Your search keyword '"An, Xinyou"' showing total 36 results

1. The genome sequence of segmental allotetraploid peanut Arachis hypogaea

Author

Bertioli, David J, Jenkins, Jerry, Clevenger, Josh, Dudchenko, Olga, Gao, Dongying, Seijo, Guillermo, Leal-Bertioli, Soraya CM, Ren, Longhui, Farmer, Andrew D, Pandey, Manish K, Samoluk, Sergio S, Abernathy, Brian, Agarwal, Gaurav, Ballén-Taborda, Carolina, Cameron, Connor, Campbell, Jacqueline, Chavarro, Carolina, Chitikineni, Annapurna, Chu, Ye, Dash, Sudhansu, El Baidouri, Moaine, Guo, Baozhu, Huang, Wei, Kim, Kyung Do, Korani, Walid, Lanciano, Sophie, Lui, Christopher G, Mirouze, Marie, Moretzsohn, Márcio C, Pham, Melanie, Shin, Jin Hee, Shirasawa, Kenta, Sinharoy, Senjuti, Sreedasyam, Avinash, Weeks, Nathan T, Zhang, Xinyou, Zheng, Zheng, Sun, Ziqi, Froenicke, Lutz, Aiden, Erez L, Michelmore, Richard, Varshney, Rajeev K, Holbrook, C Corley, Cannon, Ethalinda KS, Scheffler, Brian E, Grimwood, Jane, Ozias-Akins, Peggy, Cannon, Steven B, Jackson, Scott A, and Schmutz, Jeremy

Subjects

Biological Sciences, Genetics, Human Genome, Biotechnology, Arachis, Argentina, Chromosomes, Plant, Crops, Agricultural, DNA Methylation, DNA, Plant, Domestication, Evolution, Molecular, Gene Expression Regulation, Plant, Genetic Variation, Genome, Plant, Hybridization, Genetic, Phenotype, Polyploidy, Recombination, Genetic, Species Specificity, Tetraploidy, Medical and Health Sciences, Developmental Biology, Agricultural biotechnology, Bioinformatics and computational biology

Abstract

Like many other crops, the cultivated peanut (Arachis hypogaea L.) is of hybrid origin and has a polyploid genome that contains essentially complete sets of chromosomes from two ancestral species. Here we report the genome sequence of peanut and show that after its polyploid origin, the genome has evolved through mobile-element activity, deletions and by the flow of genetic information between corresponding ancestral chromosomes (that is, homeologous recombination). Uniformity of patterns of homeologous recombination at the ends of chromosomes favors a single origin for cultivated peanut and its wild counterpart A. monticola. However, through much of the genome, homeologous recombination has created diversity. Using new polyploid hybrids made from the ancestral species, we show how this can generate phenotypic changes such as spontaneous changes in the color of the flowers. We suggest that diversity generated by these genetic mechanisms helped to favor the domestication of the polyploid A. hypogaea over other diploid Arachis species cultivated by humans.

Published

2019

2. Development and application of whole-chromosome painting of chromosomes 7A and 8A of Arachis duranensis based on chromosome-specific single-copy oligonucleotides.

Author

Li, Chenyu, Fu, Liuyang, Wang, Qian, Liu, Hua, Chen, Guoquan, Qi, Feiyan, Zhang, Maoning, Jia, Yaoguang, Li, Xiaona, Huang, Bingyan, Dong, Wenzhao, Du, Pei, and Zhang, Xinyou

Subjects

HOMOLOGOUS chromosomes, CHROMOSOME analysis, ARACHIS, CHROMOSOME inversions, CHROMOSOMES, FLUORESCENCE in situ hybridization, MOLECULAR probes, NUDITY

Abstract

For peanut, the lack of stable cytological markers is a barrier to tracking specific chromosomes, elucidating the genetic relationships between genomes and identifying chromosomal variations. Chromosome mapping using single-copy oligonucleotide (oligo) probe libraries has unique advantages for identifying homologous chromosomes and chromosomal rearrangements. In this study, we developed two whole-chromosome single-copy oligo probe libraries, LS-7A and LS-8A, based on the reference genome sequences of chromosomes 7A and 8A of Arachis duranensis. Fluorescence in situ hybridization (FISH) analysis confirmed that the libraries could specifically paint chromosomes 7 and 8. In addition, sequential FISH and electronic localization of LS-7A and LS-8A in A. duranensis (AA) and A. ipaensis (BB) showed that chromosomes 7A and 8A contained translocations and inversions relative to chromosomes 7B and 8B. Analysis of the chromosomes of wild Arachis species using LS-8A confirmed that this library could accurately and effectively identify A genome species. Finally, LS-7A and LS-8A were used to paint the chromosomes of interspecific hybrids and their progenies, which verified the authenticity of the interspecific hybrids and identified a disomic addition line. This study provides a model for developing specific oligo probes to identify the structural variations of other chromosomes in Arachis and demonstrates the practical utility of LS-7A and LS-8A. [ABSTRACT FROM AUTHOR]

Published

2024

3. A near complete genome of Arachis monticola, an allotetraploid wild peanut.

Author

Xue, Hongzhang, Zhao, Kai, Zhao, Kunkun, Han, Suoyi, Chitikineni, Annapurna, Zhang, Lin, Qiu, Ding, Ren, Rui, Gong, Fangping, Li, Zhongfeng, Ma, Xingli, Zhang, Xingguo, Varshney, Rajeev K., Zhang, Xinyou, Wei, Chaochun, and Yin, Dongmei

Subjects

GENOMES, ARACHIS, GENE expression, GENE families, HOMOLOGOUS chromosomes, PEANUTS

Abstract

The article presents the development of an updated high-quality genome assembly of Arachis monticola, a wild peanut species. The previous genome assembly had low quality, but the use of long-read sequencing technologies allowed for a higher-quality assembly. The new assembly, called Amon2.0, has improved contiguity and completeness compared to the previous version. The genome assembly will contribute to further understanding the domestication and evolutionary histories of Arachis spp. and will be a valuable resource for functional genomics and molecular-assisted breeding in legume crops. [Extracted from the article]

Published

2024

4. Chloroplast Phylogenomic Analyses Reveal a Maternal Hybridization Event Leading to the Formation of Cultivated Peanuts

Author

Xiangyu Tian, Luye Shi, Jia Guo, Liuyang Fu, Pei Du, Bingyan Huang, Yue Wu, Xinyou Zhang, and Zhenlong Wang

Subjects

Arachis, whole plastid genome, genetic structure, phylogenomics, maternal hybridization event, Plant culture, SB1-1110

Abstract

Peanuts (Arachis hypogaea L.) offer numerous healthy benefits, and the production of peanuts has a prominent role in global food security. As a result, it is in the interest of society to improve the productivity and quality of peanuts with transgenic means. However, the lack of a robust phylogeny of cultivated and wild peanut species has limited the utilization of genetic resources in peanut molecular breeding. In this study, a total of 33 complete peanut plastomes were sequenced, analyzed and used for phylogenetic analyses. Our results suggest that sect. Arachis can be subdivided into two lineages. All the cultivated species are contained in Lineage I with AABB and AA are the two predominant genome types present, while species in Lineage II possess diverse genome types, including BB, KK, GG, etc. Phylogenetic studies also indicate that all allotetraploid cultivated peanut species have been derived from a possible maternal hybridization event with one of the diploid Arachis duranensis accessions being a potential AA sub-genome ancestor. In addition, Arachis monticola, a tetraploid wild species, is placed in the same group with all the cultivated peanuts, and it may represent a transitional species, which has been through the recent hybridization event. This research could facilitate a better understanding of the taxonomic status of various Arachis species/accessions and the evolutionary relationship among them, and assists in the correct and efficient use of germplasm resources in breeding efforts to improve peanuts for the benefit of human beings.

Published

2021

5. Genome-wide association study and development of molecular markers for yield and quality traits in peanut (Arachis hypogaea L.).

Author

Guo, Minjie, Deng, Li, Gu, Jianzhong, Miao, Jianli, Yin, Junhua, Li, Yang, Fang, Yuanjin, Huang, Bingyan, Sun, Ziqi, Qi, Feiyan, Dong, Wenzhao, Lu, Zhenhua, Li, Shaowei, Hu, Junping, Zhang, Xinyou, and Ren, Li

Subjects

GENOME-wide association studies, PEANUTS, GENOTYPE-environment interaction, SINGLE nucleotide polymorphisms, GENETIC markers in plants, ARACHIS, LINKAGE disequilibrium

Abstract

Background: This study aims to decipher the genetic basis governing yield components and quality attributes of peanuts, a critical aspect for advancing molecular breeding techniques. Integrating genotype re-sequencing and phenotypic evaluations of seven yield components and two grain quality traits across four distinct environments allowed for the execution of a genome-wide association study (GWAS). Results: The nine phenotypic traits were all continuous and followed a normal distribution. The broad heritability ranged from 88.09 to 98.08%, and the genotype-environment interaction effects were all significant. There was a highly significant negative correlation between protein content (PC) and oil content (OC). The 10× genome re-sequencing of 199 peanut accessions yielded a total of 631,988 high-quality single nucleotide polymorphisms (SNPs), with 374 significant SNP loci identified in association with the nine traits of interest. Notably, 66 of these pertinent SNPs were detected in multiple environments, and 48 of them were linked to multiple traits of interest. Five loci situated on chromosome 16 (Chr16) exhibited pleiotropic effects on yield traits, accounting for 17.64–32.61% of the observed phenotypic variation. Two loci on Chr08 were found to be strongly associated with protein and oil contents, accounting for 12.86% and 14.06% of their respective phenotypic variations, respectively. Linkage disequilibrium (LD) block analysis of these seven loci unraveled five nonsynonymous variants, leading to the identification of one yield-related candidate gene and two quality-related candidate genes. The correlation between phenotypic variation and SNP loci in these candidate genes was validated by Kompetitive allele-specific PCR (KASP) marker analysis. Conclusions: Overall, molecular markers were developed for genetic loci associated with yield and quality traits through a GWAS investigation of 199 peanut accessions across four distinct environments. These molecular tools can aid in the development of desirable peanut germplasm with an equilibrium of yield and quality through marker-assisted breeding. [ABSTRACT FROM AUTHOR]

Published

2024

6. Genome-Wide Characterization of the Phenylalanine Ammonia-Lyase Gene Family and Their Potential Roles in Response to Aspergillus flavus L. Infection in Cultivated Peanut (Arachis hypogaea L.).

