The first step towards eukaryotic genome duplication is loading of the replicative helicase, the Mcm2-7 complex, onto chromatin. This so-called “licensing” step is executed by the Pre-Replication Complex (Pre-RC) whose assembly on chromatin is nucleated by the DNA-binding activity of the Origin Recognition Complex (ORC). It is thought that metazoan ORC, like the yeast complex, is recruited directly to chromatin by its ATP-dependent DNA binding and encirclement activity. However, we have previously shown that this DNA binding mode is dispensable for chromatin recruitment of fly ORC, raising the question of how metazoan ORC binds chromosomes. We show here that the intrinsically disordered region (IDR) of fly Orc1 is both necessary and sufficient for the recruitment of ORC to chromosomes in vivo and demonstrate that this activity is regulated by IDR phosphorylation. In vitro studies show that the IDR alone binds DNA and this bestows the ORC holocomplex with a high-affinityATP-independentDNA binding mode. Interestingly, we find that Orc1 IDRs have diverged so markedly across metazoans that they are unrecognizable as orthologs and yet we find that these compositionally homologous sequences retain DNA and chromatin binding activity down to basal metazoans. Altogether, these data suggest that chromatin is recalcitrant to ORC’s ATP-dependent DNA binding activity and we propose that this necessitates IDR-dependent chromatin tethering which poises ORC to opportunistically encircle nucleosome-free regions as they become available. This work reveals a novel step in metazoan replication licensing and expands our understanding of disordered protein homology and evolution by stretching the relationship between primary structure and function.

README: The Origin Recognition Complex requires chromatin tethering by a hypervariable intrinsically disordered region that is functionally conserved from sponge to man

##Description of data

Notes:

**For "EMSA" data each includes replicate images of separate experiments and are named according to the construct (e.g., "WT", "D1-D6", or "DBP") and their replicate number (I.e., "1-3")

**For imaging data in FIG1A-FIG1B, each has the following six components:
1) a maximum intensity projection of the data (file name contains "MAX" description)
2) the background corrected and median filtered data (file name contains "BG_MEDIAN" description)
3) a sub-stack of three images derived from item 2 above (file name contains "Substack")
4) three individual images in jpg format from item 3 above (file name contains "0000" or "0001" or "0002")

**Imaging data in SFIG1E has the following five components
1) a maximum intensity projection of the data (file name contains "MAX" description)
2) a sub-stack of three images derived from item 2 above (file name contains "Substack")
3) three individual images in jpg format from item 3 above (file name contains "0000" or "0001" or "0002")

**Multiple images are associated with the western blot data in SFIG7 and images are named according to the primary antibody used (e.g., "antiHis" or "antiGFP") followed by the sample (e.g., "control" or "Orc1")

**The imaging data associated with FIG6F represent a time series of images which are named according to the two channels (i.e., "C1" and "C2") and their associated 12 images from early to late time points (I.e., "10000" to "10011"). These twenty four images are .jpg. The time points between the two channels are matched. The parent image stack (before separation of individual time points) is also included as a tif file and is named according to the channel (as above).

FIG1A: spinning disk imaging data of wild-type Orc1 in fly embryos
FIG1B: spinning disk imaging data of Orc1 delta IDR in fly embryos
FIG1C: spinning disk imaging data of Orc1 IDR alone in fly embryos
FIG1D: excel file for quantitation of FIG1A-C
FIG1E: spinning disk imaging data for S-phase nuclear enrichment of constructs in FIG1A-C
FIG1F: spinning disk imaging data of Orc1 IDR alone in S2 cells

FIG2A: excel file of raw fluorescence polarization readings for ORC DNA binding at 300 mM KGlutamate
FIG2B: excel file of raw fluorescence polarization readings for ORC DNA binding at 150 mM KGlutamate
FIG2C: excel file of raw fluorescence polarization readings for ORC delta IDR at 150 mM KGlutamate

