Involvement of TatD nuclease during programmed cell death in the protozoan parasite Trypanosoma brucei

In this report, we describe the involvement of TatD nuclease during programmed cell death (PCD) in the human protozoan parasite Trypanosoma brucei. T. brucei TatD nuclease showed intrinsic DNase activity, was localized in the cytoplasm and translocated to the nucleus when cells were treated with inducers previously demonstrated to cause PCD in T. brucei. Overexpression of TatD nuclease resulted in elevated PCD and conversely, loss of TatD expression by RNAi conferred significant resistance to the induction of PCD in T. brucei. Co‐immunoprecipitation studies revealed that TatD nuclease interacts with endonucleaseG suggesting that these two nucleases could form a DNA degradation complex in the nucleus. Together, biochemical activity, RNAi and subcellular localization results demonstrate the role of TatD nuclease activity in DNA degradation during PCD in these evolutionarily ancient eukaryotic organisms. Further, in conjunction with endonucleaseG, TatD may represent a critical nuclease in a caspase‐independent PCD pathway in trypanosomatid parasites since caspases have not been identified in these organisms.     

Enzymatic characterization of Catalase from Bacillus anthracis and prediction of critical residues using information theoretic measure of Relative Entropy

In order to cope up with the reactive oxygen species (ROS) generated by host innate immune response, most of the intracellular organisms express Catalase for the enzymatic destruction/detoxification of hydrogen peroxide, to combat its deleterious effects. Catalase thus, scavenges ROS thereby playing a pivotal role in facilitating the survival of the pathogen within the host, and thus contributes to its pathogenesis. Bacillus anthracis harbors five isoforms of Catalase, but none of them has been studied so far. Thus, this study is the first attempt to delineate the biochemical and functional characteristics of one of the isoforms of Catalase (Cat1.4) of B. anthracis, followed by identification of residues critical for catalysis. The general strategy used, so far for mutational analysis in Catalases is structure based, i.e. the residues in the vicinity of heme were mutated to decipher the enzymatic mechanism. However, in the present study, protein sequence analysis was used for the prediction of catalytically important residues of Catalase. Essential measures were adopted to ensure the accuracy of predictions like after retrieval of well-annotated sequences from the database with EC 1.11.1.6, preprocessing was done to remove irrelevant sequences. The method used for multiple alignment of sequences, was guided by structural alignment and thereafter, an information theoretic measure, Relative Entropy was used for the critical residue prediction. By exploiting this strategy, we identified two previously known essential residues, H55 and Y338 in the active site which were demonstrated to be crucial for the activity. We also identified six novel crucial residues (Q332, Y117, H215, W257, N376 and H146) located distantly from the active site. Thus, the present study highlights the significance of this methodology to identify not only those crucial residues which lie in the active site of Catalase, but also the residues located distantly.     

Crystal structure of the Bacillus anthracis nucleoside diphosphate kinase and its characterization reveals an enzyme adapted to perform under stress conditions

Nucleoside diphosphate kinases (Ndks) play an important role in a plethora of regulatory and metabolic functions. Inhibition of the B. anthracis Ndk mRNA results in the formation of nonviable aberrant spores. We report the characterization and crystal structure of the enzyme from B. anthracis nucleoside diphosphate kinase (BaNdk), the first from sporulating bacteria. The enzyme, although from a mesophilic source, is active at extremes of pH (3.5–10.5), temperature (10–95°C) and ionic strength (0.25–4.0M NaCl). It exists as a hexamer that is composed of two SDS‐stable trimers interacting in a back‐to‐back association; mutational analysis confirms that the enzyme is a histidine kinase. The high‐resolution crystal structure reported here reveals an unanticipated change in the conformation of residues between 43 and 63 that also regulates substrate entry in other Ndks. A comparative structural analysis involving Ndks from seven mesophiles and three thermophiles has resulted in the delineation of the structure into relatively rigid and flexible regions. The analysis suggests that the larger number of intramolecular hydrogen bonds and to a lesser extent ionic interactions in BaNdk contributes to its high thermostability. Mutational analysis and Molecular Dynamics simulations were used to probe the role of a highly conserved Gly19 (present at the oligomeric interface in most of the Ndks). The results suggest that the mutation leads to a rigidification of those residues that facilitate substrate entry and consequently leads to a large reduction in the kinase activity. Overall, the enzyme characterization helps to understand its apparent adaptation to perform under stress conditions. Proteins 2009. © 2009 Wiley‐Liss, Inc.     

