Detection of walnut residues in processed foods by polymerase chain reaction

A sensitive qualitative detection method for walnut (Juglans regia) using polymerase chain reaction (PCR) was developed. For detection of walnuts with high specificity, the primer pair WAL-F/WAL-R was designed based on walnut matK genes. Trace amounts of walnuts in commercial food products can be qualitatively detected using this method.     

Phytopatological problems and solutions in the walnut orchards along Lake Balaton

European or Persian Walnut (Juglans regia) is an important and healthy food as well as base material of timber industry. Several pests (pathogens and insect pests) may cause serious damages on walnut. These are less known on the crop land of the tree. Results of some years of our experiments including bacteriological and mycological studies, are presented in this paper. The optimum time of chemical protection against the walnut blight (Xanthomonas arboricola pv. juglandis) was determined. Occurrences of pathogenic fungi were surveyed in an orchard and on home garden trees in Hungary (18 fungus species were identified). The following experimental results are reported on the pathogenic fungi: cultivar resistance to walnut anthracnose (Gnomonia leptostyla), dying of wood parts in the cultivar collection, application of the spore trap, in vitro fungicide testing against Phomopsis juglandina.     

In-silico mining,type and frequency analysis of genic microsatellites of finger millet (Eleusine coracana (L.) Gaertn.): a comparative genomic analysis of NBS–LRR regions of finger millet with rice

In recent years, the increased availability of the DNA sequences has given the possibility to develop and explore the expressed sequence tags (ESTs) derived SSR markers. In the present study, a total of 1956 ESTs of finger millet were used to find the microsatellite type, distribution, frequency and developed a total of 545 primer pairs from the ESTs of finger millet. Thirty-two EST sequences had more than two microsatellites and 1357 sequences did not have any SSR repeats. The most frequent type of repeats was trimeric motif, however the second place was occupied by dimeric motif followed by tetra-, hexa- and penta repeat motifs. The most common dimer repeat motif was GA and in case of trimeric SSRs, it was CGG. The EST sequences of NBS-LRR region of finger millet and rice showed higher synteny and were found on nearly same positions on the rice chromosome map. A total of eight, out of 15 EST based SSR primers were polymorphic among the selected resistant and susceptible finger millet genotypes. The primer FMBLEST5 could able to differentiate them into resistant and susceptible genotypes. The alleles specific to the resistant and susceptible genotypes were sequenced using the ABI 3130XL genetic analyzer and found similarity to NBS–LRR regions of rice and finger millet and contained the characteristic kinase-2 and kinase 3a motifs of plant R-genes belonged to NBS–LRR region. The In-silico and comparative analysis showed that the genes responsible for blast resistance can be identified, mapped and further introgressed through molecular breeding approaches for enhancing the blast resistance in finger millet.     

Functional markers based molecular characterization and cloning of resistance gene analogs encoding NBS-LRR disease resistance proteins in finger millet (<Emphasis Type="Italic">Eleusine coracana)</Emphasis>

Magnaporthe grisea, the blast fungus is one of the main pathological threats to finger millet crop worldwide. A systematic search for the blast resistance gene analogs was carried out, using functional molecular markers. Three-fourths of the recognition-dependent disease resistance genes (R-genes) identified in plants encodes nucleotide binding site (NBS) leucine-rich repeat (LRR) proteins. NBS-LRR homologs have only been isolated on a limited scale from Eleusine coracana. Genomic DNA sequences sharing homology with NBS region of resistance gene analogs were isolated and characterized from resistant genotypes of finger millet using PCR based approach with primers designed from conserved regions of NBS domain. Attempts were made to identify molecular markers linked to the resistance gene and to differentiate the resistant bulk from the susceptible bulk. A total of 9 NBS-LRR and 11 EST-SSR markers generated 75.6 and 73.5% polymorphism respectively amongst 73 finger millet genotypes. NBS-5, NBS-9, NBS-3 and EST-SSR-04 markers showed a clear polymorphism which differentiated resistant genotypes from susceptible genotypes. By comparing the banding pattern of different resistant and susceptible genotypes, five DNA amplifications of NBS and EST-SSR primers (NBS-05_504, NBS-09₇₁₁, NBS-07₆₈₈, NBS-03₅₀₉ and EST-SSR-04₂₄₁) were identified as markers for the blast resistance in resistant genotypes. Principal coordinate plot and UPGMA analysis formed similar groups of the genotypes and placed most of the resistant genotypes together showing a high level of genetic relatedness and the susceptible genotypes were placed in different groups on the basis of differential disease score. Our results provided a clue for the cloning of finger millet blast resistance gene analogs which not only facilitate the process of plant breeding but also molecular characterization of blast resistance gene analogs from Eleusine coracana.     

