A DNA ligase from the psychrophile Pseudoalteromonas haloplanktis gives insights into the adaptation of proteins to low temperatures.

The cloning, overexpression and characterization of a cold-adapted DNA ligase from the Antarctic sea water bacterium Pseudoalteromonas haloplanktis are described. Protein sequence analysis revealed that the cold-adapted Ph DNA ligase shows a significant level of sequence similarity to other NAD+-dependent DNA ligases and contains several previously described sequence motifs. Also, a decreased level of arginine and proline residues in Ph DNA ligase could be involved in the cold-adaptation strategy. Moreover, 3D modelling of the N-terminal domain of Ph DNA ligase clearly indicates that this domain is destabilized compared with its thermophilic homologue. The recombinant Ph DNA ligase was overexpressed in Escherichia coli and purified to homogeneity. Mass spectroscopy experiments indicated that the purified enzyme is mainly in an adenylated form with a molecular mass of 74 593 Da. Ph DNA ligase shows similar overall catalytic properties to other NAD+-dependent DNA ligases but is a cold-adapted enzyme as its catalytic efficiency (kcat/Km) at low and moderate temperatures is higher than that of its mesophilic counterpart E. coli DNA ligase. A kinetic comparison of three enzymes adapted to different temperatures (P. haloplanktis, E. coli and Thermus scotoductus DNA ligases) indicated that an increased kcat is the most important adaptive parameter for enzymatic activity at low temperatures, whereas a decreased Km for the nicked DNA substrate seems to allow T. scotoductus DNA ligase to work efficiently at high temperatures. Besides being useful for investigation of the adaptation of enzymes to extreme temperatures, P. haloplanktis DNA ligase, which is very efficient at low temperatures, offers a novel tool for biotechnology.     

Structural and functional adaptations to extreme temperatures in psychrophilic,mesophilic, and thermophilic DNA ligases

Psychrophiles, host of permanently cold habitats, display metabolic fluxes comparable to those exhibited by mesophilic organisms at moderate temperatures. These organisms have evolved by producing, among other peculiarities, cold-active enzymes that have the properties to cope with the reduction of chemical reaction rates induced by low temperatures. The emerging picture suggests that these enzymes display a high catalytic efficiency at low temperatures through an improved flexibility of the structural components involved in the catalytic cycle, whereas other protein regions, if not implicated in catalysis, may be even more rigid than their mesophilic counterparts. In return, the increased flexibility leads to a decreased stability of psychrophilic enzymes. In order to gain further advances in the analysis of the activity/flexibility/stability concept, psychrophilic, mesophilic, and thermophilic DNA ligases have been compared by three-dimensional-modeling studies, as well as regards their activity, surface hydrophobicity, structural permeability, conformational stabilities, and irreversible thermal unfolding. These data show that the cold-adapted DNA ligase is characterized by an increased activity at low and moderate temperatures, an overall destabilization of the molecular edifice, especially at the active site, and a high conformational flexibility. The opposite trend is observed in the mesophilic and thermophilic counterparts, the latter being characterized by a reduced low temperature activity, high stability and reduced flexibility. These results strongly suggest a complex relationship between activity, flexibility and stability. In addition, they also indicate that in cold-adapted enzymes, the driving force for denaturation is a large entropy change.     

Activity,stability and flexibility in glycosidases adapted to extreme thermal environments

