Protein electrophoresis as an aid to oat variety identification

Summary Ten cultivars of oats (Avena sativa L.) were investigated for their isozymes of esterase (E), leucine aminopeptidase (LAP), and anodal and cathodal peroxidase (APX and CPX).From repeated observations, a typical zymogram was prepared for each enzyme system, and the frequencies of the isozyme bands were scored for each variety separately. The results showed that: (1) most of the isozyme bands are very stable in their appearance on the gel: (2) each variety has a characteristic isozyme pattern; (3) 7 out of 10 oat cultivars showed no intravarietal isozyme variation. Some variation was found for the varieties Mesa, Rapida and Curt. This overall high level of homozygosity and homogeneity of these varieties for the isozyme bands makes this technique useful for varietal identification.     

Resistance to barley yellow-dwarf-virus disease in derivatives of crosses between hexaploid wheat and species of Lophopyrum (Triticeae; Poaceae)

Among the wheatgrasses that are possible sources of genetic resistance for wheat to barley yellow-dwarf-virus disease (BYD) are those that have been commonly subsumed under the name Agropyron elongatum (Host) P. Beauv. Two of these wheatgrass species are the diploid Lophopymm elongatum (Host) Á. Löve (2n = 2x = 14) and the decaploid L. ponticum (Podp.) Á. Löve (2n = 10x = 70). These two species, the addition and substitution lines of L. elongatum chromosomes in hexaploid wheat (Triticum aestivum L.), and derivatives of hybrids between hexaploid wheat and L. ponticum, were screened for resistance to BYD, as defined by visual symptoms in field-grown plants. The two species, an amphiploid derived from L. elongatumבChinese Spring’ wheat, and the derivatives involving L. ponticum chromosomes were all highly resistant. The substitution and addition lines of L. elongatum chromosomes in ‘Chinese Spring’ revealed that the genetic control of resistance in L. elongatum must be complex, with more than one critical locus involved. Chromosomes 2E and 5E are involved and there are lesser contributions to resistance from the remaining wheatgrass chromosomes. One highly resistant derivative was determined to have only three pairs of L. ponticum chromosomes. It has a wheat-like morphology and shows promise for further characterization.     

Chemically induced sterility in wheat for hybrid seed production

Summary The gametocidal effects of RH-531, RH-532, and RH-2956 were studied with three rates and times of foliar application on two spring wheat (Triticum aestivum L.) varieties, Anza and Yecora 70. RH-531 and RH-532 applied at or before booting stage caused rather large reduction in plant height while RH-2956 had a small effect on height. Application of any of the three chemicals on Anza at meiotic stages reduced self-pollination (SP) fertility by 97–99%. If 90% SP fertility reduction is acceptable, the application time could vary from premeiosis to postmeiosis for Anza. Yecora 70 was less sensitive than Anza to gametocide treatments. The lowest SP fertility obtained in Yecora 70 with RH-531, RH-532, and RH-2956 was by treatment at booting (4 kg/ha), at premeiosis (2 kg/ha), and heading (8 kg/ha), and the corresponding SP fertility reductions were 74, 89, and 71%. Pollen stainability-determined by aceto-carmine, IKI, and Alexander's stains-was not affected by gametocide treatment and was not useful in evaluating sterility induced by these chemicals. For the RH-531-treated Anza and Yecora 70 and the RH-532-treated Anza, more than 94% of the seeds produced by open-pollination on treated plants were from self-or sib-pollination as determined by progeny testing. However, RH-532-treated Yecora 70 and RH-2956-treated Anza and Yecora 70 did result in more crossed seeds, with a maximum of 20% outcrossing. It was believed that spike compactness induced by the chemicals and the related poor flower opening were the major limitations for outcrossing. Artificial pollinations made to the test varieties showed that RH-531 induced both male and female sterility and was undesirable for practical use. RH-532, however, could be applied at the booting stage to avoid severe female sterility, and RH-2956 clearly was the best of the three chemicals, with the female fertility very close to those of the untreated checks of both Anza and Yecora 70. Of the three chemicals, RH-2956 gave the highest percentage of hybrid plants in the progeny of hand-or open-pollinated spikes. Its practical use for hybrid seed production, however, will depend largely on improvement of methods to increase cross pollination in wheat.     