Characterization of Active-Site Residues of the NIa Protease from Tobacco Vein Mottling Virus

Nuclear inclusion a (NIa) protease of tobacco vein mottling virus is responsible for the processing of the viral polyprotein into functional proteins. In order to identify the active-site residues of the TVMV NIa protease, the putative active-site residues, His-46, Asp-81 and Cys-151, were mutated individually to generate H46R, H46A, D81E, D81N, C151S, and C151A, and their mutational effects on the proteolytic activities were examined. Proteolytic activity was completely abolished by the mutations of H46R, H46A, D81N, and C151A, suggesting that the three residues are crucial for catalysis. The mutation of D81E decreased k_cat marginally by about 4.7-fold and increased K_m by about 8-fold, suggesting that the aspartic acid at position 81 is important for substrate binding but can be substituted by glutamate without any significant decrease in catalysis. The replacement of Cys-151 by Ser to mimic the catalytic triad of chymotrypsin-like serine protease resulted in the drastic decrease in k_cat by about 1,260-fold. This result might be due to the difference of the active-site geometry between the NIa protease and chymotrypsin. The protease exhibited a bell-shaped pH-dependent profile with a maximum activity approximately at pH 8.3 and with the abrupt changes at the respective pK_m values of approximately 6.6 and 9.2, implying the involvement of a histidine residue in catalysis. Taken together, these results demonstrate that the three residues, His-46, Asp-81, and Cys-151, play a crucial role in catalysis of the TVMV NIa protease.     

Identification of functionally relevant histidine residues in the apoptotic nuclease CAD

The caspase-activated DNase CAD (DFF40/CPAN) degrades chromosomal DNA during apoptosis. Chemical modification with DEPC inactivates the enzyme, suggesting that histidine residues play a decisive role in the catalytic mechanism of this nuclease. Sequence alignment of murine CAD with four homologous apoptotic nucleases reveals four completely (His242, His263, His304 and His308) and two partially (His127 and His313) conserved histidine residues in the catalytic domain of the enzyme. We have changed these residues to asparagine and characterised the variant enzymes with respect to their DNA cleavage activity, structural integrity and oligomeric state. All variants show a decrease in activity compared to the wild-type nuclease as measured by a plasmid DNA cleavage assay. H242N, H263N and H313N exhibit DNA cleavage activities below 5% and H308N displays a drastically altered DNA cleavage pattern compared to wild-type CAD. Whereas all variants but one have the same secondary structure composition and oligomeric state, H242N does not, suggesting that His242 has an important structural role. On the basis of these results, possible roles for His127, His263, His304, His308 and His313 in DNA binding and cleavage are discussed for murine CAD.     

A critical role for the histidine residues in the catalytic function of acyl-CoA:cholesterol acyltransferase catalysis: evidence for catalytic difference between ACAT1 and ACAT2

To investigate a role for histidine residues in the expression of normal acyl-CoA:cholesterol acyltransferase (ACAT) activity, the histidine residues located at five different positions in two isoenzymes were substituted by alanine, based on the sequence homology between ACAT1 and ACAT2. Among the 10 mutants generated by baculovirus expression technology, H386A-ACAT1, H460A-ACAT1, H360A-ACAT2, and H399A-ACAT2 lost their enzymatic activity completely. A reduction in catalytic activity is unlikely to result from structural changes in the substrate-binding pocket, because their substrate-binding affinities were normal. However, the enzymatic activity of H386A-ACAT1 was restored to <37% of the level of the wild-type activity when cholesterol was replaced by 25-hydroxycholesterol as substrate. H527A-ACAT1 and H501A-ACAT2, termed carboxyl end mutants, exhibit activities of ∼96% and ∼75% of that of the wild-type. Interestingly, H425A-ACAT1 showed 59% of the wild-type activity, in contrast to its equivalent mutant, H399A-ACAT2. These results demonstrate that the histidine residues located at the active site are very crucial both for the catalytic activity of the enzyme and for distinguishing ACAT1 from ACAT2 with respect to enzyme catalysis and substrate specificity.     

Structural basis for the nuclease activity of a bacteriophage large terminase

The DNA‐packaging motor in tailed bacteriophages requires nuclease activity to ensure that the genome is packaged correctly. This nuclease activity is tightly regulated as the enzyme is inactive for the duration of DNA translocation. Here, we report the X‐ray structure of the large terminase nuclease domain from bacteriophage SPP1. Similarity with the RNase H family endonucleases allowed interactions with the DNA to be predicted. A structure‐based alignment with the distantly related T4 gp17 terminase shows the conservation of an extended β‐sheet and an auxiliary β‐hairpin that are not found in other RNase H family proteins. The model with DNA suggests that the β‐hairpin partly blocks the active site, and in vivo activity assays show that the nuclease domain is not functional in the absence of the ATPase domain. Here, we propose that the nuclease activity is regulated by movement of the β‐hairpin, altering active site access and the orientation of catalytically essential residues.     

