Enabling adoption of 2D-NMR for the higher order structure assessment of monoclonal antibody therapeutics

The increased interest in using monoclonal antibodies (mAbs) as a platform for biopharmaceuticals has led to the need for new analytical techniques that can precisely assess physicochemical properties of these large and very complex drugs for the purpose of correctly identifying quality attributes (QA). One QA, higher order structure (HOS), is unique to biopharmaceuticals and essential for establishing consistency in biopharmaceutical manufacturing, detecting process-related variations from manufacturing changes and establishing comparability between biologic products. To address this measurement challenge, two-dimensional nuclear magnetic resonance spectroscopy (2D-NMR) methods were introduced that allow for the precise atomic-level comparison of the HOS between two proteins, including mAbs. Here, an inter-laboratory comparison involving 26 industrial, government and academic laboratories worldwide was performed as a benchmark using the NISTmAb, from the National Institute of Standards and Technology (NIST), to facilitate the translation of the 2D-NMR method into routine use for biopharmaceutical product development. Two-dimensional ¹H,¹⁵N and ¹H,¹³C NMR spectra were acquired with harmonized experimental protocols on the unlabeled Fab domain and a uniformly enriched-¹⁵N, 20%-¹³C-enriched system suitability sample derived from the NISTmAb. Chemometric analyses from over 400 spectral maps acquired on 39 different NMR spectrometers ranging from 500 MHz to 900 MHz demonstrate spectral fingerprints that are fit-for-purpose for the assessment of HOS. The 2D-NMR method is shown to provide the measurement reliability needed to move the technique from an emerging technology to a harmonized, routine measurement that can be generally applied with great confidence to high precision assessments of the HOS of mAb-based biotherapeutics.

Carbohydrates protect protein against abiotic fragmentation by soil minerals

The degradation and turnover of soil organic matter is an important part of global carbon cycling and of particular importance with respect to attempts to predict the response of ecosystems to global climate change. Thus, it is important to mechanistically understand the processes by which organic matter can be degraded in the soil environment, including contact with reactive or catalytic mineral surfaces. We have characterized the outcome of the interaction of two minerals, birnessite and kaolinite, with two disaccharides, cellobiose and trehalose. These results show that birnessite reacts with and degrades the carbohydrates, while kaolinite does not. The reaction of disaccharides with birnessite produces Mn(II), indicating that degradation of the disaccharides is the result of their oxidation by birnessite. Furthermore, we find that both sugars can inhibit the degradation of a model protein by birnessite, demonstrating that the presence of one organic constituent can impact abiotic degradation of another. Therefore, both the reactivity of the mineral matrix and the presence of certain organic constituents influence the outcomes of abiotic degradation. These results suggest the possibility that microorganisms may be able to control the functionality of exoenzymes through the concomitant excretion of protective organic substances, such as those found in biofilms.

Role of Ordered Proteins in the Folding-Upon-Binding of Intrinsically Disordered Proteins

In this work, we quantitatively investigate the thermodynamic analogy between the folding of monomeric proteins and the interactions of intrinsically disordered proteins (IDPs). Motivated by the hypothesis that similar hydrophobic forces guide both globular protein folding and also IDP interactions, we present a unified experimental and computational investigation of the coupling between the folding and binding of the intrinsically disordered tail of FCP1 when interacting with the cooperatively folding winged-helix domain of Rap74. Our calorimetric measurements quantitatively demonstrate the significance of hydrophobic interactions for this binding event. Our computational studies indicate that IDPs relieve frustration at the surface of ordered proteins to generate a minimally frustrated complex that is strikingly similar to a globular monomeric protein. In summary, these results not only quantify the thermodynamic forces driving disordered protein interactions but also highlight the role of ordered proteins for IDP function.

Carbon-Detected (15)N NMR Spin Relaxation of an Intrinsically Disordered Protein: FCP1 Dynamics Unbound and in Complex with RAP74

Intrinsically disordered proteins (IDPs) lack unique 3D structures under native conditions and as such exist as highly dynamic ensembles in solution. We present two (13)C-direct detection experiments for the measurement of (15)N NMR spin relaxation called the CON(T1)-IPAP and CON(T2)-IPAP that quantify backbone dynamics on a per-residue basis for IDPs in solution. These experiments have been applied to the intrinsically disordered C-terminal of FCP1, both free in solution and while bound to the RAP74 winged-helix domain. The results provide evidence that most of FCP1 remains highly dynamic in both states, while the 20 residues forming direct contact with RAP74 become more ordered in the complex. Parallel analysis of RAP74 backbone (15)N NMR spin relaxation reveals only very limited ordering of RAP74 upon FCP1 binding. Taken together, these data show that folding-upon-binding is highly local in this system, with disorder prevailing even in the complex.

The disordered C-terminus of the RNA polymerase II phosphatase FCP1 is partially helical in the unbound state

Intrinsically disordered proteins (IDPs) lack unique 3D structures under native conditions and yet retain critical functions. Recycling of RNA Polymerase II after transcription is promoted by an interaction between the winged helix domain of RAP74, a component of the general transcription factor IIF (TFIIF), and the C-terminus of the TFIIF-associating CTD phosphatase (FCP1). Sixteen residues from the C-terminus of FCP1 form an α-helix in the complex, but the protein is otherwise agreed in the literature to be intrinsically disordered. Here we show through CD and recently developed carbon-detected NMR that, although FCP1 is intrinsically disordered, the above 16 residues composing the RAP74 binding surface form nascent α-helical structure in the unbound state. We further show retention of general FCP1 disorder and the nascent helical content in HeLa extract, establishing cellular relevance. The conformational bias observed leads to a mechanistic proposal for FCP1's transition from a disordered ensemble to an ordered conformation upon binding.

Acoustic Emissions During Indentation Tests

When a hard tip indents a sample, cracking, delamination and plasticity can all produce acoustic signals in the form of elastic waves. This paper describes how these acoustic emissions (AE) can be monitored using piezoelectric elements and a load-controlled indentation instrument. Signals emitted from thin films and bulk materials are shown and they are correlated with distinct jumps in displacement of the indenter tip. The benefits and difficulties of different methods of monitoring the emissions are also considered.

CD8(+) T cell-mediated injury in vivo progresses in the absence of effector T cells

Tissue injury is a common sequela of acute virus infection localized to a specific organ such as the lung. Tissue injury is an immediate consequence of infection with lytic viruses. It can also result from the direct destruction of infected cells by effector CD8(+) T lymphocytes and indirectly through the action of the T cell-derived proinflammatory cytokines and recruited inflammatory cells on infected and uninfected tissue. We have examined CD8(+) T cell-mediated pulmonary injury in a transgenic model in which adoptively transferred, virus-specific cytotoxic T lymphocytes (CTLs) produce lethal, progressive pulmonary injury in recipient mice expressing the viral target transgene exclusively in the lungs. We have found that over the 4-5 day course of the development of lethal pulmonary injury, the effector CTLs, while necessary for the induction of injury, are present only transiently (24-48 h) in the lung. We provide evidence that the target of the antiviral CD8(+) T cells, the transgene expressing type II alveolar cells, are not immediately destroyed by the effector T cells. Rather, after T cell-target interaction, the type II alveolar cells are stimulated to produce the chemokine monocyte chemoattractant protein 1. These results reinforce the concept that, in vivo, the cellular targets of specific CTLs may participate directly in the development of progressive tissue injury by activating in response to interaction with the T cells and producing proinflammatory mediators without sustained in vivo activation of CD8(+) T cell effectors.