To elucidate the strategy of low temperature adaptation for a cold-adapted family 8 xylanase, the thermal and chemical stabilities, thermal inactivation, thermodependence of activity and conformational flexibility, as well as the thermodynamic basis of these processes, were compared with those of a thermophilic homolog. Differential scanning calorimetry, fluorescence monitoring of guanidine hydrochloride unfolding and fluorescence quenching were used, among other techniques, to show that the cold-adapted enzyme is characterized by a high activity at low temperatures, a poor stability and a high flexibility. In contrast, the thermophilic enzyme is shown to have a reduced low temperature activity, high stability and a reduced flexibility. These findings agree with the hypothesis that cold-adapted enzymes overcome the quandary imposed by low temperature environments via a global or local increase in the flexibility of their molecular edifice, with this in turn leading to a reduced stability. Analysis of the guanidine hydrochloride unfolding, as well as the thermodynamic parameters of irreversible thermal unfolding and thermal inactivation shows that the driving force for this denaturation and inactivation is a large entropy change while a low enthalpy change is implicated in the low temperature activity. A reduced number of salt-bridges are believed to be responsible for both these effects. Guanidine hydrochloride unfolding studies also indicate that both family 8 enzymes unfold via an intermediate prone to aggregation.     

Polymorphism at the α-glycerophosphate dehydrogenase locus in Drosophila melanogaster. I. Properties of adult allozymes

A biochemical comparison was made between alpha-glycerophosphate dehydrogenase allozymes from Drosophila melanogaster. Enzymes extracted from the three major genotypes were indistinguishable in terms of their pH optima and thermal stabilities. Distinctive differences were observed for three parameters; temperature dependence of specific activity, temperature dependence of K-m, and reaction rate constancy over a physiological temperature range. These results are discussed in terms of a model of balancing selection and the existence of spatial and temporal allele frequency clines in natural populations.     

DNA Ligases: Progress and Prospects

DNA ligases seal 5′-PO₄ and 3′-OH polynucleotide ends via three nucleotidyl transfer steps involving ligase-adenylate and DNA-adenylate intermediates. DNA ligases are essential guardians of genomic integrity, and ligase dysfunction underlies human genetic disease syndromes. Crystal structures of DNA ligases bound to nucleotide and nucleic acid substrates have illuminated how ligase reaction chemistry is catalyzed, how ligases recognize damaged DNA ends, and how protein domain movements and active-site remodeling are used to choreograph the end-joining pathway. Although a shared feature of DNA ligases is their envelopment of the nicked duplex as a C-shaped protein clamp, they accomplish this feat by using remarkably different accessory structural modules and domain topologies. As structural, biochemical, and phylogenetic insights coalesce, we can expect advances on several fronts, including (i) pharmacological targeting of ligases for antibacterial and anticancer therapies and (ii) the discovery and design of new strand-sealing enzymes with unique substrate specificities.     

Structural and mechanistic conservation in DNA ligases

DNA ligases are enzymes required for the repair, replication and recombination of DNA. DNA ligases catalyse the formation of phosphodiester bonds at single-strand breaks in double-stranded DNA. Despite their occurrence in all organisms, DNA ligases show a wide diversity of amino acid sequences, molecular sizes and properties. The enzymes fall into two groups based on their cofactor specificity, those requiring NAD⁺ for activity and those requiring ATP. The eukaryotic, viral and archael bacteria encoded enzymes all require ATP. NAD⁺-requiring DNA ligases have only been found in prokaryotic organisms. Recently, the crystal structures of a number of DNA ligases have been reported. It is the purpose of this review to summarise the current knowledge of the structure and catalytic mechanism of DNA ligases.     

Wheat leaf RNA polymerases. II. Kinetic characterization and template specificities of nuclear, chloroplast, and soluble enzymes

Further comparisons were made of DNA-dependent RNA polymerase (nucleotide triphosphate: RNA nucleotidyl transferase, EC 2.7.7.6) activities, partially purified from purified nuclear fragments and chloroplasts and from the soluble phase of young wheat leaves. All three preparations had the same cation specificities for maximal RNA polymerase activity (Mg²⁺ > Mn²⁺ > Ca²⁺) and showed an absolute dependence on an added divalent cation. All three preparations showed the same thermal stabilities and pH optima, very similar pH-activity profiles, and the same type of kinetics with ATP as substrate. Enzyme activities showed negative cooperativity with respect to ATP concentration; the high and low K_m values for ATP were not significantly different for the three preparations.     