Author

Chai, Pengpei, Cui, Mengjie, Zhao, Qi, Chen, Linjie, Guo, Tengda, Guo, Jingkun, Wu, Chendi, Du, Pei, Liu, Hua, Xu, Jing, Zheng, Zheng, Huang, Bingyan, Dong, Wenzhao, Han, Suoyi, and Zhang, Xinyou

Subjects

GENE families, ASPERGILLUS flavus, PEANUTS, PHENYLALANINE, ARACHIS, PROMOTERS (Genetics)

Abstract

Phenylalanine ammonia-lyase (PAL) is an essential enzyme in the phenylpropanoid pathway, in which numerous aromatic intermediate metabolites play significant roles in plant growth, adaptation, and disease resistance. Cultivated peanuts are highly susceptible to Aspergillus flavus L. infection. Although PAL genes have been characterized in various major crops, no systematic studies have been conducted in cultivated peanuts, especially in response to A. flavus infection. In the present study, a systematic genome-wide analysis was conducted to identify PAL genes in the Arachis hypogaea L. genome. Ten AhPAL genes were distributed unevenly on nine A. hypogaea chromosomes. Based on phylogenetic analysis, the AhPAL proteins were classified into three groups. Structural and conserved motif analysis of PAL genes in A. hypogaea revealed that all peanut PAL genes contained one intron and ten motifs in the conserved domains. Furthermore, synteny analysis indicated that the ten AhPAL genes could be categorized into five pairs and that each AhPAL gene had a homologous gene in the wild-type peanut. Cis-element analysis revealed that the promoter region of the AhPAL gene family was rich in stress- and hormone-related elements. Expression analysis indicated that genes from Group I (AhPAL1 and AhPAL2), which had large number of ABRE, WUN, and ARE elements in the promoter, played a strong role in response to A. flavus stress. [ABSTRACT FROM AUTHOR]

Published

2024

7. Genome-Wide Association Studies of Embryogenic Callus Induction Rate in Peanut (Arachis hypogaea L.).

Author

Luo, Dandan, Shi, Lei, Sun, Ziqi, Qi, Feiyan, Liu, Hongfei, Xue, Lulu, Li, Xiaona, Liu, Han, Qu, Pengyu, Zhao, Huanhuan, Dai, Xiaodong, Dong, Wenzhao, Zheng, Zheng, Huang, Bingyan, Fu, Liuyang, and Zhang, Xinyou

Subjects

GENOME-wide association studies, PEANUTS, CALLUS (Botany), ARACHIS, GENETIC engineering, GENETIC variation

Abstract

The capability of embryogenic callus induction is a prerequisite for in vitro plant regeneration. However, embryogenic callus induction is strongly genotype-dependent, thus hindering the development of in vitro plant genetic engineering technology. In this study, to examine the genetic variation in embryogenic callus induction rate (CIR) in peanut (Arachis hypogaea L.) at the seventh, eighth, and ninth subcultures (T7, T8, and T9, respectively), we performed genome-wide association studies (GWAS) for CIR in a population of 353 peanut accessions. The coefficient of variation of CIR among the genotypes was high in the T7, T8, and T9 subcultures (33.06%, 34.18%, and 35.54%, respectively), and the average CIR ranged from 1.58 to 1.66. A total of 53 significant single-nucleotide polymorphisms (SNPs) were detected (based on the threshold value −log10(p) = 4.5). Among these SNPs, SNPB03-83801701 showed high phenotypic variance and neared a gene that encodes a peroxisomal ABC transporter 1. SNPA05-94095749, representing a nonsynonymous mutation, was located in the Arahy.MIX90M locus (encoding an auxin response factor 19 protein) at T8, which was associated with callus formation. These results provide guidance for future elucidation of the regulatory mechanism of embryogenic callus induction in peanut. [ABSTRACT FROM AUTHOR]

Published

2024

8. Identification of two major QTLs for pod shell thickness in peanut (Arachis hypogaea L.) using BSA-seq analysis.

Author

Liu, Hongfei, Zheng, Zheng, Sun, Ziqi, Qi, Feiyan, Wang, Juan, Wang, Mengmeng, Dong, Wenzhao, Cui, Kailu, Zhao, Mingbo, Wang, Xiao, Zhang, Meng, Wu, Xiaohui, Wu, Yue, Luo, Dandan, Huang, Bingyan, Zhang, Zhongxin, Cao, Gangqiang, and Zhang, Xinyou

Subjects

PEANUT hulls, PEANUTS, LOCUS (Genetics), ARACHIS, GENE mapping, CHROMOSOMES

Abstract

Background: Pod shell thickness (PST) is an important agronomic trait of peanut because it affects the ability of shells to resist pest infestations and pathogen attacks, while also influencing the peanut shelling process. However, very few studies have explored the genetic basis of PST. Results: An F2 segregating population derived from a cross between the thick-shelled cultivar Yueyou 18 (YY18) and the thin-shelled cultivar Weihua 8 (WH8) was used to identify the quantitative trait loci (QTLs) for PST. On the basis of a bulked segregant analysis sequencing (BSA-seq), four QTLs were preliminarily mapped to chromosomes 3, 8, 13, and 18. Using the genome resequencing data of YY18 and WH8, 22 kompetitive allele-specific PCR (KASP) markers were designed for the genotyping of the F2 population. Two major QTLs (qPSTA08 and qPSTA18) were identified and finely mapped, with qPSTA08 detected on chromosome 8 (0.69-Mb physical genomic region) and qPSTA18 detected on chromosome 18 (0.15-Mb physical genomic region). Moreover, qPSTA08 and qPSTA18 explained 31.1–32.3% and 16.7–16.8% of the phenotypic variation, respectively. Fifteen genes were detected in the two candidate regions, including three genes with nonsynonymous mutations in the exon region. Two molecular markers (Tif2_A08_31713024 and Tif2_A18_7198124) that were developed for the two major QTL regions effectively distinguished between thick-shelled and thin-shelled materials. Subsequently, the two markers were validated in four F2:3 lines selected. Conclusions: The QTLs identified and molecular markers developed in this study may lay the foundation for breeding cultivars with a shell thickness suitable for mechanized peanut shelling. [ABSTRACT FROM AUTHOR]

Published

2024

9. Identification of QTL for kernel weight and size and analysis of the pentatricopeptide repeat (PPR) gene family in cultivated peanut (Arachis hypogaea L.).

Author

Fang, Yuanjin, Liu, Hua, Qin, Li, Qi, Feiyan, Sun, Ziqi, Wu, Jihua, Dong, Wenzhao, Huang, Bingyan, and Zhang, Xinyou

Subjects

GENE families, PENTATRICOPEPTIDE repeat genes, PEANUTS, LOCUS (Genetics), ARACHIS, PEANUT growing, SINGLE nucleotide polymorphisms

Abstract

Peanut (Arachis hypogaea L.) is an important oilseed crop worldwide. Improving its yield is crucial for sustainable peanut production to meet increasing food and industrial requirements. Deciphering the genetic control underlying peanut kernel weight and size, which are essential components of peanut yield, would facilitate high-yield breeding. A high-density single nucleotide polymorphism (SNP)-based linkage map was constructed using a recombinant inbred lines (RIL) population derived from a cross between the variety Yuanza9102 and a germplasm accession wt09-0023. Kernel weight and size quantitative trait loci (QTLs) were co-localized to a 0.16 Mb interval on Arahy07 using inclusive composite interval mapping (ICIM). Analysis of SNP, and Insertion or Deletion (INDEL) markers in the QTL interval revealed a gene encoding a pentatricopeptide repeat (PPR) superfamily protein as a candidate closely linked with kernel weight and size in cultivated peanut. Examination of the PPR gene family indicated a high degree of collinearity of PPR genes between A. hypogaea and its diploid progenitors, Arachis duranensis and Arachis ipaensis. The candidate PPR gene, Arahy.JX1V6X, displayed a constitutive expression pattern in developing seeds. These findings lay a foundation for further fine mapping of QTLs related to kernel weight and size, as well as validation of candidate genes in cultivated peanut. [ABSTRACT FROM AUTHOR]

Published

2023

10. Physical mapping of repetitive oligonucleotides facilitates the establishment of a genome map-based karyotype to identify chromosomal variations in peanut

Author

Junjia Guo, Huang Bingyan, Li Lina, Ziqi Sun, Siyu Wang, Qian Wang, Pei Du, Suoyi Han, Wenzhao Dong, Tao Lang, Fu Liuyang, and Xinyou Zhang

Subjects

0106 biological sciences, 0301 basic medicine, Crops, Agricultural, Oligos, Arachis, Genotype, Reference sequence, Karyotype, Chromosomal variants, Plant Science, Computational biology, 01 natural sciences, DNA sequencing, Chromosomes, Plant, 03 medical and health sciences, Arachis ipaensis, Tandem repeat, FISH, lcsh:Botany, medicine, Genomic organization, Repetitive Sequences, Nucleic Acid, biology, medicine.diagnostic_test, Chromosome, Chromosome Mapping, Genetic Variation, TRs, biology.organism_classification, lcsh:QK1-989, 030104 developmental biology, Peanut, Ploidy, Oligonucleotide Probes, Genome, Plant, 010606 plant biology & botany, Fluorescence in situ hybridization, Reference genome, Research Article

Abstract

Background Chromosomal variants play important roles in crop breeding and genetic research. The development of single-stranded oligonucleotide (oligo) probes simplifies the process of fluorescence in situ hybridization (FISH) and facilitates chromosomal identification in many species. Genome sequencing provides rich resources for the development of oligo probes. However, little progress has been made in peanut due to the lack of efficient chromosomal markers. Until now, the identification of chromosomal variants in peanut has remained a challenge. Results A total of 114 new oligo probes were developed based on the genome-wide tandem repeats (TRs) identified from the reference sequences of the peanut variety Tifrunner (AABB, 2n = 4x = 40) and the diploid species Arachis ipaensis (BB, 2n = 2x = 20). These oligo probes were classified into 28 types based on their positions and overlapping signals in chromosomes. For each type, a representative oligo was selected and modified with green fluorescein 6-carboxyfluorescein (FAM) or red fluorescein 6-carboxytetramethylrhodamine (TAMRA). Two cocktails, Multiplex #3 and Multiplex #4, were developed by pooling the fluorophore conjugated probes. Multiplex #3 included FAM-modified oligo TIF-439, oligo TIF-185-1, oligo TIF-134-3 and oligo TIF-165. Multiplex #4 included TAMRA-modified oligo Ipa-1162, oligo Ipa-1137, oligo DP-1 and oligo DP-5. Each cocktail enabled the establishment of a genome map-based karyotype after sequential FISH/genomic in situ hybridization (GISH) and in silico mapping. Furthermore, we identified 14 chromosomal variants of the peanut induced by radiation exposure. A total of 28 representative probes were further chromosomally mapped onto the new karyotype. Among the probes, eight were mapped in the secondary constrictions, intercalary and terminal regions; four were B genome-specific; one was chromosome-specific; and the remaining 15 were extensively mapped in the pericentric regions of the chromosomes. Conclusions The development of new oligo probes provides an effective set of tools which can be used to distinguish the various chromosomes of the peanut. Physical mapping by FISH reveals the genomic organization of repetitive oligos in peanut chromosomes. A genome map-based karyotype was established and used for the identification of chromosome variations in peanut following comparisons with their reference sequence positions.

Published

2021

11. Development of Oligo-GISH kits for efficient detection of chromosomal variants in peanut.

Author

Pei Du, Liuyang Fu, Qian Wang, Tao Lang, Hua Liu, Suoyi Han, Chenyu Li, Bingyan Huang, Li Qin, Xiaodong Dai, Wenzhao Dong, and Xinyou Zhang

Subjects

PEANUT genetics, PLANT variation, PLANT chromosomes, IN situ hybridization, ARACHIS

Abstract

Oligo probe staining is a low-cost and efficient chromosome identification technique. In this study, oligo genomic in situ hybridization (Oligo-GISH) technology was established in peanut. Peanut A and B subgenome-specific interspersed repeat (IR) oligo probe sets were developed based on clustering and electronic localization of tandem repeat sequences in the reference genome of Tifrunner. The Oligo-GISH kit was then used to perform staining of 15 Arachis species. The A-subgenome probe set stained the chromosomes of A- and E-genome Arachis species, the B-subgenome probe set stained those of B-, F-, K-, and E-genome species, and neither set stained those of H-genome species. These results indicate the relationships among the genomes of these Arachis species. The Oligo-GISH kit was also used for batch staining of the chromosomes of 389 seedlings from the irradiated M1 generation, allowing 67 translocation and deletion lines to be identified. Subsequent Oligo-FISH karyotyping, FISH using single-copy probe libraries, and trait investigation identified seven homozygous chromosomal variants from the M3 generation and suggested that there may be genes on chromosome 4B controlling seed number per pod. These findings demonstrate that the IR probe sets and method developed in this study can facilitate research on distant hybridization and genetic improvement in peanut. [ABSTRACT FROM AUTHOR]

Published

2023

12. AhNPR3 regulates the expression of WRKY and PR genes, and mediates the immune response of the peanut (Arachis hypogaea L.)

