Bacteroides sp. Strain D8, the First Cholesterol-Reducing Bacterium Isolated from Human Feces

The microbial community in the human colon contains bacteria that reduce cholesterol to coprostanol, but the species responsible for this conversion are still unknown. We describe here the first isolation and characterization of a cholesterol-reducing bacterium of human intestinal origin. Strain D8 was isolated from a 10⁻⁸ dilution of a fresh stool sample provided by a senior male volunteer with a high capacity to reduce luminal cholesterol to coprostanol. Cholesterol-to-coprostanol conversion by strain D8 started on the third day, while cells were in stationary phase, and was almost complete after 7 days. Intermediate products (4-cholesten-3-one and coprostanone) were occasionally observed, suggesting an indirect pathway for cholesterol-to-coprostanol conversion. Resting-cell assays showed that strain D8 could reduce 1.5 μmol of cholesterol/mg bacterial protein/h. Strain D8 was a gram-negative, non-spore-forming, rod-shaped organism identified as a member of the genus Bacteroides closely related to Bacteroides vulgatus, based on its morphological and biochemical characteristics. The 16S rRNA gene sequence of strain D8 was most similar (>99.5%) to those of two isolates of the recently described species Bacteroides dorei. Phylogenetic tree construction confirmed that Bacteroides sp. strain D8 clustered within an independent clade together with these B. dorei strains. Nevertheless, no cholesterol-reducing activity could be detected in cultures of the B. dorei type strain. Based on Bacteroides group-specific PCR-temporal temperature gradient gel electrophoresis, there was no correlation between the presence of a band comigrating with the band of Bacteroides sp. strain D8 and cholesterol conversion in 11 human fecal samples, indicating that this strain is unlikely to be mainly responsible for cholesterol conversion in the human population.     

Termite Hindguts and the Ecology of Microbial Communities in the Sequencing Age

Advances in high‐throughput nucleic acid sequencing have improved our understanding of microbial communities in a number of ways. Deeper sequence coverage provides the means to assess diversity at the resolution necessary to recover ecological and biogeographic patterns, and at the same time single‐cell genomics provides detailed information about the interactions between members of a microbial community. Given the vastness and complexity of microbial ecosystems, such analyses remain challenging for most environments, so greater insight can also be drawn from analysing less dynamic ecosystems. Here, we outline the advantages of one such environment, the wood‐digesting hindgut communities of termites and cockroaches, and how it is a model to examine and compare both protist and bacterial communities. Beyond the analysis of diversity, our understanding of protist community ecology will depend on using statistically sound sampling regimes at biologically relevant scales, transitioning from discovery‐based to experimental ecology, incorporating single‐cell microbiology and other data sources, and continued development of analytical tools.     

Methane Oxidation in Termite Hindguts: Absence of Evidence and Evidence of Absence

A steep oxygen gradient and the presence of methane render the hindgut internal periphery of termites a potential habitat for aerobic methane-oxidizing bacteria. However, methane emissions of various termites increased, if at all, only slightly when termites were exposed to an anoxic (nitrogen) atmosphere, and ¹⁴CH₄ added to the air headspace over live termites was not converted to ¹⁴CO₂. Evidence for the absence of methane oxidation in living termites was corroborated by the failure to detect pmoA, the marker gene for particulate methane monooxygenase, in hindgut DNA extracts of all termites investigated. This adds robustness to our concept of the degradation network in the termite hindgut and eliminates the gut itself as a potential sink of this important greenhouse gas.     

Physiology and Nutrition of Treponema primitia, an H2/ CO2-Acetogenic Spirochete from Termite Hindguts

Treponema primitia strains ZAS-1 and ZAS-2, the first spirochetes to be isolated from termite hindguts (J. R. Leadbetter, T. M. Schmidt, J. R. Graber, and J. A. Breznak, Science 283:686-689, 1999), were examined for nutritional, physiological, and biochemical properties relevant to growth and survival in their natural habitat. In addition to using H₂ plus CO₂ as substrates, these strains were capable of homoacetogenic growth on mono- and disaccharides and (in the case of ZAS-2) methoxylated benzenoids. Cells were also capable of mixotrophic growth (i.e., simultaneous utilization of H₂ and organic substrates). Cell extracts of T. primitia possessed enzyme activities of the Wood/Ljungdahl (acetyl coenzyme A) pathway of acetogenesis, including tetrahydrofolate-dependent enzymes of the methyl group-forming branch. However, a folate compound was required in the medium for growth. ZAS-1 and ZAS-2 growing on H₂ plus CO₂ displayed H₂ thresholds of 650 and 490 ppmv, respectively. Anoxic cultures of ZAS-1 and ZAS-2 maintained growth after the addition of as much as 0.5% (vol/vol) O₂ to the headspace atmosphere. Cell extracts exhibited NADH and NADPH peroxidase and NADH oxidase activities but neither catalase nor superoxide dismutase activity. Results indicate that (i) T. primitia is able to exploit a variety of substrates derived from the food of its termite hosts and in so doing contributes to termite nutrition via acetogenesis, (ii) in situ growth of T. primitia is likely dependent on secretion of a folate compound(s) by other members of the gut microbiota, and (iii) cells possess enzymatic adaptations to oxidative stress, which is likely to be encountered in peripheral regions of the termite hindgut.     

