Vladislav A. Lanzov

Insights into thermal resistance of proteins from the intrinsic stability of their α‐helices

To investigate the role of α helices in protein thermostability, we compared energy characteristics of α helices from thermophilic and mesophilic proteins belonging to four protein families of known three‐dimensional structure, for at least one member of each family. The changes in intrinsic free energy of α‐helix formation were estimated using the statistical mechanical theory for describing helix/coil transitions in peptide helices [Munoz, V., Serrano, L. Nature Struc. Biol. 1:399–409, 1994; Munoz, V., Serrano, L. J. Mol. Biol. 245:275–296, 1995; Munoz, V., Serrano, L. J. Mol. Biol. 245:297–308, 1995]. Based on known sequences of mesophilic and thermophilic RecA proteins we found that (1) a high stability of α helices is necessary but is not a sufficient condition for thermostability of RecA proteins, (2) the total helix stability, rather than that of individual helices, is the factor determining protein thermostability, and (3) two facets of intrahelical interactions, the intrinsic helical propensities of amino acids and the side chain–side chain interactions, are the main contributors to protein thermostability. Similar analysis applied to families of L‐lactate dehydrogenases, seryl‐tRNA synthetases, and aspartate amino transferases led us to conclude that an enhanced total stability of α helices is a general feature of many thermophilic proteins. The magnitude of the observed decrease in intrinsic free energy on α‐helix formation of several thermoresistant proteins was found to be sufficient to explain the experimentally determined increase of their thermostability. Free energies of intrahelical interactions of different RecA proteins calculated at three temperatures that are thought to be close to its normal environmental conditions were found to be approximately equal. This indicates that certain flexibility of RecA protein structure is an essential factor for protein function. All RecA proteins analyzed fell into three temperature‐dependent classes of similar α‐helix stability (ΔGint = 45.0 ± 2.0 kcal/mol). These classes were consistent with the natural origin of the proteins. Based on the sequences of protein α helices with optimized arrangement of stabilizing interactions, a natural reserve of RecA protein thermoresistance was estimated to be sufficient for conformational stability of the protein at nearly 200°C. Proteins 29:309–320, 1997.

Overexpression of bacterial RecA protein stimulates homologous recombination in somatic mammalian cells.

The pairing of homologous molecules and strand exchange is a key event in homologous recombination promoted by RecA protein in Escherichia coli. Structural homologs of RecA are widely distributed in eukaryotes including mouse and man. As has been shown, human HsRad51 protein is not only structural but also functional homolog of RecA. The question arises whether the bacterial functional homolog of Rad51 can function in mammalian cells and increase the frequency of the homologous recombination. To investigate possible effects of bacterial RecA protein on the frequency of homologous recombination in mammalian cells, the E. coli RecA protein fused with a nuclear location signal from the large T antigen of simian virus 40 was overexpressed in the mouse F9 teratocarcinoma cells. We found that the frequency of gene targeting at the hprt locus was 10-fold increased in the mouse cells expressing the nucleus-targeted RecA protein. Southern blot analysis of individual clones that were generated by targeting recombination revealed predicted type of alterations in hprt gene. The data indicate that the bacterial nucleus-targeted RecA protein can stimulate homologous recombination in mammalian cells.

Efficient Strand Transfer by the RadA Recombinase from the Hyperthermophilic Archaeon Desulfurococcus amylolyticus

The radA gene predicted to be responsible for homologous recombination in a hyperthermophilic archaeon, Desulfurococcus amylolyticus, was cloned, sequenced, and overexpressed in Escherichia coli cells. The deduced amino acid sequence of the gene product, RadA, was more similar to the human Rad51 protein (65% homology) than to the E. coli RecA protein (35%). A highly purified RadA protein was shown to exclusively catalyze single-stranded DNA-dependent ATP hydrolysis, which monitored presynaptic recombinational complex formation, at temperatures above 65 degrees C (catalytic rate constant of 1.2 to 2.5 min(-1) at 80 to 95 degrees C). The RadA protein alone efficiently promoted the strand exchange reaction at the range of temperatures from 80 to 90 degrees C, i.e., at temperatures approaching the melting point of DNA. It is noteworthy that both ATP hydrolysis and strand exchange are very efficient at temperatures optimal for host cell growth (90 to 92 degrees C).

