Probing the two-domain structure of homodimeric prokaryotic and eukaryotic catalase–peroxidases

Catalase–peroxidases (KatGs) are ancestral bifunctional heme peroxidases found in archaeons, bacteria and lower eukaryotes. In contrast to homologous cytochrome c peroxidase (CcP) and ascorbate peroxidase (APx) homodimeric KatGs have a two-domain monomeric structure with a catalytic N-terminal heme domain and a C-terminal domain of high sequence and structural similarity but without obvious function. Nevertheless, without its C-terminal counterpart the N-terminal domain exhibits neither catalase nor peroxidase activity. Except some hybrid-type proteins all other members of the peroxidase–catalase superfamily lack this C-terminal domain. In order to probe the role of the two-domain monomeric structure for conformational and thermal stability urea and temperature-dependent unfolding experiments were performed by using UV–Vis-, electronic circular dichroism- and fluorescence spectroscopy, as well as differential scanning calorimetry. Recombinant prokaryotic (cyanobacterial KatG from Synechocystis sp. PCC6803) and eukaryotic (fungal KatG from Magnaporthe grisea) were investigated. The obtained data demonstrate that the conformational and thermal stability of bifunctional KatGs is significantly lower compared to homologous monofunctional peroxidases. The N- and C-terminal domains do not unfold independently. Differences between the cyanobacterial and the fungal enzyme are relatively small. Data will be discussed with respect to known structure and function of KatG, CcP and APx.     

Identification of Comamonas species using 16S rRNA gene sequence

A bacterial strain Bz02 was isolated from a water sample collected from river Gomti at the Indian city of Lucknow. We characterized the strain using 16S rRNA sequence. Phylogenetic analysis showed that the strain formed a monophyletic clade with members of the genus Comamonas. The closest phylogenetic relative was Comamonas testosteroni with 95% 16S rRNA gene sequence similarity. It is proposed that the identified strain Bz02 be assigned as the type strain of a species of the genus Comamonas (Comamonas sp Bz02) based on 16S rRNA gene sequence search in Ribosomal Database Project, small subunit rRNA and large subunit rRNA databases together with the phylogenetic tree analysis. The sequence is deposted in GenBank with the accession number {"type":"entrez-nucleotide","attrs":{"text":"FJ211417","term_id":"209164434"}}FJ211417.     

High Conformational Stability of Secreted Eukaryotic Catalase-peroxidases: ANSWERS FROM FIRST CRYSTAL STRUCTURE AND UNFOLDING STUDIES

Catalase-peroxidases (KatGs) are bifunctional heme enzymes widely spread in archaea, bacteria, and lower eukaryotes. Here we present the first crystal structure (1.55 Å resolution) of an eukaryotic KatG, the extracellular or secreted enzyme from the phytopathogenic fungus Magnaporthe grisea. The heme cavity of the homodimeric enzyme is similar to prokaryotic KatGs including the unique distal ⁺Met-Tyr-Trp adduct (where the Trp is further modified by peroxidation) and its associated mobile arginine. The structure also revealed several conspicuous peculiarities that are fully conserved in all secreted eukaryotic KatGs. Peculiarities include the wrapping at the dimer interface of the N-terminal elongations from the two subunits and cysteine residues that cross-link the two subunits. Differential scanning calorimetry and temperature- and urea-mediated unfolding followed by UV-visible, circular dichroism, and fluorescence spectroscopy combined with site-directed mutagenesis demonstrated that secreted eukaryotic KatGs have a significantly higher conformational stability as well as a different unfolding pattern when compared with intracellular eukaryotic and prokaryotic catalase-peroxidases. We discuss these properties with respect to the structure as well as the postulated roles of this metalloenzyme in host-pathogen interactions.     