Bacteroides pectinophilus sp. nov. and Bacteroides galacturonicus sp. nov.: two pectinolytic bacteria from the human intestinal tract

Studies on the physiological characteristics of two obligately anaerobic, rod-shaped bacteria from the human intestinal tract indicated that the organisms represented two previously undescribed species of Bacteroides, for which we propose the names Bacteroides pectinophilus (type strain, N3) and Bacteroides galacturonicus (type strain, N6). Both strains were pectinophilic; that is, they utilized as fermentable substrates for growth only pectin and a few related compounds. The two species differed significantly from each other in guanine plus cytosine content of the DNA, in substrate utilization patterns, and in other phenotypic characteristics. Both species deesterified pectin by means of an extracellular pectinesterase (EC 3.1.1.11) activity. Polygalacturonate (the main component of deesterified pectin) was depolymerized extracellularly with formation of unsaturated products by both species. The depolymerizing activity required Ca2+, functioned at a higher rate when polygalacturonate was the substrate as compared with pectin, and had an alkaline pH optimum. These data, as well as viscosity decrease studies and identification of products formed from polygalacturonate, indicated that the extracellular depolymerizing activity of either species was characteristic of an exopectate (exopolygalacturonate) lyase. The exopectate lyase activity had an unusual action pattern that resulted in terminal cleavage of unsaturated trigalacturonic acid units from polygalacturonate. An unsaturated trimer was the major product that accumulated in cell-free reaction mixtures, where it was not cleaved further. Growing cells of both Bacteroides species released the exopectate lyase into the external environment by processes that did not involve cell lysis to any significant extent.(ABSTRACT TRUNCATED AT 250 WORDS)     

Bacteroides pectinophilus sp. nov. and Bacteroides galacturonicus sp. nov.: two pectinolytic bacteria from the human intestinal tract.

Studies on the physiological characteristics of two obligately anaerobic, rod-shaped bacteria from the human intestinal tract indicated that the organisms represented two previously undescribed species of Bacteroides, for which we propose the names Bacteroides pectinophilus (type strain, N3) and Bacteroides galacturonicus (type strain, N6). Both strains were pectinophilic; that is, they utilized as fermentable substrates for growth only pectin and a few related compounds. The two species differed significantly from each other in guanine plus cytosine content of the DNA, in substrate utilization patterns, and in other phenotypic characteristics. Both species deesterified pectin by means of an extracellular pectinesterase (EC 3.1.1.11) activity. Polygalacturonate (the main component of deesterified pectin) was depolymerized extracellularly with formation of unsaturated products by both species. The depolymerizing activity required Ca2+, functioned at a higher rate when polygalacturonate was the substrate as compared with pectin, and had an alkaline pH optimum. These data, as well as viscosity decrease studies and identification of products formed from polygalacturonate, indicated that the extracellular depolymerizing activity of either species was characteristic of an exopectate (exopolygalacturonate) lyase. The exopectate lyase activity had an unusual action pattern that resulted in terminal cleavage of unsaturated trigalacturonic acid units from polygalacturonate. An unsaturated trimer was the major product that accumulated in cell-free reaction mixtures, where it was not cleaved further. Growing cells of both Bacteroides species released the exopectate lyase into the external environment by processes that did not involve cell lysis to any significant extent.(ABSTRACT TRUNCATED AT 250 WORDS)     

Molecular cloning of the lactose-metabolizing genes from Streptococcus lactis.

