Non‐GMO potato lines,synthesizing increased amylose and resistant starch,are mainly deficient in isoamylase debranching enzyme

Solanum tuberosum potato lines with high amylose content were generated by crossing with the wild potato species Solanum sandemanii followed by repeated backcrossing to Solanum tuberosum lines. The trait, termed increased amylose (IAm), was recessive and present after three generations of backcrossing into S. tuberosum lines (6.25% S. sandemanii genes). The tubers of these lines were small, elongated and irregular with small and misshaped starch granules and high sugar content. Additional backcrossing resulted in less irregular tuber morphology, increased starch content (4.3%–9.5%) and increased amylose content (29%–37.9%) but indifferent sugar content. The amylose in the IAm starch granules was mainly located in peripheral spots, and large cavities were found in the granules. Starch pasting was suppressed, and the digestion‐resistant starch (RS) content was increased. Comprehensive microarray polymer profiling (CoMPP) analysis revealed specific alterations of major pectic and glycoprotein cell wall components. This complex phenotype led us to search for candidate IAm genes exploiting its recessive trait. Hence, we sequenced genomic DNA of a pool of IAm lines, identified SNPs genome wide against the draft genome sequence of potato and searched for regions of decreased heterozygosity. Three regions, located on chromosomes 3, 7 and 10, respectively, displayed markedly less heterozygosity than average. The only credible starch metabolism‐related gene found in these regions encoded the isoamylase‐type debranching enzyme Stisa1. Decreased expression of mRNA (>500 fold) and reduced enzyme activity (virtually absent from IAm lines) supported Stisa1 as a candidate gene for IAm.     

Statistical epistasis between candidate gene alleles for complex tuber traits in an association mapping population of tetraploid potato

Association mapping using DNA-based markers is a novel tool in plant genetics for the analysis of complex traits. Potato tuber yield, starch content, starch yield and chip color are complex traits of agronomic relevance, for which carbohydrate metabolism plays an important role. At the functional level, the genes and biochemical pathways involved in carbohydrate metabolism are among the best studied in plants. Quantitative traits such as tuber starch and sugar content are therefore models for association genetics in potato based on candidate genes. In an association mapping experiment conducted with a population of 243 tetraploid potato varieties and breeding clones, we previously identified associations between individual candidate gene alleles and tuber starch content, starch yield and chip quality. In the present paper, we tested 190 DNA markers at 36 loci scored in the same association mapping population for pairwise statistical epistatic interactions. Fifty marker pairs were associated mainly with tuber starch content and/or starch yield, at a cut-off value of q ≤ 0.20 for the experiment-wide false discovery rate (FDR). Thirteen marker pairs had an FDR of q ≤ 0.10. Alleles at loci encoding ribulose-bisphosphate carboxylase/oxygenase activase (Rca), sucrose phosphate synthase (Sps) and vacuolar invertase (Pain1) were most frequently involved in statistical epistatic interactions. The largest effect on tuber starch content and starch yield was observed for the paired alleles Pain1-8c and Rca-1a, explaining 9 and 10% of the total variance, respectively. The combination of these two alleles increased the means of tuber starch content and starch yield. Biological models to explain the observed statistical epistatic interactions are discussed.     

The potato amylase inhibitor gene SbAI regulates cold‐induced sweetening in potato tubers by modulating amylase activity

Potato cold‐induced sweetening (CIS) is critical for the postharvest quality of potato tubers. Starch degradation is considered to be one of the key pathways in the CIS process. However, the functions of the genes that encode enzymes related to starch degradation in CIS and the activity regulation of these enzymes have received less attention. A potato amylase inhibitor gene known as SbAI was cloned from the wild potato species Solanum berthaultii. This genetic transformation confirmed that in contrast to the SbAI suppression in CIS‐resistant potatoes, overexpressing SbAI in CIS‐sensitive potatoes resulted in less amylase activity and a lower rate of starch degradation accompanied by a lower reducing sugar (RS) content in cold‐stored tubers. This finding suggested that the SbAI gene may play crucial roles in potato CIS by modulating the amylase activity. Further investigations indicated that pairwise protein–protein interactions occurred between SbAI and α‐amylase StAmy23, β‐amylases StBAM1 and StBAM9. SbAI could inhibit the activities of both α‐amylase and β‐amylase in potato tubers primarily by repressing StAmy23 and StBAM1, respectively. These findings provide the first evidence that SbAI is a key regulator of the amylases that confer starch degradation and RS accumulation in cold‐stored potato tubers.     

