[Efficiency of the Induction of Cytomixis in the Microsporogenesis of Dicotyledonous (N. tabacum L.) and Monocotyledonous (H. distichum L.) Plants by Thermal Stress].

Ontogenez Pub Date : 2016-11-01

Yu V Sidorchuk, E A Kravets, S R Mursalimov, S G Plokhovskaya, I I Goryunova, A I Yemets, Y B Blume, E V Deineko

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Abstract

The efficiencies of the induction of cytomixis in microsporogenesis by thermal stress are compared in tobacco (N. tabacum L.) and barley (H. distichum L.) It has been shown that different thermal treatment schedules (budding tobacco plants at 50°C and air-dried barley grains at 48°C) produce similar results in the species: the frequency of cytomixis increases, and its maximum shifts to later stages of meiosis. However, the species show differences in response. The cytomixis frequency increase in tobacco is more pronounced, and its maximum shifts from the zygotene–pachytene stages of meiotic prophase I to prometaphase–metaphase I. Later in the meiosis, aberrations in chromosome structure and meiotic apparatus formation typical of cytomixis are noted, as well as cytomixis activation in tapetum cells. Thermal stress disturbs the integration of callose- bearing vesicles into the callose wall. Cold treatment at 7°C does not affect cytomixis frequency in tobacco microsporogenesis. Incubation of barley seeds at 48°C activates cytomixis in comparison to the control, shifts its maximum from the premeiotic interphase to zygotene, and changes the habit of cytomictic interactions from pairwise contacts to the formation of multicellular clusters. Thermal treatment induces cytomictic interactions within the tapetum and between microsporocytes and the tapetum. However, later meiotic phases show no adverse consequences of active cytomixis in barley. It is conjectured that heat stress affects callose metabolism and integration into the forming callose wall, thereby causing incomplete closure of cytomictic channels and favoring intercellular chromosome migration at advanced meiotic stages.

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[通过热胁迫在双子叶植物（N.tabacum L.）和单子叶植物（H.distichum L.）的小孢子发生中诱导细胞融合的效率]。

在烟草（N. tabacum L.）和大麦（H. distichum L.）中比较了热胁迫诱导小孢子发生中细胞混合的效率。结果表明，不同的热处理方案（烟草植株在 50°C 下含苞待放和大麦粒在 48°C 下风干）在物种中产生了相似的结果：细胞混合的频率增加，其最大值转移到减数分裂的后期。然而，不同物种的反应却有所不同。烟草的细胞混合频率增加更明显，其最大值从减数分裂原期 I 的合子-幼子阶段转移到减数分裂后期 I。在减数分裂后期，染色体结构和减数装置的形成出现畸变，这是典型的细胞混合现象，同时在绦细胞中细胞混合现象也被激活。热应力干扰了含胼胝质的囊泡与胼胝质壁的结合。7°C 的冷处理不会影响烟草微孢子发生中的细胞混合频率。与对照组相比，将大麦种子置于 48°C 下孵育可激活细胞混合作用，将其最大值从减数分裂前期的间期移至子叶期，并改变细胞混合作用的习性，从成对接触转变为形成多细胞簇。热处理可诱导绦膜内部以及小孢子细胞与绦膜之间的胞体相互作用。不过，在大麦的减数分裂后期，活跃的细胞混合并没有造成不良后果。据推测，热胁迫影响了胼胝质的新陈代谢和与形成中的胼胝质壁的结合，从而导致细胞混交通道的不完全闭合，有利于减数第二次分裂后期的细胞间染色体迁移。

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Ontogenez

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