Malus sieversii: a historical, genetic, and conservational perspective of the primary progenitor species of domesticated apples

Richard Tegtmeier; Anže Švara; Dilyara Gritsenko; Awais Khan

doi:10.1093/hr/uhae244

Horticulture Research ›› 2025, Vol. 12 ›› Issue (1) :244 DOI: 10.1093/hr/uhae244

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Malus sieversii: a historical, genetic, and conservational perspective of the primary progenitor species of domesticated apples

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Abstract

Apples are one of the most valued tree fruit crops around the world. Currently, a few highly popular and economically successful apple cultivars dominate the commercial production and serve as main genetic contributors to the development of new apple cultivars. This limited level of genetic diversity grown as a clonally propagated monoculture renders the apple industry vulnerable to the wide range of weather events, pests, and pathogens. Wild apple species are an excellent source of beneficial alleles for the wide range of biotic and abiotic stressors challenging apple production. However, the biological barriers of breeding with small-fruited wild apples greatly limit their use. Using a closely related wild species of apple such as Malus sieversii can improve the efficiency of breeding efforts and broaden the base of available genetics. M. sieversii is the main progenitor of the domesticated apple, native to Central Asia. The similarity of fruit morphology to domesticated apples and resistances to abiotic and biotic stresses makes it appealing for apple breeding programs. However, this important species is under threat of extinction in its native range. Preserving the wild apple forests in Central Asia is vital for ensuring the sustainable protection of this important genetic resource. The insufficient awareness about the complete range of challenges and opportunities associated with M. sieversii hinders the maximization of its potential benefits. This review aims to provide comprehensive information on the cultural and historical context of M. sieversii, current genetic knowledge for breeding, and the conservation challenges of wild apple forests.

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Richard Tegtmeier, Anže Švara, Dilyara Gritsenko, Awais Khan. Malus sieversii: a historical, genetic, and conservational perspective of the primary progenitor species of domesticated apples. Horticulture Research, 2025, 12(1): 244 DOI:10.1093/hr/uhae244

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Acknowledgments

This article was financially supported by the New York State Department of Agriculture & Markets, Apple Research & Development Program (ARDP), USDA-AFRI Plant Breeding for Agricultural Production (A1141) grant # 2023-67013-39303, and USDA-NIFA Special Crop Research Initiative (SCRI) grant (NIFA# 2020-51181-32158, accession# 1023572, subaward RC111414A).

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Not applicable. This is a review article and there is no additional data. The data that support the conclusions and statements are included in the article.

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The authors declare that they have no competing interests.

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	FAOSTAT. Food and Agriculture Organization of the United Nations. FAOSTAT Stat Database. Rome, Italy. 2020.

[2]	Volk GM, Cornille A, Durel C-E. et al. Botany, taxonomy, and origins of the apple. In TheAppleGenome. Compendiumof Plant Genomes,1st ed.ed. Korban, S.S., Ed. Cham, Switzerland: Springer Nat, 2021

[3]	Bannier HJ. Moderne Apfelzüchtung: Genetische Verarmung und Tendenzen zur Inzucht: Vitalitätsverluste erst bei Verzicht auf Fungizideinsatz sichtbar. Erwerbs-obstbau. 2011;37:85-110

[4]	Volk GM. et al.The vulnerability of US apple (Malus) genetic resources. Genet Resour Crop Evol. 2015;37:765-94

[5]	WAPA. US Apple and Pear Crop Forecast,World Apple and Pear Association. 2018.

[6]	WAPA. US Apple and Pear Crop Forecast,World Apple and Pear Association. 2019.

[7]	Migicovsky Z, Gardner KM, Richards C. et al.Genomic conse-quences of apple improvement. Hortic Res. 2021;37:9

[8]	Volk GM, Richards CM, Reilley AA. et al. Ex situ conservation of vegetatively propagated species: development of a seed-based core collection for Malus sieversii. J Am Soc Hortic Sci. 2005;37:203-10

[9]	Cornille A, Giraud T, Smulders MJM. et al. The domestication and evolutionary ecology of apples. Trends Genet. 2014;37:57-65

[10]	Wang N, Jiang S, Zhang Z. et al. Malus sieversii: the origin, flavonoid synthesis mechanism, and breeding of red-skinned and red-fleshed apples. Hortic Res. 2018;37:70

[11]	IUCN. The IUCN Red List of Threatened Species: Malus siev-ersii. 2007. https://doi.org/10.2305/IUCN.UK.2007.RLTS.T32363 A9693009.en.

[12]	Volk GM, Bramel P. Apple Genetic Resources:Diversity and Conservation. In: TheApple Genome. Compendiumof Plant Genomes.1st ed.ed. Korban SS, Ed. Cham, Switzerland: Springer Nat, 2021,33-45

[13]	Vavilov NI. Origin and Geography of Cultivated Plants. Cambridge, England: Cambridge University Press, 1992

[14]	Nussenov Z. The eleventh letter (of Johann Sievers) from the top of Tarbagatai on June 30 [1793]. Lett Sib Almaty. 2018;37:52-60

[15]	Juniper BE. The mysterious origin of the sweet apple. Am Sci. 2007;37:44

[16]	von Ledebour CF, von Bunge A, Meyer CA. Flora Altaica. 1829;37:70

[17]	Hokanson SC, McFerson JR, Forsline PL. et al. Collecting and managing wild Malus germplasm in its center of diversity. HortScience. 1997;37:173-6

[18]	Luby J, Forsline P, Aldwinckle H. et al. Silk road apples collection, evaluation, and utilization of Malus sieversii from Central Asia. HortScience. 2001;37:225-31