Eukaryotic mutagenesis and translesion replication dependent on DNA polymerase zeta and Rev1 protein

Translesion replication is a mechanism that employs specialized DNA polymerases for promoting continued nascent strand extension at forks blocked by the presence of unrepaired DNA damage. In Saccharomyces cerevisiae at least, this process contributes only modestly to the ability of cells to tolerate DNA damage, but is a major source of DNA-damage-induced substitutions and frameshifts, and of spontaneous mutations. Translesion replication past many types of DNA damage in yeast depends on the activities of DNA polymerase zeta (pol zeta) and Rev1p. Pol zeta is found in most, but not all, eukaryotes investigated, whereas Rev1p appears to be universal. Genes encoding these enzymes are found in humans, and appear to perform functions similar to those in yeast.

Mutagenesis in eukaryotes dependent on DNA polymerase zeta and Rev1p

DNA polymerase zeta (Pol zeta) and Rev1p carry out translesion replication in budding yeast, Saccharomyces cerevisiae, and are jointly responsible for almost all base pair substitution and frameshift mutations induced by DNA damage in this organism. In addition, Pol zeta is responsible for the majority of spontaneous mutations in yeast and has been proposed as the enzyme responsible for somatic hypermutability. Pol zeta, a non-processive enzyme that lacks a 3' to 5' exonuclease proofreading activity, is composed of Rev3p, the catalytic subunit, and a second subunit encoded by REV7. In keeping with its role, extension by Pol zeta is relatively tolerant of abnormal DNA structure at the primer terminus and is much more capable of extension from terminal mismatches than yeast DNA polymerase alpha (Pol alpha). Rev1p is a bifunctional enzyme that possesses a deoxycytidyl transferase activity that incorporates deoxycytidyl opposite abasic sites in the template and a second, at present poorly defined, activity that is required for the bypass of a variety of lesions as well as abasic sites. Human homologues of the yeast REV1 and REV3 have been identified and, based on the phenotype of cells producing antisense RNA to one or other of these genes, their products appear also to be employed in translation replication and spontaneous mutagenesis. We suggest that Pol zeta is best regarded as a replication enzyme, albeit one that is used only intermittently, that promotes extension at forks the progress of which is blocked for any reason, whether the presence of an unedited terminal mismatch or unrepaired DNA lesion.

Mutagenesis in eukaryotes dependent on DNA polymerase zeta and Rev1p

DNA polymerase zeta (Pol zeta) and Rev1p carry out translesion replication in budding yeast, Saccharomyces cerevisiae, and are jointly responsible for almost all base pair substitution and frameshift mutations induced by DNA damage in this organism. In addition, Pol zeta is responsible for the majority of spontaneous mutations in yeast and has been proposed as the enzyme responsible for somatic hypermutability. Pol zeta, a non-processive enzyme that lacks a 3' to 5' exonuclease proofreading activity, is composed of Rev3p, the catalytic subunit, and a second subunit encoded by REV7. In keeping with its role, extension by Pol zeta is relatively tolerant of abnormal DNA structure at the primer terminus and is much more capable of extension from terminal mismatches than yeast DNA polymerase alpha (Pol alpha). Rev1p is a bifunctional enzyme that possesses a deoxycytidyl transferase activity that incorporates deoxycytidyl opposite abasic sites in the template and a second, at present poorly defined, activity that is required for the bypass of a variety of lesions as well as abasic sites. Human homologues of the yeast REV1 and REV3 have been identified and, based on the phenotype of cells producing antisense RNA to one or other of these genes, their products appear also to be employed in translation replication and spontaneous mutagenesis. We suggest that Pol zeta is best regarded as a replication enzyme, albeit one that is used only intermittently, that promotes extension at forks the progress of which is blocked for any reason, whether the presence of an unedited terminal mismatch or unrepaired DNA lesion.

Evidence for a second function for Saccharomyces cerevisiae Rev1p

The function of the Saccharomyces cerevisiae REV1 gene is required for translesion replication and mutagenesis induced by a wide variety of DNA-damaging agents. We showed previously that Rev1p possesses a deoxycytidyl transferase activity, which incorporates dCMP opposite abasic sites in the DNA template, and that dCMP insertion is the major event during bypass of an abasic site in vivo. However, we now find that Rev1p function is needed for the bypass of a T-T (6-4) UV photoproduct, a process in which dCMP incorporation occurs only very rarely, indicating that Rev1p possesses a second function. In addition, we find that Rev1p function is, as expected, required for bypass of an abasic site. However, replication past this lesion was also much reduced in the G-193R rev1-1 mutant, which we find retains substantial levels of deoxycytidyl transferase activity. This mutant is, therefore, presumably deficient principally in the second, at present poorly defined, function. The bypass of an abasic site and T-T (6-4) lesion also depended on REV3 function, but neither it nor REV1 was required for replication past the T-T dimer; bypass of this lesion presumably depends on another enzyme.

The function of the human homolog of Saccharomyces cerevisiae REV1 is required for mutagenesis induced by UV light

In Saccharomyces cerevisiae, most mutations induced by a wide range of mutagens arise during translesion replication employing the REV1 gene product and DNA polymerase zeta. As part of an effort to investigate mammalian mutagenic mechanisms, we have identified cDNA clones of the human homologs of the yeast REV genes and examined their function in UV mutagenesis. Previously, we described the isolation of a human homolog of yeast REV3, the catalytic subunit of pol zeta, and here report the identification and sequence of a human homolog of yeast REV1. This gene was isolated by identifying an expressed sequence tag encoding a peptide with similarity to the C terminus of yeast Rev1p, followed by sequencing of the clone and retrieval of the remaining cDNA by 5' rapid amplification of cDNA ends. The human gene encodes an expected protein of 1,251 residues, compared with 985 residues in the yeast protein. The proteins share two amino-terminal regions of approximately 100 residues with 41% and 20% identity, a region of approximately 320 residues with 31% identity, and a central motif in which 11 of 13 residues are identical. Human cells expressing high levels of an hREV1 antisense RNA grew normally, and were not more sensitive to the cytotoxic effect of 254 nm UV radiation than cells lacking antisense RNA. However, the frequencies of 6-thioguanine resistance mutants induced by UV in the cells expressing antisense hREV1 RNA were significantly lower than in the control (P = 0.01), suggesting that the human gene has a function similar to that of the yeast homolog.

