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1.
Tamerlane Mark S. Nas Darlene L. Sanchez Genaleen Q. Diaz Merlyn S. Mendioro Sant S. Virmani 《Euphytica》2005,145(1-2):67-75
Three thermosensitive genetic male sterility (TGMS) genes – tms2, tgms and tms5 – were pyramided using linked microsatellite markers. Three TGMS donors, Norin PL 12 (tms2), SA2 (tgms) and DQ200047-21 (tms5) were utilized in generating crosses from which two-gene and three-gene pyramids possessing the RM11 allele of Norin PL 12,
RM257 allele of SA2 and RM174 allele of DQ200047-21 were selected. All selected progenies were male-sterile at sterility-inducing
conditions. In addition, rice SF21 was identified as a candidate tms5 gene because of its complete linkage with RM174. The 4,200-bp region was amplified from the TGMS line M105S and the two ends
were sequenced. In silico analysis of partial nucleotide sequences showed that the region is similar to the SF21 pollen-specific gene of Arabidopsis and Helianthus. The M105S tms5 sequence was also compared to the SF21 sequence from the International Rice Genome Sequencing Project (IRGSP) database. 相似文献
2.
Changhu Wang Peng Zhang Zhenrong Ma Mingyong Zhang Guchou Sun Dinghou Ling 《Euphytica》2004,140(3):217-222
Application of the thermo-sensitive genic male sterile (TGMS) system has a great potential to increase the efficiency of hybrid rice breeding. An indica rice TGMS mutant, 0A15-1, was crossed with a fertile indica line Guisi-8 to map the gene responsible to the TGMS. A RAPD (random amplified polymorphic DNA) maker, S187-770, linked to the TGMS gene at a distance of 1.3 cM in coupling phase was identified. The S187-770 was then cloned and sequenced to develop a dominant SCAR (sequence characterized amplified region) marker. Homology search against rice genome DNA sequence database indicated that S187-770 located on the short arm of chromosome 3 and close to centromere as a single copy sequence. This SCAR marker can be used in the marker-assisted transfer of this gene to different genetic background. As no other TGMS gene has been mapped on rice chromosome 3, the gene from 0A15-1 is a new TGMS gene and tentatively designated tms6(t). 相似文献
3.
Summary The genetics of resistance to whitebacked planthopper, Sogatella furcifera (Horvath) in ten resistant cultivars was studied. The reactions of the F1, F2 and F3 populations of resistant varieties with Taichung Native 1, a suspectible check, showed that WBPH resistance is monogenic in nature and governed by dominant gene(s) in Ptb 19 and IET 6288 and recessive gene in eight cultivars viz. ARC 5838, ARC 6579, ARC 6624, ARC 10464, ACR 11321, ARC 11320, Balamawee and IR 2415-90-4-3. Allelic relationship of resistance gene(s) in the test cultivars revealed recessive gene in IR 2415-90-4-3, ARC 5838 and ARC 11324 to be allelic but it was non allelic to the resistance gene in ARC 6624. Cultivars ARC 6579, ARC 11321 and Balamawee have identical gene among themselves but their relationship with IR 2415-90-4-3, ARC 5838, ARC 11324 and ARC 6624 is unknown. The recessive gene in ARC 10464 is non-identical to all other cultivars having the recessive gene except ARC 6624 with which its relationship needs further investigation. 相似文献
4.
Expression of thermosensitive genic male sterility in rice under varying temperature situations 总被引:1,自引:0,他引:1
Response of thermosensitive genic male sterility in rice to varying temperature situations was studied by using four TGMS
lines. In three sets of maximum, minimum and their combined temperatures, it was observed that maximum temperature played
a predominant role in influencing sterility/fertility of TGMS lines under the combined regimes. Expression of a TGMS gene
was found to be influenced by the genetic background of the recipient lines. Exposure for more than 8 hours of 32 °C was found necessary to induce complete male sterility in indica TGMS lines: IR68945-4-33-4-14 and IR68949-11-5-31 while,
more than 4 hours of such exposure was enough to induce sterility in case of their japonica donor Norin PL 12. Sudden interruption
with 27 °C even for 2 hours under the sterility inducing regime of 32/24 °C could induce partial fertility in the line IR68945-4-33-4-14. However, the line ID 24 remained completely sterile even with
10 hours of interruption with 27 °C. An interruption with lower temperature of 27 °C for 4 hours for even one day induced partial fertility in IR68945-4-33-4-14. The period of four to eight days after panicle
initiation was the stage most sensitive to temperature variations. Hybrid rice breeders need to develop numerous genetically
diverse TGMS lines, which possess critical sterility inducing temperature of 28 °C and are not affected by sudden interruptions with a lower temperature for few hours daily for a couple of days.