Thiosulfate Oxidation by <Emphasis Type="Italic">Comamonas</Emphasis> sp. S23 Isolated from a Sulfur Spring

A bacterial isolate S23 capable of oxidizing thiosulfate was isolated from a sulfur spring. Strain S23 is gram-negative, aerobic, and motile. The G + C content of DNA is 61.4 mol%. The fatty acid composition and phylogenetic analysis of the 16S rRNA gene sequence of strain S23 showed that it is related to the members of the genus Comamonas, and most closely related to Comamonas testosteroni (99.9% sequence similarity). The isolate S23 exhibited thiosulfate oxidation under a mixotrophic growth condition. Polymerase chain reaction (PCR) using soxB-specific primers and DNA sequencing showed the presence of the soxB gene. This is the first report in Comamonas sp. showing thiosulfate oxidation under a mixotrophic growth condition.     

Polyhydroxyalkanoate production from anaerobically treated palm oil mill effluent by new bacterial strain <Emphasis Type="Italic">Comamonas</Emphasis> sp. EB172

A new isolate designated as strain EB172 was isolated from a digester treating palm oil mill effluent and was investigated by polyphasic taxonomic approach. The cells were rod-shaped, Gram-negative, non-pigmented, non-spore-forming and non-fermentative. Phylogenetic analysis using the 16S rRNA gene sequence showed that the strain clustered with the genus Comamonas. Its closest neighbours were the type strains Comamonas terrigena (96.8%), Comamonas koreensis (93.4%), Comamonas composti (92.9%), and Comamonas kerstersii (91.1%). The ability of the strain EB172 to produce polyhydroxyalkanoates (PHA) when supplied with organic acids made this bacterium unique among Comamonas species. The bacterial strain was clearly distinguished from all of the existing strains by phylogenetic analysis, fatty acid composition and a range of physiological and biochemical characteristics. The G+C content of the genomic DNA was 59.1 mol%. The strain showed good growth in acetic, propionic and n-butyric acids. Comamonas sp. EB172 produced 9.8 g/l of cell dry weight and accumulated 59 (wt%) of PHAs when supplemented with mixed organic acids from anaerobically treated palm oil mill effluent. It is evident from the genotypic, phenotypic data and ability to produce PHAs that strain EB172 represents a new strain in the genus Comamonas (GeneBank accession no. EU847238).     

Genetics of naphthalene and phenanthrene degradation by Comamonas testosteroni

Naphthalene and phenanthrene have long been used as model compounds to investigate the ability of bacteria to degrade polycyclic aromatic hydrocarbons. The catabolic pathways have been determined, several of the enzymes have been purified to homogeneity, and genes have been cloned and sequenced. However, the majority of this work has been performed with fast growing Pseudomonas strains related to the archetypal naphthalene-degrading P. putida strains G7 and NCIB 9816-4. Recently Comamonas testosteroni strains able to degrade naphthalene and phenanthrene have been isolated and shown to possess genes for polycyclic aromatic hydrocarbon degradation that are different from the canonical genes found in Pseudomonas species. For instance, C. testosteroni GZ39 has genes for naphthalene and phenanthrene degradation which are not only different from those found in Pseudomonas species but are also arranged in a different configuration. C. testosteroni GZ42, on the other hand, has genes for naphthalene and phenanthrene degradation which are arranged almost the same as those found in Pseudomonas species but show significant divergence in their sequences. Received 10 August 1997/ Accepted in revised form 15 August 1997     

The Complete Genome of Comamonas testosteroni Reveals Its Genetic Adaptations to Changing Environments

