Advances in development of a genetic system for Thermoanaerobacterium spp.: expression of genes encoding hydrolytic enzymes, development of a second shuttle vector, and integration of genes into the chromosome

Despite recent success in transforming various thermophilic gram-type-positive anaerobes with plasmid DNA, use of shuttle vectors for the expression of genes other than antibiotic resistance markers has not previously been described. We constructed new vectors in order to express heterologous hydrolytic enzymes in our model system, Thermoanaerobacterium saccharolyticum JW/SL-YS485. Transformed Thermoanaerobacterium expressed active enzyme, indicating that this system may function as an alternate expression host, especially for genes with a thermophilic origin. To develop further the genetic system for T. saccharolyticum JW/SL-YS485, two improved Escherichia coli-Thermoanaerobacterium shuttle vectors, pRKM1 and pRUKM, were constructed. Furthermore, the kanamycin resistance cassette alone and the kanamycin resistance cassette plus the cellobiohydrolase gene (cbhA) from Clostridium thermocellum JW20 were integrated into the xylanase gene (xynA) region of the Thermoanaerobacterium chromosome via homologous recombination using pUC-based suicide vectors pUXK and pUXKC.     

Metabolic engineering of Thermoanaerobacterium saccharolyticum for n-butanol production

The thermophilic anaerobe Thermoanaerobacterium saccharolyticum JW/SL-YS485 was investigated as a host for n-butanol production. A systematic approach was taken to demonstrate functionality of heterologous components of the clostridial n-butanol pathway via gene expression and enzymatic activity assays in this organism. Subsequently, integration of the entire pathway in the wild-type strain resulted in n-butanol production of 0.85 g/L from 10 g/L xylose, corresponding to 21% of the theoretical maximum yield. We were unable to integrate the n-butanol pathway in strains lacking the ability to produce acetate, despite the theoretical overall redox neutrality of n-butanol formation. However, integration of the n-butanol pathway in lactate deficient strains resulted in n-butanol production of 1.05 g/L from 10 g/L xylose, corresponding to 26% of the theoretical maximum.     

Establishment of a Genetic Transformation System and Its Application in Thermoanaerobacter tengcongensis

The whole-genome sequence of Thermoanaerobacter tengcongensis,an anaerobic thermophilic bacterium isolated from the Tengchong hot spring in China,was completed in 2002.However,in vivo studies on the genes of this strain have been hindered in the absence of genetic manipulation system.In order to establish such a system,the plasmid pBOLOl containing the replication origin of the T.tengcongensis chromosome and a kanamycin resistance cassette,in which kanamycin resistance gene expression was controlled by the ttel482 promoter from T.tengcongensis,was constructed and introduced into T.tengcongensis via electroporation.Subsequently,the high transformation efficiency occurred when using freshly cultured T.tengcongensis cells without electroporation treatment,suggesting that T.tengcongensis is naturally competent under appropriate growth stage.A genetic transformation system for this strain was then established based on these important components,and this system was proved to be available for studying physiological characters of T.tengcongensis in vivo by means of hisG gene disruption and complementation.     

Cloning of <Emphasis Type="SmallCaps">l</Emphasis>-lactate dehydrogenase and elimination of lactic acid production via gene knockout in<Emphasis Type="Italic"> Thermoanaerobacterium saccharolyticum</Emphasis> JW/SL-YS485

The gene encoding l-lactate dehydrogenase from Thermoanaerobacterium saccharolyticum JW/SL-YS485 was cloned, sequenced, and used to obtain an l-ldh deletion mutant strain (TD1) following a site-specific double-crossover event as confirmed by PCR and Southern blot. Growth rates and final cell densities were similar for strain TD1 and the wild-type grown on glucose and xylose. Lactic acid was below the limit of detection (0.3 mM) for strain TD1 on both glucose and xylose at all times tested, but was readily detected for the wild-type strain, with average final concentrations of 8.1and 1.8 mM on glucose and xylose, respectively. Elimination of lactic acid as a fermentation product was accompanied by a proportional increase in the yields of acetic acid and ethanol. The results reported here represent a step toward using metabolic engineering to develop strains of thermophilic anaerobic bacteria that do not produce organic acids, and support the methodological feasibility of this goal.     

