Spontaneous mutagenesis: the roles of DNA repair, replication, and recombination

There appears to be no dearth of mechanisms to explain spontaneous mutagenesis. In the case of base substitutions, data for bacteriophage T4 and especially for E. coli and S. cerevisiae suggest important roles in spontaneous mutagenesis for the error-prone repair of DNA damage (to produce mutations) and for error-free repair of DNA damage (to avoid mutagenesis). Data from the very limited number of studies on the subject suggest that about 50% of the spontaneous base substitutions in E. coli, and perhaps 90% in S. cerevisiae are due to error-prone DNA repair. On the other hand, spontaneous frameshifts and deletions seem to result from mechanisms involving recombination and replication. Spontaneous insertions have been shown to be important in the strongly polar inactivation of certain loci, but it is less important at other loci. Perhaps with continued study, the term "spontaneous mutagenesis" will be replaced by more specific terms such as 5-methylcytosine deamination mutagenesis, fatty acid oxidation mutagenesis, phenylalanine mutagenesis, and imprecise-recombination mutagenesis. While most studies have concentrated on mutator mutations, the most conclusive data for the actual source of spontaneous mutations have come from the study of antimutator mutations. Further study in this area, perhaps along with an understanding of chemical antimutagens, should be invaluable in clarifying the bases of spontaneous mutagenesis.     

Ligand specificity of odorant receptors

Odorant receptors belong to class A of the G protein-coupled receptors (GPCRs) and detect a large number of structurally diverse odorant molecules. A recent structural bioinformatic analysis suggests that structural features are conserved across class A of GPCRs in spite of their low sequence identity. Based on this work, we have aligned the sequences of 29 ORs for which ligand binding data are available. Recent site-directed mutagenesis experiments on one such receptor (MOR174-9) provide information that helped to identify nine amino-acid residues involved in ligand binding. Our modeling provides a rationale for amino acids in equivalent positions in most of the odorant receptors considered and helps to identify other amino acids that could be important for ligand binding. Our findings are consistent with most of the previous models and allow predictions for site-directed mutagenesis experiments, which could also validate our model.     

Iterative saturation mutagenesis (ISM) for rapid directed evolution of functional enzymes

Iterative saturation mutagenesis (ISM) is a new and efficient method for the directed evolution of functional enzymes. It reduces the necessary molecular biological work and the screening effort drastically. It is based on a Cartesian view of the protein structure, performing iterative cycles of saturation mutagenesis at rationally chosen sites in an enzyme, a given site being composed of one, two or three amino acid positions. The basis for choosing these sites depends on the nature of the catalytic property to be improved, e.g., enantioselectivity, substrate acceptance or thermostability. In the case of thermostability, sites showing highest B-factors (available from X-ray data) are chosen. The pronounced increase in thermostability of the lipase from Bacillus subtilis (Lip A) as a result of applying ISM is illustrated here.     

Penicillin-binding and degrading enzymes

Within the past year, two refined crystal structures of class-A β-lactamases have been reported, adding accurate structural details to previous crystallographic work on various β-lactamases and one penicillin-binding protein. In addition, mutagenesis data linked to kinetic analysis are accumulating rapidly. Proposals concerning the catalytic mechanism, substrate specificity, and folding properties of this important group of enzymes may now be tested more rigorously using these data.     

PCR mutagenesis identifies a polymerase-binding sequence of sigma 54 that includes a sigma 70 homology region.

Sigma 54 is a minor bacterial sigma factor that is not a member of the sigma 70 family of proteins but binds the same core RNA polymerase. Previously, we identified a region of sigma 54 that is important for binding core polymerase. In this work, PCR mutagenesis was used to identify specific amino acids important for this binding. The results show that important residues are clustered most closely in a short sequence that was previously speculated to be potentially homologous to a sequence in sigma 70. The mutagenesis also identifies important residues in the flanking hydrophobic-acidic region of sigma 54, which is absent in sigma 70. Overall, the data indicate that sigma 54 binds core polymerase through a sequence homologous to that of sigma 70 but in addition uses unique motifs to modify this interaction.     

Cluster and information entropy patterns in immunoglobulin complementarity determining regions

Previous studies of antibody binding domains have established many crucial features that include important structural positions, canonical formations, and the geometric correlations with the binding site nature and topography. In this work, position-specific frequency and hierarchical clustering analysis are used to explore the statistical pattern of the residues in the complementarity determining regions of human antibodies. In addition, Shannon's information entropy is computed for the entire heavy and light chains and compared with germline patterns to seek variability due to antibody clonal selection. Results are compared with reported analyses based on structural data and ligand-protein contact point computations based on Protein Data Bank records. Observations derived from the present sequence analysis are consistent with previous structural based methods. In the absence of structural data, methods used in this work can be effective and efficient computational tools used for identifying residues that are important for antigen targeting and predicting the probable amino acid distribution expected at these positions. The results in turn can be applied to help design or plan mutagenesis experiments to improve the binding properties of antibodies.     