Intrinsic polymerase activities of UmuD'(2)C and MucA'(2)B are responsible for their different mutagenic properties during bypass of a T-T cis-syn cyclobutane dimer

In wild-type Escherichia coli, translesion replication is largely dependent upon the UmuD'(2)C complex (DNA polymerase V [polV]) or its plasmid-encoded homologs, such as MucA'(2)B. Interestingly, both the efficiency of translesion replication of a T-T cis-syn dimer and the spectra of mutations observed are different in Umu- and Muc-expressing strains. We have investigated whether the polIII core is responsible for these differences by measuring the frequency of dimer bypass, the error rate of bypass, and the resulting mutation spectrum in mutants carrying a deletion of dnaQ (epsilon subunit) or holE (theta subunit) or carrying the dnaQ allele mutD5, which is deficient in proofreading but is competent in the structural function of epsilon, or the dnaE antimutator allele spq-2. The chromosomal copy of the umuDC operon was deleted in each strain, and the UmuDC, UmuD'C, MucAB, or MucA'B proteins were expressed from a low-copy-number plasmid. With only few exceptions, we found that the characteristically different mutation spectra resulting from Umu- and Muc-mediated bypass are maintained in all of the strains investigated, indicating that differences in the activity or structure of the polIII core are not responsible for the observed phenotype. We also demonstrate that the MucA'(2)B complex is more efficient in promoting translesion replication than the UmuD'(2)C proteins and show that, contrary to expectation, the T-T dimer is bypassed more accurately by MucA'(2)B than by UmuD'(2)C. These results are consistent with the view that in a wild-type cell, the polV-like enzymes are responsible for the spectra of mutations generated during translesion replication and that polIII may simply be required to fix the misincorporations as mutations by completing chromosomal replication. Our observations also show that the mutagenic properties of a lesion can depend strongly on the particular enzyme employed in bypass.

UV lesions located on the leading strand inhibit DNA replication but do not inhibit SV40 T-antigen helicase activity

DNA replication in eucaryotic cells involves a variety of proteins which synthesize the leading and lagging strands in an asymmetric coordinated manner. To analyse the effect of this asymmetry on the translesion synthesis of UV-induced lesions, we have incubated SV40 origin-containing plasmids with a unique site-specific cis, syn-cyclobutane dimer or a pyrimidine-pyrimidone (6-4) photoproduct on either the leading or lagging strand template with DNA replication-competent extracts made from human HeLa cells. Two dimensional agarose gel electrophoresis analyses revealed a strong blockage of fork progression only when the UV lesion is located on the leading strand template. Because DNA helicases are responsible for unwinding duplex DNA ahead of the fork and are then the first component to encounter any potential lesion, we tested the effect of these single photoproducts on the unwinding activity of the SV40 T antigen, the major helicase in our in vitro replication assay. We showed that the activity of the SV40 T-antigen helicase is not inhibited by UV-induced DNA lesions in double-stranded DNA substrate.

Specific binding of human MSH2.MSH6 mismatch-repair protein heterodimers to DNA incorporating thymine- or uracil-containing UV light photoproducts opposite mismatched bases

Previous studies have demonstrated recognition of DNA-containing UV light photoproducts by bacterial (Feng, W.-Y., Lee, E., and Hays, J. B. (1991) Genetics 129, 1007-1020) and human (Mu, D., Tursun, M., Duckett, D. R., Drummond, J. T., Modrich, P., and Sancar, A. (1997) Mol. Cell. Biol. 17, 760-769) long-patch mismatch-repair systems. Mismatch repair directed specifically against incorrect bases inserted during semi-conservative DNA replication might efficiently antagonize UV mutagenesis. To test this hypothesis, DNA 51-mers containing site-specific T-T cis-syn-cyclobutane pyrimidine-dimers or T-T pyrimidine-(6-4')pyrimidinone photoproducts, with all four possible bases opposite the respective 3'-thymines in the photoproducts, were analyzed for the ability to compete with radiolabeled (T/G)-mismatched DNA for binding by highly purified human MSH2.MSH6 heterodimer protein (hMutSalpha). Both (cyclobutane-dimer)/AG and ((6-4)photoproduct)/AG mismatches competed about as well as non-photoproduct T/T mismatches. The two respective pairs of photoproduct/(A(T or C)) mismatches also showed higher hMutSalpha affinity than photoproduct/AA "matches"; the apparent affinity of hMutSalpha for the ((6-4)photoproduct)/AA-"matched" substrate was actually less than that for TT/AA homoduplexes. Surprisingly, although hMutSalpha affinities for both non-photoproduct UU/GG double mismatches and for (uracil-cyclobutane-dimer)/AG single mismatches were high, affinity for the (uracil-cyclobutane-dimer)/GG mismatch was quite low. Equilibrium binding of hMutSalpha to DNA containing (photoproduct/base) mismatches and to (T/G)-mismatched DNA was reduced similarly by ATP (in the absence of magnesium).

Efficient translesion replication in the absence of Escherichia coli Umu proteins and 3'-5' exonuclease proofreading function

Translesion replication (TR) past a cyclobutane pyrimidine dimer in Escherichia coli normally requires the UmuD'2C complex, RecA protein, and DNA polymerase III holoenzyme (pol III). However, we find that efficient TR can occur in the absence of the Umu proteins if the 3'-5' exonuclease proofreading activity of the pol III epsilon-subunit also is disabled. TR was measured in isogenic uvrA6 DeltaumuDC strains carrying the dominant negative dnaQ allele, mutD5, or DeltadnaQ spq-2 mutations by transfecting them with single-stranded M13-based vectors containing a specifically located cis-syn T-T dimer. As expected, little TR was observed in the DeltaumuDC dnaQ+ strain. Surprisingly, 26% TR occurred in UV-irradiated DeltaumuDC mutD5 cells, one-half the frequency found in a uvrA6 umuDC+mutD5 strain. lexA3 (Ind-) derivatives of the strains showed that this TR was contingent on two inducible functions, one LexA-dependent, responsible for approximately 70% of the TR, and another LexA-independent, responsible for the remaining approximately 30%. Curiously, the DeltaumuDC DeltadnaQ spq-2 strain exhibited only the LexA-independent level of TR. The cause of this result appears to be the spq-2 allele, a dnaE mutation required for viability in DeltadnaQ strains, since introduction of spq-2 into the DeltaumuDC mutD5 strain also reduces the frequency of TR to the LexA-independent level. The molecular mechanism responsible for the LexA-independent TR is unknown but may be related to the UVM phenomenon [Palejwala, V. A., Wang, G. E., Murphy, H. S. & Humayun, M. Z. (1995) J. Bacteriol. 177, 6041-6048]. LexA-dependent TR does not result from the induction of pol II, since TR in the DeltaumuDC mutD5 strain is unchanged by introduction of a DeltapolB mutation.