A stable shuttle vector system for efficient genetic complementation of Helicobacter pylori strains by transformation and conjugation

A versatile plasmid shuttle vector system was constructed, which is useful for genetic complementation of Helicobacter pylori strains or mutants with cloned genes of homologous or heterologous origin. The individual plasmid vectors consist of the minimal essential genetic elements, including an origin of replication for Escherichia coli, a H. pylori-specific replicon originally identified on a small cryptic H. pylori plasmid, an oriT sequence and a multiple cloning site. Shuttle plasmid pHel2 carries a chloramphenicol resistance cassette (cat _GC) and pHel3 contains a kanamycin resistance gene (aphA-3) as the selectable marker; both are functional in E. coli and H. pylori. The shuttle plasmids were introduced into the H. pylori strain P1 by natural transformation. A efficiency of 7.0?×?10^?7 and 4.7?×?10^?7 transformants per viable recipient was achieved with pHel2 and pHel3, respectively, and both vectors showed stable, autonomous replication in H. pylori. An approximately 100-fold higher H. pylori transformation rate was obtained when the shuttle vectors for transformation were isolated from the homologous H. pylori strain, rather than E. coli, indicating that DNA restriction and modification mechanisms play a crucial role in plasmid transformation. Interestingly, both shuttle vectors could also be mobilized efficiently from E. coli into different H.?pylori recipients, with pHel2 showing an efficiency of 2.0?×?10^?5 transconjugants per viable H. pylori P1 recipient. Thus, DNA restriction seems to be strongly reduced or absent during conjugal transfer. The functional complementation of a recA-deficient H. pylori mutant by the cloned H. pylorirecA ⁺ gene, and the expression of the heterologous green fluorescent protein (GFP) in H.?pylori demonstrate the general usefulness of?this system, which will significantly facilitate the molecular analysis of H. pylori virulence factors in the future.     

Small multicopy, non-integrative shuttle vectors based on the plasmid pRN1 for Sulfolobus acidocaldarius and Sulfolobus solfataricus, model organisms of the (cren-)archaea

The extreme thermoacidophiles of the genus Sulfolobus are among the best-studied archaea but have lacked small, reliable plasmid vectors, which have proven extremely useful for manipulating and analyzing genes in other microorganisms. Here we report the successful construction of a series of Sulfolobus–Escherichia coli shuttle vectors based on the small multicopy plasmid pRN1 from Sulfolobus islandicus. Selection in suitable uracil auxotrophs is provided through inclusion of pyrEF genes in the plasmid. The shuttle vectors do not integrate into the genome and do not rearrange. The plasmids allow functional overexpression of genes, as could be demonstrated for the β-glycosidase (lacS) gene of S. solfataricus. In addition, we demonstrate that this β-glycosidase gene could function as selectable marker in S. solfataricus. The shuttle plasmids differ in their interruption sites within pRN1 and allowed us to delineate functionally important regions of pRN1. The orf56/orf904 operon appears to be essential for pRN1 replication, in contrast interruption of the highly conserved orf80/plrA gene is tolerated. The new vector system promises to facilitate genetic studies of Sulfolobus and to have biotechnological uses, such as the overexpression or optimization of thermophilic enzymes that are not readily performed in mesophilic hosts.     

Plasmids for heterologous expression in Pasteurella haemolytica

New cloning and expression vectors that replicate both in Pasteurella haemolytica and in Escherichia coli were constructed based on a native sulfonamide (Su^R) and streptomycin (Sm^R) resistant plasmid of P. haemolytica called pYFC1. Each shuttle vector includes an MCS and a selectable antibiotic resistance marker that is expressed in both organisms. Plasmid pNF2176 carries the P. haemolytica ROB-1 β-lactamase gene (blaP, Ap^R) and pNF2214 carries the Tn903 aph3 kanamycin resistance (Km^R) element. The expression vector, pNF2176, was created by placing the MCS downstream of the sulfonamide gene promoter (P_sulII) on pYFC1; this was used to clone and express the promoterless Tn9 chloramphenicol resistance gene (cat, Cm^R) in P. haemolytica (pNF2200). A promoter-probe vector (pNF2283) was constructed from pNF2200 by deleting P_sulII.     

Cloning, sequencing, and expression of the gene encoding a large S-layer-associated endoxylanase from Thermoanaerobacterium sp. strain JW/SL-YS 485 in Escherichia coli.