In vitro studies of membrane protein folding.

The study of membrane protein folding is a new and challenging research field. Consequently, there are few direct studies on the in vitro folding of membrane proteins. This review covers work aimed at understanding folding mechanisms and the intermolecular forces that drive the folding of integral membrane proteins. We discuss the kinetic and thermodynamic studies that have been undertaken. Our review also draws on closely related research, mainly from purification studies of functional membrane proteins, and gives an overview of some of the successful methods. A brief survey is also given of the large body of mutagenesis and fragment work on membrane proteins, as this too has relevance to the folding problem. It is noticeable that the choice of solubilizing detergents and lipids can determine the success of the method, and indeed it appears that particular lipid properties can be used to control the rate and efficiency of folding. This has important ramifications for much in vitro folding work in that it aids our understanding of how to obtain and handle folded, functional protein. With this in mind, we also cover some relevant properties of model, lipid-bilayer systems.     

Perspectives on the use of an endogenous gene target in studies of mutational specificity

Mutational spectra have become increasingly important tools in generating a molecular level understanding of mutagenesis in mammalian cells. The work in this field has primarily involved the use of shuttle vector systems although some work has also been reported using endogenous cellular genes as mutational targets. In this communication we discuss the relative utility of these two approaches. We specifically focus on UV light-induced mutagenesis since this agent has been studied in both types of system. We conclude that shuttle vector and endogenous gene studies of mutagenesis are highly complementary, each possessing unique advantages.     

Structure-function relationships in heme-proteins

Biological systems rely on heme-proteins to carry out a number of basic functions essential for their survival. Hemes, or iron-porphyrin complexes, are the versatile and ubiquitous active centers of these proteins. In the past decade, discovery of new heme-proteins, together with functional and structural research, provided a wealth of information on these diverse and biologically important molecules. Structure determination work has shown that nature has used a variety of different scaffolds and architectures to bind heme and modulate functions such as redox properties. Structural data have also provided insights into the heme-linked protein conformational changes required in many regulatory heme-proteins. Remarkable efforts have been made towards the understanding of factors governing redox potentials. Site-directed mutagenesis studies and theoretical calculations on heme environments investigated the roles of hydrophobic and electrostatic residues, and analyzed the effect of heme solvent accessibility. This review focuses on the structure-function relationships underlying the association of heme in signaling and iron metabolism proteins. In addition, an account is given about molecular features affecting heme's redox properties; this briefly revisits previous conclusions in the light of some more recent reports.     

Differential recognition of ultraviolet lesions by RecA protein. Possible mechanism for preferential targeting of SOS mutagenesis to (6-4) dipyrimidine sites

A knowledge of the biochemical basis for UV-induced mutagenesis requires an understanding of the interaction of SOS-activated proteins with DNA polymerase at the replication-blocking dipyrimidine lesions. We have suggested previously that the presence of RecA in this multiprotein complex might be an important feature of induced mutagenesis because RecA associates preferentially with UV-irradiated double-stranded DNA compared to nonirradiated DNA. Previous work by others has indicated that (6-4) dipyrimidine lesions might be more mutagenic than the more common cyclobutane dimer. We have explored the possibility that RecA associates more efficiently with (6-4) lesions than with cyclobutane lesions. We have found that RecA binds DNA with (6-4) lesions much more efficiently than DNA with solely cyclobutane lesions. The distinction between substrates is probably achieved by differential nucleation of the RecA nucleoprotein filament. To investigate the structural basis for differential binding of RecA, we have estimated the unwinding of duplex DNA introduced by (6-4) and cyclobutane lesions. Our data indicate that (6-4) lesions introduce much greater distortion than cyclobutane dimers. We conclude that RecA probably binds preferentially at sites of (6-4) lesions in DNA and that this localization of RecA might target the mutagenic response more frequently to those sites.     

The MBLOSUM: a server for deriving mutation targets and position-specific substitution rates

To facilitate mutagenesis study, it is necessary to be able to derive mutation targets and associated substitution rates in the sequence of interest regardless of the availability of corresponding structure. It is also important to obtain these data depending on the specific aims of the mutation process. The MBLOSUM server determines candidate positions for mutations and derives position-specific substitution rates given only a protein sequence. Different sets of complete genomes collected according to their phylogeny or specificity of environments along with compete set of non-redundant sequences can be used in calculations depending on the experimental task. MBLOSUM server is available at: http://apps.cbu.uib.no/mblosum.     

