In vitro Culture of Heat-treated Anthers Induces Embryogenic Callus in Cassava (Manihot esculenta Crantz)

Buttibwa M Kawuki Rs, B. Oshaba, M. Eyokia, C. Hershey, Perera Pip, E. Heberle‐Bors, Y. Baguma, A. Tugume
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引用次数: 1

Abstract

Microspore embryogenesis is the developmental plasticity of juvenile male gametophytes to switch from pollen to embryo development upon exposure to in vitro stress. It is a common method for obtaining haploid and doubled haploid plants in breeding programs for development of superior varieties via haploid-diploidization which allows fast development of homozygous lines from heterozygous parents. In cassava, obtaining haploidization through traditional methods of successive selfing is difficult because of cassava’s long reproductive cycle, high heterozygosity, and inbreeding depression. As a first step towards microspore embryogenesis, callus induction following heat treatment has not been investigated in cassava. We used two elite Ugandan cassava varieties, hereafter called “genotypes”, NASE3 and NASE14, for the study of callus induction. Heat stress of 40°C for 0, 6, 12, 18 and 24hrs and Murashige and Skoog medium supplemented with 2-9% sucrose, and 2,4-dichlorophenoxy acetic acid were used. Heating anthers of NASE3 at 40°C for 6 hrs resulted in a significantly higher percentage of callus induction on MS medium supplemented with 2% sucrose. Callus emerged from inside of the anthers with production influenced by genotype, sucrose concentration, anther density and duration in culture (P≤0.001). Limited in vitro callus differentiation was observed on auxin-and cytokinin-supplemented media. In both genotypes, embryo genic callus was obtained in liquid medium, while green callus was achieved on solid medium. This is a significant step upstream of double haploid plant production pathway in cassava: rigorous optimization of protocols downstream of callus induction are needed for regeneration of microspore-derived embryos and haploid plants.
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木薯热处理花药离体培养诱导胚性愈伤组织的研究
小孢子胚发生是雄性幼配子体在体外胁迫下由花粉向胚胎发育转变的发育可塑性。通过单倍体-二倍体分化获得单倍体和双单倍体植株是培育优良品种的一种常用方法,它可以使杂合亲本快速发育为纯合子系。在木薯中,由于木薯的繁殖周期长,杂合度高,近交抑制,通过传统的自交方法获得单倍体化是困难的。作为小孢子胚胎发生的第一步,热处理后的愈伤组织诱导尚未在木薯中进行过研究。以2个乌干达木薯优良品种NASE3和NASE14为研究对象,对其愈伤组织诱导进行了研究。采用40℃热应激0、6、12、18和24h,添加2-9%蔗糖和2,4-二氯苯氧基乙酸的Murashige和Skoog培养基。在添加2%蔗糖的MS培养基上,将NASE3花药在40℃下加热6 h,愈伤组织诱导率显著提高。愈伤组织的产生受基因型、蔗糖浓度、花药密度和培养时间的影响(P≤0.001)。在补充生长素和细胞分裂素的培养基上,愈伤组织的体外分化有限。两种基因型均在液体培养基上获得胚源性愈伤组织,在固体培养基上获得绿色愈伤组织。这是木薯双单倍体植株产生途径上游的重要一步,小孢子胚和单倍体植株的再生需要对愈伤组织诱导下游的工艺进行严格的优化。
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