Development of SCAR marker linked to anthracnose resistance from Indian French bean (Phaseolus vulgaris L.) germplasm

This study was performed to identify the French bean genotypes resistant to anthracnose disease. Thirty-five RAPD primers were used for screening four resistant and nine susceptible French bean accessions. Of these, three RAPD primers, viz. OPAH16₇₀₀, OPN6₇₀₀ and OPS₉₀₀ showed polymorphic bands differentiating between resistant and susceptible genotypes. The RAPD primer OPAH16 was then selected for conversion into a SCAR marker. The polymorphic band present in the resistant line (D line) was eluted, cloned in pTZ57R/T cloning vector and was then transferred into DH5α Escherichia coli cells. The positively transformed clones were selected based on ampicillin resistance blue-white colony selection method. The plasmid DNA was isolated from transformed white colonies, sequenced and developed into SCAR marker SPAH 16. This SCAR marker SPAH 16 was then verified via PCR using the original French bean accessions.     

美国黑核桃SSR反应体系优化

优化SSR-PCR反应体系是黑核桃（Juglans nigra L.）SSR基因鉴定和群体遗传等研究的基础。本研究通过对PCR反应中Mg²⁺浓度、牛血清白蛋白（Bovine Serum Albumin,BSA）浓度、Taq聚合酶用量、dNTPs浓度、引物浓度和模板DNA量的组合以及PCR程序组合试验,确定了黑核桃SSR的最佳反应体系,即在10 μL的PCR反应体系中,含10 ng模板DNA,0.1 mg·mL^-1牛血清蛋白（BSA）,0.25 mmol·L^-1 dNTPs,1.5 mmol·L^-1 Mg²⁺ 1 μL 10X Taq DNA聚合酶反应缓冲液,0.5 U Taq聚合酶,1.0 mmol·L^-1单对引物（0.5 mmol·L^-13对引物）。SSR-PCR反应扩增程序为：94℃变性3 min;93℃变性15 s,50℃或者53.5℃退火1 min,72℃延伸30 s,32个循环;72℃后延伸10 min,置4℃保存。利用此反应体系对黑核桃进行PCR扩增并电泳检测,其结果清晰、稳定、可靠,适合进一步对黑核桃群体遗传、基因型鉴定和分子生态研究。     

Polygalacturonase inhibitor protein from fruits of anthracnose resistant and susceptible varieties of Chilli (Capsicum annuum L)