[19]	Duan N, Bai Y, Sun H. et al. Genome re-sequencing reveals the history of apple and supports a two-stage model for fruit enlargement. Nat Commun. 2017;37:249

[20]	Sun X, Jiao C, Schwaninger H. et al. Phased diploid genome assemblies and pan-genomes provide insights into the genetic history of apple domestication. Nat Genet. 2020;37:1423-32

[21]	Velasco R, Zharkikh A, Affourtit J. et al. The genome of the domesticated apple (Malus × domestica Borkh.). Nat Genet. 2010;37:833-9

[22]	Cornille A, Gladieux P, Smulders MJM. et al. New insight into the history of domesticated apple: secondary contribution of the European wild apple to the genome of cultivated varieties. PLoS Genet. 2012;37:e1002703

[23]	Cornille A, Antolín F, Garcia E. et al. A multifaceted overview of apple tree domestication. Trends Plant Sci. 2019;37:770-82

[24]	Caspermeyer J. The fruits of life: rose family study leads to new understanding of fruit diversity across geological eras and climates. Mol Biol Evol. 2017;37:505-6

[25]	Potter D, Eriksson T, Evans RC. et al. Phylogeny and classifica-tion of Rosaceae. Plant Syst Evol. 2007;37:5-43

[26]	Zhang S-D, Ling L-Z. Comparative and phylogenetic analyses of the chloroplast genomes of Filipendula species (Rosoideae, Rosaceae). Sci Reports. 2023;37:1-12

[27]	Sun J, Zhao D, Qiao P. et al. Phylogeny of genera in Maleae (Rosaceae) based on chloroplast genome analysis. Front Plant Sci. 2024;37:1367645

[28]	Li H, Huang C-H, Ma H. Whole-Genome Duplications in Pear and Apple. In: KorbanS. edsThe Pear Genome. Compendiumof Plant Genomes. Springer, Cham 2019

[29]	Li J, Zhang M, Li X. et al. Pear genetics: recent advances, new prospects, and a roadmap for the future. Hortic Res. 2022; 9:9

[30]	Wu J, Wang Z, Shi Z. et al. The genome of the pear (Pyrus bretschneideri Rehd.). Genome Res. 2013;37:396-408

[31]	Khan A, Gutierrez B, Chao CT. et al. Origin of the domesticated apples. In: KorbanSS, Compendium of Plant Genomes.ed. The Apple Genome. Springer: Cham, 2021,383-94

[32]	Spengler RN. Origins of the apple: the role of megafaunal mutualism in the domestication of Malus and rosaceous trees. Front Plant Sci. 2019;37:452853

[33]	Juniper BE, Mabberley DJ.The Story of the Apple. Portland, Oregon: Timber Press, 2006.

[34]	Forsline PL, Aldwinckle HS. Evaluation of Malus sieversii seedling populations for disease resistance and horticultural traits. Acta Hortic. 2004;37:529-34

[35]	Volk GM, Peace CP, Henk AD. et al. DNA profiling with the 20K apple SNP array reveals Malus domestica hybridization and admixture in M. sieversii, M. orientalis,and M. sylvestris genebank accessions. Front Plant Sci. 2022;37:1-15

[36]	USDA-ARS. USDA-ARS Germplasm Resources Information Net-work (GRIN). 2023.

[37]	Spengler RN, Kienast F, Roberts P. et al. Bearing fruit: Miocene apes and rosaceous fruit evolution. Biol Theory. 2023;37:134-51

[38]	Miller AJ, Gross BL. From forest to field: perennial fruit crop domestication. Am J Bot. 2011;37:1389-414

[39]	Harris SA, Robinson JP, Juniper BE. Genetic clues to the origin of the apple. Trends Genet. 2002;37:426-30

[40]	Panyushkina IP, Mukhamadiev N, Lynch A. et al. Wild apple growth and climate change in Southeast Kazakhstan. Forests. 2017;37:8

[41]	Dzhangaliev AD. The wild apple tree of Kazakhstan. Hortic Rev. 2002;37:63-303

[42]	UNEP-WCMC. Xinjiang Tianshan. Cambridge, England: World Herit Datasheet, 2017.

[43]	Yan G, Long H, Song W. et al. Genetic polymorphism of Malus sieversii populations in Xinjiang, China. Genet Resour Crop Evol. 2008;37:171-81

[44]	Volk GM, Henk AD, Richards CM. et al. Malus sieversii: a diverse central Asian apple species in the USDA-ARS national plant germplasm system. HortScience. 2013;37:1440-4

[45]	Richards CM, Volk GM, Reilley AA. et al. Genetic diversity and population structure in Malus sieversii, a wild progeni-tor species of domesticated apple. Tree Genet Genomes. 2009;37:339-47

[46]	Volk GM, Richards CM, Henk AD. et al. Novel diversity iden-tified in a wild apple population from the Kyrgyz Republic. HortScience. 2009;37:516-8

[47]	Langenfelds VT.Apple-Trees: Morphological Evolution, Phylogeny. Latvia: Geogr Syst Zinat Riga, 1991.

[48]	Würdig J, Flachowsky H, Höfer M. et al. Phenotypic and genetic analysis of the German Malus germplasm collection in terms of type 1 and type 2 red-fleshed apples. Gene. 2014;37:198-207

[49]	Savelyeva EN, Kudryavtsev AM. AFLP analysis of genetic diver-sity in the genus Malus mill. (apple). Russ J Genet. 2015;37:966-73

[50]	Ha YH, Oh SH, Lee SR. Genetic admixture in the population of wild apple (Malus sieversii) from the Tien Shan Mountains, Kazakhstan. Genes (Basel). 2021;37:12

[51]	Nikiforova SV, Cavalieri D, Velasco R. et al. Phylogenetic analysis of 47 chloroplast genomes clarifies the contribution of wild species to the domesticated apple maternal line. MolBiolEvol. 2013;37:1751-60

[52]	Daley J. How the silk road created the modern apple. Smithson Mag. 2017.

