A draft genome of sweet cherry (Prunus avium L.) reveals genome‐wide and local effects of domestication

Sweet cherry (Prunus avium L.) trees are both economically important fruit crops but also important components of natural forest ecosystems in Europe, Asia and Africa. Wild and domesticated trees currently coexist in the same geographic areas with important questions arising on their historical relationships. Little is known about the effects of the domestication process on the evolution of the sweet cherry genome. We assembled and annotated the genome of the cultivated variety “Big Star*” and assessed the genetic diversity among 97 sweet cherry accessions representing three different stages in the domestication and breeding process (wild trees, landraces and modern varieties). The genetic diversity analysis revealed significant genome‐wide losses of variation among the three stages and supports a clear distinction between wild and domesticated trees, with only limited gene flow being detected between wild trees and domesticated landraces. We identified 11 domestication sweeps and five breeding sweeps covering, respectively, 11.0 and 2.4 Mb of the P. avium genome. A considerable fraction of the domestication sweeps overlaps with those detected in the related species, Prunus persica (peach), indicating that artificial selection during domestication may have acted independently on the same regions and genes in the two species. We detected 104 candidate genes in sweep regions involved in different processes, such as the determination of fruit texture, the regulation of flowering and fruit ripening and the resistance to pathogens. The signatures of selection identified will enable future evolutionary studies and provide a valuable resource for genetic improvement and conservation programs in sweet cherry.     

Genetic diversity and peculiarity of annual wild soybean (<Emphasis Type="Italic">G. soja</Emphasis> Sieb. et Zucc.) from various eco-regions in China

Annual wild soybean (Glycine soja Sieb. et Zucc.) is believed to be a potential gene source for future soybean improvement in coping with the world climate change for food security. To evaluate the wild soybean genetic diversity and differentiation, we analyzed allelic profiles at 60 simple-sequence repeat (SSR) loci and variation of eight morph-biological traits of a representative sample with 196 accessions from the natural growing area in China. For comparison, a representative sample with 200 landraces of Chinese cultivated soybean was included in this study. The SSR loci produced 1,067 alleles (17.8 per locus) with a mean gene diversity of 0.857 in the wild sample, which indicated the genetic diversity of G. soja was much higher than that of its cultivated counterpart (total 826 alleles, 13.7 per locus, mean gene diversity 0.727). After domestication, the genetic diversity of the cultigens decreased, with its 65.5% alleles inherited from the wild soybean, while 34.5% alleles newly emerged. AMOVA analysis showed that significant variance did exist among Northeast China, Huang-Huai-Hai Valleys and Southern China subpopulations. UPGMA cluster analysis indicated very significant association between the geographic grouping and genetic clustering, which demonstrated the geographic differentiation of the wild population had its relevant genetic bases. In comparison with the other two subpopulations, the Southern China subpopulation showed the highest allelic richness, diversity index and largest number of specific-present alleles, which suggests Southern China should be the major center of diversity for annual wild soybean. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Single nucleotide mutation leading to an amino acid substitution in the variant <Emphasis Type="Italic">Tik</Emphasis> soybean Kunitz trypsin inhibitor (SKTI) identified in Chinese wild soybean (<Emphasis Type="Italic">Glycine soja</Emphasis> Sieb. &; Zucc.)

The wild soybean (Glycine soja), which is the progenitor of cultivated soybean (Glycine max), is expected to offer more information about genetic variability and more useful mutants for evolutionary research and breeding applications. Here, a total of 1,600 wild soybean samples from China were investigated for genetic variation with regard to the soybean Kunitz trypsin inhibitor (SKTI). A new mutant SKTI, Tik, was identified. It was found to be a Tia-derived codominant allele caused by a transversion point mutation from C to G at nucleotide +171, leading to an alteration of one codon (AAC → AAG) and a corresponding amino acid substitution (Asn → Lys) at the ninth residue. Upon examination of this variant and others previously found in wild soybeans, it became clear that SKTI has undergone high-level evolutionary differentiation. There were more abundant polymorphisms in the wild than in the cultivated soybean.     

Understandings and future challenges in soybean functional genomics and molecular breeding

Soybean(Glycine max) is a major source of plant protein and oil.Soybean breeding has benefited from advances in functional genomics.In particular,the release of soybean reference genomes has advanced our understanding of soybean adaptation to soil nutrient deficiencies,the molecular mechanism of symbiotic nitrogen(N) fixation,biotic and abiotic stress tolerance,and the roles of flowering time in regional adaptation,plant architecture,and seed yield and quality.Nevertheless,many challenges remain...     

