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2024 | OriginalPaper | Buchkapitel

Haploid System in Mutation Breeding

verfasst von : Rasoul Amirian, Mehran E. Shariatpanahi, Golnoosh Taghiabadi

Erschienen in: Plant Mutagenesis

Verlag: Springer Nature Switzerland

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Abstract

During a century since the discovery of the first haploid in Datura stramonium in 1923, doubled haploids (DH) have played a critical role in simplifying plant breeding approaches and development of new cultivars (rice, wheat, etc.) or parents of hybrids (maize, rapeseed, etc.). Mutation breeding, which started in 1920 by radiation of plants to induce genetic variations, has evolved from random mutations using physical and later chemical mutagens to safer random and precise mutagenesis using biological approaches. Both mutation breeding and DH technology enable breeders to create new genetic/phenotypic variations and facilitate the detection/application of beneficial ones, respectively. In mutation breeding programs, haploids and DHs are produced in vitro by androgenesis, gynogenesis or in vivo by uniparental genome elimination. In vitro and in vivo DH production facilitate mutation breeding by fast fixation of recessive mutations and obtaining homozygous lines. The gametes of mutated seeds, directly mutated gametes, or in vitro selected mutants can be used for DH production. Also, DH technology decreases the timing and the cost needed to evaluate gene-trait relations in the mutated populations and site-directed mutagenesis. This chapter focuses on the different aspects of DH technology application in mutation breeding and considers new approaches and technologies in both areas.

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Aklilu E (2021) Review on forward and reverse genetics in plant breeding. All Life 14(1):127–135CrossRef

Amirian R, Hojati Z, Azadi P (2020) Male flower induction significantly affects androgenesis in cucumber (Cucumis sativus L.). J Hortic Sci Biotechnol 95(2):183–191

Bae CH, Lee YI, Lim YP, Seo YW, Lee DJ, Yang DC, Lee HY (2002) Selection of herbicide tolerant cell lines from gamma-ray-irradiated cell cultures in rice (Oryza sativa L. cv. Ilpumbyeo). J Plant Biotechnol 4(3):123–127

Barro F, Fernández-Escobar J, De la Vega M, Martín A (2003) Modification of glucosinolate and erucic acid contents in doubled haploid lines of Brassica carinata by UV treatment of isolated microspores. Euphytica 129:1–6CrossRef

Barro F, Fernandez-Escobar J, De La Vega M, Martin A (2001) Doubled haploid lines of Brassica carinata with modified erucic acid content through mutagenesis by EMS treatment of isolated microspores. Plant Breed 120(3):262–264CrossRef

Bartels PG, Hilton JL (1973) Comparison of trifluralin, oryzalin, pronamide, propham, and colchicine treatments on microtubules. Pestic Biochem Physiol 3(4):462–472CrossRef

Beversdorf WD, Kott LS (1987) An in vitro mutagenesis/selection system for Brassica napus. Iowa. State J Res 61(4):435–443

Bilgin O, Sarier SY, Başer İ, Balkan A (2022) Enhancement of Androgenesis and plant regeneration from wheat anther culture by seed pre-sowing gamma irradiation. Tekirdağ ziraat fak 19(2):354–365

Bitsch C, Gröger S, Lelley T (2000) Effect of parental genotypes on haploid embryo and plantlet formation in wheat × maize crosses. Euphytica 103:319–323CrossRef

Blakeslee AF, Belling J, Farnham ME, Bergner AD (1922) A haploid mutant in the Jimson weed, Datura stramonium. Science 55:646–647CrossRef

Bohanec B, Jakse M, Havey MJ (2003) Genetic analyses of gynogenetic haploid production in onion. J Am Soc Hortic 128(4):571–574CrossRef

Bohanec B (2009) Doubled haploids via gynogenesis. In: Touraev A, Forster BP, Jain SM (eds) Advances in haploid production in higher plants. Springer, Heidelberg, Berlin, pp 35–46CrossRef

Britt AB, Kuppu S (2016) Cenh3: an emerging player in haploid induction technology. Front Plant Sci 7:357CrossRef

Brook RD (1979) Mutation plant breeding for seed protein improvement. In Seed protein improvement in cereals and grain legumes. Proceedings of an international symposium jointly organized by IAEA and FAO in cooperation with GSF Neuherberg, 4–8 September 1978. pp 43–55. IAEA