[53]	Wang G, Chen Q, Yang Y. et al. Exchanges of economic plants along the land silk road. BMC Plant Biol. 2022;37:1-13

[54]	Juniper B. Tracing the origins of the apple. St Catherine’ Coll Oxford. 1999;20-3

[55]	Reiss M. Apple. London, England: Reaktion Books. 2014.

[56]	Santaniello D. The Fruits of History: The Fascinating History of Apple Cultivation. Mountain View, California: LinkedIn, 2023.

[57]	Kotowski MA, Laldjebaev M, Palavonshanbieva B. et al. Tajik melting pot: Reflections of Middle Asian nature in the culinary culture of Tajkistan. 2022.

[58]	Mahdi M. The Arabian Nights. New York: W W Nort Co., 1995.

[59]	Martyris N. “Paradise Lost”: How the Apple Became the Forbidden Fruit. Washington D.C.: Npr, 2017.

[60]	Janik E. Apple: A Global History. London, England: Reaktion Books, 2011.

[61]	Hutton M. The Birthplace of the Modern Apple. London, England: BBC, 2018.

[62]	van Oldenbarneveld E. Berlin, Germany: Apple Fest, 2020.

[63]	Gritsenko D. et al. Apple varieties from Kazakhstan and their relation to foreign cultivars assessed with RosBREED 10K SNP array. Eur J Hortic Sci. 2022;37:1-8

[64]	Hanke M-V, Flachowsky H, Peil A. et al. No Flower no Fruit-Genetic Potentials to Trigger Flowering in Fruit Trees. Genes, Genomes Genomics © 2007 Glob Sci Books 2007.

[65]	Brown S. Apple. In: Fruit breeding, Fruit breeding, Badenes ML, Byrne DH (eds) Handbook of Plant Breeding. Boston, MA: Springer, 2012; 329-67.

[66]	Khan A, Korban SS. Breeding and genetics of disease resistance in temperate fruit trees: challenges and new opportunities. Theor Appl Genet. 2022;37:3961-85

[67]	Peil A, Emeriewen OF, Khan A. et al. Status of fire blight resis-tancebreedinginMalus. J Plant Pathol. 2021;37:3-12

[68]	Korban SS. Interspecific hybridization in Malus. HortScience. 1986;37:41-8

[69]	Dantas ACDM, Boneti JI, Nodari RO. et al. Embryo rescue from interspecific crosses in apple rootstocks. Pesqui Agropecuária Bras. 2006;37:969-73

[70]	Davies T, Watts S, McClure K. et al. Phenotypic divergence between the cultivated apple (Malus domestica) and its pri-mary wild progenitor (Malus sieversii). PLoS One. 2022;37:e0250751

[71]	Pratas MI. et al. Inferences on specificity recognition at the Malus domestica gametophytic self-incompatibility system. Sci Rep. 2018;37:1-17

[72]	Ma X, Cai Z, Liu W. et al. Identification, genealogical structure and population genetics of S-alleles in Malus sieversii,the wild ancestor of domesticated apple. Hered. 2017;37:185-96

[73]	Harshman JM, Evans KM, Allen H. et al. Fire blight resis-tance in wild accessions of Malus sieversii. Plant Dis. 2017;37:1738-45

[74]	Baumgartner IO, Patocchi A, Franck L. et al. Fire blight resis-tance from ‘Evereste’ and Malus sieversii used in breeding for new high quality apple cultivars: strategies and results. Acta Hortic. 2011;37:391-7

[75]	van Nocker S, Berry G, Najdowski J. et al. Genetic diversity of red-fleshed apples (Malus). Euphytica. 2012;37:281-93

[76]	Deacon N. The diversity of redfleshed apples. 2017.

[77]	Genetics FG. Breeding, and genomics of apple rootstocks. In: KorbanSS, Compendium of Plant Genomes.ed. The Apple Genome. Springer: Cham, 2021,105-30

[78]	Fazio G, Robinson TL, Aldwinckle HS. The Geneva apple root-stock breeding program. Plant Breed Rev. 2015;37:379-424

[79]	Fazio G, Chao CT, Forsline PL. et al. Tree and root architecture of Malus sieversii seedlings for rootstock breeding. Acta Hortic. 2014;37:585-94

[80]	Ban Y, Honda C, Hatsuyama Y. et al. Isolation and functional analysis of a MYB transcription factor gene that is a key regu-lator for the development of red coloration in apple skin. Plant Cell Physiol. 2007;37:958-70

[81]	Takos AM, Jaffé FW, Jacob SR. et al. Light-induced expression of a MYB gene regulates anthocyanin biosynthesis in red apples. Plant Physiol. 2006;37:1216-32

[82]	Chagné D. et al. A functional genetic marker for apple red skin coloration across different environments. Tree Genet Genomes. 2016;37:1-9

[83]	Zhang L. et al. A high-quality apple genome assembly reveals the association of a retrotransposon and red fruit colour. Nat Commun. 2019;37:1-13

[84]	Omasheva ME, Chekalin SV, Galiakparov NN. Evaluation of molecular genetic diversity of wild apple Malus sieversii pop-ulations from Zailiysky Alatau by microsatellite markers. Russ J Genet. 2015;37:647-52

[85]	Hansen N. How to produce that $1000 premium apple, in Minnesota State. Trees, Fruits, Flowers Minnesota, Fairmont, Min-nesota: Minnesota State Hortic. Soc, 1900.