DNA and RNA ligases: structural variations and shared mechanisms

DNA and RNA ligases join 3' OH and 5' PO4 ends in polynucleotide substrates using a three-step reaction mechanism that involves covalent modification of both the ligase enzyme and the polynucleotide substrate with AMP. In the past three years, several polynucleotide ligases have been crystallized in complex with nucleic acid, providing the introductory views of ligase enzymes engaging their substrates. Crystal structures for two ATP-dependent DNA ligases, an NAD+-dependent DNA ligase, and an ATP-dependent RNA ligase demonstrate how ligases utilize the AMP group and their multi-domain architectures to manipulate nucleic acid structure and catalyze the end-joining reaction. Together with unliganded crystal structures of DNA and RNA ligases, a more comprehensive and dynamic understanding of the multi-step ligation reaction mechanism has emerged.     

Cofactor binding modulates the conformational stabilities and unfolding patterns of NAD(+)-dependent DNA ligases from Escherichia coli and Thermus scotoductus

DNA ligases are important enzymes required for cellular processes such as DNA replication, recombination, and repair. NAD(+)-dependent DNA ligases are essentially restricted to eubacteria, thus constituting an attractive target in the development of novel antibiotics. Although such a project might involve the systematic testing of a vast number of chemical compounds, it can essentially gain from the preliminary deciphering of the conformational stability and structural perturbations associated with the formation of the catalytically active adenylated enzyme. We have, therefore, investigated the adenylation-induced conformational changes in the mesophilic Escherichia coli and thermophilic Thermus scotoductus NAD(+)-DNA ligases, and the resistance of these enzymes to thermal and chemical (guanidine hydrochloride) denaturation. Our results clearly demonstrate that anchoring of the cofactor induces a conformational rearrangement within the active site of both mesophilic and thermophilic enzymes accompanied by their partial compaction. Furthermore, the adenylation of enzymes increases their resistance to thermal and chemical denaturation, establishing a thermodynamic link between cofactor binding and conformational stability enhancement. Finally, guanidine hydrochloride-induced unfolding of NAD(+)-dependent DNA ligases is shown to be a complex process that involves accumulation of at least two equilibrium intermediates, the molten globule and its precursor.     

A comparison of DNA and RNA quadruplex structures and stabilities

Guanosine-rich sequences are prone to fold into four-stranded nucleic acid structures. Such quadruplex sequences have long been suspected to play important roles in regulatory processes within cells. Although DNA quadruplexes have been studied in great detail, four-stranded structures made up from RNA have received only minor attention, although it is known that RNA is able to form stable quadruplexes as well.Here, we compare quadruplex structures and stabilities of a variety of DNA and RNA sequences. We focus on well established DNA sequences and determine the topologies and stabilities of the corresponding RNA sequences by CD spectroscopy and CD thermal melting experiments. We find that the RNA sequences exclusively fold into the all-parallel conformation in contrast to the diverse topologies adopted by DNA quadruplexes. The thermal stabilities of the RNA structures rival those of the corresponding DNA sequences, often displaying enhanced stabilities compared to their DNA counterparts. Especially thermodynamically less stable sequences show a strong preference for potassium, with the RNA quadruplexes exhibiting much higher stabilities than the corresponding DNAs. The latter finding suggests that quadruplexes formed at critical positions in mRNAs might perturb gene expression to a larger extend than previously anticipated.     