A genome-wide association study revealed five SNPs affecting 8-month weight in sheep

Lamb weight at 8 months of age is an important trait in the sheep industry in terms of the onset of puberty around this age; however, knowledge of its effective genetic factors is limited. Therefore, a GWAS using the 50K SNP-Chip was performed on 96 Baluchi sheep to identify the genomic regions associated with 8-month weight. The results of the present study revealed five SNPs on chromosomes 4, 14 and 16 at 5% chromosome-wide significance level, jointly accounting for 0.95% of total genetic variance. Four genes – MTPN, HYDIN, LRGUK and ZFP90 – were found in 50 kb intervals around the significant SNPs, of which MTPN is involved in regulation of skeletal muscle growth. Our results may provide a new vision to identify the genomic regions affecting growth traits in sheep.     

Identification and characterization of intraspecific variability of the sucrose synthase gene <Emphasis Type="Italic">Sus4</Emphasis> of potato (<Emphasis Type="Italic">Solanum tuberosum</Emphasis>)

Nucleotide and amino acid variability of fragments of the Sus4 gene encoding the sucrose synthase enzyme was studied in 24 potato cultivars bred in Russia and other countries and differing in starch content in tubers. Both SNPs and indels were detected in a chosen Sus4 gene fragment including the sequence from exon 3 to exon 6 and corresponding to the main part of the sucrose synthase domain. Four types of Sus4 sequences were revealed depending on the presence of an insertion in introns 4 and 5 and of the mononucleotide octamer (T)₈ in intron 5. Differentiation of these sequences was confirmed by statistical methods. Sixteen amino acid substitutions were identified in the translated sequence, of which eleven were nonsynonymous. Specific cultivar-specific nucleotide and amino acid substitutions were also revealed, which can be used in future for identifying potato cultivars/genotypes. No direct associations between the mutational changes and the starch content were found in the potato cultivars studied.     

Mechanism of Chilling Injury in Sweet Potatoes

1. 1. Both amounts of lipid phosphorus and acid-insoluble nitrogen in the mitochondrial fraction from chilling-injured sweet potatoes (var. Okinawa 100) were larger than in the fraction from healthy sweet potatoes. The N-amount appeared to be increased more by chilling-injury than the P-amount.

2. 2. Sweet potato, a tropical plant, showed lower value of the degree of unsaturation of fatty acids in mitochondrial fraction than white potato, a temperate-zone plant.

3. 3. The amount of unsaturated fatty acids of C₁₆, C₁₈ and C₂₀ as percentage of the total fatty acids was higher in mitochondrial fractions from chilling-injured sweet potatoes (var. Okinawa 100 and var. Norin 1) than in mitochondrial fractions from healthy sweet potatoes. However, in the case of white potato mitochondrial fraction no detectable difference was observed between storage at 0~1°C and at 10~14°C.

     

Genomic footprints of speciation in Atlantic eels (Anguilla anguilla and A. rostrata)

The importance of speciation‐with‐geneflow scenarios is increasingly appreciated. However, the specific processes and the resulting genomic footprints of selection are subject to much discussion. We studied the genomics of speciation between the two panmictic, sympatrically spawning sister species; European (Anguilla anguilla) and American eel (A. rostrata). Divergence is assumed to have initiated more than 3 Ma, and although low gene flow still occurs, strong postzygotic barriers are present. Restriction‐site‐associated DNA (RAD) sequencing identified 328 300 SNPs for subsequent analysis. However, despite the presence of 3757 strongly differentiated SNPs (F_ST > 0.8), sliding window analyses of F_ST showed no larger genomic regions (i.e. hundreds of thousands to millions of bases) of elevated differentiation. Overall F_ST was 0.041, and linkage disequilibrium was virtually absent for SNPs separated by more than 1000 bp. We suggest this to reflect a case of genomic hitchhiking, where multiple regions are under directional selection between the species. However, low but biologically significant gene flow and high effective population sizes leading to very low genetic drift preclude accumulation of strong background differentiation. Genes containing candidate SNPs for positive selection showed significant enrichment for gene ontology (GO) terms relating to developmental processes and phosphorylation, which seems consistent with assumptions that differences in larval phase duration and migratory distances underlie speciation. Most SNPs under putative selection were found outside coding regions, lending support to emerging views that noncoding regions may be more functionally important than previously assumed. In total, the results demonstrate the necessity of interpreting genomic footprints of selection in the context of demographic parameters and life‐history features of the studied species.     

