Genomic-Led Potato Breeding for Increasing Genetic Gains: Achievements and Outlook-Crop Breeding, Genetics and Genomics-CSCIED科技核心评价数据库-手机版

Genomic-Led Potato Breeding for Increasing Genetic Gains: Achievements and Outlook

Genomic-Led Potato Breeding for Increasing Genetic Gains: Achievements and Outlook

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DOI	10.20900/cbgg20200010
刊名	Crop Breeding, Genetics and Genomics CBGG
年，卷(期)	2020, 2(2)
作者	Rodomiro Ortiz*,
作者单位	Department of Plant Breeding (VF), Swedish University of Agricultural Sciences (SLU), Sundsvagen 10 Box 101, SE2053 Lomma, Sweden ;
Abstract	Potato is the third most important crop, after rice and wheat, in human diets worldwide. Genetic gains due to its crossbreeding for productivity per se appear to be stagnant in this tetraploid crop. Its genetic enhancement needs to overcome inherent barriers such as ploidy, outcrossing and heterozygosity. Pathogens and pests affect potato because they may infect the entire plant, including stems, leaves and tubers, thus leading to significant tuber yield loss. Hence, host plant resistance breeding remains key for improving the productivity of this crop. This article reviews recent research advances relevant to potato breeding emphasizing genomic resources, methods and tools for genetic analysis, mapping of genes and quantitative trait loci, and genomic prediction of breeding values (or genomic selection) for population improvement. In this regard, association genetics has provided insights onto genetic architecture and inheritance of priority breeding traits, as well as tagging them to DNA markers for their further use as aids for indirect selection. Early research results show the feasibility of genomic selection as a new breeding approach for a tetrasomic polyploid such as potato. This manuscript also highlights the proposed inbred line strategy for producing diploid F1 true potato seed hybrids, and how its use may speed up and increase genetic gains in potato breeding; as well as promoting alleles through gene editing. The paper ends proposing a new interploidy breeding approach considering ploidy manipulations and incorporating genomic selection and gene editing for both population improvement and cultivar development.
KeyWord	Solanum tuberosum; cultivar development; F1 true seed hybrid; gene editing; genomic selection; heterosis; polyploidy; tetrasomic inheritance
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相关文献

1.van Merrienboer S. World potato map 2019: fries are on the menu globally. Amsterdam (The Netherlands): RaboResearch Food & Agribusiness; 2019.

2.Spooner DM, McLean K, Ramsay G, Waugh R, Bryan GJ. A single domestication for potato based on multilocus amplified fragment length polymorphism genotyping. Proc Natl Acad Sci U S A. 2005;102:14694-9.

3.Earle R. A brief history of that most noble tuber, the potato. 2019. Available from: https://lithub.com/a-brief-history-of-that-most-noble-tuber-the-potato/. Accessed 2019 Apr 1.

4.Hardigan MA, Laimbeer FPE, Newton L, Crisovan E, Hamilton JP, Vaillancourt B, et al. Genome diversity of tuber-bearing Solanum uncovers complex evolutionary history and targets of domestication in the cultivated potato. Proc Natl Acad Sci U S A. 2017;114(46):E9999-10008. doi: 10.1073/pnas.1714380114

5.Glendinning DR. Potato introductions and breeding up to the early 20th century. New Phytol. 1983;94:479-505.

6.van Berloo R, Hutten RCB, van Eck HJ, Visser RGF. An online potato pedigree database resource. Potato Res. 2007;50:45-57.

7.Li X, Xu J, Duan S, Bian C, Hu J, Shen H, et al. Pedigree-based deciphering of genome-wide conserved patterns in an elite potato parental line. Front Plant Sci. 2018;9:690. doi: 10.3389/fpls.2018.00690

8.Endelman JB, Schmitz Carley CA, Douches DS, Coombs JJ, Bizimungu B, De Jong WS, et al. Pedigree reconstruction with genome-wide Markers in potato. Am J Potato Res. 2017;94:184-90.

