Balestrini A , Cosentino C , Errico A , Garner E , Costanzo V .

Cancer Research UK, A7124 Cancer Research UK, 206281 European Research Council, CRUK_A7124 Cancer Research UK, ERC_206281 European Research Council

	Figure 2. Analysis of GEMC1 role in DNA replicationa) Chromatin binding of Orc1, MCM7, Cdc45, xGEMC1 and Sld5 at the indicated times after addition of sperm nuclei (3000 n/μl) to interphase egg extracts supplemented with buffer (Control), 80 nM geminin (GEM) or 1 μM p27 protein. The sample collected at 0 minutes was DNA free. b) WB of egg extract depleted with mock (ΔMock) or affinity purified anti xGEMC1 antibodies (ΔxGEMC1). c) DNA replication assay showing incorporation of α32P-dCTP in genomic DNA incubated in egg extract for 2 hours. From left to right sperm nuclei (1000 n-μl) were replicated in egg extracts that were untreated (Un), depleted with mock IgGs (Mock IgG, 80 ng/μl), depleted with affinity purified anti xGEMC1 IgGs (ΔxGEMC1) and supplemented with buffer (Buffer) or with 10 ng/μl xGEMC1 (r-xGEMC1) or incubated with affinity purified anti xGEMC1 IgGs (xGEMC1 IgG, 80 ng/μl) and supplemented with buffer (Buffer) or an excess of recombinant xGEMC1 (r-xGEMC1). DNA was isolated, run on agarose gel that was dried and exposed. d) Amount of replicated DNA measured by quantifying α32P-dATP incorporation over time using TCA precipitation (see Supplementary methods) in extracts treated as indicated in (c). The graph shows a typical result. e) Amount of α32P-dCTP incorporated in single stranded M13 phage DNA relative to untreated sample. Extracts were untreated (Un), supplemented with mock IgGs (Mock IgG, 80 ng/μl), with affinity purified anti xGEMC1 immunoglobulins (xGEMC1 IgG, 80 ng/μl) or xGEMC1 depleted (xGEMC1 dep). Experiment was repeated 3 times (n=3). Average results are shown. Error bars indicate SD. f) Chromatin binding of indicated proteins at different times after addition of sperm nuclei (3000 n/μl) to egg extracts that were mock (ΔMock) or xGEMC1 depleted in the absence (ΔxGEMC1) or in the presence (ΔxGEMC1+r-xGEMC1) of 10 ng/μl r-xGEMC1. (*) indicates binding of r-xGEMC1 to chromatin, which was probed with anti MBP antibodies. See Supplementary Fig 6 for uncropped gels shown in this figure.
	Figure 3. Identification of GEMC1 interacting proteinsa) WB of indicated proteins on pull-downs performed with amylose resin that was untreated (Mock), pre-bound to MBP (MBP) or to xGEMC1 fused to MBP (r-xGEMC1) and subsequently incubated in egg extract. * indicates non-specific band. b) WB of TopBP1 on pull-downs performed with amylose resin that was untreated (Mock), pre-bound to MBP (MBP) or to GEMC1 fused to MBP (r-GEMC1) and incubated with extract (+ Extract) or with recombinant TopBP1. c) Chromatin binding of the indicated proteins at different times after addition of sperm nuclei (3000 n/μl) to egg extracts that were mock (Mock) or TopBP1 (ΔTopBP1) depleted. d) Chromatin binding of the indicated proteins at different times after addition of sperm nuclei (3000 n/μl) to interphase egg extracts that were mock (Mock) or Orc1 depleted (ΔORC1). e) Autoradiograph of 35S-labelled xGEMC1 (35S-GEMC1) or 35S-labelled xGEMC1 mutated in the Cyclin binding site (35S-xGEMC1-ANA) produced in reticulocyte lysates and incubated with buffer (−) or recombinant Cdk2-CyclinE complex (Cdk2-E). f) Amount of replicated DNA measured by quantifying α32P-dATP incorporation over time using TCA precipitation (see methods) at different times after the addition of 1000 or 6000 nuclei/μl to egg extracts supplemented with 300 ng/μl recombinant xGEMC1 (r-xGEMC1), 300 ng-μl xGEMC1-8ST-D (r-xGEMC1-8ST-D) carrying the serine and threonine residues phosphorylated by Cdk2 mutated to aspartate, 300 ng/μl xGEMC1-8ST-A protein (r-xGEMC1-8ST-A) with the same residues mutated to alanine, with 3 mM caffeine (Caff) or with 3 mM caffeine in the presence of 300 ng/μl xGEMC1-8ST-D protein (xGEMC1-8ST-D + Caff). The graphs show data from one representative experiment. xGEMC1 proteins used in these experiments were defective for the Cyclin-binding domain (R198NL to A198NA mutation) to avoid titration of endogenous Cdk2-Cyclin E complex. g) Cdc45 chromatin binding. Egg extracts were supplemented with buffer (Buffer) or 300 ng/μl xGEMC1-8ST-D mutant protein (r-xGEMC1-8ST-D). Orc1 was used as loading control. h) WB of TopBP1 (top panel) on pull-downs performed with amylose resin that was pre-bound to MBP (MBP), to MBP fused to wild type xGEMC1 (r-xGEMC1), to aspartate (r-xGEMC1-8ST-D) or to alanine substituted xGEMC1 (xGEMC1-8ST-A) (bottom panel, coumassie) and incubated with recombinant TopBP1. See Supplementary Fig 6 for uncropped gels shown in this figure.