A review of cellular structure,starch, and texture qualities of processed potatoes

Certain combined characteristics of cellular structure and starch properties provide distinctions between varieties of potatoes and bear strong relation to their culinary qualities. Larger tissue cells and larger average starch granules are associated with mealiness. Smaller cells and starch granules characterize the less mealy and “waxy” varieties. Similarly, the same general relationships hold for the varietal characteristics of high vs. low solids and high vs. low starch contents. Within a variety, proportionately larger numbers of large starch granules are associated with tubers of high specific gravity, and more smaller granules, with low specific gravity. There also is a distinct reduction in percent of small granules during storage of tubers. Differences in starch granule size are accompanied by differences in amylose and amylopectin. Small granules contain less amylose and gel at higher temperatures than do the larger starch granules. Amylose content likewise appears to be a varietal characteristic. These variations in amylose content reflect fundamental differences in the properties of the starch gels formed when different varieties of potatoes are cooked. Likewise, there are similar distinctions between the starches within different tissue zones of individual tubers. Cell size also varies characteristically within different tuber regions. Starch gel properties may be manipulated during processing by such treatments as precooking-heating, chilling, freezing, and thawing. These treatments provide some measure of control of textural quality in the finished product. Additives such as stearates or glycerides complex readily with amylose and also influence gel properties and texture in processed potato products. Sucrose accumulated during tuber storage also may increase gel strength and influence texture. Varietal differences in cell structure and in starch granule size and composition offer opportunities for genetic exploitation. The merits of special processing for texture control vs. development of varieties for specific processed product qualities are briefly discussed.     

Nucleotide diversity in starch synthase IIa and validation of single nucleotide polymorphisms in relation to starch gelatinization temperature and other physicochemical properties in rice (Oryza sativa L.)

The characteristics of starch, such as gelatinization temperature (GT), apparent amylose content (AAC), pasting temperature (PT) and other physicochemical properties, determine the quality of various products of rice, e.g., eating, cooking and processing qualities. The GT of rice flour is controlled by the alk locus, which has been co-mapped to the starch synthase IIa (SSIIa) locus. In this study, we sequenced a 2,051 bp DNA fragment spanning part of intron 6, exon 7, intron 7, exon 8 and part of 3′ untranslated region of SSIIa for 30 rice varieties with diverse geographical distribution and variation in starch physicochemical properties. A total of 24 single nucleotide polymorphisms (SNPs) and one insertion/deletion (InDel) were identified, which could be classified into nine haplotypes. The mean pairwise nucleotide diversity π was 0.00292, and Watterson’s estimator θ was 0.00296 in this collection of rice germplasm. Tajima’s D test for selection showed no significant deviation from the neutral expectation (D = − 0.04612, P > 0.10). However, significant associations were found between seven of the SNPs and peak GT (T _p) at P < 0.05, of which two contiguous SNPs (GC/TT) showed a very strong association with T _p (P < 0.0001). With some rare exception, this GC/TT polymorphism alone can differentiate rice varieties with high or intermediate GT (possessing the GC allele) from those with low GT (possessing the TT allele). In contrast, none of these SNPs or InDel was significantly associated with amylose content. A further 509 rice varieties with known physicochemical properties (e.g., AAC and PT) and known alleles of other starch synthesizing genes were genotyped for the SSIIa GC/TT alleles. Association analysis indicated that 82% of the total variation of AAC in these samples could be explained by a (CT)n simple sequence repeat (SSR) and a G/T SNP of Waxy gene (Wx), and 62.4% of the total variation of PT could be explained by the GC/TT polymorphism. An additional association analysis was performed between these molecular markers and the thermal and retrogradation properties for a subset of 245 samples from the 509 rice varieties. The SSIIa GC/TT polymorphism explained more than 60% of the total variation in thermal properties, whereas the SSR and SNP of Wx gene explained as much as the SSIIa GC/TT of the total variation in retrogradation properties. Our study provides further support for the utilization of the GC/TT polymorphism in SSIIa. As shown in our study of 509 rice varieties, the GC/TT SNP could differentiate rice with high or intermediate GT from those with low GT in about 90% of cases. Using four primers in a single PCR reaction, the GC/TT polymorphism can be surveyed on a large scale. Thus, this SNP polymorphism can be very useful in marker-assisted selection for the improvement of GT and other physicochemical properties of rice.     