9.Andrivon D. Potato facing global challenges: how, how much, how well? Potato Res. 2017;60(3-4):389-400. doi: 10.1007/s11540-018-9386-z

10.Ortiz R, Mihovilovich E. Genetics and cytogenetics in potato. In: Campos H, Ortiz O, editors. The Potato Crop. Cham (Switzerland): Springer; 2020. p. 219-47.

11.Douches DS, Maas D, Jastrzebski K, Chase RW. Assessment of potato breeding progress in the USA over the last century. Crop Sci. 1996;36:1544-52.

12.Jansky S. Breeding for disease resistance in potato. Plant Breed Rev. 2000;19:69-155.

13.Mendoza HA, Haynes FL. Genetic relationship among potato cultivars grown in the United States. HortScience. 1974;9:328-30.

14.Slater AT, Wilson GM, Cogan NOI, Forster JW, Hayes BJ. Improving the analysis of low heritability complex traits for enhanced genetic gain in potato. Theor Appl Genet. 2014;127:809-20.

15.Muthoni J, Kabira J, Shimelis H, Melis R. Tetrasomic inheritance in cultivated potato and implications in conventional breeding. Austr J Crop Sci. 2015;9:185-90.

16.Mendoza HA, Haynes FL. Genetic basis of heterosis for yield in the autotetraploid potato. Theor Appl Genet. 1974;45:21-5.

17.Mendiburu AO, Peloquin SJ. The significance of 2N gametes in potato breeding. Theor Appl Genet. 1977;49:53-61.

18.Bonierbale MW, Plaisted RL, Tanksley SD. A test of the maximum heterozygosity hypothesis using molecular markers in tetraploid potatoes. Theor Appl Genet. 1993;86:481-91.

19.Zhang C, Wang P, Tang D, Yang Z, Lu F, Qi J, et al. The genetic basis of inbreeding depression in potato. Nat Genet. 2019;51:374-8.

20.Ortiz R, Simon P, Jansky S, Stelly D. Ploidy manipulation of the gametophyte, endosperm, and sporophyte in nature and for crop improvement—A tribute to Prof. Stanley J. Peloquin (1921–2008). Ann Bot. 2009;104:795-807.

21.Ehlenfeldt MK, Ortiz R. On the origins of endosperm dosage requirements in Solanum and other angiosperma genera. Sexual Plant Repr. 1995;8:189-96.

22.Bethke PC, Halterman DA, Jansky SH. Potato germplasm enhancement enters the genomics era. Agronomy. 2019;9:575. doi: 10.3390/agronomy9100575

23.The Potato Genome Sequencing Consortium. Genome sequence and analysis of the tuber crop potato. Nature. 2011;475:189-95.

24.Gálvez JH, Tai HH, Barkley NA, Gardner K, Ellis D, Strömvik MV. Understanding potato with the help of genomics. AIMS Agric Food. 2017;2:16-39.

25.Gutaker RM, Weiß CL, Ellis D, Anglin NL, Knapp S, Fernández-Alonso JL, et al. The origins and adaptation of European potatoes reconstructed from historical genomes. Nat Ecol Evol. 2019;3:1093-101.

26.Bonierbale MW, Plaisted RL, Tanksley SD, RFLP maps based on a common set of clones reveal modes of chromosomal evolution in potato and tomato. Genetics. 1988;120:1095-103.

27.Meyer S, Nagel A, Gebhardt C. PoMaMo—a comprehensive database for potato genome data. Nucleic Acids Res. 2005;33:D666-70.

28.Watanabe K. Potato genetics, genomics and applications. Breed Sci. 2015;65:53-68.

29.Anithakumari AM, Tang J, van Eck HJ, Visser RGF, Leunissen JAM, Vosman B, et al. A pipeline for high throughput detection and mapping of SNP from EST databases. Mol Breed. 2010;26:65-75.

30.Hamilton JP, Hansey CN, Whitty BR, Stoffel K, Massa AN, Van Deynze A, et al. Single nucleotide polymorphism discovery in elite North American potato germplasm. BMC Genomics. 2011;12:302. doi: 10.1186/1471-2164-12-302

31.Ellis D, Chavez O, Coombs J, Soto J, Gomez R, Douches D, et al. Application of the SolCAP 12K SNP array in fingerprinting and diversity analysis in the global in trust potato collection. Genome. 2018;61:523-37.

