Amino acid residues in the GIY-YIG endonuclease II of phage T4 affecting sequence recognition and binding as well as catalysis

Phage T4 endonuclease II (EndoII), a GIY-YIG endonuclease lacking a carboxy-terminal DNA-binding domain, was subjected to site-directed mutagenesis to investigate roles of individual amino acids in substrate recognition, binding, and catalysis. The structure of EndoII was modeled on that of UvrC. We found catalytic roles for residues in the putative catalytic surface (G49, R57, E118, and N130) similar to those described for I-TevI and UvrC; in addition, these residues were found to be important for substrate recognition and binding. The conserved glycine (G49) and arginine (R57) were essential for normal sequence recognition. Our results are in agreement with a role for these residues in forming the DNA-binding surface and exposing the substrate scissile bond at the active site. The conserved asparagine (N130) and an adjacent proline (P127) likely contribute to positioning the catalytic domain correctly. Enzymes in the EndoII subfamily of GIY-YIG endonucleases share a strongly conserved middle region (MR, residues 72 to 93, likely helical and possibly substituting for heterologous helices in I-TevI and UvrC) and a less strongly conserved N-terminal region (residues 12 to 24). Most of the conserved residues in these two regions appeared to contribute to binding strength without affecting the mode of substrate binding at the catalytic surface. EndoII K76, part of a conserved NUMOD3 DNA-binding motif of homing endonucleases found to overlap the MR, affected both sequence recognition and catalysis, suggesting a more direct involvement in positioning the substrate. Our data thus suggest roles for the MR and residues conserved in GIY-YIG enzymes in recognizing and binding the substrate.     

Characterization of uracil-DNA glycosylase activity from Trypanosoma cruzi and its stimulation by AP endonuclease

The intracellular pathogen Trypanosoma cruzi is the etiological agent of Chagas' disease. We have isolated a full-length cDNA encoding uracil-DNA glycosylase (UDGase), a key enzyme involved in DNA repair, from this organism. The deduced protein sequence is highly conserved at the C-terminus of the molecule and shares key residues involved in binding or catalysis with most of the UDGases described so far, while the N-terminal part is highly variable. The gene is single copy and is located on a chromosome of approximately 1.9 Mb. A His-tagged recombinant protein was overexpressed, purified and used to raise polyclonal antibodies. Western blot analysis revealed the existence of a single UDGase species in parasite extracts. Using a specific ethidium bromide fluorescence assay, recombinant T.cruzi UDGase was shown to specifically excise uracil from DNA. The addition of both Leishmania major AP endonuclease and exonuclease III, the major AP endonuclease from Escherichia coli, produces stimulation of UDGase activity. This activation is specific for AP endonuclease and suggests functional communication between the two enzymes.     

The structure and function of catalytic domains within inositol polyphosphate 5-phosphatases

Phosphoinositide signaling pathways regulate many essential cellular functions including proliferation, differentiation and survival, cytoskeletal organization, and vesicular trafficking. The inositol polyphosphate 5-phosphatases regulate the cellular levels of several bioactive phosphoinositide species. This review describes the structure and function of the 5-phosphatase and Sac1 catalytic domains of these enzymes. The crystal structure of the 5-phosphatase domain has been solved and shares homology with members of the AP endonuclease family. The phosphoinositide polyphosphatase activity of the Sac1 domain, found in some inositol polyphosphate 5-phosphatases, is defined by a motif, CX5 R(T/S), also found in both protein and lipid phosphatases.     

Isolation of cDNA clones encoding a human apurinic/apyrimidinic endonuclease that corrects DNA repair and mutagenesis defects in E. coli xth (exonuclease III) mutants.

Apurinic/apyrimidinic (AP) sites in cellular DNA are considered to be both cytotoxic and mutagenic, and can arise spontaneously or following exposure to DNA damaging agents. We have isolated cDNA clones which encode an endonuclease, designated HAP1 (human AP endonuclease 1), that catalyses the initial step in AP site repair in human cells. The predicted HAP1 protein has an Mr of 35,500 and shows striking sequence similarity (93% identity) to BAP 1, a bovine AP endonuclease enzyme. Significant sequence homology to two bacterial DNA repair enzymes, E. coli exonuclease III and S. pneumoniae ExoA proteins, and to Drosophila Rrp1 protein is also apparent. We have expressed the HAP1 cDNA in E. coli mutants lacking exonuclease III (xth), endonuclease IV (nfo), or both AP endonucleases. The HAP1 protein can substitute for exonuclease III, but not for endonuclease IV, in respect of some, but not all, DNA repair and mutagenesis functions. Moreover, a dut xth (ts) double mutant, which is nonviable at 42 degrees C due to an accumulation of unrepaired AP sites following excision of uracil from DNA, was rescued by expression of the HAP1 cDNA. These results indicate that AP endonucleases show remarkable conservation of both primary sequence and function. We would predict that the HAP1 protein is important in human cells for protection against the toxic and mutagenic effects of DNA damaging agents.     

