umuDC-dnaQ Interaction and its implications for cell cycle regulation and SOS mutagenesis in Escherichia coli

The Escherichia coli SOS-regulated umuDC gene products participate in a DNA damage checkpoint control and in translesion DNA synthesis. Specific interactions involving the UmuD and UmuD' proteins, both encoded by the umuD gene, and components of the replicative DNA polymerase, Pol III, appear to be important for regulating these two biological activities of the umuDC gene products. Here we show that overproduction of the epsilon proofreading subunit of Pol III suppresses the cold sensitivity normally associated with overexpression of the umuDC gene products. Our results suggest that this suppression is attributable to specific interactions between UmuD or UmuD' and the C-terminal domain of epsilon.     

umuDC-mediated cold sensitivity is a manifestation of functions of the UmuD(2)C complex involved in a DNA damage checkpoint control

The umuDC genes are part of the Escherichia coli SOS response, and their expression is induced as a consequence of DNA damage. After induction, they help to promote cell survival via two temporally separate pathways. First, UmuD and UmuC together participate in a cell cycle checkpoint control; second, UmuD'(2)C enables translesion DNA replication over any remaining unrepaired or irreparable lesions in the DNA. Furthermore, elevated expression of the umuDC gene products leads to a cold-sensitive growth phenotype that correlates with a rapid inhibition of DNA synthesis. Here, using two mutant umuC alleles, one that encodes a UmuC derivative that lacks a detectable DNA polymerase activity (umuC104; D101N) and another that encodes a derivative that is unable to confer cold sensitivity but is proficient for SOS mutagenesis (umuC125; A39V), we show that umuDC-mediated cold sensitivity can be genetically separated from the role of UmuD'(2)C in SOS mutagenesis. Our genetic and biochemical characterizations of UmuC derivatives bearing nested deletions of C-terminal sequences indicate that umuDC-mediated cold sensitivity is not due solely to the single-stranded DNA binding activity of UmuC. Taken together, our analyses suggest that umuDC-mediated cold sensitivity is conferred by an activity of the UmuD(2)C complex and not by the separate actions of the UmuD and UmuC proteins. Finally, we present evidence for structural differences between UmuD and UmuD' in solution, consistent with the notion that these differences are important for the temporal regulation of the two separate physiological roles of the umuDC gene products.     

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.     

The genetic requirements for UmuDC-mediated cold sensitivity are distinct from those for SOS mutagenesis.

The umuDC operon of Escherichia coli, a member of the SOS regulon, is required for SOS mutagenesis. Following the posttranslational processing of UmuD to UmuD' by RecA-mediated cleavage, UmuD' acts in concert with UmuC, RecA, and DNA polymerase III to facilitate the process of translesion synthesis, which results in the introduction of mutations. Constitutive expression of the umuDC operon causes an inhibition of growth at 30 degrees C (cold sensitivity). The umuDC-dependent physiological phenomenon manifested as cold-sensitive growth is shown to differ from SOS mutagenesis in two respects. Intact UmuD, the form inactive in SOS mutagenesis, confers a significantly higher degree of cold sensitivity in combination with UmUC than does UmuD'. In addition, umuDC-mediated cold sensitivity, unlike SOS mutagenesis, does not require recA function. Since the RecA protein mediates the autodigestion of UnmD to UmuD', this finding supports the conclusion that intact UmuD is capable of conferring cold sensitivity in the presence of UmuC. The degree of inhibition of growth at 30 degrees C correlates with the levels of UmuD and UmuC, which are the only two SOS-regulated proteins required to observe cold sensitivity. Analysis of the cellular morphology of strains that exhibit cold sensitivity for growth led to the finding that constitutive expression of the umuDC operon causes a novel form of sulA- and sfiC-independent filamentation at 30 degrees C. This filamentation is observed in a strain constitutively expressing the single, chromosomal copy of umuDC and can be suppressed by overexpression of the ftsQAZ operon.     