32.Vos PG, Uitdewilligen JGAML, Voorrips RE, Visser RGF, van Eck HJ. Development and analysis of 20k SNP array for potato (Solanum tuberosum): an insight into the breeding history. Theor Appl Genet. 2015;128:2387-401.

33.D’hoop BB, Paulo MJ, Kowitwanich K, Sengers M, Visser RGF, van Eck HJ, et al. Population structure and linkage disequilibrium unraveled in tetraploid potato. Theor Appl Genet. 2010;121:1151-70.

34.Stich B, Urbany C, Hoffman P, Gebhardt C. Population structure and linkage disequilibrium in diploid and tetraploid potato revealed by genome-wide high-density genotyping using the SolCAP SNP array. Plant Breed. 2013;132:718-24.

35.Sved JA. The relationship between diploid and tetraploid recombination frequencies. Heredity. 1964;19:585-96.

36.Motazedi E, de Ridder D, Finkers R, Baldwin S, Thomson S, Monaghan K, et al. TriPoly: a haplotype estimation for polyploids using sequencing data of related individuals. Bioinformatics. 2018;34:3864-72.

37.Shen J, Li Z, Chen J, Song Z, Zhou Z, Shi Y. SHEsisPlus, a toolset for genetic studies on polyploid species. Sci Rep. 2016;6:24095. doi: 10.1038/srep24095

38.Field DL, Broadhurst LM, Elliott CP, Young AG. Population assignment in autopolyploids. Heredity. 2017;109:389-401.

39.Amadeu RR, Cellon C, Olmstead JW, Garcia AFF, Resende MFR Jr, Muñoz PR. AGHmatrix: R package to construct relationship matrices for autotetraploid and diploid species: a blueberry example. Plant Genome. 2016;9:1-10. doi: 10.3835/plantgenome2016.01.0009

40.Hamilton MG, Ker RJ. Computation of the inverse additive relationship matrix for autopolyploid and multiple ploidy populations. Theor Appl Genet. 2018;131:851-60.

41.err RJ, Li L, Tier B, Dutkowski GW, McRae TA. Use of the numerator relationship matrix in genetic analysis of autopolyploid species. Theor Appl Genet. 2012;124:1271-82.

42.Faria SR. Genotipagem de polyplôides: um modelo de urnas e bolas
[PhD thesis]. São Paulo (Brazil): Instituto de Matemática e Estatística, Universidade São Paulo; 2012.

43.Schmitz Carley CA, Coombs JJ, Douches DS, Bethke PC, Palta JP, Novy RG, et al. Automated tetraploid genotype calling by hierarchical clustering. Theor Appl Genet. 2017;130:717-26.

44.Voorrips RE, Gort G, Vosman B. Genotype calling in tetraploid species from bi-allelic marker data using mixture models. BMC Bioinf. 2011;12:172. doi: 10.1186/1471-2105-12-172

45.Mollinari M, Garcia AAF. Linkage analysis and haplotype phasing in experimental autopolyploid populations with high ploidy level using hidden Markov models. G3. 2019;9:3297-314. doi: 10.1534/g3.119.400378

46.Simko I, Haynes KG, Jones RW. Assessment of linkage disequilibrium in potato genome with single nucleotide polymorphism markers. Genetics. 2006;173:2237-45.

47.Vos PG, Paulo MJ, Voorrips RE, Visser RGF, van Eck HJ, van Eeuwijk FA. Evaluation of LD decay and various LD decay estimators in simulated and SNP array data of tetraploid potato. Theor Appl Genet. 2017;130:123-35.

48.Bourke PM, Voorrips RE, Visser RGF, Maliepaard C. The double-reduction landscape in tetraploid potato as revealed by a high-density linkage map. Genetics. 2015;201:853-63.

49.Preedy KF, Hackett CA. A rapid marker ordering approach for high density genetic linkage maps in experimental autotetraploid populations using multidimensional scaling. Theor Appl Genet. 2016;129:2117-32.