Chilli fruit is highly susceptible to anthracnose infection at the stage of harvest maturity, due to which the fruit yield in the leading commercial variety Byadgi is severely affected. Field studies on screening of several varieties for resistance to anthracnose have shown that a variety of chilli AR-4/99K is resistant to anthracnose infection. In many crops, resistance to fungal attack has been correlated with PGIP activity in developing fruits based on which transgenic varieties have been developed with resistance to fungi. The present study was carried out to determine whether anthracnose resistance in AR-4/99K was due to the increased levels of PGIP alone and/ or due to differences, if any, in the properties of PGIP. Hence, a comparative study of the properties of polygalacturonase inhibitor protein (PGIP) isolated from fruits of anthracnose resistant chilli var AR-4/99K and a susceptible variety Byadgi was conducted with the objective of utilizing the information in genetic transformation studies. Both the PGIPs from anthracnose resistant and susceptible varieties of chilli exhibited similarities in the elution pattern on Sephadex gel, DEAE cellulose, PAGE and SDS-PAGE. The two PGIPs were active over a wide range of pH and temperature. Both PGIPs showed differential inhibitory activity against polygalacturonase (PG) secreted by Colletotrichum gleosporoides, C. capsici, C. lindemuthianum, Fusarium moniliforme and Sclerotium rolfsii. The inhibitory activity of PGIP from both resistant and susceptible varieties was the highest (82% and 76%, respectively) against the PG from Colletotrichum capsici, a pathogen causing anthracnose rot of chilli, while the activity was lower (1.27 to 12.3%) on the other fungal PGs. Although PGIP activity decreased with fruit maturation in both the varieties, the resistant variety maintained a higher activity at 45 days after flowering (DAF) as compared to the susceptible variety which helped it to overcome the infection by anthracnose as against the susceptible variety (Byadgi) in which PGIP activity was drastically reduced at maturity. The molecular mass of PGIP as determined by SDS-PAGE was found to be 37 kDa. N-terminal sequence analysis of the PGIP showed the first six amino acid residues from N-terminal end were Asp-Thr-His-Lys-Ser-Glu (DTHKSE), respectively. The similarities in properties of the two PGIPs support the earlier findings that resistance of AR-4/99K to anthracnose fungus is a result of its higher PGIP activity at maturity.     

核桃JrNPR1基因的克隆与抗病响应潜力

病程相关基因非表达子NPR1（Nonexpressor of pathogenesis-related gene 1）基因,在植物抗病过程中起核心调控作用。核桃（Juglans regia）是我国乡村振兴的重要经济油料树种,其生长和产量严重受病虫害制约。为探索核桃抗病生理机制,筛选抗病基因,以‘香玲’核桃为试材,克隆获得JrNPR1基因,对其基本生物信息和病害响应进行分析,预测JrNPR1响应病害的功能。结果显示：JrNPR1基因开放读码框（ORF）长1 782 bp,包含593个氨基酸,理论等电点为6.40;与杨梅（Morella rubra）、蓖麻（Ricinus communis）等同源蛋白进行多序列比对,发现均有NPR1-like-C保守结构域,且JrNPR1与杨梅和欧洲栓皮栎（Quercus suber）等的同源蛋白具有较近的进化关系。其上游1 233 bp启动子中含有多种与植物抗病相关的顺式作用元件,如,WRKY71OS。在胶孢炭疽菌（Colletotrichum gloeosporioides）、矩圆黑盘孢菌（Melanconium oblongum）、黄单胞菌（Xanthomonas campestris）等病原处理下,JrNPR1被显著诱导,且其表达在水杨酸（Salicylic acid,SA）存在下高出单一病原处理的1.31~178.89倍。表明JrNPR1基因可能是抵抗核桃炭疽病、枝枯病、细菌性黑斑病的重要基因,且涉及SA信号通路。     

Genetic variation in walnuts (Juglans regia and J. sigillata; Juglandaceae): Species distinctions, human impacts, and the conservation of agrobiodiversity in Yunnan, China

Walnuts are a major crop of many countries and mostly cultivated in large-scale plantations with few cultivars. Landraces provide important genetic reservoirs; thus, understanding factors influencing the geographic distribution of genetic variation in crop resources is a fundamental goal of agrobiodiversity conservation. Here, we investigated the role of human settlements and kinship on genetic variation and population structure of two walnut species: Juglans regia, an introduced species widely cultivated for its nuts, and J. sigillata, a native species cultivated locally in Yunnan. The objectives of this study were to characterize sympatric populations of J. regia and J. sigillata using 14 molecular markers and evaluate the role of Tibetan villages and kin groups (related households) on genotypic variation and population structure of J. regia and J. sigillata. Our results based on 220 walnut trees from six Tibetan villages show that although J. regia and J. sigillata are morphologically distinct, the two species are indistinguishable based on microsatellite data. Despite the lack of interspecific differences, AMOVAs partitioned among villages (5.41%, P = 0.0068) and kin groups within villages (3.34%, P = 0.0068) showed significant genetic variation. These findings suggest that village environments and familial relationships are factors contributing to the geographic structure of genetic variation in Tibetan walnuts.     

