Isolation and Characterization of a Novel Bacteriophage φ4D Lytic Against Enterococcus faecalis Strains

In recent years, Enterococcus faecalis has emerged as an important opportunistic nosocomial pathogen capable of causing dangerous infections. Therefore, there is an urgent need to develop novel antibacterial agents to control this pathogen. Bacteriophages have very effective bactericidal activity and several advantages over other antimicrobial agents and so far, no serious or irreversible side effects of phage therapy have been described. The objective of this study was to characterize a novel virulent bacteriophage φ4D isolated from sewage. Electron microscopy revealed its resemblance to Myoviridae, with an isometric head (74 ± 4 nm) and a long contractile tail (164 ± 4 nm). The φ4D phage genome was tested using pulsed-field gel electrophoresis and estimated to be 145 ± 2 kb. It exhibited short latent period (25 min) and a relatively small burst size (36 PFU/cell). Tests were conducted on the host range, multiplicities of infection (MOI), thermal stability, digestion of DNA by restriction enzymes, and proteomic analyses of this phage. The isolated phage was capable of infecting a wide spectrum of enterococcal strains. The results of these investigations indicate that φ4D is similar to other Myoviridae bacteriophages (for example φEF24C), which have been successfully used in phagotherapy.     

Isolation and Characterization of “Dehalococcoides” sp. Strain MB,Which Dechlorinates Tetrachloroethene to trans-1,2-Dichloroethene