50.Luo ZW, Hackett CA, Bradshaw JE, McNicol JW, Milbourne D. Construction of a genetic linkage map in tetraploid species using molecular markers. Genetics. 2001;157:1369-85.

51.Li J, Das K, Fu G, Tong C, Li Y, Tobias C, et al. EM algorithm for mapping quantitative trait loci in multivalent tetraploids. Intl J Plant Genom. 2010;2010:216547. doi: 10.1155/2010/216547

52.Rosyara UR, De Jong WS, Douches DS, Endelman JB. Software for genome-wide association studies in autopolyploids and its application to potato. Plant Genome. 2016;9:1-10. doi: 10.3835/plantgenome2015.08.0073

53.Bourke PM, Voorrips RE, Visser RGF, Maliepaard C. Tools for genetic studies in experimental populations of polyploids. Front Plant Sci. 2018;9:513. doi: 10.3389/fpls.2018.00513

54.Fischer RA. The theory of linkage in polysomic inheritance. Philos Trans R Soc London B. 1947;233:55-87.

55.Luo ZW, Zhang R, Kearsey MJ. Theoretical basis for genetic linkage analysis in autotetraploid species. Proc Natl Acad Sci U S A. 2004;101:7040-5.

56.Bourke PM, Voorrips RE, Kranenburg T, Jansen J, Visser RGF, Maliepaard M. Integrating haplotype specific linkage maps in tetraploid species using SNP markers. Theor Appl Genet. 2016;129:2211-26.

57.Bartkiewicz AM, Chilla F, Terefe-Ayana D, Lübeck J, Strahwald J, Tacke E, et al. Maximization of markers linked in coupling for tetraploid Potatoes via monoparental Haploids. Front. Plant Sci. 2018;9:620. doi: 10.3389/fpls.2018.00620

58.Jacobs JME, Van Eek HJ, Arens P, Verkerk-Bakker B, te Lintel Hekkert B, Bastiaanssen HJM, et al. A genetic map of potato (Solanum tuberosum) integrating molecular markers, including transposons, and classical markers. Theor Appl Genet. 1995;91:289-300.

59.Felcher KJ, Coombs JJ, Massa AN, Hansey CN, Hamilton JP, Veilleux RE, et al. Integration of two diploid potato linkage maps with the potato genome sequence. PLoS One. 2012;7:e36347. doi: 10.1371/journal.pone.0036347

60.Endelman JB, Jansky SH. Genetic mapping with an inbred line derived F2 population in potato. Theor Appl Genet. 2016;129:935-43.

61.Meijer D, Viquez-Zamora M, van Eck HJ, Hutten RCB, Su Y, Rothengatter R, et al. QTL mapping in diploid potato by using selfed progenies of the cross S. tuberosum × S. chacoense. Euphytica. 2018;214:121. doi: 10.1007/s10681-018-2191-6

62.Hackett CA, Milne I, Bradshaw JE, Luo Z. TetraploidMap for Windows: Linkage map construction and QTL mapping in autotetraploid species. J Hered. 2007;98:727-9.

63.McCord PH, Sosinski BR, Haynes KG, Clough ME, Yencho GC. Linkage mapping and QTL analysis of agronomic traits in tetraploid potato (Solanum tuberosum subsp. tuberosum). Crop Sci. 2011;51:771-85.

64.Rak K, Bethke PC, Palta JP. QTL mapping of potato chip color and tuber traits within an autotetraploid family. Mol Breed. 2017;37:15. doi: 10.1007/s11032-017-0619-7

65.Schumann MJ, Zeng Z-B, Clough ME, Yencho GC. Linkage map construction and QTL analysis for internal heat necrosis in autotetraploid potato. Theor Appl Genet. 2017;130:2045-56.

66.Strachan SM, Armstrong MR, Kaur A, Wright KM, Lim TY, Baker K, et al. Mapping the H2 resistance effective against Globodera pallida pathotype Pa1 in tetraploid potato. Theor Appl Genet. 2019;132:1283-94.

67.Vleeshouwers VGAA, Raffaele S, Vossen JH, Champouret N, Oliva R, Segretin ME, et al. Understanding and exploiting late blight resistance in the age of effectors. Annu. Rev. Plant Pathol. 2011;49:507-31.