Mechanistic similarity and diversity among the guanidine-modifying members of the pentein superfamily

The pentein superfamily is a mechanistically diverse superfamily encompassing both noncatalytic proteins and enzymes that catalyze hydrolase, dihydrolase and amidinotransfer reactions on guanidine substrates. Despite generally low sequence identity, they possess a conserved structural fold and display common mechanistic themes in catalysis. The structurally characterized catalytic penteins possess a conserved core of residues that include a Cys, His and two polar, guanidine-binding residues. All known catalytic penteins use the core Cys to attack the substrate's guanidine moiety to form a covalent thiouronium adduct and all cleave one or more of the guanidine C―N bonds. The mechanistic information compiled to date supports the hypothesis that this superfamily may have evolved divergently from a catalytically promiscuous ancestor.     

Conserved Structural Chemistry for Incision Activity in Structurally Non-homologous Apurinic/Apyrimidinic Endonuclease APE1 and Endonuclease IV DNA Repair Enzymes

Non-coding apurinic/apyrimidinic (AP) sites in DNA form spontaneously and as DNA base excision repair intermediates are the most common toxic and mutagenic in vivo DNA lesion. For repair, AP sites must be processed by 5′ AP endonucleases in initial stages of base repair. Human APE1 and bacterial Nfo represent the two conserved 5′ AP endonuclease families in the biosphere; they both recognize AP sites and incise the phosphodiester backbone 5′ to the lesion, yet they lack similar structures and metal ion requirements. Here, we determined and analyzed crystal structures of a 2.4 Å resolution APE1-DNA product complex with Mg²⁺ and a 0.92 Å Nfo with three metal ions. Structural and biochemical comparisons of these two evolutionarily distinct enzymes characterize key APE1 catalytic residues that are potentially functionally similar to Nfo active site components, as further tested and supported by computational analyses. We observe a magnesium-water cluster in the APE1 active site, with only Glu-96 forming the direct protein coordination to the Mg²⁺. Despite differences in structure and metal requirements of APE1 and Nfo, comparison of their active site structures surprisingly reveals strong geometric conservation of the catalytic reaction, with APE1 catalytic side chains positioned analogously to Nfo metal positions, suggesting surprising functional equivalence between Nfo metal ions and APE1 residues. The finding that APE1 residues are positioned to substitute for Nfo metal ions is supported by the impact of mutations on activity. Collectively, the results illuminate the activities of residues, metal ions, and active site features for abasic site endonucleases.     

Role of the tryptophan residue in the vicinity of the catalytic center of exonuclease III family AP endonucleases: AP site recognition mechanism

The mechanisms by which AP endonucleases recognize AP sites have not yet been determined. Based on our previous study with Escherichia coli exonuclease III (ExoIII), the ExoIII family AP endonucleases probably recognize the DNA-pocket formed at an AP site. The indole ring of a conserved tryptophan residue in the vicinity of the catalytic site presumably intercalates into this pocket. To test this hypothesis, we constructed a series of mutants of ExoIII and human APE1. Trp-212 of ExoIII and Trp-280 of APE1 were critical to the AP endonuclease activity and binding to DNA containing an AP site. To confirm the ability of the tryptophan residue to intercalate with the AP site, we examined the interaction between an oligopeptide containing a tryptophan residue and an oligonucleotide containing AP sites, using spectrofluorimetry and surface plasmon resonance (SPR) technology. The tryptophan residue of the oligopeptide specifically intercalated into an AP site of DNA. The tryptophan residue in the vicinity of the catalytic site of the ExoIII family AP endonucleases plays a key role in the recognition of AP sites.     