Caldwell DG, McCallum N, Shaw P, Muehlbauer GJ, Marshall DF, Waugh R (2004) A structured mutant population for forward and reverse genetics in Barley (Hordeum vulgare L). The Plant J 40(1):143–150CrossRef

Castillo AM, Cistue L, Valles MP, Sanz JM, Romagosa I, Molina-Cano JL (2001) Efficient production of androgenic doubled-haploid mutants in barley by the application of sodium azide to anther and microspore cultures. Plant Cell Rep 20:105–111CrossRef

Chen JL, Beversdorf WD (1991) Evaluation of microspore-derived embryos as models for studying lipid biosynthesis in seed of rapessed (Brassica napus L). Euphytica 58:145–155CrossRef

Chen JF, Cui L, Malik AA, Mbira KG (2011) In vitro haploid and dihaploid production via unfertilized ovule culture. Plant Cell Tissue Organ Cult 104:311–319CrossRef

Chen QF, Wang CL, Lu YM, Shen M, Afza R, Duren MV, Brunner H (2001) Anther culture in connection with induced mutations for rice improvement. Euphytica 120:401–408CrossRef

Coe JEH (1559) A line of maize with high haploid frequency. Am Nat 193:381–382

Daurova A, Daurov D, Volkov D, Karimov A, Abai Z, Raimbek D, Zhapar K, Zhambakin K, Shamekova M (2020) Mutagenic treatment of microspore-derived embryos of turnip rape (Brassica rapa) to increase oleic acid content. Plant Breed 139(5):916–922CrossRef

Dhooghe E, Denis S, Eeckhaut T, Reheul D, Van Labeke MC (2009) In vitro induction of tetraploids in ornamental Ranunculus. Euphytica 168:33–40CrossRef

Diao WP, Jia YY, Song H, Zhang XQ, Lou QF, Chen JF (2009) Efficient embryo induction in cucumber ovary culture and homozygous identification of the regenetants using SSR markers. Sci Hortic 119(3):246–251CrossRef

Dore C, Marie F (1993) Production of gynogenetic plants of onion (Allium cepa L.) after crossing with irradiated pollen. Plant breed 111(2):142–147

Ferrie AMR, Taylor DC, MacKenzie SL, Rakow G, Raney JP, Keller WA (2008) Microspore mutagenesis of Brassica species for fatty acid modifications: a preliminary evaluation. Plant Breed 27(5):501–506CrossRef

Ferrie AM, Bhowmik P, Rajagopalan N, Kagale S (2020) CRISPR/Cas9-mediated targeted mutagenesis in wheat doubled haploids. Cereal genomics: methods and protocols, 183–198

Forster BP, Thomas WT (2010) Doubled haploids in genetics and plant breeding. Plant Breed Rev 25:57–88

Freisleben R, Lein A (1944) Möglichkeiten und praktische Durchführung der Mutationszüchtung. Kühn-Arhiv 60:211–222

Friedberg EC (2003) DNA damage and repair. Nature 421:436–440CrossRef

Fróna D, Szenderák J, Harangi-Rákos M (2019) The challenge of feeding the world. Sustainability 11(20):5816CrossRef

Fu S, Yin L, Xu M, Li Y, Wang M, Yang J, ..., Tang R (2018) Maternal doubled haploid production in interploidy hybridization between Brassica napus and Brassica allooctaploids. Planta 247:113–125

Gao R, Guo G, Fang C, Huang S, Chen J, Lu R, ..., Liu C (2018) Rapid generation of barley mutant lines with high nitrogen uptake efficiency by microspore mutagenesis and field screening. Front Plant Sci 9:450

Gavazzi G, Tonelli C, Todesco G, Arreghini E, Raffaldi F, Vecchio F, ..., Sala F (1987) Somaclonal variation versus chemically induced mutagenesis in tomato (Lycopersicon esculentum L). Theor Appl Genet 74:733–738

Gémes-Juhász A, Balogh P, Ferenczy A, Kristóf Z (2002) Effect of optimal stage of female gametophyte and heat treatment on in vitro gynogenesis induction in cucumber (Cucumis sativus L). Plant Cell Rep 21:105–111CrossRef