68.Lenman M, Ali A, Mühlenbock P, Carlson Nilsson U, Liljeroth E, Champouret N, et al. Effector-driven marker development and cloning of resistance genes against Phytophthora infestans in potato breeding clone SW93-1015. Theor Appl Genet. 2016;129:105-15.

69.Jupe F, Witek K, Verweij W, Sliwka J, Pritchard L, Etherington GJ, et al. Resistance gene enrichment sequencing (RenSeq) enables reannotation of the NB-LRR gene family from sequenced plant genomes and rapid mapping of resistance loci in segregating populations. Plant J. 2013;76:530-44.

70.Li J, Lindqvist-Kreuze H, Tian Z, Liu J, Song B, Landeo J, et al. Conditional QTL underlying resistance to late blight in a diploid potato population. Theor Appl Genet. 2012;124:1339-50.

71.Sliwka J, Jakuczun H, Kamiñski P, Zimnoch-Guzowska E. Marker-assisted selection of diploid and tetraploid potatoes carrying Rpi-phu1, a major gene for resistance to Phytophthora infestans. J Appl Genet. 2010;51:133-40.

72.Colton LM, Groza HI, Wielgus SM, Jiang J. Marker-assisted selection for the broad-spectrum potato late blight resistance conferred by gene RB derived from a wild potato species. Crop Sci. 2006;46:589-94.

73.Halterman DA, Middleton G. Presence of the potato late blight resistance gene RB does not promote adaptive parasitism of Phytophthora infestans. Am J Plant Sci. 2012;3:360-7.

74.Jiang R, Li J, Tian Z, Du J, Armstrong M, Baker K, et al. Potato late blight field resistance from QTL dPI09c is conferred by the NB-LRR gene R8. J Exp Bot. 2018;69:1545-55.

75.Vossen JH, van Arkel G, Bergervoet M, Jo KR, Jacobsen E, Visser RGF. The Solanum demissum R8 late blight resistance gene is an Sw 5 homologue that has been deployed worldwide in late blight resistant varieties. Theor Appl Genet. 2016;129:1785-96.

76.Myles S, Peiffer J, Brown PJ, Ersoz ES, Zhang Z, Costich DE, et al. Association mapping: critical considerations shift from genotyping to experimental design. Plant Cell. 2009;21:2194-202.

77.D’hoop BB, Paulo MJ, Visser RGF, van Eck HJ, van Eeuwijk FA. Phenotypic analyses of multi-environment data for two diverse tetraploid potato collections: comparing an academic panel with an industrial panel. Potato Res. 2011;54:157-81.

78.Stich B, Melchinger A. Comparison of mixed-model approaches for association mapping in rapeseed, potato, sugar beet, maize, and Arabidopsis. BMC Genomics. 2009;10:94. doi: 10.1186/1471-2164-10-94

79.Gebhardt C, Ballvora A, Walkemeier B, Oberhagemann P, Schuler K. Assessing genetic potential in germplasm collections of crop plants by marker-trait association: a case study for potatoes with quantitative variation of resistance to late blight and maturity type. Mol Breed. 2004;13:93-102.

80.Malosetti M, Van der Linden CG, Vosman B, Van Eeuwijk FA. A mixed-model approach to association mapping using pedigree information with an illustration of resistance to Phytophthora infestans in potato. Genetics. 2007;175:879-89.

81.Simko I, Costanzo S, Haynes KG, Christ BJ, Jones RW. Linkage disequilibrium mapping of a Verticillium dahliae resistance quantitative trait locus in tetraploid potato (Solanum tuberosum) through a candidate gene approach. Theor Appl Genet. 2004;108:217-24.

82.Pajerowska-Mukhtar KM, Stich B, Achenbach U, Ballvora A, Lubeck J, Strahwald J, et al. Single nucleotide polymorphisms in the allene oxide synthase 2 gene are associated with field resistance to late blight in populations of tetraploid potato cultivars. Genetics. 2009;181:1115-27.

