Accurate chromosome segregation during meiosis relies on the presence of crossover events distributed among all chromosomes. MutSγ and MutLγ homologs (Msh4/5 and Mlh1/3) facilitate the formation of a prominent group of meiotic crossovers that mature within the context of an elaborate chromosomal structure called the synaptonemal complex (SC). SC proteins are required for intermediate steps in the formation of MutSγ-MutLγ crossovers, but whether the assembled SC structure per se is required for MutSγ-MutLγ-dependent crossover recombination events is unknown. Here we describe an interspecies complementation experiment that reveals that the mature SC is dispensable for the formation of Mlh3-dependent crossovers in budding yeast. Zip1 forms a major structural component of the budding yeast SC, and is also required for MutSγ and MutLγ-dependent crossover formation. Kluyveromyces lactis ZIP1 expressed in place of Saccharomyces cerevisiae ZIP1 in S. cerevisiae cells fails to support SC assembly (synapsis) but promotes wild-type crossover levels in those nuclei that progress to form spores. While stable, full-length SC does not assemble in S. cerevisiae cells expressing K. lactis ZIP1, aggregates of K. lactis Zip1 displayed by S. cerevisiae meiotic nuclei are decorated with SC-associated proteins, and K. lactis Zip1 promotes the SUMOylation of the SC central element protein Ecm11, suggesting that K. lactis Zip1 functionally interfaces with components of the S. cerevisiae synapsis machinery. Moreover, K. lactis Zip1-mediated crossovers rely on S. cerevisiae synapsis initiation proteins Zip3, Zip4, Spo16, as well as the Mlh3 protein, as do the crossovers mediated by S. cerevisiae Zip1. Surprisingly, however, K. lactis Zip1-mediated crossovers are largely Msh4/Msh5 (MutSγ)-independent. This separation-of-function version of Zip1 thus reveals that neither assembled SC nor MutSγ is required for Mlh3-dependent crossover formation per se in budding yeast. Our data suggest that features of S. cerevisiae Zip1 or of the assembled SC in S. cerevisiae normally constrain MutLγ to preferentially promote resolution of MutSγ-associated recombination intermediates.
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机译:减数分裂过程中准确的染色体分离取决于所有染色体之间分布的交换事件的存在。 MutSγ和MutLγ同源物(Msh4 / 5和Mlh1 / 3)有助于形成一组明显的减数分裂交叉点,它们在称为突触复合体(SC)的复杂染色体结构的背景下成熟。 SC蛋白是MutSγ-MutLγ交叉反应形成过程中的中间步骤所必需的,但尚不清楚组装的SC结构本身是否是MutSγ-MutLγ依赖性交叉重组事件所必需的。在这里,我们描述了一个种间互补实验,该实验揭示了成熟的SC对于萌芽酵母中Mlh3依赖型交换的形成是必不可少的。 Zip1形成了发芽酵母SC的主要结构成分,也是MutSγ和MutLγ依赖的交叉形成所必需的。在酿酒酵母细胞中表达的乳酸克鲁维酵母ZIP1代替酿酒酵母ZIP1不能支持SC组装(突触),但会促进那些逐渐形成孢子的细胞核中的野生型交叉水平。虽然稳定的全长SC不能在表达乳酸克鲁维酵母ZIP1的啤酒酵母细胞中组装,但是由啤酒酵母减数分裂核显示的乳酸克鲁维酵母Zip1的聚集体装饰有SC相关蛋白,而乳酸克鲁维酵母Zip1促进SUMOylation SC中央元素蛋白Ecm11的克隆,表明K. lactis Zip1在功能上与 S 的组件连接。 cerevisiae 突触机器。此外, K 。 lactis Zip1介导的交叉依赖于 S 。 啤酒突触起始蛋白Zip3,Zip4,Spo16以及Mlh3蛋白,以及 S 介导的交叉。 cerevisiae Zip1。但是,令人惊讶的是, K 。 lactis Zip1介导的交换很大程度上独立于Msh4 / Msh5(MutSγ)。因此,这种功能分离形式的Zip1揭示出,萌芽酵母本身不依赖Mlh3的交换形成 既不需要组装的SC也不需要MutSγ。我们的数据表明 S 的功能。 cerevisiae Zip1或 S 中组装的SC。 cerevisiae 通常限制MutLγ以优先促进与MutSγ相关的重组中间体的分离。
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