Author

Suoyi, Han, Ximeng, Zhou, Lei, Shi, Huayang, Zhang, Yun, Geng, Yuanjin, Fang, Han, Xia, Hua, Liu, Pengcheng, Li, Shuzhen, Zhao, Lijuan, Miao, Lei, Hou, Zhongxin, Zhang, Jing, Xu, Changle, Ma, Zhenyu, Wang, Hongyan, Li, Zheng, Zheng, Bingyan, Huang, Wenzhao, Dong, Jun, Zhang, Fengshou, Tang, Shaojian, Li, Meng, Gao, Xinyou, Zhang, Chuanzhi, Zhao, and Xingjun, Wang

Subjects

Phenotype, Arachis, RNA, Disease Resistance

Abstract

Systemic acquired resistance is an essential immune response that triggers a broad-spectrum disease resistance throughout the plant. In the present study, we identified a peanut lesion mimic mutant m14 derived from an ethyl methane sulfonate-mutagenized mutant pool of peanut cultivar "Yuanza9102." Brown lesions were observed in the leaves of an m14 mutant from seedling stage to maturity. Using MutMap together with bulked segregation RNA analysis approaches, a G-to-A point mutation was identified in the exon region of candidate gene Arahy.R60CUW, which is the homolog of AtNPR3 (Nonexpresser of PR genes) in Arabidopsis. This point mutation caused a transition from Gly to Arg within the C-terminal transactivation domain of AhNPR3A. The mutation of AhNPR3A showed no effect in the induction of PR genes when treated with salicylic acid. Instead, the mutation resulted in upregulation of WRKY genes and several PR genes, including pathogenesis-related thaumatin- and chitinase-encoding genes, which is consistent with the resistant phenotype of m14 to leaf spot disease. Further study on the AhNPR3A gene will provide valuable insights into understanding the molecular mechanism of systemic acquired resistance in peanut. Moreover, our results indicated that a combination of MutMap and bulked segregation RNA analysis is an effective method for identifying genes from peanut mutants.

Published

2022

13. Genome-Wide Identification and Expression Analysis of GATA Gene Family under Different Nitrogen Levels in Arachis hypogaea L.

Author

Li, Xiujie, Deng, Xiaoxu, Han, Suoyi, Zhang, Xinyou, and Dai, Tingbo

Subjects

GENE expression, GENE families, PEANUTS, CULTIVARS, ARACHIS, NITROGEN fertilizers, ZINC-finger proteins

Abstract

Nitrogen, one of the essential elements, is a key determinant for improving peanut growth and yield. GATA zinc finger transcription factors have been found to be involved in regulation of nitrogen metabolism. However, a systematic characterization of the GATA gene family and patterns of their expression under different nitrogen levels remains elusive. In this study, a total of 45 GATA genes distributed among 17 chromosomes were identified in the peanut genome and classified into three subfamilies I, II and III with 26, 13 and 6 members, respectively, whose physicochemical characteristics, gene structures and conserved motifs were also analyzed. Furthermore, the optimal level of nitrogen fertilizer on the growth of peanut cultivar Yuhua 23 was determined by pod yield and value cost ratio from 2020 to 2022, and the results revealed that 150 kg hm−2 nitrogen was the best for cultivation of peanut Yuhua 23 because of its highest pod yield and relatively higher VCR of more than four. In addition, expression patterns of peanut GATA genes under different nitrogen levels were detected by real-time quantitative PCR and several GATA genes were significantly changed under a nitrogen level of 150 kg hm−2. Overall, the above results would be helpful for further understanding biological functions of the GATA gene family in cultivated peanut. [ABSTRACT FROM AUTHOR]

Published

2023

14. The genome of cultivated peanut provides insight into legume karyotypes, polyploid evolution and crop domestication

Author

Pengchuan Sun, Annapurna Chitikineni, Shubiao Zhang, Jinpeng Wang, Jigao Yu, Haibao Tang, Shanshan Zhao, Niaz Ali, Zhang Chong, Chen Hua, Rong Long Pan, Andrew H. Paterson, Shihua Shan, Depeng Wang, Guohao He, Yuting Chen, Faqian Xiong, Zhenyi Wang, Kun Chen, Kangcheng Wu, Shahid Ali Khan, Jiang Hu, Xinguo Li, Ye Deng, Liangsheng Zhang, Meng Yang, Yongli Zhao, Baozhu Guo, Manish K. Pandey, Tiecheng Cai, Wenting Chu, Junpeng Fan, Yu Li, Ziliang Luo, Hansong Yan, Tao Zhuo, Mei Yuan, Vanika Garg, Chuanzhi Zhao, Prasad Bajaj, Xiyin Wang, Ruirong Zhuang, Xingjun Wang, Yuhao Zhao, Zifan Zhao, Dongyang Xie, Xingtan Zhang, Gandeka Mamadou, Li Zha, Yuhui Zhuang, Qinzheng Liu, Fan Liang, Wenping Xie, Qiang Yang, Chi Nga Chow, Congcong Wang, Jiaqing Yuan, Huasong Zou, Jianping Wang, Weijian Zhuang, Han Xia, Chunjuan Li, Tang Ronghua, Boshou Liao, Shengyi Liu, Ze Peng, Ray Ming, Weichang Yu, Weipeng Quan, Aamir W. Khan, Fanbo Meng, Xinyou Zhang, Wen Chi Chang, P. B. KaviKishor, Shuaiyin Wang, Yixiong Zheng, Jingjing Li, and Rajeev K. Varshney

Subjects

Arachis, Karyotype, Plant disease resistance, Biology, Plant Proteins, Dietary, Genome, Article, Chromosomes, Plant, Domestication, Evolution, Molecular, Polyploidy, 03 medical and health sciences, 0302 clinical medicine, Polyploid, Genetic variation, Botany, Genetics, DNA sequencing, Gene, Disease Resistance, Plant Diseases, 030304 developmental biology, Ecotype, Whole genome sequencing, 0303 health sciences, Chromosome Mapping, food and beverages, Genomics, Droughts, Plant Breeding, Seeds, Peanut Oil, Functional genomics, Genome, Plant, 030217 neurology & neurosurgery

Abstract

High oil and protein content make tetraploid peanut a leading oil and food legume. Here we report a high-quality peanut genome sequence, comprising 2.54 Gb with 20 pseudomolecules and 83,709 protein-coding gene models. We characterize gene functional groups implicated in seed size evolution, seed oil content, disease resistance and symbiotic nitrogen fixation. The peanut B subgenome has more genes and general expression dominance, temporally associated with long-terminal-repeat expansion in the A subgenome that also raises questions about the A-genome progenitor. The polyploid genome provided insights into the evolution of Arachis hypogaea and other legume chromosomes. Resequencing of 52 accessions suggests that independent domestications formed peanut ecotypes. Whereas 0.42–0.47 million years ago (Ma) polyploidy constrained genetic variation, the peanut genome sequence aids mapping and candidate-gene discovery for traits such as seed size and color, foliar disease resistance and others, also providing a cornerstone for functional genomics and peanut improvement., High-quality genome sequence of cultivated peanut comprising 2.54 Gb with 20 pseudomolecules and 83,709 protein-coding gene models provides insights into genome evolution and the genetic mechanisms underlying seed size and leaf resistance in peanut.

Published

2019

15. Distribution, accumulation, migration and risk assessment of trace elements in peanut-soil system

Author

Bolei Yang, Jihao Shan, Fuguo Xing, Xiaodong Dai, Gang Wang, Junning Ma, Tosin Victor Adegoke, Xinyou Zhang, Qiang Yu, and Xiaohua Yu

Subjects

China, Arachis, Health, Toxicology and Mutagenesis, General Medicine, Toxicology, Risk Assessment, Pollution, Trace Elements, Soil, Metals, Heavy, Humans, Soil Pollutants, Cadmium, Environmental Monitoring

Abstract

Trace elements contamination is mainly originated from industrial emission, sewage irrigation and pesticides, and poses a threat to the environment and human health. This study analyzed the trace element pollutants in peanut-soil systems, the enrichment and translocation capacity of peanut to trace elements, and the potential risk of trace elements to environment and human health. The results indicated that Cd and Ni in peanut kernels exceeded the standard limits in 2019, and the exceeding rate were 9% and 31%, respectively. Cd in 8% of soil samples and As in 98% of soil samples exceeded the risk screening value of trace elements. The concentration of trace elements in peanuts was related to varieties and planting regions. In addition, there was a significant positive correlation between the concentration of Cd in peanut kernel and its concentration in soil. Compared with other trace elements, peanut kernels had stronger ability to enrich and transport Cd, Cu, and Zn, the BFs were 0.45, 0.51 and 0.47, respectively. After oil extraction, trace elements were mainly concentrated in peanut meal, and only 0.25% of Cd was in oil. The RI of trace elements was less than 150, indicating that the study area was under low degree of ecological risk. However, As and Cd might pose moderate risk to environment. Trace elements in soil and peanut could not cause non-carcinogenic and carcinogenic risks to human, but the HI and CR value of As (0.59 and 9.54 × 10

Published

2022

16. Comparative transcriptomics analysis of developing peanut (Arachis hypogaea L.) pods reveals candidate genes affecting peanut seed size.

Author

Yue Wu, Ziqi Sun, Feiyan Qi, Mengdi Tian, Juan Wang, Ruifang Zhao, Xiao Wang, Xiaohui Wu, Xinlong Shi, Hongfei Liu, Wenzhao Dong, Bingyan Huang, Zheng Zheng, and Xinyou Zhang

Subjects

SEED pods, AUXIN, SEED size, ARACHIS, MITOGEN-activated protein kinases, PEANUTS, PLANT cells & tissues

Abstract

Pod size is one of the most important agronomic features of peanuts, which directly affects peanut yield. Studies on the regulation mechanism underpinning pod size in cultivated peanuts remain hitherto limited compared to model plant systems. To better understand the molecular elements that underpin peanut pod development, we conducted a comprehensive analysis of chronological transcriptomics during pod development in four peanut accessions with similar genetic backgrounds, but varying pod sizes. Several plant transcription factors, phytohormones, and the mitogen-activated protein kinase (MAPK) signaling pathways were significantly enriched among differentially expressed genes (DEGs) at five consecutive developmental stages, revealing an eclectic range of candidate genes, including PNC, YUC, and IAA that regulate auxin synthesis and metabolism, CYCD and CYCU that regulate cell differentiation and proliferation, and GASA that regulates seed size and pod elongation via gibberellin pathway. It is plausible that MPK3 promotes integument cell division and regulates mitotic activity through phosphorylation, and the interactions between these genes form a network of molecular pathways that affect peanut pod size. Furthermore, two variant sites, GCP4 and RPPL1, were identified which are stable at the QTL interval for seed size attributes and function in plant cell tissue microtubule nucleation. These findings may facilitate the identification of candidate genes that regulate pod size and impart yield improvement in cultivated peanuts. [ABSTRACT FROM AUTHOR]

Published

2022

17. Gene Co-expression Network Analysis of the Comparative Transcriptome Identifies Hub Genes Associated With Resistance to Aspergillus flavus L. in Cultivated Peanut (Arachis hypogae a L.).

