Hybridizing <Emphasis Type="Italic">Brassica rapa</Emphasis> with wild crucifers <Emphasis Type="Italic">Diplotaxis erucoides</Emphasis> and <Emphasis Type="Italic">Brassica maurorum</Emphasis>

Two wide hybrids, Diplotaxis erucoides (2n = 14) × Brassica rapa (2n = 20) and B. maurorum (2n = 20) × B. rapa, were developed using the sequential ovary–ovule culture. Reciprocal crosses failed, possibly as a consequence of strong unilateral incompatibility. The F ₁ hybrids in each combination were completely male sterile and morphologically intermediate to the respective parents. DNA marker polymorphism and chromosome counts confirmed their hybrid nature. High frequency of bivalents in the F ₁ and the presence of trivalents/quadrivalents in the derived amphiploids suggested genomic duplications and homoeology of the parental genomes. Up to three homoeologous pairs between the D. erucoides (D^eD^e) and B. rapa (AA) genomes, and one between B. maurorum (B^mB^m) and B. rapa genomes were observed. Successful synthesis of the F ₁ hybrids and amphiploids of B. rapa with D. erucoides and B. maurorum, and allosyndetic chromosome pairing are expected to permit introgressions of desirable loci into the cultivated Brassica germplasm, especially for resistance to Alternaria brassicae and Albugo candida.     

A 192bp allele at the <Emphasis Type="Italic">Xgwm261</Emphasis> locus is not always associated with the <Emphasis Type="Italic">Rht8</Emphasis> dwarfing gene in wheat (<Emphasis Type="Italic">Triticum aestivum</Emphasis> L.)

The height-reducing gene Rht8 was introduced into Italian wheats by breeder Nazareno Strampelli from the Japanese landrace Akakomugi, and has been widely used in wheats adapted to southern and eastern European conditions. Following identification of a close linkage to Rht8, microsatellite marker Gwm261 has been used extensively to screen large numbers of diverse international germplasm. A 192bp allele at this locus has been taken as “diagnostic” for Rht8 and used to infer the international distribution of Rht8. In this paper, we report several instances of cultivars and mapping populations that vary for the presence of the 192bp allele at the Xgwm261 locus (Xgwm261 ₁₉₂ ), but with no associated reduction in height, suggesting a lack of association with Rht8. For instance, in the population derived from a cross between Sunco (Rht-B1b, Xgwm261 ₁₆₅ ) and Tasman (Rht-D1b, Xgwm261 ₁₉₂ ), there were significant height differences associated with the segregation of Rht-B1b and Rht-D1b, but no height differences between Xgwm261 genotypes. Similar results were obtained in a population derived from the cross between Molineux (Rht-B1b, Xgwm261 ₁₉₂ ) and Trident (Rht-D1b Xgwm261 ₂₀₈ ). In contrast, the cross between Trident and Chuanmai 18 (Xgwm261 ₁₉₂ ) gave significant height effects at both the Rht-D1 and Xgwm261 loci, with no epistatic interaction between loci. Chuanmai 18 is closely related to the Strampelli wheat Mara (ancestrally derived from Akakomugi) and is therefore likely to carry Rht8. The old Japanese cultivar Norin 10, used by Norman Borlaug to introduce Rht-B1b and Rht-D1b into Mexican wheats, also has a 192bp allele at the Xgwm261 locus, and the sequence of the amplified product is identical to that of Akakomugi. We suggest that the widespread use of Norin 10-derived germplasm during and after the Green Revolution introduced a second haplotype into international germplasm, in which Xgwm261 ₁₉₂ has no association with Rht8. Therefore, the presence of Xgwm261 ₁₉₂ is only indicative of Rht8 in wheat cultivars that have inherited this allele from Akakomugi or a Strampelli wheat ancestor.     

Haplotype analysis of <Emphasis Type="Italic">Viviparous</Emphasis>-<Emphasis Type="Italic">1</Emphasis> gene in CIMMYT elite bread wheat germplasm