In an attempt to understand the microorganisms involved in the generation of trans-1,2-dichloroethene (trans-DCE), pure-culture “Dehalococcoides” sp. strain MB was isolated from environmental sediments. In contrast to currently known tetrachloroethene (PCE)- or trichloroethene (TCE)-dechlorinating pure cultures, which generate cis-DCE as the predominant product, Dehalococcoides sp. strain MB reductively dechlorinates PCE to trans-DCE and cis-DCE at a ratio of 7.3 (±0.4):1. It utilizes H₂ as the sole electron donor and PCE or TCE as the electron acceptor during anaerobic respiration. Strain MB is a disc-shaped, nonmotile bacterium. Under an atomic force microscope, the cells appear singly or in pairs and are 1.0 μm in diameter and ∼150 nm in depth. The purity was confirmed by culture-based approaches and 16S rRNA gene-based analysis and was corroborated further by putative reductive dehalogenase (RDase) gene-based, quantitative real-time PCR. Although strain MB shares 100% 16S rRNA gene sequence identity with Dehalococcoides ethenogenes strain 195, these two strains possess different dechlorinating pathways. Microarray analysis revealed that 10 putative RDase genes present in strain 195 were also detected in strain MB. Successful cultivation of strain MB indicates that the biotic process could contribute significantly to the generation of trans-DCE in chloroethene-contaminated sites. It also enhances our understanding of the evolution of this unusual microbial group, Dehalococcoides species.Dehalorespiring bacteria play an important role in the transformation and detoxification of a wide range of halogenated compounds, e.g., chlorophenols, chloroethenes, chlorobenzenes, polychlorinated biphenyls (PCBs), and polybrominated diphenyl ethers (PBDEs) (2, 4, 9, 14, 16, 17, 32, 35, 38). Among these compounds, the organic solvents tetrachloroethene (PCE) and trichloroethene (TCE) are suspected carcinogens that are found in soil and groundwater due to their extensive usage and improper disposal (6). The widespread PCE and TCE in the subsurface environment have driven intensive studies of anaerobic microbes capable of reductive dechlorination of chloroethenes (40). Over the last decade, at least 18 isolates, which belong to the genera Desulfitobacterium, Sulfurospirillum, Desulfomonile, Desulfuromonas, Geobacter, “Dehalococcoides,” and Dehalobacter, show reductive dechlorination of chlorinated ethenes (16, 40). In particular, most of these microbes produce cis-1,2-dichloroethene (cis-DCE) as the end product in the chloroethene-contaminated sites, whereas complete detoxification of PCE or TCE to ethene has been restricted only to members of the genus Dehalococcoides. Thus, the Dehalococcoides species have received considerable attention from the bioremediation community in the past decade.Several strains of Dehalococcoides species (e.g., 195, CBDB1, BAV1, and VS) have been sequenced for their whole genomes (24, 39). Their dechlorinating capabilities have also been well addressed through identification and quantification of the known chloroethene reductive dehalogenase (RDase) genes or expression of specific RDase genes (18, 21, 25, 41). In chloroethene-contaminated sites, the natural activities of single or multiple Dehalococcoides strains can lead either to more-toxic, mobile intermediates (e.g., cis- or trans-DCEs and vinyl chloride [VC]) via partial dechlorination of PCE/TCE or to harmless ethene by complete detoxification (10, 13, 15, 41). Many mixed cultures and pure isolates have been reported to produce cis-DCE or VC during PCE/TCE dechlorination processes (15, 40, 43). However, trans-DCE has been detected in more than one-third of the U.S. Environmental Protection Agency (EPA) superfund sites (3a). The source of trans-DCE production was thought to be an abiotic process; however, recently both trans-DCE generation and cis-DCE generation were reported to occur via microbial dechlorination.To date, microbes from either Dehalococcoides- or DF-1-containing mixed cultures have been reported to produce more trans- than cis-DCE, with a ratio of 1.2:1 to 3.5:1 in laboratory-scale studies (8, 10, 22, 31). For example, in a recent report by Kittelmann and Friedrich (22), trans-/cis-DCE at a ratio of 3.5:1 was generated in tidal flat sediment-containing microcosms with microbes closely related to Dehalococcoides sp. or DF-1-like microbes. Additionally, Griffin et al. identified Dehalococcoides species of the Pinellas subgroup in several enrichment cultures, which dechlorinated TCE (∼0.25 mM) to trans-DCE and cis-DCE at a ratio of ∼3:1 (10). There is no information available on the Dehalococcoides isolates that generate trans-DCE as the main end product. This also means a lack of information on the genomic contents of trans-DCE-producing bacteria. Therefore, finding microorganisms that produce trans-DCE in pure culture will be useful for the comprehensive characterization of this group of bacteria.The aim of this study was to isolate a PCE-to-trans-DCE-dechlorinating culture to facilitate the elucidation of trans-DCE formation during reductive dechlorination processes. Microarray analysis was conducted to compare the whole-genome contents of the new isolate and the well-characterized Dehalococcoides ethenogenes strain 195 (30). In addition, a coculture which consisted of the new isolate and TCE-to-cis-DCE-to-VC-dechlorinating Dehalococcoides sp. strain ANAS1 was explored to study the interaction, distribution, and function of the dechlorinators in the dechlorinating process.     

Molecular Characterization of the Nonphotosynthetic Partner Bacterium in the Consortium “Chlorochromatium aggregatum”

Phototrophic consortia represent valuable model systems for the study of signal transduction and coevolution between different bacteria. The phototrophic consortium “Chlorochromatium aggregatum” consists of a colorless central rod-shaped bacterium surrounded by about 20 green-pigmented epibionts. Although the epibiont was identified as a member of the green sulfur bacteria, and recently isolated and characterized in pure culture, the central colorless bacterium has been identified as a member of the β-Proteobacteria but so far could not be characterized further. In the present study, “C. aggregatum” was enriched chemotactically, and the 16S rRNA gene sequence of the central bacterium was elucidated. Based on the sequence information, fluorescence in situ hybridization probes targeting four different regions of the 16S rRNA were designed and shown to hybridize exclusively to cells of the central bacterium. Phylogenetic analyses of the 1,437-bp-long sequence revealed that the central bacterium of “C. aggregatum” represents a so far isolated phylogenetic lineage related to Rhodoferax spp., Polaromonas vacuolata, and Variovorax paradoxus within the family Comamonadaceae. The majority of relatives of this lineage are not yet cultured and were found in low-temperature aquatic environments or aquatic environments containing xenobiotica or hydrocarbons. In CsCl-bisbenzimidazole equilibrium density gradients, genomic DNA of the central bacterium of “Chlorochromatium aggregatum” formed a distinct band which could be detected by quantitative PCR using specific primers. Using this method, the G+C content of the central bacterium was determined to be 55.6 mol%.     