Restriction endonucleases and agarose gel electrophoresis were used to analyze plasmid pLM2001, which is required for lactose metabolism by Streptococcus lactis LM0232. The enzymes XhoI, SstI, BamHI, and KpnI each cleaved the plasmid into two fragments, whereas EcoRI and BglII cleaved the plasmid into seven and five fragments, respectively. Sizing of fragments and multiple digestions allowed construction of a composite restriction map. The KpnI fragments of pLM2001 were cloned into the KpnI cleavage site of the vector plasmid pDB101. A recombinant plasmid (pSH3) obtained from a lactose-fermenting, erythromycin-resistant (Lac+ Eryr) transformant of Streptococcus sanguis Challis was analyzed by enzyme digestion and agarose gel electrophoresis. Plasmid pSH3 contained 7 of the 11 KpnI-HindIII fragments from pLM2001 and 5 of the 7 fragments from pDB101. It was determined that a 23-kilobase (kb) KpnI-generated fragment from pLM2001 had been cloned into pDB101 with deletion of part of the vector plasmid. The recombinant plasmid could be transformed with high frequency into several Lac- strains of S. sanguis, conferring the ability to ferment lactose and erythromycin resistance. The presence of pSH3 allowed a strain deficient in Enzyme IIlac, Factor IIIlac, and phospho-beta-galactosidase of the lactose phosphoenolpyruvate-dependent phosphotransferase system to efficiently ferment lactose. Under conditions designed to maximize curing of plasmid DNA with acriflavin, no Lac- derivatives could be isolated from cells transformed with pSH3. Seven of the 40 Lac+ colonies isolated after 10 transfers in acriflavin were shown to be sensitive to erythromycin and did not appear to harbor plasmid DNA.(ABSTRACT TRUNCATED AT 250 WORDS)     

Reconstitution of phosphate-linked antiport from Streptococcus lactis

Membrane protein solubilized by octyl-beta-D-glucopyranoside in the presence of dispersed phospholipid was incubated with bath-sonicated liposomes and additional detergent. The proteoliposomes formed on dilution showed transport and exchange properties consistent with a reconstitution of phosphate:sugar 6-phosphate antiport. Thus, phosphate self-exchange was found only when protein from induced cells was used; this exchange was blocked by a sugar 6-phosphate, not by a sugar 1-phosphate; and proteoliposomes supported an accumulation of 2-deoxyglucose 6-phosphate with no added source of energy. Solubilization and reconstitution of protein was most effective when performed in the presence of gram-positive phospholipids.     

Isolation of a Cellulolytic Bacteroides sp. from Human Feces

An anaerobic cellulolytic bacterium, identified as a Bacteroides sp., was present in 10^-8 g of feces from only one of five human subjects.     

Differentiation of Streptococcus lactis var. maltigenes from Other Lactic Streptococci

Strains of lactic streptococci isolated from samples of raw milk which had developed a malty aroma were subjected to the cultural, physiological, and serological tests commonly employed in the classification of streptococci. None of the strains could be differentiated from Streptococcus lactis by these tests. Resting cells of strains which produced an organoleptically detectable malty aroma when cultured in milk were usually found to possess an active α-ketoacid decarboxylase, indicating the presence of the mechanism responsible for the characteristic aroma production. This decarboxylase activity was either weak or nonexistent in the nonmalty strains, and no activity was detected in known strains of S. lactis, S. cremoris, or S. diacetilactis. The malty strains usually produced higher acidities in milk than did the nonmalty strains, and, in most instances, they developed a granular type of growth sediment in broth, as opposed to a viscid sediment. Many of them gave weakly positive Voges-Proskauer tests in glucose broth with or without added citrate and appeared to be somewhat more resistant to nisin than the nonmalty strains.     

Prophage-Cured Derivatives of Streptococcus lactis and Streptococcus cremoris

Prophage curing was achieved in Streptococcus lactis and Streptococcus cremoris, and the cured derivatives were shown to be indicators for their temperate bacteriophages. Relysogenization of these cured derivatives completed the first formal demonstration of the lysogenic state in lactic streptococci.     

Ornithine transport and exchange in Streptococcus lactis.

Resting cells of Streptococcus lactis 133 appeared to accumulate [14C]ornithine to a high concentration in the absence of an exogenous energy source. However, analysis of intracellular amino acid pool constituents and results of transport experiments revealed that the accumulation of ornithine represented a homoexchange between extracellular [14C]ornithine and unlabeled ornithine in the cell. The energy-independent exchange of ornithine was not inhibited by proton-conducting uncouplers or by metabolic inhibitors. Intracellular [14C]ornithine was retained by resting cells after suspension in a buffered medium. However, addition of unlabeled ornithine to the suspension elicited rapid exit of labeled amino acid. The initial rate of exit of [14C]ornithine was dependent on the concentration of unlabeled ornithine in the medium, but this accelerative exchange diffusion process caused no net loss of amino acid. By contrast, the presence of a fermentable energy source caused a rapid expulsion of and net decrease in the concentration of intracellular ornithine. Kinetic analyses of amino acid transport demonstrated competitive inhibition between lysine and ornithine, and data obtained by two-dimensional thin-layer chromatography established the heteroexchange of these basic amino acids. The effects of amino acids and of ornithine analogs on both entry and exit of [14C]ornithine have been examined. The data suggest that a common carrier mediates the entry and exchange of lysine, arginine, and ornithine in cells of S. lactis.     

Transformation of Streptococcus sanguis Challis with Streptococcus lactis plasmid DNA.