Author

Cui, Mengjie, Han, Suoyi, Wang, Du, Haider, Muhammad Salman, Guo, Junjia, Zhao, Qi, Du, Pei, Sun, Ziqi, Qi, Feiyan, Zheng, Zheng, Huang, Bingyan, Dong, Wenzhao, Li, Peiwu, and Zhang, Xinyou

Subjects

PEANUTS, ASPERGILLUS flavus, GENE regulatory networks, SNARE proteins, PATTERN perception receptors, ARACHIS, AFLATOXINS

Abstract

Cultivated peanut (Arachis hypogaea L.), a cosmopolitan oil crop, is susceptible to a variety of pathogens, especially Aspergillus flavus L., which not only vastly reduce the quality of peanut products but also seriously threaten food safety for the contamination of aflatoxin. However, the key genes related to resistance to Aspergillus flavus L. in peanuts remain unclear. This study identifies hub genes positively associated with resistance to A. flavus in two genotypes by comparative transcriptome and weighted gene co-expression network analysis (WGCNA) method. Compared with susceptible genotype (Zhonghua 12, S), the rapid response to A. flavus and quick preparation for the translation of resistance-related genes in the resistant genotype (J-11, R) may be the drivers of its high resistance. WGCNA analysis revealed that 18 genes encoding pathogenesis-related proteins (PR10), 1-aminocyclopropane-1-carboxylate oxidase (ACO1), MAPK kinase, serine/threonine kinase (STK), pattern recognition receptors (PRRs), cytochrome P450, SNARE protein SYP121, pectinesterase, phosphatidylinositol transfer protein, and pentatricopeptide repeat (PPR) protein play major and active roles in peanut resistance to A. flavus. Collectively, this study provides new insight into resistance to A. flavus by employing WGCNA, and the identification of hub resistance-responsive genes may contribute to the development of resistant cultivars by molecular-assisted breeding. [ABSTRACT FROM AUTHOR]

Published

2022

18. QTL mapping of web blotch resistance in peanut by high-throughput genome-wide sequencing

Author

Wenzhao Dong, Yujie Cheng, Gao Meng, Xu Jing, Huang Bingyan, Liu Hua, Wang Zhenyu, Qin Li, Zhang Zhongxin, Qi Feiyan, Xinyou Zhang, Pei Du, Lina Zhang, Zheng Zheng, Suoyi Han, Ziqi Sun, and Shaojian Li

Subjects

Genetic Markers, QTL mapping, Candidate gene, Arachis, Phoma, Population, Quantitative Trait Loci, Plant Science, Biology, Quantitative trait locus, Genome, Polymorphism, Single Nucleotide, lcsh:Botany, Web blotch resistance, Cultivar, education, Disease Resistance, Plant Diseases, Molecular breeding, Genetics, education.field_of_study, food and beverages, Chromosome Mapping, High-Throughput Nucleotide Sequencing, Arachis hypogaea, lcsh:QK1-989, Peanut, Genetic distance, Research Article, Resequencing

Abstract

Background Web blotch is one of the most important foliar diseases worldwide in peanut (Arachis hypogaea L.). The identification of quantitative trait loci (QTLs) for peanut web blotch resistance represents the basis for gene mining and the application of molecular breeding technologies. Results In this study, a peanut recombinant inbred line (RIL) population was used to map QTLs for web blotch resistance based on high-throughput genome-wide sequencing. Frequency distributions of disease grade and disease index in five environments indicated wide phenotypic variations in response to web blotch among RILs. A high-density genetic map was constructed, containing 3634 bin markers distributed on 20 peanut linkage groups (LGs) with an average genetic distance of 0.5 cM. In total, eight QTLs were detected for peanut web blotch resistance in at least two environments, explaining from 2.8 to 15.1% of phenotypic variance. Two major QTLs qWBRA04 and qWBRA14 were detected in all five environments and were linked to 40 candidate genes encoding nucleotide-binding site leucine-rich repeat (NBS-LRR) or other proteins related to disease resistances. Conclusions The results of this study provide a basis for breeding peanut cultivars with web blotch resistance.

Published

2020

19. Transcriptome analysis of pod mutant reveals plant hormones are important regulators in controlling pod size in peanut (Arachis hypogaea L.).

Author

Yaqi Wang, Maoning Zhang, Pei Du, Hua Liu, Zhongxin Zhang, Jing Xu, Li Qin, Bingyan Huang, Zheng Zheng, Wenzhao Dong, Xinyou Zhang, and Suoyi Han

Subjects

PLANT hormones, PEANUT breeding, ARACHIS, PEANUTS, TRANSCRIPTOMES, SEED pods

Abstract

Pod size is an important yield-influencing trait in peanuts. It is affected by plant hormones and identifying the genes related to these hormones may contribute to pod-related trait improvements in peanut breeding programs. However, there is limited information on the molecular mechanisms of plant hormones that regulate pod size in peanuts. We identified a mutant with an extremely small pod (spm) from Yuanza 9102 (WT) by 60Co -radiation mutagenesis. The length and width of the natural mature pod in spm were only 71.34% and 73.36% of those in WT, respectively. We performed comparative analyses for morphological characteristics, anatomy, physiology, and global transcriptome between spm and WT pods. Samples were collected at 10, 20, and 30 days after peg elongation into the soil, representing stages S1, S2, and S3, respectively. The differences in pod size between WT and spm were seen at stage S1 and became even more striking at stages S2 and S3. The cell sizes of the pods were significantly smaller in spm than in WT at stages S1, S2, and S3. These results suggested that reduced cell size may be one of the important contributors for the small pod in spm. The contents of indole-3-acetic acid (IAA), gibberellin (GA), and brassinosteroid (BR) were also significantly lower in spm pods than those in WT pods at all three stages. RNA-Seq analyses showed that 1,373, 8,053, and 3,358 differently expressed genes (DEGs) were identified at stages S1, S2, and S3, respectively. Functional analyses revealed that a set of DEGs was related to plant hormone biosynthesis, plant hormone signal transduction pathway, and cell wall biosynthesis and metabolism. Furthermore, several hub genes associated with plant hormone biosynthesis and signal transduction pathways were identified through weighted gene co-expression network analysis. Our results revealed that IAA, GA, and BR may be important regulators in controlling pod size by regulating cell size in peanuts. This study provides helpful information for the understanding of the complex mechanisms of plant hormones in controlling pod size by regulating the cell size in peanuts and will facilitate the improvement of peanut breeding. [ABSTRACT FROM AUTHOR]

Published

2022

20. Chloroplast Phylogenomic Analyses Reveal a Maternal Hybridization Event Leading to the Formation of Cultivated Peanuts.

Author

Tian, Xiangyu, Shi, Luye, Guo, Jia, Fu, Liuyang, Du, Pei, Huang, Bingyan, Wu, Yue, Zhang, Xinyou, and Wang, Zhenlong

Subjects

PEANUTS, PEANUT breeding, SPECIES hybridization, GERMPLASM, ARACHIS, CHLOROPLAST DNA, PLANT hybridization

Abstract

Peanuts (Arachis hypogaea L.) offer numerous healthy benefits, and the production of peanuts has a prominent role in global food security. As a result, it is in the interest of society to improve the productivity and quality of peanuts with transgenic means. However, the lack of a robust phylogeny of cultivated and wild peanut species has limited the utilization of genetic resources in peanut molecular breeding. In this study, a total of 33 complete peanut plastomes were sequenced, analyzed and used for phylogenetic analyses. Our results suggest that sect. Arachis can be subdivided into two lineages. All the cultivated species are contained in Lineage I with AABB and AA are the two predominant genome types present, while species in Lineage II possess diverse genome types, including BB, KK, GG, etc. Phylogenetic studies also indicate that all allotetraploid cultivated peanut species have been derived from a possible maternal hybridization event with one of the diploid Arachis duranensis accessions being a potential AA sub-genome ancestor. In addition, Arachis monticola , a tetraploid wild species, is placed in the same group with all the cultivated peanuts, and it may represent a transitional species, which has been through the recent hybridization event. This research could facilitate a better understanding of the taxonomic status of various Arachis species/accessions and the evolutionary relationship among them, and assists in the correct and efficient use of germplasm resources in breeding efforts to improve peanuts for the benefit of human beings. [ABSTRACT FROM AUTHOR]

Published

2021

21. Development of an oligonucleotide dye solution facilitates high throughput and cost-efficient chromosome identification in peanut

Author

Fu Liuyang, Xu Jing, Qin Li, Liu Hua, Xiaodong Dai, Zengjun Qi, Suoyi Han, Xinyou Zhang, Siyu Wang, Huang Bingyan, Wenzhao Dong, Tang Fengshou, Li Lina, Bing Liu, Pei Du, and Caihong Cui

Subjects

0106 biological sciences, 0301 basic medicine, Arachis, Oligonucleotide dye solution, Arachis species, Karyotype, Plant Science, lcsh:Plant culture, 01 natural sciences, Genome, 03 medical and health sciences, FISH, Genetics, medicine, lcsh:SB1-1110, lcsh:QH301-705.5, biology, medicine.diagnostic_test, Oligonucleotide, Chemistry, Research, Chromosome, biology.organism_classification, Fluorescence, Staining, 030104 developmental biology, lcsh:Biology (General), Biochemistry, 010606 plant biology & botany, Biotechnology, Fluorescence in situ hybridization

Abstract

Background Development of oligonucleotide probes facilitates chromosome identification via fluorescence in situ hybridization (FISH) in many organisms. Results We report a high throughput and economical method of chromosome identification based on the development of a dye solution containing 2 × saline-sodium citrate (SSC) and oligonucleotide probes. Based on the concentration, staining time, and sequence effects of oligonucleotides, an efficient probe dye of peanut was developed for chromosome identification. To validate the effects of this solution, 200 slides derived from 21 accessions of the cultivated peanut and 30 wild Arachis species were painted to identify Arachis genomes and establish karyotypes. The results showed that one jar of dye could be used to paint 10 chromosome preparations and recycled at least 10 times to efficiently dye more than 100 slides. The A, B, K, F, E, and H genomes showed unique staining karyotype patterns and signal colors. Conclusions Based on the karyotype patterns of Arachis genomes, we revealed the relationships among the A, B, K, F, E, and H genomes in genus Arachis, and demonstrated the potential for adoption of this oligonucleotide dye solution in practice. Electronic supplementary material The online version of this article (10.1186/s13007-019-0451-7) contains supplementary material, which is available to authorized users.

Published

2019

22. Genome-Wide Identification and Expression Analysis of AP2/ERF Transcription Factor Related to Drought Stress in Cultivated Peanut (Arachis hypogaea L.).