Isolation and Characterization of two New Microbial Strains Capable of Degradation of the Naturally Occurring Organophosphonate––Ciliatine

Air-born mixed fungal and bacterial culture capable of complete degradation of ciliatine was isolated. The utilization of the natural organophosphonate proceeded in the phosphate independent manner. Enzymatic activity involved in ciliatine degradation studied in the fungal cell-free extract proved to be distinct from bacterial pathway described before.     

Characterization and study of a κ-casein-like chymosin-sensitive linkage

The present report is dealing with the identification, in various unrelated proteins, of protein fragments sharing local sequence and structure similarities with the chymosin-sensitive linkage surrounding the Phe-Met/Ile bond of κ-caseins. In all these proteins, this linkage is observed within an exposed β-strand-like structure, as also predicted for κ-caseins. The structure of one of these fragments, included in glutamine synthetase, particularly superimposes well with the conformation observed for a chymosin inhibitor (CP-113972) within the complex it forms with chymosin and can be similarly accommodated by specificity pockets within the enzyme substrate binding cleft. The effect of the enzyme activity of chymosin was thus tested on glutamine synthetase. Chymosin cut the latter at the Phe-Met linkage, suggesting that this system may locally resemble the κ-casein/chymosin complex.     

Maltotriose Utilization by Industrial Saccharomyces Strains: Characterization of a New Member of the α-Glucoside Transporter Family

Maltotriose utilization by Saccharomyces cerevisiae and closely related yeasts is important to industrial processes based on starch hydrolysates, where the trisaccharide is present in significant concentrations and often is not completely consumed. We undertook an integrated study to better understand maltotriose metabolism in a mixture with glucose and maltose. Physiological data obtained for a particularly fast-growing distiller's strain (PYCC 5297) showed that, in contrast to what has been previously reported for other strains, maltotriose is essentially fermented. The respiratory quotient was, however, considerably higher for maltotriose (0.36) than for maltose (0.16) or glucose (0.11). To assess the role of transport in the sequential utilization of maltose and maltotriose, we investigated the presence of genes involved in maltotriose uptake in the type strain of Saccharomyces carlsbergensis (PYCC 4457). To this end, a previously constructed genomic library was used to identify maltotriose transporter genes by functional complementation of a strain devoid of known maltose transporters. One gene, clearly belonging to the MAL transporter family, was repeatedly isolated from the library. Sequence comparison showed that the novel gene (designated MTY1) shares 90% and 54% identity with MAL31 and AGT1, respectively. However, expression of Mty1p restores growth of the S. cerevisiae receptor strain on both maltose and maltotriose, whereas the closely related Mal31p supports growth on maltose only and Agt1p supports growth on a wider range of substrates, including maltose and maltotriose. Interestingly, Mty1p displays higher affinity for maltotriose than for maltose, a new feature among all the α-glucoside transporters described so far.     

Isolation and Characterization of a “phiKMV-Like” Bacteriophage and Its Therapeutic Effect on Mink Hemorrhagic Pneumonia