Mammalian DNA ligases

DNA joining enzymes play an essential role in the maintenance of genomic integrity and stability. Three mammalian genes encoding DNA ligases, LIG1, LIG3 and LIG4, have been identified. Since DNA ligase II appears to be derived from DNA ligase III by a proteolytic mechanism, the three LIG genes can account for the four biochemically distinct DNA ligase activities, DNA ligases I, II, III and IV, that have been purified from mammalian cell extracts. It is probable that the specific cellular roles of these enzymes are determined by the proteins with which they interact. The specific involvement of DNA ligase I in DNA replication is mediated by the non-catalytic amino-terminal domain of this enzyme. Furthermore, DNA ligase I participates in DNA base excision repair as a component of a multiprotein complex. Two forms of DNA ligase III are produced by an alternative splicing mechanism. The ubiqitously expressed DNA ligase III-α forms a complex with the DNA single-strand break repair protein XRCC1. In contrast, DNA ligase III-β, which does not interact with XRCC1, is only expressed in male meiotic germ cells, suggesting a role for this isoform in meiotic recombination. At present, there is very little information about the cellular functions of DNA ligase IV.     

Structure-activity relationships among DNA ligase inhibitors: Characterization of a selective uncompetitive DNA ligase I inhibitor

In human cells, there are three genes that encode DNA ligase polypeptides with distinct but overlapping functions. Previously small molecule inhibitors of human DNA ligases were identified using a structure-based approach. Three of these inhibitors, L82, a DNA ligase I (LigI)-selective inhibitor, and L67, an inhibitor of LigI and DNA ligases III (LigIII), and L189, an inhibitor of all three human DNA ligases, have related structures that are composed of two 6-member aromatic rings separated by different linkers. Here we have performed a structure-activity analysis to identify determinants of activity and selectivity. The majority of the LigI-selective inhibitors had a pyridazine ring whereas the LigI/III- and LigIII-selective inhibitors did not. In addition, the aromatic rings in LigI-selective inhibitors had either arylhydrazone or acylhydrazone, but not vinyl linkers. Among the LigI-selective inhibitors, L82-G17 exhibited increased activity against and selectivity for LigI compared with L82. Notably. L82-G17 is an uncompetitive inhibitor of the third step of the ligation reaction, phosphodiester bond formation. Cells expressing LigI were more sensitive to L82-G17 than isogenic LIG1 null cells. Furthermore, cells lacking nuclear LigIIIα, which can substitute for LigI in DNA replication, were also more sensitive to L82-G17 than isogenic parental cells. Together, our results demonstrate that L82-G17 is a LigI-selective inhibitor with utility as a probe of the catalytic activity and cellular functions of LigI and provide a framework for the future design of DNA ligase inhibitors.     

Structural Features of a Cold-adapted Alaskan Bacterial Lipase

Abstract

The three dimensional model of cold-adapted Alaskan psychrotroph Pseudomonas species (Strain B11-1) lipase has been constructed by homology modeling based on the crystal structure of acetyl esterase from Rhodococcus species and refined by molecular dynamics methods. Our model locates the substrate-binding cavity and further suggests that Ser-155, Asp-250, and His-280 are the members of the catalytic triad. Substrate specificity of the modeled lipase has been examined by docking experiments, which indicates that the ester of C₆ fatty acid has the highest affinity for the enzyme. Our model also identifies the oxyanion hole that plays an important role in the stabilization of the tetrahedral intermediate during catalysis. Comparison of this cold-adapted lipase with the crystal structure of a thermophilic Bacillus stearothermophilus P1 lipase supported the assumption that cold-adapted enzymes have a more flexible three-dimensional structure than their thermophilic counterparts. The conformational flexibility of this modeled cold-adapted lipase at low temperature probably originates from a combination of factors compared to its thermophilic counterpart, i.e., lower number of salt bridges and cation-π interactions, increase in the non-polar surface area exposed to solvent. Our study may help in understanding the structural features of a cold- adapted lipase and can further be used in engineering lipase that can function at or near extreme temperatures with considerable biotechnological potential.     