A human homolog of the Saccharomyces cerevisiae REV3 gene, which encodes the catalytic subunit of DNA polymerase zeta

To get a better understanding of mutagenic mechanisms in humans, we have cloned and sequenced the human homolog of the Saccharomyces cerevisiae REV3 gene. The yeast gene encodes the catalytic subunit of DNA polymerase zeta, a nonessential enzyme that is thought to carry out translesion replication and is responsible for virtually all DNA damage-induced mutagenesis and the majority of spontaneous mutagenesis. The human gene encodes an expected protein of 3,130 residues, about twice the size of the yeast protein (1,504 aa). The two proteins are 29% identical in an amino-terminal region of approximately 340 residues, 39% identical in a carboxyl-terminal region of approximately 850 residues, and 29% identical in a 55-residue region in the middle of the two genes. The sequence of the expected protein strongly predicts that it is the catalytic subunit of a DNA polymerase of the pol zeta type; the carboxyl-terminal domain possesses, in the right order, the six motifs characteristic of eukaryotic DNA polymerases, most closely resembles yeast pol zeta among all polymerases in the GenBank database, and is different from the human alpha, delta, and epsilon enzymes. Human cells expressing high levels of an hsREV3 antisense RNA fragment grow normally, but show little or no UV-induced mutagenesis and are slightly more sensitive to killing by UV. The human gene therefore appears to carry out a function similar to that of its yeast counterpart.

Mutagenic properties of the T-C cyclobutane dimer

G x C-->A x T transitions within T-C or C-C bipyrimidine sequences are by far the most frequent class of mutation induced by 254-nm UV irradiation in most genes and species investigated, but the reason for the high degree of mutability and specificity at these sites is uncertain. Some data implicate the deamination of cytosine to uracil as a possible cause, but other results appear to indicate that the rate of deamination is too low for this to be significant in Escherichia coli. If deamination is not the cause, the high degree of mutability must presumably reflect the inherent properties of T-C and C-C dimers. We investigated this question by transfecting excision-deficient and excision-proficient strains of E. coli with single-stranded vectors that carried a site-specific cis-syn T-C cyclobutane dimer and by analyzing the nucleotide sequences of replicated vector products. We found that replication past the T-C dimer, like replication past its T-T and U-U counterparts, is in fact >95% accurate and that the frequencies of bypass are also very similar for these photoproducts. Since the T-C dimer appears to be only weakly mutagenic, the high frequency of UV-induced mutations at T-C sites presumably depends on some other process, such as deamination, although the mechanism remains to be established.

Deoxycytidyl transferase activity of yeast REV1 protein

Mutagenesis induced by DNA damage in Saccharomyces cerevisiae requires the products of the REV1, REV3 and REV7 genes. The Rev3 and Rev7 proteins are subunits of DNA polymerase-zeta (Pol-zeta), an enzyme whose sole function appears to be translesion synthesis. Rev1 protein has weak homology with UmuC protein which facilitates translesion synthesis in Escherichia coli by an unknown mechanism. We show here that Rev1 protein has a deoxycytidyl transferase activity which transfers a dCMP residue from dCTP to the 3' end of a DNA primer in a template-dependent reaction. Efficient transfer occurred opposite a template abasic site, but approximately 20% transfer also occurred opposite a template guanine and approximately 10% opposite adenine or uracil; < or = 1% was seen opposite thymine or cytosine. Insertion of cytosine opposite an abasic site produced a terminus that was extended efficiently by Pol-zeta, but not by yeast Pol-alpha.

Analysis of the mutagenic properties of the UmuDC, MucAB and RumAB proteins, using a site-specific abasic lesion

The mucAB and rumAB loci have been shown to promote mutagenesis to a greater extent than the structurally and functionally homologous Escherichia coli umuDC operon. We have analyzed the basis of this enhanced mutagenesis by comparing the influence of these operons, relative to umuDC, on the mutagenic properties of each of two abasic sites, specifically located in a single-stranded vector. Experiments with these vectors are useful analytical tools because they provide independent estimates of the efficiency of translesion synthesis and of the relative frequencies of each type of nucleotide insertion or other kind of mutagenic event. The umuDC, mucAB, and rumAB genes were expressed from their natural LexA-regulated promoter on low-copy-number plasmids in isogenic strains carrying a umuDC deletion. In addition, plasmids expressing the UmuD'C, MucA'B, or RumA'B proteins were also used. Compared to umuDC, the chief effect of mucAB was to increase the efficiency of translesion synthesis past the abasic site. The enhanced capacity of mucAB for translesion synthesis depended about equally on an inherently greater capacity to promote this process and on a greater susceptibility of the MucA protein to proteolytic processing. The RumA protein also appeared to be more susceptible to proteolytic processing, but the inherent capacity of the Rum products for translesion synthesis was no greater than that of UmuDC. dAMP was inserted opposite one of the two abasic sites studied at a somewhat greater frequency in strains expressing rum (82%) compared to those expressing umu (72%), which might result in higher mutation frequencies in rumAB than in umuDC strains.

Thymine-thymine dimer bypass by yeast DNA polymerase zeta

The REV3 and REV7 genes of the yeast Saccharomyces cerevisiae are required for DNA damage-induced mutagenesis. The Rev3 and Rev7 proteins were shown to form a complex with DNA polymerase activity. This polymerase replicated past a thymine-thymine cis-syn cyclobutane dimer, a lesion that normally severely inhibits replication, with an efficiency of approximately 10 percent. In contrast, bypass replication efficiency with yeast DNA polymerase alpha was no more than 1 percent. The Rev3-Rev7 complex is the sixth eukaryotic DNA polymerase to be described, and is therefore called DNA polymerase zeta.

Mutagenicity of a unique thymine-thymine dimer or thymine-thymine pyrimidine pyrimidone (6-4) photoproduct in mammalian cells

The mutagenic properties of UV-induced photoproducts, both the cis-syn thymine-thymine dimer (TT) and the thymine-thymine pyrimidine pyrimidone (6-4) photoproduct [T(6-4)T] were studied in mammalian cells using shuttle vectors. A shuttle vector able to replicate in both mammalian cells and bacteria was produced in its single-stranded DNA form. A unique photoproduct was inserted at a single restriction site and after recircularization of the single-stranded DNA vector, this latter was transfected into simian COS7 cells. After DNA replication the vector was extracted from cells and used to transform bacteria. Amplified DNA was finally analyzed without any selective screening, DNA from randomly picked bacterial colonies being directly sequenced. Our results show clearly that both lesions are mutagenic, but at different levels. Mutation frequencies of 2 and 60% respectively were observed with the TT dimer and the T(6-4)T. With the TT dimer the mutations were targeted on the 3'-T. With the T(6-4)T a large variety of mutations were observed. A majority of G-->T transversions were semi-targeted to the base before the 5'-T of the photoproduct. These kinds of mutations were not observed when the same plasmid was transfected directly into SOS-induced JM105 bacteria or when the T(6-4)T oligonucleotide inserted in a different plasmid was replicated in SOS-induced SMH10 Escherichia coil bacteria. These semi-targeted mutations are therefore the specific result of bypass of the T(6-4)T lesion in COS7 cells by one of the eukaryotic DNA polymerases.