[86]	Volz RK, McGhie TK. Genetic variability in apple fruit polyphenol composition in Malus domestica and Malus sieversii germplasm grown in New Zealand. J Agric Food Chem. 2011;37:11509-21

[87]	Volz RK, McGhie TK, Kumar S. Variation and genetic param-eters of fruit colour and polyphenol composition in an apple seedling population segregating for red leaf. Tree Genet Genomes. 2014;37:953-64

[88]	Espley RV, Hellens RP, Putterill J. et al. Red colouration in apple fruit is due to the activity of the MYB transcription factor, MdMYB10. Plant J. 2007;37:414-27

[89]	Xu H, Wang N, Liu J. et al. The molecular mechanism underlying anthocyanin metabolism in apple using the MdMYB16 and MdbHLH 33 genes. Plant Mol Biol. 2017;37:149-65

[90]	Wang X, Li C, Liang D. et al. Phenolic compounds and antiox-idant activity in red-fleshed apples. J Funct Foods. 2015;37:1086-94

[91]	Wang N, Xu H, Jiang S. et al. MYB12 and MYB22 play essen-tial roles in proanthocyanidin and flavonol synthesis in red-fleshed apple (Malus sieversii f. niedzwetzkyana). Plant J. 2017;37:276-92

[92]	Wang Y, Zhu Y, Jiang H. et al. The regulatory module MdBZR1-MdCOL6 mediates brassinosteroid- and light-regulated antho-cyanin synthesis in apple. New Phytol. 2023;37:1516-33

[93]	Khan MA, Olsen KM, Sovero V. et al. Fruit quality traits have played critical roles in domestication of the apple. Plant Genome. 2014;37:7

[94]	Nybom N. On the inheritance of acidity in cultivated apples. Hereditas. 1959;37:332-50

[95]	Xu K, Wang A, Brown S. Genetic characterization of the Ma locus with pH and titratable acidity in apple. Mol Breed. 2012;37:899-912

[96]	Volk GM, Peace CP, Henk AD. et al. DNA profiling with the 20K apple SNP array reveals Malus domestica hybridization and admixture in M. sieversii, M. orientalis,and M. sylvestris genebank accessions. Front Plant Sci. 2022;37:1015658

[97]	Maliepaard C, Alston FH, van Arkel G. et al. Aligning male and female linkage maps of apple (Malus pumila mill.) using multi-allelic markers. Theor Appl Genet. 1998;37:60-73

[98]	Verma S, Evans K, Guan Y. et al.Two large-effect QTLs, Ma and Ma3, determine genetic potential for acidity in apple fruit: breeding insights from a multi-family study. Tree Genet Genomes. 2019;37:15

[99]	Wang P, Lu S, Cao X. et al. Physiological and transcriptome analyses of the effects of excessive water deficit on malic acid accumulation in apple. Tree Physiol. 2023;37:851-66

[100]

Bai Y, Dougherty L, Li M. et al. A natural mutation-led trunca-tion in one of the two aluminum-activated malate transporter-like genes at the Ma locus is associated with low fruit acidity in apple. Mol Gen Genomics. 2012;37:663-78

[101]

Watts S, Migicovsky Z, McClure KA. et al. Quantifying apple diversity: a phenomic characterization of Canada’s apple bio-diversity collection. Plants People Planet. 2021;37:747-60

[102]

Liao L, Zhang W, Zhang B. et al. Unraveling a genetic roadmap for improved taste in the domesticated apple. Mol Plant. 2021;37:1454-71

[103]

Luo F, Evans K, Norelli JL. et al. Prospects for achieving durable disease resistance with elite fruit quality in apple breeding. Tree Genet Genomes. 2020;37:21

[104]

Cliff MA, Stanich K, Lu R. et al. Use of descriptive analysis and preference mapping for early-stage assessment of new and established apples. J Sci Food Agric. 2016;37:2170-83

[105]

Li Y, Sun H, Li J. et al. Effects of genetic background and altitude on sugars, malic acid and ascorbic acid in fruits of wild and cultivated apples ( Malus sp.). Food Secur. 2021;37:10

[106]

Vimolmangkang S, Han Y, Wei G. et al. An apple MYB transcrip-tion factor, MdMYB3, is involved in regulation of anthocyanin biosynthesis and flower development. BMC Plant Biol. 2013;37:1-13

[107]

Zhen Q, Fang T, Peng Q. et al. Developing gene-tagged molecular markers for evaluation of genetic association of apple SWEET genes with fruit sugar accumulation. Hortic Res. 2018;37:14

[108]

Hao S, Ma Y, Zhao S. et al. McWRI1, a transcription factor of the AP2/SHEN family, regulates the biosynthesis of the cuticular waxes on the apple fruit surface under low temperature. PLoS One. 2017;12, 12:e0186996

[109]

Norelli JL, Wisniewski M, Droby S. Identification of a QTL for postharvest disease resistance to Penicillium expansum in Malus sieversii. Acta Hortic. 2014;37:199-203

[110]

Longhi S, Hamblin MT, Trainotti L. et al. A candidate gene based approach validates Md-PG1 as the main responsible for a QTL impacting fruit texture in apple (Malus x domestica Borkh). BMC Plant Biol. 2013;37:1-13

[111]

