Abstract
Centromeres are defined epigenetically in the majority of eukaryotes by the presence of chromatin containing the centromeric histone H3 variant CENP-A. Most species have a single gene encoding a centromeric histone variant whereas C. elegans has two: HCP-3 (also known as CeCENP-A) and CPAR-1. Prior RNAi replacement experiments showed that HCP-3 is the functionally dominant isoform, consistent with CPAR-1 not being detectable in embryos. GFP::CPAR-1 is loaded onto meiotic chromosomes in diakinesis and is enriched on bivalents until meiosis I. Here we show that GFP::CPAR-1 signal loss from chromosomes precisely coincides with homolog segregation during anaphase I. This loss of GFP::CPAR-1 signal reflects proteolytic cleavage between GFP and the histone fold of CPAR-1, as CPAR-1::GFP, in which GFP is fused to the C-terminus of CPAR-1, does not exhibit any loss of GFP signal. A focused candidate screen implicated separase, the protease that initiates anaphase by cleaving the kleisin subunit of cohesin, in this cleavage reaction. Examination of the N-terminal tail sequence of CPAR-1 revealed a putative separase cleavage site and mutation of the signature residues in this site eliminated the cleavage reaction, as visualized by retention of GFP::CPAR-1 signal on separating homologous chromosomes at the metaphase-anaphase transition of meiosis I. Neither cleaved nor uncleavable CPAR-1 were centromere-localized in mitosis and instead localized throughout chromatin, indicating that centromere activity has not been retained in CPAR-1. Although the functions of CPAR-1 and of its separase-dependent cleavage remain to be elucidated, this effort reveals a new substrate of separase and provides an in vivo biosensor to monitor separase activity at the onset of meiosis I anaphase.
Highlights
Centromeres direct chromosome segregation by building kinetochores, the protein machines that form dynamic attachments to spindle microtubules and function as scaffolds for signaling pathways that ensure accuracy in chromosome segregation [1,2]
We show that this signal loss likely reflects direct cleavage within the N-terminal tail of CPAR-1 by the protease separase
The high primary sequence homology (Fig 1B [16]) and intronic nucleotide sequence homology between hcp-3 and cpar-1 genomic loci suggests that this duplication is relatively recent
Summary
Centromeres direct chromosome segregation by building kinetochores, the protein machines that form dynamic attachments to spindle microtubules and function as scaffolds for signaling pathways that ensure accuracy in chromosome segregation [1,2]. The mechanisms that ensure propagation of CENP-A nucleosomal chromatin across cell division and the features of this specialized chromatin that direct kinetochore assembly are both areas of active investigation [6]. GFP::CPAR-1 signal is abruptly lost from chromosomes coincident with anaphase onset of meiosis I. We show that this signal loss likely reflects direct cleavage within the N-terminal tail of CPAR-1 by the protease separase. Both cleaved CPAR-1 and an uncleavable mutant of CPAR-1 are not centromere-localized in embryos, indicating that CPAR-1 has lost centromere activity. The functional significance of CPAR-1 cleavage by separase is currently unclear, these results reveal a new substrate for separase and provide a biosensor for precisely timing separase activation during meiosis I
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