Substitution of mucAB or rumAB for umuDC alters the relative frequencies of the two classes of mutations induced by a site-specific T-T cyclobutane dimer and the efficiency of translesion DNA synthesis

We have examined the effect of replacing umuDC with mucAB or rumAB on the mutagenic properties of a T-T cyclobutane dimer in an attempt to determine the molecular basis for the differences in UV-induced mutagenesis that are associated with these structurally and functionally related genes. A single-stranded vector carrying a site-specific T-T cis-syn cyclobutane dimer was transfected into a set of isogenic Escherichia coli delta umuDC strains harboring low-copy-number plasmids expressing UmuDC, MucAB, RumAB, or their genetically engineered and mutagenically active counterparts UmuD'C, MucA'B, and RumA'B, respectively. Although the overall mutation frequency was similar for all strains, the relative frequencies of the two classes of mutation induced by the T-T dimer varied according to the mutagenesis operon expressed. In umuDC strains, 3' T-->A mutations outnumbered 3' T-->C mutations, but the reverse was true for the mucAB and rumAB strains. We also found that the T-T dimer was bypassed with differing efficiencies in unirradiated cells expressing wild-type UmuDC, MucAB, and RumAB proteins. These differences can probably be attributed to the relative efficiency of the normal cellular posttranslational activation of UmuD, MucA, and RumA, respectively, since recombinant constructs expressing the mutagenically active UmuD'C, MucA'B, and RumA'B proteins all promoted similarly high levels of bypass in UV-irradiated cells. These results suggest that the UmuD'/UmuC complex and its homologs may differ in their relative abilities to promote elongation from T - T and T - G mismatched termini. Alternatively, they may differentially influence the efficiency with which these mismatches are edited or influence nucleotide insertion by the catalytic subunit of the DNA polymerase III.

Complete replication of plasmid DNA containing a single UV-induced lesion in human cell extracts

To investigate the effect of the major UV-induced lesions on SV40 origin-dependent DNA replication and mutagenesis in a mammalian cell extract, double-stranded plasmids containing a single cis,syn-cyclobutane dimer or a pyrimidine-pyrimidone (6-4) photoproduct at a unique TT sequence have been constructed. These plasmids have been used as templates in DNA replication-competent extracts from human HeLa cells. Plasmids containing a single pyrimidine cyclobutane dimer on the potential lagging strand for DNA replication are replicated with an efficiency approximately equal to that of an unmodified plasmid. A small decrease in replication efficiency of approximately 20% was observed when the lesion was located on the potential leading strand for DNA replication. In both orientations, DpnI-resistant, replicated closed circular plasmid DNA was sensitive to nicking by the pyrimidine dimer-specific enzyme, T4 endonuclease V, indicating that complete replication of the damaged plasmid occurs in vitro. In contrast, a (6-4) photoproduct, within the same site and sequence context on the lagging strand for DNA synthesis, inhibits replication in vitro by an average of approximately 50%, indicating that the mammalian replication complex responds differently to the two major UV-induced lesions during DNA replication in vitro. Analysis of the DpnI-resistant, replicated DNA for mutations targeted to the lesion site indicates that neither of these lesions resulted in significant mutagenesis. UV-induced lesions at TT sites may therefore be poorly mutagenic under these conditions for DNA replication in human cell extracts in vitro.

Novel mutagenic properties of abasic sites in Saccharomyces cerevisiae

Abasic sites are particularly important in mutation research because they are frequently the ultimate lesion in chemical mutagenesis, and because they are believed to be a paradigm for non-pairing lesions. Although preferential insertion of dAMP ("A-rule") opposite the lesion has been observed in almost all previous studies with other organisms, we find that in budding yeast, Saccharomyces cerevisiae, the preferred nucleotide is dCMP, suggesting that yeast has a "C-rule", at least with respect to the vector constructs used. These constructs contained a single abasic site specifically located within a 28 nucleotide single-stranded region in an otherwise duplex vector. Nucleotide insertions were determined by sequence analysis of replicated vectors taken from a random set of yeast transformants. In three different sequence contexts, the frequencies of dCMP and dAMP insertion were 83% and 13%, 62% and 31%, and 85% and 8%, respectively. A similar bias in favor of cytosine insertion was found using vectors that were entirely single-stranded. However, a preference for dAMP insertion was found when Escherichia coli, rather than yeast, was transfected with samples of the same gapped duplex vector DNA. Preferential insertion of dCMP is not likely to have arisen by previously proposed mechanisms, but is also unlikely to have occurred by a primer/template misalignment mechanism, in which a nearby template guanine directs the insertion of cytosine. Predominant dCMP insertion was observed even when template guanine bases were excluded from a region extending 19 nucleotides 5', and 13 nucleotides 3', to the abasic site.

The T-T pyrimidine (6-4) pyrimidinone UV photoproduct is much less mutagenic in yeast than in Escherichia coli

We have examined the mutagenic properties of the T-T pyrimidine (6-4) pyrimidinone UV photoproduct in Saccharomyces cerevisiae, transforming the yeast cells either with single-stranded vectors that carried this adduct at a unique site or with gapped duplex vectors in which the adduct was located within a 28 nt single-stranded region. In an earlier study with SOS-induced Escherichia coli, we found that this photoproduct is highly mutagenic, specifically generating 3' T-->C substitutions in >85% of replicated molecules, and ascribed this specificity to the formation of a stable guanine-pyrimidinone mispair via hydrogen bonds at N-3 and O-2. In contrast, this adduct is very much less mutagenic in yeast, with 60-70% of molecules being replicated accurately and only 12-20% of them exhibiting 3' T-->C substitutions. The enhanced accuracy may reflect the ability of a yeast DNA polymerase, but not E.coli DNA polymerase III, to trap the adduct in a configuration favorable for the formation of an adenine-pyrimidinone base pair.

Cloning and sequence of REV7, a gene whose function is required for DNA damage-induced mutagenesis in Saccharomyces cerevisiae

The function of the REV7 gene is required for DNA damage-induced mutagenesis in budding yeast, Saccharomyces cerevisiae, and is therefore thought to promote replication past sites of mutagen damage in the DNA template. We have cloned this gene by complementation of the rev7-2 mutant defect, and determined its sequence. REV7 encodes a predicted protein of M(r) 28,759 which is unlikely any other protein in the NCBI non-redundant protein sequence data base, and which is inessential for viability.