Converting a DNA damage checkpoint effector (UmuD2C) into a lesion bypass polymerase (UmuD'2C)

During the SOS response of Escherichia coli to DNA damage, the umuDC operon is induced, producing the trimeric protein complexes UmuD2C, a DNA damage checkpoint effector, and UmuD'2C (DNA polymerase V), which carries out translesion synthesis, the basis of 'SOS mutagenesis'. UmuD'2, the homodimeric component of DNA pol V, is produced from UmuD by RecA-facilitated self-cleavage, which removes the 24 N-terminal residues of UmuD. We report the solution structure of UmuD'2 (PDB ID 1I4V) and interactions within UmuD'-UmuD, a heterodimer inactive in translesion synthesis. The overall shape of UmuD'2 in solution differs substantially from the previously reported crystal structure, even though the topologies of the two structures are quite similar. Most significantly, the active site residues S60 and K97 do not point directly at one another in solution as they do in the crystal, suggesting that self-cleavage of UmuD might require RecA to assemble the active site. Structural differences between UmuD'2 and UmuD'- UmuD suggest that UmuD'2C and UmuD2C might achieve their different biological activities through distinct interactions with RecA and DNA pol III.     

Selective disruption of the DNA polymerase III α-β complex by the umuD gene products

DNA polymerase III (DNA pol III) efficiently replicates the Escherichia coli genome, but it cannot bypass DNA damage. Instead, translesion synthesis (TLS) DNA polymerases are employed to replicate past damaged DNA; however, the exchange of replicative for TLS polymerases is not understood. The umuD gene products, which are up-regulated during the SOS response, were previously shown to bind to the α, β and ε subunits of DNA pol III. Full-length UmuD inhibits DNA replication and prevents mutagenic TLS, while the cleaved form UmuD' facilitates mutagenesis. We show that α possesses two UmuD binding sites: at the N-terminus (residues 1-280) and the C-terminus (residues 956-975). The C-terminal site favors UmuD over UmuD'. We also find that UmuD, but not UmuD', disrupts the α-β complex. We propose that the interaction between α and UmuD contributes to the transition between replicative and TLS polymerases by removing α from the β clamp.     

Characterization of Escherichia coli UmuC active-site loops identifies variants that confer UV hypersensitivity

DNA is constantly exposed to chemical and environmental mutagens, causing lesions that can stall replication. In order to deal with DNA damage and other stresses, Escherichia coli utilizes the SOS response, which regulates the expression of at least 57 genes, including umuDC. The gene products of umuDC, UmuC and the cleaved form of UmuD, UmuD', form the specialized E. coli Y-family DNA polymerase UmuD'2C, or polymerase V (Pol V). Y-family DNA polymerases are characterized by their specialized ability to copy damaged DNA in a process known as translesion synthesis (TLS) and by their low fidelity on undamaged DNA templates. Y-family polymerases exhibit various specificities for different types of DNA damage. Pol V carries out TLS to bypass abasic sites and thymine-thymine dimers resulting from UV radiation. Using alanine-scanning mutagenesis, we probed the roles of two active-site loops composed of residues 31 to 38 and 50 to 54 in Pol V activity by assaying the function of single-alanine variants in UV-induced mutagenesis and for their ability to confer resistance to UV radiation. We find that mutations of the N-terminal residues of loop 1, N32, N33, and D34, confer hypersensitivity to UV radiation and to 4-nitroquinoline-N-oxide and significantly reduce Pol V-dependent UV-induced mutagenesis. Furthermore, mutating residues 32, 33, or 34 diminishes Pol V-dependent inhibition of recombination, suggesting that these mutations may disrupt an interaction of UmuC with RecA, which could also contribute to the UV hypersensitivity of cells expressing these variants.     