Synthesis and Hybridization Properties of Oligonucleotides Containing (2 S ,3 R )-9-(2,3,4-Trihydroxybutyl)Adenine

The synthesis and properties of oligonucleotides (ONs) containing 9-(2,3,4-trihydroxybutyl)adenine, A ^C2 and A ^C3, are described. The ON containing A ^C2 involves the 3′ → 4′ and 3′ → 5′ phosphodiester linkages in the strand, whereas that containing A ^C3 possesses the 3′ → 4′ and 2′ → 5′ phosphodiester linkages. It was found that incorporation of the analogs, A ^C2 or A ^C3, into ONs significantly reduces the thermal and thermodynamic stabilities of the ON/DNA duplexes, but does not largely decrease the thermal and thermodynamic stabilities of the ON/RNA duplexes as compared with the case of the ON/DNA duplexes. It was revealed that the base recognition ability of A ^C2 is greater than that of A ^C3 in the ON/RNA duplexes.     

Identification of essential residues in Thermus thermophilus DNA ligase.

DNA ligases play a pivotal role in DNA replication, repair and recombination. Reactions catalyzed by DNA ligases consist of three steps: adenylation of the ligase in the presence of ATP or NAD+, transferring the adenylate moiety to the 5'-phosphate of the nicked DNA substrate (deadenylation) and sealing the nick through the formation of a phosphodiester bond. Thermus thermophilus HB8 DNA ligase (Tth DNA ligase) differs from mesophilic ATP-dependent DNA ligases in three ways: (i) it is NAD+ dependent; (ii) its optimal temperature is 65 instead of 37 degrees C; (iii) it has higher fidelity than T4 DNA ligase. In order to understand the structural basis underlying the reaction mechanism of Tth DNA ligase, we performed site-directed mutagenesis studies on nine selected amino acid residues that are highly conserved in bacterial DNA ligases. Examination of these site-specific mutants revealed that: residue K118 plays an essential role in the adenylation step; residue D120 may facilitate the deadenylation step; residues G339 and C433 may be involved in formation of the phosphodiester bond. This evidence indicates that a previously identified KXDG motif for adenylation of eukaryotic DNA ligases [Tomkinson, A.E., Totty, N.F., Ginsburg, M. and Lindahl, T. (1991) Proc. Natl. Acad. Sci. USA, 88, 400-404] is also the adenylation site for NAD+-dependent bacterial DNA ligases. In a companion paper, we demonstrate that mutations at a different Lys residue, K294, may modulate the fidelity of Tth DNA ligase.     

Evolutionary changes of nonlinear reaction norms according to thermal adaptation: a comparison of two Drosophila species

While the adaptive significance of discontinuous reaction norms is generally accepted, the evolutionary interpretation of continuous response curves remains speculative, and the occurrence of internal constraints is often suggested as an explanation of experimental observations. In Drosophila melanogaster, various morphometrical traits exhibit convex reaction norms to growth temperature, with a maximum value within the developmental thermal range. We compared a cold-adapted species (D. subobscura) with a mid thermal range at 16 °C, to the warm-adapted D. melanogaster (mid thermal range at 22 °C) for three different morphometrical traits: wing and thorax length in both sexes and ovariole number in females. Maximum value temperatures were ordered in the same way for the three traits in both species: ovariole number > thorax length > wing length. Significant differences were also observed between the two species for the curvature parameter of the quadratic adjustment. The major observation was a significant lateral shift in the reaction norms: maximum values were observed at much lower temperatures in the cold-adapted species than in the warm-adapted one. The parallelism between mid thermal range variation and the position of the maximum value strongly suggests an adaptive displacement of the response curves. Natural selection may thus act not only on trait mean values but also on phenotypic plasticity and on the shape of reaction norms.     