Accuracy of replication past the T-C (6-4) adduct

The thymine-cytosine pyrimidine-pyrimidone (6-4) adduct has variously been predicted to be among the most and among the least mutagenic of the ultraviolet light photoproducts. We have therefore investigated the frequency and accuracy of DNA replication past this lesion, using a single-stranded M13mp7-based vector with a uniquely located example of this lesion transfected into SOS-induced and uninduced cells of a uvr A6 strain of Escherichia coli. Both the UVC T-C (6-4) adduct and its Dewar valence (UVB) photoisomer were studied. Random samples from non-selective collections of progeny phage were sequenced to determine the nature of the replication events that occurred at or near the site of template damage under SOS conditions. The UVC (6-4) adduct was found to be much less mutagenic than its T-T counterpart, but still much more mutagenic than a cyclobutane dimer; 34% (71 out of 206) of all bypass events yielded mutations, of which all were targeted and 80% (57 out of 71) were 3' C-->T transitions. The Dewar valence photoisomer exhibited reduced specificity and enhanced mutagenicity; 79% (183 out of 233) of the phage progeny were mutants, of which all but one were targeted and 45% (83 out of 183) were 3' C-->T transitions. For the most part, these results are consistent with a model postulating base-pairing between the pyrimidinone (of either the C or T variety) and guanine, via hydrogen bonds at N-3 and O-2 in the UVC, but not the Dewar, isomer. The occurrence of the 3' C-->T transitions, not predicted by this model, shows however that the absence of a methyl group at C-5 also has a significant influence on mutation induction. Both isomers were efficient blocks to replication; less than 1% of these vectors could be replicated in uninduced cells. Following SOS induction the frequency of bypass increased to 24.5% and 12.5% for the UVC and the Dewar isomers, respectively.

Repair by human cell extracts of single (6-4) and cyclobutane thymine-thymine photoproducts in DNA

One cis-syn cyclobutane thymine dimer or one (6-4) thymine-thymine photoproduct was built into an identical sequence of a closed-circular M13 duplex DNA, and nucleotide excision repair synthesis carried out by human cell extracts in the area containing each lesion was determined. Extracts from normal cells repaired the (6-4) photoproduct with a patch size of approximately 20-30 nucleotides, but repair was at least 10-fold lower at the cyclobutane dimer. The (6-4) lesion was repaired with comparable efficiency to a single acetylamino-fluorene-guanine adduct in a similar location. Extract from nucleotide excision repair-deficient xeroderma pigmentosum group A cells could not remove any of these adducts but could complete repair of the lesions after incision with Escherichia coli UvrABC proteins. This direct comparison of repair of two UV photoproducts, in an in vitro system where chromatin assembly and transcription are absent, suggests that the more rapid repair of the (6-4) lesion observed in the mammalian cell genome overall is due in part to a significant difference in the ability of the repair complex to locate and incise these lesions in DNA.

U-U and T-T cyclobutane dimers have different mutational properties

We have examined the mutagenic properties in E. coli of single stranded vectors containing a uniquely placed cis-syn or trans-syn uracil-uracil cyclobutane dimer in the sequence 5' GCAAGUUGGAG 3', and compared these with the properties of the corresponding T-T dimers in the same sequence context. The frequencies with which U-U and T-T photoproducts were bypassed were similar in SOS induced cells, and each induced similar frequencies of mutations. However, although both U-U and T-T cis-syn dimers showed a preference for misincorporation in about 5-7% of the replication products, with T or G being incorporated in place of A, the ratios of these events differed, being > 4:1 for T-T cis-syn, but only 2:1 for U-U cis-syn. A shift towards G insertion opposite dimerized uracil was also found with the trans-syn dimers, but the difference was greater; T and G were misincorporated opposite the U-U trans-syn dimer in a ratio of 1:2, compared with 4:1 for its T-T counterpart. In addition, the U-U dimer induced only nucleotide substitutions, unlike the T-T photoproduct which induced single nucleotide deletions as well as substitutions. We conclude that even relatively minor differences in photoproduct structure, such as the presence of a methyl group at C-5, can alter mutational properties, and that such properties cannot depend only on the attributes of the DNA polymerase. Neither the efficiency of bypass, the error frequency nor the mutation spectrum of either U-U isomer is influenced by DNA uracil glycosylase. In vitro, the U-U cis-syn dimer is a substrate for DNA photolyase, but not for the glycosylase.

Human non-secretory ribonucleases. I. Purification, peptide mapping and lectin blotting analysis of the kidney, liver and spleen enzymes

Human non-secretory neutral ribonucleases (RNases) from kidney, liver and spleen have been purified and characterized. SDS-PAGE indicates that all three RNases are highly purified and have apparent mol. wts of 17-18 kDa. Kinetic analysis indicates that all three RNases have a broad pH optimum centred around 6.5, and all three have similar substrate specificities with significant preference for RNA and poly(U) when compared to poly(C), poly(A) and poly(G). All of the above data, as well as immunoblotting data using three polyclonal antibodies (anti-human liver RNase, anti-human pancreatic RNase, anti-human eosinophil-derived neurotoxin), indicate that the three proteins are highly purified and are non-secretory RNases (IIN). Further characterization by cyanogen bromide peptide mapping and extensive lectin blotting indicated no significant differences between the three human RNases. All three RNases appear to have very similar, if not identical, protein backbones and all three are glycoproteins which are recognized by lectins with specificity for GlcNAc, Fuc and, to a lesser extent, with specificity for Gal beta(1-4)GlcNAc. No significant tissue-specific differences were found among the three human non-secretory RNases.

Human non-secretory ribonucleases. II. Structural characterization of the N-glycans of the kidney, liver and spleen enzymes by NMR spectroscopy and electrospray mass spectrometry

The N-glycans have been removed by peptide-N-glycosidase F (PNGase F) from purified human non-secretory RNases derived from kidney, liver and spleen. The spleen RNase was purified by two procedures, one of which did not include the usual acid treatment step (0.25 M H2SO4, 45 min, 4 degrees C), to determine if acid treatment alters the carbohydrate moieties. The N-glycans of the RNases were fractionated by Bio-Gel P-4 chromatography and analysed by 600 MHz 1H-NMR spectroscopy and electrospray mass spectrometry. All four non-secretory RNase preparations contained the following structures: [formula: see text] The relative amounts of the trisaccharide, pentasaccharide and hexasaccharide appeared to vary slightly in the different tissue RNases. The overall results indicate: (i) that acid treatment during purification does not alter the N-glycans of non-secretory RNases; (ii) that the N-glycans from kidney, liver and spleen non-secretory RNases are very similar, if not identical, to one another, but different from the N-glycan structures reported for secretory RNase.