Cloning and sequence diversity analysis of <Emphasis Type="Italic">GmHs1</Emphasis><Superscript><Emphasis Type="Italic">pro-1</Emphasis></Superscript> in Chinese domesticated and wild soybeans

Soybean cyst nematode (SCN) (Heterodera glycines Ichinohe) is the most important pathogen in soybean production worldwide and causes substantial yield losses. An apparent narrow genetic base of SCN resistance was observed in current elite soybean cultivars, and searching for novel SCN resistance genes as well as novel resistance sources rather than focusing on the two important genes rhg1 and Rhg4 has become another major objective in soybean research. In the present paper we report a 1,477 bp Hs1 ^pro-1 homolog, named GmHs1 ^pro-1 . This gene was cloned from soybean variety Wenfeng 7 based on information for Hs1 ^pro-1 , a beet cyst nematode resistance gene in sugar beet. It has two domains, Hs1pro-1_N and Hs1pro-1_C, both of which are believed to confer resistance to nematodes. Of the 1,477 bp sequence in GmHs1 ^pro-1 , an open reading frame of 1,314 bp, encoding a protein with 437 amino acids, was flanked by a 5′-untranslated region of 27 bp and a 3′-untranslated region of 135 bp. Fourteen single-nucleotide polymorphisms (SNPs) were observed in 44 soybean accessions including 23 wild soybeans, 8 landraces, and 13 soybean varieties (or lines), among which 5 in wild soybeans and 3 in landrace accessions were unique. Sequence diversity analysis on the 44 soybean accessions showed π = 0.00168 and θ = 0.00218 for GmHs1 ^pro-1 ; landraces had the highest diversity, followed by wild soybeans, with varieties (or lines) having the lowest. Although we did not detect a significant effect of selection on GmHs1 ^pro-1 in the three populations, sequence diversity, unique SNPs, and phylogenetic analysis indicated a slight domestication bottleneck and an intensive selection bottleneck. High sequence diversity, more unique SNPs, and broader representation across the phylogenetic tree in wild soybeans and landraces indicated that wild collections and landrace accessions are invaluable germplasm for broadening the genetic base of elite soybean varieties resistant to SCN. C. Yuan and G. Zhou contributed to this paper equally.     

SNP genotyping reveals genetic diversity between cultivated landraces and contemporary varieties of tomato

Background

The tomato (Solanum lycopersium L.) is the most widely grown vegetable in the world. It was domesticated in Latin America and Italy and Spain are considered secondary centers of diversification. This food crop has experienced severe genetic bottlenecks and modern breeding activities have been characterized by trait introgression from wild species and divergence in different market classes.

Results

With the aim to examine patterns of polymorphism, characterize population structure and identify putative loci under positive selection, we genotyped 214 tomato accessions (which include cultivated landraces, commercial varieties and wild relatives) using a custom-made Illumina SNP-panel. Most of the 175 successfully scored SNP loci were found to be polymorphic. Population structure analysis and estimates of genetic differentiation indicated that landraces constitute distinct sub-populations. Furthermore, contemporary varieties could be separated in groups (processing, fresh and cherry) that are consistent with the recent breeding aimed at market-class specialization. In addition, at the 95% confidence level, we identified 30, 34 and 37 loci under positive selection between landraces and each of the groups of commercial variety (cherry, processing and fresh market, respectively). Their number and genomic locations imply the presence of some extended regions with high genetic variation between landraces and contemporary varieties.

Conclusions

Our work provides knowledge concerning the level and distribution of genetic variation within cultivated tomato landraces and increases our understanding of the genetic subdivision of contemporary varieties. The data indicate that adaptation and selection have led to a genomic signature in cultivated landraces and that the subpopulation structure of contemporary varieties is shaped by directed breeding and largely of recent origin. The genomic characterization presented here is an essential step towards a future exploitation of the available tomato genetic resources in research and breeding programs.

Electronic supplementary material

The online version of this article (doi:10.1186/1471-2164-14-835) contains supplementary material, which is available to authorized users.     