A non-cleavable UmuD variant that acts as a UmuD' mimic

UmuD(2) cleaves and removes its N-terminal 24 amino acids to form UmuD'(2), which activates UmuC for its role in UV-induced mutagenesis in Escherichia coli. Cells with a non-cleavable UmuD exhibit essentially no UV-induced mutagenesis and are hypersensitive to killing by UV light. UmuD binds to the beta processivity clamp ("beta") of the replicative DNA polymerase, pol III. A possible beta-binding motif has been predicted in the same region of UmuD shown to be important for its interaction with beta. We performed alanine-scanning mutagenesis of this motif ((14)TFPLF(18)) in UmuD and found that it has a moderate influence on UV-induced mutagenesis but is required for the cold-sensitive phenotype caused by elevated levels of wild-type UmuD and UmuC. Surprisingly, the wild-type and the beta-binding motif variant bind to beta with similar K(d) values as determined by changes in tryptophan fluorescence. However, these data also imply that the single tryptophan in beta is in strikingly different environments in the presence of the wild-type versus the variant UmuD proteins, suggesting a distinct change in some aspect of the interaction with little change in its strength. Despite the fact that this novel UmuD variant is non-cleavable, we find that cells harboring it display phenotypes more consistent with the cleaved form UmuD', such as resistance to killing by UV light and failure to exhibit the cold-sensitive phenotype. Cross-linking and chemical modification experiments indicate that the N-terminal arms of the UmuD variant are less likely to be bound to the globular domain than those of the wild-type, which may be the mechanism by which this UmuD variant acts as a UmuD' mimic.     

A model for the structure of the Escherichia coli SOS-regulated UmuD2 protein

The ubiquitous Y-family of DNA polymerases, exemplified by the Escherichia coli UmuC protein (the catalytic subunit of DNA Pol V), possess the remarkable ability to replicate imperfect DNA templates that cannot be replicated by other types of DNA polymerases. Since this ability comes at the cost of a reduced fidelity, it is important that organisms manage these unique polymerases to coordinate their actions with those of the replication machinery. In E. coli, it is becoming evident that a sophisticated series of protein-protein interactions involving the two forms of the umuD gene product, UmuD and UmuD' and components of the replicative DNA polymerase serve to manage the actions of the umuC-encoded DNA polymerase. The purpose of this study was to better understand how structural differences between UmuD2 and UmuD2' help to determine which biological role the umuDC gene products will play; the UmuD2C complex functions as a DNA damage checkpoint effector, while the UmuD2'C complex participates in translesion DNA synthesis, which serves as the mechanistic basis for most chemical and UV light mutagenesis. Based on the results of a combination of disulfide cross-linking experiments, measurements of solvent accessibility and electron paramagnetic spin resonance (EPR) studies, we have developed a refined model for the structure of the UmuD2 homodimer. In the model that we are proposing, the N-terminal arms of UmuD (residues 1-39) form an extended interface in the UmuD2 homodimer by folding down over the globular domains of their intradimer partners. As a result, significant portions of the surface of each globular domain are buried in the UmuD2 homodimer. Based on the structure of the UmuD2' homodimer, both in the crystal and in solution, these same surfaces are exposed. Implications of these structural differences between the UmuD2 and the UmuD2' homodimers with respect to their roles in managing the actions of the umuC-encoded DNA polymerase are discussed.     

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.     

The dimeric SOS mutagenesis protein UmuD is active as a monomer

The homodimeric umuD gene products play key roles in regulating the cellular response to DNA damage in Escherichia coli. UmuD(2) is composed of 139-amino acid subunits and is up-regulated as part of the SOS response. Subsequently, damage-induced RecA·ssDNA nucleoprotein filaments mediate the slow self-cleavage of the N-terminal 24-amino acid arms yielding UmuD'(2). UmuD(2) and UmuD'(2) make a number of distinct protein-protein contacts that both prevent and facilitate mutagenic translesion synthesis. Wild-type UmuD(2) and UmuD'(2) form exceptionally tight dimers in solution; however, we show that the single amino acid change N41D generates stable, active UmuD and UmuD' monomers that functionally mimic the dimeric wild-type proteins. The UmuD N41D monomer is proficient for cleavage and interacts physically with DNA polymerase IV (DinB) and the β clamp. Furthermore, the N41D variants facilitate UV-induced mutagenesis and promote overall cell viability. Taken together, these observations show that a monomeric form of UmuD retains substantial function in vivo and in vitro.     