A conserved 3'----5' exonuclease active site in prokaryotic and eukaryotic DNA polymerases

The 3'----5' exonuclease active site of E. coli DNA polymerase I is predicted to be conserved for both prokaryotic and eukaryotic DNA polymerases based on amino acid sequence homology. Three amino acid regions containing the critical residues in the E. coli DNA polymerase I involved in metal binding, single-stranded DNA binding, and catalysis of the exonuclease reaction are located in the amino-terminal half and in the same linear arrangement in several prokaryotic and eukaryotic DNA polymerases. Site-directed mutagenesis at the predicted exonuclease active site of the phi 29 DNA polymerase, a model enzyme for prokaryotic and eukaryotic alpha-like DNA polymerases, specifically inactivated the 3'----5' exonuclease activity of the enzyme. These results reflect a high evolutionary conservation of this catalytic domain. Based on structural and functional data, a modular organization of enzymatic activities in prokaryotic and eukaryotic DNA polymerases is also proposed.     

Primer-terminus stabilization at the 3'-5' exonuclease active site of phi29 DNA polymerase. Involvement of two amino acid residues highly conserved in proofreading DNA polymerases.

By site-directed mutagenesis in phi29 DNA polymerase, we have analyzed the functional importance of two evolutionarily conserved residues belonging to the 3'-5' exonuclease domain of DNA-dependent DNA polymerases. In Escherichia coli DNA polymerase I, these residues are Thr358 and Asn420, shown by crystallographic analysis to be directly acting as single-stranded DNA (ssDNA) ligands at the 3'-5' exonuclease active site. On the basis of these structural data, single substitution of the corresponding residues of phi29 DNA polymerase, Thr15 and Asn62, produced enzymes with a very reduced or altered capacity to bind ssDNA. Analysis of the residual 3'-5' exonuclease activity of these mutant derivatives on ssDNA substrates allowed us to conclude that these two residues do not play a direct role in the catalysis of the reaction. On the other hand, analysis of the 3'-5' exonuclease activity on either matched or mismatched primer/template structures showed a critical role of these two highly conserved residues in exonucleolysis under polymerization conditions, i.e. in the proofreading of DNA polymerization errors, an evolutionary advantage of most DNA-dependent DNA polymerases. Moreover, in contrast to the dual role in 3'-5' exonucleolysis and strand displacement previously observed for phi29 DNA polymerase residues acting as metal ligands, the contribution of residues Thr15 and Asn62 appears to be restricted to the proofreading function, by stabilization of the frayed primer-terminus at the 3'-5' exonuclease active site.     

Analysis of class II (hydrolytic) and class I (beta-lyase) apurinic/apyrimidinic endonucleases with a synthetic DNA substrate.

We have developed simple and sensitive assays that distinguish the main classes of apurinic/apyrimidinic (AP) endonucleases: Class I enzymes that cleave on the 3' side of AP sites by beta-elimination, and Class II enzymes that cleave by hydrolysis on the 5' side. The distinction of the two types depends on the use of a synthetic DNA polymer that contains AP sites with 5'-[32P]phosphate residues. Using this approach, we now show directly that Escherichia coli endonuclease IV and human AP endonuclease are Class II enzymes, as inferred previously on the basis of indirect assays. The assay method does not exhibit significant interference by nonspecific nucleases or primary amines, which allows the ready determination of different AP endonuclease activities in crude cell extracts. In this way, we show that virtually all of the Class II AP endonuclease activity in E. coli can be accounted for by two enzymes: exonuclease III and endonuclease IV. In the yeast Saccharomyces cerevisiae, the Class II AP endonuclease activity is totally dependent on a single enzyme, the Apn1 protein, but there are probably multiple Class I enzymes. The versatility and ease of our approach should be useful for characterizing this important class of DNA repair enzymes in diverse systems.     

The elastic network model reveals a consistent picture on intrinsic functional dynamics of type II restriction endonucleases

The vibrational dynamics of various type II restriction endonucleases, in complex with cognate/non-cognate DNA and in the apo form, are investigated with the elastic network model in order to reveal common functional mechanisms in this enzyme family. Scissor-like and tong-like motions observed in the slowest modes of all enzymes and their complexes point to common DNA recognition and cleavage mechanisms. Normal mode analysis further points out that the scissor-like motion has an important role in differentiating between cognate and non-cognate sequences at the recognition site, thus implying its catalytic relevance. Flexible regions observed around the DNA-binding site of the enzyme usually concentrate on the highly conserved β-strands, especially after DNA binding. These β-strands may have a structurally stabilizing role in functional dynamics for target site recognition and cleavage. In addition, hot spot residues based on high-frequency modes reveal possible communication pathways between the two distant cleavage sites in the enzyme family. Some of these hot spots also exist on the shortest path between the catalytic sites and are highly conserved.     