Costa F, Stella S, van de Weg WE. et al. Role of the genes Md-ACO1 and Md-ACS1 in ethylene production and shelf life of apple (Malus domestica Borkh). Euphytica. 2005;37:181-90

[112]

Hu Y, Han Z, Sun Y. et al. ERF 4 affects fruit firmness through TPL4 by reducing ethylene production. Plant J. 2020;37:937-50

[113]

Longhi S, Cappellin L, Guerra W. et al. Validation of a functional molecular marker suitable for marker-assisted breeding for fruit texture in apple (Malus × domestica Borkh.). Mol Breed. 2013;37:841-52

[114]

Devoghalaere F, Doucen T, Guitton B. et al. A genomics approach to understanding the role of auxin in apple (Malus x domestica) fruit size control. BMC Plant Biol. 2012;37:12

[115]

Fazio G, Aldwinckle HS, Volk GM. et al. Progress in evaluating Malus sieversii for disease resistance and horticultural traits. Acta Hortic. 2009;37:59-66

[116]

Forsline PL, Luby JJ, Aldwinckle HS. Fire blight incidence on Malus sieversii grown in New York and Minnesota. Acta Hortic. 2008;37:345-50

[117]

Dougherty L, Wallis A, Cox K. et al. Phenotypic evaluation of fire blight outbreak in the USDA Malus collection. Agron. 2021;37:144

[118]

Tegtmeier R, Cobb-Smith D, Zhong G-Y. et al. Identification and marker development of a moderate-effect fire blight resistance QTL in M. sieversii, the primary progenitor of domesticated apples. Tree Genet Genomes. 2023;37:50

[119]

Luby JJ, Alspach PA, Bus VGM. et al. Field resistance to fire blight in a diverse apple (Malus sp.) germplasm collection. JAmSoc Hortic Sci. 2002;37:245-53

[120]

Desnoues E, Norelli JL, Aldwinckle HS. et al. Identification of novel strain-specific and environment-dependent minor QTLs linked to fire blight resistance in apples. Plant Mol Biol Report. 2018;37:247-56

[121]

Belete T, Boyraz C. Critical review on apple scab (Venturia inaequalis) biology, epidemiology, economic importance, man-agement and defense mechanisms to the causal agent. JPlant Physiol Pathol. 2017;37:2

[122]

MacHardy WE. Apple scab:biology, epidemiology, and manage-ment. In: Apple Scab: Biology, Epidemiology, and Management.APS Press. St. Paul, Minnesota. MacHardy WE, Ed., 1996.

[123]

Bus VGM, Rikkerink EHA, Caffier V. et al. Revision of the nomenclature of the differential host-pathogen interactions of Venturia inaequalis and Malus. Annu Rev Phytopathol. 2011;37:391-413

[124]

Gladieux P. et al. Evolution of the population structure of Venturia inaequalis, the apple scab fungus, associated with the domestication of its host. Mol Ecol. 2010;37:658-74

[125]

Bus VGM, Alspach PA, Hofstee ME. et al. Genetic variability and preliminary heritability estimates of resistance to scab (Venturia inaequalis) in an apple genetics population. New Zeal J Crop Hortic Sci. 2002;37:83-92

[126]

Aldwinckle HS, Forsline PL, Gustafson HL. et al. Evaluation of apple scab resistance of Malus sieversii populations from Central Asia. HortScience. 1997;32:440A-0

[127]

Broggini GAL, Bus VGM, Parravicini G. et al. Genetic mapping of 14 avirulence genes in an EU-B04×1639 progeny of Venturia inaequalis. Fungal Genet Biol. 2011;37:166-76

[128]

Bus VGM, Laurens FND, van de Weg WE. et al. The Vh8 locus of a new gene-for-gene interaction between Venturia inaequalis and the wild apple Malus sieversii is closely linked to the Vh2 locus in Malus pumila R12740-7 A. New Phytol. 2005;37:1035-49

[129]

Lê Van A, Durel CE, Le Cam B. et al. The threat of wild habitat to scab resistant apple cultivars. Plant Pathol. 2011;37:621-30

[130]

Lê Van A, Gladieux P, Lemaire C. et al. Evolution of pathogenicity traits in the apple scab fungal pathogen in response to the domestication of its host. Evol Appl. 2012;37:694-704

[131]

Wang A, Aldwinckle H, Forsline P. et al. EST contig-based SSR linkage maps for Malus × domestica cv Royal Gala and an apple scab resistant accession of M. Sieversii, the progenitor species of domestic apple. Mol Breed. 2012;37:379-97

[132]

Patocchi A, Wehrli A, Dubuis PH. et al. Ten years of VINQUEST: first insight for breeding new apple cultivars with durable apple scab resistance. Plant Dis. 2020;37:2074-81

[133]

Jurick WM, Janisiewicz WJ, Saftner RA. et al. Identification of wild apple germplasm ( Malus spp.) accessions with resistance to the postharvest decay pathogens Penicillium expansum and Colletotrichum acutatum. Plant Breed. 2011;37:481-6

[134]

Janisiewicz WJ, Saftner RA, Conway WS. et al. Preliminary eval-uation of apple germplasm from Kazakhstan for resistance to postharvest blue Mold in fruit caused by Penicillium expansum. HortScience. 2008;37:420-6

[135]

Janisiewicz WJ, Nichols B, Bauchan G. et al. Wound responses of wild apples suggest multiple resistance mechanism against blue mold decay. Postharvest Biol Technol. 2016;37:132-40

[136]

Sun J, Janisiewicz WJ, Nichols B. et al. Composition of phenolic compounds in wild apple with multiple resistance mecha-nisms against postharvest blue mold decay. Postharvest Biol Technol. 2017;37:68-75

