Identification of differentially expressed genes in three-pistil mutation in wheat using annealing control primer system

The common wheat line three-pistil (TP) is a valuable mutant for wheat breeding. The TP mutation has normal spike morphology; however, it only produces three pistils per floret. Therefore, it has potential to increase the grain number per spike. In order to determine the underlying molecular mechanism, an annealing control primer system was used to identify the different expressed genes in three-pistil mutation. Using 120 arbitrary ACP primers, we identified three differentially expressed genes in young spikes between two near-isogenic lines (i.e., Chuanmai 28 TP and Chinese Spring TP) and their recurrent parents. We tentatively designated the three differentially expressed genes as DETP-1, DETP-2, and DETP-3. DETP-1 showed similar function with maize cytoplasmic membrane protein, which is involved in cell division in bacteria. DETP-3 is homologous to maize endo-1, 4-beta-glucanase (EGases), which is associated with plant development, cell wall loosening, stem flowering, and root expansion. DETP-2 showed no significant hit with any sequence found in the database and translates unknown protein. These genes would likely play an important role in determining the three pistils trait in wheat.     

A molecular marker associated with the H21 Hessian fly resistance gene in wheat

Near-isogenic lines in conjunction with bulked segregant analysis were used to identify a DNA marker in wheat (Triticum aestivum L.) associated with the H21 gene conferring resistance to biotype L of Hessian fly [Mayetiola destructor (Say)] larvae. Near-isogenic lines were developed by backcross introgression BC3F3:4 (Coker 797 * 4 / Hamlet) and differed by the presence or absence of H21 (on 2RL) derived from Chaupon rye (Secale cereale L.). Bulked DNA samples were prepared from near-isogenic lines and BC3F2 population individuals segregating for reaction to Hessian fly biotype L and screened for random amplified polymorphic DNA markers using 46 10mer primers. Random-amplified polymorphic DNA markers from resistant and susceptible individuals and parental lines were scored and these data were used to identify a 3 kb DNA fragment that was related to the occurrence of H21. This fragment was amplified from DNA isolated from Hamlet, a near-isogenic line carrying 2RL, and bulked DNA from resistant BC3F2 individuals, but not from the recurrent parent Coker 797 or DNA bulks from susceptible BC3F2 plants. Analysis of 111 BC3F2 segregating individuals and BC3F2:3 segregants confirmed the co-segregation of the 3 kb DNA marker with the H21 resistance gene to Hessian fly. Use of this marker could facilitate more rapid screening of plant populations for Hessian fly resistance and monitoring the introgression of H21.     

Heterogeneous inbred family (HIF) analysis: a method for developing near-isogenic lines that differ at quantitative trait loci

Abtract  Analysis of near-isogenic lines (NILs) that differ at quantitative trait loci (QTL) can be an effective approach for the detailed mapping and characterization of individual loci. Although NILs are useful for genetic and physiological studies, the time and effort required to develop these lines have limited their use. Here we describe a procedure to identify NILs for any region of the genome that can be analyzed with molecular or other genetic markers. The procedure utilizes molecular markers to identify heterogeneous inbred families (HIFs) that segregate for a genomic region of interest. Each HIF is isogenic at the majority of loci in the genome, but NILs differing for markers linked to QTL of interest can be extracted from segregating families. The application of this procedure is described for two QTL associated with seed weight in sorghum. A population of 98 HIFs was screened with two RAPD markers from different linkage groups that were associated with seed weight. Three segregating families were identified for each marker. The progeny of these HIFs were characterized for the segregation of seed weight and other yield components and for markers flanking each QTL. NILs derived from each HIF had significantly different seed weights confirming the presence of at least two loci that influence seed weight in sorghum. Received: 16 September 1996 / Accepted: 25 April 1997     

Identification of an RFLP marker tightly linked to theHt1 gene in maize

Summary We have identified tight linkage of an RFLP marker to theHt1 gene of maize that confers resistance to the fungal pathogenHelminthosporium turcicum race 1. This was accomplished by the use of four pairs of near isogenic lines (NILs; B73, A619, W153R, and CM105), each differing by the presence or the absence of the geneHt1. SinceHt1 maps to chromosome 2, 26 clones already mapped to this chromosome were labeled and probed against Southern blots of these NILs DNA digested with three restriction enzymes:EcoRI,BamHI, andHindIII. Six markers exhibited an RFLP for at least one pair of NILs. Presumptive linkage was further tested by analyzing the segregation of five of the six markers (one was monomorphic in the cross studied) and resistance toH. turcicum race 1 on 95 F₂ individuals from the cross DF20 × LH146Ht. The results indicate a tight linkage between one of the DNA markers,UMC150B, and theHt1 gene.     