This revised version was published online in August 2006 with corrections to the Cover Date. 相似文献
5.
Stem fasciation is a morphological abnormality observed in plants where the stem is widened and leaves and flowers or pods are clustered at the apex. Several spontaneous mutants and one induced mutant for stem fasciation are found in chickpea (Cicer arietinum L.). This study was aimed at determining allelic relationship between spontaneous and induced mutant genes controlling stem fasciation and effects of stem fasciation on grain yield. Two spontaneous (ICC 2042 and ICC 5645) and one induced (JGM 2) stem fasciation mutants were crossed in all combinations, excluding reciprocals. The F1 and F2 plants from a cross between the two spontaneous mutants had fasciated stem. This indicated the presence of a common gene (designated fas1) for stem fasciation in the two spontaneous mutants. The F1s of the crosses of the induced mutant JGM 2 with both spontaneous mutants had normal plants and segregated in a ratio of 9 normal : 7 fasciated plants in F2. Thus, the gene for stem fasciation in the induced mutant JGM 2 (designated fas2) is not allelic to the common gene for stem fasciation in spontaneous mutants. The two genes in dominant condition produced normal non‐fasciated stem. The fasciated and the non‐fasciated F2 plants did not differ significantly for number of pods per plant, number of seeds per plant, grain yield per plant and seed size, suggesting that it is possible to exploit the fasciated trait in chickpea breeding without compromising on yield. 相似文献
6.
Chickpea (Cicer arietinum L.) has a racemose type of inflorescence and at each axis of the raceme usually one or two and rarely three flowers are borne.
Plants producing 3 to 9 flowers, arranged in acymose inflorescence, at many axis of the raceme, were identified in F2 of an interspecific cross ICC 5783 (C. arietinum) × ICCW 9 (C. reticulatum)in which both the parents involved were single-flowered. A spontaneous mutation in one of the two parents or in the F1was suspected. However, the possibility for establishment of a rare recombination of two interacting recessive genes could
not be ruled out. The number of pods set varied from 0 to 5 in each cyme. Inheritance studies indicated that a single recessive
gene, designated cym, is responsible for cymose inflorescence. The allelic relationship of cym with sfl, a gene for double-flowered trait, was studied from a cross involving multi flowered plants and the double-flowered line
ICC 4929. Thecym gene was not allelic to sfl, suggesting that two loci control the number of flowers per peduncle in chickpea. The cym locus segregated independently of the locus sfl, ifc (inhibitor of flower color) and blv (bronze leave).
This revised version was published online in August 2006 with corrections to the Cover Date. 相似文献
7.
The genetics of resistance to green leafhopper, Nephotettix virescens (Distant), in rice varieties ‘IR36’ and ‘Maddai Karuppan’ and breeding line ‘IR20965‐11‐3‐3’ was studied. The reactions of F1 hybrids, F2 populations and F3 lines from the crosses of test varieties with the susceptible variety ‘TN1’ revealed that resistance in ‘IR36’ and ‘Maddai Karuppan’, is governed by single recessive genes while resistance in ‘IR20965‐11‐3‐3’ is controlled by a single dominant gene. Allele tests with the known genes for resistance to green leafhopper revealed that the recessive gene of ‘IR36’ is different from and inherited independently of Glh1, Glh2, Glh3, Glh4, Glh5, Glh8 and Glh9t. This gene is designated as glh10t. The recessive gene of ‘Maddai Karuppan’ and the dominant gene of ‘IR20965‐11‐3‐3’ are also non‐allelic to Glh1, Glh2, Glh3, Glh4, Glh5 and Glh8t. Thus, the dominant gene of IR20965‐11‐3‐3 is designated as Glh11t. The allelic relationships of the recessive gene of ‘Maddai Karuppan’ with glh8 and glh10t should be investigated. 相似文献
8.