Molecular and morphological evaluation of transgenic Persian walnut plants harboring Fld gene under osmotic stress condition

Molecular Biology Reports - Soil drought stress is a limiting factor of productivity in walnut (Juglans regia L). Ferredoxin (Fd) level decreases under adverse environmental stress. Functional...     

Genomic organization, rapid evolution and meiotic instability of nucleotide-binding-site-encoding genes in a new fruit crop, "chestnut rose"

From chestnut rose, a promising fruit crop of the Rosa genus, powdery mildew disease-resistant and susceptible genotypes and their F(1) progeny were used to isolate nucleotide-binding-site (NBS)-encoding genes using 19 degenerate primer pairs and an additional cloning method called overlapping extension amplification. A total of 126 genes were harvested; of these, 38 were from a resistant parent, 37 from a susceptible parent, and 51 from F(1) progeny. A phylogenetic tree was constructed, which revealed that NBS sequences from parents and F(1) progeny tend to form a mixture and are well distributed among the branches of the tree. Mapping of these NBS genes suggested that their organization in the genome is a "tandem duplicated cluster" and, to a lesser extent, a "heterogeneous cluster." Intraspecific polymorphisms and interspecific divergence were detected by Southern blotting with NBS-encoding genes as probes. Sequencing on the nucleotide level revealed even more intraspecific variation: for the R4 gene, 9.81% of the nucleotides are polymorphic. Amino acid sites under positive selection were detected in the NBS region. Some NBS-encoding genes were meiotically unstable, which may due to recombination and deletion events. Moreover, a transposon-like element was isolated in the flanking region of NBS genes, implying a possible role for transposon in the evolutionary history of resistance genes.     

Quantification of yield losses caused by leaf anthracnose on sorghum in Brazil

The leaf anthracnose disease in sorghum, caused by Colletotrichum sublineolum (Henn. ex Sacc. & Trotter), is widely distributed throughout its Brazilian cultivation areas. The disease can cause significant losses in grain yield and quality. This study aimed to quantify the effects of leaf anthracnose on grain yield of different sorghum genotypes. Two elite inbred lines of sorghum, BR009 (susceptible) and BR008 (moderately resistant), and the hybrids, BR304 and MR43 (susceptible), BRS310 and DKB599 (moderately resistant) and BRS308 and AG1060 (resistant), were planted in a complete randomized block design with three replicates. The disease severity (DS) was evaluated weekly, starting from the onset of the first foliar symptoms, and yield losses were estimated using linear regression analysis. Leaf anthracnose significantly reduced sorghum yields in the susceptible genotypes. The highest yield loss of 86% was observed in the inbred line BR009, when the disease severity reached 100%. For the hybrids, the grain yield loss varied from 35% (BRS310) to 72% (BRS308). According to the adjusted model, a grain yield reduction of 23.48 kg/ha for BR304, 14.57 kg/ha for BRS310 and 15.91 kg/ha for DKB599 was observed for every 1% increase in disease severity. We demonstrate for the first time the effect of leaf anthracnose disease on grain sorghum yields under Brazilian conditions. The results from this study provide a starting point for developing new strategies for the integrated disease management of sorghum anthracnose.     