Author

Cui, Mengjie, Haider, Muhammad Salman, Chai, Pengpei, Guo, Junjia, Du, Pei, Li, Hongyan, Dong, Wenzhao, Huang, Bingyan, Zheng, Zheng, Shi, Lei, Zhang, Xinyou, and Han, Suoyi

Subjects

PEANUTS, TRANSCRIPTION factors, ARACHIS, DROUGHTS, MEDICAGO truncatula, PROTEIN-protein interactions

Abstract

APETALA2/ethylene response element-binding factor (AP2/ERF) transcription factors (TFs) have been found to regulate plant growth and development and response to various abiotic stresses. However, detailed information of AP2/ERF genes in peanut against drought has not yet been performed. Herein, 185 AP2/ERF TF members were identified from the cultivated peanut (A. hypogaea cv. Tifrunner) genome, clustered into five subfamilies: AP2 (APETALA2), ERF (ethylene-responsive-element-binding), DREB (dehydration-responsive-element-binding), RAV (related to ABI3/VP), and Soloist (few unclassified factors)). Subsequently, the phylogenetic relationship, intron–exon structure, and chromosomal location of AhAP2/ERF were further characterized. All of these AhAP2/ERF genes were distributed unevenly across the 20 chromosomes, and 14 tandem and 85 segmental duplicated gene pairs were identified which originated from ancient duplication events. Gene evolution analysis showed that A. hypogaea cv. Tifrunner were separated 64.07 and 66.44 Mya from Medicago truncatula L. and Glycine max L., respectively. Promoter analysis discovered many cis -acting elements related to light, hormones, tissues, and stress responsiveness process. The protein interaction network predicted the exitance of functional interaction among families or subgroups. Expression profiles showed that genes from AP2 , ERF , and dehydration-responsive-element-binding subfamilies were significantly upregulated under drought stress conditions. Our study laid a foundation and provided a panel of candidate AP2/ERF TFs for further functional validation to uplift breeding programs of drought-resistant peanut cultivars. [ABSTRACT FROM AUTHOR]

Published

2021

23. High-resolution chromosome painting with repetitive and single-copy oligonucleotides in Arachis species identifies structural rearrangements and genome differentiation

Author

Qin Li, Xu Jing, Lifang Zhuang, Tang Fengshou, Pei Du, Liu Hua, Caihong Cui, Xiaodong Dai, Xinyou Zhang, Zengjun Qi, Huang Bingyan, Zhang Zhongxin, Wenzhao Dong, Fu Liuyang, Li Lina, Suoyi Han, Ziqi Sun, and Yonghua Han

Subjects

0301 basic medicine, Genome evolution, Chromosome engineering, Arachis, Arachis species, Oligonucleotides, Plant Science, Chromosomal rearrangement, Biology, Genome, DNA, Ribosomal, Chromosomes, Plant, Chromosome Painting, 03 medical and health sciences, High-resolution karyotype, lcsh:Botany, Chromosome regions, medicine, In Situ Hybridization, Fluorescence, Repetitive Sequences, Nucleic Acid, Genetics, Gene Rearrangement, medicine.diagnostic_test, Chromosome, food and beverages, Karyotype, lcsh:QK1-989, 030104 developmental biology, Karyotyping, Molecular Probes, Genomic evolution, Genome, Plant, Oligonucleotide multiplex, Fluorescence in situ hybridization, Research Article

Abstract

Background Arachis contains 80 species that carry many beneficial genes that can be utilized in the genetic improvement of peanut (Arachis hypogaea L. 2n = 4x = 40, genome AABB). Chromosome engineering is a powerful technique by which these genes can be transferred and utilized in cultivated peanut. However, their small chromosomes and insufficient cytological markers have made chromosome identification and studies relating to genome evolution quite difficult. The development of efficient cytological markers or probes is very necessary for both chromosome engineering and genome discrimination in cultivated peanut. Results A simple and efficient oligonucleotide multiplex probe to distinguish genomes, chromosomes, and chromosomal aberrations of peanut was developed based on eight single-stranded oligonucleotides (SSONs) derived from repetitive sequences. High-resolution karyotypes of 16 Arachis species, two interspecific F1 hybrids, and one radiation-induced M1 plant were then developed by fluorescence in situ hybridization (FISH) using oligonucleotide multiplex, 45S and 5S rDNAs, and genomic in situ hybridization (GISH) using total genomic DNA of A. duranensis (2n = 2x = 20, AA) and A. ipaënsis (2n = 2x = 20, BB) as probes. Genomes, chromosomes, and aberrations were clearly identifiable in the established karyotypes. All eight cultivars had similar karyotypes, whereas the eight wild species exhibited various chromosomal variations. In addition, a chromosome-specific SSON library was developed based on the single-copy sequence of chromosome 6A of A. duranensis. In combination with repetitive SSONs and rDNA FISH, the single-copy SSON library was applied to identify the corresponding A3 chromosome in the A. duranensis karyotype. Conclusions The development of repetitive and single-copy SSON probes for FISH and GISH provides useful tools for the differentiation of chromosomes and identification of structural chromosomal rearrangement. It facilitates the development of high-resolution karyotypes and detection of chromosomal variations in Arachis species. To our knowledge, the methodology presented in this study demonstrates for the first time the correlation between a sequenced chromosome region and a cytologically identified chromosome in peanut. Electronic supplementary material The online version of this article (10.1186/s12870-018-1468-1) contains supplementary material, which is available to authorized users.

Published

2018

24. Differential gene expression in leaf tissues between mutant and wild-type genotypes response to late leaf spot in peanut (Arachis hypogaea L.)

Author

Suoyi Han, Mei Yan, Xinyou Zhang, Wenzhao Dong, Huang Bingyan, Yaqi Wang, Tang Fengshou, Sun Ziqi, Guohao He, Qi Feiyan, and Liu Hua

Subjects

0106 biological sciences, 0301 basic medicine, Leaves, Arachis, Mutant, lcsh:Medicine, Gene Expression, Plant Science, Pathology and Laboratory Medicine, 01 natural sciences, Biochemistry, Gene Expression Regulation, Plant, Gene expression, Medicine and Health Sciences, Photosynthesis, Plant Hormones, lcsh:Science, Genetics, Multidisciplinary, biology, Plant Biochemistry, Plant Anatomy, Gene Ontologies, food and beverages, Genomics, Plants, Legumes, Pathogens, Research Article, Genotype, Plant Pathogens, 03 medical and health sciences, Botany, Leaf spot, KEGG, Gene, Plant Diseases, Sequence Analysis, RNA, Hypogaea, Gene Expression Profiling, lcsh:R, fungi, Wild type, Organisms, Biology and Life Sciences, Computational Biology, Plant Pathology, biology.organism_classification, Genome Analysis, WRKY protein domain, Hormones, Plant Leaves, 030104 developmental biology, Peanut, Mutation, lcsh:Q, Transcriptome, 010606 plant biology & botany

Abstract

Late leaf spot (LLS) is a major foliar disease in peanut (A. hypogaea L.) worldwide, causing significant losses of potential yield in the absence of fungicide applications. Mutants are important materials to study the function of disease-related genes. In this study, the mutant line M14 was derived from cultivar Yuanza 9102 treated with EMS. Yuanza 9102 was selected from an interspecific cross of cultivar Baisha 1016 with A. diogoi, and is resistant to several fungal diseases. By contrast, the M14 was highly susceptible to late leaf spot. RNA-Seq analysis in the leaf tissues of the M14 and its wild type Yuanza 9102 under pathogen challenge showed 2219 differentially expressed genes including1317 up-regulated genes and 902 down-regulated genes. Of these genes, 1541, 1988, 1344, 643 and 533 unigenes were obtained and annotated by public protein databases of SwissPort, TrEMBL, gene ontology (GO), KEGG and clusters of orthologous groups (COG), respectively. Differentially expressed genes (DEGs) showed that expression of inducible pathogenesis-related (PR) proteins was significantly up-regulated; in the meantime DEGs related to photosynthesis were down-regulated in the susceptible M14 in comparison to the resistant WT. Moreover, the up-regulated WRKY transcription factors and down-regulated plant hormones related to plant growth were detected in the M14. The results suggest that down-regulated chloroplast genes, up-regulated WRKY transcription factors, and depressed plant hormones related to plant growth in the M14 might coordinately render the susceptibility though there was a significant high level of PRs. Those negative effectors might be triggered in the susceptible plant by fungal infection and resulted in reduction of photosynthesis and phytohormones and led to symptom formation.

Published

2017

25. Comparative analysis of NBS-LRR genes and their response to Aspergillus flavus in Arachis

Author

Baozhu Guo, Changsheng Li, Chuanzhi Zhao, Xingjun Wang, Suoyi Han, Han Xia, Pengfei Wang, Xinyou Zhang, Yuping Bi, and Hui Song

Subjects

0106 biological sciences, 0301 basic medicine, Arachis, Gene Expression, lcsh:Medicine, Pathology and Laboratory Medicine, 01 natural sciences, Genome, Database and Informatics Methods, Medicine and Health Sciences, lcsh:Science, Phylogeny, Plant Proteins, Fungal Pathogens, Genetics, Multidisciplinary, Chromosome Biology, food and beverages, Phylogenetic Analysis, Genomics, Plants, Legumes, Genomic Databases, Aspergillus, Experimental Organism Systems, Medical Microbiology, Multigene Family, Aspergillus Flavus, Tandem exon duplication, Pathogens, Research Article, Arabidopsis Thaliana, Mycology, Brassica, Paralogous Gene, Biology, Research and Analysis Methods, Microbiology, Chromosomes, Arachis duranensis, 03 medical and health sciences, Model Organisms, Arachis ipaensis, Plant and Algal Models, Gene family, Molecular Biology Techniques, Microbial Pathogens, Molecular Biology, Gene, Molecular Biology Assays and Analysis Techniques, fungi, lcsh:R, Organisms, Fungi, Computational Biology, Biology and Life Sciences, Cell Biology, Genome Analysis, Chromosome Pairs, biology.organism_classification, Molds (Fungi), Peanut, Biological Databases, 030104 developmental biology, lcsh:Q, 010606 plant biology & botany

Abstract

Studies have demonstrated that nucleotide-binding site–leucine-rich repeat (NBS–LRR) genes respond to pathogen attack in plants. Characterization of NBS–LRR genes in peanut is not well documented. The newly released whole genome sequences of Arachis duranensis and Arachis ipaënsis have allowed a global analysis of this important gene family in peanut to be conducted. In this study, we identified 393 (AdNBS) and 437 (AiNBS) NBS–LRR genes from A. duranensis and A. ipaënsis, respectively, using bioinformatics approaches. Full-length sequences of 278 AdNBS and 303 AiNBS were identified. Fifty-one orthologous, four AdNBS paralogous, and six AiNBS paralogous gene pairs were predicted. All paralogous gene pairs were located in the same chromosomes, indicating that tandem duplication was the most likely mechanism forming these paralogs. The paralogs mainly underwent purifying selection, but most LRR 8 domains underwent positive selection. More gene clusters were found in A. ipaënsis than in A. duranensis, possibly owing to tandem duplication events occurring more frequently in A. ipaënsis. The expression profile of NBS–LRR genes was different between A. duranensis and A. hypogaea after Aspergillus flavus infection. The up-regulated expression of NBS–LRR in A. duranensis was continuous, while these genes responded to the pathogen temporally in A. hypogaea.

