A single hydrophobic cleft in the Escherichia coli processivity clamp is sufficient to support cell viability and DNA damage-induced mutagenesis in vivo.

BACKGROUND: The ubiquitous family of DnaN sliding processivity clamp proteins plays essential roles in DNA replication, DNA repair, and cell cycle progression, in part by managing the actions of the different proteins involved in these processes. Interactions of the homodimeric Escherichia coli ß clamp with its known partners involves multiple surfaces, including a hydrophobic cleft located near the C-terminus of each clamp protomer. RESULTS: A mutant E. coli ß clamp protein lacking a functional hydrophobic cleft (ßC) complemented the temperature sensitive growth phenotype of a strain bearing the dnaN159 allele, which encodes a thermolabile mutant clamp protein (ß159). Complementation was conferred by a ßC/ß159 heterodimer, and was observed only in the absence of the dinB gene, which encodes DNA polymerase IV (Pol IV). Furthermore, the complemented strain was proficient for umuDC (Pol V)--dependent ultraviolet light (UV)--induced mutagenesis. CONCLUSIONS: Our results suggest that a single cleft in the homodimeric E. coli ß sliding clamp protein is sufficient to support both cell viability, as well as Pol III, Pol IV, and Pol V function in vivo. These findings provide further support for a model in which different Pols switch places with each other on DNA using a single cleft in the clamp.

Sliding clamp-DNA interactions are required for viability and contribute to DNA polymerase management in Escherichia coli.

Sliding clamp proteins topologically encircle DNA and play vital roles in coordinating the actions of various DNA replication, repair, and damage tolerance proteins. At least three distinct surfaces of the Escherichia coli beta clamp interact physically with the DNA that it topologically encircles. We utilized mutant beta clamp proteins bearing G66E and G174A substitutions (beta159), affecting the single-stranded DNA-binding region, or poly-Ala substitutions in place of residues 148-HQDVR-152 (beta(148-152)), affecting the double-stranded DNA binding region, to determine the biological relevance of clamp-DNA interactions. As part of this work, we solved the X-ray crystal structure of beta(148-152), which verified that the poly-Ala substitutions failed to significantly alter the tertiary structure of the clamp. Based on functional assays, both beta159 and beta(148-152) were impaired for loading and retention on a linear primed DNA in vitro. In the case of beta(148-152), this defect was not due to altered interactions with the DnaX clamp loader, but rather was the result of impaired beta(148-152)-DNA interactions. Once loaded, beta(148-152) was proficient for DNA polymerase III (Pol III) replication in vitro. In contrast, beta(148-152) was severely impaired for Pol II and Pol IV replication and was similarly impaired for direct physical interactions with these Pols. Despite its ability to support Pol III replication in vitro, beta(148-152) was unable to support viability of E. coli. Nevertheless, physiological levels of beta(148-152) expressed from a plasmid efficiently complemented the temperature-sensitive growth phenotype of a strain expressing beta159 (dnaN159), provided that Pol II and Pol IV were inactivated. Although this strain was impaired for Pol V-dependent mutagenesis, inactivation of Pol II and Pol IV restored the Pol V mutator phenotype. Taken together, these results support a model in which a sophisticated combination of competitive clamp-DNA, clamp-partner, and partner-DNA interactions serve to manage the actions of the different E. coli Pols in vivo.

Contributions of the individual hydrophobic clefts of the Escherichia coli beta sliding clamp to clamp loading, DNA replication and clamp recycling.

The homodimeric Escherichia coli beta sliding clamp contains two hydrophobic clefts with which proteins involved in DNA replication, repair and damage tolerance interact. Deletion of the C-terminal five residues of beta (beta(C)) disrupted both clefts, severely impairing interactions of the clamp with the DnaX clamp loader, as well as the replicative DNA polymerase, Pol III. In order to determine whether both clefts were required for loading clamp onto DNA, stimulation of Pol III replication and removal of clamp from DNA after replication was complete, we developed a method for purification of heterodimeric clamp proteins comprised of one wild-type subunit (beta(+)), and one beta(C) subunit (beta(+)/beta(C)). The beta(+)/beta(C) heterodimer interacted normally with the DnaX clamp loader, and was loaded onto DNA slightly more efficiently than was beta(+). Moreover, beta(+)/beta(C) interacted normally with Pol III, and stimulated replication to the same extent as did beta(+). Finally, beta(+)/beta(C) was severely impaired for unloading from DNA using either DnaX or the delta subunit of DnaX. Taken together, these findings indicate that a single cleft in the beta clamp is sufficient for both loading and stimulation of Pol III replication, but both clefts are required for unloading clamp from DNA after replication is completed.

Differential binding of Escherichia coli DNA polymerases to the beta-sliding clamp.