Biochemical basis of hyper‐recombinogenic activity of Pseudomonas aeruginosa RecA protein in Escherichia coli cells

The replacement of Escherichia coli recA gene (recAEc) with the Pseudomonas aeruginosa recAPa gene in Escherichia coli cells results in constitutive hyper‐recombination (high frequency of recombination exchanges per unit length of DNA) in the absence of constitutive SOS response. To understand the biochemical basis of this unusual in vivo phenotype, we compared in vitro the recombination properties of RecAPa protein with those of RecAEc protein. Consistent with hyper‐recombination activity, RecAPa protein appeared to be more proficient both in joint molecule formation, producing extensive DNA networks in strand exchange reaction, and in competition with single‐stranded DNA binding (SSB) protein for single‐stranded DNA (ssDNA) binding sites. The RecAPa protein showed in vitro a normal ability for cleavage of the E. coli LexA repressor (a basic step in SOS regulon derepression) both in the absence and in the presence (i.e. even under suboptimal conditions for RecAEc protein) of SSB protein. However, unlike other hyper‐recombinogenic proteins, such as RecA441 and RecA730, RecAPa protein displaced insufficient SSB protein from ssDNA at low magnesium concentration to induce the SOS response constitutively. In searching for particular characteristics of RecAPa in comparison with RecAEc, RecA441 and RecA803 proteins, RecAPa showed unusually high abilities: to be resistant to the displacement by SSB protein from poly(dT); to stabilize a ternary complex RecA::ATP::ssDNA to high salt concentrations; and to be much more rapid in both the nucleation of double‐stranded DNA (dsDNA) and the steady‐state rate of dsDNA‐dependent ATP hydrolysis at pH 7.5. We hypothesized that the high affinity of RecAPa protein for ssDNA, and especially dsDNA, is the factor that directs the ternary complex to bind secondary DNA to initiate additional acts of recombination instead of to bind LexA repressor to induce constitutive SOS response.

Nucleotide sequence between recA and alaSp in E. coli K12 and the sequence change in four recA mutations

The sequence of 366 nucleotides between the C-terminal trailer region of recA and the N-terminal leader region of alaS is presented. This sequence reveals an open reading frame of 166 codons we have named oraA. An NdeI restriction nuclease cleavage site also revealed by the sequence was used to clone, map and sequence three recA mutations: recA11, recA12 and recA52. A mutation in recA (recA946), was discovered in strains originally reported to contain recH166. The relation between recA946 and recH166 is unclear.

Modulating cellular recombination potential through alterations in RecA structure and regulation.

The wild‐type Escherichia coli RecA protein is a recombinase platform with unrealized recombination potential. We have explored the factors affecting recombination during conjugation with a quantitative assay. Regulatory proteins that affect RecA function have the capacity to increase or decrease recombination frequencies by factors up to sixfold. Autoinhibition by the RecA C‐terminus can affect recombination frequency by factors up to fourfold. The greatest changes in recombination frequency measured here are brought about by point mutations in the recA gene. RecA variants can increase recombination frequencies by more than 50‐fold. The RecA protein thus possesses an inherently broad functional range. The RecA protein of E. coli (EcRecA) is not optimized for recombination function. Instead, much of the recombination potential of EcRecA is structurally suppressed, probably reflecting cellular requirements. One point mutation in EcRecA with a particularly dramatic effect on recombination frequency, D112R, exhibits an enhanced capacity to load onto SSB‐coated ssDNA, overcome the effects of regulatory proteins such as PsiB and RecX, and to pair homologous DNAs. Comparisons of key RecA protein mutants reveal two components to RecA recombination function – filament formation and the inherent DNA pairing activity of the formed filaments.

