Replication Factor C Subunits Research Articles

Functional and physical interaction between Rad24 and Rfc5 in the yeast checkpoint pathways.

The RFC5 gene encodes a small subunit of replication factor C (RFC) complex in Saccharomyces cerevisiae and has been shown to be required for the checkpoints which respond to replication block and DNA damage. Here we describe the isolation of RAD24, known to play a role in the DNA damage checkpoint, as a dosage-dependent suppressor of rfc5-1. RAD24 overexpression suppresses the sensitivity of rfc5-1 cells to DNA-damaging agents and the defect in DNA damage-induced Rad53 phosphorylation. Rad24, like Rfc5, is required for the regulation of Rad53 phosphorylation in response to DNA damage. The Rad24 protein, which is structurally related to the RFC subunits, interacts physically with RFC subunits Rfc2 and Rfc5 and cosediments with Rfc5. Although the rad24Delta mutation alone does not cause a defect in the replication block checkpoint, it does enhance the defect in rfc5-1 mutants. Furthermore, overexpression of RAD24 suppresses the rfc5-1 defect in the replication block checkpoint. Taken together, our results demonstrate a physical and functional interaction between Rad24 and Rfc5 in the checkpoint pathways.

Functional Interactions among the Subunits of Replication Factor C Potentiate and Modulate Its ATPase Activity

Replication factor C (RF-C), a complex of five subunits, and several subassemblies of RF-C, representing intermediates along the proposed protein assembly pathway (Podust, V. N., and Fanning, E. (1997) J. Biol. Chem. 272, 6303-6310), were expressed in insect cells using baculoviruses encoding individual subunits (p140, p40, p38, p37, and p36). Purified proteins were analyzed for ATPase activity to assess the role of individual subunits in ATP hydrolysis. His-tagged p40 contained low ATPase activity, but tagged p37 and p36 did not. Complexes of p40.p37.p36 bearing a His tag on any subunit displayed DNA-stimulated ATPase activity, in agreement with a recent report (Cai, J., Gibbs, E., Uhlmann, F., Philips, B., Yao, N., O'Donnell, M. , and Hurwitz, J. (1997) J. Biol. Chem. 272, 18974-18981). In contrast, complex p38.p37.p36-his displayed no ATPase, suggesting that p40 is essential for ATPase activity. Although p38 was not required for ATPase activity, the activity of the p40-his.p38.p37. p36 complex was more salt-resistant than that of the p40-his.p37.p36 complex. The p140 subunit further increased the specific ATPase activity of RF-C complex by enhancing its stimulation by DNA. Taken together, the data indicate that all five RF-C subunits constitute ATPase activity, although the contributions of the individual subunits differ. Predicted ATP-binding domains of all five subunits were mutated to assess the importance of multiple ATP-binding sites of RF-C. In each case, the Lys of the conserved P-loop motif was replaced by Glu. The ATP-binding domain of p38 was found to be dispensable for the activity of the five-subunit RF-C in polymerase delta DNA synthesis. In contrast, mutation of the ATP-binding domains in other RF-C subunits impaired RF-C assembly, function, or both.

Destabilized PCNA trimers suppress defective Rfc1 proteins in vivo and in vitro.

Replication factor C (RFC) and the proliferating cell nuclear antigen (PCNA) are two essential DNA polymerase accessory proteins that are required for numerous aspects of DNA metabolism including DNA replication, DNA repair, and telomere metabolism. PCNA is a homotrimeric ring-shaped sliding DNA clamp that can facilitate DNA replication by tethering DNA polymerase delta or DNA polymerase epsilon to the DNA template. RFC is the 5-subunit multiprotein complex that loads PCNA onto DNA at primer-template junctions in an ATP-dependent reaction. All five of the RFC subunits share a set of related sequences (RFC boxes) that include nucleotide-binding consensus sequences. We report here that a mutation in the gene encoding the large subunit of yeast RFC gives rise to DNA metabolism defects that can be observed in vivo and in vitro. The rfc1-1 substitution (D513N) lies within the widely conserved RFC box VIII consensus sequence and results in phenotypes including DNA replication defects, increased sensitivity to DNA damaging agents, and elongated telomeres. Mutant Rfc1-1 complexes exhibit in vitro DNA replication defects that are sensitive to ATP concentrations, and these defects can be suppressed by mutant PCNA proteins which contain substitutions that destabilize the homotrimeric sliding DNA clamp.

The large subunit of replication factor C is a substrate for caspase-3 in vitro and is cleaved by a caspase-3-like protease during Fas-mediated apoptosis.