Escherichia coli strains expressing the mutant beta159-sliding clamp protein (containing both a G66E and a G174A substitution) are temperature sensitive for growth and display altered DNA polymerase (pol) usage. We selected for suppressors of the dnaN159 allele able to grow at 42 degrees C, and identified four intragenic suppressor alleles. One of these alleles (dnaN780) contained only the G66E substitution, while a second (dnaN781) contained only the G174A substitution. Genetic characterization of isogenic E. coli strains expressing these alleles indicated that certain phenotypes were dependent upon only the G174A substitution, while others required both the G66E and G174A substitutions. In order to understand the individual contributions of the G66E and the G174A substitution to the dnaN159 phenotypes, we utilized biochemical approaches to characterize the purified mutant beta159 (G66E and G174A), beta780 (G66E) and beta781 (G174A) clamp proteins. The G66E substitution conferred a more pronounced effect on pol IV replication than it did pol II or pol III, while the G174A substitution conferred a greater effect on pol III and pol IV than it did pol II. Taken together, these findings indicate that pol II, pol III and pol IV interact with distinct, albeit overlapping surfaces of the beta clamp.

Specific amino acid residues in the beta sliding clamp establish a DNA polymerase usage hierarchy in Escherichia coli.

Escherichia coli dnaN159 strains encode a mutant form of the beta sliding clamp (beta159), causing them to display altered DNA polymerase (pol) usage. In order to better understand mechanisms of pol selection/switching in E. coli, we have further characterized pol usage in the dnaN159 strain. The dnaN159 allele contains two amino acid substitutions: G66E (glycine-66 to glutamic acid) and G174A (glycine-174 to alanine). Our results indicated that the G174A substitution impaired interaction of the beta clamp with the alpha catalytic subunit of pol III. In light of this finding, we designed two additional dnaN alleles. One of these dnaN alleles contained a G174A substitution (beta-G174A), while the other contained D173A, G174A and H175A substitutions (beta-173-175). Examination of strains bearing these different dnaN alleles indicated that each conferred a distinct UV sensitive phenotype that was dependent upon a unique combination of Delta polB (pol II), Delta dinB (pol IV) and/or Delta umuDC (pol V) alleles. Taken together, these findings indicate that mutations in the beta clamp differentially affect the functions of these three pols, and suggest that pol II, pol IV and pol V are capable of influencing each others' abilities to gain access to the replication fork. These findings are discussed in terms of a model whereby amino acid residues in the vicinity of those mutated in beta159 (G66 and G174) help to define a DNA polymerase usage hierarchy in E. coli following UV irradiation.

Mutant forms of the Escherichia colibeta sliding clamp that distinguish between its roles in replication and DNA polymerase V-dependent translesion DNA synthesis.

The Escherichia colibeta sliding clamp is proposed to play an important role in regulating DNA polymerase traffic at the replication fork. As part of an ongoing effort to understand how organisms manage the actions of their multiple DNA polymerases, we examined the ability of several mutant forms of the beta clamp to function in DNA polymerase V- (pol V-) dependent translesion DNA synthesis (TLS) in vivo. Our results indicate that a dnaN159 strain, which expresses a temperature sensitive form of the beta clamp, was impaired for pol V-dependent TLS at the permissive temperature of 37 degrees C. This defect was complemented by a plasmid that expressed near-physiological levels of the wild-type clamp. Using a dnaN159 mutant strain, together with various plasmids expressing mutant forms of the clamp, we determined that residues H148 through R152, which comprise a portion of a solvent exposed loop, as well as position P363, which is located in the C-terminal tail of the beta clamp, are critically important for pol V-dependent TLS in vivo. In contrast, these same residues appear to be less critical for pol III-dependent replication. Taken together, these findings indicate that: (i) the beta clamp plays an essential role in pol V-dependent TLS in vivo and (ii) pol III and pol V interact with non-identical surfaces of the beta clamp.

Identification of specific amino acid residues in the E. coli beta processivity clamp involved in interactions with DNA polymerase III, UmuD and UmuD'.

Variants of a pentapeptide sequence (QL[S/F]LF), referred to as the eubacterial clamp-binding motif, appear to be required for certain proteins to bind specifically to the Escherichia coli beta sliding clamp, apparently by making contact with a hydrophobic pocket located at the base of the C-terminal tail of each beta protomer. Although both UmuC (DNA pol V) and the alpha catalytic subunit of DNA polymerase III (pol III) each bear a reasonable match to this motif, which appears to be required for their respective interactions with the clamp, neither UmuD not UmuD' do. As part of an ongoing effort to understand how interactions involving the different E. coli umuDC gene products and components of DNA polymerase III help to coordinate DNA replication with a DNA damage checkpoint control and translesion DNA synthesis (TLS) following DNA damage, we characterized the surfaces on beta important for its interactions with the two forms of the umuD gene product. We also characterized the surface of beta important for its interaction with the alpha catalytic subunit of pol III. Our results indicate that although UmuD, UmuD' and alpha share some common contacts with beta, each also makes unique contacts with the clamp. These findings suggest that differential interactions of UmuD and UmuD' with beta impose a DNA damage-responsive conditionality on how beta interacts with the translesion DNA polymerase UmuC. This is formally analogous to how post-translational modification of the eukaryotic PCNA clamp influences mutagenesis. We discuss the implications of our findings in terms of how E. coli might coordinate the actions of the umuDC gene products with those of pol III, as well as for how organisms in general might manage the actions of their multiple DNA polymerases.