Genomic regions influencing intramuscular fat in divergently selected rabbit lines

Intramuscular fat (IMF) is one of the main meat quality traits for breeding programmes in livestock species. The main objective of this study was to identify genomic regions associated with IMF content comparing two rabbit populations divergently selected for this trait, and to generate a list of putative candidate genes. Animals were genotyped using the Affymetrix Axiom OrcunSNP Array (200k). After quality control, the data involved 477 animals and 93 540 SNPs. Two methods were used in this research: single marker regressions with the data adjusted by genomic relatedness, and a Bayesian multiple marker regression. Associated genomic regions were located on the rabbit chromosomes (OCU) OCU1, OCU8 and OCU13. The highest value for the percentage of the genomic variance explained by a genomic region was found in two consecutive genomic windows on OCU8 (7.34%). Genes in the associated regions of OCU1 and OCU8 presented biological functions related to the control of adipose cell function, lipid binding, transportation and localisation (APOLD1, PLBD1, PDE6H, GPRC5D and GPRC5A) and lipid metabolic processes (MTMR2). The EWSR1 gene, underlying the OCU13 region, is linked to the development of brown adipocytes. The findings suggest that there is a large component of polygenic effect behind the differences in IMF content in these two lines, as the variance explained by most of the windows was low. The genomic regions of OCU1, OCU8 and OCU13 revealed novel candidate genes. Further studies would be needed to validate the associations and explore their possible application in selection programmes.     

Genomic prediction of starch content and chipping quality in tetraploid potato using genotyping-by-sequencing

Key message

Genomic prediction models for starch content and chipping quality show promising results, suggesting that genomic selection is a feasible breeding strategy in tetraploid potato.

Abstract

Genomic selection uses genome-wide molecular markers to predict performance of individuals and allows selections in the absence of direct phenotyping. It is regarded as a useful tool to accelerate genetic gain in breeding programs, and is becoming increasingly viable for crops as genotyping costs continue to fall. In this study, we have generated genomic prediction models for starch content and chipping quality in tetraploid potato to facilitate varietal development. Chipping quality was evaluated as the colour of a potato chip after frying following cold induced sweetening. We used genotyping-by-sequencing to genotype 762 offspring, derived from a population generated from biparental crosses of 18 tetraploid parents. Additionally, 74 breeding clones were genotyped, representing a test panel for model validation. We generated genomic prediction models from 171,859 single-nucleotide polymorphisms to calculate genomic estimated breeding values. Cross-validated prediction correlations of 0.56 and 0.73 were obtained within the training population for starch content and chipping quality, respectively, while correlations were lower when predicting performance in the test panel, at 0.30–0.31 and 0.42–0.43, respectively. Predictions in the test panel were slightly improved when including representatives from the test panel in the training population but worsened when preceded by marker selection. Our results suggest that genomic prediction is feasible, however, the extremely high allelic diversity of tetraploid potato necessitates large training populations to efficiently capture the genetic diversity of elite potato germplasm and enable accurate prediction across the entire spectrum of elite potatoes. Nonetheless, our results demonstrate that GS is a promising breeding strategy for tetraploid potato.

     

Increased fatty acid production in potato by engineering of acetyl-CoA carboxylase