用AFLP技术分析四川核桃资源的遗传多样性

 利用AFLP分子标记技术, 运用EcoRⅠ/MseⅠ双酶切组合, 选用多态性高、分辨力强的4对选择性扩增引物组合E32/M48、E33/M61、E35/M61、E33/M62分别对四川省3个野生核桃(Juglans regia)种群和1个野生铁核桃(J. sigillata)种群共46个样品进行遗传多样性分析、居群遗传结构分析及种属关系探讨。结果表明: 1)共扩增出244个遗传位点, 其中146个多态位点, 多态率为59.84%; 核桃群体组和铁核桃群体的多态性百分率分别为55.33%和52.05%, 两个物种遗传多态性水平相当; 核桃群体组所检出的位点平均有效等位基因数Ae、Nei’s基因多样度H、平均Shannon信息指数I分别为1.322 9、0.190 8和0.286 3, 而铁核桃群体分别为1.339 9、0.196 1和0.289 8, 铁核桃群体遗传多样性水平略高于核桃群体。2)群体间特异带及群体间共有带占总扩增带数的15.16%, 其中铁核桃群体特异谱带最多, 群体特异谱带揭示了群体间的遗传差异及相似性。3) Shannon信息指数(I)、Nei’s基因多样性指数(H)和分子方差分析(AMOVA)表明核桃遗传多样性在群体间和群体内的分布分别为14.36%和85.64%、12.6%和87.4%、11.07%和88.93%, 表明群体内的遗传多样性大于群体间的遗传多样性; 核桃群体组与铁核桃群体的变异主要存在于群体组内, 组间的遗传变异仅占总变异的9.35%, 两者间的遗传分化系数Gst为0.093 5, 与AMOVA分析结果一致。4) 4个群体的Nei’s遗传距离在0.038 2～0.069 2之间, 遗传一致度在0.933 2～0.962 5之间, 表现出较高的遗传相似性; 运用Nei’s遗传一致度对供试种群进行了UPGMA聚类, 结果表明核桃的3个群体优先聚类, 大渡河流域群体与甘南地区群体聚类最近。AFLP所检测出的结果既是核桃与铁核桃生物学特性的反映, 又是其各自生态学特性的反映, 该研究结果对核桃种质资源的保护和育种提供一定的理论依据。     

Characterizing the walnut genome through analyses of BAC end sequences

Persian walnut (Juglans regia L.) is an economically important tree for its nut crop and timber. To gain insight into the structure and evolution of the walnut genome, we constructed two bacterial artificial chromosome (BAC) libraries, containing a total of 129,024 clones, from in vitro-grown shoots of J. regia cv. Chandler using the HindIII and MboI cloning sites. A total of 48,218 high-quality BAC end sequences (BESs) were generated, with an accumulated sequence length of 31.2?Mb, representing approximately 5.1% of the walnut genome. Analysis of repeat DNA content in BESs revealed that approximately 15.42% of the genome consists of known repetitive DNA, while walnut-unique repetitive DNA identified in this study constitutes 13.5% of the genome. Among the walnut-unique repetitive DNA, Julia SINE and JrTRIM elements represent the first identified walnut short interspersed element (SINE) and terminal-repeat retrotransposon in miniature (TRIM) element, respectively; both types of elements are abundant in the genome. As in other species, these SINEs and TRIM elements could be exploited for developing repeat DNA-based molecular markers in walnut. Simple sequence repeats (SSR) from BESs were analyzed and found to be more abundant in BESs than in expressed sequence tags. The density of SSR in the walnut genome analyzed was also slightly higher than that in poplar and papaya. Sequence analysis of BESs indicated that approximately 11.5% of the walnut genome represents a coding sequence. This study is an initial characterization of the walnut genome and provides the largest genomic resource currently available; as such, it will be a valuable tool in studies aimed at genetically improving walnut.     

Identification of SCAR markers linked to Rca2 anthracnose resistance gene and their assessment in strawberry germplasm

Bulked segregant analysis combined with AFLPs was used to identify molecular markers linked to the Rca2 gene conferring resistance to Colletotrichum acutatum pathogenicity group 2 which causes anthracnose in the octoploid strawberry Fragaria × ananassa. DNA bulks originating from a cross between the resistant cultivar ‘Capitola’ and the susceptible cultivar ‘Pajaro’ were screened with 110 EcoRI/MseI AFLP combinations. Four AFLP markers were found linked in coupling phase to Rca2 with recombination percentages between 0% and 17.7%. Among the four markers linked to the resistance gene, two were converted into SCAR markers (STS-Rca2_417 and STS-Rca2_240) and screened in a large segregating population including 179 genotypes. The Rca2 resistance gene was estimated to be 0.6 cM from STS-Rca2_417 and 2.8 cM from STS-Rca2_240. The presence/absence of the two SCAR markers was further studied in 43 cultivars of F. × ananassa, including 14 susceptible, 28 resistant, and one intermediate genotype. Results showed that 81.4% and 62.8% of the resistant/susceptible genotypes were correctly predicted by using STS-Rca2_417 and STS-Rca2_240, respectively. The 14 susceptible genotypes showed no amplification for either SCARs. These developed SCARs constitute new tools for indirect selection criteria of anthracnose resistance genotypes in strawberry breeding programs.     