Gilles LM, Khaled A, Laffaire JB, Chaignon S, Gendrot G, Laplaige J, ... Widiez T (2017) Loss of pollen‐specific phospholipase NOT LIKE DAD triggers gynogenesis in maize. EMBO J 36(6):707–717

Gritsenko D, Daurova A, Pozharskiy A, Nizamdinova G, Khusnitdinova M, Sapakhova Z, Daurov D, Zhapar K, Shamekova M, Kalendar R, Zhambakin K (2023) Investigation of mutation load and rate in androgenic mutant lines of rapeseed in early generations evaluated by high-density SNP genotyping. Heliyon 9:e14065CrossRef

Guha S, Maheshwari SC (1964) In vitro production of embryos from anthers of Datura. Nature 204(4957):497–497CrossRef

Gurushidze M, Trautwein H, Hoffmeister P, Otto I, Müller A, Kumlehn J (2017) Doubled haploidy as a tool for chimaera dissolution of talen-induced mutations in barley. Biotechnol. Plant Mut Breed Protocols, 129–141

Harland SC (1920) A note on a peculiar type of “rogue” in Sea Island cotton. Agr News, Barbados, pp 19–29

Hazem F, Golabadi M (2018) Use of chemical mutagens for production of inactive pollen grains, embryo rescue, and morphological changes in cucumber. Turk J Agric for 42(1):11–21CrossRef

Henikoff S, Comai L (2003) Single-nucleotide mutations for plant functional genomics. Annu Rev Plant Biol 54(1):375–401CrossRef

Hoffie RE, Otto I, Hisano H, Kumlehn J (2021) Site-directed mutagenesis in barley using RNA-guided Cas endonucleases during microspore-derived generation of doubled haploids. Doubled Haploid Technology: Volume 1: General Topics, Alliaceae, Cereals, pp 199–214

Hooghvorst I, Ribas P, Nogués S (2020) Chromosome doubling of androgenic haploid plantlets of rice (Oryza sativa) using antimitotic compounds. Plant Breeding 139(4):754–761CrossRef

Hoseman D, Bossoutrot D (1983) Induction of haploid plants from in vitro culture of unpollinated beet (Beta vulgaris L.). Z Pflanzenzuchtg 91:74–77

Hsing YI, Chern CG, Fan MJ, Lu PC, Chen KT, Lo SF, ..., Yu SM (2007) A rice gene activation/knockout mutant resource for high throughput functional genomics. Plant Mol Boil 63:351–364

Huang B (1992) Genetic manipulation of microspores and microspore-derived embryos. In: vitro Cell. Develop Biol Plant, pp 53–58

Hugdahl JD, Morejohn LC (1993) Rapid and reversible high-afnity binding of the dinitroaniline herbicide oryzalin to tubulin from Zea mays L. Plant Physiol 102:725–740CrossRef

Hwang SG, Lee SC, Lee J, Lee JW, Kim JH. Choi SY, ..., Jang CS (2020) Resequencing of a core rice mutant population induced by gamma-ray irradiation and its application in a genome-wide association study. J Plant Biol 63:463–472

Ibrahim R, Ahmad Z, Salleh S, Hassan AA, Ariffin S (2018) Mutation breeding in ornamentals. Ornamental crops, pp 175–211

Jain SM, Ahloowalia BS, Veilleux RE (1998) Somaclonal variation in crop improvement, pp 203–218

Jensen CJ (1974) Chromosome doubling techniques in haploids. In: Haploids in higher plants: advances and potential, pp 151–190

Jiang C, Lei M, Guo Y, Gao G, Shi L, Jin Y, ..., Yang P (2022) A reference-guided TILLING by amplicon-sequencing platform supports forward and reverse genetics in barley. Plant Commun 3(4):100317

Kasha KJ (2005) Chromosome doubling and recovery of doubled haploid plants. Haploids in Crop Improvement II:123–152CrossRef

Kasha KJ, Hu TC, Oro R, Simion E, Shim YS (2001) Nuclear fusion leads to chromosome doubling during mannitol pretreatment of barley (Hordeum vulgare L.) microspores. J Exp Bot 52(359):1227–1238