Diversity distribution and population structure of tea germplasms in China revealed by EST-SSR markers

Tea plant (Camellia sinensis (L.) O. Kuntze) originated from China, where distributed abundant genetic resources. It is of critical importance to well understanding of genetic diversity and population structure for effective collection, conservation, and utilization of tea germplasms. In this study, 96 new polymorphic EST-SSR markers were developed and used to analyze 450 tea accessions collected from 14 tea-producing regions across China. A total of 409 alleles were observed, and the gene diversity (H) and polymorphic information content (PIC) were estimated to be averagely 0.64 and 0.61, respectively, across all the tested samples. The higher level of genetic diversity was observed in original regions like Guangxi, Yunnan, and Guizhou provinces. The allele number, H, and PIC showed decreasing trend when the region was more and more away from origin center of tea plant, which gave us implications on the spreading route of tea plant in China. The clustering of 450 samples both showed a clear separation according to their geographic origin based on either model simulation or genetic distance. The genetic differentiation was further analyzed among five inferred populations represented different eco-geographic regions. The lowest F _st and the closest relationship were revealed between proximal populations, which indicated that gene exchanges occurred frequently between nearby regions than distance ones. The majority of genetic variation resulted from differentiation within population (81.36%) rather than among inferred (13.6%) and regional (5.04%) populations based on analysis of molecular variance. Our study also revealed that the lower diversity and simpler population structure were found in improved cultivars than wild teas and landraces, which indicated that genetic base of developed cultivars became narrow because of long-standing domestication and artificial selection. So more attentions should be focused to conserve and utilize the beneficial genes in wild teas and landraces to broaden genetic variation of new cultivars in future breeding of the tea plant.     

Genome‐wide association and epistasis studies unravel the genetic architecture of sudden death syndrome resistance in soybean

Soybean [Glycine max (L.) Merr.] is an economically important crop that is grown worldwide. Sudden death syndrome (SDS), caused by Fusarium virguliforme, is one of the top yield‐limiting diseases in soybean. However, the genetic basis of SDS resistance, especially with respect to epistatic interactions, is still unclear. To better understand the genetic architecture of soybean SDS resistance, genome‐wide association and epistasis studies were performed using a population of 214 germplasm accessions and 31 914 SNPs from the SoySNP50K Illumina Infinium BeadChip. Twelve loci and 12 SNP–SNP interactions associated with SDS resistance were identified at various time points after inoculation. These additive and epistatic loci together explained 24–52% of the phenotypic variance. Disease‐resistant, pathogenesis‐related and chitin‐ and wound‐responsive genes were identified in the proximity of peak SNPs, including stress‐induced receptor‐like kinase gene 1 (SIK1), which is pinpointed by a trait‐associated SNP and encodes a leucine‐rich repeat‐containing protein. We report that the proportion of phenotypic variance explained by identified loci may be considerably improved by taking epistatic effects into account. This study shows the necessity of considering epistatic effects in soybean SDS resistance breeding using marker‐assisted and genomic selection approaches. Based on our findings, we propose a model for soybean root defense against the SDS pathogen. Our results facilitate identification of the molecular mechanism underlying SDS resistance in soybean, and provide a genetic basis for improvement of soybean SDS resistance through breeding strategies based on additive and epistatic effects.     

Environmental versus geographical effects on genomic variation in wild soybean (Glycine soja) across its native range in northeast Asia

A fundamental goal in evolutionary biology is to understand how various evolutionary factors interact to affect the population structure of diverse species, especially those of ecological and/or agricultural importance such as wild soybean (Glycine soja). G. soja, from which domesticated soybeans (Glycine max) were derived, is widely distributed throughout diverse habitats in East Asia (Russia, Japan, Korea, and China). Here, we utilize over 39,000 single nucleotide polymorphisms genotyped in 99 ecotypes of wild soybean sampled across their native geographic range in northeast Asia, to understand population structure and the relative contribution of environment versus geography to population differentiation in this species. A STRUCTURE analysis identified four genetic groups that largely corresponded to the geographic regions of central China, northern China, Korea, and Japan, with high levels of admixture between genetic groups. A canonical correlation and redundancy analysis showed that environmental factors contributed 23.6% to population differentiation, much more than that for geographic factors (6.6%). Precipitation variables largely explained divergence of the groups along longitudinal axes, whereas temperature variables contributed more to latitudinal divergence. This study provides a foundation for further understanding of the genetic basis of climatic adaptation in this ecologically and agriculturally important species.     