In contrast to oil seeds, potato (Solanum tuberosum L.) is characterized by a high amount of starch stored in the tubers. To assess the capacity for oil synthesis in potato tubers, the changes in lipid content and flux into lipid synthesis were explored in transgenic potatoes altered in carbohydrate or lipid metabolism. A strong decrease in the amount of starch observed in antisense lines for ADP-glucose pyrophosphorylase or plastidic phosphoglucomutase had no effect on storage-lipid content. Similarly, potato lines over-expressing the Arabidopsis thaliana (L.) Heynh. plastidic ATP/ADP transporter that contained an increased amount of starch were not altered in oil content, indicating that the plastidic ATP level is not limiting fatty acid synthesis in potato tubers. However, over-expression of the acetyl-CoA carboxylase from Arabidopsis in the amyloplasts of potato tubers led to an increase in fatty acid synthesis and a more than 5-fold increase in the amount of triacylglycerol. Taken together, these data demonstrate that potato tubers have the capacity for storage-lipid synthesis and that malonyl-CoA, the substrate for elongation during fatty acid synthesis, represents one of the limiting factors for oil accumulation.Abbreviations AATP Plastidic ADP/ATP transporter - ACCase Acetyl-CoA:carboxylase - DGAT Acyl-CoA:diacylglycerol acyltransferase - FW Fresh weight - TLC Thin-layer chromatography - WT Wild typeSource for transgenic plant material. Upon request, transgenic potato lines altered in ACCase activity can be obtained from Peter Dörmann. For potato lines with alterations in AATP transporter activity, please refer to H. Ekkehard Neuhaus. Transgenic AGP and PGM lines are available from A. Fernie (Max-Planck-Institute of Molecular Plant Physiology, Golm, Germany).     

Single nucleotide polymorphism (SNP) genotyping as basis for developing a PCR-based marker highly diagnostic for potato varieties with high resistance to Globodera pallida pathotype Pa2/3

Globodera pallida is a parasitic root cyst nematode of potato, which causes reduction of crop yield and quality in infested fields. Field populations of G. pallida containing mixtures of pathotypes Pa2 and Pa3 (Pa2/3) are currently most relevant for potato cultivation in middle Europe. Genes for resistance to G. pallida have been introgressed into the cultivated potato gene pool from the wild, tuber bearing Solanum species S. spegazzinii and S. vernei. Selection of resistant genotypes in breeding programs is hampered by the fact that the phenotypic evaluation of resistance to G. pallida is time consuming, costly and often ambiguous. DNA-based markers diagnostic for resistance to G. pallida would facilitate the development of resistant varieties. A tetraploid F₁ hybrid family SR-Gpa segregating for quantitative resistance to G.␣pallida was developed and evaluated for resistance to G. pallida population ‘Chavornay’. Two subpopulations of 30 highly resistant and 30 susceptible individuals were selected and genotyped for 96 single nucleotide polymorphism (SNP) markers tagging 12 genomic regions on 10 potato chromosomes. Seven SNPs were found significantly linked to the nematode resistance, which were all located within a resistance ‘hotspot’ on potato chromosome V. A haplotype model for these seven SNPs was deduced from the SNP patterns observed in the SR-Gpa family. A PCR assay ‘HC’ was developed, which specifically detected the SNP haplotype c that was linked with high levels of nematode resistance. The HC marker was only found in accessions of S.␣vernei. Screening with the HC marker 34 potato varieties resistant to G. pallida pathotypes Pa2 and/or Pa3 and 22 susceptible varieties demonstrated that the HC marker was highly diagnostic for presence of high levels of resistance to G. pallida pathotype Pa2/Pa3.Amirali Sattarzadeh and Ute Achenbach contributed equally to the work     

Optimization of Glycoalkaloid Analysis for Use in Industrial Potato Fruit Juice Downstreaming

Annually, within the European Union about 1.7 million tons of starch is produced by processing over 8 million tons of potato tubers, Solanum tuberosum. In recent years, the potato protein content has gained tremendous industrial interest, since these proteins have excellent nutritional value. As naturally occurring, secondary plant metabolites steroidal potato glycoalkaloids are formed in potatoes. The two major glycoalkaloids in potatoes are α‐solanine and α‐chaconine. Because of the significant toxicity of the glycoalkaloids for human and for animal nutrition it was essential to develop efficient extraction processes. The need for an easy, fast, sensitive and reliable glycoalkaloid assay at the very beginning of the production chain is obvious. In this study an efficient analytical assay for potato glycoalkaloids from powdery protein samples under industrially relevant conditions is described: sample extraction, analyte pre‐purification, and final HPLC analysis. An acetic acid extraction/homogenization process was used for glycoalkaloid extraction from potato protein samples. The extracts were purified by means of solid phase extraction cartridges using the different washing steps developed in this study. The final determination was performed through an HPLC method using a Reprosil‐Pur NH₂ column. The limit of detection was 5 μg/mL for α‐solanine and α‐chaconine, respectively, corresponding to concentrations of 20 ppm in potato protein powder.     