M. N. Shrivastava Arvind Kumar Sandeep Bhandarkar B. C. Shukla K. C. Agrawal 《Euphytica》2003,130(1):143-145
The Asian rice gall midge, Orseolia oryzae Wood Mason (Diptera: Cecidomyiidae), is a major pest of rice in several South and South East Asian countries. The maggots
feed internally on the growing tips of the tillers and transform them into tubular galls, onion leaf-like structures called
‘silver shoots’ resulting into severe yield loss to the rice crop. We studied the mode of inheritance and allelic relationships
of the resistance genes involved in resistant donor Line 9, a sib of a susceptible cultivar ‘Madhuri’. The segregation behaviour
of F1, F2 and F3 populations of the cross between Line 9 and susceptible cultivar MW10 confirmed the presence of a single dominant gene for
resistance. Tests of allelism with all the known genes giving resistance to this population indicated that Line 9 possessed
a new gene which was designated Gm 9
This revised version was published online in July 2006 with corrections to the Cover Date. 相似文献
9.
Summary Genetic analysis of generation means of F1, F2, F3, F4, and the parental populations of the cross IR10154-23-3-3A/IR15795-232-3-3-2 for ratooning ability was conducted. Good ratooning ability is a recessive trait. The parents differed by at least two pairs of major genes for ratooning ability. A large proportion of transgressive segregants in F2 suggested that the expression of ratooning ability is influenced not only by major genes but also by modifiers. Broad-sense heritability estimates computed by different methods ranged from 0.66 to 0.88. Narrow-sense heritability by the F4–F3 regression method was 0.39. The heritability estimates were 0.42 and 0.33 by the variance component method. The prevalence of additive x additive type of gene effects along with prominent additive effects imply some scope for selection in the segregating generations. However, non-additive type of gene action also affects the expression of ratooning ability. 相似文献
10.
Identification of QTLs controlling quantitative characters in rice using RFLP markers 总被引:14,自引:0,他引:14
Summary Segregation of plant height (PH), tiller number (TN), panicle number (PN), average panicle length per plant (PL), average primary branch number per panicle per plant (PBN) and 1000 grain weight (1000G) were specific in an F2 population derived from a cross of Palawan, a tall Javanica variety, and IR42, an Indica semidwarf variety. One hundred and four informative RFLP markers covering all 12 chromosomes were used for detecting putative QTLs controlling the traits. Orthogonal contrasts and interval mapping analysis were used for the analysis. QTL detected for PH on the region of chromosome 1, where semidwarfing gene sd-1 locus is located, seems to be a multiple allelic locus. An additional QTL for PH was identified on chromosome 2. Two QTLs for TN were detected on chromosomes 4 and 12. The QTL on chromosome 4 seemed also to govern the variation in PN. Four QTLs were found for the other traits, two of them for PL were located on chromosomes 6 and 2, one for PBN on chromosome 6 and the other for 1000G on chromosome 1. Additive gene actions were found to be predominant, except one QTL for PH and one QTL for PL, but partial or incomplete dominance also existed for the QTLs detected. 相似文献
11.
Summary Inheritance studies on the stem termination in pigeon pea using F1, F2 and F3 generations of two crosses between determinate and indeterminate lines suggested that two dominant genes with epistatic (inhibitory) interaction of one of them control the interminate growth habit. The gene symbols D. idid and ddIdId have been designated to the parental plants with determinate and indeterminate growth habits, respectively. The gene IdId was epistatic (inhibitory) to the gene D giving a ratio of 13 indeterminate: 3 determinate inthe F2's observed. F3 segregation supported the proposed model on the mode of inheritance. 相似文献
12.
Five parents of common vetch (Vicia sativa L.) having orange/beige cotyledon colour, brown/white testa colour, purple/green seedling colour and purple/white flower colour were crossed as a full diallele set. The inheritance patterns of cotyledon, testa or seed coat colour, flower and seedling colour, were studied by analyzing their F1, F2, BC1 and BC2 generations. The segregation pattern in F2, BC1 and BC2, showed that cotyledon colour was governed by a single gene with incomplete dominance and it is proposed that cotyledon colour is controlled by two allelic genes, which have been designated Ct1 and Ct2. Testa colour was governed by a single gene with the brown allele dominant and the recessive allele white. This gene has been given the symbol H. Two complementary genes governed both flower and seedling colours. These flower and seedling colour genes are pleiotropic and the two genes have been given the symbols S and F. 相似文献
13.