AP lyases and dRPases: commonality of mechanism

Enzymes that release 5'-deoxyribose-5-phosphate (dRP) residues from preincised apurinic/apyrimidinic (AP) DNA have been collectively termed DNA deoxyribophosphodiesterases (dRPases), but they fall into two distinct categories: the hydrolytic dRPases and AP lyases. In order to resolve a number of conflicting reports in the dRPase literature, we examined two putative hydrolytic dRPases (Escherichia coli exonuclease I (exo I) and RecJ) and four AP lyases (E. coli 2, 6-dihydroxy-5N-formamidopyrimidine (Fapy) DNA glycosylase (Fpg) and endonuclease III (endo III), bacteriophage T4 endonuclease V (endo V), and rat polymerase beta (beta-pol)) for their abilities to (i) excise dRP from preincised AP DNA and (ii) incise AP DNA. Although exo I and RecJ exhibited robust 3' to 5' and 5' to 3' exonucleolytic activities, respectively, on appropriate substrates, they failed to demonstrate detectable dRPase activity. All four AP lyases possessed both dRPase and traditional AP lyase activities, albeit to varying degrees. Moreover, as best illustrated with Fpg, AP lyase enzymes could be trapped on both preincised and unincised AP DNA using NaBH(4) as the reducing agent. These results further support the assertion that the catalytic mechanism of the AP lyases, the beta-elimination reaction, does proceed through an imine enzyme-DNA intermediate and that the active site residues responsible for dRP release must contain primary amines. Further, these data indicate a biological significance for the beta-elimination reaction of DNA glycosylase/AP lyases in that they, in concert with hydrolytic AP endonucleases, can create appropriate gapped substrates for short patch base excision repair (BER) synthesis to occur efficiently.     

Abasic site recognition mechanism by the Escherichia coli exonuclease III.

In order to elucidate the mechanism of AP site recognition by Echerichia coli exonuclease III (exoIII), site-directed mutagenesis of the Tyr109, the Trp212, and the Phe213 residues, which were conserved in the type II AP endonuclease from various organisms and located in the vicinity of the catalytic site, was performed. The exoIII-W212S mutant lacked any detectable AP endonuclease activity and binding ability to the duplex DNA containing an AP site, while the exoIII-Y109S and exoIII-F213W mutants retained a low level of activities (13% and 83%, respectively, compared with wild-type exoIII). This study suggests that the Trp212 is an important component for abasic site recognition by the E. coli exonuclease III.     

Peptidase family U34 belongs to the superfamily of N-terminal nucleophile hydrolases

Peptidase family U34 consists of enzymes with unclear catalytic mechanism, for instance, dipeptidase A from Lactobacillus helveticus. Using extensive sequence similarity searches, we infer that U34 family members are homologous to penicillin V acylases (PVA) and thus potentially adopt the N-terminal nucleophile (Ntn) hydrolase fold. Comparative sequence and structural analysis reveals a cysteine as the catalytic nucleophile as well as other conserved residues important for catalysis. The PVA/U34 family is variable in sequence and exhibits great diversity in substrate specificity, to include enzymes such as choloyglycine hydrolases, acid ceramidases, isopenicillin N acyltransferases, and a subgroup of eukaryotic proteins with unclear function.     

Iterative database searches demonstrate that glycoside hydrolase families 27, 31, 36 and 66 share a common evolutionary origin with family 13

A catalytic sequence motif PDX10-30(E/D)XK is found in many restriction enzymes. On the basis of sequence similarities and mapping of the conserved residues to the crystal structure of NgoMIV we suggest that residues D160, K182, R186, R188 and E195 contribute to the catalytic/DNA binding site of the Ecl18kI restriction endonuclease. Mutational analysis confirms the functional significance of the conserved residues of Ecl18kI. Therefore, we conclude that the active site motif 159VDX21KX12E of Ecl18kI differs from the canonical PDX10-30(E/D)XK motif characteristic for most of the restriction enzymes. Moreover, we propose that two subfamilies of endonucleases Ecl18kI/PspGI/EcoRII and Cfr10I/Bse634I/NgoMIV, specific, respectively, for CCNGG/CCWGG and RCCGGY/GCCGGC sites, share conserved active site architecture and DNA binding elements.     

Site-directed mutagenesis at the Exo III motif of phi 29 DNA polymerase; overlapping structural domains for the 3''-5'' exonuclease and strand-displacement activities.