FIG3B: excel file quantifying spinning disk imaging of Orc1 IDR chromatin partitioning in S2 cells
FIG3C: coomassie stained SDS-PAGE gel of IDR phosphorylated by CDK1/CycA
FIG3D: coomassie stained SDS-PAGE gel of IDR phosphorylated by CDK2/CycE
FIG3E: excel file for mass of intact mass spectrometry of phosphorylated IDR
FIG3F: excel file for liquid chromatography mass spectrometry to identify phosphorylation sites and PDF of sequence logo
FIG3H: image of agarose gel for EMSA analysis of Orc1 IDR DNA binding
FIG3I: excel file quantifying EMSA analysis in FIG3H
FIG3J: excel file of fluorescence polarization analysis of DNA binding by phosphorylated IDR
FIG3K: excel file of fluorescence polarization analysis of DNA binding by phosphorylated IDR (time resolved assay)

FIG4B: excel file quantifying EMSA analysis of IDR variants
FIG4C: excel file analyzing fraction charged residues in Orc1 IDR
FIG4D: vector graphic of Chi-Score Analysis of Drosophila Orc1 IDR

FIG5B: csv file of Orc1 IDR ortholog alignment
FIG5C: vector graphic of sequence similarity scores of Orc1 IDR and AAA orthologs
FIG5D: vector graphic of compositional homology scores of Orc1 IDR and AAA orthologs
FIG5E: excel file of ortholog Orc1 IDR isoelectric point (pI)

FIG6A: image of agarose gel for EMSA analysis of Orc1 IDR ortholog DNA binding
FIG6B: excel file of phosphorylation sites in Orc1 IDR orthologs
FIG6C: image of agarose gel for EMSA analysis of Orc1 IDR ortholog DNA binding with phosphorylation
FIG6D: excel file quantifying partitioning of Orc1 IDR orthologs onto chromatin in S2 cells in metaphase
FIG6E: excel file quantifying partitioning of Orc1 IDR orthologs onto chromatin in S2 cells through mitosis
FIG6F: excel file and image analyzing human Orc1 IDR binding to mitotic chromosomes in HeLa cells

SFIG1D: excel file of nuclear intensity of delta IDR Orc1 in embryos
SFIG1E: spinning disk imaging data of genomic Orc1 IDR transgene in embryos

SFIG2A: coomasie stained SDS-PAGE gel of ORC complexes and Orc1IDR
SFIG2B: image of agarose gel for EMSA analysis of Drosophila Orc1 IDR DNA binding

SFIG3A: coomasie stained SDS-PAGE gel of ORC holocomplex phosphorylation
SFIG3B: coomasie stained SDS-PAGE gel of Orc1 IDR phosphorylation
SFIG3C: excel file of intact mass spectrometry analysis of Orc1 IDR phosphorylation

SFIG4A: coomassie stained SDS-PAGE gel of purified Orc1 IDR variants
SFIG4B-H: images of agarose gel for EMSA analysis of Drosphila Orc1 IDR variant DNA binding

SFIG5: vector graphic of Chi-Score comparison of compositional homology between Orc1 IDR orthologs and other IDRs

SFIG6A: coomassie stained SDS-PAGE gel of purified Orc1 IDR orthologs
SFIG6B-H: text file of raw data for fluorescence polarization DNA binding of Orc1 IDR orthologs
SFIG6I: text file of binding affinity (Kd) data for Orc1 IDR orthologs

SFIG7: images of western blot analysis HsOrc1-IDR-eGFP chromatin spin down assay

##Description of the file structure
Data in this upload are organized based on the figures in which they appear in the forthecoming publication of this work in the journal Nucleic Acids Research, article number NAR-01896-J-2023.R1.

##Code/Software
All image quantification was completed using Fiji (is just ImageJ) version 2.1.0/1.53c

Data from: The Origin Recognition Complex requires chromatin tethering by a hypervariable intrinsically disordered region that is functionally conserved from sponge to man

Data files

Abstract

README: The Origin Recognition Complex requires chromatin tethering by a hypervariable intrinsically disordered region that is functionally conserved from sponge to man