Caspase-3 is an ICE-like protease activated during apoptosis induced by different stimuli. Poly(ADP-ribose) polymerase (PARP), the first characterized substrate of caspase-3, shares a region of homology with the large subunit of Replication Factor C (RF-C), a five-subunit complex that is part of the processive eukaryotic DNA polymerase holoenzymes. Caspase-3 cleaves PARP at a DEVD-G motif present in the 140 kDa subunit of RF-C (RFC140) and evolutionarily conserved. We show that cleavage of RFC140 during Fas-mediated apoptosis in Jurkat cells and lymphocytes results in generation of multiple fragments. Cleavage is inhibited by the caspase-3-like protease inhibitor Ac-DEVD-CHO but not the caspase-1/ICE-type protease inhibitor Ac-YVAD-CHO. In addition, recombinant caspase-3 cleaves RFC140 in vitro at least at three different sites in the C-terminal half of the protein. Using amino-terminal microsequencing of radioactive fragments, we identified three sites: DEVD723G, DLVD922S and IETD1117A. We did not detect cleavage of small subunits of RF-C of 36, 37, 38 and 40 kDa by recombinant caspase-3 or by apoptotic Jurkat cell lysates. Cleavage of RFC140 during apoptosis inactivates its function in DNA replication and generates truncated forms that further inhibit DNA replication. These results identify RFC140 as a critical target for caspase-3-like proteases and suggest that caspases could mediate cell cycle arrest.

Phosphorylation of the PCNA binding domain of the large subunit of replication factor C by Ca2+/calmodulin-dependent protein kinase II inhibits DNA synthesis.

Replication factor C (RF-C) is a heteropentameric protein essential for DNA replication and DNA repair. It is a molecular matchmaker required for loading of the proliferating cell nuclear antigen (PCNA) sliding clamp onto double-strand DNA and for PCNA-dependent DNA synthesis by DNA polymerases delta and epsilon. The DNA and PCNA binding domains of the large 140 kDa subunit of human RF-C have been recently cloned [Fotedar, R., Mossi, R., Fitzgerald, P., Rousselle, T., Maga, G., Brickner, H., Messier, H., Khastilba. S., Hübscher, U., & Fotedar, A. (1996) EMBO J. 15, 4423-4433]. Here we show that the PCNA binding domain is phosphorylated by the Ca2+/calmodulin-dependent protein kinase II (CaMKII), an enzyme required for cell cycle progression in eukaryotic cells. The DNA binding domain, on the other hand, is not phosphorylated. Phosphorylation by CaMKII reduces the binding of PCNA to RF-C and consequently inhibits RF-C-dependent DNA synthesis by DNA polymerases delta1 and epsilon. Once bound to PCNA and DNA, RF-C is protected from phosphorylation by CaMKII, suggesting a possible role of CaMKII in regulating the dynamics of interaction between PCNA and RF-C and thus interfering in the formation of an active sliding clamp by DNA polymerases delta and epsilon.

Deletion Analysis of the Large Subunit p140 in Human Replication Factor C Reveals Regions Required for Complex Formation and Replication Activities

Replication factor C (RFC) and proliferating cell nuclear antigen (PCNA) are processivity factors for eukaryotic DNA polymerases delta and epsilon. RFC contains multiple activities, including its ability to recognize and bind to a DNA primer end and load the ring-shaped PCNA onto DNA in an ATP-dependent reaction. PCNA then tethers the polymerase to the template allowing processive DNA chain elongation. Human RFC consists of five distinct subunits (p140, p40, p38, p37, and p36), and RFC activity can be reconstituted from the five cloned gene products. To characterize the role of the large subunit p140 in the function of the RFC complex, deletion mutants were created that defined a region within the p140 C terminus required for complex formation with the four small subunits. Deletion of the p140 N-terminal half, including the DNA ligase homology domain, resulted in the formation of an RFC complex with enhanced activity in replication and PCNA loading. Deletion of additional N-terminal amino acids, including those constituting the RFC homology box II that is conserved among all five RFC subunits, disrupted RFC replication function. DNA primer end recognition and PCNA binding activities, located in the p140 C-terminal half, were unaffected in this mutant, but PCNA loading was abolished.

Identification of Regions within the Four Small Subunits of Human Replication Factor C Required for Complex Formation and DNA Replication

Replication factor C (RFC) and proliferating cell nuclear antigen (PCNA) are processivity factors for eukaryotic DNA polymerases delta and epsilon. RFC binds to a DNA primer end and loads PCNA onto DNA in an ATP-dependent reaction. The five RFC subunits p140, p40, p38, p37, and p36, all of which are required to form the active RFC complex, share regions of high homology including the defined RFC boxes II-VIII. RFC boxes III and V constitute a putative ATP binding site, whereas the function of the other conserved boxes is unknown. To study the individual subunits in the RFC complex and the role of the RFC boxes, deletion mutations were created in all subunits. Sequences close to the C terminus of each of the small subunits are required for formation of the five subunit complex. A N-terminal region of the small subunits, containing the RFC homology box II, plays a critical role in the function of these subunits, deletion of which reduces but does not abolish RFC activity in loading PCNA onto DNA and in supporting an RFC-dependent replication reaction. The N termini of p37 and p40, although highly homologous, are not interchangeable, suggesting unique functions for the individual subunits.