Genetic diversity of cultivated flax (Linum usitatissimum L.) germplasm assessed by retrotransposon-based markers

Retrotransposon segments were characterized and inter-retrotransposon amplified polymorphism (IRAP) markers developed for cultivated flax (Linum usitatissimum L.) and the Linum genus. Over 75 distinct long terminal repeat retrotransposon segments were cloned, the first set for Linum, and specific primers designed for them. IRAP was then used to evaluate genetic diversity among 708 accessions of cultivated flax comprising 143 landraces, 387 varieties, and 178 breeding lines. These included both traditional and modern, oil (86), fiber (351), and combined-use (271) accessions, originating from 36 countries, and 10 wild Linum species. The set of 10 most polymorphic primers yielded 141 reproducible informative data points per accession, with 52% polymorphism and a 0.34 Shannon diversity index. The maximal genetic diversity was detected among wild Linum species (100% IRAP polymorphism and 0.57 Jaccard similarity), while diversity within cultivated germplasm decreased from landraces (58%, 0.63) to breeding lines (48%, 0.85) and cultivars (50%, 0.81). Application of Bayesian methods for clustering resulted in the robust identification of 20 clusters of accessions, which were unstratified according to origin or user type. This indicates an overlap in genetic diversity despite disruptive selection for fiber versus oil types. Nevertheless, eight clusters contained high proportions (70?C100%) of commercial cultivars, whereas two clusters were rich (60%) in landraces. These findings provide a basis for better flax germplasm management, core collection establishment, and exploration of diversity in breeding, as well as for exploration of the role of retrotransposons in flax genome dynamics.     

Functional Role of miRNAs: Key Players in Soybean Improvement

Soybean (Glycine max (L.) Merr) is an agro-economic crop growing across the world to cater nutrition for both human and animal feed due to the high oil and protein content in its edible seeds. The genes and QTLs associated with important agronomic traits in this crop have already been identified and validated for soybean cyst nematode (SCN), Phytophthora root and stem rot, Pythium root rot and aphid resistance, seed quality, nutrient values, and also employed for genetic improvement in soybean. In the last decade, micro RNAs (miRNAs) have been considered the effector molecules, so the detection and characterization of novel miRNAs in soybean have been taken up by several workers. The advancement in the strategy of sequencing and tools of bioinformatics during last decade has contributed to the discovery of many soybean miRNAs, thus miRNA can be used as a tool in molecular breeding studies, and this has opened new vistas for miRNA mediated genetic improvement of soybean to augment crop productivity as well as nutritional quality. This review addresses the current state of understanding of miRNAmediated stress responses, nutrient acquisition, plant development and crop production processes in soybean.     

360度群体遗传变异扫描——大豆泛基因组研究

大豆(Glycine max)是重要的油料和蛋白作物, 其丰富的遗传变异为生物学性状挖掘和育种改良提供了重要的资源基础。然而, 单个基因组信息无法全面揭示种质资源的遗传变异, 泛基因组研究为解决这一不足提供了新方案。近日, 中国科学院遗传与发育生物学研究所田志喜和梁承志研究团队从2 898份大豆种质中选取26份代表性材料, 并整合已有的3个基因组, 构建了包含野生和栽培大豆的泛基因组和图基因组(graph-based genome), 鉴定了整个群体的绝大多数结构变异数据集, 确定了大豆种质的核心、非必需和个体特异的基因集。利用这些数据系统地揭示了生育期位点E3的等位基因变异和基因融合事件、种皮颜色基因I的单体型和演化关系以及结构变异对铁离子转运基因表达和地区适应性选择的影响。该研究为作物基因组学研究提供了一个新的模式, 同时将加速推动大豆遗传变异的鉴定、性状解析和种质创新。     

Differential responses of molecular mechanisms and physiochemical characters in wild and cultivated soybeans against invasion by the pathogenic Fusarium oxysporum Schltdl