The frequency and accuracy of replication past a thymine-thymine cyclobutane dimer are very different in Saccharomyces cerevisiae and Escherichia coli

We have compared the mutagenic properties of a T-T cyclobutane dimer in baker's yeast, Saccharomyces cerevisiae, with those in Escherichia coli by transforming each of these species with the same single-stranded shuttle vector carrying either the cis-syn or the trans-syn isomer of this UV photoproduct at a unique site. The mutagenic properties investigated were the frequency of replicational bypass of the photoproduct, the error rate of bypass, and the mutation spectrum. In SOS-induced E. coli, the cis-syn dimer was bypassed in approximately 16% of the vector molecules, and 7.6% of the bypass products had targeted mutations. In S. cerevisiae, however, bypass occurred in about 80% of these molecules, and the bypass was at least 19-fold more accurate (approximately 0.4% targeted mutations). Each of these yeast mutations was a single unique event, and none were like those in E. coli, suggesting that in fact the difference in error rate is much greater. Bypass of the trans-syn dimer occurred in about 17% of the vector molecules in both species, but with this isomer the error rate was higher in S. cerevisiae (21 to 36% targeted mutations) than in E. coli (13%). However, the spectra of mutations induced by the latter photoproduct were virtually identical in the two organisms. We conclude that bypass and error frequencies are determined both by the structure of the photoproduct-containing template and by the particular replication proteins concerned but that the types of mutations induced depend predominantly on the structure of the template. Unlike E. coli, bypass in S. cerevisiae did not require UV-induced functions.

Mutagenesis induced by single UV photoproducts in E. coli and yeast

Data from experiments with single-stranded vectors that carry a site-specific cyclobutane dimer, pyrimidine (6-4) pyrimidone adduct, or abasic lesion, replicated in either E. coli or, in some cases, bakers' yeast, Saccharomyces cerevisiae, are used to examine two questions: (i) what factors are responsible for the lesion's mutagenicity? and (ii) what are the relative contributions of different photoproducts to the spectrum of UV-induced mutations? With respect to the first question, we suggest that the structure of the mutagen-modified template itself largely determines the kinds of mutations induced, but the relative frequencies of these mutations, the error frequency, and the bypass frequency are strongly dependent on the particular organism studied. With respect to the second question, we suggest that cyclobutane dimers may be responsible for most of the mutations in slowly replicating genomes because of the deamination of cytosine, and that the T-T, and to a lesser extent the T-C, (6-4) adducts play a greater role in the UV mutagenesis of quickly replicating viruses, such as M13 and lambda phage.

The REV3 gene of Saccharomyces cerevisiae is transcriptionally regulated more like a repair gene than one encoding a DNA polymerase

We measured the relative steady-state levels of the mRNA transcribed from the Saccharomyces cerevisiae REV3 gene in cells at different stages of the mitotic and meiotic cycles, and after UV irradiation. This gene is thought to encode a DNA polymerase concerned only with a specific recovery function, the replication on mutagen-damaged templates that produces damaged-induced mutations. In keeping with this proposed function, the REV3 gene showed no evidence of the periodic transcription at the G1/S boundary of the mitotic and meiotic cycle that occurs with genes encoding replication enzymes. However, levels of REV3 mRNA were much increased in late meiotic cells, like those of transcripts of some other DNA repair-related genes. Steady-state levels of REV3 transcript were increased only slightly in response to UV irradiation.

The thymine-thymine pyrimidine-pyrimidone(6-4) ultraviolet light photoproduct is highly mutagenic and specifically induces 3' thymine-to-cytosine transitions in Escherichia coli

We have constructed single-stranded, M13-based vectors that contain a specifically located thymine-thymine pyrimidine-pyrimidone(6-4) UV photoproduct and have used these to estimate the frequency and accuracy of DNA replication past this adduct in uvrA6 cells of Escherichia coli. Both the normal and the Dewar valence photoisomer of the (6-4) adduct were studied. In the absence of SOS induction, vectors carrying the photoproducts were rarely replicated; relative to the lesion-free control, 1.9% of vectors carrying the normal (6-4) isomer produced plaques, and with the Dewar valence isomer the proportion was 0.4%. In SOS-induced cells, these frequencies rose to 22.1% and 12.3%, respectively. The error frequency of replication past the normal isomer in SOS-induced cells was high; in a random sample of 185 progeny phage analyzed, 169 (91%) contained mutations, all of which were targeted. Equally striking, a high proportion of the mutations (158/169; 93%) were of only one type, namely 3' T----C transitions. Both the error frequency and the specificity were much reduced with the Dewar valence isomer; overall, 74/140 (53%) of the phage analyzed were mutant, and of these only 34 (46%) entailed the 3' T----C transition. We speculate that the high error frequency and specificity arise from the formation of a stable T-G base pair, involving hydrogen bonds at O-2 and N-3 in the pyrimidone ring. Potential hydrogen bonds at these sites are coplanar in the normal but not in the Dewar isomer, perhaps explaining the reduced specificity of mutagenesis with the latter adduct.

T-T cyclobutane dimers are misinstructive, rather than non-instructive, mutagenic lesions

The lesions produced by SOS-dependent mutagens in Escherichia coli are commonly referred to as nonpairing or non-instructive. Although these terms are likely to be appropriate for some lesions, particularly the abasic site, for others, such as the cyclobutane dimer, their suitability is open to question. To address this question, we have compared the error frequencies and spectra that result when a uniquely located T-T sequence, carried in a single-stranded vector, contains either a cis-syn or a trans-syn cyclobutane dimer, or when either the 5'T or 3'T is converted to an abasic site. The data suggest that the high accuracy with which the dimer-containing templates are replicated is unlikely to be the consequence of polymerase preference for the non-instructive insertion of dAMP. Similarly, mispairing, rather than non-pairing, is likely to cause mutations. Cyclobutane dimers seem therefore to be misinstructive rather than non-instructive lesions, and the common feature shared by SOS-inducing lesions is more their ability to block replication than inability to form correct base pairs.

Mutation frequency and spectrum resulting from a single abasic site in a single-stranded vector

We have investigated the mutagenic properties of an abasic site in DNA by transfecting SOS-induced and uninduced cells of E. coli with a single-stranded M13mp7-based vector that carries a single example of this lesion at one or other of two unique and adjacent sites. Random samples of progeny phage were sequenced to determine the nature of the replication events that occurred at and around these locations. 5% to 7% of the vectors could be replicated in SOS-induced cells, but only 0.1% to 0.7% of them gave plaques in the absence of SOS induction. In SOS-induced cells, 93% and 96% of the phage replicated resulted from the insertion of a nucleotide opposite the abasic site, while the remainder resulted from a targeted omission of a single nucleotide. At one of the sites, nucleotide insertions were 54% dAMP, 25% dTMP, 20% dGMP and 1% dCMP. At the other site they were 80% dAMP, 4% dTMP, 15% dGMP and 1% dCMP. The sequence variation in all but two of the 204 sequences analyzed was restricted to the abasic site itself. In the remaining two, a change at the abasic site was accompanied by a mutation at an immediately flanking nucleotide.

SOS-dependent replication past a single trans-syn T-T cyclobutane dimer gives a different mutation spectrum and increased error rate compared with replication past this lesion in uninduced cells

We have transfected SOS-induced and uninduced cells of a uvrA6 strain of Escherichia coli with single-stranded M13mp7-based vectors that carried a single trans-syn T-T cyclobutane dimer at a unique site. Unlike constructs carrying the cis-syn isomer of this lesion, these vectors could be replicated with modest efficiency (14%) in the absence of SOS induction and therefore provided an opportunity to measure directly the influence of such induction on error rate and mutation spectrum. We found that translesion synthesis in the absence of SOS induction was remarkably accurate; only 4% of the replicated bacteriophage contained mutations, which were exclusively targeted single T deletions. In SOS-induced cells, error frequency increased to 11% and the resulting mutations included targeted substitutions and near-targeted single base additions, as well as the T deletions. Replication efficiency was 29% in these conditions. SOS induction therefore leads not only to an enhanced capacity to replicate damaged DNA but also to a marked change in mutation frequency and spectrum.

