Susan B. Leschine

Clostridium phytofermentans sp. nov., a cellulolytic mesophile from forest soil.

An obligately anaerobic, mesophilic, cellulolytic bacterium, strain ISDgT, was isolated from forest soil. Cells of this isolate stained Gram-negative, despite possessing a Gram-positive cell-wall ultrastructure, and were motile, straight rods that formed spherical terminal spores that swelled the sporangium. Cellulose, pectin, polygalacturonic acid, starch, xylan, arabinose, cellobiose, fructose, galactose, gentiobiose, glucose, lactose, maltose, mannose, ribose and xylose supported growth. The major end products of fermentation were ethanol, acetate, CO2 and H2; formate and lactate were minor products. The optimum temperature for growth was 35-37 degrees C. Phylogenetic analyses based on 16S rRNA sequence comparisons showed that strain ISDgT was related to a group of anaerobes that included Clostridium herbivorans, Clostridium polysaccharolyticum and Clostridium populeti. The G+C content of this strain was 35.9 mol%. On the basis of numerous genotypic and phenotypic differences between strain ISDgT and its close relatives, strain ISDgT is proposed as a novel species in the genus Clostridium, for which the name Clostridium phytofermentans sp. nov. is proposed. The type strain is ISDgT (= ATCC 700394T).

Spirochaeta caldaria sp. nov., a thermophilic bacterium that enhances cellulose degradation by Clostridium thermocellum

Two strains of obligately anaerobic, thermophilic spirochetes were isolated from cyanobacterial mat samples collected at freshwater hot springs in Oregon and Utah, USA. The isolates grew optimally between 48° and 52°C, and did not grow at 25° or 60°C. Both strains fermented various pentoses, hexoses, and disaccharides. Amino acids or cellulose did not serve as fermentable substrates for growth. H2, CO2, acetate, and lactate were end products of d-glucose fermentation. On the basis of physiological characteristics, guanine + cytosine content of DNA, and comparisons of 16S ribosomal RNA sequences, it was concluded that the two isolates were representatives of a novel species of Spirochaeta for which the name Spirochaeta caldaria is proposed. One of the two strains was grown in coculture with a thermophilic cellulolytic bacterium (Clostridium thermocellum) in a medium containing cellulose as the only fermentable substrate. In the coculture cellulose was broken down at a faster rate than in the clostridial monoculture. The results are consistent with the suggestion that interactions between cellulolytic bacteria and non-cellulolytic spirochetes enhance cellulose breakdown in natural environments in which cellulose-containing plant material is biodegraded.

Involvement of a bacterial microcompartment in the metabolism of fucose and rhamnose by Clostridium phytofermentans.

Background Clostridium phytofermentans, an anaerobic soil bacterium, can directly convert plant biomass into biofuels. The genome of C. phytofermentans contains three loci with genes encoding shell proteins of bacterial microcompartments (BMC), organelles composed entirely of proteins. Methodology and Principal Findings One of the BMC loci has homology to a BMC-encoding locus implicated in the conversion of fucose to propanol and propionate in a human gut commensal, Roseburia inulinivorans. We hypothesized that it had a similar role in C. phytofermentans. When C. phytofermentans was grown on fucose, the major products identified were ethanol, propanol and propionate. Transmission electron microscopy of fucose- and rhamnose-grown cultures revealed polyhedral structures, presumably BMCs. Microarray analysis indicated that during growth on fucose, operons coding for the BMC locus, fucose dissimilatory enzymes, and an ATP-binding cassette transporter became the dominant transcripts. These data are consistent with fucose fermentation producing a 1,2-propanediol intermediate that is further metabolized in the microcompartment encoded in the BMC locus. Growth on another deoxyhexose sugar, rhamnose, resulted in the expression of the same BMC locus and similar fermentation products. However, a different set of dissimilatory enzymes and transport system genes were induced. Quite surprisingly, growth on fucose or rhamnose also led to the expression of a diverse array of complex plant polysaccharide-degrading enzymes. Conclusions/Significance Based on physiological, genomic, and microarray analyses, we propose a model for the fermentation of fucose and rhamnose in C. phytofermentans that includes enzymes encoded in the same BMC locus. Comparative genomic analysis suggests that this BMC may be present in other clostridial species.

