New approaches for anti-infective drug discovery: antibiotics, vaccines and beyond

Infectious disease is the leading cause of death worldwide, and billions of dollars are invested every year in developing anti-infective drugs. In the meantime, resistant bacteria are on the steady rise and render many once effective drugs useless. The tremendous funding and the urgent need to treat the resistant bacterial infections lead to the rapid progress on development of new drugs and potential new drug targets. New discoveries are being made that increase our understanding of microbial pathogenesis. Technological advancement is also being made to accelerate the drug discovery process. This review will mainly focus on discussing novel strategies on the development of antibiotics and vaccines for treating bacterial infections. Details of how some of the emerging technologies such as genomics and bioinformatics are accelerating the drug discovery process will be highlighted. Newly emerging concepts in controlling bacterial infections such as the use of probiotics and enzybiotics will also be briefly described.

The role of Bacteroides conjugative transposons in the dissemination of antibiotic resistance genes

Investigations into the mechanisms of antibiotic resistance gene transfer utilized by Bacteroides species have led to a greater understanding of how bacteria transfer antibiotic resistance genes, and what environmental stimuli promote such horizontal transfer events. Although Bacteroides spp. harbor a variety of transmissible elements that are involved in the dissemination of antibiotic resistance genes, it is one particular class of elements, the conjugative transposons, that are responsible for most of the resistance gene transfer in Bacteroides. The potential for Bacteroides conjugative transposons to transfer antibiotic resistance genes extends beyond those genes carried by the conjugative transposon itself, because Bacteroides conjugative transposons are able to mobilize coresident plasmids in trans and in cis, and also stimulate the excision and transfer of unlinked integrated elements called mobilizable transposons. These characteristics of conjugative transposons alone have significant implications for the ecology and spread of antibiotic resistance genes, and in terms of biotechnology. A novel feature of the most widespread family of Bacteroides conjugative transposons, the CTnDOT/ERL family, is that their transfer is stimulated 100- to 1000-fold by low concentrations of tetracycline. This is significant because the use of antibiotics not only selects for resistant Bacteroides strains, but also stimulates their transfer. Other Bacteroides conjugative transposons do not require any induction to stimulate transfer, and hence appear to transfer constitutively. The constitutively transferring elements characterized so far appear to have a broader host range than the CTnDOT/ERL family of conjugative transposons, and the prevalence of these elements is on the increase. Since these constitutively transferring elements do not require induction by antibiotics to stimulate transfer, they have the potential to become as pervasive as the CTnDOT/ERL family of conjugative transposons.

Biochemical analysis of interactions between outer membrane proteins that contribute to starch utilization by Bacteroides thetaiotaomicron

An early step in the utilization of starch by Bacteroides thetaiotaomicron is the binding of starch to the bacterial surface. Four starch-associated outer membrane proteins of B. thetaiotaomicron that have no starch-degrading activity have been identified. Two of these, SusC and SusD, have been shown by genetic analysis to be required for starch binding. In this study, we provide the first biochemical evidence that these two proteins interact physically with each other. Both formaldehyde cross-linking and nondenaturing gel electrophoresis experiments showed that SusC and SusD interact to form a complex. Two other proteins encoded by genes in the same operon, SusE and SusF, proved not to be essential for starch utilization and actually decreased starch binding when they were present along with SusC and SusD. Consistent with this, nondenaturing gel analysis revealed that in a strain producing SusC, SusD, and SusE, the SusCD complex was partially destabilized. The strain producing SusC, SusD, and SusE also grew more slowly on starch than a strain producing SusC, SusD, SusE, and SusF (mu(max), 0.29 and 0.37/h, respectively). Thus, SusE appears to interact with the SusCD complex. SusE also interacts with SusF, because SusE was less susceptible to proteinase K digestion when SusF was present, and nondenaturing gel analysis detected a complex formed by these two proteins. Our results indicate that SusC, SusD, SusE, and SusF form a protein complex in the outer membrane but that SusE and SusF are dispensable members of this complex.