83.Mosquera T, Alvarez MF, Jiménez-Gómez JM, Muktar MS, Paulo MJ, Steinemann S, et al. Targeted and untargeted approaches unravel novel candidate genes and diagnostic SNPs for quantitative resistance of the potato (Solanum tuberosum L.) to Phytophthora infestans causing the late blight disease. PLoS One. 2016;11:e0156254. doi: 10.1371/journal.pone.0156254

84.Juyo Rojas DK, Soto Sedano JC, Ballvora A, Léon J, Mosquera Vásquez T. Novel organ-specific genetic factors for quantitative resistance to late blight. PLoS One. 2019;14:e0213818. doi: 10.1371/journal.pone.0213818

85.Lindqvist-Kreuze H, Gastelo M, Perez W, Forbes GA, de Koeyer D, Bonierbale M. Phenotypic stability and genome-wide association study of late blight resistance in potato genotypes adapted to the tropical highlands. Phytopathology. 2014;104:624-33.

86.Fischer M, Schreiber L, Colby T, Kuckenberg M, Tacke E, Hofferbert H-R, et al. Novel candidate genes influencing natural variation in potato tuber cold sweetening identified by comparative proteomics and association mapping. BMC Plant Biol. 2013;13:113. doi: 10.1186/1471-2229-13-113

87.Li L, Paulo M-J, Strahwald J, Lüubeck J, Hofferbert H-R, Tacke E, et al. Natural DNA variation at candidate loci is associated with potato chip color, tuber starch content, yield and starch yield. Theor Appl Genet. 2008;116:1167-81.

88.Li L, Strahwald J, Hofferbert HR, Lübeck J, Tacke E, Junghans H, et al. DNA variation at the invertase locus invGE/GF is associated with tuber quality traits in populations of potato breeding clones. Genetics. 2005;170:813-21.

89.D’hoop BB, Paulo MJ, Mank RA, van Eck HJ, van Eeuwijk FA. Association mapping of quality traits in potato (Solanum tuberosum L.). Euphytica. 2008;161:47-60.

90.Aliche EB, Oortwijn M, Theeuwen TMPJ, Bachem CWB, van Eck HJ, Visser RGF, et al. Genetic mapping of tuber size distribution and marketable tuber yield under drought stress in potatoes. Euphytica. 2019;215:186. doi: 10.1007/s10681-019-2508-0

91.Young ND, Tanksley SD. Restriction fragment length polymorphism maps and the concept of graphical genotypes. Theor Appl Genet. 1989;77:95-101.

92.van Eck HJ, Vos PG, Valkonen JPT, Uitdewilligen JGAML, Lensing H, de Vetten N, et al. Graphical genotyping as a method to map Ny(o,n)sto and Gpa5 using a reference panel of tetraploid potato cultivars. Theor Appl Genet. 2017;130:515-28.

93.Uitdewilligen JG, Wolters AM, D’hoop BB, Borm TJ, Visser RG, van Eck HJ. A next-generation sequencing method for genotyping-by-sequencing of highly heterozygous autotetraploid potato. PLoS One. 2013;8:e62355. doi: 10.1371/journal.pone.0062355

94.Desta ZA, Ortiz R. Genomic selection: genome-wide prediction in plant improvement. Trends Plant Sci. 2014;19:592-601.

95.de Bem Oliveira I, Resende MFR Jr, Ferrão LFV, Amadeu RP, Endelman JB, Kirst M, et al. Genomic prediction of autotetraploids; influence of relationship matrices, allele dosage, and continuous genotyping calls in phenotype prediction. G3. 2019;9:1189-98.

96.Endelman JB, Schmitz Carley CA, Bethke PC, Coombs JJ, Clough ME, da Silva WL, et al. Genetic variance partitioning and genome-wide prediction with allele dosage information in autotetraploid potato. Genetics. 2018;209:77-87.

97.Slater AT, Cogan NOI, Forster JW, Hayes BJ, Daetwyler HD. Improving genetic gain with genomic selection in autotetraploid potato. Plant Genome. 2016;9. doi: 10.3835/plantgenome2016.02.0021

98.Sverrisdóttir E, Sundmark EHR, Johnsen HØ, Kirk HG, Asp T, Janss L, et al. The value of expanding the training population to improve genomic selection models in tetraploid potato. Front Plant Sci. 2018;9:1118. doi: 10.3389/fpls.2018.01118

99.Sverrisdóttir E, Byrne S, Sundmark EHR, Johnsen HØ, Kirk HG, Asp A, et al. Genomic prediction of starch content and chipping quality in tetraploid potato using genotyping by sequencing. Theor Appl Genet. 2017;130:2091-108.