The objective of this study was to investigate the potential of using phages as a therapy against hemorrhagic pneumonia in mink both in vitro and in vivo. Five Pseudomonas aeruginosa (P. aeruginosa) strains were isolated from lungs of mink with suspected hemorrhagic pneumonia and their identity was confirmed by morphological observation and 16S rDNA sequence analysis. Compared to P. aeruginosa strains isolated from mink with hemorrhagic pneumonia in 2002, these isolates were more resistant to antibiotics selected. A lytic phage vB_PaeP_PPA-ABTNL (PPA-ABTNL) of the Podoviridae family was isolated from hospital sewage using a P. aeruginosa isolate as host, showing broad host range against P. aeruginosa. A one-step growth curve analysis of PPA-ABTNL revealed eclipse and latent periods of 20 and 35 min, respectively, with a burst size of about 110 PFU per infected cell. Phage PPA-ABTNL significantly reduced the growth of P. aeruginosa isolates in vitro. The genome of PPA-ABTNL was 43,227 bp (62.4% G+C) containing 54 open reading frames and lacked regions encoding known virulence factors, integration-related proteins and antibiotic resistance determinants. Genome architecture analysis showed that PPA-ABTNL belonged to the “phiKMV-like Viruses” group. A repeated dose inhalational toxicity study using PPA-ABTNL crude preparation was conducted in mice and no significantly abnormal histological changes, morbidity or mortality were observed. There was no indication of any potential risk associated with using PPA-ABTNL as a therapeutic agent. The results of a curative treatment experiment demonstrated that atomization by ultrasonic treatment could efficiently deliver phage to the lungs of mink and a dose of 10 multiplicity of infection was optimal for treating mink hemorrhagic pneumonia. Our work demonstrated the potential for phage to fight P. aeruginosa involved in mink lung infections when administered by means of ultrasonic nebulization.     

Detection and Quantification of Dehalogenimonas and “Dehalococcoides” Populations via PCR-Based Protocols Targeting 16S rRNA Genes

Members of the haloalkane dechlorinating genus Dehalogenimonas are distantly related to “Dehalococcoides” but share high homology in some variable regions of their 16S rRNA gene sequences. In this study, primers and PCR protocols intended to uniquely target Dehalococcoides were reevaluated, and primers and PCR protocols intended to uniquely target Dehalogenimonas were developed and tested. Use of the genus-specific primers revealed the presence of both bacterial groups in groundwater at a Louisiana Superfund site.“Dehalococcoides” strains are the only bacteria presently known to reductively dehalogenate the carcinogen vinyl chloride (10-12, 17, 22), and DNA-based approaches have been widely applied to detect and quantify these bacteria in mixed cultures and environmental samples (1, 3, 4, 6, 7, 13, 15, 16, 20). As recently reported, Dehalococcoides strains are the closest previously cultured phylogenetic relatives of Dehalogenimonas lykanthroporepellens strains BL-DC-8 and BL-DC-9^T (18, 23). The newly isolated Dehalogenimonas strains, which can reductively dehalogenate a variety of polychlorinated alkanes (e.g., 1,2,3-trichloropropane and 1,2-dichloroethane) but not chlorinated ethenes (e.g., tetrachloroethene and vinyl chloride), however, are only distantly related to Dehalococcoides, with 90% identity in 16S rRNA gene sequences. Research reported here was aimed at (i) reevaluating PCR primers and protocols previously reported as allowing specific detection of Dehalococcoides 16S rRNA gene sequences in light of the 16S rRNA gene sequences of the recently isolated Dehalogenimonas strains and (ii) designing and testing PCR primers and protocols that allow detection and quantification of Dehalogenimonas strains.     

Towards a better understanding of mouse and human diseases—International Mouse Phenotyping Consortium

<正>With the completion of the human genome sequence,the last several decades have seen the pursuit of gene function in vivo.The mouse is generally considered the best model animal for examining gene function because of its high productivity,pure genetic background,and degree of similarity to the human genome.With the development of sev-     

Purification and Characterization of a Novel α-Agarase from a Thalassomonas sp.