The gene (xynA) encoding a surface-exposed, S-layer-associated endoxylanase from Thermoanaerobacterium sp. strain JW/SL-YS 485 was cloned and expressed in Escherichia coli. A 3.8-kb fragment was amplified from chromosomal DNA by using primers directed against conserved sequences of endoxylanases isolated from other thermophilic bacteria. This PCR product was used as a probe in Southern hybridizations to identify a 4.6-kb EcoRI fragment containing the complete xynA gene. This fragment was cloned into E. coli, and recombinant clones expressed significant levels of xylanase activity. The purified recombinant protein had an estimated molecular mass (150 kDa), temperature maximum (80 degrees C), pH optimum (pH 6.3), and isoelectric point (pH 4.5) that were similar to those of the endoxylanase isolated from strain JW/SL-YS 485. The entire insert was sequenced and analysis revealed a 4,044-bp open reading frame encoding a protein containing 1,348 amino acid residues (estimated molecular mass of 148 kDa).xynA was preceded by a putative promoter at -35 (TTAAT) and -10 (TATATT) and a potential ribosome binding site (AGGGAG) and was expressed constitutively in E. coli. The deduced amino acid sequence showed 30 to 96% similarity to sequences of family F beta-glycanases. A putative 32-amino-acid signal peptide was identified, and the C-terminal end of the protein contained three repeating sequences 59, 64, and 57 amino acids) that showed 46 to 68% similarity to repeating sequences at the N-terminal end of S-layer and S-layer-associated proteins from other gram-positive bacteria. These repeats could permit an interaction of the enzyme with the S-layer and tether it to the cell surface.     

The ethanol pathway from Thermoanaerobacterium saccharolyticum improves ethanol production in Clostridium thermocellum

Clostridium thermocellum ferments cellulose, is a promising candidate for ethanol production from cellulosic biomass, and has been the focus of studies aimed at improving ethanol yield. Thermoanaerobacterium saccharolyticum ferments hemicellulose, but not cellulose, and has been engineered to produce ethanol at high yield and titer. Recent research has led to the identification of four genes in T. saccharolyticum involved in ethanol production: adhE, nfnA, nfnB and adhA. We introduced these genes into C. thermocellum and observed significant improvements to ethanol yield, titer, and productivity. The four genes alone, however, were insufficient to achieve in C. thermocellum the ethanol yields and titers observed in engineered T. saccharolyticum strains, even when combined with gene deletions targeting hydrogen production. This suggests that other parts of T. saccharolyticum metabolism may also be necessary to reproduce the high ethanol yield and titer phenotype in C. thermocellum.     

A Modified MultiSite Gateway Cloning Strategy for Consolidation of Genes in Plants

The genome information is offering opportunities to manipulate genes, polygenic characters and multiple traits in plants. Although a number of approaches have been developed to manipulate traits in plants, technical hurdles make the process difficult. Gene cloning vectors that facilitate the fusion, overexpression or down regulation of genes in plant cells are being used with various degree of success. In this study, we modified gateway MultiSite cloning vectors and developed a hybrid cloning strategy which combines advantages of both traditional cloning and gateway recombination cloning. We developed Gateway entry (pGATE) vectors containing attL sites flanking multiple cloning sites and plant expression vector (pKM12GW) with specific recombination sites carrying different plant and bacterial selection markers. We constructed a plant expression vector carrying a reporter gene (GUS), two Bt cry genes in a predetermined pattern by a single round of LR recombination reaction after restriction endonuclease-mediated cloning of target genes into pGATE vectors. All the three transgenes were co-expressed in Arabidopsis as evidenced by gene expression, histochemical assay and insect bioassay. The pGATE vectors can be used as simple cloning vectors as there are rare restriction endonuclease sites inserted in the vector. The modified multisite vector system developed is ideal for stacking genes and pathway engineering in plants.     

Development of a System for Genetic Manipulation of Bartonella bacilliformis

Lack of a system for site-specific genetic manipulation has severely hindered studies on the molecular biology of all Bartonella species. We report the first site-specific mutagenesis and complementation for a Bartonella species. A highly transformable strain of B. bacilliformis, termed JB584, was isolated and found to exhibit a significant increase in transformation efficiency with the broad-host-range plasmid pBBR1MCS-2, relative to wild-type strains. Restriction analyses of genomic preparations with the methylation-sensitive restriction enzymes ClaI and StuI suggest that strain JB584 possesses a dcm methylase mutation that contributes to its enhanced transformability. A suicide plasmid, pUB1, which contains a polylinker, a pMB1 replicon, and a nptI kanamycin resistance cassette, was constructed. An internal 508-bp fragment of the B. bacilliformis flagellin gene (fla) was cloned into pUB1 to generate pUB508, a fla-targeting suicide vector. Introduction of pUB508 into JB584 by electroporation generated eight Kan^r clones of B. bacilliformis. Characterization of one of these strains, termed JB585, indicated that allelic exchange between pUB508 and fla had occurred. Analysis by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, immunoblotting, and electron microscopy showed that synthesis of flagellin encoded by fla and secretion/assembly of flagella were abolished. Complementation of fla in trans was accomplished with a pBBR1MCS recombinant containing the entire wild-type fla gene (pBBRFLAG). These data conclusively show that inactivation of fla results in a bald, nonmotile phenotype and that pMB1 and REP replicons make suitable B. bacilliformis suicide and shuttle vectors, respectively. When used in conjunction with the highly transformable strain JB584, this system for site-specific genetic manipulation and complementation provides a new venue for studying the molecular biology of B. bacilliformis.     