Pre-harvest sprouting (PHS) greatly reduces the quality and economic value of wheat grain. In this study, a total of 168 International Maize and Wheat Improvement Center (CIMMYT) wheat germplasm lines were examined to characterize the haplotypes of Vp-1A, Vp-1B and Vp-1D, which are located on the long arms of chromosomes 3A, 3B and 3D, respectively. Among them, five new alleles of Vp-1Aa (the wild allele) were identified on chromosome 3A, and designated as Vp-1Ab, Vp-1Ac, Vp-1Ad, Vp-1Ae and Vp-1Af, respectively. The main difference between Vp-1Aa and the newly identified alleles was in the numbers of CTT repeats located in the third intron, but Vp-1Af also had 6 and 2 bp deletions at positions 2860–2865 bp and 2880–2881 bp, and possessed five SNPs within the same intron region. In the Vp-1B locus, several alleles (Vp-1Ba, Vp-1Bb, Vp-1Bc, Vp-1Bd, Vp-1Be and Vp-1Bf) have already been identified. In the present material only two, the already known allele Vp-1Bc, and a new one, designated as Vp-1Bg, were detected. Compared with Vp-Ba, Vp-1Bg had additional insertion of TCC at position 2372 bp and a 9 bp change from CTGCATC AC to GCATCAGTG at 2417–2425 bp. However, no polymorphism was detected in Vp-1D. The frequencies of Vp-1Aa Vp-1Ab, Vp-1Ac, Vp-1Ad, Vp-1Ae, and Vp-1Af were 65, 10, 11, 4, 5 and 5%, respectively. For Vp-1B, 155 out of the 168 lines were Vp-1Bc; the remaining 13 were Vp-1Bg. Analyses of the germination index (GI) and abscisic acid (ABA) sensitivity showed that genotypes with Vp-1Ab or Vp-1Af showed higher PHS resistance than the ones with other alleles, suggesting that they might be valuable for CIMMYT breeding program or germplasm introduction. The results presented here will underpin the introduction of germplasm from CIMMYT and the improvement of PHS resistance, both in CIMMYT and elsewhere.     

Quantitative resistance and its components in 16 barley cultivars to yellow rust, <Emphasis Type="Italic">Puccinia striiformis</Emphasis> f. sp. <Emphasis Type="Italic">hordei</Emphasis>

Sixteen barley cultivars with a susceptible infection type (IT = 7–8) in the seedling stage to an isolate of race 24 of Puccinia striiformis f. sp. hordei were planted at two locations in México. Disease severity (DS) parameters were assessed for the flag leaf and for the upper three leaves. The cultivars represented at least five levels of quantitative resistance ranging from very susceptible to quite resistant. “Granado”, “Gloria/Copal” and “Calicuchima-92” represented the most resistant group and had an IT of 7 or 8. The cultivar × environment interaction variance, although significant, was very small compared with the cultivar variance. The disease severity parameters were highly correlated. The monocyclic parameter DS_m, measured when the most susceptible cultivar had reached its maximum DS, was very highly correlated with the area under the disease progress curve (AUDPC), r being 0.98. Components of quantitative resistance were evaluated in two plant stages. In the seedling stage small cultivar effects for the latency period were observed, which were not correlated with the quantitative resistance measured in the field. In the adult plant stage the latency period (LP), infection frequency (IF) and colonization rate (CR) were measured in the upper two leaves. The LP was much longer than in the seedling stage and differed strongly between cultivars. The differences in IF were too large, those in CR varied much less. The components showed association with one another. The LP and IF were well correlated with the AUDPC (r = 0.7–0.8). †Deceased     

Co-suppression of <Emphasis Type="Italic">Si401</Emphasis>, a maize pollen specific <Emphasis Type="Italic">Zm401</Emphasis> homologous gene,results in aberrant anther development in foxtail millet

We previously reported that the maize pollen-specific gene Zm401 functions in anther development. In this study, a Zm401’s ortholog Si401 was amplified and cloned from foxtail millet (Setaria italica). Zm401 and Si401 are highly conserved with 99% of their coding sequences identical to each other. Southern blot and RT-PCR analysis reveal that Si401 has only one copy in the genome and is expressed exclusively in the panicle. Co-suppression of Si401 in foxtail millet results in multiple abnormalities during the late stages of anther development, including premature degeneration of the tapetum, pre-deposition of fibrous bands in endothecium cells, and aborted pollen grains. Our results demonstrate that Si401 plays an essential role in anther development in foxtail millet and might be useful for generation of male-sterile plants in cereal crops.     

Predicting transgressive segregants in early generation using single seed descent method-derived <Emphasis Type="Italic">micro-macrosperma</Emphasis> genepool of lentil (<Emphasis Type="Italic">Lens culinaris</Emphasis> Medikus)

In a self-fertilised crop like lentil, the identification of transgressive segregants for economically important trait such as seed yield is an important aspect of any practical breeding programme. The prediction of expected transgressive segregants in F₁ generation obtained as a ratio of additive genic effect [d] and additive variance (D) i.e. [d]/√D was studied in 28 crosses of lentil generated in a diallel fashion involving four parents each of macrosperma (exotic) and microsperma (Indian) types, respectively, resulting in three hybridization groups. The seed material advanced to F₂, F₃ and F₄ generations through single seed descent method was evaluated to determine the observed transgressive segregants for seed yield/plant. The observed frequency of crosses showing more than 20% transgressive segregants in F₂ to F₄ generations were exhibited in 9(32%) crosses, of which 7(77%) crosses were of macrosperma × microsperma type. Genotypes Precoz and HPL-5 of the exotic group (macrosperma) produced maximum number of transgressive segregants with the genotypes L-259, L-4145 and PL-406 of the Indian origin (microsperma). Goodness of fit (non-significant χ² value) in F₂ generation was observed for 19(68%) crosses of the total genepool, out of which 9(56%) crosses each in F₃ and F₄ generation belonged to the macrosperma × microsperma group, depicting it as the gene pool of paramount importance to obtain maximum transgressive segregants, therefore establishing the efficacy of the method used.     