Members of the gram-negative, strictly aerobic genus Comamonas occur in various environments. Here we report the complete genome of Comamonas testosteroni strain CNB-2. Strain CNB-2 has a circular chromosome that is 5,373,643 bp long and has a G+C content of 61.4%. A total of 4,803 open reading frames (ORFs) were identified; 3,514 of these ORFs are functionally assigned to energy production, cell growth, signal transduction, or transportation, while 866 ORFs encode hypothetical proteins and 423 ORFs encode purely hypothetical proteins. The CNB-2 genome has many genes for transportation (22%) and signal transduction (6%), which allows the cells to respond and adapt to changing environments. Strain CNB-2 does not assimilate carbohydrates due to the lack of genes encoding proteins involved in glycolysis and pentose phosphate pathways, and it contains many genes encoding proteins involved in degradation of aromatic compounds. We identified 66 Tct and nine TRAP-T systems and a complete tricarboxylic acid cycle, which may allow CNB-2 to take up and metabolize a range of carboxylic acids. This nutritional bias for carboxylic acids and aromatic compounds enables strain CNB-2 to occupy unique niches in environments. Four different sets of terminal oxidases for the respiratory system were identified, and they putatively functioned at different oxygen concentrations. This study conclusively revealed at the genomic level that the genetic versatility of C. testosteroni is vital for competition with other bacteria in its special niches.The members of the genus Comamonas are gram-negative, strict aerobes and frequently occur in diverse habitats, including activated sludge, marshes, marine habitats, and plant and animal tissues (4, 12, 13). They grow on organic acids, amino acids, and peptone, but they rarely attack carbohydrates. Some species, such as Comamonas testosteroni, can also mineralize complex and xenobiotic compounds, such as testosterone (17) and 4-chloronitrobenzene (CNB) (54). Their diversified niches make Comamonas species environmentally important and also suggest that the genus Comamonas represents a group of bacteria that can adapt very well, both ecologically and physiologically, to environments.To understand better how environmental microbes adapt to their environments, many well-known environmental microbes, such as Pseudomonas putida (53) and Rhodococcus sp. strain RAH1 (31), have been sequenced. The genome data for these organisms, as well as other environmental microbes, provide not only an understanding of physiological and environmental functions at the genetic level but also a starting point for systems biology analyses of these microbes. Until now, none of the Comamonas species has been sequenced, although these organisms represent an important group of environmental microbes.C. testosteroni strain CNB-1 was isolated from CNB-contaminated activated sludge and grows with CNB as a sole source of carbon and nitrogen, and it has been used successfully for rhizoremediation of CNB-polluted soil (25). Strain CNB-1 has a circular chromosome and a large plasmid, and the genes involved in the degradation of CNB on plasmid pCNB1 were identified previously (28). In the present study, the genome of strain CNB-2, which was derived from strain CNB-1, was sequenced, and a genome analysis was performed parallel to physiological experiments. The aim of this work was to obtain genetic insight into how C. testosteroni adapts to changing and diverse environments.     

Characterization of Comamonas thiooxidans sp. nov., and Comparison of Thiosulfate Oxidation with Comamonas testosteroni and Comamonas composti

Comamonas thiooxidans (strain S23^T) capable of oxidizing thiosulfate under a mixotrophic growth condition was isolated from a sulfur spring. DNA–DNA homology study showed 55% similarity with Comamonas testosteroni KCTC2990^T and 52% with Comamonas composti LMG24008^T, the nearest phylogenetic relative (16S rRNA sequence similarity <97%). Comparative genomic fingerprinting by using ERIC and Rep-PCR further delineated species identity of the strain S23^T for which Comamonas thiooxidans sp. nov. is proposed. In addition, thiosulfate oxidation potential of the strain S23^T was compared with Comamonas testosteroni and Comamonas composti.     

Comamonas faecalis sp. nov., Isolated from Domestic Pig Feces

A new bacterial strain, designated as FF42^T, was isolated from feces of domestic pigs—collected from Suwon, Korea—and was characterized to determine its taxonomic position. Strain FF42^T was observed to be Gram negative, aerobic, non-spore forming, motile, and rod-shaped cells. Based on the phylogenetic and 16S rRNA sequence analyses, it was revealed that strain FF42^T belonged to the genus Comamonas. The highest degree of sequence similarities was determined to be with Comamonas zonglianii BF-3^T (96.3 %), Comamonas composti CC-YY287^T (96.1 %), and Comamonas nitrativorans 23310^T (95.9 %), while showing less than 95.6 % identity with the remaining Comamonas species. Growth of strain FF42^T occurred between 25 and 40 °C (optimum, 28 °C) and at pH of 5-9 (optimum, pH 6.0). It grew in the presence of 0–3 % (w/v) NaCl while minimally tolerating at 3 % (w/v) NaCl. Biochemical and physiological tests revealed phenotypic differentiation of strain FF42^T to other members of the genus Comamonas. The predominant quinone is ubiquinone (Q-8). The major cellular fatty acids were C_10:0 3OH, C_16:0, summed feature 3 (C_16:1 ω7c/C_16:1 ω6c), and summed feature 8 (C_18:1 ω6c/C_18:1 ω7c), all of which have previously been reported to occur in the species of the genus Comamonas. The G+C molar content for strain FF42^T is 60.2 mol %. Based on phylogenetic and phenotypic analyses, strain FF42^T (=KEMC 1002-058^T=JCM 17561^T) is clearly referred to be a novel species for the genus Comamonas, for which the name Comamonas faecalis sp. nov. is proposed.     