Seedling emergence,coleoptile length,and plant height relationships in crosses of dwarf and standard-height wheats

Summary Seedling emergence was closely correlated with coleoptile length and plant height among parents, F₂ and F₃, populations of crosses involving dwarf wheats Olesen Dwarf (CI 14497), Norin 10 derivative D6301, Tom Thumb derivative D6899, and the standard-height varieties Ramona 50 and Nainari 60. Genetic mechanisms that governed plant height also influenced coleoptile length, but the relative effects of genes showing dominant or epistatic effects appeared to be different. With respect to the two parents involved in each of 15 crosses, mean F₂ coleoptile lengths were consistently closer to the low parent value than were corresponding mean F₂ plant heights. A slight curvilinear relationship was also found between coleoptile length and plant height of F₃ lines. The results suggest that selection of semidwarf wheats with long coleoptiles and improved emergence properties from crosses involving the dwarf wheats of this study would be unlikely.     

Rapid introduction of disease resistance from rye into common wheat by anther culture of a 6x triticale × nulli-tetrasomic wheat

Powdery mildew (caused by Erysiphe graminis) and yellow rust (caused by Puccinia striiformis) are the two most serious wheat diseases found in China. Rye chromosomes, carrying genes for resistance to these diseases, were introduced into common wheat in two generations using chromosome engineering and anther culture. The F₁ hybrids from a cross involving a hexaploid triticale (×Triticosecale Wittmack) בChinese Spring’ nulli‐tetrasomic N6DT6A wheat aneuploid line were anther cultured and doubled‐haploid plants were regenerated. Using genomic in situ hybridization, C‐banding and biochemical marker analyses, one of the anther‐cultured lines (ZH‐1)studied in detail, proved to be a doubled‐haploid with one rye chromosome pair added (1R) and a homozygous 6R/6D substitution (2n= 44). The line was tested for expression of disease resistance and found to be highly resistant to powdery mildew and moderately resistant to yellow rust.     

Flag Leaf Variation and the Analysis of Diversity in Durum Wheat

Flag leaf in wheat (Triticum spp.) is a major source of photosynthate for the developing grain and its size contributes to interplant competition. Flag leaf length, width, and area in a sample of 778 entries of durum wheat (T. turgidum L. durum group) germplasm obtained from the U.S. National Small Grains Collection showed considerable phenotypic variation. Correlations between flag leaf and eight spike quantitative characters showed significant values greater than 0.30 for kernel weight per spike with all three flag leaf measurements and for awn length with flag leaf length and area. Larger flag leaf area appeared to be associated with accessions having a history of some deliberate plant breeding for high grain yield. A multivariate approach was used to assess how discrimination among 26 countries of origin obtained with spike characters in a previous study was affected by reducing the sample size from about 3,000 to 735 and by the addition of flag leaf measurements to the analysis. The reduced sample size had little impact on the results of the previous analysis on the whole collection of about 3,000 entries. The addition of flag leaf characters to the analysis caused a rearrangement in the clusters of countries, mostly from Asia, where less germplasm modified by plant breeding was included in the collection. Five clusters were identified: (1) 11 Mediterranean basin countries, (2) USA, UdSSR, and Yugoslavia, (3) four Near East Countries and Bulgaria, (4) three Middle East countries and Greece, India and Ethiopia, and (5) Afghanistan. Phenotypic differentiation of durum wheat, and probably many other crops, on a geographic basis is more pronounced in areas where plant breeding has had little impact.     

Chemical induction of sterility in wheat

Euphytica - Foliar application of two spring wheat varieties, Anza and Yecora 70, with RH-531 several days before meiosis in a field experiment almost completely prevented seed development. A...     