Kasha KJ, Kao KN (1970) High frequency haploid production in barley (Hordeum vulgare L). Nature 225:874–876

Kelliher T, Starr D, Richbourg L, Chintamanani S, Delzer B, Nuccio ML, ... Martin B (2017) MATRILINEAL, a sperm-specific phospholipase, triggers maize haploid induction. Nature 542(7639):105–109

Kelliher T, Starr D, Su X, Tang G, Chen Z, Carter J, ..., Que Q (2019) One-step genome editing of elite crop germplasm during haploid induction. Nat Biotechnol 37(3):287–292

Khan AJ, Hassan S, Tariq M, Kahn T (2001) Haploidy breeding and mutagenesis for drought tolerance in wheat. Euphytica 120:409–414CrossRef

Khan AJ, Hassan S, Tariq M, Khan T (2002) Haploidy breeding and mutagenesis for drought tolerance in wheat. Mutations, In vitro and molecular techniques for environmentally sustainable crop improvement, pp 75–82

Kim DS, Lee IS, Jang CS, Hyun DY, Lee SJ, Seo YW, Lee YI (2003) Selection of 5-methyltryptophan and S-(2-aminoethyl)-L-cysteine resistant microspore-derived rice cell lines irradiated with gamma rays. J Plant Biotech 5(1):33–41

Kopecký D, Vagera J (2005) The use of mutagens to increase the efficiency of the androgenic progeny production in Solanum nigrum. Biol Plant 49:181–186CrossRef

Kott L (1998) Application of doubled haploid technology in breeding of oilseed Brassica napus. AgBiotech News Inform 10:69N-74N

Krishnan A, Guiderdoni E, An G, Hsing YIC, Han CD, Lee MC, ... Pereira A (2009) Mutant resources in rice for functional genomics of the grasses. Plant Physiol 149(1):165–170

Kyin SM, Khine OA, Khin S (2005) Development of a short duration upland rice mutant line through anther culture of gamma irradiated plants. Mutat Breed News Lett Rev 1:13–14

Lee JH, Lee SY (2002) Selection of stable mutants from cultured rice anthers treated with ethyl methane sulfonic acid. Plant Cell Tissue Organ Cult 71:165–171CrossRef

Lee SY, Cheong JI, Kim TS (2003) Production of doubled haploids through anther culture of M 1 rice plants derived from mutagenized fertilized egg cells. Plant Cell Rep 22:218–223CrossRef

Liu C, Li X, Meng D, Zhong Y, Chen C, Dong X, ..., Chen S (2017) A 4-bp insertion at ZmPLA1 encoding a putative phospholipase a generates haploid induction in maize. Mol Plant 10(3):520–522

Liu H, Wang K, Jia Z, Gong Q, Lin Z, Du L, ..., Ye X (2020) Efficient induction of haploid plants in wheat by editing of TaMTL using an optimized Agrobacterium-mediated CRISPR system. J Exp Bot 71(4):1337–1349

Liu S, Wang H, Zhang J, Fitt BD, Xu Z, Evans N, ..., Guo X (2005) In vitro mutation and selection of doubled-haploid Brassica napus lines with improved resistance to Sclerotinia sclerotiorum. Plant Cell Rep 24:133–144

Lu Y, Chen J, Xiao M, Li W, Miller DD (2012) An overview of tubulin inhibitors that interact with the colchicine binding site. Pharm Res 29:2943–2971CrossRef

Lu Y, Dai S, Gu A, Liu M, Wang Y, Luo S, ..., Shen S (2016) Microspore induced doubled haploids production from ethyl methanesulfonate (EMS) soaked flower buds is an efficient strategy for mutagenesis in Chinese cabbage. Front Plant Sci 7:1780

Lux H, Herrmann L, Wetzel C (1990) Production of haploid sugar beet (Beta vulgaris L.) by culturing unpollinated ovules. Plant Breed 104(3):177–183

Lv J, Yu K, Wei J, Gui H, Liu C, Liang D, ..., Kelliher T (2020) Generation of paternal haploids in wheat by genome editing of the centromeric histone CENH3. Nat Biotechnol 38(12):1397–1401