Published

2017

26. Identification of lipoxygenase (LOX) genes from legumes and their responses in wild type and cultivated peanut upon Aspergillus flavus infection

Author

Suoyi Han, Changsheng Li, Xinyou Zhang, Pengfei Wang, Javier Lopez-Baltazar, Xingjun Wang, and Hui Song

Subjects

0106 biological sciences, 0301 basic medicine, Arachis, Lotus japonicus, Plant disease resistance, 01 natural sciences, Article, Arachis duranensis, 03 medical and health sciences, Arachis ipaensis, Codon, Gene, Phylogeny, Genetics, Multidisciplinary, biology, fungi, food and beverages, Lipoxygenases, biology.organism_classification, Medicago truncatula, 030104 developmental biology, Codon usage bias, 010606 plant biology & botany, Aspergillus flavus

Abstract

Lipoxygenase (LOX) genes are widely distributed in plants and play crucial roles in resistance to biotic and abiotic stress. Although they have been characterized in various plants, little is known about the evolution of legume LOX genes. In this study, we identified 122 full-length LOX genes in Arachis duranensis, Arachis ipaënsis, Cajanus cajan, Cicer arietinum, Glycine max, Lotus japonicus and Medicago truncatula. In total, 64 orthologous and 36 paralogous genes were identified. The full-length, polycystin-1, lipoxygenase, alpha-toxin (PLAT) and lipoxygenase domain sequences from orthologous and paralogous genes exhibited a signature of purifying selection. However, purifying selection influenced orthologues more than paralogues, indicating greater functional conservation of orthologues than paralogues. Neutrality and effective number of codons plot results showed that natural selection primarily shapes codon usage, except for C. arietinum, L. japonicas and M. truncatula LOX genes. GCG, ACG, UCG, CGG and CCG codons exhibited low relative synonymous codon usage (RSCU) values, while CCA, GGA, GCU, CUU and GUU had high RSCU values, indicating that the latter codons are strongly preferred. LOX expression patterns differed significantly between wild-type peanut and cultivated peanut infected with Aspergillus flavus, which could explain the divergent disease resistance of wild progenitor and cultivars.

Published

2016

27. Annotation of Trait Loci on Integrated Genetic Maps of Arachis Species

Author

Hui Wang, Moses Osiru, Jianping Wang, Xingjun Wang, Jing Chen, Baozhu Guo, Pawan Khera, F. Waliyar, Mei Yuan, Xinyou Zhang, Chuan T. Wang, Ze Peng, Hari Kishan Sudini, Vincent Vadez, and Rajeev K. Varshney

Subjects

Genetics, Expressed sequence tag, Arachis, biology, Gene mapping, Botany, Leaf spot, Genomics, Quantitative trait locus, biology.organism_classification, Association mapping, Arachis hypogaea

Abstract

Peanut or groundnut (Arachis hypogaea L.) is second, behind soybean, in the world’s legume oilseed market. In 2012, global production was 41.2metric tons from an area of 24.7million hectares (FAOSTAT, 2014). Yield of peanut under stressed environments is an ultimate goal of improvement for enhanced production as it is usually susceptible to a range of abiotic and biotic stresses, such as drought, tomato spotted wilt virus (TSWV), early leaf spot (ELS) and late leaf spot (LLS), nematodes, rust, and aflatoxin contamination (Guo et al., 2012a). However, cultivated peanut is an allotetraploid (2n=4x=40) with a large genome, which greatly complicates interpretation of genomic data compared with the diploid wild relatives (2n=2x=20) (Guo et al., 2013). It is difficult to transfer alleles from wild species to cultivated peanuts (Simpson, 1991). For the last ten years, extensive efforts in the area of peanut genomics have resulted in a large number of genetic and genomic resources such as mapping populations, expressed sequence tags (ESTs), a wide range of molecular markers, transcriptome and proteomics (Guo et al., 2013; Katam et al., 2014; Varshney et al., 2013). These genetic and genomic resources have been successfully used to construct genetic maps, to identify quantitative trait loci (QTLs) of traits of Author's personal copy 164 Peanuts Peanuts, First Edition, 2016, 163-207 interest, and to conduct marker-assisted selection and association mapping for peanut improvement (Pandey et al., 2014a).

Published

2016

28. The genome sequences of Arachis duranensis and Arachis ipaensis, the diploid ancestors of cultivated peanut

Author

Lutz Froenicke, David J. Bertioli, Andrew Farmer, Ethalinda K. S. Cannon, Sudhansu Dash, Josh Clevenger, Brian E. Scheffler, Baozhu Guo, Xu Xun, Mark D. Burow, Noelle A. Barkley, Brian Abernathy, Steven B. Cannon, Xinyou Zhang, Boshou Liao, Kenta Shirasawa, Peggy Ozias-Akins, Bruna Vidigal, Chad E. Niederhuth, Pooja E. Umale, Dongying Gao, Xin Liu, Alexander Kozik, H. Thomas Stalker, Rajeev K. Varshney, Scott A. Jackson, Kyung Do Kim, Soraya C. M. Leal-Bertioli, Ye Chu, Richard W Michelmore, Longhui Ren, Ana Claudia Guerra Araujo, Robert J. Schmitz, Xingjun Wang, Márcio C. Moretzsohn, Wei Huang, Guodong Huang, Sachiko Isobe, and Patricia M. Guimarães

Subjects

0106 biological sciences, 0301 basic medicine, Arachis, Genetic Linkage, Population, Genomics, 01 natural sciences, Genome, Synteny, Chromosomes, Plant, Arachis duranensis, Evolution, Molecular, 03 medical and health sciences, Arachis ipaensis, Botany, Genetics, education, education.field_of_study, Ploidies, biology, food and beverages, Molecular Sequence Annotation, Sequence Analysis, DNA, DNA Methylation, biology.organism_classification, Arachis hypogaea, 030104 developmental biology, DNA Transposable Elements, Ploidy, Genome, Plant, 010606 plant biology & botany

Abstract

Cultivated peanut (Arachis hypogaea) is an allotetraploid with closely related subgenomes of a total size of ∼2.7 Gb. This makes the assembly of chromosomal pseudomolecules very challenging. As a foundation to understanding the genome of cultivated peanut, we report the genome sequences of its diploid ancestors (Arachis duranensis and Arachis ipaensis). We show that these genomes are similar to cultivated peanut's A and B subgenomes and use them to identify candidate disease resistance genes, to guide tetraploid transcript assemblies and to detect genetic exchange between cultivated peanut's subgenomes. On the basis of remarkably high DNA identity of the A. ipaensis genome and the B subgenome of cultivated peanut and biogeographic evidence, we conclude that A. ipaensis may be a direct descendant of the same population that contributed the B subgenome to cultivated peanut.

Published

2015

29. Analysis of genetic diversity and population structure of peanut cultivars and breeding lines from China, India and the US using simple sequence repeat markers

Author

Hui, Wang, Pawan, Khera, Bingyan, Huang, Mei, Yuan, Ramesh, Katam, Weijian, Zhuang, Karen, Harris-Shultz, Kim M, Moore, Albert K, Culbreath, Xinyou, Zhang, Rajeev K, Varshney, Lianhui, Xie, and Baozhu, Guo

Subjects

Genetic Markers, China, Principal Component Analysis, Polymorphism, Genetic, Arachis, Genetic Variation, India, Breeding, United States, Genetics, Population, Cluster Analysis, Factor Analysis, Statistical, Phylogeny, Microsatellite Repeats

Abstract

Cultivated peanut is grown worldwide as rich-source of oil and protein. A broad genetic base is needed for cultivar improvement. The objectives of this study were to develop highly informative simple sequence repeat (SSR) markers and to assess the genetic diversity and population structure of peanut cultivars and breeding lines from different breeding programs in China, India and the US. A total of 111 SSR markers were selected for this study, resulting in a total of 472 alleles. The mean values of gene diversity and polymorphic information content (PIC) were 0.480 and 0.429, respectively. Country-wise analysis revealed that alleles per locus in three countries were similar. The mean gene diversity in the US, China and India was 0.363, 0.489 and 0.47 with an average PIC of 0.323, 0.43 and 0.412, respectively. Genetic analysis using the STRUCTURE divided these peanut lines into two populations (P1, P2), which was consistent with the dendrogram based on genetic distance (G1, G2) and the clustering of principal component analysis. The groupings were related to peanut market types and the geographic origin with a few admixtures. The results could be used by breeding programs to assess the genetic diversity of breeding materials to broaden the genetic base and for molecular genetics studies.

Published

2015

30. Advances in Arachis genomics for peanut improvement

Author

Peggy Ozias-Akins, Richard W Michelmore, E. S. Monyo, Pasupuleti Janila, X Liang, Baozhu Guo, Hari D. Upadhyaya, Douglas R. Cook, Shyam N. Nigam, Manish K. Pandey, Patricia M. Guimarães, David J. Bertioli, Xinyou Zhang, and Rajeev K. Varshney

Subjects

Molecular breeding, Genetics, Genetic diversity, Arachis, biology, Population, food and beverages, Population genetics, Chromosome Mapping, Bioengineering, Genomics, Sequence Analysis, DNA, biology.organism_classification, Genes, Plant, Applied Microbiology and Biotechnology, Polymorphism, Single Nucleotide, Genetic architecture, Allele, Transcriptome, Functional genomics, Genome, Plant, Biotechnology, Microsatellite Repeats

Abstract

Peanut genomics is very challenging due to its inherent problem of genetic architecture. Blockage of gene flow from diploid wild relatives to the tetraploid; cultivated peanut, recent polyploidization combined with self pollination, and the narrow genetic base of the primary genepool have resulted in low genetic diversity that has remained a major bottleneck for genetic improvement of peanut. Harnessing the rich source of wild relatives has been negligible due to differences in ploidy level as well as genetic drag and undesirable alleles for low yield. Lack of appropriate genomic resources has severely hampered molecular breeding activities, and this crop remains among the less-studied crops. The last five years, however, have witnessed accelerated development of genomic resources such as development of molecular markers, genetic and physical maps, generation of expressed sequenced tags (ESTs), development of mutant resources, and functional genomics platforms that facilitate the identification of QTLs and discovery of genes associated with tolerance/resistance to abiotic and biotic stresses and agronomic traits. Molecular breeding has been initiated for several traits for development of superior genotypes. The genome or at least gene space sequence is expected to be available in near future and this will further accelerate use of biotechnological approaches for peanut improvement.