Mutational analysis of a conserved motif of Agrobacterium tumefaciens VirD2.

The VirD2 polypeptide from Agrobacterium tumefaciens, in the presence of VirD1, introduces a site- and strand-specific nick at the T-DNA borders. A similar reaction at the origin of transfer (oriT) of plasmids is essential for plasmid transfer by bacterial conjugation. A comparison of protein sequences of VirD2 and its functional homologs in bacterial conjugation and in rolling circle replication revealed that they share a conserved 14 residue segment, HxDxxx(P/u)HuHuuux [residues 126-139 of VirD2; Ilyina, T.V. and Koonin, E.V. (1992) Nucleic Acids Res. 20, 3279-3285]. A mutational approach was used to test the role of these residues in the endonuclease activity of VirD2. The results demonstrated that the two invariant histidine residues (H133 and H135) are essential for activity. Mutations at three sites, histidine 126, aspartic acid 128 and aspartic acid 130, that are conserved in a subfamily of the plasmid mobilization proteins, led to the loss of VirD2 activity. Aspartic acid at position 130, could be substituted with glutamic acid and to a much lesser extent, with tyrosine. In contrast, another conserved residue, asparagine 139, tolerated many different amino acid substitutions. The non-conserved residues, arginine 129, proline 132 and leucine 134, were also found to be important for function. Isolation of null mutations that map throughout this conserved domain confirm the hypothesis that this region is essential for function.     

Biochemical and genetic analysis of the phosphoethanolamine methyltransferase of the human malaria parasite Plasmodium falciparum

The PfPMT enzyme of Plasmodium falciparum, the agent of severe human malaria, is a member of a large family of known and predicted phosphoethanolamine methyltransferases (PMTs) recently identified in plants, worms, and protozoa. Functional studies in P. falciparum revealed that PfPMT plays a critical role in the synthesis of phosphatidylcholine via a plant-like pathway involving serine decarboxylation and phosphoethanolamine methylation. Despite their important biological functions, PMT structures have not yet been solved, and nothing is known about which amino acids in these enzymes are critical for catalysis and binding to S-adenosyl-methionine and phosphoethanolamine substrates. Here we have performed a mutational analysis of PfPMT focused on 24 residues within and outside the predicted catalytic motif. The ability of PfPMT to complement the choline auxotrophy of a yeast mutant defective in phospholipid methylation enabled us to characterize the activity of the PfPMT mutants. Mutations in residues Asp-61, Gly-83 and Asp-128 dramatically altered PfPMT activity and its complementation of the yeast mutant. Our analyses identify the importance of these residues in PfPMT activity and set the stage for advanced structural understanding of this class of enzymes.     

His1205 and His1223 are essential for the activity of the mitogenic Pasteurella multocida toxin

Pasteurella multocida produces a 146-kDa protein toxin (PMT), which activates multiple cellular signal-transduction pathways, resulting in the activation of PLCbeta, Rho, JNK, and ERK. In addition to an essential cysteine residue at position 1165, PMT contains several histidine residues in the catalytically important C-terminal part of the protein. To elucidate the role of the histidine residues, we treated PMT with the histidine-modifying substance diethyl pyrocarbonate (DEPC). DEPC inhibited PMT in a time- and concentration-dependent manner, suggesting that one or several histidine residues are essential for the biological activity of PMT. In experiments in which PMT was directly delivered into the cytosol of EBL cells by electroporation, we show that DEPC treatment inhibits the catalytically important histidine residues. Leucine substitutions of eight individual histidine residues in the C-terminal catalytic domain of PMT were constructed, and the effect on the biological activity of PMT was analyzed by determining PLCbeta, Rho, and ERK activation. Substitution of two histidine residues, H1205 and H1223, led to inactivation of the resulting PMT proteins, indicating that H1205 and H1223 play an important role in biological activity of the toxin. In addition, we show that the mutant toxins appear to be correctly folded, as judged by protease digestion. The precise function of H1205 and H1223 is not yet known. However, treatment of PMT with the cation chelating substance 1,10-phenantroline led to inactivation of the toxin, indicating that the essential histidine residues and cysteine 1165 might be involved in metal ion binding.     

