wittmack) lines were examined using molecular markers and the hybridization in situ technique. Triticale lines were generated based on wheat varieties differing by the Vrn gene systems and the earing times. Molecular analysis was performed using Xgwm and Xrms microsatellite markers with the known chromosomal localization in the common wheat Triticum aestivum, and rye Secale cereale genomes. Comparative molecular analysis of triticale lines and their parental forms showed that all lines contained A and B genomes of common wheat and also rye homeologous chromosomes. In the three lines the presence of D genome markers, mapped to the chromosomes 2D and 7D, was demonstrated. This was probably the consequence of the translocations of homeologous chromosomes from wheat genomes, which took part during the process of triticale formation. The data obtained by use of genomic in situ hybridization supported the data of molecular genetic analysis. In none of the lines wheat--rye translocations or recombinations were observed. These findings suggest that the change of the period between the seedling appearance and earing time in triticale lines compared to the initial wheat lines, resulted from the inhibitory effect of rye genome on wheat vernalization genes.     

Plant regeneration and somaclonal variation from cultured immature embryos of sister lines of rye and triticale differing in their content of heterochromatin

Summary Plants were regenerated from cultured immature embryos of two pairs of sister lines of triticale (X Triticosecale) cvs Rosner and Drira and five sister lines of rye (Secale cereale). The triticale lines differ in heterochromatic content of a particular rye chromosome (6R or 7R), while the rye lines differ in only one heterochromatic band. Variation in morphogenetic response was present between the triticale cultivars and between the rye lines. One of the rye lines (7RL+ +) showed a distinctive superior response in terms of somatic embryogenesis. These findings are discussed in relation to factors affecting morphogenetic response and genetic stability in culture.     

Populations of doubled haploids for genetic mapping in hexaploid winter triticale

To create a framework for genetic dissection of hexaploid triticale, six populations of doubled haploid (DH) lines were developed from pairwise hybrids of high-yielding winter triticale cultivars. The six populations comprise between 97 and 231 genotyped DH lines each, totaling 957 DH lines. A consensus genetic map spans 4593.9 cM is composed of 1576 unique DArT markers. The maps reveal several structural rearrangements in triticale genomes. In preliminary tests of the populations and maps, markers specific to wheat segments of the engineered rye chromosome 1R (RM1B) were identified. Example QTL mapping of days to heading in cv. Krakowiak revealed loci on chromosomes 2BL and 2R responsible for extended vernalization requirement, and candidate genes were identified. The material is available to all parties interested in triticale genetics.