Multiple aspects of amyloid dynamics in vivo integrate to establish prion variant dominance in yeast

IF 3.5 3区医学 Q2 NEUROSCIENCES

Frontiers in Molecular Neuroscience Pub Date : 2024-07-30 DOI:10.3389/fnmol.2024.1439442

Jennifer Norton, Nicole Seah, Fabian Santiago, Suzanne S. Sindi, Tricia R. Serio

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Abstract

Prion variants are self-perpetuating conformers of a single protein that assemble into amyloid fibers and confer unique phenotypic states. Multiple prion variants can arise, particularly in response to changing environments, and interact within an organism. These interactions are often competitive, with one variant establishing phenotypic dominance over the others. This dominance has been linked to the competition for non-prion state protein, which must be converted to the prion state via a nucleated polymerization mechanism. However, the intrinsic rates of conversion, determined by the conformation of the variant, cannot explain prion variant dominance, suggesting a more complex interaction. Using the yeast prion system [PSI+], we have determined the mechanism of dominance of the [PSI+]Strong variant over the [PSI+]Weak variant in vivo. When mixed by mating, phenotypic dominance is established in zygotes, but the two variants persist and co-exist in the lineage descended from this cell. [PSI+]Strong propagons, the heritable unit, are amplified at the expense of [PSI+]Weak propagons, through the efficient conversion of soluble Sup35 protein, as revealed by fluorescence photobleaching experiments employing variant-specific mutants of Sup35. This competition, however, is highly sensitive to the fragmentation of [PSI+]Strong amyloid fibers, with even transient inhibition of the fragmentation catalyst Hsp104 promoting amplification of [PSI+]Weak propagons. Reducing the number of [PSI+]Strong propagons prior to mating, similarly promotes [PSI+]Weak amplification and conversion of soluble Sup35, indicating that template number and conversion efficiency combine to determine dominance. Thus, prion variant dominance is not an absolute hierarchy but rather an outcome arising from the dynamic interplay between unique protein conformations and their interactions with distinct cellular proteostatic niches.

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体内淀粉样蛋白动态的多个方面结合在一起，确立了酵母中的朊病毒变体优势

朊病毒变体是一种蛋白质的自我延续构象，它们组装成淀粉样纤维，并赋予独特的表型状态。多种朊病毒变体可能会出现，尤其是在环境发生变化时，并在生物体内相互作用。这些相互作用通常是竞争性的，其中一种变体会建立对其他变体的表型优势。这种优势与非朊病毒状态蛋白质的竞争有关，这种蛋白质必须通过有核聚合机制转化为朊病毒状态。然而，由变体构象决定的内在转化率无法解释朊病毒变体的优势，这表明存在更复杂的相互作用。我们利用酵母朊病毒系统[PSI+]，确定了[PSI+]强变体在体内对[PSI+]弱变体的优势机制。当交配混合时，表型优势在子代中确立，但两种变体在该细胞的后代中持续共存。正如利用 Sup35 的变体特异性突变体进行的荧光光漂白实验所揭示的那样，[PSI+]强传播子（可遗传单位）通过可溶性 Sup35 蛋白的有效转化，以牺牲[PSI+]弱传播子为代价而被放大。然而，这种竞争对[PSI+]强淀粉样纤维的碎裂高度敏感，即使是对碎裂催化剂Hsp104的短暂抑制也会促进[PSI+]弱传播子的放大。在交配前减少[PSI+]强传播子的数量，同样会促进[PSI+]弱传播子的扩增和可溶性 Sup35 的转化，这表明模板数量和转化效率共同决定了优势。因此，朊病毒变体的优势并不是一个绝对的等级，而是独特的蛋白质构象及其与不同细胞蛋白静态位点之间相互作用的动态结果。

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来源期刊

Frontiers in Molecular Neuroscience NEUROSCIENCES-

CiteScore

5.70

自引率

2.10%

发文量

669

审稿时长

14 weeks

期刊介绍： Frontiers in Molecular Neuroscience is a first-tier electronic journal devoted to identifying key molecules, as well as their functions and interactions, that underlie the structure, design and function of the brain across all levels. The scope of our journal encompasses synaptic and cellular proteins, coding and non-coding RNA, and molecular mechanisms regulating cellular and dendritic RNA translation. In recent years, a plethora of new cellular and synaptic players have been identified from reduced systems, such as neuronal cultures, but the relevance of these molecules in terms of cellular and synaptic function and plasticity in the living brain and its circuits has not been validated. The effects of spine growth and density observed using gene products identified from in vitro work are frequently not reproduced in vivo. Our journal is particularly interested in studies on genetically engineered model organisms (C. elegans, Drosophila, mouse), in which alterations in key molecules underlying cellular and synaptic function and plasticity produce defined anatomical, physiological and behavioral changes. In the mouse, genetic alterations limited to particular neural circuits (olfactory bulb, motor cortex, cortical layers, hippocampal subfields, cerebellum), preferably regulated in time and on demand, are of special interest, as they sidestep potential compensatory developmental effects.