Structure and function of TatD exonuclease in DNA repair

TatD is an evolutionarily conserved protein with thousands of homologues in all kingdoms of life. It has been suggested that TatD participates in DNA fragmentation during apoptosis in eukaryotic cells. However, the cellular functions and biochemical properties of TatD in bacterial and non-apoptotic eukaryotic cells remain elusive. Here we show that Escherichia coli TatD is a Mg²⁺-dependent 3′–5′ exonuclease that prefers to digest single-stranded DNA and RNA. TatD-knockout cells are less resistant to the DNA damaging agent hydrogen peroxide, and TatD can remove damaged deaminated nucleotides from a DNA chain, suggesting that it may play a role in the H₂O₂-induced DNA repair. The crystal structure of the apo-form TatD and TatD bound to a single-stranded three-nucleotide DNA was determined by X-ray diffraction methods at a resolution of 2.0 and 2.9 Å, respectively. TatD has a TIM-barrel fold and the single-stranded DNA is bound at the loop region on the top of the barrel. Mutational studies further identify important conserved metal ion-binding and catalytic residues in the TatD active site for DNA hydrolysis. We thus conclude that TatD is a new class of TIM-barrel 3′–5′ exonuclease that not only degrades chromosomal DNA during apoptosis but also processes single-stranded DNA during DNA repair.     

TatD is a central component of a Tat translocon‐initiated quality control system for exported FeS proteins in Escherichia coli

Bacterial Tat systems export folded proteins, including FeS proteins such as NrfC and NapG, which acquire their cofactors before translocation. NrfC and NapG are proofread by the Tat pathway, and misfolded examples are degraded after interaction with the translocon. Here, we identify TatD as a crucial component of this quality control system in Escherichia coli. NrfC/NapG variants lacking FeS centres are rapidly degraded in wild‐type cells but stable in a ΔtatD strain. The precursor of another substrate, FhuD, is also transiently detected in wild‐type cells but stable in the ΔtatD strain. Surprisingly, these substrates are stable in ΔtatD cells that overexpress TatD, and export of the non‐mutated precursors is inhibited. We propose that TatD is part of a quality control system that is intimately linked to the Tat export pathway, and that the overexpression of TatD leads to an imbalance between the two systems such that both Tat‐initiated turnover and export are prevented.     

The catalytic role of the distal site asparagine-histidine couple in catalase-peroxidases.

Catalase-peroxidases (KatGs) are unique in exhibiting an overwhelming catalase activity and a peroxidase activity of broad specificity. Similar to other peroxidases the distal histidine in KatGs forms a hydrogen bond with an adjacent conserved asparagine. To investigate the catalytic role(s) of this potential hydrogen bond in the bifunctional activity of KatGs, Asn153 in Synechocystis KatG was replaced with either Ala (Asn153-->Ala) or Asp (Asn153-->Asp). Both variants exhibit an overall peroxidase activity similar with wild-type KatG. Cyanide binding is monophasic, however, the second-order binding rates are reduced to 5.4% (Asn153-->Ala) and 9.5% (Asn153-->Asp) of the value of native KatG [(4.8 +/- 0.4) x 105 m-1.s-1 at pH 7 and 15 degrees C]. The turnover number of catalase activity of Asn153-->Ala is 6% and that of Asn153-->Asp is 16.5% of wild-type activity. Stopped-flow analysis of the reaction of the ferric forms with H2O2 suggest that exchange of Asn did not shift significantly the ratio of rates of H2O2-mediated compound I formation and reduction. Both rates seem to be reduced most probably because (a) the lower basicity of His123 hampers its function as acid-base catalyst and (b) Asn153 is part of an extended KatG-typical H-bond network, the integrity of which seems to be essential to provide optimal conditions for binding and oxidation of the second H2O2 molecule necessary in the catalase reaction.     

Role of conserved histidine residues in metalloactivation of the ArsA ATPase

The ArsA ATPase is the catalytic subunit of a pump that is responsible for resistance to arsenicals and antimonials in Escherichia coli. Arsenite or antimonite allosterically activates the ArsA ATPase activity. ArsA homologues from eubacteria, archaea and eukarya have a signature sequence (DTAPTGHT) that includes a conserved histidine. The ArsA ATPase has two such conserved motifs, one in the NH₂-terminal (A1) half and the other in the COOH-terminal (A2) half of the protein. These sequences have been proposed to be signal transduction domains that transmit the information of metal occupancy at the allosteric to the catalytic site to activate ATP hydrolysis. The role of the conserved residues His148 and His453, which reside in the A1 and A2 signal transduction domains respectively, was investigated by mutagenesis to create H148A, H453A or H148A/H453A ArsAs. Each altered protein exhibited a decrease in the V _max of metalloid-activated ATP hydrolysis, in the order wild type ArsA>H148A>H453A>H148A/H453A. These results suggest that the histidine residues play a role in transmission of the signal between the catalytic and allosteric sites.     