	Figure 4. Effects resulting from inhibition of GEMC1 expression in Xenopus embryosa) WB of xGEMC1 extracted from Xenopus embryos that were untreated (Un) or injected with control (C-MO) and morpholino oligos complementary to xGEMC1 DNA sequence (xGEMC1-MO) taken at the indicated stages. Lower panel shows coumassie staining of histone proteins from total embryo lysates. b) Morphology of Xenopus embryos that were untreated (Un), injected with control (C-MO) or anti xGEMC1 morpholino oligos (xGEMC1-MO) taken at the indicated stages. c) Quantification of experiment shown in (b). 100 embryos were counted for each treatment. Graph shows a typical result. d) Sections of fixed Xenopus embryos injected with control (C-MO) or with anti xGEMC1 morpholino oligos (xGEMC1-MO) and stained with ematossilin-eosin. Area in the rectangle shows 5x magnification. e) DNA content reduction in embryos that were uninjected (Not injected), injected with control morpholino oligos (Control MO) or with anti xGEMC1 morpholino oligos (xGEMC1-MO). Data are mean ± SD of 3 independent experiments; * and ** P <0.001 compared with not injected control, t-test) f) Cleavage of 35S-labeled PARP induced by lysates of embryos that were uninjected (Not injected), injected with control morpholino oligos (Control MO) or anti xGEMC1 morpholino oligos (xGEMC1-MO). See Supplementary Fig 6 for un-cropped gels shown in this figure.
	Figure 5. Effects resulting from inhibition of GEMC1 expression in mammalian cellsa) RT-PCR of mouse GEMC1 (mGEMC1) and GAPDH (GAPDH) mRNA derived from mouse NIH 3T3 fibroblasts that were treated with control (Mock) or mouse GEMC1 siRNA oligos (mGEMC1_1 and mGEMC1_2). b) Quantification of RNA levels shown in (a). The graph shows data from one representative experiment. c) Histograms relative to FACS analysis following incorporation of BrdU in mouse NIH3T3 cells that were untreated (Un), mock treated (Mock), transfected with two independent mouse GEMC1 siRNA (mGEMC1_1 or mGEMC1_2) or with Cdc45 siRNA oligos. The graph shows data from one representative experiment. d) Typical FACS profiles relative to experiments shown in (c). Circles in pink indicate BrdU incorporating cells. e) WB of MEF-3T3 cells stably transfected with empty TET-OFF vector (Vector), with TET-OFF vector expressing hemagglutinin epitope (HA) tagged mGEMC1 (mGEMC1) or with the same vector expressing siRNA resistant HA tagged mGEMC1 (mGEMC1* Rescue). Cells were subjected to silencing with mGEMC1_1 siRNA in the absence or presence of 1 μg/ml doxycycline (Dox), which represses the expression driven by the exogenous promoter present on the vector. After 96 hours cells were collected and processed for WB using anti HA and anti GAPDH antibodies as indicated. f) The histograms represent the percentage in S-phase of MEF-3T3 cells that were treated with mock (Mock) or mGEMC1 siRNA oligos (mGEMC1_1 siRNA). mGEMC1_1 siRNA treated cells were stably transfected with empty TET-OFF vector (Vector), with TET-OFF vector expressing HA tagged mGEMC1 (mGEMC1) or with the same vector expressing siRNA resistant HA tagged mGEMC1 (mGEMC1*) in the absence (−Dox) or in the presence (+Dox) of 1 μg/ml doxycycline. Cells were BrdUTP labelled and processed for FACS analysis. The graph shows data from one representative experiment. g) Model for GEMC1 function at replication origins (see text for explanation). See Supplementary Fig 6 for uncropped gels shown in this figure.