Loida M. Perez Edilberto D. Redo?a Merlyn S. Mendioro Casiana M. Vera Cruz Hei Leung 《Euphytica》2008,164(3):627-636
Bacterial blight (BB) of rice caused by X. oryzae pv. oryzae is a major production constraint in commercial hybrid rice production in the Philippines because most of the parental lines
used in hybrid production do not carry resistance genes against the pathogen. In this study, three bacterial blight resistance
genes, Xa4, Xa7 and Xa21, were introgressed to a temperature-sensitive genetic male sterile (TGMS1) line. A three-way cross of AR32-19-3-3/TGMS1//IRBB4/7
(PR36944) was made to produce 1,364 F2 plants carrying various combinations of Xa4, Xa7 and Xa21. Individual plants were characterized for reaction to bacterial blight PXO61 (race 1), PXO86 (race 2), PXO99 (race 6) and
pollen sterility. Of 144 F2 plants demonstrating resistance against PXO61, PXO86 and PXO99, 22 exhibited highly resistant phenotypes with mean lesion
lengths ranging from 0.37–2.97 cm. Analysis of disease reaction identified 20 potential TGMS F2 plants containing Xa4, Xa7 and Xa21 while 78 plants with Xa4 + Xa7. Phenotypic and polymerase chain reaction (PCR) analyses confirmed PR36944-450, PR36944-473 and PR36944-700 as homozygous
for Xa7 and Xa21 and highly resistant to all three Xoo races. Fertility of PR36944-450 and PR36944-700 was restored at permissive temperature in a growth chamber. BB-resistant
TGMS lines should facilitate breeding two-line hybrids in the tropics. 相似文献
14.
A breeding program was initiated at the International Rice Research Institute (IRRI) in 1990 to develop thermosensitive genic
male sterile (TGMS) rice lines for developing two-line rice hybrids for the tropics. The TGMS trait was transferred from a
temperate japonica TGMS mutant, Norin PL 12, to indica and tropical japonica rice varieties using the pedigree selection procedure.
Six new TGMS rice lines adapted to tropical conditions were developed which showed complete pollen and spikelet sterility
when maximum temperature was higher than 30 °C 1–2 week after panicle initiation. However, up to 85.5% spikelet fertility was observed when these lines were exposed to
26–29 °C during the critical stage. Using two of these TGMS lines, some heterotic rice hybrids showing 1–1.6 t/ha higher grain yield
than the inbred check varieties were identified in unreplicated observational yield trial conducted at IRRI. Two of the six
two-line hybrids yielded significantly higher than the check variety in a replicated preliminary yield trial.
This revised version was published online in July 2006 with corrections to the Cover Date. 相似文献
15.
The Russian wheat aphid (RWA), Diuraphis noxia (Mordvilko), has become a serious, perennial pest of wheat (Triticum aestivum L.) in many areas of the world. This study was initiated to determine the inheritance of RWA resistance in PI 140207 (a RWA-resistant spring wheat) and to determine its allelic relationship with a previously reported RWA resistance gene. Crosses were made between PI 140207 and ‘Pavon’ (a RWA-susceptible spring wheat). Genetic analysis was performed on the parents, F1, F2, backcross (BC) population and F2-derived F3 families. Analyses of segregation patterns of plants in the F1, F2, and BC populations, and F2-derived F3 families indicated single dominant gene control of RWA resistance in PI 140207. Results of the allelism test indicated that the resistance gene in PI 140207, while conferring distinctly different seedling reactions to RWA feeding, is the same as Dn 1, the resistance gene in PI 137739. 相似文献
16.
Summary F2 plants of five, and F3 plants of three, crosses between genotypes carrying the race-specific resistance gene Xa-4 and genotypes not carrying this gene were inoculated with two isolates of Xanthomonas campestris pv. oryzae. Half the tillers of each plant received isolate PX061, avirulent on the Xa-4 gene, the other half of the tillers received isolate PX099, virulent for the Xa-4 gene. The F2 and F3 populations segregated for a single dominant resistance gene, Xa-4.The parental, F2 and F3 genotypes not carrying Xa-4 had mean lesion lengths between 28 and 29 cm for both isolates. The Xa-4 carrying parents showed a mean lesion length of 2.7 cm with the avirulent isolate and of 12.4 cm with the virulent isolate. The Xa-4 carrying F2 and F3 genotypes had mean lesion lengths of 5.2 and 20.1 cm for the two isolates, respectively. These observations strongly indicate that the Xa-4 gene, carried by the rice genotypes studied (IR28, Cisadane and BR51-282-8), had a considerable residual effect when exposed to virulent isolate PXO99. 相似文献
17.
