Affinity hierarchies and amphiphilic proteins underlie the co-assembly of nucleolar and heterochromatin condensates.

Srivarsha Rajshekar, Omar Adame-Arana, Gaurav Bajpai, Serafin Colmenares, Kyle Lin, Samuel Safran, Gary H Karpen
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Abstract

Nucleoli are surrounded by Pericentromeric Heterochromatin (PCH), reflecting a close spatial association between the two largest biomolecular condensates in eukaryotic nuclei. Nucleoli are the sites of ribosome synthesis, while the repeat-rich PCH is essential for chromosome segregation, genome stability, and transcriptional silencing. How and why these two distinct condensates co-assemble is unclear. Here, using high-resolution live imaging of Drosophila embryogenesis, we find that de novo establishment of PCH around the nucleolus is highly dynamic, transitioning from the nuclear edge to surrounding the nucleolus. Eliminating the nucleolus by removing the ribosomal RNA genes (rDNA) resulted in increased PCH compaction and subsequent reorganization into a toroidal structure. In addition, in embryos lacking rDNA, some nucleolar proteins were redistributed into new bodies or 'neocondensates', including enrichment in the PCH toroidal hole. Combining these observations with physical modeling revealed that nucleolar-PCH associations can be mediated by a hierarchy of interaction strengths between PCH, nucleoli, and 'amphiphilic' protein(s) that have affinities for both nucleolar and PCH components. We validated this model by identifying a candidate amphiphile, a DEAD-Box RNA Helicase called Pitchoune, whose depletion or mutation of its PCH interaction motif disrupted PCH-nucleolar associations. Together, this study unveils a dynamic program for establishing nucleolar-PCH associations during animal development, demonstrates that nucleoli are required for normal PCH organization, and identifies Pitchoune as an amphiphilic molecular link required for PCH-nucleolar associations.

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亲和层次和两亲性蛋白质是核仁和异染色质缩合物共同组装的基础。
细胞核被着丝粒周围异染色质(PCH)包围,反映了真核中两个最大的生物分子缩合物之间的紧密空间联系。这种核组织特征是高度保守的,在衰老等疾病状态下会被破坏,然而,驱动PCH-核仁结合的机制尚不清楚。果蝇早期发育过程中的高分辨率实时成像揭示了一个高度动态的过程,在这个过程中PCH和核仁的形成是协调和相互依赖的。当通过删除核糖体RNA基因(rDNA)来消除核仁组装时,PCH表现出增强的压实和随后的壳状结构重组。此外,在缺乏rDNA的胚胎中,一些核仁蛋白被重新分配到新的身体或“新缩合物”中,包括PCH外壳核心的富集。这些观察结果,结合物理建模和模拟,表明核仁与PCH的结合是由PCH、核仁和与核仁和PCH成分相互作用的“两亲性”蛋白之间的亲和力层次介导的。这一结果通过证明一种候选两亲物,即核仁蛋白Pitchoune的缺失,显著减少了PCH与核仁的结合而得到验证。总之,这些结果揭示了在动物发育过程中建立核仁-PCH结合的动态程序,证明了正常的PCH组织所需的核仁,并确定了Pitchoune是促进PCH-核仁结合的两亲性分子连接。最后,我们提出,破坏相互作用的缩合物之间的亲和力层次可以释放分子,形成新缩合物或其他可能导致细胞疾病表型的异常结构。
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