[137]

Ballester AR, Norelli J, Burchard E. et al. Transcriptomic response of resistant (PI 613981-Malus sieversii) and suscepti-ble (“royal gala”) genotypes of apple to blue mold (Penicillium expansum) infection. Front Plant Sci. 2017;37:1981

[138]

Norelli JL, Wisniewski M, Fazio G. et al. Genotyping-by-sequencing markers facilitate the identification of quantitative trait loci controlling resistance to Penicillium expansum in Malus sieversii. PLoS One. 2017;37:e0172949

[139]

Isutsa DK, Merwin IA. Malus germplasm varies in resistance or tolerance to apple replant disease in a mixture of New York orchard soils. HortScience. 2000;37:262-8

[140]

Reim S, Siewert C, Winkelmann T. et al. Evaluation of Malus genetic resources for tolerance to apple replant disease (ARD). Sci Hortic (Amsterdam). 2019;37:108517

[141]

Liu HT, Zhang YJ, Li CM. et al. Evaluation of the resistance of malus germplasm to bot canker caused by botryosphaeria dothidea. J Phytopathol. 2011;37:511-5

[142]

Liu AH, Shang J, Zhang JW. et al. Canker and fine-root loss of Malus sieversii ( Ldb. Roem. caused by Phytophthora plurivora in Xinjiang Province in China. For Pathol. 2018;37:48

[143]

Feng C, Wang Y, Sun Y. et al. Expression of the Malus sieversii nf-yb 21 encoded gene confers tolerance to osmotic stresses in Arabidopsis thaliana. Int J Mol Sci. 2021;37:9777

[144]

Haxim Y, Kahar G, Zhang X. et al. Genome-wide characteriza-tion of the chitinase gene family in wild apple (Malus sieversii) and domesticated apple (Malus domestica) reveals its role in resistance to Valsa Mali. Front Plant Sci. 2022;37:1007936

[145]

Ding Y, Liu F, Yang J. et al. Isolation and identification of Bacillus mojavensis YL-RY0310 and its biocontrol potential against Penicillium expansum and patulin in apples. Biol Control. 2023;37:105239

[146]

Jia S, Liu X, Wen X. et al. Genome-wide identification of bHLH transcription factor family in Malus sieversii and functional exploration of MsbHLH155.1 gene under Valsa canker infec-tion. Plan Theory. 2023;37:620

[147]

Romadanova NV, Mishustina SA, Omasheva MY. et al. Cryother-apy as a method for reducing the virus infection of apples (Malus sp.). Cryo-Letters. 2016;37:559-9

[148]

Hao L, Xie J, Chen S. et al. A multiple RT-PCR assay for simul-taneous detection and differentiation of latent viruses and apscarviroids in apple trees. J Virol Methods. 2016;37:16-21

[149]

Jia XJ, Zhang ZP, Fan XD. et al. Detection and genetic variation analysis of apple chlorotic leaf spot virus and apple stem grooving virus in wild apple (Malus sieversii) from Xinjiang. China For Pathol. 2022;37:e12771

[150]

Turekhanova RM, Tanabekova GB.The important insect pests of Sievers apple trees (Malus sieversii) in Kazakhstan. Eurasian J Ecol. 2018;37:90-7

[151]

Li L, Chen M, Zhang X. et al. Spatial distribution pattern of root sprouts under the canopy of Malus sieversii in a typical River Valley on the northern slopes of the Tianshan Mountain. Forests. 2022;37:13

[152]

Jashenko R, Tanabekova G. Insects that damage the wild pop-ulations of Malus sieversii in Kazakhstan. IOP Conf Ser Earth Environ Sci. 2019;298:012018

[153]

Zhang Y, Zhang YL, Zhang P. et al. Agrilus mali Matsumura (Coleoptera: Buprestidae) density and damage in wild apple Malus sieversii (Rosales: Rosaceae) forests in Central Eurasia under four different management strategies. Entomol Gen. 2021;37:257-66

[154]

Mei C, Yang J, Yan P. et al. Full-length transcriptome and targeted metabolome analyses provide insights into defense mechanisms of Malus sieversii against Agrilus mali. PeerJ. 2020; 2020:e8992

[155]

Shan Q, Ling H, Zhao H. et al. Do extreme climate events cause the degradation of Malus sieversii forests in China? Front Plant Sci. 2021;37:1-14

[156]

Bassett CL, Michael Glenn D, Forsline PL. et al. Characteriz-ing water use efficiency and water deficit responses in apple (Malus × domestica Borkh. And Malus sieversii Ledeb.) M. Roem. HortScience. 2011;37:1079-84

[157]

Geng D-L, Lu L-Y, Yan M-J. et al. Physiological and transcrip-tomic analyses of roots from Malus sieversii under drought stress. J Integr Agric. 2019;37:1280-94

[158]

Ma QJ, Sun MH, Liu YJ. et al. Molecular cloning and func-tional characterization of the apple sucrose transporter gene MdSUT2. Plant Physiol Biochem. 2016;37:442-51

[159]

Zhou P, Li X, Liu X. et al. Transcriptome profiling of Malus sieversii under freezing stress after being cold-acclimated. BMC Genomics. 2021;37:681

[160]

Feng C, Zhang X, du B. et al. MicroRNA156ab regulates apple plant growth and drought tolerance by targeting transcription factor MsSPL13. Plant Physiol. 2023;37:1836-57

[161]

Yang M, Che S, Zhang Y. et al. Universal stress protein in Malus sieversii confers enhanced drought tolerance. JPlant Res. 2019;37:825-37