In this report we present the alignment of one of the most conserved segments (Exo III) of the 3'-5' exonuclease domain in 39 DNA polymerase sequences, including prokaryotic and eukaryotic enzymes. Site-directed substitutions of the two most conserved residues, which form the Exo III motif Tyr-(X)3-Asp of phi 29 DNA polymerase, did not affect single-stranded DNA binding, DNA polymerization, processivity or protein-primed initiation. In contrast, substitution of the highly conserved Tyr residue by Phe or Cys decreased the 3'-5' exonuclease activity to 7.5 and 4.1%, respectively, of the wild-type activity. Change of the highly conserved Asp residue into Ala resulted in almost complete inactivation (0.1%) of the 3'-5' exonuclease. In accordance with the contribution of the 3'-5' exonuclease to the fidelity of DNA replication, the three mutations in the Exo III motif (Y165F, Y165C and D169A) produced enzymes with an increased frequency of misinsertion and extension of DNA polymerization errors. Surprisingly, the three mutations in the Exo III motif strongly decreased (80- to 220-fold) the ability to replicate phi 29 DNA, this behaviour being due to a defect in the strand displacement activity, an intrinsic property of phi 29 DNA polymerase required for this process. Taking these results into account, we propose that the strand displacement activity of phi 29 DNA polymerase resides in the N-terminal domain, probably overlapping with the 3'-5' exonuclease active site.     

Identification of a novel phosphatase sequence motif.

We have identified a novel, conserved phosphatase sequence motif, KXXXXXXRP-(X12-54)-PSGH-(X31-54)-SRXXXXX HXXXD, that is shared among several lipid phosphatases, the mammalian glucose-6-phosphatases, and a collection of bacterial nonspecific acid phosphatases. This sequence was also found in the vanadium-containing chloroperoxidase of Curvularia inaequalis. Several lines of evidence support this phosphatase motif identification. Crystal structure data on chloroperoxidase revealed that all three domains are in close proximity and several of the conserved residues are involved in the binding of the cofactor, vanadate, a compound structurally similar to phosphate. Structure-function analysis of the human glucose-6-phosphatase has shown that two of the conserved residues (the first domain arginine and the central domain histidine) are essential for enzyme activity. This conserved sequence motif was used to identify nine additional putative phosphatases from sequence databases, one of which has been determined to be a lipid phosphatase in yeast.     

Site-directed mutagenesis of the human DNA repair enzyme HAP1: identification of residues important for AP endonuclease and RNase H activity.

HAP1 protein, the major apurinic/apyrimidinic (AP) endonuclease in human cells, is a member of a homologous family of multifunctional DNA repair enzymes including the Escherichia coli exonuclease III and Drosophila Rrp1 proteins. The most extensively characterised member of this family, exonuclease III, exhibits both DNA- and RNA-specific nuclease activities. Here, we show that the RNase H activity characteristic of exonuclease III has been conserved in the human homologue, although the products resulting from RNA cleavage are dissimilar. To identify residues important for enzymatic activity, five mutant HAP1 proteins containing single amino acid substitutions were purified and analysed in vitro. The substitutions were made at sites of conserved amino acids and targeted either acidic or histidine residues because of their known participation in the active sites of hydrolytic nucleases. One of the mutant proteins (replacement of Asp-219 by alanine) showed a markedly reduced enzymatic activity, consistent with a greatly diminished capacity to bind DNA and RNA. In contrast, replacement of Asp-90, Asp-308 or Glu-96 by alanine led to a reduction in enzymatic activity without significantly compromising nucleic acid binding. Replacement of His-255 by alanine led to only a very small reduction in enzymatic activity. Our data are consistent with the presence of a single catalytic active site for the DNA- and RNA-specific nuclease activities of the HAP1 protein.     

The alpha/beta hydrolase fold.

We have identified a new protein fold--the alpha/beta hydrolase fold--that is common to several hydrolytic enzymes of widely differing phylogenetic origin and catalytic function. The core of each enzyme is similar: an alpha/beta sheet, not barrel, of eight beta-sheets connected by alpha-helices. These enzymes have diverged from a common ancestor so as to preserve the arrangement of the catalytic residues, not the binding site. They all have a catalytic triad, the elements of which are borne on loops which are the best-conserved structural features in the fold. Only the histidine in the nucleophile-histidine-acid catalytic triad is completely conserved, with the nucleophile and acid loops accommodating more than one type of amino acid. The unique topological and sequence arrangement of the triad residues produces a catalytic triad which is, in a sense, a mirror-image of the serine protease catalytic triad. There are now four groups of enzymes which contain catalytic triads and which are related by convergent evolution towards a stable, useful active site: the eukaryotic serine proteases, the cysteine proteases, subtilisins and the alpha/beta hydrolase fold enzymes.