Novel DNA ligase with broad nucleotide cofactor specificity from the hyperthermophilic crenarchaeon Sulfophobococcus zilligii: influence of ancestral DNA ligase on cofactor utilization

DNA ligases are divided into two groups according to their cofactor requirement to form ligase-adenylate, ATP-dependent DNA ligases and NAD(+)-dependent DNA ligases. The conventional view that archaeal DNA ligases only utilize ATP has recently been disputed with discoveries of dual-specificity DNA ligases (ATP/ADP or ATP/NAD(+)) from the orders Desulfurococcales and Thermococcales. Here, we studied DNA ligase encoded by the hyperthermophilic crenarchaeon Sulfophobococcus zilligii. The ligase exhibited multiple cofactor specificity utilizing ADP and GTP in addition to ATP. The unusual cofactor specificity was confirmed via a DNA ligase nick-closing activity assay using a fluorescein/biotin-labelled oligonucleotide and a radiolabelled oligonucleotide. The exploitation of GTP as a catalytic energy source has not to date been reported in any known DNA ligase. This phenomenon may provide evolutionary evidence of the nucleotide cofactor utilization by DNA ligases. To bolster this hypothesis, we summarize and evaluate previous assertions. We contend that DNA ligase evolution likely started from crenarchaeotal DNA ligases and diverged to eukaryal DNA ligases and euryarchaeotal DNA ligases. Subsequently, the NAD(+)-utilizing property of some euryarchaeotal DNA ligases may have successfully differentiated to bacterial NAD(+)-dependent DNA ligases.     

Mismatch discrimination and sequence bias during end-joining by DNA ligases

DNA ligases, critical enzymes for in vivo genome maintenance and modern molecular biology, catalyze the joining of adjacent 3′-OH and 5′-phosphorylated ends in DNA. To determine whether DNA annealing equilibria or properties intrinsic to the DNA ligase enzyme impact end-joining ligation outcomes, we used a highly multiplexed, sequencing-based assay to profile mismatch discrimination and sequence bias for several ligases capable of efficient end-joining. Our data reveal a spectrum of fidelity and bias, influenced by both the strength of overhang annealing as well as sequence preferences and mismatch tolerances that vary both in degree and kind between ligases. For example, while T7 DNA ligase shows a strong preference for ligating high GC sequences, other ligases show little GC-dependent bias, with human DNA Ligase 3 showing almost none. Similarly, mismatch tolerance varies widely among ligases, and while all ligases tested were most permissive of G:T mismatches, some ligases also tolerated bulkier purine:purine mismatches. These comprehensive fidelity and bias profiles provide insight into the biology of end-joining reactions and highlight the importance of ligase choice in application design.     

Biochemical characterisation of LigN, an NAD+-dependent DNA ligase from the halophilic euryarchaeon Haloferax volcanii that displays maximal in vitro activity at high salt concentrations

Background  

DNA ligases are required for DNA strand joining in all forms of cellular life. NAD⁺-dependent DNA ligases are found primarily in eubacteria but also in some eukaryotic viruses, bacteriophage and archaea. Among the archaeal NAD⁺-dependent DNA ligases is the LigN enzyme of the halophilic euryarchaeon Haloferax volcanii, the gene for which was apparently acquired by Hfx.volcanii through lateral gene transfer (LGT) from a halophilic eubacterium. Genetic studies show that the LGT-acquired LigN enzyme shares an essential function with the native Hfx.volcanii ATP-dependent DNA ligase protein LigA.     

Glycolaldehyde Dehydrogenase,Its Involvement in Vitamin B6 Biosynthetic Pathway of Escherichia coli B

The deoxyribonucleic acid (DNA) polymerases were partially purified from spores and vegetative cells of Bacillus subtilis. Some biochemical properties of the enzymes from the spores were studied in comparison with those from the vegetative cells. The spores and vegetative cells had at least three species of DNA polymerases (DNA polymerase I, II and III). These DNA polymerases in spores could not be distinguished from those in vegetative cells, respectively, with regard to the reresponses to ionic strength, the sensitivity to thiol-blocking agents, the template specificity, pH and temperature optima in assay, and the sedimentation behavior. It is inferred that DNA polymerases from spores was essentially identical to those from vegetative cells.

The DNA polymerase activity decreased rapidly in the course of sporulation, and only about 20% is recovered in the spores, suggesting that an extentive inactivation mechanism of the enzymes would be involved during sporulation.