Molecular characterization of a bifunctional glyoxylate cycle enzyme, malate synthase/isocitrate lyase, in Euglena gracilis

Euglena gracilis induced glyoxylate cycle enzymes when ethanol was fed as a sole carbon source. We purified, cloned and characterized a bifunctional glyoxylate cycle enzyme from E. gracilis (EgGCE). This enzyme consists of an N-terminal malate synthase (MS) domain fused to a C-terminal isocitrate lyase (ICL) domain in a single polypeptide chain. This domain order is inverted compared to the bifunctional glyoxylate cycle enzyme in Caenorhabditis elegans, an N-terminal ICL domain fused to a C-terminal MS domain. Purified EgGCE catalyzed the sequential ICL and MS reactions. ICL activity of purified EgGCE increased in the existence of acetyl-CoA at a concentration of micro-molar order. We discussed the physiological roles of the bifunctional glyoxylate cycle enzyme in these organisms as well as its molecular evolution.     

Divergence in structure and function of tau class glutathione transferase from Pinus tabulaeformis,P. yunnanensis and P. densata

Glutathione transferases (GSTs) are a family of enzymes that play important roles in stress tolerance and detoxification in plants. The plant GSTs are divided into four classes (phi, tau, zeta and theta), among which tau is the most numerously represented. To date, studies on GSTs in plants have focused largely on crop species. There is extremely little information on the molecular characteristics of GSTs in gymnosperms. Generalization on GST characteristics unique to gymnosperms and the patterns of GST evolution in plants cannot be made before more members of the gene family in conifers are described. In this study we report three new GSTs from Pinus tabulaeformis, Pinus densata and Pinus yunnanensis. Structural and phylogenetic analyses placed these three GSTs in tau class. The tau GST class is subdivided into three clades and this subdivision seems an ancient event that may have pre-dated the gymnosperm and angiosperm split. Sequence analysis revealed a highly conserved N-terminal domain in contrast to a highly variable C-terminal domain. Mutations even outside the critical glutathione-binding site in N-terminal domain can have pronounced effect on GST catalytic property. Thus, sequence similarity does not parallel functional specificity. The high diversity in C-terminal domain determines a wide range of substrate selectivity and specificity among tau GSTs. Thus the a few conserved residues in C-terminal domain seem essential to maintain the structure of the domain and the protein dimer. More extensive data on GST family organization and a thorough gene-by-gene analysis in conifers are needed to advance our understanding of the true diversity and evolution of GST in structure and function in plants.     

Integral role of the I′-helix in the function of the “inactive” C-terminal domain of catalase–peroxidase (KatG)

Catalase–peroxidases (KatGs) have two peroxidase-like domains. The N-terminal domain contains the heme-dependent, bifunctional active site. Though the C-terminal domain lacks the ability to bind heme or directly catalyze any reaction, it has been proposed to serve as a platform to direct the folding of the N-terminal domain. Toward such a purpose, its I′-helix is highly conserved and appears at the interface between the two domains. Single and multiple substitution variants targeting highly conserved residues of the I′-helix were generated for intact KatG as well as the stand-alone C-terminal domain (KatG^C). Single variants of intact KatG produced only subtle variations in spectroscopic and catalytic properties of the enzyme. However, the double and quadruple variants showed substantial increases in hexa-coordinate low-spin heme and diminished enzyme activity, similar to that observed for the N-terminal domain on its own (KatG^N). The analogous variants of KatG^C showed a much more profound loss of function as evaluated by their ability to return KatG^N to its active conformation. All of the single variants showed a substantial decrease in the rate and extent of KatG^N reactivation, but with two substitutions, KatG^C completely lost its capacity for the reactivation of KatG^N. These results suggest that the I′-helix is central to direct structural adjustments in the adjacent N-terminal domain and supports the hypothesis that the C-terminal domain serves as a platform to direct N-terminal domain conformation and bifunctionality.     