Cultivated soybean (Glycine max) was derived from the wild soybean (Glycine soja), which has genetic resources that can be critically important for improving plant stress resistance. However, little information is available pertaining to the molecular and physiochemical comparison between the cultivated and wild soybeans in response to the pathogenic Fusarium oxysporum Schltdl. In this study, we first used comparative phenotypic and paraffin section analyses to indicate that wild soybean is indeed more resistant to F. oxysporum than cultivated soybean. Genome‐wide RNA‐sequencing approach was then used to elucidate the genetic mechanisms underlying the differential physiological and biochemical responses of the cultivated soybean, and its relative, to F. oxysporum. A greater number of genes related to cell wall synthesis and hormone metabolism were significantly altered in wild soybean than in cultivated soybean under F. oxysporum infection. Accordingly, a higher accumulation of lignins was observed in wild soybean than cultivated soybean under F. oxysporum infection. Collectively, these results indicated that secondary metabolites and plant hormones may play a vital role in differentiating the response between cultivated and wild soybeans against the pathogen. These important findings may provide future direction to breeding programs to improve resistance to F. oxysporum in the elite soybean cultivars by taking advantage of the genetic resources within wild soybean germplasm.     

Origin of tetraploid cultivated asparagus landraces inferred from nuclear ribosomal DNA internal transcribed spacers’ polymorphisms

The genus Asparagus includes a group of wild species that are closely related to the cultivated Asparagus officinalis (2n = 2× = 20). The narrow genetic background present in the asparagus cultivars shows the importance of asparagus landraces and the wild related species. The study of both genetic resources becomes necessary to facilitate their effective use in the breeding programmes. ‘Morado de Huetor’ (MH) and ‘Violetto d’Albenga’ (VA) are tetraploid asparagus landraces (2n = 4× = 40) cultivated in Spain and Italy, respectively, and whose origin remains unknown. To discover the origin of these landraces, a phylogenetic study was conducted based on restriction fragment length polymorphism (RFLP) of nuclear ribosomal DNA (nrDNA). The sequence of the two internal transcribed spacers (ITS) flanking the nrDNA5.8S gene (ITS1‐5.8S‐ITS2) were analysed for RFLP in 11 populations including both landraces (MH and VA), A. officinalis (wild and cultivated) and a group of closely related wild species (Asparagus maritimus, Asparagus prostratus, Asparagus pseudoscaber and Asparagus tenuifolius) with a European distribution. Restriction fragment patterns of both cultivated asparagus (2×) and two populations of A. maritimus (6×) from the Adriatic Sea area were present in the MH landrace. However, VA showed a similar pattern to A. officinalis. This study revealed that MH seems to be a hybrid between A. officinalis and A. maritimus that may have occurred in the Adriatic Sea region where hybridisations between cultivated diploid and wild species may have taken place. The origin of another tetraploid landrace (VA) might have had a similar origin but followed a different evolutionary path. Therefore, these landraces constitute a valuable genetic resource that could be used to enlarge the genetic background of modern cultivars. The ploidy levels of the populations employed in this study were analysed and levels not described previously were detected: A. maritimus (12×), A. tenuifolius (6×) and A. pseudoscaber (2×).     

Wide variability in kernel composition, seed characteristics, and zein profiles among diverse maize inbreds, landraces, and teosinte

All crop species have been domesticated from their wild relatives, and geneticists are just now beginning to understand the consequences of artificial (human) selection on agronomic traits that are relevant today. The primary consequence is a basal loss of diversity across the genome, and an additional reduction in diversity for genes underlying traits targeted by selection. An understanding of attributes of the wild relatives may provide insight into target traits and valuable allelic variants for modern agriculture. This is especially true for maize (Zea mays ssp. mays), where its wild ancestor, teosinte (Z. mays ssp. parviglumis), is so strikingly different than modern maize. One obvious target of selection is the size and composition of the kernel. We evaluated kernel characteristics, kernel composition, and zein profiles for a diverse set of modern inbred lines, teosinte accessions, and landraces, the intermediate between inbreds and teosinte. We found that teosinte has very small seeds, but twice the protein content of landraces and inbred lines. Teosinte has a higher average alpha zein content (nearly 89% of total zeins as compared to 72% for inbred lines and 76% for landraces), and there are many novel alcohol-soluble proteins in teosinte relative to the other two germplasm groups. Nearly every zein protein varied in abundance among the germplasm groups, especially the methionine-rich delta zein protein, and the gamma zeins. Teosinte and landraces harbor phenotypic variation that will facilitate genetic dissection of kernel traits and grain quality, ultimately leading to improvement via traditional plant breeding and/or genetic engineering.     