Long-term human impacts on genetic structure of Italian walnut inferred by SSR markers

Life history traits, historic factors, and human activities can all shape the genetic diversity of a species. In Italy, walnut (Juglans regia L.) has a long history of cultivation both for wood and edible nuts. To better understand the genetic variability of current Italian walnut resources, we analyzed the relationships among the genetic structure of local walnut populations (inferred by SSR markers) and human migrations along ancient routes, using the territory of Royal Tratturo Candela-Pescasseroli (RT) as a case study. Sixteen J. regia provenances were collected along RT and compared with 13 Italian provenances and the landrace Sorrento. Although the level of SSR polymorphism we observed was moderately high, AMOVA revealed that most of the diversity was located within individuals (92.58%), and geographical differentiation was low (D _est = 0.076). Evidence for human-mediated domestication bottleneck events was detected in about 95% of walnut provenances. A Bayesian approach divided 456 walnut samples into three clusters: (1) Sorrento genotypes, (2) trees from the island of Sicily, and (3) the remaining germplasm. The UPGMA tree based on Nei's distances distinguished northeastern provenances and weakly grouped 12 of 16 provenances of RT. The observed genetic differences derived mainly from gradations in allele frequencies. Separation of the Sicilian provenance from the mainland may be explained in terms of founder effects and prolonged geographic isolation. Two contrasting forces, selection, and frequent inter-regional transfer of propagules, appear to drive the patterns of genetic variability for J. regia.     

Identification and application of RAPD markers for anthracnose resistance in water yam (Dioscorea alata)

Anthracnose, caused by Colletotrichum gloeosporioides, is the most severe foliar disease of water yam (Dioscorea alata) worldwide. The tetraploid breeding line, TDa 95/00328, is a source of dominant genetic resistance to the moderately virulent fast growing salmon (FGS) strain of C. gloeosporioides. Bulked segregant analysis was used to search for random amplified polymorphic DNA (RAPD) markers linked to anthracnose resistance in F₁ progeny derived from a cross between TDa 95/00328 and the susceptible male parent, TDa 95–310. Two hundred and eighty decamer primers were screened using bulks obtained from pooled DNA of individuals comprising each extreme of the disease phenotype distribution. A single locus that contributes to anthracnose resistance in TDa 95/00328 was identified and tentatively named Dcg‐1. We found two RAPD markers closely linked in coupling phase with Dcg‐1, named OPI7₁₇₀₀ and OPE6₉₅₀, both of which were mapped on the same linkage group. OPI7₁₇₀₀ appeared tightly linked to the Dcg‐1 locus; it was present in all the 58 resistant F₁ individuals and absent in all but one of the 13 susceptible genotypes (genetic distance of 2.3 cM). OPE6₉₅₀ was present in 56 of the 58 resistant progeny and only one susceptible F₁ plant showed this marker (6.8 cM). Both markers successfully identified Dcg‐1 in resistant D. alata genotypes among 34 breeding lines, indicating their potential for use in marker‐assisted selection. OPI7₁₇₀₀ and OPE6₉₅₀ are the first DNA markers for yam anthracnose resistance. The use of molecular markers presents a valuable strategy for selection and pyramiding of anthracnose resistance genes in yam improvement.     

Genetic Diversity of Xanthomonas arboricola pv. juglandis (synonyms: X. campestris pv. juglandis;X. juglandis pv. juglandis) Strains from Different Geographical Areas shown by Repetitive Polymerase Chain Reaction Genomic Fingerprinting