Published

2011

31. The genome sequence of segmental allotetraploid peanut Arachis hypogaea

Author

Richard W Michelmore, Brian Abernathy, Melanie Pham, Jacqueline D. Campbell, Sergio Sebastián Samoluk, Ethalinda K. S. Cannon, Marie Mirouze, Ziqi Sun, Scott A. Jackson, Jane Grimwood, Zheng Zheng, Christopher Lui, C. Corley Holbrook, Longhui Ren, Manish K. Pandey, Ye Chu, Kenta Shirasawa, Guillermo Seijo, Sudhansu Dash, Carolina Chavarro, Connor Cameron, Xinyou Zhang, Gaurav Agarwal, Lutz Froenicke, Sophie Lanciano, Andrew Farmer, Soraya C. M. Leal-Bertioli, Nathan T. Weeks, David J. Bertioli, Walid Korani, Senjuti Sinharoy, Olga Dudchenko, Carolina Ballén-Taborda, Rajeev K. Varshney, Annapurna Chitikineni, Jerry Jenkins, Steven B. Cannon, Peggy Ozias-Akins, Erez Lieberman Aiden, Moaine El Baidouri, Márcio C. Moretzsohn, Jeremy Schmutz, Jin Hee Shin, Wei Huang, Dongying Gao, Josh Clevenger, Brian E. Scheffler, Baozhu Guo, Kyung Do Kim, Avinash Sreedasyam, DOE Joint Genome Institute [Walnut Creek], Baylor College of Medicine (BCM), Baylor University, University of Georgia [USA], Laboratoire Génome et développement des plantes (LGDP), Université de Perpignan Via Domitia (UPVD)-Centre National de la Recherche Scientifique (CNRS), Universität Bern [Bern] (UNIBE), Diversité, adaptation, développement des plantes (UMR DIADE), Centre de Coopération Internationale en Recherche Agronomique pour le Développement (Cirad)-Université de Montpellier (UM)-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD [France-Sud]), Genome Center and Department of Plant Sciences, University of California (UC), Purdue University [West Lafayette], United States Department of Energy, Université de Berne, Institut de Recherche pour le Développement (IRD [France-Sud])-Centre National de la Recherche Scientifique (CNRS)-Université de Montpellier (UM)-Centre de Coopération Internationale en Recherche Agronomique pour le Développement (Cirad), University of California, DAVID J. BERTIOLI, UNIVERSITY OF GEORGIA, USA, JERRY JENKINS, HUDSONALPHA INSTITUTE OF BIOTECHNOLOGY, USA, JOSH CLEVENGER, UNIVERSITY OF GEORGIA, USA, OLGA DUDCHENKO, BAYLOR COLLEGE OF MEDICINE, HOUSTON, USA, DONGYING GAO, UNIVERSITY OF GEORGIA, USA, GUILLERMO SEIJO, CONICETUNNE, ARGENTINA, SORAYA C. M. LEAL-BERTIOLI, UNIVERSITY OF GEORGIA, USA, LONGHUI REN, IOWA STATE UNIVERSITY, USA, ANDREW D. FARMER, NATIONAL CENTER FOR GENOME RESOURCES, USA, MANISH K. PANDEY, INTERNATIONAL CROPS RESEARCH INSTITUTE FOR THE SEMI-ARID TROPICS (ICRISAT), INDIA, SERGIO S. SAMOLUK, INSTITUTO DE BOTÁNICA DEL NORDESTE (CONICETUNNE), ARGENTINA, BRIAN ABERNATHY, UNIVERSITY OF GEORGIA, USA, GAURAV AGARWAL, UNIVERSITY OF GEORGIA, USA, CAROLINA BALLÉN-TABORDA, UNIVERSITY OF GEORGIA, USA, CONNOR CAMERON, NATIONAL CENTER FOR GENOME RESOURCES, USA, JACQUELINE CAMPBELL, IOWA STATE UNIVERSITY, USA, CAROLINA CHAVARRO, UNIVERSITY OF GEORGIA, USA, ANNAPURNA CHITIKINENI, INTERNATIONAL CROPS RESEARCH INSTITUTE FOR THE SEMI-ARID TROPICS (ICRISAT), INDIA, YE CHU, UNIVERSITY OF GEORGIA, USA, SUDHANSU DASH, NATIONAL CENTER FOR GENOME RESOURCES, USA, MOAINE EL BAIDOURI, UMR5096, FRANCE, BAOZHU GUO, CROP PROTECTION AND MANAGEMENT RESEARCH UNIT, USA, WEI HUANG, IOWA STATE UNIVERSITY, USA, KYUNG DO KIM, UNIVERSITY OF GEORGIA, USA, WALID KORANI, UNIVERSITY OF GEORGIA, USA, SOPHIE LANCIANO, UNIVERSITÉ DE PERPIGNAN, FRANCE, CHRISTOPHER G. LUI, BAYLOR COLLEGE OF MEDICINE, USA, MARIE MIROUZE, UNIVERSITÉ DE PERPIGNAN, FRANCE, MARCIO DE CARVALHO MORETZSOHN, Cenargen, MELANIE PHAM, BAYLOR COLLEGE OF MEDICINE, USA, JIN HEE SHIN, UNIVERSITY OF GEORGIA, USA, KENTA SHIRASAWA, KAZUSA DNA RESEARCH INSTITUTE, JAPAN, SENJUTI SINHAROY, NATIONAL INSTITUTE OF PLANT GENOME RESEARCH, INDIA, AVINASH SREEDASYAM, HUDSONALPHA INSTITUTE OF BIOTECHNOLOGY, USA, NATHAN T. WEEKS, US DEPARTMENT OF AGRICULTURE AGRICULTURAL RESEARCH SERVICE, USA, XINYOU ZHANG, HENAN ACADEMY OF AGRICULTURAL SCIENCES, CHINA, ZHENG ZHENG, HENAN ACADEMY OF AGRICULTURAL SCIENCES, CHINA, ZIQI SUN, HENAN ACADEMY OF AGRICULTURAL SCIENCES, CHINA, LUTZ FROENICKE, UNIVERSITY OF CALIFORNIA, DAVIS, USA, EREZ L. AIDEN, BAYLOR COLLEGE OF MEDICINE, USA, RICHARD MICHELMORE, UNIVERSITY OF CALIFORNIA, DAVIS, USA, RAJEEV K. VARSHNEY, INTERNATIONAL CROPS RESEARCH INSTITUTE FOR THE SEMI-ARID TROPICS (ICRISAT), INDIA, C. CORLEY HOLBROOK, US DEPARTMENT OF AGRICULTURE AGRICULTURAL RESEARCH SERVICE, USA, ETHALINDA K. S. CANNON, IOWA STATE UNIVERSITY, USA, BRIAN E. SCHEFFLER, US DEPARTMENT OF AGRICULTURE AGRICULTURAL RESEARCH SERVICE, USA, JANE GRIMWOOD, HUDSONALPHA INSTITUTE OF BIOTECHNOLOGY, USA, PEGGY OZIAS-AKINS, UNIVERSITY OF GEORGIA, USA, STEVEN B. CANNON, US DEPARTMENT OF AGRICULTURE AGRICULTURAL RESEARCH SERVICE, USA, SCOTT A. JACKSON, UNIVERSITY OF GEORGIA, USA, and JEREMY SCHMUTZ, HUDSONALPHA INSTITUTE OF BIOTECHNOLOGY, USA.

Subjects

Arachis, [SDV]Life Sciences [q-bio], Medical and Health Sciences, Genome, Domestication, 0302 clinical medicine, Gene Expression Regulation, Plant, ComputingMilieux_MISCELLANEOUS, Recombination, Genetic, 2. Zero hunger, Peanuts, 0303 health sciences, purl.org/becyt/ford/4.4 [https], food and beverages, Biodiversity, Biological Sciences, GENOME, Phenotype, Biotecnología Agrícola y Biotecnología Alimentaria, ARACHIS HYPOGAEA, Ploidy, SEGMENTAL ALLOTETRAPLOID, Genome, Plant, Crops, Agricultural, Plant genetics, DNA, Plant, Evolution, Biotecnología Agropecuaria, Argentina, Crops, Genomics, Biology, Chromosomes, Chromosomes, Plant, Evolution, Molecular, Polyploidy, 03 medical and health sciences, Genetic, Species Specificity, Polyploid, Genetics, Hybridization, 030304 developmental biology, Whole genome sequencing, Agricultural, Hypogaea, fungi, Molecular, Genetic Variation, Plant, DNA, DNA Methylation, biology.organism_classification, Base sequence, Recombination, Arachis hypogaea L, Arachis hypogaea, Tetraploidy, Gene Expression Regulation, CIENCIAS AGRÍCOLAS, Evolutionary biology, Hybridization, Genetic, purl.org/becyt/ford/4 [https], 030217 neurology & neurosurgery, Developmental Biology

Abstract

Like many other crops, the cultivated peanut (Arachis hypogaea L.) is of hybrid origin and has a polyploid genome that contains essentially complete sets of chromosomes from two ancestral species. Here we report the genome sequence of peanut and show that after its polyploid origin, the genome has evolved through mobile-element activity, deletions and by the flow of genetic information between corresponding ancestral chromosomes (that is, homeologous recombination). Uniformity of patterns of homeologous recombination at the ends of chromosomes favors a single origin for cultivated peanut and its wild counterpart A. monticola. However, through much of the genome, homeologous recombination has created diversity. Using new polyploid hybrids made from the ancestral species, we show how this can generate phenotypic changes such as spontaneous changes in the color of the flowers. We suggest that diversity generated by these genetic mechanisms helped to favor the domestication of the polyploid A. hypogaea over other diploid Arachis species cultivated by humans. Fil: Bertioli, David J.. University of Georgia; Estados Unidos Fil: Jenkins, Jerry. Hudsonalpha Institute For Biotechnology; Estados Unidos Fil: Clevenger, Josh. University of Georgia; Estados Unidos Fil: Dudchenko, Olga. The Center for Genome Architecture; Estados Unidos Fil: Gao, Dongying. University of Georgia; Estados Unidos Fil: Seijo, José Guillermo. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - Nordeste. Instituto de Botánica del Nordeste. Universidad Nacional del Nordeste. Facultad de Ciencias Agrarias. Instituto de Botánica del Nordeste; Argentina Fil: Leal Bertioli, Soraya C.M.. Universidad Nacional del Nordeste; Argentina Fil: Ren, Longhui. University of Georgia; Estados Unidos Fil: Farmer, Andrew D.. University of Georgia; Estados Unidos Fil: Pandey, Manish K.. Center of Excellence in Genomics & Systems Biology, International Crops Research Institute for the Semi-Arid Tropics (ICRISAT); India Fil: Samoluk, Sergio Sebastián. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - Nordeste. Instituto de Botánica del Nordeste. Universidad Nacional del Nordeste. Facultad de Ciencias Agrarias. Instituto de Botánica del Nordeste; Argentina Fil: Abernathy, Brian. University of Georgia; Estados Unidos Fil: Agarwal, Gaurav. University of Georgia; Estados Unidos Fil: Ballén Taborda, Carolina. University of Georgia; Estados Unidos Fil: Cameron, Connor. National Center for Genome Resources; Estados Unidos Fil: Campbell, Jacqueline. University of Iowa; Estados Unidos Fil: Chavarro, Carolina. University of Georgia; Estados Unidos Fil: Chitikineni, Annapurna. Center of Excellence in Genomics & Systems Biology, International Crops Research Institute for the Semi-Arid Tropics (ICRISAT); India Fil: Chu, Ye. University of Georgia; Estados Unidos Fil: Dash, Sudhansu. National Center for Genome Resources; Estados Unidos Fil: El Baidouri, Moaine. Centre National de la Recherche Scientifique; Francia Fil: Guo, Baozhu. University of Georgia; Estados Unidos Fil: Huang, Wei. University of Iowa; Estados Unidos Fil: Kim, Kyung Do. University of Georgia; Estados Unidos. Corporate R&D, LG Chem; Corea del Sur Fil: Korani, Walid. University of Georgia; Estados Unidos Fil: Lanciano, Sophie. Centre National de la Recherche Scientifique; Francia Fil: Lui, Christopher G.. The Center for Genome Architecture; Estados Unidos Fil: Mirouze, Marie. Centre National de la Recherche Scientifique; Francia Fil: Moretzsohn, Márcio C.. Ministerio da Agricultura Pecuaria e Abastecimento de Brasil. Empresa Brasileira de Pesquisa Agropecuaria; Brasil Fil: Pham, Melanie. The Center for Genome Architecture; Estados Unidos Fil: Shin, Jin Hee. University of Georgia; Estados Unidos Fil: Shirasawa, Kenta Shirasawa. Department of Frontier Research and Development, Kazusa DNA Research Institute; Japón Fil: Sinharoy, Senjuti. National Institute of Plant Genome Research; India Fil: Sreedasyam, Avinash. Hudson Alpha Institute of Biotechnology; Estados Unidos Fil: Weeks, Nathan T.. United States Department of Agriculture; Estados Unidos Fil: Zhang, Xinyou. Henan Academy of Agricultural Sciences; China Fil: Zheng, Zheng. Henan Academy of Agricultural Sciences; China Fil: Sun, Ziqi. Henan Academy of Agricultural Sciences; China Fil: Froenicke, Lutz. University of California at Davis; Estados Unidos Fil: Aiden, Erez L.. The Center for Genome Architecture; Estados Unidos Fil: Michelmore, Richard. University of California at Davis; Estados Unidos Fil: Varshney, Rajeev K.. Center of Excellence in Genomics & Systems Biology, International Crops Research Institute for the Semi-Arid Tropics (ICRISAT); India Fil: Holbrook, C. Corley. United States Department of Agriculture; Estados Unidos Fil: Cannon, Ethalinda K. S.. University of Iowa; Estados Unidos Fil: Scheffler, Brian E.. United States Department of Agriculture; Estados Unidos Fil: Grimwood, Jane. Hudson Alpha Institute of Biotechnology; Estados Unidos Fil: Ozias-Akins, Peggy. University of Georgia; Estados Unidos Fil: Cannon, Steven B.. United States Department of Agriculture; Estados Unidos Fil: Jackson, Scott A.. University of Georgia; Estados Unidos Fil: Schmutz, Jeremy. Hudson Alpha Institute of Biotechnology; Estados Unidos

32. Development of an oligonucleotide dye solution facilitates high throughput and cost-efficient chromosome identification in peanut.