Broadening the Genetic Base of Soybean: A Multidisciplinary Approach

Soybean [Glycine max (L.) Merr.] is an economically important legume with 2n = 40 chromosomes, whose seeds contain an average of 40% protein and 20% oil, and its plants enrich the soil by fixing nitrogen in symbiosis with nitrogen-fixing bacteria. World soybean production has doubled in the past twenty years to over 220 million metric tons in 2006; the producing countries are U.S.A., Brazil, Argentina, China, and India. Soybean was domesticated in East Asia from its wild annual progenitor G. soja Sieb. & Zucc. (2n = 40). There are 26 wild perennial species, indigenous to Australia, of the subgenus Glycine but a common progenitor with 2n = 20 chromosomes has not been identified, and it may be extinct. It has been demonstrated that Glycine species are of either of allo-or auto-tetraploid origin. The cytogenetic knowledge of soybean lags far behind that of other model important crops (rice, maize, wheat, tomato), because it's somatic chromosomes are symmetrical, and only one pair of satellite chromosomes can be identified. Pachytene chromosome analysis created a chromosome map that has laid the foundation for producing primary trisomics. Several molecular linkage maps have been developed, but only 11 of the 20 molecular linkage groups (MLGs) have been associated with specific chromosomes. The genetic base of modern soybean cultivars is narrow and soybean breeders are confined to crossing within the primary gene pool (GP-1). Soybean does not have secondary gene pool (GP-2). Exploitation of the tertiary and quaternary gene pools (GP-3, GP-4) has been attempted but ended at the amphidiploid stage. A methodology for producing fertile lines derived from G. max and G. tomentella (2n = 78) cross has been developed, thereby making introgression of useful genes from GP-3. Genetic transformation has produced Roundup Ready® Soybeans, resistant to glyphosate herbicide.     

Genetic relationship among wild,landraces and cultivars of hazelnut (Corylus avellana) from Portugal revealed through ISSR and AFLP markers

The genus Corylus, a member of the birch family Betulaceae, includes several species that are widely distributed throughout temperate regions of the Northern Hemisphere. This study assesses the genetic diversity in 26 international cultivars and 32 accessions of Corylus avellana L. from Portugal: 13 wild genotypes and 19 landraces. The genetic relationships among the 58 hazelnuts (Corylus avellana L.) were analyzed using inter simple sequence repeat (ISSR) and amplified fragment length polymorphism (AFLP) markers. Eighteen ISSR primers and seven AFLP primer pairs generated a total of 570 unambiguous and repeatable bands, respectively, from which 541 (95.03 %) were polymorphic for both markers. Genetic similarity index values ranged from 0.239 for wild types and cultivars to 0.143 for landraces and wild types. The genetic relationships were presented as a Neighbor-Joining method dendrogram and a two-dimensional principal coordinate analysis (PCoA) plot. The Neighbor-Joining dendrogram showed three main clusters, and the PCoA analysis has shown to be congruent with the hierarchical analysis. Bayesian analysis clustered all individuals into three groups showing a good separation among wild genotypes, landraces and cultivars. The genetic diversity found on wild genotypes and Portuguese landraces may provide relevant information for the diversity conservation and it will be useful in breeding programs and to identify local selections for preservation.     

A platform for soybean molecular breeding: the utilization of core collections for food security

Soybean is an important crop not only for human consumption but also for its addition of nitrogen to the soil during crop rotation. China has the largest collection of cultivated soybeans (Glycine max) and wild soybeans (Glycine soja) all over the world. The platform of soybean core, mini core and integrated applied core collections has been developed in the past decade based on systematic researches which included the sampling strategies, statistical methods, phenotypic data and SSR markers. Meanwhile, intergrated applied core collections including accessions with single or integrated favorite traits are being developed in order to meet the demand of soybean breeding. These kinds of core collections provide powerful materials for evaluation of germplasm, identification of trait-specific accessions, gene discovery, allele mining, genomic study, maker development, and molecular breeding. Some successful cases have proved the usefulness and efficiency of this platform. The platform is helpful for enhancing utilization of soybean genetic resources in sustainable crop improvement for food security. The efficient utilization of this platform in the future is relying on accurate phenotyping methods, abundant functional markers, high-throughput genotyping platforms, and effective breeding programs.