An agar-degrading Thalassomonas bacterium, strain JAMB-A33, was isolated from the sediment off Noma Point, Japan, at a depth of 230 m. A novel -agarase from the isolate was purified to homogeneity from cultures containing agar as a carbon source. The molecular mass of the purified enzyme, designated as agaraseA33, was 85 kDa on both SDS-PAGE and gel-filtration chromatography, suggesting that it is a monomer. The optimal pH and temperature for activity were about 8.5 and 45°C, respectively. The enzyme had a specific activity of 40.7 U/mg protein. The pattern of agarose hydrolysis showed that the enzyme is an endo-type -agarase, and the final main product was agarotetraose. The enzyme degraded not only agarose but also agarohexaose, neoagarohexaose, and porphyran.     

Characterization and comparison of thermostability of purified β-glucosidases from a mesophilic Aureobasidium pullulans and a thermophilic Thermoascus aurantiacus

The thermophilic fungus Thermoascus aurantiacus 179-5 and the mesophilic Aureobasidium pullulans ER-16 were cultivated in corn-cob by solid state fermentation for β-glucosidase production. After fermentation both enzymes were purified. The β-glucosidases produced by the strains A. pullulans and T. aurantiacus were most active at pH 4.0–4.5 and 4.5, with apparent optimum temperatures at 80 and 75 °C, respectively. Surprisingly, the enzyme produced by the mesophilic A. pullulans was stable over a wider range of pH (4.5–9.5 against 4.5–6.5) and more thermostable (98% after 1 h at 75 °C against 98% after 1 h at 70 °C) than the enzyme from the thermophilic T. aurantiacus. The t_(1/2) at 80 °C were 90 and 30 min for A. pullulans and T. aurantiacus, respectively. β-Glucosidase thermoinactivation followed first-order kinetics and the energies of denaturation were 414 and 537 kJ mol⁻¹ for T. aurantiacus and A. pullulans, respectively. The result showed that β-glucosidase obtained from the mesophilic A. pullulans is more stable than that obtained from the thermophilic T. aurantiacus.     

Molecular and Biochemical Characterization of a β-Fructofuranosidase from Xanthophyllomyces dendrorhous