Grasses and <Emphasis Type="Italic">Neotyphodium</Emphasis> endophytes: co-adaptation and adaptive breeding

Neotyphodium endophytes profoundly affect the biology of their host grasses, including the important forage species perennial ryegrass, tall fescue and meadow fescue. The endophytic association is finely balanced, involving adaptation in each associate. The evidence for co-adaptation is discussed. The presence of endophyte, and the difference between endophyte strains, can affect some plant properties more than genetic variation intrinsic to the host. Conversely, host genotype exerts significant influence on the activity of the endophyte. Control of endophyte status is essential in any grass breeding programme, and developing knowledge of endophyte and its role in a herbage association offers new opportunities to grass breeders.     

Genetic analysis of apical lethality in <Emphasis Type="Italic">Triticum aestivum</Emphasis> L.

Investigations were carried out to determine the nature and number of genes governing apical lethality (apical death) in a number of intervarietal crosses of wheat. Genetic analysis of data in segregating generations of the cross WR95/HW2041 and its reciprocal cross revealed that WR95 carries a recessive gene that leads to the death of certain individuals when combined with another recessive gene derived from HW2041. The phenomenon, which is denoted here as “apical lethality”, is controlled by two complementary recessive genes coming together from two different parents in certain F₂ individuals. The gene symbols apd ₁ in WR95 and apd ₂ in HW2041 are proposed for these genes of apical lethality, respectively. Uniculms observed in the F₂ generation are heterozygous (apd ₁ apd ₁ Apd ₂ apd ₂) and, therefore, the uniculmness trait does not breed true. Of the wheat genotypes tested, the gene apd ₂ was found to be present in CL983, CL1019, Lok-1, HW2041, HD2329, HW2011, WH147, HW2042, HW2047, WR196, WR544, WR798 and WR936, while the remaining genotypes, including some of the exotics such as Atila, carried both Apd ₁ and Apd ₂ in the homozygous condition.     

Combining ability analysis of resistance to head blight caused by <Emphasis Type="Italic">Fusarium graminearum</Emphasis> in spring wheat

Fusarium head blight (FHB) caused by Fusarium spp. is one of the most important fungal diseases of wheat (Triticum aestivum L.) in regions with wet climatic conditions. Improvement of the FHB resistance by developing new varieties requires sound knowledge on the inheritance of resistance. An 8 × 8 diallel analysis was performed to estimate general (GCA) and specific (SCA) combining ability of resistance to FHB. The F₁s and parental lines were evaluated under artificial inoculation at the experimental field of IFA-Tulln, Austria during 2001 and 2002. Disease severity was evaluated by repeated scoring of the percentage of infected spikelets and calculating an area under the disease progress curve (AUDPC). The analysis of combining ability across two years showed highly significant GCA and non-significant SCA effects indicating the importance of additive genetic components in controlling FHB resistance. The significant GCA-by-year interaction presented the role of environmental factors in influencing the FHB reaction of wheat lines. The comparison of the crosses with low FHB infection and GCA effects of their parents showed that such crosses involved at least one parent with high or average negative GCA effect. The results revealed that it is feasible to use highly or moderately resistant genotypes and conventional breeding methods to achieve genetic improvement of FHB resistance in spring wheat.     

Heritability and gene effects for incorporating pubescence into cowpea (<Emphasis Type="Italic">Vigna unguiculata</Emphasis> (L) Walp.) from <Emphasis Type="Italic">V. rhomboidea</Emphasis> Burtt. Davy

Cowpea, an important subsistence pulse crop in the tropics and subtropics is susceptible to several insect pests that seriously limit its yield potential. Pubescence (hairiness) on the parts of some of its wild relatives has been reported to reduce the damage caused by some of the insect pests. A generation mean analysis was conducted between a cowpea variety IT82D-716 and two accessions of Vigna rhomboidea to investigate the gene effects and heritability for incorporating pubescence into cultivated cowpea from V. rhomboidea. The additive-dominance model that was adopted in the analysis was observed to sufficiently explain the mode of inheritance of leaf and stem pubescence with the additive effect being more important than the dominance effect. A six-parameter model with epistatic gene interactions was adequate for explaining the inheritance of pod pubescence. Heritability estimates, in the narrow sense were high for pubescence density and pubescence length. Inheritance of pubescence in crosses between cowpea and V. rhomboidea was governed by one and two genes. Significant and higher additive gene effects and high-heritability suggest that backcross selection schemes should be responsive in the development of pubescent cowpea lines.     