Author

Du, Pei, Cui, Caihong, Liu, Hua, Fu, Liuyang, Li, Lina, Dai, Xiaodong, Qin, Li, Wang, Siyu, Han, Suoyi, Xu, Jing, Liu, Bing, Huang, Bingyan, Tang, Fengshou, Dong, Wenzhao, Qi, Zengjun, and Zhang, Xinyou

Subjects

KARYOTYPES, PEANUTS, CHROMOSOMES, FLUORESCENCE in situ hybridization, NUCLEIC acid probes, X chromosome, ARACHIS

Abstract

Background: Development of oligonucleotide probes facilitates chromosome identification via fluorescence in situ hybridization (FISH) in many organisms. Results: We report a high throughput and economical method of chromosome identification based on the development of a dye solution containing 2 × saline-sodium citrate (SSC) and oligonucleotide probes. Based on the concentration, staining time, and sequence effects of oligonucleotides, an efficient probe dye of peanut was developed for chromosome identification. To validate the effects of this solution, 200 slides derived from 21 accessions of the cultivated peanut and 30 wild Arachis species were painted to identify Arachis genomes and establish karyotypes. The results showed that one jar of dye could be used to paint 10 chromosome preparations and recycled at least 10 times to efficiently dye more than 100 slides. The A, B, K, F, E, and H genomes showed unique staining karyotype patterns and signal colors. Conclusions: Based on the karyotype patterns of Arachis genomes, we revealed the relationships among the A, B, K, F, E, and H genomes in genus Arachis, and demonstrated the potential for adoption of this oligonucleotide dye solution in practice. [ABSTRACT FROM AUTHOR]

Published

2019

33. Proteomics analysis reveals differentially activated pathways that operate in peanut gynophores at different developmental stages

Author

Tingting Li, Han Xia, Jiangshan Wang, Li Aiqin, Changsheng Li, Shuzhen Zhao, Lei Hou, Chuanzhi Zhao, Xingjun Wang, and Xinyou Zhang

Subjects

Arachis, Geocarpy, Proteome, biology, Gravitropism, food and beverages, Plant Science, biology.organism_classification, Proteomics, Arachis hypogaea, Transcriptome, Expansin, Gene Expression Regulation, Plant, Tandem Mass Spectrometry, Seeds, Botany, Research Article, Chromatography, Liquid, Plant Proteins

Abstract

Background Cultivated peanut (Arachis hypogaea. L) is one of the most important oil crops in the world. After flowering, the peanut plant forms aboveground pegs (gynophores) that penetrate the soil, giving rise to underground pods. This means of reproduction, referred to as geocarpy, distinguishes peanuts from most other plants. The molecular mechanism underlying geocarpic pod development in peanut is poorly understood. Results To gain insight into the mechanism of geocarpy, we extracted proteins from aerial gynophores, subterranean unswollen gynophores, and gynophores that had just started to swell into pods. We analyzed the protein profiles in each of these samples by combining 1 DE with nanoLC-MS/MS approaches. In total, 2766, 2518, and 2280 proteins were identified from the three samples, respectively. An integrated analysis of proteome and transcriptome data revealed specifically or differentially expressed genes in the different developmental stages at both the mRNA and protein levels. A total of 69 proteins involved in the gravity response, light and mechanical stimulus, hormone biosynthesis, and transport were identified as being involved in geocarpy. Furthermore, we identified 91 genes that were specifically or abundantly expressed in aerial gynophores, including pectin methylesterase and expansin, which were presumed to promote the elongation of aerial gynophores. In addition, we identified 35 proteins involved in metabolism, defense, hormone biosynthesis and signal transduction, nitrogen fixation, and transport that accumulated in subterranean unswellen gynophores. Furthermore, 26 specific or highly abundant proteins related to fatty acid metabolism, starch synthesis, and lignin synthesis were identified in the early swelling pods. Conclusions We identified thousands of proteins in the aerial gynophores, subterranean gynophores, and early swelling pods of peanut. This study provides the basis for examining the molecular mechanisms underlying peanut geocarpy pod development. Electronic supplementary material The online version of this article (doi:10.1186/s12870-015-0582-6) contains supplementary material, which is available to authorized users.

34. High-resolution chromosome painting with repetitive and single-copy oligonucleotides in Arachis species identifies structural rearrangements and genome differentiation.

Author

Du, Pei, Li, Lina, Liu, Hua, Fu, Liuyang, Qin, Li, Zhang, Zhongxin, Cui, Caihong, Sun, Ziqi, Han, Suoyi, Xu, Jing, Dai, Xiaodong, Huang, Bingyan, Dong, Wenzhao, Tang, Fengshou, Zhuang, Lifang, Han, Yonghua, Qi, Zengjun, and Zhang, Xinyou

Subjects

ARACHIS, CHROMOSOMES, GENOMES, BIOLOGICAL tags, OLIGONUCLEOTIDES

Abstract

Background: Arachis contains 80 species that carry many beneficial genes that can be utilized in the genetic improvement of peanut (Arachis hypogaea L. 2n = 4x = 40, genome AABB). Chromosome engineering is a powerful technique by which these genes can be transferred and utilized in cultivated peanut. However, their small chromosomes and insufficient cytological markers have made chromosome identification and studies relating to genome evolution quite difficult. The development of efficient cytological markers or probes is very necessary for both chromosome engineering and genome discrimination in cultivated peanut. Results: A simple and efficient oligonucleotide multiplex probe to distinguish genomes, chromosomes, and chromosomal aberrations of peanut was developed based on eight single-stranded oligonucleotides (SSONs) derived from repetitive sequences. High-resolution karyotypes of 16 Arachis species, two interspecific F1 hybrids, and one radiation-induced M1 plant were then developed by fluorescence in situ hybridization (FISH) using oligonucleotide multiplex, 45S and 5S rDNAs, and genomic in situ hybridization (GISH) using total genomic DNA of A. duranensis (2n = 2x = 20, AA) and A. ipaënsis (2n = 2x = 20, BB) as probes. Genomes, chromosomes, and aberrations were clearly identifiable in the established karyotypes. All eight cultivars had similar karyotypes, whereas the eight wild species exhibited various chromosomal variations. In addition, a chromosome-specific SSON library was developed based on the single-copy sequence of chromosome 6A of A. duranensis. In combination with repetitive SSONs and rDNA FISH, the single-copy SSON library was applied to identify the corresponding A3 chromosome in the A. duranensis karyotype. Conclusions: The development of repetitive and single-copy SSON probes for FISH and GISH provides useful tools for the differentiation of chromosomes and identification of structural chromosomal rearrangement. It facilitates the development of high-resolution karyotypes and detection of chromosomal variations in Arachis species. To our knowledge, the methodology presented in this study demonstrates for the first time the correlation between a sequenced chromosome region and a cytologically identified chromosome in peanut. [ABSTRACT FROM AUTHOR]

Published

2018

35. Marker-assisted backcrossing to improve seed oleic acid content in four elite and popular peanut (Arachis hypogaea L.) cultivars with high oil content.

Author

Bingvan Huang, Feiyan Qi, Ziqi Sun, Lijuan Miao, Zhongxin Zhang, Hua Liu, Yuanjin Fang, Wenzhao Dong, Fengshou Tang, Zheng Zheng, and Xinyou Zhang

Subjects

*PEANUTS, *OLEIC acid, *ARACHIS, *SINGLE nucleotide polymorphisms, *SEED quality, *SEEDS, *RAPESEED oil

Abstract

High oleic acid composition is an important determinant of seed quality in peanut (Arachis hypogaea) in regard to its nutritional benefits for human health and prolonged shelf-life for peanut products. To improve the oleic acid content of popular peanut cultivars in China, four peanut cultivars of different market types were hybridized with high-oleic-acid donors and backcrossed for four generations as recurrent parents using fad2 marker-assisted backcross selection. Seed quality traits in advanced generations derived by selling w'ere assessed using near-infrared reflectance spectroscopy for detection of oleic acid and Kompetitive allele-specific PCR (KASP) screening of fad2 mutant markers. Twenty-four high-oleic-acid lines of BC4F4 and BC4F5 populations, with morphological features and agronomic traits similar to those of the recurrent parents, were obtained within 5 years. The genetic backgrounds of BC4F5 lines were estimated using the KASP assay, which revealed the genetic background recovery rate was 79.49%—92.31 %. The superior lines raised are undergoing a multi-location test for cultivar registration and release. To our knowledge, this is the first application of single nucleotide polymorphism markers based on the high-throughput and cost-effective KASP assay for detection of fad2 mutations and genetic background evaluation in a peanut breeding program. [ABSTRACT FROM AUTHOR]

Published

2019

36. Advances in Arachis genomics for peanut improvement

Author

Pandey, Manish K., Monyo, Emmanuel, Ozias-Akins, Peggy, Liang, Xuanquiang, Guimarães, Patricia, Nigam, Shyam N., Upadhyaya, Hari D., Janila, Pasupuleti, Zhang, Xinyou, Guo, Baozhu, Cook, Douglas R., Bertioli, David J., Michelmore, Richard, and Varshney, Rajeev K.

Subjects

*ARACHIS, *GENOMICS, *PEANUTS, *PLANT genetic engineering, *COMPETITION (Biology), *MOLECULAR cloning, *BIOTECHNOLOGY

Abstract

Abstract: Peanut genomics is very challenging due to its inherent problem of genetic architecture. Blockage of gene flow from diploid wild relatives to the tetraploid; cultivated peanut, recent polyploidization combined with self pollination, and the narrow genetic base of the primary genepool have resulted in low genetic diversity that has remained a major bottleneck for genetic improvement of peanut. Harnessing the rich source of wild relatives has been negligible due to differences in ploidy level as well as genetic drag and undesirable alleles for low yield. Lack of appropriate genomic resources has severely hampered molecular breeding activities, and this crop remains among the less-studied crops. The last five years, however, have witnessed accelerated development of genomic resources such as development of molecular markers, genetic and physical maps, generation of expressed sequenced tags (ESTs), development of mutant resources, and functional genomics platforms that facilitate the identification of QTLs and discovery of genes associated with tolerance/resistance to abiotic and biotic stresses and agronomic traits. Molecular breeding has been initiated for several traits for development of superior genotypes. The genome or at least gene space sequence is expected to be available in near future and this will further accelerate use of biotechnological approaches for peanut improvement. [Copyright &y& Elsevier]

Published

2012