Human IFN-alpha protein engineering: the amino acid residues at positions 86 and 90 are important for antiproliferative activity

Human IFN-alpha is a family of structurally related proteins that exhibit a wide range of antiproliferative activities. To understand the structural basis for these different antiproliferative activities, eight recombinant human IFN-alpha hybrids (HY) of alpha21a/alpha2c (HY-4, HY-5) and mutants (site-directed mutagenesis (SDM)-1, 2 and cassette mutagenesis (CM)-1, 2, 3, and 4) have been expressed, purified, and characterized. The data showed that the amino acid region 81-95 is important for antiproliferative activity. Site-directed mutagenesis and cassette mutagenesis studies showed that if serine (S) 86 and asparagine (N) 90 were replaced by tyrosine (Y), the antiproliferative activity was increased. We have also observed that if Y86 was replaced by isoleucine (I), the antiproliferative activity was comparable. However, if Y86 was replaced by aspartic acid (D), lysine (K), or alanine (A), the antiproliferative activity was substantially decreased. Our results indicate that Y and/or I at position 86 and Y at position 90 are very important in antiproliferative activity of human IFN-alpha. Circular dichroism spectra showed that the amino acid replacements at position 86 did not change the secondary structure. Thus the biological activity changes among those mutants do not appear to be due to conformational changes. The results also suggest that hydrophobic residue(s) at position 86 may be important for the interaction of the molecule with its receptor. The competitive binding data correlated with the antiproliferative activity. The N-terminal region of the molecule and the hydrophobic residues (including Y and I) on the C-helix region at positions 86 and/or 90 are important for binding and antiproliferative activities of human IFN-alphas.     

Structural and Energetic Effects of A2A Adenosine Receptor Mutations on Agonist and Antagonist Binding

To predict structural and energetic effects of point mutations on ligand binding is of considerable interest in biochemistry and pharmacology. This is not only useful in connection with site-directed mutagenesis experiments, but could also allow interpretation and prediction of individual responses to drug treatment. For G-protein coupled receptors systematic mutagenesis has provided the major part of functional data as structural information until recently has been very limited. For the pharmacologically important A_2A adenosine receptor, extensive site-directed mutagenesis data on agonist and antagonist binding is available and crystal structures of both types of complexes have been determined. Here, we employ a computational strategy, based on molecular dynamics free energy simulations, to rationalize and interpret available alanine-scanning experiments for both agonist and antagonist binding to this receptor. These computer simulations show excellent agreement with the experimental data and, most importantly, reveal the molecular details behind the observed effects which are often not immediately evident from the crystal structures. The work further provides a distinct validation of the computational strategy used to assess effects of point-mutations on ligand binding. It also highlights the importance of considering not only protein-ligand interactions but also those mediated by solvent water molecules, in ligand design projects.     

Dual role of NER in mutagenesis in Pseudomonas putida

Nucleotide excision repair (NER) is one of the most important repair systems which counteracts different forms of DNA damage either induced by various chemicals or irradiation. At the same time, less is known about the functions of NER in repair of DNA that is not exposed to exogenous DNA-damaging agents. We have investigated the role of NER in mutagenesis in Pseudomonas putida. The genome of this organism contains two uvrA genes, uvrA and uvrA2. Genetic studies on the effects of uvrA, uvrA2, uvrB and UvrC in mutagenic processes revealed that all of these genes are responsible for the repair of UV-induced DNA damage in P. putida. However, uvrA plays more important role in this process than uvrA2 since the deletion of uvrA2 gene had an effect on the UV-tolerance of bacteria only in the case when uvrA was also inactivated. Interestingly, the lack of functional uvrB, uvrC or uvrA2 gene reduced the frequency of stationary-phase mutations. The contribution of uvrA2, uvrB and uvrC to the mutagenesis appeared to be most significant in the case of 1-bp deletions whose emergence is dependent on error-prone DNA polymerase Pol IV. These data imply that NER has a dual role in mutagenesis in P. putida-besides functioning in repair of damaged DNA, NER is also important in generation of mutations. We hypothesize that NER enzymes may initiate gratuitous DNA repair and the following DNA repair synthesis might be mutagenic.     

Mathematical expressions useful in the construction, description and evaluation of protein libraries

The creation of protein libraries by random mutagenesis and cassette mutagenesis has proven to be a successful method of protein engineering. Appropriate statistical analysis is important for the proper construction of these libraries and even more important for the interpretation of data from these libraries. We present simple mathematical expressions useful in the creation and evaluation of such libraries. These equations are useful in estimating the distribution of mutations, the degeneracy of the library and the frequency of a particular clone in the library. In addition, general equations addressing the probability that a particular clone is in a library, the probability that a library is complete, and as the consequences of retransformation of the library on these probabilities are presented.     

Insertional versus targeted mutagenesis in mice.