MacDonald MV, Ahmad I, Menten JOM, Ingram DS (1991) Haploid culture and in vitro mutagenesis (UV light, X-rays and gamma rays) of rapid cycling Brassica napus for improved resistance to disease. In: Plant mutation breeding for crop improvement. V. 2

Maluszynski M, Szarejko I, Sigurbjörnsson B (1996) Haploidy and mutation techniques. In: vitro haploid production in higher plants: Volume 1-Fundamental Aspects and Methods, pp 67–93

Marion-Poll A, Missonier C, Goujaud J, Caboche M (1988) Isolation and characterization of valine-resistant mutants of Nicotiana plumbaginifolia. Theor Appl Genet 75:272–277CrossRef

McClinchey SL, Kott LS (2008) Production of mutants with high cold tolerance in spring canola (Brassica napus). Euphytica 162:51–67CrossRef

Monakhos SG, Nguen ML, Bezbozhnaya AV, Monakhos GF (2014) A relationship between ploidy level and the number of chloroplasts in stomatal guard cells in diploid and amphidiploid Brassica species. Ceльcкoxoзяйcтвeннaя Биoлoгия 5:44–54

Nirwan S, Chatterjee A, Tewari AK, Sharma P, Agnihotri A, Shrivastava N (2022) Biochemical profiling of Brassica juncea doubled haploid mutant genotypes under white rust disease stress. Res Crop 23(3):574–583

Pauk J, Hasan MS, Puolimatka M, Lantos C, Mihály R, Mesterhazy A, ..., Matuz J (2004) Microspore and anther culture improvements for wheat breeding. In: In vitro application in crop improvement, pp 151–172

Polsoni L, Kott LS, Beversdorf WD (1988) Large-scale microspore culture technique for mutation–selection studies in Brassica napus. Canad. J Bot 66(8):1681–1685CrossRef

Ram H, Soni P, Salvi P, Gandass N, Sharma A, Kaur A, Sharma TR (2019) Insertional mutagenesis approaches and their use in rice for functional genomics. Plants 8(9):310CrossRef

Ravi M, Chan SWL (2010) Haploid plants produced by centromere- mediated genome elimination. Nature 464:615–618CrossRef

Ravi M, Marimuthu MPA, Tan EH, Maheshwari S, Henry IM, Marin-Rodriguez B, ..., Chan SW (2014) A haploid genetics toolbox for Arabidopsis thaliana. Nat Commun 5(1):5334

Ruiz RT, Haupt W, Haberer G (1998) The use of balanced lines for preservation of mutants in Arabidopsis and other plants. J Exp Bot 49(326):1597–1601CrossRef

San Noeum LH (1979) In vitro induction of gynogenesis in higher plants. In: Broadening genetics base crops: proceedings conference, pp 327–329

San LH, Gelebart P (1986) Production of gynogenetic haploids. Plant reg genet Var, pp 305–322

Sanei M, Pickering R, Kumke K, Nasuda S, Houben A (2011) Loss of centromeric histone H3 (CENH3) from centromeres precedes uniparental chromosome elimination in interspecific barley hybrids. Proc Natl Acad Sci 108(33):498–505CrossRef

Schieder O (1976) Isolation of mutants with altered pigments after irradiating haploid protoplasts from Datura innoxia Mill. with X-rays. Mol Genet Genom 149(3):251–254

Sen A (2017) Retrotransposon insertion variations in doubled haploid bread wheat mutants. Plant Growth Regul 81:325–333CrossRef

Shariatpanahi ME, Ahmadi B (2016) Isolated microspore culture and its applications in plant breeding and genetics. In: Anis M, Ahmad N (eds) Plant tissue culture: propagation, conservation and crop improvement. Springer, Singapore, pp 487–507CrossRef

Shariatpanahi ME, Ebrahimzadeh H, Niazian M, Eskandari A, Ahmadi B (2018) Amino acids and cycocel application to enhance cucumber haploid embryogenesis with gamma irradiated pollen. FAO/IAEA international symposium on plant mutation breeding and biotechnology; Vienna (Austria); IAEA-CN–263-93

Shariatpanahi ME, Niazian M, Ahmadi B (2021) Methods for chromosome doubling. Doubled Haploid Technology: Volume 1: General Topics, Alliaceae, Cereals, pp 127–148