Identification of the [FeFe]-Hydrogenase Responsible for Hydrogen Generation in Thermoanaerobacterium saccharolyticum and Demonstration of Increased Ethanol Yield via Hydrogenase Knockout

Three putative hydrogenase enzyme systems in Thermoanaerobacterium saccharolyticum were investigated at the genetic, mRNA, enzymatic, and phenotypic levels. A four-gene operon containing two [FeFe]-hydrogenase genes, provisionally termed hfs (hydrogenase-Fe-S), was found to be the main enzymatic catalyst of hydrogen production. hfsB, perhaps the most interesting gene of the operon, contains an [FeFe]-hydrogenase and a PAS sensory domain and has several conserved homologues among clostridial saccharolytic, cellulolytic, and pathogenic bacteria. A second hydrogenase gene cluster, hyd, exhibited methyl viologen-linked hydrogenase enzymatic activity, but hyd gene knockouts did not influence the hydrogen yield of cultures grown in closed-system batch fermentations. This result, combined with the observation that hydB contains NAD(P)+ and FMN binding sites, suggests that the hyd genes are specific to the transfer of electrons from NAD(P)H to hydrogen ions. A third gene cluster, a putative [NiFe]-hydrogenase with homology to the ech genes, did not exhibit hydrogenase activity under any of the conditions tested. Deletion of the hfs and hydA genes resulted in a loss of detectable methyl viologen-linked hydrogenase activity. Strains with a deletion of the hfs genes exhibited a 95% reduction in hydrogen and acetic acid production. A strain with hfs and ldh deletions exhibited an increased ethanol yield from consumed carbohydrates and represents a new strategy for engineering increased ethanol yields in T. saccharolyticum.Thermophilic anaerobic bacteria have long been of interest for studies of cellulosic biomass conversion due to their native hydrolytic and fermentative abilities (5, 33). However, all thermophilic anaerobes isolated to date have branched fermentation pathways which produce organic acids in addition to solvents such as ethanol (12). For cellulosic fuel production, significant yield loss is likely to be economically unfeasible (11).In their natural environments, saccharolytic fermentative bacteria participate in interspecies hydrogen transfer, producing hydrogen from carbohydrates that is rapidly consumed by methanogens and sulfate-reducing bacteria (30). As a result, the hydrogen partial pressure remains exceedingly low, allowing hydrogen (E₀′, −414 mV) to be produced not only from ferredoxin (E₀′, ∼−400 mV) but also from the less favorable electron source NAD(P)H (E₀′, −320 mV). Fermentative bacteria benefit from hydrogen production, because they are able to coproduce acetic acid and an additional ATP via acetate kinase (23). When grown in pure culture in a closed fermentation vessel, hydrogen is generated primarily from reduced ferredoxin, since generation from NAD(P)H becomes less favorable as the concentration of hydrogen increases (7).We have recently demonstrated high-yield ethanol production in the thermophilic anaerobe Thermoanaerobacterium saccharolyticum JW/SL-YS485 through deletion of the l-lactate dehydrogenase (ldh), phosphate acetyltransferase (pta), and acetate kinase (ack) genes (20). In addition to producing ethanol at high yield, this strain produced significantly less hydrogen, as is required to balance end product electron stoichiometry, although hydrogenase activity in cell extracts remained high. In this study, we used gene knockout to identify gene clusters that are implicated in hydrogenase activity in T. saccharolyticum and to identify the hfs gene operon, which is required for hydrogen production. The hfs operon contains a protein with [FeFe]-hydrogenase and PAS sensory domains that is conserved among a few members of the genera Clostridium and Thermoanaerobacter. Strains with hfs deletions showed decreased acetic acid production, and a strain with hfs and ldh deletions produced ethanol at an increased yield.     