Recent innovations in mutagenesis techniques for mice have the potential to revolutionize the molecular genetic analysis of mouse development. Insertional mutagenesis by the introduction of exogenous DNA into the mouse germline hs permitted the molecular cloning and analysis of several novel genes important for early embryonic development. Targeted mutagenesis by homologous recombination in embryonic stem cells permits, in theory, the production of mutations in any cloned gene. The complementary information being obtained from these two mutagenesis procedures is shedding new light on the genes important for early mouse development, and the roles these genes play in that process.     

Importance of Gly-13 for the coenzyme binding of human UDP-glucose dehydrogenase

UDP-glucose dehydrogenase (UGDH) is the unique pathway enzyme furnishing in vertebrates UDP-glucuronate for numerous transferases. In this report, we have identified an NAD(+)-binding site within human UGDH by photoaffinity labeling with a specific probe, [(32)P]nicotinamide 2-azidoadenosine dinucleotide (2N(3) NAD(+)), and cassette mutagenesis. For this work, we have chemically synthesized a 1509-base pair gene encoding human UGDH and expressed it in Escherichia coli as a soluble protein. Photolabel-containing peptides were generated by photolysis followed by tryptic digestion and isolated using the phosphopeptide isolation kit. Photolabeling of these peptides was effectively prevented by the presence of NAD(+) during photolysis, demonstrating a selectivity of the photoprobe for the NAD(+)-binding site. Amino acid sequencing and compositional analysis identified the NAD(+)-binding site of UGDH as the region containing the sequence ICCIGAXYVGGPT, corresponding to Ile-7 through Thr-19 of the amino acid sequence of human UGDH. The unidentified residue, X, can be designated as a photolabeled Gly-13 because the sequences including the glycine residue in question have a complete identity with those of other UGDH species known. The importance of Gly-13 residue in the binding of NAD(+) was further examined with a G13E mutant by cassette mutagenesis. The mutagenesis at Gly-13 had no effects on the expression or stability of the mutant. Enzyme activity of the G13E point mutant was not measurable under normal assay conditions, suggesting an important role for the Gly-13 residue. No incorporation of [(32)P]2N(3)NAD(+) was observed for the G13E mutant. These results indicate that Gly-13 plays an important role for efficient binding of NAD(+) to human UGDH.     

Large-scale mutational analysis for the annotation of the mouse genome

After sequencing the human and mouse genomes, the annotation of these sequences with biological functions is an important challenge in genomic research. A major tool to analyse gene function on the organismal level is the analysis of mutant phenotypes. Because of its genetic and physiological similarity to man, the mouse has become the model organism of choice for the study of genetic diseases. In addition, there is at the moment no other vertebrate for which versatile techniques to manipulate the genome are as well developed. Several mouse mutagenesis projects have provided the proof-of-principle that a systematic and comprehensive mutagenesis of every gene in the mammalian genome will be feasible. An exhaustive functional annotation of the mammalian genome can only be achieved in a combination of phenotype- and gene-driven approaches in large- and small-scale academic and private projects. Major challenges will be to develop standardised phenotyping protocols for the clinical and pathological characterisation of mouse mutants, the improvement of mutation detection methods and the dissemination of resources and data. Beyond gene annotation, it will be necessary to understand how gene functions are integrated into the complex network of regulatory interactions in the cell.     

The stachydrine catabolism region in Sinorhizobium meliloti encodes a multi-enzyme complex similar to the xenobiotic degrading systems in other bacteria

Stachydrine (proline betaine) can be used by Sinorhizobium meliloti as a source of carbon and nitrogen. Catabolism depends on an initial N-demethylation, after which the resultant N-methyl proline enters general metabolism. Deletion and insertion mutagenesis demonstrated that the information necessary for catabolism is carried on the symbiotic plasmid (pSym) distal to nodD2 and the nod-nif cluster. Sequencing of an 8.5kb fragment spanning this region revealed four open reading frames with functional homology to known proteins, including a putative monooxygenase and a putative NADPH-FMN-reductase, which were shown by insertional and frame-shift mutagenesis to be necessary for stachydrine catabolism. Other open reading frames, encoding a putative flavoprotein and a repressor, were judged not to be required for stachydrine catabolism, since they were not included in a fragment capable of complementing a deletion of the entire stc region. Sequence and mutagenesis data suggest that stachydrine is demethylated by an iron-sulfur monooxygenase of the Rieske type with a requirement for a specific reductase. The stc catabolic cluster, therefore, resembles xenobiotic degradation in other bacteria and recalls rhizopine catabolism in S. meliloti. Stachydrine appears to have multiple roles in osmoprotection, nutrition and nodulation. Genes involved in stachydrine catabolism are also necessary for carnitine degradation; thus, they could be important in the catabolism of a variety of root exudates and mediate other relationships.