Streptococcus lactis plasmid DNA, which is required for the fermentation of lactose (plasmid pLM2001), and a potential streptococcal cloning vector plasmid (pDB101) which confers resistance to erythromycin were evaluated by transformation into Streptococcus sanguis Challis. Plasmid pLM2001 transformed lactose-negative (Lac-) mutants of S. sanguis with high efficiency and was capable of conferring lactose-metabolizing ability to a mutant deficient in Enzyme IIlac, Factor IIIlac, and phospho-beta-galactosidase of the lactose phosphoenolpyruvate-phosphotransferase system. Plasmid pDB101 was capable of high-efficiency transformation of S. sanguis to antibiotic resistance, and the plasmid could be readily isolated from transformed strains. However, when 20 pLM2001 Lac+ transformants were analyzed by a variety of techniques for the presence of plasmids, none could be detected. In addition, attempts to cure the Lac+ transformants by treatment with acriflavin were unsuccessful. Polyacrylamide gel electrophoresis was used to demonstrate that the transformants had acquired a phospho-beta-galactosidase characteristic of that normally produced by S. lactis and not S. sanguis. It is proposed that the genes required for lactose fermentation may have become stabilized in the transformants due to their integration into the host chromosome. The efficient transformation into and expression of pLM2001 and pDB101 genes in S. sanguis provides a model system which could allow the development of a system for cloning genes from dairy starter cultures into S. sanguis to examine factors affecting their expression and regulation.     

Hydrogen-Dependent Oxygen Reduction by Homoacetogenic Bacteria Isolated from Termite Guts

Although homoacetogenic bacteria are generally considered to be obligate anaerobes, they colonize the intestinal tracts of termites and other environments that are not entirely anoxic in space or time. In this study, we investigated how homoacetogenic bacteria isolated from the hindguts of various termites respond to the presence of molecular oxygen. All strains investigated formed growth bands in oxygen gradient agar tubes under a headspace of H₂-CO₂. The position of the bands coincided with the oxic-anoxic interface and depended on the O₂ partial pressure in the headspace; the position of the bands relative to the meniscus remained stable for more than 1 month. Experiments with dense cell suspensions, performed with Clark-type O₂ and H₂ electrodes, revealed a large capacity for H₂-dependent oxygen reduction in Sporomusa termitida and Sporomusa sp. strain TmAO3 (149 and 826 nmol min⁻¹ mg of protein⁻¹, respectively). Both strains also reduced O₂ with endogenous reductants, albeit at lower rates. Only in Acetonema longum did the basal rates exceed the H₂-dependent rates considerably (181 versus 28 nmol min⁻¹ mg of protein)⁻¹). Addition of organic substrates did not stimulate O₂ consumption in any of the strains. Nevertheless, reductive acetogenesis by cell suspensions of strain TmAO3 was inhibited even at the lowest O₂ fluxes, and growth in nonreduced medium occurred only after the bacteria had rendered the medium anoxic. Similar results were obtained with Acetobacterium woodii, suggesting that the results are not unique to the strains isolated from termites. We concluded that because of their tolerance to temporary exposure to O₂ at low partial pressures (up to 1.5 kPa in the case of strain TmAO3) and because of their large capacity for O₂ reduction, homoacetogens can reestablish conditions favorable for growth by actively removing oxygen from their environment.     

Purification and characterization of mucopolysaccharidase from an oral strain of Bacteroides sp.

A mucopolysaccharidase in the cell extract of an oral strain of Bacteroides sp. was purified to homogeneity by ammonium sulfate precipitation, DEAE-cellulose column chromatography, gel filtration on Sephadex G-200, and isoelectric focusing. Specific activity increased 110-fold and recovery was 2%. The molecular weight was determined to be 89,000 by gel filtration, and the isoelectric point was 7.0. The optimum pH for the activity was 6.5. The enzyme was inactivated by heating at 60 degrees C for 5 min. The purified mucopolysaccharidase degraded hyaluronic acid more rapidly than chondroitin and chondroitin sulfate A and C. However, it had no activity against chondroitin sulfate B, heparin, and heparan sulfate. Since unsaturated disaccharides were derived from the enzyme substrate, this enzyme was considered to be a mucopolysaccharide lyase.     

Membrane H+ conductance of Streptococcus lactis.

Membrane conductance to H+ was measured in the anaerobic bacterium Streptoccus lactis by a pulse technique employing a low driving force (0.1 pH unit; 6 mV). Over the pH range of 3.7 to 8.5, a constant value for passive H+ conductance was observed, corresponding to 0.2 mumol of H+/s per p/ unit per g, dry weight (1.6 microS/cm2 of surface area). The pH insensitivity of this low basal H+ conductance supports the idea that a circulation of protons can mediate highly efficiency engery transductions across the membranes of bacteria.