A role for the umuDC gene products of Escherichia coli in increasing resistance to DNA damage in stationary phase by inhibiting the transition to exponential growth

The umuDC gene products, whose expression is induced by DNA-damaging treatments, have been extensively characterized for their role in SOS mutagenesis. We have recently presented evidence that supports a role for the umuDC gene products in the regulation of growth after DNA damage in exponentially growing cells, analogous to a prokaryotic DNA damage checkpoint. Our further characterization of the growth inhibition at 30 degrees C associated with constitutive expression of the umuDC gene products from a multicopy plasmid has shown that the umuDC gene products specifically inhibit the transition from stationary phase to exponential growth at the restrictive temperature of 30 degrees C and that this is correlated with a rapid inhibition of DNA synthesis. These observations led to the finding that physiologically relevant levels of the umuDC gene products, expressed from a single, SOS-regulated chromosomal copy of the operon, modulate the transition to rapid growth in E. coli cells that have experienced DNA damage while in stationary phase. This activity of the umuDC gene products is correlated with an increase in survival after UV irradiation. In a distinction from SOS mutagenesis, uncleaved UmuD together with UmuC is responsible for this activity. The umuDC-dependent increase in resistance in UV-irradiated stationary-phase cells appears to involve, at least in part, counteracting a Fis-dependent activity and thereby regulating the transition to rapid growth in cells that have experienced DNA damage. Thus, the umuDC gene products appear to increase DNA damage tolerance at least partially by regulating growth after DNA damage in both exponentially growing and stationary-phase cells.     

Coexpression of UmuD'' with UmuC suppresses the UV mutagenesis deficiency of groE mutants.

The GroE proteins of Escherichia coli are heat shock proteins which have also been shown to be molecular chaperone proteins. Our previous work has shown that the GroE proteins of E. coli are required for UV mutagenesis. This process requires the umuDC genes which are regulated by the SOS regulon. As part of the UV mutagenesis pathway, the product of the umuD gene, UmuD, is posttranslationally cleaved to yield the active form, UmuD'. In order to investigate what role the groE gene products play in UV mutagenesis, we measured UV mutagenesis in groE+ and groE strains which were expressing either the umuDC or umuD'C genes. We found that expression of umuD' instead of umuD will suppress the nonmutability conferred by the groE mutations. However, cleavage of UmuD to UmuD' is unaffected by mutations at the groE locus. Instead we found that the presence of UmuD' increased the stability of UmuC in groE strains. In addition, we obtained evidence which indicates that GroEL interacts directly with UmuC.     

Mutagenic DNA repair in enterobacteria.

Sixteen species of enterobacteria have been screened for mutagenic DNA repair activity. In Escherichia coli, mutagenic DNA repair is encoded by the umuDC operon. Synthesis of UmuD and UmuC proteins is induced as part of the SOS response to DNA damage, and after induction, the UmuD protein undergoes an autocatalytic cleavage to produce the carboxy-terminal UmuD' fragment needed for induced mutagenesis. The presence of a similar system in other species was examined by using a combined approach of inducible-mutagenesis assays, cross-reactivity to E. coli UmuD and UmuD' antibodies to test for induction and cleavage of UmuD-like proteins, and hybridization with E. coli and Salmonella typhimurium umu DNA probes to map umu-like genes. The results indicate a more widespread distribution of mutagenic DNA repair in other species than was previously thought. They also show that umu loci can be more complex in other species than in E. coli. Differences in UV-induced mutability of more than 200-fold were seen between different species of enteric bacteria and even between multiple natural isolates of E. coli, and yet some of the species which display a poorly mutable phenotype still have umu-like genes and proteins. It is suggested that umDC genes can be curtailed in their mutagenic activities but that they may still participate in some other, unknown process which provides the continued stimulus for their retention.     