Clostridium hungatei sp. nov., a mesophilic, N2-fixing cellulolytic bacterium isolated from soil.

Two strains of obligately anaerobic, mesophilic, cellulolytic, N2-fixing, spore-forming bacteria were isolated from soil samples collected at two different locations near Amherst, MA, USA. Single cells of both strains were slightly curved rods that measured between 2 and 6 microm in length and approximately 0.5 microm in diameter. The spores were spherical, terminally located, distended the sporangium and measured 0.8-1.0 microm in diameter. The cells of both isolates (designated strain ADT and strain B3B) stained Gram-negative, but did not have a typical Gram-negative cell wall structure as demonstrated by transmission electron microscope analysis. The cells of both strains were motile with subpolarly inserted flagella and exhibited chemotactic behaviour towards cellobiose and D-glucose. Both strains fermented cellulose, xylan, cellobiose, cellodextrins, D-glucose, D-xylose, D-fructose, D-mannose and gentiobiose. In addition, strain B3B fermented L-arabinose. For both strains, fermentation products from cellulose were acetate, ethanol, H2 and CO2, as well as small amounts of lactate and formate. The G+C content of strain AD was 40 mol% and that of strain B3B was 42 mol%. Based on their morphological, physiological and phylogenetic characteristics, it was concluded that the two isolates are representatives of a novel species of Clostridium. The name Clostridium hungatei is proposed for the new species. The type strain of Clostridium hungatei sp. nov. is strain ADT (= ATCC 700212T).

Biological conversion assay using Clostridium phytofermentans to estimate plant feedstock quality.

BackgroundThere is currently considerable interest in developing renewable sources of energy. One strategy is the biological conversion of plant biomass to liquid transportation fuel. Several technical hurdles impinge upon the economic feasibility of this strategy, including the development of energy crops amenable to facile deconstruction. Reliable assays to characterize feedstock quality are needed to measure the effects of pre-treatment and processing and of the plant and microbial genetic diversity that influence bioconversion efficiency.ResultsWe used the anaerobic bacterium Clostridium phytofermentans to develop a robust assay for biomass digestibility and conversion to biofuels. The assay utilizes the ability of the microbe to convert biomass directly into ethanol with little or no pre-treatment. Plant samples were added to an anaerobic minimal medium and inoculated with C. phytofermentans, incubated for 3 days, after which the culture supernatant was analyzed for ethanol concentration. The assay detected significant differences in the supernatant ethanol from wild-type sorghum compared with brown midrib sorghum mutants previously shown to be highly digestible. Compositional analysis of the biomass before and after inoculation suggested that differences in xylan metabolism were partly responsible for the differences in ethanol yields. Additionally, we characterized the natural genetic variation for conversion efficiency in Brachypodium distachyon and shrub willow (Salix spp.).ConclusionOur results agree with those from previous studies of lignin mutants using enzymatic saccharification-based approaches. However, the use of C. phytofermentans takes into consideration specific organismal interactions, which will be crucial for simultaneous saccharification fermentation or consolidated bioprocessing. The ability to detect such phenotypic variation facilitates the genetic analysis of mechanisms underlying plant feedstock quality.

A halotolerantPlanococcus from Antarctic Dry Valley soil

A halotolerantPlanococcus (strain A4a) was isolated from saline Antarctic Dry Valley soil.Planococcus strain A4a grew over wide ranges of temperature (0°C−40°C) and NaCl concentrations (0–2.0M). When the NaCl concentration of the growth medium was increased, the total intracellular free amino acid concentration increased; however, the intracellular potassium concentration did not increase. This result suggested that intracellular free amino acids functioned as compatible solutes for growth ofPlanococcus strain A4a at elevated NaCl concentrations. The halotolerant and psychrotolerant nature ofPlanococcus strain A4a would appear to provide it with the capacity for growth in the saline Antarctic Dry Valley soil environment from which it was isolated.