Assembly of Functional Replication Factor C Expressed Using Recombinant Baculoviruses

Replication factor C (RF-C), a complex of five subunits, is an essential eukaryotic protein involved in both DNA replication and DNA repair. To generate an easily accessible source of human RF-C for biochemical and genetic studies, we cloned the cDNAs of all five subunits into baculoviruses so that each subunit could be expressed both as a non-fused polypeptide and as an N-terminal His-tagged fusion (-his). Co-infection of insect cells with five baculoviruses encoding individual RF-C subunits (p140, p40, p38, p37, and p36) yielded a protein preparation active in two assays characteristic for authentic RF-C: stimulation of DNA polymerase delta DNA synthesis on singly primed single-stranded DNA template and formation of a complex of proliferating cell nuclear antigen with circular double-stranded DNA. Functional recombinant RF-C containing p40-his, p37-his, or p36-his was isolated using affinity resin. Active RF-C was reconstituted only by co-expression of all five subunits. A model for assembly of RF-C from individual subunits was derived from co-purification experiments performed with various combinations of His-tagged and non-fused subunits expressed by co-infection of insect cells with recombinant baculoviruses. p37 and p36 are proposed to form the first intermediate, which, upon addition of either p40 or p38, generates stable tertiary complexes: p40.p37.p36 and p38.p37.p36. The remaining fourth small subunit binds to the tertiary complex to form a quaternary complex p40.p38. p37.p36. Large subunit p140 binds last to form the five-subunit protein.

Replication Factor C Interacts with the C-terminal Side of Proliferating Cell Nuclear Antigen

Replication factor C (RF-C) is a heteropentameric protein essential for DNA replication and repair. It is a molecular matchmaker required for loading of proliferating cell nuclear antigen (PCNA) onto double-stranded DNA and, thus, for PCNA-dependent DNA elongation by DNA polymerases delta and epsilon. To elucidate the mode of RF-C binding to the PCNA clamp, modified forms of human PCNA were used that could be 32P-labeled in vitro either at the C or the N terminus. Using a kinase protection assay, we show that the heteropentameric calf thymus RF-C was able to protect the C-terminal region but not the N-terminal region of human PCNA from phosphorylation, suggesting that RF-C interacts with the PCNA face at which the C termini are located (C-side). A similar protection profile was obtained with the recently identified PCNA binding region (residues 478-712), but not with the DNA binding region (residues 366-477), of the human RF-C large subunit (Fotedar, R., Mossi, R., Fitzgerald, P., Rousselle, T., Maga, G., Brickner, H., Messner, H., Khastilba, S., Hübscher, U., and Fotedar, A., (1996) EMBO J., 15, 4423-4433). Furthermore, we show that the RF-C 36 kDa subunit of human RF-C could interact independently with the C-side of PCNA. The RF-C large subunit from a third species, namely Drosophila melanogaster, interacted similarly with the modified human PCNA, indicating that the interaction between RF-C and PCNA is conserved through eukaryotic evolution.

A conserved domain of the large subunit of replication factor C binds PCNA and acts like a dominant negative inhibitor of DNA replication in mammalian cells.

Replication factor C (RF-C), a complex of five polypeptides, is essential for cell-free SV40 origin-dependent DNA replication and viability in yeast. The cDNA encoding the large subunit of human RF-C (RF-Cp145) was cloned in a Southwestern screen. Using deletion mutants of RF-Cp145 we have mapped the DNA binding domain of RF-Cp145 to amino acid residues 369-480. This domain is conserved among both prokaryotic DNA ligases and eukaryotic poly(ADP-ribose) polymerases and is absent in other subunits of RF-C. The PCNA binding domain maps to amino acid residues 481-728 and is conserved in all five subunits of RF-C. The PCNA binding domain of RF-Cp145 inhibits several functions of RF-C, such as: (i) in vitro DNA replication of SV40 origin-containing DNA; (ii) RF-C-dependent loading of PCNA onto DNA; and (iii) RF-C-dependent DNA elongation. The PCNA binding domain of RF-Cp145 localizes to the nucleus and inhibits DNA synthesis in transfected mammalian cells. In contrast, the DNA binding domain of RF-Cp145 does not inhibit DNA synthesis in vitro or in vivo. We therefore conclude that amino acid residues 481-728 of human RF-Cp145 are critical and act as a dominant negative mutant of RF-C function in DNA replication in vivo.

Identification of the fifth subunit of Saccharomyces cerevisiae replication factor C.