Two processivity clamp interactions differentially alter the dual activities of UmuC

DNA polymerases of the Y family promote survival by their ability to synthesize past lesions in the DNA template. One Escherichia coli member of this family, DNA pol V (UmuC), which is primarily responsible for UV-induced and chemically induced mutagenesis, possesses a canonical beta processivity clamp-binding motif. A detailed analysis of this motif in DNA pol V (UmuC) showed that mutation of only two residues in UmuC is sufficient to result in a loss of UV-induced mutagenesis. Increased levels of wild-type beta can partially rescue this loss of mutagenesis. Alterations in this motif of UmuC also cause loss of the cold-sensitive and beta-dependent synthetic lethal phenotypes associated with increased levels of UmuD and UmuC that are thought to represent an exaggeration of a DNA damage checkpoint. By designing compensatory mutations in the cleft between domains II and III in beta, we restored UV-induced mutagenesis by a UmuC beta-binding motif variant. A recent co-crystal structure of the 'little finger' domain of E. coli pol IV (DinB) with beta suggests that, in addition to the canonical beta-binding motif, a second site of pol IV ((303)VWP(305)) interacts with beta at the outer rim of the dimer interface. Mutational analysis of the corresponding motif in UmuC showed that it is dispensable for induced mutagenesis, but that alterations in this motif result in loss of the cold-sensitive phenotype. These two beta interaction sites of UmuC affect the dual functions of UmuC differentially and indicate subtle and sophisticated polymerase management by the beta clamp.     

Subunit-specific degradation of the UmuD/D' heterodimer by the ClpXP protease: the role of trans recognition in UmuD' stability

The Escherichia coli UmuD' protein is a subunit of the recently described error-prone DNA polymerase, pol V. UmuD' is initially synthesized as an unstable and mutagenically inactive pro-protein, UmuD. Upon processing, UmuD' assumes a relatively stable conformation and becomes mutagenically active. While UmuD and UmuD' by themselves exist in vivo as homodimers, when together they preferentially interact to form heterodimers. Quite strikingly, it is in this context that UmuD' becomes susceptible to ClpXP-mediated proteolysis. Here we report a novel targeting mechanism designed for degrading the mutagenically active UmuD' subunit of the UmuD/D' heterodimer complex, while leaving the UmuD protein intact. Surprisingly, a signal that is essential and sufficient for targeting UmuD' for degradation was found to reside on UmuD not UmuD'. UmuD was also shown to be capable of channeling an excess of UmuD' to ClpXP for degradation, thereby providing a mechanism whereby cells can limit error-prone DNA replication.     

Escherichia coli DNA polymerase V subunit exchange: a post-SOS mechanism to curtail error-prone DNA synthesis

DNA polymerase V consisting of a heterotrimer composed of one molecule of UmuC and two molecules of UmuD' (UmuD'2C) is responsible for SOS damage-induced mutagenesis in Escherichia coli. Here we show that although the UmuD'2C complex remains intact through multiple chromatographic steps, excess UmuD, the precursor to UmuD', displaces UmuD' from UmuD'2C by forming a UmuDD' heterodimer, while UmuC concomitantly aggregates as an insoluble precipitate. Although soluble UmuD'2C is readily detected when the two genes are co-transcribed and translated in vitro, soluble UmuD2C or UmuDD'C are not detected. The subunit exchange between UmuD'2C and UmuD offers a biological means to inactivate error-prone polymerase V following translesion synthesis, thus preventing mutations from occurring on undamaged DNA.     

Error-prone repair and translesion synthesis III: the activation of UmuD (or less is more)

Following DNA damage to Escherichia coli bacteria, RecA protein is activated by binding to single stranded DNA and cleaves its own gene repressor (LexA protein). Two papers from Graham Walker's laboratory showed that several bacterial genes in addition to RecA are repressed by the LexA repressor and are inducible following DNA damage [C.J. Keyon, G.C. Walker, DNA-damaging agents stimulate gene expression at specific loci in Escherichia coli, in: Proceedings of the National Academy of Sciences of the United States of America 77, 1980, pp. 2819--2823] and predicted that one of them (UmuD) might itself be subject to activation by a further cleavage reaction involving activated RecA protein [K.L. Perry, S.J. Elledge, B.B. Mitchell, L. Marsh, G.C. Walker, umuD,C and mucA,B operans whose products are required for UV light- and chemical-induced mutagenesis: UmuD, MucA, and LexA proteins share homology, in: Proceedings of the National Academy of Sciences of the United States of America 82, 1985, pp. 4331--4335]. The processed form of UmuD, termed UmuD', later proved to be a subunit of DNA polymerase V, a key enzyme involved in translesion synthesis.