A world-wide collection of 61 Xanthomonas arboricola pv. juglandis strains, isolated from Persian walnut ( Juglans regia L.) or obtained from international culture collections and bacterial plant diseases laboratories, were studied by means of repetitive polymerase chain reaction (PCR) genomic fingerprinting using ERIC, BOX and REP primer sets and polyacrylamide gel electrophoresis. Cluster analyses were performed by UPGMA . Copper resistance, ability to hydrolize starch and quinate metabolism of the strains was also assessed. Pathogenicity was tested by inoculating leaves and nuts of Persian walnut seedlings. Polyacrylamide gel electrophoresis allowed very clear and reproducible differentiation of the PCR products. Cluster analysis showed the existence of three major groups of strains. The first two groups were 85% genetically similar, whereas the third clustered at 78% similarity with the other two. Each group could be divided into two subgroups which clustered according to the geographical origin of the isolates. In some cases, different genomic profiles were shown by strains from one country. This is possibly due to Persian walnut cultivation being mainly based on ecotypes and/or local seedlings that have become adapted to particular environments and so have allowed selection of different X.a . pv. juglandis populations. All strains were pathogenic and positive in starch hydrolysis and quinate metabolism tests. This is the first record of copper-resistant strains occurring outside California, USA.     

RAPD-based SCAR marker SCA 12 linked to recessive gene conferring resistance to anthracnose in sorghum [Sorghum bicolor (L.) Moench]

Anthracnose, caused by Colletotrichum graminicola, infects all aerial parts of sorghum, Sorghum bicolor (L.) Moench, plants and causes loss of as much as 70%. F₁ and F₂ plants inoculated with local isolates of C. graminicola indicated that resistance to anthracnose in sorghum accession G 73 segregated as a recessive trait in a cross with susceptible cultivar HC 136. To facilitate the use of marker-assisted selection in sorghum breeding programs, a PCR-based specific sequence characterized amplified region (SCAR) marker was developed. A total of 29 resistant and 20 susceptible recombinant inbred lines (RILs) derived from a HC 136 × G 73 cross was used for bulked segregant analysis to identify a RAPD marker closely linked to a gene for resistance to anthracnose. The polymorphism between the parents HC 136 and G 73 was evaluated using 84 random sequence decamer primers. Among these, only 24 primers generated polymorphism. On bulked segregant analysis, primer OPA 12 amplified a unique band of 383 bp only in the resistant parent G 73 and resistant bulk. Segregation analysis of individual RILs showed the marker OPA 12₃₈₃ was 6.03 cM from the locus governing resistance to anthracnose. The marker OPA 12₃₈₃ was cloned and sequenced. Based on the sequence of cloned RAPD product, a pair of SCAR markers SCA 12-1 and SCA 12-2 was designed using the MacVector program, which specifically amplified this RAPD fragment in resistant parent G 73, resistant bulk and respective RILs. Therefore, it was confirmed that SCAR marker SCA 12 is at the same locus as RAPD marker OPA 12₃₈₃ and hence, is linked to the gene for resistance to anthracnose.     

DNA markers identify hybrids between butternut (Juglans cinerea L.) and Japanese walnut (Juglans ailantifolia Carr.)

Butternut (Juglans cinerea L.) is a temperate deciduous hardwood native to the eastern USA and southern Canada valued for its nuts and wood. Butternut’s survival is threatened by butternut canker, a disease caused by the exotic fungus Sirococcus clavigignenti-juglandacearum Nair, Kostichka & Kuntz. Field observations indicate that trees commonly called buartnut (a hybrid of butternut and its close congener Japanese walnut (Juglans ailantifolia × J. cinerea)) may be more resistant to butternut canker than is either parental species. Hybrids are difficult to distinguish morphologically from butternuts, and scientists have expressed concern over the possibility of range-wide genetic invasion by Japanese walnut via hybridization with butternut. We used pair-wise combinations of 40 random primers to screen bulked DNA pools of butternut, Japanese walnut, and buartnuts to identify genomic regions unique to Japanese walnut. We ultimately identified one ITS region marker, one chloroplast marker, one mitochondrial marker, and six nuclear markers. The utility of the markers for identifying hybrids was tested and verified using more than 190 genotypes. The markers will be used to identify buartnut hybrids based on the presence of introgressed genomic fragments inherited from Japanese walnut. We confirmed that hybrids have a complex genetic history and present features of the parental species in all possible combinations. These results will assist in the identification and testing of (non-hybrid) butternut for breeding and reintroduction of the species to its former habitats.