Blow, Initiation of DNA replication in nuclei and purified DNA by a cell-free extract of Xenopus eggs. 1986, Pubmed, Xenbase

Blow, Initiation of DNA replication in nuclei and purified DNA by a cell-free extract of Xenopus eggs. 1986, Pubmed , Xenbase
Costanzo, Xenopus cell-free extracts to study DNA damage checkpoints. 2004, Pubmed , Xenbase
Diffley, Regulation of early events in chromosome replication. 2004, Pubmed , Xenbase
Dunphy, The Xenopus cdc2 protein is a component of MPF, a cytoplasmic regulator of mitosis. 1988, Pubmed , Xenbase
Hashimoto, Xenopus Cut5 is essential for a CDK-dependent process in the initiation of DNA replication. 2003, Pubmed , Xenbase
Kamimura, Sld3, which interacts with Cdc45 (Sld4), functions for chromosomal DNA replication in Saccharomyces cerevisiae. 2001, Pubmed
Khokha, Techniques and probes for the study of Xenopus tropicalis development. 2002, Pubmed , Xenbase
Krasinska, Cdk1 and Cdk2 activity levels determine the efficiency of replication origin firing in Xenopus. 2008, Pubmed , Xenbase
Kubota, Determination of initiation of DNA replication before and after nuclear formation in Xenopus egg cell free extracts. 1993, Pubmed , Xenbase
Kubota, A novel ring-like complex of Xenopus proteins essential for the initiation of DNA replication. 2003, Pubmed , Xenbase
Luciani, Characterization of a novel ATR-dependent, Chk1-independent, intra-S-phase checkpoint that suppresses initiation of replication in Xenopus. 2004, Pubmed , Xenbase
Matsuno, The N-terminal noncatalytic region of Xenopus RecQ4 is required for chromatin binding of DNA polymerase alpha in the initiation of DNA replication. 2006, Pubmed , Xenbase
McGarry, Geminin, an inhibitor of DNA replication, is degraded during mitosis. 1998, Pubmed , Xenbase
Mimura, Xenopus Cdc45-dependent loading of DNA polymerase alpha onto chromatin under the control of S-phase Cdk. 1998, Pubmed , Xenbase
Mimura, Phosphorylation-dependent binding of mitotic cyclins to Cdc6 contributes to DNA replication control. 2004, Pubmed
Nakajima, SpSld3 is required for loading and maintenance of SpCdc45 on chromatin in DNA replication in fission yeast. 2002, Pubmed
Newport, Nuclear reconstitution in vitro: stages of assembly around protein-free DNA. 1987, Pubmed , Xenbase
Sangrithi, Initiation of DNA replication requires the RECQL4 protein mutated in Rothmund-Thomson syndrome. 2005, Pubmed , Xenbase
Saxena, A dimerized coiled-coil domain and an adjoining part of geminin interact with two sites on Cdt1 for replication inhibition. 2004, Pubmed , Xenbase
Schulman, Substrate recruitment to cyclin-dependent kinase 2 by a multipurpose docking site on cyclin A. 1998, Pubmed
Shechter, ATR and ATM regulate the timing of DNA replication origin firing. 2004, Pubmed , Xenbase
Takisawa, Eukaryotic DNA replication: from pre-replication complex to initiation complex. 2000, Pubmed
Tanaka, Association of RPA with chromosomal replication origins requires an Mcm protein, and is regulated by Rad53, and cyclin- and Dbf4-dependent kinases. 1998, Pubmed
Tanaka, CDK-dependent phosphorylation of Sld2 and Sld3 initiates DNA replication in budding yeast. 2007, Pubmed
Tanaka, The role of CDK in the initiation step of DNA replication in eukaryotes. 2007, Pubmed
Trenz, Plx1 is required for chromosomal DNA replication under stressful conditions. 2008, Pubmed , Xenbase
Van Hatten, The Xenopus Xmus101 protein is required for the recruitment of Cdc45 to origins of DNA replication. 2002, Pubmed , Xenbase
Walter, Initiation of eukaryotic DNA replication: origin unwinding and sequential chromatin association of Cdc45, RPA, and DNA polymerase alpha. 2000, Pubmed , Xenbase
Wohlschlegel, Xenopus Mcm10 binds to origins of DNA replication after Mcm2-7 and stimulates origin binding of Cdc45. 2002, Pubmed , Xenbase
Zegerman, Phosphorylation of Sld2 and Sld3 by cyclin-dependent kinases promotes DNA replication in budding yeast. 2007, Pubmed