Construction of New Shuttle Vectors for Acetbacter

Shuttle vector pMV301 was constructed by ligation of pMV102 found in A. aceti subsp. xylinum NBI 1002 to E. coli plasmid pACYC177. It is 6.0 kb in size, has unique restriction sites suitable for insertion of a foreign DNA fragment and confers ampicillin resistance to the Acetobacter host. This vector transforms A. aceti subsp. aceti 10-80S1 and industrial vinegar producer A. aceti subsp. xylinum NBI 1002 as well as E. coli. Various chimeric plasmids were also constructed by ligation of pMV102 to E. coli plasmids to examine the expression of drug resistance genes. In addition to the ampicillin resistance gene, resistance genes for kanamycin, chloramphenicol and tetracycline derived from E. coli plasmids were expressed in Acetobacter. Most of the constructed shuttle vectors were stably maintained in Acetobacter.     

Marker rescue from the Nicotiana tabacum plastid genome using a plastid/Escherichia coli shuttle vector

We recently reported an 868-bp plastid DNA minicircle, NICE1, that formed during transformation in a transplastomic Nicotiana tabacum line. Shuttle plasmids containing NICEI sequences were maintained extrachromosomally in plastids and shown to undergo recombination with NICE1 sequences on the plastid genome. To prove the general utility of the shuttle plasmids, we tested whether plastid genes outside the NICE1 region could be rescued in Escherichia coli. The NICE1-based rescue plasmid, pNICER1, carries NICE1 sequences for maintenance in plastids, the CoIE1 ori for maintenance in E. coli and a spectinomcyin resistance gene (aadA) for selection in both systems. In addition, pNICERl carries a defective kanamycin resistance gene, kan*, to target the rescue of a functional kanamycin resistance gene, kan, from the recipient plastid genome. pNICERl was introduced into plastids where recombination could occur between the homologous kan/kan* sequences, and subsequently rescued in E. coli to recover the products of recombination. Based on the expression of kanamycin resistance in E. coli and the analysis of three restriction fragment polymorphisms, recombinant kan genes were recovered at a high frequency. Efficient rescue of kan from the plastid genome in E. coli indicates that NICE 1-based plasmids are suitable for rescuing mutations from any part of the plastid genome, expanding the repertoire of genetic tools available for plastid biology.     

A Rhodobacter sphaeroides puf L, M and X deletion mutant and its complementation in trans with a 5.3 kb puf operon shuttle fragment

A Rhodobacter sphaeroides puf L, M and X deletion mutant was constructed using interposon mutagenesis. The puf L, M and X genes were replaced with a kanamycin resistance cartridge isolated from the transposon Tn5. The deletion strain PUFLMX 21 did not grow photoheterotrophically and was resistant to kanamycin. Southern blot analysis of genomic DNA from the deletion strain confirmed that the kanamycin resistance was inserted specifically into the puf operon and that the L, M and X genes were deleted. A spontaneous carotenoid mutant of PUFLMX was selected and was found to accumulate primarily neurosporene. Spectroscopic analysis of chromatophores isolated from the deletion strain showed normal B875 and B800-850 expression providing further evidence that the photosynthetic minus phenotype was not the result of insertional inactivation of the promoter region of the puf operon, or the puf Q region. The deletion strain could be returned to the photosynthetic plus phenotype by complementation in trans with a 5.3 kb puf operon shuttle fragment, although the generation time of the complemented strain was 30% longer than wild type.     

Variables Controlling the Expression Level of Exogenous Genes in Dictyostelium

Ectopic expression of genes from recombinant plasmids is commonly used to study gene function. In Dictyostelium, three drug resistance cassettes are commonly used as selectable markers in vectors. We report here a comparative study of the expression of green fluorescent protein (GFP) gene from vectors containing each of the drug-resistant cassettes. The expression was highest in cells transformed with the vectors containing the neomycin-resistant cassette (pDNeoGFP), followed by the hygromycin-resistant cassette (pDHygGFP) and the blasticidin-resistant cassette (pDBsrGFP). The level of GFP expression was directly related to the copy number of the vector in transformants. In turn, the copy number of the vector depended on the drug resistance cassette as well as the concentration of the drug used in selection. In general, cells with higher copy numbers could be selected by a higher drug concentration. The expression of GFP was also affected by the method of transformation. For pDHygGFP, expression of GFP was much higher in cells transformed by electroporation than those transformed by calcium phosphate coprecipitation. However, only a slight difference was observed for pDNeoGFP or pDBsrGFP.     