REV3, a Saccharomyces cerevisiae gene whose function is required for induced mutagenesis, is predicted to encode a nonessential DNA polymerase

We have cloned the REV3 gene of Saccharomyces cerevisiae by complementation of the rev3 defect in UV-induced mutagenesis. The nucleotide sequence of this gene encodes a predicted protein of Mr 172,956 showing significant sequence similarity to Epstein-Barr virus DNA polymerase and to other members of a class of DNA polymerases including human DNA polymerase alpha and yeast DNA polymerase I. REV3 protein shows less sequence identity, and presumably a more distant evolutionary relationship, to the latter two enzymes than they do to each other. Haploids carrying a complete deletion of REV3 are viable. We suggest that induced mutagenesis in S. cerevisiae depends on a specialized DNA polymerase that is not required for other replicative processes. REV3 is located 2.8 centimorgans from CDC60, on chromosome XVI.

Frequency and spectrum of mutations produced by a single cis-syn thymine-thymine cyclobutane dimer in a single-stranded vector

We have constructed a single-stranded vector that contains a uniquely located cis-syn T-T cyclobutane dimer by ligating a synthetic oligomer containing this UV photoproduct into M13mp7 viral DNA linearized with EcoRI. In the absence of SOS induction, transfection of a uvrA6 mutant of Escherichia coli with this vector gave very few progeny plaques, and the data imply that a single dimer blocks replication in at least 99.5% of the molecules. In vitro photoreactivation completely abolished this inhibition. Transfection of cells irradiated with UV at 4 J.m-2 to induce the SOS response gave 27% of the number of plaques found with a dimer-free control. Nucleotide sequence analysis of 529 progeny phage showed that translesion synthesis was usually accurate: the normal sequence was found in 93% of them. Where mutations occurred, all were targeted single-nucleotide substitutions, with approximately 90% being targeted at the 3' nucleotide of the lesion: of a total of 26 mutations, 15 were 3' T----A, 8 were 3' T----C, and 3 were 5' T----C. No T----G mutations were found. In addition to these results with the normal construct, data were also obtained from vectors in which the M13mp7 cloning site, which forms a hairpin in single-stranded DNA, was present 4 nucleotides on the 3' side of the T-T dimer. These hairpin-containing vectors gave a very similar mutation frequency (8% versus 7%) but altered mutation spectrum: all 12 mutations detected were 3' T----A transversions, a difference from the previous set of data that is significant (P = 0.03).

Ultraviolet light induces different spectra of lacI sequence changes in vegetative and conjugating cells of Escherichia coli

We have analyzed the nucleotide sequence changes responsible for mutations from lacIs to lacI- induced in ultraviolet light-irradiated, excision-deficient cells. Irradiated cells were either used as donors in the conjugational transfer of an F' lacIs plasmid to SOS-induced, excision-deficient recipients or allowed to continue vegetative growth. Although the types and proportions of premutagenic lesions are likely to have been very similar in these two circumstances, analysis of the sequence data shows that different spectra of mutations were induced. In vegetative cells there were about equal numbers of transitions and transversions, but transitions outnumbered transversions by about three to one in exconjugants. About 90% of the single nucleotide substitutions could be assigned to a bipyrimidine target sequence in both sets of data, but they differed with respect to the location of the substitution: more or less equal numbers were found at the 3' and 5' sites of the probable bipyrimidine target in vegetative cells, but in exconjugants over 80% were at the 3' site. It is also possible that mutations were targeted more commonly at T-C sequences in exconjugants than in vegetative cells, but the evidence for this is less secure. We conclude that these results reflect some dissimilarity between vegetative cells and exconjugants in the way damaged DNA is replicated or lesions tolerated, but the particular features of these processes responsible for the different mutational spectra have not yet been identified.

UmuC function is not essential for the production of all targeted lacI mutations induced by ultraviolet light

Up to a quarter or more of the normal yield of lacI- mutations could be induced by ultraviolet light in a uvrA6 umuC122:: Tn5 strain if they were detected by plating on 5-bromo-4-chloro-3-indolyl-beta-D-galactoside medium, where all surviving cells can form colonies. Using phenyl beta-D-galactoside selection, which curtails post-irradiation growth, only low yields of mutations were induced. Nucleotide sequence analysis of 134 spontaneous and 145 ultraviolet light-induced mutations shows that broadly similar kinds of mutations were induced in the umuC mutant and its uvrA6 umuC+ counterpart. In particular, these data offer no reason for believing that most of the mutations induced in the umuC mutant were other than normal, targeted events. We conclude that UmuC function, rather than being essential, facilitates recovery and specifically, following the model of Bridges & Woodgate, that it facilitates the prompt resumption of chain elongation.

The isolation and characterization of ngm2, a mutation that affects nitrosoguanidine mutagenesis in yeast

We have isolated and characterized a new mutant of Saccharomyces cerevisiae, carrying a single mutant allele that we designate ngm2-1, which is defective with respect to induced mutagenesis. This mutant was isolated by screening mutagenized clones for reduced frequencies of reversion of the his1-7 allele, induced by N-methyl-N-nitro-N-nitrosoguanidine. As judged by the reversion of his1-7 and ilv1-92, ngm2-1 mutant strains are also deficient with respect to mutability induced by methyl methane sulfonate, ethyl methane sulfonate and, at least partially, by UV. UV-induced reversion of the ochre mutation arg4-17 and the frameshift mutation his4-38 was not much affected by ngm2-1, however. Like rev3 and rev7 mutations, ngm2-1 also has little influence on the reversion of the proline missense allele, cyc1-115. Ngm2-1 mutants are only at best very slightly more sensitive to the toxicity of the four mutagens used, and homozygous diploids sporulate normally.

The isolation and characterization of an alkylating-agent-sensitive yeast mutant, ngs1

We have isolated and characterized a mutant of baker's yeast, Saccharomyces cerevisiae, carrying the new mutation, ngs1, which is sensitive to the toxic effects of monofunctional alkylating agents, but normal with respect to 254-nm ultraviolet light sensitivity. ngs1 mutants exhibited more or less normal reversion frequencies for his1-7 and ilv1-92 induced by each of these mutagens. The various sensitivities associated with ngs1 cosegregated and have been shown to be the result of a lesion in a single nuclear gene. Extracts of ngs1 and NGS1+ strains contained approximately equal levels of an activity that removes 3-methyladenine (3MA) and 7-methylguanine (7MG) from DNA in vitro. The mutation also depressed sporulation.