Yeast replication factor C (RF-C) is a multipolypeptide complex required for chromosomal DNA replication. Previously this complex was known to consist of at least four subunits. We here report the identification of a fifth RF-C subunit from Saccharomyces cerevisiae, encoded by the RFC5 (YBR0810) gene. This subunit exhibits highest homology to the 38 kDa subunit (38%) of human RF-C (activator 1). Like the other four RFC genes, the RFC5 gene is essential for yeast viability, indicating an essential function for each subunit. RFC5 mRNA is expressed at steady-state levels throughout the mitotic cell cycle. Upon overexpression in Escherichia coli Rfc5p has an apparent molecular mass of 41 kDa. Overproduction of RF-C activity in yeast is dependent on overexpression of the RFC5 gene together with overexpression of the RFC1-4 genes, indicating that the RFC5 gene product forms an integral subunit of this replication factor.

Cloning and characterization of the essential Saccharomyces cerevisiae RFC4 gene encoding the 37-kDa subunit of replication factor C.

The RFC4 gene encoding the 37-kDa subunit of Saccharomyces cerevisiae replication factor C (RF-C) has been cloned and sequenced. The RFC4 gene encodes a 323-amino acid polypeptide with a molecular weight of 36,126. The deduced amino acid sequence of the RFC4 gene shows high sequence similarity to the other two small subunits of yeast RF-C and the three small subunits of human RF-C (35-60% identity, 55-78% similarity). The similarity is greatest with the 40-kDa subunit of human RF-C (also called Activator 1). Despite the presence of a MluI cell cycle box in the regulatory region of the RFC4 gene, the steady state levels of its mRNA do not change significantly during the yeast mitotic cell cycle. The RFC4 gene is essential for yeast viability and is located on the left arm of chromosome XV, between the SUF1 and ADH1 genes. The essential role of this as well as the other small subunits of RF-C indicates a unique function for each of these subunits, despite their apparent structural redundancy. Rfc4p was overexpressed in Escherichia coli. Despite the presence of consensus ATPase motifs in the primary amino acid sequence, no discernible biochemical function could be ascribed to the purified protein. However, Rfc4p formed a tight complex with the product of the RFC3 gene which encodes the ATPase of RF-C.

The RFC2 gene encoding a subunit of replication factor C of Saccharomyces cerevisiae.

Replication Factor C (RF-C) of Saccharomyces cerevisiae is a complex that consists of several different polypeptides ranging from 120- to 37 kDa (Yoder and Burgers, 1991; Fien and Stillman, 1992), similar to human RF-C. We have isolated a gene, RFC2, that appears to be a component of the yeast RF-C. The RFC2 gene is located on chromosome X of S. cerevisiae and is essential for cell growth. Disruption of the RFC2 gene led to a dumbbell-shaped terminal morphology, common to mutants having a defect in chromosomal DNA replication. The steady-state levels of RFC2 mRNA fluctuated less during the cell cycle than other genes involved in DNA replication. Nucleotide sequence of the gene revealed an open reading frame corresponding to a polypeptide with a calculated Mr of 39,716 and a high degree of amino acid sequence homology to the 37-kDa subunit of human RF-C. Polyclonal antibodies against bacterially expressed Rfc2 protein specifically reduced RF-C activity in the RF-C-dependent reaction catalyzed by yeast DNA polymerase III. Furthermore, the Rfc2 protein was copurified with RF-C activity throughout RF-C purification. These results strongly suggest that the RFC2 gene product is a component of yeast RF-C. The bacterially expressed Rfc2 protein preferentially bound to primed single-strand DNA and weakly to ATP.

CDNAs encoding the large subunit of human replication factor C.

Replication factor C (RFC) is a multisubunit, DNA polymerase accessory protein required for the coordinated synthesis of both DNA strands during simian virus 40 DNA replication in vitro. Previous studies have shown that RFC is a DNA-dependent ATPase that binds in a structure-specific manner to the 3' end of a primer hybridized to a template DNA, an activity thought intrinsic to the 140-kDa component of this multisubunit complex. Here, the isolation and analysis of cDNAs encoding this subunit is described. Analysis of the full-length coding sequence revealed an open reading frame of 3.4 kb, encoding an 1148-amino acid protein with a predicted molecular mass of 130 kDa. A putative ATP-binding motif was observed that is similar to a motif in several of the smaller subunits of RFC and in functionally homologous replication factors of bacterial and viral origin. A "DEAD" box is also conserved among these proteins. The predicted protein shows significant identity with a DNA-binding protein of murine origin (B. Luckow, P. Lichter, and G. Schütz, personal communication). Regions of similarity were also seen between the amino acid sequences of the 140-kDa subunit of RFC, poly(ADP-ribose) polymerase, and bacterial DNA ligases--possibly representing a conserved structural feature of these proteins that bind similar DNA substrates.