Shen Y, Pan G, Lübberstedt T (2015) Haploid strategies for functional validation of plant genes. Trends Biotechnol 33(10):611–620CrossRef

Shrivastava V, Savarimuthu A, Patil M, Sarkar P, Hadole S, Dasgupta S (2021) Gametic embryogenesis and callogenesis in isolated microspore culture of Jatropha curcas L. a recalcitrant bioenergy crop. Plant Cell Tissue Organ Cult 144:359–370CrossRef

Shtereva LA, Zagorska NA, Dimitrov BD, Kruleva MM, Oanh HK (1998) Induced androgenesis in tomato (Lycopersicon esculentum Mill. II). Factors affecting induction of androgenesis. Plant Cell Rep 18:312–317CrossRef

Shu QY (2009) Turning plant mutation breeding into a new era: molecular mutation breeding. Induced Plant Mutations in the Genomic Era. FAO, Rome, pp 425–427

Song H, Lou QF, Luo XD, Wolukau JN, Diao WP, Qian CT, Chen JF (2007) Regeneration of doubled haploid plants by androgenesis of cucumber (Cucumis sativus) L. Plant Cell Tissue Organ Cult 90:245–254CrossRef

Spencer-Lopes MM, Forster BP, Jankuloski L (2018) Manual on mutation breeding. No. Ed. 3. Food and agriculture organization of the united nations (FAO)

Stemple DL (2004) TILLING—a high-throughput harvest for functional genomics. Nat Rev Genet 5(2):145–151CrossRef

Sumaryati S, Negrutiu I, Jacobs M (1992) Characterization and regeneration of salt-and water-stress mutants from protoplast culture of Nicotiana plumbaginifolia (Viviani. Theor Appl Genet 83:613–619CrossRef

Sunderland N, Roberts M, Evans LJ, Wildon DC (1979) Multicellular pollen formation in cultured barley anthers: I. Independent division of the generative and vegetative cells. J Exp Botany J Exp Bot 30(6):1133–1144

Swanson EB, Coumans MP, Brown GL, Patel JD, Beversdorf WD (1988) The characterization of herbicide tolerant plants in Brassica napus L. after in vitro selection of microspores and protoplasts. Plant Cell Rep 7:83–87CrossRef

Swanson EB, Herrgesell MJ, Arnoldo M, Sippell DW, Wong RSC (1989) Microspore mutagenesis and selection: canola plants with field tolerance to the imidazolinones. Theor Appl Genet 78:525–530CrossRef

Szarejko I (2003) Doubled haploid mutant production. Doubled haploid production in crop plants: a manual, 351–361

Szarejko I (2012) Haploid mutagenesis. In: Plant mutation breeding and biotechnology, pp 387–410

Szarejko I, Forster BP (2007) Doubled haploidy and induced mutation. Euphytica 158:359–370CrossRef

Szarejko I, Guzy J, Jimenez DJ, Roland Chavez A, Maluszynski M (1995) Production of mutants using barley DH systems. Induced mutations and molecular techniques for crop improvement. IAEA, Vienna, pp 517–530

Szarejko I, Szurman-Zubrzycka M, Nawrot M, Marzec M, Gruszka D, Kurowska M, ..., Maluszynski M (2017) Creation of a TILLING population in barley after chemical mutagenesis with sodium azide and MNU. In: Biotechnologies for plant mutation breeding; Springer: Cham, Switzerland, pp 91–111

Tajedini S, Fakheri B, Niazian M, Mahdinezhad N, Ghanim AMA, Kazemi Pour A, ..., Shariatpanahi ME (2022) Efficient Microspore Embryogenesis and Haploid Induction in Mutant Indica Rice (Oryza sativa L.) Cultivars. J Plant Growth Regul, 1–15

Tuvesson SD, Larsson CT, Ordon F (2021) Use of molecular markers for doubled haploid technology: from academia to plant breeding companies. Doubled Haploid technology: Volume 2: Hot Topics, Apiaceae, Brassicaceae, Solanaceae, pp 49–72

Turner J, Facciotti D (1990) High oleic acid Brassica napus from mutagenized microspores. In: Proceedings 6th crucifer genetics workshop, Geneva, pp 24