Occurrence of Cystic Fibrosis Transmembrane Conductance Regulator Gene Mutations in Patients with Allergic Bronchopulmonary Aspergillosis Complicating Asthma

Background

Whether cystic fibrosis transmembrane conductance regulator (CFTR) gene mutations contribute to the high prevalence of allergic bronchopulmonary aspergillosis (ABPA) in India remains unknown. We aimed to evaluate the occurrence of CFTR mutations in subjects with ABPA complicating asthma.

Methods

We sequenced the CFTR gene using genomic DNA from blood on the Illumina NextSeq500 platform. Before undertaking zygosity analysis by genome analysis toolkit, the known or novel single nucleotide polymorphisms (SNPs) and indels were called. For rigorous analysis, we included only high-quality SNPs (scores?>?500) and coverage ranging from 30 × 150x.

Results

We included 18, 12, and eight adult participants of ABPA, asthma, and healthy controls, respectively. The frequency of SNPs was higher in asthmatic subjects than ABPA or healthy controls, albeit not statistically significant (9/12 [75%] vs. 11/18 [61.1%] vs. 3/8 [37.5%], p?=?0.24). Of the 38 subjects, 23 yielded 50 variants (healthy controls [n?=?5], ABPA [n?=?22], asthma [n?=?23]) corresponding to six SNPs not previously linked with ABPA. Of these, four SNPs (rs213950, rs200735475, rs1800113, and rs1800136) were catalogued in the NCBI database. We identified two novel SNPs (chr7:117250703, chr7:117282655) in four (ABPA [n?=?1], asthma [n?=?3]) subjects without corresponding reference SNP. Most SNPs (85.5%) were heterozygous. The frequency of SNPs was higher in ABPA subjects with high-attenuation mucus (52.2%) and bronchiectasis (39.1%) than serological ABPA (8.7%).

Conclusions

Our study suggests the role of CFTR mutations in the pathogenesis of ABPA. The SNPs in the CFTR gene may contribute to disease severity in ABPA. Larger studies are required to confirm our findings.

     

不同生境马铃薯根际土壤细菌多样性分析

近年来,随着国家对马铃薯产业重视程度的增加,生产的专业化和规模化程度越来越高,化肥农药用量不断加大,加之连作等种植模式,致使以疮痂病为代表的土传病害普遍发生且逐年加重,个别地块发病率达90%以上,给种植业者带来巨大的经济损失。[目的] 为了探索马铃薯疮痂病发生与土壤环境的关系,分析区域性种植方式和施肥量对土壤细菌种群变化的影响,为实现土传病害有效防治提供借鉴。[方法] 本文分别从1年连作土传病害轻的宁夏西吉（西北）、3年连作土传病害严重的河北沽源（华北）、5年轮作未发现土传病害的内蒙古海拉尔（东北）大田马铃薯根际采集土壤,利用高通量测序技术,比较了样品间细菌群落结构差异。[结果] 3组样品共获得有效条带617558条,可分类操作单元（OTUs）3077个。各样品中变形菌门（Proteobacteria）数量最多,含量均在33%以上。与未发病土壤样品相比,土传病害发生严重的样品中细菌数量、物种数、细菌多样性、种类丰富度均有所降低,有害菌数量增加,益生菌数量减少。其中,放线菌（Actinobacteria）数量明显增多,变形菌（Proteobacteria）、绿弯菌（Chloroflexi）和酸杆菌（Acidobacteria）数量明显减少,组分及数量差异明显的细菌（尤其是放线菌门）大多与土壤全磷含量呈显著相关。[结论] 过量施用化肥和常年连作改变了土壤细菌群落结构,生态环境恶化,导致土传性病害发生。其中,磷可能是影响土壤微生物群落结构变化最主要的肥料元素。     

甘薯品种营养成份与抗小象虫的相关性研究

通过田间和网室测定结果,抗小象虫较好的甘薯品种有抗虫1号、台农26、Tis2534、Ricin和鸡蛋黄;抗小象虫较弱的品种有新种花、惠红早、“329”、广薯15等。甘薯品种的营养成份与抗小象虫相关性分析结果表明,抗、感品种与粗纤维、粗脂肪含量无明显相关,与粗淀粉有显负相关,R1=-0．9935,而与粗蛋白和18种氨基酸总量有显正相关,R2=0．9741,R3=0．9621。表现粗淀粉含量高的品种,其虫害指敦较低,抗虫性强;而粗蛋白含量和18种氨基酸总量高的品种,其虫害指数较高,抗虫性则表现较弱。测定分析说明了甘薯品种营养成份与抗虫性存在一定的相关性。     