An extracellular β-fructofuranosidase from the yeast Xanthophyllomyces dendrorhous was characterized biochemically, molecularly, and phylogenetically. This enzyme is a glycoprotein with an estimated molecular mass of 160 kDa, of which the N-linked carbohydrate accounts for 60% of the total mass. It displays optimum activity at pH 5.0 to 6.5, and its thermophilicity (with maximum activity at 65 to 70°C) and thermostability (with a T₅₀ in the range 66 to 71°C) is higher than that exhibited by most yeast invertases. The enzyme was able to hydrolyze fructosyl-β-(2→1)-linked carbohydrates such as sucrose, 1-kestose, or nystose, although its catalytic efficiency, defined by the k_cat/K_m ratio, indicates that it hydrolyzes sucrose approximately 4.2 times more efficiently than 1-kestose. Unlike other microbial β-fructofuranosidases, the enzyme from X. dendrorhous produces neokestose as the main transglycosylation product, a potentially novel bifidogenic trisaccharide. Using a 41% (wt/vol) sucrose solution, the maximum fructooligosaccharide concentration reached was 65.9 g liter⁻¹. In addition, we isolated and sequenced the X. dendrorhous β-fructofuranosidase gene (Xd-INV), showing that it encodes a putative mature polypeptide of 595 amino acids and that it shares significant identity with other fungal, yeast, and plant β-fructofuranosidases, all members of family 32 of the glycosyl-hydrolases. We demonstrate that the Xd-INV could functionally complement the suc2 mutation of Saccharomyces cerevisiae and, finally, a structural model of the new enzyme based on the homologous invertase from Arabidopsis thaliana has also been obtained.The basidiomycetous yeast Xanthophyllomyces dendrorhous (formerly Phaffia rhodozyma) produces astaxanthin (3-3′-dihydroxy-β,β-carotene-4,4 dione [17, 25]). Different industries have displayed great interest in this carotenoid pigment due to its attractive red-orange color and antioxidant properties, which has intensified the molecular and genetic study of this yeast. As a result, several genes involved in the astaxanthin biosynthetic pathway have been cloned and/or characterized, as well as some other genes such as those encoding actin (60), glyceraldehyde-3-phosphate dehydrogenase (56), endo-β-1,3-glucanase, and aspartic protease (4). In terms of the use of carbon sources, a β-amylase (9), and an α-glucosidase (33) with glucosyltransferase activity (12), as well as a yeast cell-associated invertase (41), have also been reported.Invertases or β-fructofuranosidases (EC 3.2.1.26) catalyze the release of β-fructose from the nonreducing termini of various β-d-fructofuranoside substrates. Yeast β-fructofuranosidases have been widely studied, including that of Saccharomyces cerevisiae (11, 14, 45, 46), Schizosaccharomyces pombe (36), Pichia anomala (40, 49), Candida utilis (5, 8), or Schwanniomyces occidentalis (2). They generally exhibit strong similarities where sequences are available, and they have been classified within family 32 of the glycosyl-hydrolases (GH) on the basis of their amino acid sequences. The catalytic mechanism proposed for the S. cerevisiae enzyme implies that an aspartate close to the N terminus (Asp-23) acts as a nucleophile, and a glutamate (Glu-204) acts as the acid/base catalyst (46). In addition, the three-dimensional structures of some enzymes in this family have been resolved, such as that of an exoinulinase from Aspergillus niger (var. awamori; 37) and the invertase from Arabidopsis thaliana (55).As well as hydrolyzing sucrose, β-fructofuranosidases from microorganisms may also catalyze the synthesis of short-chain fructooligosaccharides (FOS), in which one to three fructosyl moieties are linked to the sucrose skeleton by different glycosidic bonds depending on the source of the enzyme (3, 52). FOS are one of the most promising ingredients for functional foods since they act as prebiotics (44), and they exert a beneficial effect on human health, participating in the prevention of cardiovascular diseases, colon cancer, or osteoporosis (28). Currently, Aspergillus fructosyltransferase is the main industrial producer of FOS (15, 52), producing a mixture of FOS with an inulin-type structure, containing β-(2→1)-linked fructose-oligomers (¹F-FOS: 1-kestose, nystose, or ¹F-fructofuranosylnystose). However, there is certain interest in the development of novel molecules that may have better prebiotic and physiological properties. In this context, β-(2→6)-linked FOS, where this link exits between two fructose units (⁶F-FOS: 6-kestose) or between fructose and the glucosyl moiety (⁶G-FOS: neokestose, neonystose, and neofructofuranosylnystose), may have enhanced prebiotic properties compared to commercial FOS (29, 34, 54). The enzymatic synthesis of 6-kestose and other related β-(2→6)-linked fructosyl oligomers has already been reported in yeasts such as S. cerevisiae (11) or Schwanniomyces occidentalis (2) and in fungi such as Thermoascus aurantiacus (26) or Sporotrichum thermophile (27). However, the production of FOS included in the ⁶G-FOS series has not been widely reported in microorganisms, probably because they are not generally produced (2, 15) or because they represent only a minor biosynthetic product (e.g., with baker''s yeast invertase) (11). Most research into neo-FOS production has been carried out with Penicillium citrinum cells (19, 31, 32, 39). In this context, neokestose is the main transglycosylation product accumulated by whole X. dendrorhous cells from sucrose (30), although the enzyme responsible for this reaction remained uncharacterized.Here, we describe the molecular, phylogenetic, and biochemical characterization of an extracellular β-fructofuranosidase from X. dendrorhous. Kinetic studies of its hydrolytic activity were performed using different substrates, and we investigated its fructosyltransferase capacity. The functionality of the gene analyzed was verified through its heterologous expression, and a structural model of this enzyme based on the homologous invertase from A. thaliana has also been obtained.     