Genetic control of crossability of triticale with rye

Limited genetic knowledge is available regarding crossability between hexaploid triticale (2n= 6x= 42, 21″, AABBRR, amphiploid Triticum turgidum L.‐Secale cereale L.) and rye (2n= 14, 7″, RR). Our objectives were to determine (1) the crossability between triticales and rye and (2) the inheritance of crossability between F₂ progeny from intertriticale crosses and rye. First, ‘8F/Corgo’, a hexaploid triticale, was crossed as a female with two landrace ryes, ‘Gimonde’ and, ‘Vila Pouca’ and two derived north European cultivars, ‘Pluto’ and ‘Breno’. These crosses produced 21.7, 20.9, 5.9, and 5.6%, seed‐set or crossability, respectively, showing that the landrace ryes produced higher seed‐set than the cultivars. Second, ‘Gimonde’ rye was crossed as a male with four triticales for 3 years. The control cross, ‘Chinese Spring’ wheat × rye, produced 80‐90% seed‐set. Of the four triticales, ‘Beagle’ produced 35.7‐56.8% seed‐set. The other three triticales produced less than 20% seed‐set, showing that the triticales differ in crossability with ‘Gimonde’ rye. Third, six FiS from intertriticale crosses (‘8F/Corgo’בBeagle’, ‘Beagle’בCachirulo’, ‘Lasko’בBeagle’, ‘8F/Corgo’בCachirulo’, ‘Lasko’בCachirulo’, ‘Lasko’ב8F/Corgo’) were crossed to ‘Gimonde’ rye. Results indicated that lower crossability trait was partially dominant in the two F₁S from crosses involving ‘Beagle’(high crossability) with‘8F/Corgo’ and ‘Cachirulo’(low crossability) and completely dominant in the ‘Beagle’בLasko’ cross, as it happens in wheat. Fourth, segregants in four F₂ populations (‘Lasko’בBeagle’, ‘8F/Corgo’בBeagle’, ‘Lasko’ב8F/Corgo’, and‘8F/Corgo’בCachirulo’) were crossed with rye. Segregation for crossability was observed, although distinct segregation classes were blurred by environmental and perhaps other factors, such as self‐incompatibility alleles in rye. Segregation patterns showed that ‘Beagle’, with high crossability to rye, carries either Kr1 or Kr2. The three triticales with low crossability with rye were most likely homozygous for Kr1 and Kr2. Therefore, it is likely that the Kr loci from A and B genomes acting in wheat also play a role in triticale × rye crosses.     

Grain yield and grain protein percentage of common wheat lines with wild emmer chromosome-arm substitutions

Wild emmer wheat, Triticum turgidum subsp. dicoccoides, (2n = 4× = 28; genome BBAA), the progenitor of domesticated wheat, is genetically closely related to durum and common wheat. This wild taxon has characteristics that would be valuable if transferred to domesticated wheat. A series of chromosome-arm substitution lines (CASLs) of wild emmer wheat were produced in the background of an Israeli common wheat cultivar. These CASLs were evaluated in a pot experiment and in field trials in Israel and California for their grain yield (GY) and its components and for grain protein percentage. In addition, the extent of genetic interactions (epistatic effects) between “wild” and “domesticated” alleles, within and between homoeologous groups 1 and 7 as expressed in grain and protein yields and other quantitative traits, were determined. The research has shown that wild emmer wheat harbors genetic variability for quantitative traits and that the “wild” genes interact among themselves in a non-additive way in the common genetic background. Several chromosome arms improve GY and protein percentage in common wheat, but their effects will be presumably enhanced when combination of genes from several “wild” arms are integrated into a single “domesticated” genotype. Hence, the interaction between these genes and those in the recipient common wheat must be accounted for when higher yield or protein content is desired. The results of this study indicate on the potential of this material for breeding and genetic analysis, and support the idea of pyramiding genes from a wild species.