Reversible control of biofilm formation by Cellulomonas spp. in response to nitrogen availability

The microbial degradation of cellulose contributes greatly to the cycling of carbon in terrestrial environments and feedbacks to the atmosphere, a process that is highly responsive to nitrogen inputs. Yet how key groups of cellulolytic microorganisms adaptively respond to the global conditions of nitrogen limitation and/or anthropogenic or climate nitrogen inputs is poorly understood. The actinobacterial genus Cellulomonas is of special interest because it incorporates the only species known to degrade cellulose aerobically and anaerobically. Furthermore, despite their inability to fix nitrogen, they are active decomposers in nitrogen-limited environments. Here we show that nitrogen limitation induced biofilm formation in Cellulomonas spp., a process that was coupled to carbon sequestration and storage in a curdlan-type biofilm matrix. The response was reversible and the curdlan matrix was solubilized and used as a carbon and energy source for biofilm dispersal once nitrogen sources became available. The biofilms attached strongly to cellulosic surfaces and, despite the growth limitation, produced cellulases and degraded cellulose more efficiently. The results show that biofilm formation is a competitive strategy for carbon and nitrogen acquisition and provide valuable insights linking nitrogen inputs to carbon sequestration and remobilization in terrestrial environments.

Ornithine dissimilation byTreponema denticola

Treponema denticola convertedl-ornithine, a product ofl-arginine catabolism, to putrescine via a decarboxylation reaction and to proline via a deamination reaction. Ornithine decarboxylation byT. denticola extracts was stimulated by pyridoxal 5′-phosphate. In the absence of pyridoxal 5′-phosphate, (NH4)2SO4-fractionated extracts converted ornithine to proline and ammonia. This activity was not stimulated by α-keto acids, nicotinamide adenine dinucleotide, reduced nicotinamide adenine dinucleotide or ADP. Neither ornithine δ-transaminase (l-ornithine: 2-oxoacid aminotransferase, EC 2.6.1.13) nor Δ1 reductase [l-proline: NAD(P) 5-oxidoreductase, EC 1.5.1.2.] activity was detectable in cell extracts. These results indicate that formation of proline from ornithine inT. denticola is catalyzed by an enzyme system analogous to the ornithine cyclase (deaminating) ofClostridium sporogenes. Exogenous ornithine inhibited the growth ofT. denticola. Thus, in addition to generating putrescine and proline, the ornithine dissimilatory pathways may serve to prevent accumulation of inhibitory concentrations of ornithine in the spirochetes environment.

A high-throughput biological conversion assay for determining lignocellulosic quality.

Lignocellulosic biomass is a source of low cost polysaccharides that some microbes can deconstruct and convert into liquid transportation fuel. Feedstocks vary in their ease of use depending on their source and handing. Estimating conversion amenability is useful to determine the effects of biomass pretreatment and genetic potential for the purposes of energy crop breeding and genetics. Here we describe a small-scale high-throughput assay that measures ethanol production from a culture of plant biomass and the ethanologen Clostridium phytofermentans.

The complete genome sequence of Clostridium indolis DSM 755T

Clostridium indolis DSM 755T is a bacterium commonly found in soils and the feces of birds and mammals. Despite its prevalence, little is known about the ecology or physiology of this species. However, close relatives, C. saccharolyticum and C. hathewayi, have demonstrated interesting metabolic potentials related to plant degradation and human health. The genome of C. indolis DSM 755T reveals an abundance of genes in functional groups associated with the transport and utilization of carbohydrates, as well as citrate, lactate, and aromatics. Ecologically relevant gene clusters related to nitrogen fixation and a unique type of bacterial microcompartment, the CoAT BMC, are also detected. Our genome analysis suggests hypotheses to be tested in future culture based work to better understand the physiology of this poorly described species.