Abstract
The conservation of orthologs of most subunits of the origin recognition complex (ORC) has served to propose that the whole complex is common to all eukaryotes. However, various uncertainties have arisen concerning ORC subunit composition in a variety of lineages. Also, it is unclear whether the ancestral diversification of ORC in eukaryotes was accompanied by the neofunctionalization of some subunits, for example, role of ORC1 in centriole homeostasis. We have addressed these questions by reconstructing the distribution and evolutionary history of ORC1-5/CDC6 in a taxon-rich eukaryotic data set. First, we identified ORC subunits previously undetected in divergent lineages, which allowed us to propose a series of parsimonious scenarios for the origin of this multiprotein complex. Contrary to previous expectations, we found a global tendency in eukaryotes to increase or decrease the number of subunits as a consequence of genome duplications or streamlining, respectively. Interestingly, parasites show significantly lower number of subunits than free-living eukaryotes, especially those with the lowest genome size and gene content metrics. We also investigated the evolutionary origin of the ORC1 role in centriole homeostasis mediated by the PACT region in human cells. In particular, we tested the consequences of reducing ORC1 levels in the centriole-containing green alga Chlamydomonas reinhardtii. We found that the proportion of centrioles to flagella and nuclei was not dramatically affected. This, together with the PACT region not being significantly more conserved in centriole-bearing eukaryotes, supports the notion that this neofunctionalization of ORC1 would be a recent acquisition rather than an ancestral eukaryotic feature.
Highlights
DNA replication is essential for the maintenance of the genetic integrity in any cellular lineage
Our phylogenetic tree, constructed from a subsampling of taxa, shows all eukaryotic subunits (i.e., Cell Division Cycle 6 (CDC6) and ORC1–ORC5) branching in a separate clade than the archaeal homologs (100% nodal support). This suggests that all eukaryotic subunits (CDC6þORC1-5) originated from a single archaeal paralog and not from distinct paralogs as previously suggested (Makarova and Koonin 2013), with a first duplication leading to pre-CDC6/ORC1 and to pre-ORC2-5 paralogs
In ORC1, AAAþ ATPase is the only domain conserved, whereas the Bromo adjacent homology domain (BAH) and C-terminal winged helix (Cdc6_C) are both patchily distributed, the last only found in Holozoa (Metazoa þ relatives) and Holomycota (Fungi þ relatives)
Summary
DNA replication is essential for the maintenance of the genetic integrity in any cellular lineage. The first event in DNA replication is the specification of potential DNA replication origins (ORIs) by the formation of a stable complex of initiator proteins (Yeeles et al 2015), a process where the AAAþ ATPases are crucial and a common feature of Bacteria, Archaea, and eukaryotes (Duderstadt and Berger 2008). Potential ORIs are specified by the formation of prereplication complexes by binding of the origin recognition complex (ORC) and the sequential assembly of Cell Division Cycle 6 (CDC6), CDC10-dependent transcription factor 1 (CDT1), and the minichromosome maintenance (MCM) protein complex (Yeeles et al 2015).
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