The Helicobacter pylori UreI protein: role in adaptation to acidity and identification of residues essential for its activity and for acid activation

Helicobacter pylori is a human gastric pathogen that survives the strong acidity of the stomach by virtue of its urease activity. This activity produces ammonia, which neutralizes the bacterial microenvironment. UreI, an inner membrane protein, is essential for resistance to low pH and for the gastric colonization of mice by H. pylori. In the heterologous Xenopus oocytes expression system, UreI behaves like an H+-gated urea channel, and His-123 was found to be important for low pH activation. We investigated the role of UreI directly in H. pylori and showed that, in the presence of urea, strains expressing wild-type UreI displayed very rapid stimulation of extracellular ammonia production upon exposure to pH 相似文献   

Identification of Histidine Residues Involved in Zn2+ Binding to αA- and αB-Crystallin by Chemical Modification and MALDI TOF Mass Spectrometry

??-Crystallin, a member of the small heat shock protein family is the major protein of mammalian eye lens and is a molecular chaperone. As there is no protein turn over in the lens, stability of ??-crystallin is one of the most crucial factors for its survival and function. We previously reported that the molecular chaperone-like activity and stability of ??-crystallin dramatically increased in the presence of Zn²⁺ (Biochemistry, 2008). We also reported that each subunit of ??-crystallin could bind multiple zinc ions through inter-subunit bridging giving rise to enhanced stability (Biopolymers, 2011). The amino acid residues involved in zinc binding were not known. Since cysteine residues were not responsible for binding to Zn²⁺, we tried to identify the histidine residues bound to zinc ions. We modified recombinant ??A- and ??B-crystallin with diethylpyrocarbonate (DEPC) a histidine modifying reagent, in presence and absence of Zn²⁺ followed by tryptic digestion. The residues modified by DEPC were identified through peptide mass matching by MALDI mass spectrometry. We have clearly identified H79, H107 and H115 of ??A-crystallin and H104, H111 and H119 of ??B-crystallin as the Zn²⁺ binding residues. The significance of the histidine rich sequence region of ??-crystallin for its stability is discussed.     

NMR assignments of the four histidines of staphylococcal nuclease in native and denatured states

NMR signals from all four histidine ring C epsilon protons and three of the four histidine C delta protons in the protein staphylococcal nuclease have been assigned by comparing spectra of the wild-type (Foggi strain) protein to spectra of three variants that each lack a different histidine residue. All proteins studied were cloned and overproduced in Escherichia coli. The NMR spectra of the three mutant proteins (H8R, H46Y, and H124L) used to make these assignments were similar to one another and to those of the wild type, except for signals from the mutated residues. The pKa values of those histidines conserved between the wild type and the mutants remained essentially unchanged. Multiple histidine C epsilon proton resonances due to non-native forms of nuclease were observed in both thermally induced and acid-induced unfolding. Residue-specific assignments of H epsilon protons in the thermally denatured forms of the mutant H46Y were obtained from connectivities to the native state by saturation transfer.     

Original Research Report: Structure-Function Analysis of the ArsA ATPase: Contribution of Histidine Residues

The ArsA ATPase is the catalytic subunit of the ArsAB oxyanion pump in Escherichia coli that is responsible for extruding arsenite or antimonite from inside the cell, thereby conferring resistance. Either antimonite or arsenite stimulates ArsA ATPase activity. In this study, the role of histidine residues in ArsA activity was investigated. Treatment of ArsA with diethyl pyrocarbonate (DEPC) resulted in complete loss of catalytic activity. The inactivation could be reversed upon subsequent incubation with hydroxylamine, suggesting specific modification of histidine residues. ATP and oxyanions afforded significant protection against DEPC inactivation, indicating that the histidines are located at the active site. ArsA has 13 histidine residues located at position 138, 148, 219, 327, 359, 368, 388, 397, 453, 465, 477, 520, and 558. Each histidine was individually altered to alanine by site-directed mutagenesis. Cells expressing the altered ArsA proteins were resistant to both arsenite and antimonite. The results indicate that no single histidine residue plays a direct role in catalysis, and the inhibition by DEPC may be caused by steric hindrance from the carbethoxy group.