Two RecA Protein Types That Mediate Different Modes of Hyperrecombination

RecAX53 is a chimeric variant of the Escherichia coli RecA protein (RecAEc) that contains a part of the central domain of Pseudomonas aeruginosa RecA (RecAPa), encompassing a region that differs from RecAEc at 12 amino acid positions. Like RecAPa, this chimera exhibits hyperrecombination activity in E. coli cells, increasing the frequency of recombination exchanges per DNA unit length (FRE). RecAX53 confers the largest increase in FRE observed to date. The contrasting properties of RecAX53 and RecAPa are manifested by in vivo differences in the dependence of the FRE value on the integrity of the mutS gene and thus in the ratio of conversion and crossover events observed among their hyperrecombination products. In strains expressing the RecAPa or RecAEc protein, crossovers are the main mode of hyperrecombination. In contrast, conversions are the primary result of reactions promoted by RecAX53. The biochemical activities of RecAX53 and its ancestors, RecAEc and RecAPa, have been compared. Whereas RecAPa generates a RecA presynaptic complex (PC) that is more stable than that of RecAEc, RecAX53 produces a more dynamic PC (relative to both RecAEc and RecAPa). The properties of RecAX53 result in a more rapid initiation of the three-strand exchange reaction but an inability to complete the four-strand transfer. This indicates that RecAX53 can form heteroduplexes rapidly but is unable to convert them into crossover configurations. A more dynamic RecA activity thus translates into an increase in conversion events relative to crossovers.

Analytical model for determination of parameters of helical structures in solution by small angle scattering: comparison of RecA structures by SANS

The filament structures of the self‐polymers of RecA proteins from Escherichia coli and Pseudomonas aeruginosa, their complexes with ATPγS, phage M13 single‐stranded DNA (ssDNA) and the tertiary complexes RecA::ATPγS::ssDNA were compared by small angle neutron scattering. A model was developed that allowed for an analytical solution for small angle scattering on a long helical filament, making it possible to obtain the helical pitch and the mean diameter of the protein filament from the scattering curves. The results suggest that the structure of the filaments formed by these two RecA proteins, and particularly their complexes with ATPγS, is conservative.

Rad51 Protein from the Thermotolerant Yeast Pichia angusta as a Typical but Thermodependent Member of the Rad51 Family

ABSTRACT The Rad51 protein from the methylotrophic yeast Pichia angusta (Rad51Pa) of the taxonomic complex Hansenula polymorpha is a homolog of the RecA-RadA-Rad51 protein superfamily, which promotes homologous recombination and recombination repair in prokaryotes and eukaryotes. We cloned the RAD51 gene from the cDNA library of the thermotolerant P. angusta strain BKM Y1397. Induction of this gene in a rad51-deficient Saccharomyces cerevisiae strain partially complemented the survival rate after ionizing radiation. Purified Rad51Pa protein exhibited properties typical of the superfamily, including the stoichiometry of binding to single-stranded DNA (ssDNA) (one protomer of Rad51Pa per 3 nucleotides) and DNA specificity for ssDNA-dependent ATP hydrolysis [poly(dC) > poly(dT) > φX174 ssDNA > poly(dA) > double-stranded M13 DNA]. An inefficient ATPase and very low cooperativity for ATP interaction position Rad51Pa closer to Rad51 than to RecA. Judging by thermoinactivation, Rad51Pa alone was 20-fold more thermostable at 37°C than its S. cerevisiae homolog (Rad51Sc). Moreover, it maintained ssDNA-dependent ATPase and DNA transferase activities up to 52 to 54°C, whereas Rad51Sc was completely inactive at 47°C. A quick nucleation and an efficient final-product formation in the strand exchange reaction promoted by Rad51Pa occurred only at temperatures above 42°C. These reaction characteristics suggest that Rad51Pa is dependent on high temperatures for activity.

Hyper-recombinogenic RecA protein from Pseudomonas aeruginosa with enhanced activity of its primary DNA binding site.

According to one prominent model, each protomer in the activated nucleoprotein filament of homologous recombinase RecA possesses two DNA-binding sites. The primary site binds (1) single-stranded DNA (ssDNA) to form presynaptic complex and (2) the newly formed double-stranded (ds) DNA whereas the secondary site binds (1) dsDNA of a partner to initiate strand exchange and (2) the displaced ssDNA following the strand exchange. RecA protein from Pseudomonas aeruginosa (RecAPa) promotes in Escherichia coli hyper-recombination in an SOS-independent manner. Earlier we revealed that RecAPa rapidly displaces E.coli SSB protein (SSB-Ec) from ssDNA to form presynaptic complex. Here we show that this property (1) is based on increased affinity of ssDNA for the RecAPa primary DNA binding site while the affinity for the secondary site remains similar to that for E.coli RecA, (2) is not specific for SSB-Ec but is also observed for SSB protein from P.aeruginosa that, in turn, predicts a possibility of enhanced recombination repair in this pathogenic bacterium.