High correlation between genotypes and phenotypes of environmental bacteria Comamonas testosteroni strains

Background

Members of Comamonas testosteroni are environmental microorganisms that are usually found in polluted environment samples. They utilize steroids and aromatic compounds but rarely sugars, and show resistance to multiple heavy metals and multiple drugs. However, comprehensive genomic analysis among the C. testosteroni strains is lacked.

Results

To understand the genome bases of the features of C. testosteroni, we sequenced 10 strains of this species and analyzed them together with other related published genome sequences. The results revealed that: 1) the strains of C. testosteroni have genome sizes ranging from 5.1 to 6.0 Mb and G + C contents ranging from 61.1% to 61.8%. The pan-genome contained 10,165 gene families and the core genome contained 3,599 gene families. Heap’s law analysis indicated that the pan-genome of C. testosteroni may be open (α = 0.639); 2) by analyzing 31 phenotypes of 11 available C. testosteroni strains, 99.4% of the genotypes (putative genes) were found to be correlated to the phenotypes, indicating a high correlation between phenotypes and genotypes; 3) gene clusters for nitrate reduction, steroids degradation and metal and multi-drug resistance were found and were highly conserved among all the genomes of this species; 4) the genome similarity of C. testosteroni may be related to the geographical distances.

Conclusions

This work provided an overview on the genomes of C. testosteroni and new genome resources that would accelerate the further investigations of this species. Importantly, this work focused on the analysis of potential genetic determinants for the typical characters and found high correlation between the phenotypes and their corresponding genotypes.

Electronic supplementary material

The online version of this article (doi:10.1186/s12864-015-1314-x) contains supplementary material, which is available to authorized users.     

Cloning and sequence analyses of a 2,3-dihydroxybiphenyl 1,2-dioxygenase gene (<Emphasis Type="Italic">bphC</Emphasis>) from<Emphasis Type="Italic"> Comamonas</Emphasis> sp. SMN4 for phylogenetic and structural analysis

A genomic library of biphenyl-degrading Comamonas sp. SMN4 for isolating fragments containing the 2,3-dihydroxybiphenyl 1,2-dioxygenase (23DBDO) gene was constructed. The smallest subclone (pNPX9) encoding 23DBDO activity was sequenced and analyzed. The C-terminal domain of 23DBDO from Comamonas sp. SMN4 had five catalytically essential residues and was more highly conserved than the N-terminal domain. Phylogenetic and structural relationships of 23DBDO from Comamonas sp. SMN4 were analyzed. Electronic Publication     

The Cytoplasm-Entry Domain of Antibacterial CdiA Is a Dynamic α-Helical Bundle with Disulfide-Dependent Structural Features

Many Gram‐negative bacterial species use contact-dependent growth inhibition (CDI) systems to compete with neighboring cells. CDI⁺ strains express cell-surface CdiA effector proteins, which carry a toxic C-terminal region (CdiA-CT) that is cleaved from the effector upon transfer into the periplasm of target bacteria. The released CdiA-CT consists of two domains. The C-terminal domain is typically a nuclease that inhibits cell growth, and the N-terminal “cytoplasm-entry” domain mediates toxin translocation into the target-cell cytosol. Here, we use NMR and circular dichroism spectroscopic approaches to probe the structure, stability, and dynamics of the cytoplasm-entry domain from Escherichia coli STEC_MHI813. Chemical shift analysis reveals that the CdiA-CT^MHI813 entry domain is composed of a C-terminal helical bundle and a dynamic N-terminal region containing two disulfide linkages. Disruption of the disulfides by mutagenesis or chemical reduction destabilizes secondary structure over the N-terminus, but has no effect on the C-terminal helices. Although critical for N-terminal structure, the disulfides have only modest effects on global thermodynamic stability, and the entry domain exhibits characteristics of a molten globule. We find that the disulfides form in vivo as the entry domain dwells in the periplasm of inhibitor cells prior to target-cell recognition. CdiA-CT^MHI813 variants lacking either disulfide still kill target bacteria, but disruption of both bonds abrogates growth inhibition activity. We propose that the entry domain's dynamic structural features are critical for function. In its molten globule-like state, the domain resists degradation after delivery, yet remains pliable enough to unfold for membrane translocation.     