Natural Competence in Thermoanaerobacter and Thermoanaerobacterium Species

Low-G+C thermophilic obligate anaerobes in the class Clostridia are considered among the bacteria most resistant to genetic engineering due to the difficulty of introducing foreign DNA, thus limiting the ability to study and exploit their native hydrolytic and fermentative capabilities. Here, we report evidence of natural genetic competence in 13 Thermoanaerobacter and Thermoanaerobacterium strains previously believed to be difficult to transform or genetically recalcitrant. In Thermoanaerobacterium saccharolyticum JW/SL-YS485, natural competence-mediated DNA incorporation occurs during the exponential growth phase with both replicating plasmid and homologous recombination-based integration, and circular or linear DNA. In T. saccharolyticum, disruptions of genes similar to comEA, comEC, and a type IV pilus (T4P) gene operon result in strains unable to incorporate further DNA, suggesting that natural competence occurs via a conserved Gram-positive mechanism. The relative ease of employing natural competence for gene transfer should foster genetic engineering in these industrially relevant organisms, and understanding the mechanisms underlying natural competence may be useful in increasing the applicability of genetic tools to difficult-to-transform organisms.The genera Thermoanaerobacter and Thermoanaerobacterium contain bacteria which are thermophilic, obligate anaerobes that specialize in polysaccharide and carbohydrate fermentation, producing primarily l-lactic acid, acetic acid, ethanol, CO₂, and H₂ (24, 27, 49). Taxonomically, they are distinguished from other anaerobic thermophilic clostridia by the ability to reduce thiosulfate to hydrogen sulfide or elemental sulfur (21). The majority of characterized Thermoanaerobacter and Thermoanaerobacterium strains have been isolated from hot springs and other thermal environments (20-22, 38, 47); however, they have also been isolated from canned foods (4, 10), soil (48), paper mills and breweries (41, 43), and deep subsurface environments (5, 13, 35), suggesting a somewhat ubiquitous environmental presence.Representatives of the Thermoanaerobacter and Thermoanaerobacterium genera have been considered for biotechnological applications, such as conversion of lignocellulosic biomass to ethanol (8, 27) or other fuels and chemicals (3, 24). However, the branched fermentation pathways of these organisms generally require modification for industrial application. Several studies have investigated manipulating bioprocess and growth conditions to alter end product ratios and yields, but this has not resulted in reliable conditions to maximize the yield of a single end product (18, 25). Genetic engineering is likely necessary for commercial application of Thermanaerobacter or Thermoanaerobacterium species (26, 27, 44). As genetic systems for these bacteria have emerged (28, 45), increased product yields have been demonstrated by gene knockout of l-lactate dehydrogenase (9, 14), phosphotransacetylase and acetate kinase (40), and hydrogenase (39). Despite this recent progress, genetic transformation is still considered the greatest barrier for engineering these organisms (44).In contrast, some of the bacteria most amenable to genetic manipulation are those exhibiting natural competence; for example, work with the naturally competent Streptococcus pneumoniae first established DNA as the molecule containing inheritable information (42). Naturally competent organisms are found in many bacterial phyla, although the overall number of bacteria known to be naturally competent is relatively small (16).The molecular mechanisms of natural competence are often divided into two stages: early-stage genes that encode regulatory and signal cascades to control competence induction, and late-stage genes that encode the machinery of DNA uptake and integration (16). The Gram-positive late-stage consensus mechanism for DNA uptake and assimilation, elucidated primarily through work with Bacillus subtilis, occurs through several molecular machinery steps. First, DNA is believed to interact with a type IV pilus (T4P) or pseudopilus that brings it into close proximity of the cell membrane. The precise mechanism of this phenomenon is unclear; although components of the T4P in both Gram-positive and Gram-negative bacteria have been shown to bind DNA (7, 19), in specific studies, a full pilus structure has been either not observed or shown not to be essential during natural competence (6, 36). Two proteins, ComEA and ComEC, are then involved in creation and transport of single-stranded DNA across the membrane, where it is subsequently bound by CinA-localized RecA and either integrated into the genome or replicated at an independent origin, as for plasmid DNA (6).Here, we report that several Thermoanaerobacter and Thermoanaerobacterium strains are naturally competent, characterize growth conditions conducive to natural competence, and identify genes in Thermoanaerobacterium saccharolyticum JW/SL-YS485 required for competence exhibition.