100.Stich B, Van Inghelandt D. Prospects and potential uses of genomic prediction of key performance traits in tetraploid potato. Front Plant Sci. 2018;9:159. doi: 10.3389/fpls.2018.00159

101.Habyarimana E, Paris B, Mandolino G. Genomic prediction for yields, processing and nutritional quality traits in cultivated potato (Solanum tuberosum L.). Plant Breed. 2017;136:245-52.

102.Enciso-Rodriguez F, Douches D, Lopez-Cruz M, Coombs J, de los Campos G. Genomic selection for late blight and common scab resistance in tetraploid potato (Solanum tuberosum). G3. 2018;8:2471-81.

103.Sverrisdóttir E. Initiating genomic selection in tetraploid potato
[PhD Thesis]. Aalborg (Denmark): Faculty of Engineering and Science, Aalborg University; 2017.

104.Bradshaw J. Review and analysis of limitations in ways to improve conventional potato breeding. Potato Res. 2017;60:171-93.

105.Slater AT, Cogan NOI, Rodoni BC, Daetwyler HD, Hayes BJ, Caruana B, et al. Breeding differently—the digital revolution: high-throughput phenotyping and genotyping. Potato Res. 2017;60:337-52.

106.Prashar A, Yildiz J, McNicol JW, Bryan GJ, Jones HG. Infra-red thermography for high throughput field phenotyping in Solanum tuberosum. PLoS One. 2013;8:e65816. doi: 10.1371/journal.pone.0065816

107.Bernhard T, Truberg B, Friedt W, Snowdon R, Wittkop B. Development of near-infrared reflection spectroscopy calibrations for crude protein and dry matter content in fresh and dried potato tuber samples. Potato Res. 2016;59:149-65.

108.Stokstad E. The new potato. Science. 2019;363:574-8.

109.Lindhout P, Meijer D, Schotte T, Hutten RCB, Visser RGF, van Eck HJ. Towards F1 hybrid seed potato breeding. Potato Res. 2011;54:301-12.

110.Jansky SH, Charkowski AO, Douches DS, Gusmini G, Richael C, Bethke PC, et al. Reinventing potato as a diploid inbred line–based crop. Crop Sci. 2016;56:1-11.

111.de Vries M, ter Maat M, Lindhout P. The potential of hybrid potato for East-Africa. Open Agric. 2016;1:151-6.

112.Jansky SH, Spooner DM. The evolution of potato breeding. Plant Breed Rev. 2018;41:169-214.

113.Phumichai C, Mori M, Kobayashi A, Kamijima O, Hosaka K. Toward the development of highly homozygous diploid potato lines using the self-compatibility controlling Sli gene. Genome. 2005;48:977-84.

114.Ye M, Peng Z, Tang D, Yang Z, Li D, Xu Y, et al. Generation of self-compatible diploid potato by knockout of S-RNase. Nat Plants. 2018;4:651-3.

115.Taylor M. Routes to genetic gain in potato. Nat Plants. 2018;4:631-2.

116.Andersson M, Turesson H, Olsson N, Fält A-S, Olsson P, Gonzalez MN, et al. Genome editing in potato via CRISPR-Cas9 ribonucleoprotein delivery. Physiol Plant. 2018;164:378-84.

117.Andersson M, Turesson H, Nicolia A, Fält A-S, Samuelsson M, Hofvander P. Efficient targeted multiallelic mutagenesis in tetraploid potato. Plant Cell Rep. 2018;36(1):117-28.

引用本文

Rodomiro Ortiz*. Genomic-Led Potato Breeding for Increasing Genetic Gains: Achievements and Outlook, Crop Breeding, Genetics and Genomics. 2020; 2; (2). https://doi.org/10.20900/cbgg20200010.

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