Functional domains of theEscherichia coli ferric uptake regulator protein (Fur)

The functions of N- and C-terminal domains of the Fur repressor ofEscherichia coli in promoter recognition and dimerization were studied. We investigated the ability of fusion proteins containing the N- or C-terminal domain of Fur to dimerize and to repress a Fur-regulatedlacZ fusion gene. The N-terminal domain, when fused to the C-terminal domain of the repressor C1857, repressed a Fur-regulatedlacZ fusion. However, the Fur-CI857 fusion was unable to complement the growth defect of anE. coli fur mutant on fumarate and succinate. The C-terminal domain of Fur, when fused to the N-terminus of CI857, repressed a λP, -regulatedlacZ fusion, indicating dimerization of the chimeric protein, which is a prerequisite for Cl activity. Both fusion proteins were fully active under both iron-rich and iron-poor growth conditions. We conclude that the N-terminal domain of Fur is involved in recognition of the Fur-responsive promoter and the C-terminus mediates oligomerization of the repressor.     

Genetic Diversity among 3-Chloroaniline- and Aniline-Degrading Strains of the Comamonadaceae

We examined the diversity of the plasmids and of the gene tdnQ, involved in the oxidative deamination of aniline, in five bacterial strains that are able to metabolize both aniline and 3-chloroaniline (3-CA). Three strains have been described and identified previously, i.e., Comamonas testosteroni I2 and Delftia acidovorans CA28 and BN3.1. Strains LME1 and B8c were isolated in this study from linuron-treated soil and from a wastewater treatment plant, respectively, and were both identified as D. acidovorans. Both Delftia and Comamonas belong to the family Comamonadaceae. All five strains possess a large plasmid of ca. 100 kb, but the plasmids from only four strains could be transferred to a recipient strain by selection on aniline or 3-CA as a sole source of carbon and/or nitrogen. Plasmid transfer experiments and Southern hybridization revealed that the plasmid of strain I2 was responsible for total aniline but not 3-CA degradation, while the plasmids of strains LME1 and B8c were responsible only for the oxidative deamination of aniline. Several transconjugant clones that had received the plasmid from strain CA28 showed different degradative capacities: all transconjugants could use aniline as a nitrogen source, while only some of the transconjugants could deaminate 3-CA. For all four plasmids, the IS1071 insertion sequence of Tn5271 was found to be located on a 1.4-kb restriction fragment, which also hybridized with the tdnQ probe. This result suggests the involvement of this insertion sequence element in the dissemination of aniline degradation genes in the environment. By use of specific primers for the tdnQ gene from Pseudomonas putida UCC22, the diversity of the PCR-amplified fragments in the five strains was examined by denaturing gradient gel electrophoresis (DGGE). With DGGE, three different clusters of the tdnQ fragment could be distinguished. Sequencing data showed that the tdnQ sequences of I2, LME1, B8c, and CA28 were very closely related, while the tdnQ sequences of BN3.1 and P. putida UCC22 were only about 83% identical to the other sequences. Northern hybridization revealed that the tdnQ gene is transcribed only in the presence of aniline and not when only 3-CA is present.     

Biochemical and mutational analysis of EcoRII functional domains reveals evolutionary links between restriction enzymes

The archetypal Type IIE restriction endonuclease EcoRII is a dimer that has a modular structure. DNA binding studies indicate that the isolated C-terminal domain dimer has an interface that binds a single cognate DNA molecule whereas the N-terminal domain is a monomer that also binds a single copy of cognate DNA. Hence, the full-length EcoRII contains three putative DNA binding interfaces: one at the C-terminal domain dimer and two at each of the N-terminal domains. Mutational analysis indicates that the C-terminal domain shares conserved active site architecture and DNA binding elements with the tetrameric restriction enzyme NgoMIV. Data provided here suggest possible evolutionary relationships between different subfamilies of restriction enzymes.