Udage AC (2021) Introduction to plant mutation breeding: Different approaches and mutagenic agents. J Agric Sci Sri Lanka 16:466–483

Vagera J, Novotný J, Ohnoutková L (2004) Induced androgenesis in vitro in mutated populations of barley, Hordeum vulgare. Plant Cell Tissue Organ Cult 77:55–61CrossRef

Van den Bulk RW, Löffler HJM, Lindhout WH, Koornneef M (1990) Somaclonal variation in tomato: effect of explant source and a comparison with chemical mutagenesis. Theor Appl Genet 80:817–825CrossRef

Wang N, Gent JI, Dawe RK (2021) Haploid induction by a maize cenh3 null mutant. Sci Adv 7(4):eabe2299

Wang Y, Cheng X, Shan Q, Zhang Y, Liu J, Gao C, Qiu JL (2014) Simultaneous editing of three homoeoalleles in hexaploid bread wheat confers heritable resistance to powdery mildew. Nat Biotech 32(9):947–951CrossRef

Watts A, Singh SK, Bhadouria J, Naresh V, Bishoyi AK, Geetha KA, ..., Bhat SR (2017) Brassica juncea lines with substituted chimeric GFP-CENH3 give haploid and aneuploid progenies on crossing with other lines. Front Plant Sci 7:2019

Wu BJ, Chen KC (1982) Cytological and embryological studies on haploid plant production from cultured unpollinated ovaries of Nicotiana tabacum L. Act Bot Sin 24:125–129

Wong RSC, Swanson E (1991) Genetic modification of canola oil: high oleic acid canola. In: Haberstroh C, Morris CE (eds) Fat and cholesterol reduced food. Gulf, Houston, pp 154–164

Wu JL, Wu C, Lei C, Baraoidan M, Bordeos A, Madamba MRS, ..., Leung H (2005) Chemical-and irradiation-induced mutants of indica rice IR64 for forward and reverse genetics. Plant Mol Boil 59:85–97

Yali W, Mitiku T (2022) Mutation breeding and its importance in modern plant breeding. J Plant Sci 10(2):64–70

Yao L, Zhang Y, Liu C, Liu Y, Wang Y, Liang D, ..., Kelliher T (2018) OsMATL mutation induces haploid seed formation in indica rice. Nat Plant 4(8):530–533

Zapata FJ (1986) Induction of salt tolerance in high yielding rice varieties through mutagenesis and anther culture. Current options for cereal improvement, pp 193–202

Zhai Z, Sooksa-nguan T, Vatamaniuk OK (2009) Establishing RNA interference as a reverse-genetic approach for gene functional analysis in protoplasts. Plant Physiol 149(2):642–652CrossRef

Zhang X, Shi C, Li S, Zhang B, Luo P, Peng X, ..., Sun MX (2023) A female in vivo haploid-induction system via mutagenesis of egg cell-specific peptidases. Molec Plant 16(2):471–480

Zhang YX, Bouvier L, Lespinassei Y (1992) Microspore embryogenesis induced by low gamma dose irradiation in apple. Plant Breed 108(2):173–176CrossRef

Zhao X, Yuan K, Liu Y, Zhang N, Yang L, Zhang Y, ..., Lv H (2022) In vivo maternal haploid induction based on genome editing of DMP in Brassica oleracea. Plant Biotechnol J 20(12):2242–2244

Zhong YU, Liu C, Qi X, Jiao Y, Wang D, Wang Y, ... Chen S (2019) Mutation of ZmDMP enhances haploid induction in maize. Nat Plants 5(6):575–580

Zhong Y, Wang Y, Chen B, Liu J, Wang D, Li M, ..., Chen S (2022) Establishment of a dmp based maternal haploid induction system for polyploid Brassica napus and Nicotiana tabacum. J Integr Plant Biol 64(6):1281–1294

Titel: Haploid System in Mutation Breeding
verfasst von: Rasoul Amirian
Mehran E. Shariatpanahi
Golnoosh Taghiabadi
Verlag: Springer Nature Switzerland
Buch: Plant Mutagenesis
Print ISBN: 978-3-031-50728-1

Electronic ISBN: 978-3-031-50729-8

Copyright-Jahr: 2024
DOI: https://doi.org/10.1007/978-3-031-50729-8_6

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