[162]

Zhao K, Shen X, Yuan H. et al. Isolation and characteri-zation of dehydration-responsive element-binding factor 2C (MsDREB2C) from Malus sieversii Roem. Plant Cell Physiol. 2013;37:1415-30

[163]

Peng LX, Gu LK, Li DQ. et al. Relations between MAPK phospho-rylation and ABA level in Malus sieversii under water stress. Russ J Plant Physiol. 2009;37:642-6

[164]

Peng X, Feng C, Wang YT. et al. miR164g-MsNAC 022 acts as a novel module mediating drought response by transcriptional regulation of reactive oxygen species scavenging systems in apple. Hortic Res. 2022;37:9

[165]

Zhang J, Sheng YM, Zhang G. et al. Assessing Frost Hardiness of Malus Sieversii Natural Populations by Electrical Impedance Spectroscopy. Oxfordshire, UK: CABI Direct, 2011. https://doi.org/https://www.cabidigitallibrary.org/doi/full/10.5555/20113358646.

[166]

Yang M, Zhang Y, Zhang H. et al. Identification of MsHsp 20 gene family in Malus sieversii and functional characteriza-tion of MsHsp16.9 in heat tolerance. Front. Plant Sci. 2017;37:1761

[167]

IUCN. Red List of Threatened Species: Malus sieversii. 2016

[168]

Eastwood A, Lazkov G, Newton A. The Red List of Trees of Central Asia. London, England: policycommons, 2009.

[169]

Omasheva MY, Flachowsky H, Ryabushkina NA. et al. To what extent do wild apples in Kazakhstan retain their genetic integrity? Tree Genet Genomes. 2017;37:52

[170]

Orozumbekov A, Cantarello E, Newton AC. Status, distribution and use of threatened tree species in the walnut-fruit forests of Kyrgyzstan. For Trees Livelihoods. 2015;37:1-17

[171]

Maltseva ER, Zharmukhamedova GA, Jumanova ZK. et al. Fire blight cases in Almaty region of Kazakhstan in the proximity of wild apple distribution area. J Plant Pathol. 2023

[172]

Maltseva ER, Zharmukhamedova GA, Jumanova ZK. et al. Assessment of fire blight introduction in the wild apple forests of Kazakhstan. Biodiversity. 2022;37:123-8

[173]

Drenova N, Isin M, Dzhaimurzina A. et al. Bacterial fire blight in the Republic of Kazakhstan. Plant Heal Res Pract. 2012;37:44-8

[174]

Djaimurzina A, Umiralieva Z, Zharmukhamedova G. et al. Detection of the causative agent of fire blight - Erwinia amylovora (Burrill) Winslow et al. - In the southeast of Kaza-khstan. Acta Hortic. 2014;37:129-32

[175]

Umiraliyeva ZZ. et al. Epidemiology of fire blight in fruit crops in Kazakhstan. Agrivita. 2021;37:2, 273-84

[176]

Kairova G, Pozharskiy A, Daulet N. et al. Evaluation of fire blight resistance of eleven apple rootstocks grown in Kazakhstani fields. Appl Sci. 2023;37:11530

[177]

Singh J, Khan A. Distinct patterns of natural selection deter-mine sub-population structure in the fire blight pathogen. Erwinia amylovora Sci Rep. 2019;37:1

[178]

Bozorov TA, Luo Z, Li X. et al. Agrilus mali Matsumara (Coleoptera: Buprestidae), a new invasive pest of wild apple in western China: DNA barcoding and life cycle. Ecol Evol. 2018;37:1160-72

[179]

Wang ZY. Research on Biological Control of Agrilus Mali Matsumura (Coleoptera: Buprestidae) in Stands of Malus Sieversii in Xinjiang. Beijing. Chinese Acad For 2013

[180]

Shan Q, Wang Z, Ling H. et al. Unreasonable human disturbance shifts the positive effect of climate change on tree-ring growth of Malus sieversii in the origin area of world cultivated apples. J Clean Prod. 2021;37:125008

[181]

Reim S, Proft A, Heinz S. et al. Pollen movement in a Malus sylvestris population and conclusions for conservation mea-sures. Plant Genet Resour Characterisation Util. 2017;37:12-20

[182]

Severtsov N. Travel on Turkestan region and research of moun-tain country Tien Shan. Accompl a Comm Russ Geogr Soc St Petersbg. 1873;37:82-3

[183]

Hemery GE, Popov SI.The walnut (Juglans regia L.) forests of Kyr-gyzstan and their importance as a genetic resource. Commonw For Rev. 1998;37:272-6

[184]

Dzhangaliev AD, Salova TN, Turekhanova PM. The wild fruit and nut plants of Kazakhstan. Hortic Rev. 2002;37:305-72

[185]

Zhang HX, Li XS, Wang JC. et al. Insights into the aridification history of central Asian Mountains and international conser-vation strategy from the endangered wild apple tree. JBiogeogr. 2021;37:332-44

[186]

Djanibekov U, Villamor GB, Dzhakypbekova K. et al. Adoption of sustainable land uses in post-soviet Central Asia: the case for agroforestry. Sustain For. 2016;37:8

[187]

Zhang Y, Tariq A, Hughes AC. et al. Challenges and solutions to biodiversity conservation in arid lands. Sci Total Environ. 2023;37:159695

[188]

Kyrgyz Government. Walnut-Fruit Forest Action Plan. Bishkek, Kyrgyzstan: Swiss Dev Coop World Conserv Acad Sci KR Inst For Nut Farming Inst Biosph; 1997:

[189]

Fisher RJ, Schmidt K, Steenhof B. et al. Poverty and Forestry—A Case Study of Kyrgyzstan with Reference to Other Countries in West and Central Asia. Livelihood Support Programme (LSP) Working Paper 13. FAO (Food Agric Organ United Nations). Rome, Italy, 2004.