Emasculation of Tartary buckwheat (<Emphasis Type="Italic">Fagopyrum tataricum</Emphasis> Gaertn.) using hot water

Hot water treatment was applied to Tartary buckwheat (var. ‘Hokkai T8’) for emasculation. Apical clusters of flower buds were soaked in a constant temperature water bath (42–44°C) in the afternoon and then the flowers which opened in the next morning were used for the investigation of self-fertilization and the artificial pollination. Hand pollination was carried out by rubbing the anthers taken from the male parent (var. ‘Hokkai T10’) to the stigma of the flowers treated by hot water. The seed set by self-fertilization was almost 0% when treated at 42°C for 8 min or more, at 43°C for 5 min or more and at 44°C for 3 min or more. With artificial pollination, the best performance was obtained when treated at 44°C for 3 min, in which the seed set was 55.1% and the matured seed was obtained 37.7% of the hand-pollinated flowers. Nine out of 26 progeny seedlings emerged and the cotyledonal color of them were all reddish green, probably indicating the hybrid of ‘Hokkai T8’ and ‘Hokkai T10’. The hybridization was reconfirmed by the segregation in F₂. The hot water treatment at 44°C for 3 min was available to other seven varieties. From 24.5% to 100% of the hand-pollinated flowers set mature seeds though only one self-fertilized seed remained without artificial pollinations. This hot water treatment must be practically useful in hybridization breeding of Tartary buckwheat.     

Genetic analysis of resistance to nematodes in inbred maize (<Emphasis Type="Italic">Zea mays</Emphasis> L.) and maize hybrids

Nematodes cause substantial grain yield loss in susceptible maize (Zea mays L.) cultivars. This study was conducted to estimate general combining ability (GCA), specific combining ability (SCA) and genetic effects associated with nematode resistance in maize. The 30 F ₁ hybrids generated from a 6 × 6 diallel and two local checks were evaluated in 2009 at three sites in Uganda. A split plot design was used with nematode treatments serving as whole plots and the hybrids as subplots but arranged in an 8 × 4 spatially adjusted alpha-lattice design. The experiment was replicated three times. Results showed GCA to be important for the reduction of P. zeae and Meloidogyne spp. densities and increase of root mass, with a contribution of 72 to 93% of the phenotypic variance. Inbreds MP709 and CML206 had the highest GCA for Pratylenchus zeae resistance, whereas for grain yield, it was CML444, CML312 and CML395 that were outstanding. The SCA influenced plant height and grain yield under nematode infestation, contributing 43 and 58% of the phenotypic variance, respectively. Observed reciprocal differences due to maternal effects also played a role in influencing the grain yield under nematode infestation. Overdominance genetic effects explained the non-additive variance recorded for the plant height, grain yield, number of root lesions, and P. zeae and Meloidogyne spp. densities under nematode infestation. The parents MP709, CML206, 5057, and CML444 contributed most of the dominant genes for the P. zeae resistance in all their crosses. The parent CML444 contributed most of the dominant genes for improved grain yield in all of its crosses. The high GCA effects among some parents support their utility in breeding of widely adapted nematode-resistant cultivars. The dominant genes and SCA effects would favour pedigree and various sib tests to improve grain yield under nematode pressure.     

Induction of <Emphasis Type="Italic">Anthurium andraeanum</Emphasis> “Arizona” tetraploid by colchicine in vitro

Tetraploids plants of Anthurium andraeanum “Arizona” were successfully induced after treating diploid tissue masses with colchicine. Masses originating from diploid aerial roots were treated with colchicine at three different concentrations (i.e., 0.1, 0.2, 0.3%) for about 3, 5 and 7 h, and then were transferred into Murashige and Skoog medium containing 3 mg/l BAP + 0.2 mg/l 2,4-D. After 60 days, the survival rate and numbers of regenerative shoots were scored. The high concentration and longer duration sharply reduced survival rate. In contrast, the regeneration of plantlets was not noticeably affected by colchicine. Tetraploid plants were obtained in all treatments, but the percentage of induced tetraploids ranged from 0.2 to 7.6%. The best induction was obtained with a 5-h, treatment with 0.3% colchicine. The stomatal size of tetraploid plants was larger than in diploid plants; however, the stomatal density was lower than in diploid plants. Tetraploid plants possessed stronger petioles, thicker and deeper green leaves, and thicker and longer lived spathes in comparison with diploid plants. Abnormal spathes, such as double spathes or those lacking pedicels, were observed in tetraploid plants. Tetraploid plantlets could be regenerated via aerial roots; this technique could be applied to tetraploid plant propagation.