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Mapping antixenosis genes on chromosome 6A of wheat to greenbug and to a new biotype of Russian wheat aphid 总被引:2,自引:0,他引:2
A. M. Castro A. Vasicek M. Manifiesto D. O. Giménez M. S. Tacaliti O. Dobrovolskaya M. S. Röder J. W. Snape A. Börner 《Plant Breeding》2005,124(3):229-233
Greenbug and Russian wheat aphid (RWA) are two devastating pests of wheat. The first has a long history of new biotype emergence and recently. RWA resistance has just started to break down. Thus, it is necessary to find new sources of resistance that will broaden the genetic base against these pests in wheat. Seventy‐five doubled haploid recombinant (DHR) lines for chromosome 6A from the F1 of the cross between “Chinese Spring’ and the “Chinese Spring (Synthetic 6A) (Triticum dicoccoides × Aegilops tauschii)” substitution line were used as a mapping population for testing resistance to greenbug biotype C and to a new strain of RWA that appeared in Argentina in 2003. A quantitative trait locus (QTL) (br antixenosis to greenbug was significantly associated with the marker loci Xgwm1009 and Xgwm1185 located in the centromere region of chromosome 6A. Another QTL which accounted for most of the antixenosis against RWA was associated with the marker loci Xgwm1291 and Xiinni1150. both located on the long arm of chromosome 6A. This is the first report of greenbug and RWA resistance genes located on chromosome 6A. It is also the first report of antixenosis against the new strain of RWA. As most of the RWA resistance genes present in released cultivars have been located in [he D‐ genome, it is highly desirable to find new sources in other genomes to combine the existing resistance genes with new sources. 相似文献
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Russian wheat aphid (RWA), Diuraphis noxia (Kurdjumov), is a serious pest of small grains in many countries. A previous study screened 70 genotypes, collected from
different parts of Iran, for RWA resistance. Four crosses were made between two resistant lines (Shz.W-102 and Shz.W-104)
and two susceptible lines (Shz.W-101 and Shz.W-103). Parents, F1, F2, and BCF1 seedlings were screened for RWA resistance in the greenhouse by artificial infection. To determine allelism, the two resistant
lines were intercrossed and F1, and F2 seedlings were evaluated. Resistance in Shz.W-102 and Shz.W-104, when crossed with Shz.W-101, was controlled by one dominant
gene. However, resistance in Shz.W-102 and Shz.W-104, when crossed with Shz.W-103, was controlled by two dominant genes. Genes
in two resistant lines segregated independently of each other. A three-gene system was proposed to govern resistance in the
lines under study .
This revised version was published online in July 2006 with corrections to the Cover Date. 相似文献
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Summary During the winters of 1990/91 and 1991/92, 181 accessions of Triticum dicoccon Schrank from the CIMMYT gene-bank were screened in the field for resistance to Russian wheat aphid, Diuraphis noxia (Kurdjumov). Accessions were sown in hill plots of 10 seeds and artificially infested with D. noxia at the two-leaf growth stage. Hills were visually assessed for damage at tillering, booting and heading. Entries differed significantly in their reaction to D. noxia, and severity of symptoms increased with time. Twenty four of the entries were highly resistant to the aphid. In winter 1991/92, 807 accessions of wild and cultivated wheats (26 species) and synthetic hexaploids were screened similarly for resistance to D. noxia. A large number of A-genome species were resistant, while few D-genome species were identified as resistant. These newly discovered sources of resistance can be used to expand the genetic base of resistance to D. noxia in both bread (T. aestivum L.) and durum wheats (T. turgidum L. convar. durum (Desf.) Mackey). 相似文献
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J. Robinson 《Journal of Agronomy and Crop Science》1993,171(3):168-175