Genome-wide association study (GWAS) of salt tolerance in worldwide soybean germplasm lines

Salt is a severe abiotic stress causing soybean yield loss in saline soils and irrigated fields. Marker-assisted selection (MAS) is a powerful genomic tool for improving the efficiency of breeding salt-tolerant soybean varieties. The objectives of this study were to uncover novel single-nucleotide polymorphisms (SNPs) and quantitative trait loci (QTLs) associated with salt tolerance and to confirm the previously identified genomic regions and SNPs for salt tolerance. A total of 283 diverse soybean plant introductions (PIs) were screened for salt tolerance in the greenhouse based on leaf chloride concentrations and leaf chlorophyll concentrations after 12–18 days of 120-mM NaCl treatment. A total of 33,009 SNPs across 283 genotypes from the Illumina Infinium SoySNP50K BeadChip database were employed in the association analysis with leaf chloride concentrations and leaf chlorophyll concentrations. Genome-wide association mapping showed that 45 SNPs representing nine genomic regions on chromosomes (Chr.) 2, 3, 7, 8, 10, 13, 14, 16, and 20 were significantly associated with both leaf chloride concentrations and leaf chlorophyll concentrations in 2014, 2015, and combined years. A total of 31 SNPs on Chr. 3 were mapped at or near the previously reported major salt tolerance QTL. The significant SNP on Chr. 2 was also in proximity to the previously reported SNP for salt tolerance. The other significant SNPs represent seven putative novel QTLs for salt tolerance. The significant SNP markers on Chr. 2, 3, 14, 16, and 20, which were identified in both general linear model and mixed linear model, were highly recommended for MAS in breeding salt-tolerant soybean varieties.     

Correlation of vector Aphids activity,physiological characteristics and environmental condition with the severity of PVY and PLRV viruses on potato cultivars

Abstract

Aphids have serious damage and well known of the most important pests, which may transmit different viruses on potato. Potato has immense significance as a food crop throughout the world. In the last research, the most important and different aspects of predominant potato varieties; Agria, Arinda, Fontane, Banba and Sante were studied during 2015–2016 in Karaj, Iran. This research has been conducted into several disparate categories: the effect of environmental conditions on the physiological trends, aphid characteristics and virus infection. The results showed that potato fields had an increasing trend to the end of season in the aspect of infestation by Aphis gossypii Glover and Myzus persicae Sulzer. The potato cultivars showed the same reaction in the lab and no host preference was observed between them against cotton aphid (A. gossypii). Finally, Arinda, and Agria varieties had the most photosynthesis activity, chlorophyll concentration, and leaf dry weight values and had the least electrical conductivity and susceptibility to some potato virus diseases. These results may help to provide better potato varieties by considering to the important physiological characteristic related to some destructive pests.     

Development and evaluation of single-nucleotide polymorphism markers in allotetraploid rapeseed (<Emphasis Type="Italic">Brassica napus</Emphasis> L.)

Single-nucleotide polymorphisms (SNPs) and insertion–deletions (INDELs) are currently the important classes of genetic markers for major crop species. In this study, methods for developing SNP markers in rapeseed (Brassica napus L.) and their in silico mapping and use for genotyping are demonstrated. For the development of SNP and INDEL markers, 181 fragments from 121 different gene sequences spanning 86 kb were examined. A combination of different selection methods (genome-specific amplification, hetero-duplex analysis and sequence analysis) allowed the detection of 18 singular fragments that showed a total of 87 SNPs and 6 INDELs between 6 different rapeseed varieties. The average frequency of sequence polymorphism was estimated to be one SNP every 247 bp and one INDEL every 3,583 bp. Most SNPs and INDELs were found in non-coding regions. Polymorphism information content values for SNP markers ranged between 0.02 and 0.50 in a set of 86 varieties. Using comparative genetics data for B. napus and Arabidopsis thaliana, an allocation of SNP markers to linkage groups in rapeseed was achieved: a unique location was determined for seven gene sequences; two and three possible locations were found for six and four sequences, respectively. The results demonstrate the usefulness of existing genomic resources for SNP discovery in rapeseed.