Revised Systematics of Holospora-Like Bacteria and Characterization of “Candidatus Gortzia infectiva”, a Novel Macronuclear Symbiont of Paramecium jenningsi

The genus Holospora (Rickettsiales) includes highly infectious nuclear symbionts of the ciliate Paramecium with unique morphology and life cycle. To date, nine species have been described, but a molecular characterization is lacking for most of them. In this study, we have characterized a novel Holospora-like bacterium (HLB) living in the macronuclei of a Paramecium jenningsi population. This bacterium was morphologically and ultrastructurally investigated in detail, and its life cycle and infection capabilities were described. We also obtained its 16S rRNA gene sequence and developed a specific probe for fluorescence in situ hybridization experiments. A new taxon, “Candidatus Gortzia infectiva”, was established for this HLB according to its unique characteristics and the relatively low DNA sequence similarities shared with other bacteria. The phylogeny of the order Rickettsiales based on 16S rRNA gene sequences has been inferred, adding to the available data the sequence of the novel bacterium and those of two Holospora species (Holospora obtusa and Holospora undulata) characterized for the purpose. Our phylogenetic analysis provided molecular support for the monophyly of HLBs and showed a possible pattern of evolution for some of their features. We suggested to classify inside the family Holosporaceae only HLBs, excluding other more distantly related and phenotypically different Paramecium endosymbionts.     

Isolation and Properties of Bacillus subtilis Strains Lysogenized by a Clear Plaque Mutant of Bacteriophage φ105

A clear plaque mutant of the temperate Bacillus phage phi105 lysogenized a small fraction of infected cells forming an integrated prophage at or near the normal phi105 insertion site. These lysogens exhibited a spontaneous induction rate approximately 1,000-fold lower than wild type and were noninducible (ind(-)) by mitomycin C. Prophage was induced, however, when competent cultures were incubated with transforming DNA. The ind(-) phenotype could not be attributed solely to the clear plaque mutation and appears to involve a cell-specific factor. Lysogenization by the clear plaque mutant, in contrast to wild-type phage, did not cause a marked reduction in transformation efficiency.     

Unusual Fermentative, Gram-Negative Bacilli Isolated from Clinical Specimens: I. Characterization of Erwinia Strains of the “lathyri-herbicola Group”

Five strains of gram-negative, yellow chromogenic bacilli were recovered from clinical specimens which fit the characteristics of the "lathyri-herbicola group" within the genus Erwinia. The strains were facultatively anaerobic, fermentative, anaerogenic bacilli with peritrichous flagella which grew at 37 C, reduced nitrate to nitrite, and failed to produce oxidase, pectinase, arginine dihydrolase, and decarboxylases for lysine and ornithine. Aggregations of bacteria (symplasmata) were observed in the syneresis water of slant cultures, and analogous granular aggregates and biconvex, spindle-shaped bodies developed in colonies on plate cultures. Awareness of these characteristics should result in more frequent identification of Erwinia species from human sources.     

Identification and Molecular Characterization of a Novel Type of α-galactosidase from Pyrococcus furiosus

An α-galactosidase gene from Pyrococcus furiosus was identified, cloned and functionally expressed in Escherichia coli. It is the first α-galactosidase from a hyperthermophilic archaeon described to date. The gene encodes a unique amino acid sequence compared to other α-galactosidases. Highest homology was found with α-amylases classified in family 57 of glycoside hydrolases. The 364 amino acid protein had a calculated mass of 41.6 kDa. The recombinant α-galactosidase specifically catalyzed the hydrolysis of para-nitrophenyl-α-galactopyranoside, and to some extent that of melibiose and raffinose. The enzyme proved to be an extremely thermo-active and thermostable α-galactosidase with a temperature optimum of 115°C and a half-life time of 15 hours at 100°C. The pH optimum is between 5.0 and 5.5. Sequence analysis showed four conserved carboxylic residues. Site-directed mutagenesis was applied to identify the potential catalytic residues. Glu117Ala showed decreased enzyme activity, which could be rescued by the addition of azide or formate. It is concluded that glutamate 117 is the catalytic nucleophile, whereas the acid/base catalyst remains to be identified.