Resistance to Russian wheat aphid, [ Diuraphis noxia (Kurdjumov)], was studied in barley, ( Hordeum vulgare L.), based on maintenance of plant height, spike number, straw weight, grain yield and kernel weight. The experiments comprised small plots artificially infested with the aphid, plots naturally infested, and plots regularly sprayed with insecticide. Seven symptomatically resistant and five symptomatically susceptible barleys were compared. Mature plant height of the resistant barleys, compared with the susceptible barleys, was better maintained in the artificially infested plots. Spike number, straw weight, grain weight and kernel weight were also better maintained in the resistant accessions than in the susceptible ones. Gloria/Come, symptomatically resistant, did not perform well over the parameters measured. The susceptible varieties Esperanza and Shyri were severely affected by the aphid in terms of the measured traits. Grain yield of infested plots as a percentage of control plots ranged between 50 and 77 %; spike number between 66 and 96 %; straw weight betwen 62 and 78 %, and kernel weight between 70 and 84 %. Genotypes Barberousse/ Rumorosa//Gloria/Come and Barberousse/3/ASE/2CM//B76BB/4/Gloria/Come were the most resistant accessions. Selection of barley genotypes based on visual assessment of symptoms in artificially infested hill plots facilitates selection of genotypes that maintain their yield in artificially infested plots sown at commercial rates. These D. noxia resistant barleys are widely adapted and of good agronomic type, and will be useful to barley growers where the aphid is a pest. 相似文献
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The Russian wheat aphid (RWA), Diuraphis noxia (Mordvilko), has become a perennial, serious pest of wheat (Triticum aestivum L.) in the western United States. Current methodologies used to enhance RWA resistance in wheat germplasm could benefit from
an understanding of the biochemical mechanisms underlying resistance to RWA. This study was initiated to identify specific
polypeptides induced by RWA feeding that may be associated with RWA resistance. The effects of RWA feeding on PI 140207 (a
RWA-resistant spring wheat) and Pavon (a RWA-susceptible spring wheat) were examined by visualizing, silver-stained denatured
leaf proteins separated by two-dimensional polyacrylamide gel electrophoresis. Comparisons of protein profiles of noninfested
and RWA-infested Pavon and PI 140207 revealed a 24-kilodalton-protein complex selectively inhibited in Pavon that persisted
in PI 140207during RWA attack. No other significant qualitative or quantitative differences were detected in RWA-induced alterations
of protein profiles. These results suggest that RWA feeding selectively inhibit synthesis and accumulation of proteins necessary
for normal metabolic functions in susceptible plants.
This revised version was published online in July 2006 with corrections to the Cover Date. 相似文献
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Two Triticum monococcum accessions were found to be highly resistant to the Russian wheat aphid. An attempt was made to transfer the resistance to common wheat through direct hybridization or by using bridge species. In each of the four crossing strategies tried, a gradual loss of resistance occurred as hybrids with higher ploidy levels were obtained. It appeared that the level of resistance observed was directly proportional to the ratio of the Triticum monococcum genome relative to other genomes. This would indicate suppression of the resistance gene(s) by the added genomes or dilution of its product(s) by those of homoeoloci. The degree of protection afforded by the gene(s) at the hexaploid level may prove to be small. Plants suspected to be homozygous for the resistance gene(s) were identified; however, further backcrossing to common wheat will be required to improve their agronomic types and meiotic regularities. 相似文献
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Z. Basky 《Crop Protection》1993,12(8):605-609
A yellow water pan trap was used to collect Diuraphis noxia (Mordvilko) in Central Hungary in 1989. In 1990 a Rothamsted-type suction trap collected 31 individuals. A D. noxia infestation was found in an autumn-sown wheat field in October 1990. The D. noxia population that overwintered was holocyclic. The life-span of fundatrices was 43.2 days at 18–22°C. The number of nymphs produced per fundatrix was 46.6. Average progeny numbers of first-generation apterae and alatae were 29.4 and 21.4, respectively. Second-generation apterae produced an average of 48.8 nymphs; 35.9% of nymphs were alatiform. The D. noxia population reached its peak on 3 July in the field, at which time the mean number of individuals per wheat plant was 3953.6. By 20 July, the wheat plants had matured and the D. noxia colonies had disappeared from the wheat. 相似文献