Summary Several near-isogenic lines of durum wheat cv. LD222 have been developed. These include a near-isogenic line carrying gene P and designated P-LD222. The P gene from Triticum polonicum determines a long empty outer glume. The objective of this study was to determine the inheritance and chromosomal location of the P gene. To determine the inheritance, P-LD222 was crossed to two chlorina mutants and to a near-isogenic line for the purple culm trait, Pc-LD222. Linkage of the P gene with the mutated gene in chlorina mutant CDd6 indicated that the P gene was located on chromosome 7A. P-LD222 was also crossed with durum cultivar Langdon (LDN) and the LDN D genome substitution lines, LDN 7D(7A) and LDN 7D(7B). Segregation for the long glume trait in the F2 of LDN/P-LD222 and LDN 7D(7B)/P-LD222 was normal (3:1) and indicated P gene was not on chromosome 7B. Significant deviation from a 3:1 in the F2 of LDN 7D(7A)/P-LD222 confirmed the location of P on chromosome 7A, as indicated by the linkage analysis. 相似文献
18.
Summary A true-breeding line characterized by free filaments of anthers and modified keel petal was derived from F2 population of an intergeneric cross between Cajanus cajan (L.) Millsp. and Atylosia lineata W. & A. This variant, designated as partial cleistogamy, favours a high level of self-fertilization. The inheritance of this trait was studied in the F1, F2, F3, and BC1F1 generations of three crosses. The results suggest that the partial cleistogamy trait is governed by a single recessive gene, designated as pct. 相似文献
19.
Genetic analysis and pyramiding of two gall midge resistance genes (Gm-2 and Gm-6t) in rice ( Oryza sativa L.) 总被引:4,自引:0,他引:4
Sanjay Katiyar Satish Verulkar Girish Chandel Yang Zhang Bingchao Huang John Bennett 《Euphytica》2001,122(2):327-334
Asian rice gall midge (Orseolia oryzae) is a major pest across much of south and southeast Asia. This pest is genetically diverse and many gall midge biotypes are
known to exist in each country. During the last three decades, host plant resistance has proved to be the most effective mechanism
of controlling the Asian rice gall midge. Seven genes conditioning resistance to gall midge larvae have been identified in
rice (Oryza sativa) and are being used in cultivar improvement programs. However, some of these genes are rendered ineffective by new gall midge
biotypes. Increased understanding of genetics, inheritance, allelic relationships and linkage is necessary to maximise the
durability of major gene resistance by the pyramiding of these genes. The two genes, Gm-2 and Gm-6(t), are known to confer resistance against a number of biotypes in India and China, respectively. An F3 population derived from a cross between Duokang #1 (donor of Gm-6(t)) and Phalguna (donor of Gm-2) was screened against Chinese gall midge biotype 4 at Guangdong, China, and Indian gall midge biotype 1 at Raipur, India.
At each location, separately,a single gene governed resistance. The parallel segregation of 417 F3progenies for both biotypes at two locations revealed that recombination had occurred between the two genes, establishing
that the two genes are not allelic. However, the two genes Gm-2 and Gm-6(t), were found to be linked with a distance of ∼16.3 cM. A number of lines homozygous at one locus and segregating for the other
locus were identified and selected. These lines were selfed to obtain lines homozygous for the favourable alleles at both
loci (two locus pyramids). This is the first report on use of conventional host-pest interaction method for pyramiding two
closely located Gm-resistance loci of dissimilar effects. The implications of deployment of these pyramids within and across
country borders, with reference to the prevailing gall midge populations are discussed.
This revised version was published online in August 2006 with corrections to the Cover Date. 相似文献
20.
Summary Three lentil genotypes resistant to Fusarium oxysporum f.sp. lentis viz. Pant L 234, JL 446 and LP 286 were crossed with two susceptible ones. The hybrid plants were all resistant in the eight crosses evaluated. Segregation pattern for wilt reaction in F2, BC(P1), BC(P2) and F3 generations in field and glasshouse conditions indicated that resistance to Fusarium wilt is under the control of two dominant duplicate genes in Pant L 234 and two independent dominant genes with complementary effects in JL 446 and LP 286. A third dominant gene complementary to the dominant genes in JL 446 and LP 286 is present in two susceptible lines. Allelic tests suggest the presence of five independently segregating genes for resistance. Duplicate dominant genes in Pant L 234 are non-allelic to two dominant genes with complementary effects in LP 286 and JL 446 and the third gene complementary to the two genes in JL 446 and LP 286 in susceptible lines JL 641 and L 9–12. Gene symbols among parental genotypes have been designated. 相似文献