Heterogeneous inbred populations are useful as sources of near-isogenic lines for RAPD marker localization

The development and use of RAPD markers for applications in crop improvement has recently generated considerable interest within the plant breeding community. One potential application of RAPDs is their use for tagging simply-inherited (monogenic) pest-resistance genes and enabling more efficient identification and selection of genotypes carrying specific combinations of resistance genes. In this report, we propose and describe the use of heterogeneous inbred populations as sources of near-isogenic lines (NILs) for targeting RAPD markers linked to major pest resistance genes. The development of these NILs for RAPD marker analyses involved a sequence of line and mass selection during successive generations of inbreeding. DNA bulks derived from the NILs were used to identify a RAPD marker (designated OK14₆₂₀, generated by 5-CCCGCTACAC-3 decamer) that was tightly linked (2.23±1.33 centiMorgans) to an important rust [Uromyces appendiculatus (Pers.) Unger var. appendiculatus] resistance gene (Ur-3) in common bean (Phaseolus vulgaris L.). The efficiency of this approach was demonstrated by a low rate of false-positives identified, the tightness of the linkage identified, and the ability to detect polymorphism between genomic regions that are representative of the same gene pool of common bean. This method of deriving NILs should find application by researchers interested in utilizing marker-assisted selection for one or more major pest resistance genes. The identification of OK14₆₂₀ should help to facilitate continued use of the Ur-3 resistance source and will now enable marker-assisted pyramiding of three different bean rust resistance sources (two previously tagged) to provide effective and stable resistance to this important pathogen.Research supported in part by the grant DAN 1310-G-SS-6008-00 from the USAID Bean/Cowpea Collaborative Research Support Program, the Michigan Agricultural Experiment Station, and the USDA-ARS. Mention of a trademark or a proprietary product does not constitute a guarantee or warranty of the product by the USDA and does not imply its approval to the exclusion of other products that may also be suitable     

Identification of RAPD markers linked to the Tm-2 locus in tomato

Tm-2 and Tm-2a are genes conferring resistance to tomato mosaic virus in Lycopersicon esculentum. They are allelic and originated from different lines of L. peruvianum, a wild relative of tomato. In this study, random amplified polymorphic DNA (RAPD) markers linked to these genes were screened in nearly isogenic lines (NILs). To detect RAPDs differentiating NILs, 220 different 10-base oligonucleotide primers were examined by the polymerase chain reaction (PCR), and 43 of them generated 53 consistent polymorphic fragments among the NILs. Out of these 53 fragments, 13 were arbitrarily chosen and examined in respect of whether they were linked to the netted virescent (nv) gene, since nv is tightly linked to the Tm-2 locus and its phenotype is more easily distinguishable. As a result, all 13 markers were shown to be linked to nv, and hence to the Tm-2 locus. Among them, two fragments specific to the NIL carrying Tm-2 three specific to the NIL carrying Tm-2a, and four specific to both of these NILs were closely linked to nv.     

Evaluation of resistance genes in rice against local isolates of Xanthomonas oryzae pv. oryzae in Punjab Province of Pakistan

Absence of resistance/tolerance against bacterial leaf blight (BLB), incited by Xanthomonas oryzae pv. oryzae, in famous basmati varieties is one of the main reason for BLB epidemic in Punjab in 2007–2008. For developing resistance against BLB, the response of 26 IRBB lines of IRRI including 10 near isogenic lines (NILs) and 16 gene pyramids carrying two to five resistance genes (Xa series) was evaluated against 61 indigenous Xoo isolates under artificial inoculation field conditions. None of the NILs or gene pyramid provides complete protection against all the isolates. However, Xa21 and xa13 were found resistant against the majority of Xoo isolates, followed by Xa14 and Xa7. Of the 16 gene pyramids used in this study, IRBB-54 (Xa5 + Xa21), IRBB-55 (Xa13 + Xa21) followed by IRBB-58 (Xa4 + Xa13 + Xa21) were found effective against the majority of the Xoo isolates. These resistance genes (individually and in combinations) can be incorporated for the improvement of basmati rice cultivars cultivated in Punjab province of Pakistan. Effectiveness of gene combination supports the strategy of pyramiding appropriate resistance genes. Newly identified resistant genes may also be evaluated for achieving broad spectrum resistance against more Xoo isolates of the area.     

Quality differences between NILs of wheat variety Long 97-586 possessing HMW-GS 7+8 and 7

The high molecular weight glutenin subunits (HMW-GS) 7+8 were introduced into the Long 97–586 (1,7,2+12) wheat variety (Triticum aestivum) by 5 consecutive backcrosses with biochemical marker–assisted selection.Nearly isogenic lines (NILs) of HMW-GS 7 and 7+8 were obtained,and the NILs were planted in the experimental field at the Crop Breeding Institute of Heilongjiang Academy of Agricultural Science in 2004–2006.The field experiments were designed using the two-column contrast arrangement method with six replicates in 2004–2005 and four replicates in 2006.The result of three years experiments showed that the differences between NILs of Long 97–586 with subunit 7 and those with subunits 7+8 in the quality parameters of flour protein content and dry gluten content were negligible (P0.1).However,the differences in some of the quality parameters were remarkably significant (P0.01),including wet gluten content,ratio of wet gluten/dry gluten,gluten index,Zeleny sedimentation,ratio of sedimentation/dry gluten,and the farinogram parameters of water absorption,development time,stability,breakdown time and degree of softening.The difference between NILs with subunits 7+8 and subunit 7 was significant (P0.05) on the alveogram W value and had a critical value (P=0.05) on the alveogram P value in 2006.The results show that HMW-GS 7+8 is far superior to HMW-GS 7 in terms of baking quality.The possibilities of using subunits 7+8 and subunit 7 in breeding strong and weak gluten wheat varieties are discussed in this paper.