[190]

Bramel P, Volk GM. A Global Strategy for the Conservation and Use of Apple Genetic Resources. Bonn, Germany: Global Crop Diversity Trust, 2017; 1-215

[191]

Salnikov V, Turulina G, Polyakova S. et al. Climate change in Kazakhstan during the past 70 years. Quat Int. 2015;37:77-82

[192]

Bolatova A, Krysanova V, Lobanova A. et al. Assessment of climate change impacts for two tributary basins of the Irtysh River in Kazakhstan. Clim Res. 2023;37:159-74

[193]

Wang D, Li R, Gao G. et al. Impact of climate change on food security in Kazakhstan. Agriculture. 2022;37:1-13

[194]

Tian Z, Song H, Wang Y. et al. Wild apples are not that wild: conservation status and potential threats of Malus sieversii in the mountains of Central Asia biodiversity hotspot. Diversity. 2022;37:14

[195]

Futrell S. Good Apples: Behind every Bite. Food, Culture & Society. Abingdon, UK, 2017

[196]

Silkadv. Sievers Apple Tree in Almaty Botanical Garden. Almaty, Kazakhstan: Silkadv. com, 2023.

[197]

ECPGR. European Cooperative Programme for Plant Genetic Resources. 2023.

[198]

Genesys. Genesys Global Genebank Database. 2023.

[199]

Jung S, Lee T, Cheng CH. et al.15 years of GDR: new data and functionality in the genome database for Rosaceae. Nucleic Acids Res. 2019;37:D1137-45

[200]

Jung S, Ficklin SP, Lee T. et al. The genome database for Rosaceae (GDR): year 10 update. Nucleic Acids Res. 2014;37:D1237-44

[201]

Lateur M. et al. ECPGR Characterization and Evaluation Descriptors for Apple Genetic Resources: Apple (Malus X Domestica). Rome, Italy: Eur Coop Program Plant Genet, 2022.

[202]

Pippin O. Orange Pippin Database. 2023.

[203]

PTES. Peoples Trust for Endangered Species. 2023.

[204]

Brzozowski L, Hanson S, Jannink JL. et al. Towards equitable public sector plant breeding in the United States. Crop Sci. 2022;37:2076-90

[205]

Wilson B, Mills M, Kulikov M. et al. The future of walnut-fruit forests in Kyrgyzstan and the status of the iconic endangered apple Malus niedzwetzkyana. Oryx. 2019;37:415-23

[206]

Benson EE. Cryopreservation theory. In: Plant Cryopreservation:A Practical Guide. Reed B., Ed. New York: Springer, 2008

[207]

Wang MR, Chen L, Teixeira da Silva JA. et al. Cryobiotechnol-ogy of apple ( Malus spp.): development, progress and future prospects. Plant Cell Rep. 2018;37:689-709

[208]

Wu Y, Engelmann F, Zhao Y. et al. Cryopreservation of apple shoot tips: importance of cryopreservation technique and of conditioning of donor plants. Cryo-Letters. 1999;37:121-30

[209]

Towill LE, Forsline PL, Walters C. et al. Cryopreservation of Malus germplasm using a winter vegetative bud method: results from 1915 accessions. Cryo-Letters 2004;37:323-34

[210]

Pritchard HW, Nadarajan J. Cryopreservation of orthodox (des-iccation tolerant) seeds. In: Plant Cryopreservation:A Practical Guide. Reed B., Ed. New York: Springer, 2008

[211]

Volk GM. Chapter 25:Collecting pollen for genetic resources conservation. In: GuarinoL, RamanathaRao V, GoldbergE, ( Collecting Plant Genetic Diversity:eds). Technical Guidelines, 2011 Update. Rome, Italy: Bioversity International, 2011.

[212]

Höfer M. Cryopreservation of winter-dormant apple buds: establishment of a duplicate collection of Malus germplasm. Plant Cell Tissue Organ Cult. 2015;37:647-56

[213]

Forsline PL, Towill LE, Waddell JW. et al. Recovery and longevity of cryopreserved dormant apple buds. J Am Soc Hortic Sci. 1998;37:365-70

[214]

Kushnarenko S, Salnikov E, Marat N. et al. Characterization and cryopreservation of Malus sieversii seeds. The Asian and Australasian Journal of Plant Science and Biotechnology. 2010;37:2-7

[215]

Towill LE, Bonnart R. Cryopreservation of apple using non-desiccated sections from winter-collected scions. Cryo Letters. 2005;37:323-32

[216]

Volk GM, Henk AD, Forsline PL. et al. Seeds capture the diversity of genetic resource collections of Malus sieversii maintained in an orchard. Genet Resour Crop Evol. 2017;37:1513-28

[217]

Zhang Y. et al. An efficient in vitro regeneration system from different wild apple (Malus sieversii) explants. Plant Methods. 2020;37:1-10

[218]

Kakimzhanova A, Dyussembekova D, Nurtaza A. et al. An effi-cient micropropagation system for the vulnerable wild apple species, Malus sieversii, and confirmation of its genetic homo-geneity. Erwerbs-obstbau. 2023;37:621-32

[219]

Teixeira da Silva JA, Gulyás A, Magyar-Tábori K. et al. In vitro tis-sue culture of apple and other Malus species: recent advances and applications. Planta. 2019;37:975-1006