New regulatory gene that contributes to control of Bacteroides thetaiotaomicron starch utilization genes

Bacteroides thetaiotaomicron uses starch as a source of carbon and energy. Early steps in the pathway of starch utilization, such as starch binding and starch hydrolysis, are encoded by sus genes, which have been characterized previously. The sus structural genes are expressed only if cells are grown in medium containing maltose or higher oligomers of glucose. Regulation of the sus structural genes is mediated by SusR, an activator that is encoded by a gene located next to the sus structural genes. A strain with a disruption in susR cannot grow on starch but can still grow on maltose and maltotriose. A search for transposon-generated mutants that could not grow on maltose and maltotriose unexpectedly located a gene, designated malR, which regulates expression of an alpha-glucosidase not controlled by SusR. Although a disruption in susR did not affect expression of the malR controlled gene, a disruption in malR reduced expression of the sus structural genes. Thus, MalR appears to participate with SusR in regulation of the sus genes. Results of transcriptional fusion assays and reverse transcription-PCR experiments showed that malR is expressed constitutively. Moreover, multiple copies of malR provided on a plasmid (5 to 10 copies per cell) more than doubled the amount of alpha-glucosidase activity in cell extracts. Our results demonstrate that the starch utilization system of B. thetaiotaomicron is controlled on at least two levels by the regulatory proteins SusR and MalR.

Production of two proteins encoded by the Bacteroides mobilizable transposon NBU1 correlates with time-dependent accumulation of the excised NBu1 circular form

NBU1 is a mobilizable transposon that excises from the Bacteroides chromosome to form a double-stranded circular transfer intermediate. Excision is triggered by exposure of the bacteria to tetracycline. Accordingly, we expected that the expression of NBU1 genes would be induced by tetracycline. To test this hypothesis, antibodies that recognized two NBU1-encoded proteins, PrmN1 and MobN1, were used to monitor production of these proteins. PrmN1 is essential for excision, and MobN1 is essential for transfer of the excised circular form. At first, expression of the genes encoding these two proteins appeared to be regulated by tetracycline, because the proteins were detectable on Western blots only after the cells were exposed to tetracycline. However, when the prmN1 gene and/or the mobN1 gene was cloned on a multicopy plasmid, production of the protein was constitutive. Initially, we assumed that the constitutive expression was due to loss of a repressor protein that was encoded by one of the other genes on NBU1. Deletions or insertions in the other genes (orf2 and orf3) on NBU1 and various integrated NBU1 derivatives abolished production of PrmN1 and MobN1. This is the opposite of what should have happened if one or both of these genes encoded a repressor. A second possibility was that when NBU1 excised, it replicated transiently, increasing the gene dosage of prmN1 and mobN1 and thereby producing enough PrmN1 and MobN1 for these proteins to become detectable. In fact, after the cells entered late exponential phase the copy number of NBU1 increased to 2 to 3 copies per cell. Production of PrmN1 and MobN1 showed a similar pattern. Any mutation in NBU1 that decreased or prevented excision also prevented elevated production of these two proteins. Our results show that the apparent tetracycline dependence of the production of PrmN1 and MobN1 is due to a growth phase- or time-dependent increase in the number of copies of the NBU1 circular form.

Transfer region of a Bacteroides conjugative transposon contains regulatory as well as structural genes

Conjugative transposons (CTns) are integrated elements that excise themselves from the chromosome to form a circular transfer intermediate that is transferred by conjugation to a recipient. In an earlier paper, the excision step was shown to be regulated by tetracycline and to be dependent on the regulatory gene, rteC. In this paper, we report that genes involved in conjugal transfer are also regulated by tetracycline but that regulation is more complex. Genes contained within a 20-kbp region that is sufficient for conjugal transfer were disrupted by single crossover integration events. Most of the disruptions abolished transfer of the CTn. None of them abolished excision. Antibodies to two of the proteins encoded in this region (TraG and TraN) were obtained and used to show that production of these proteins was dependent on tetracycline stimulation. Both TraG and TraN were membrane proteins. A surprising finding was that a disruption in the gene traQ increased transfer of CTnERL over 100-fold. Thus, TraQ may be a repressor protein that controls expression of transfer genes. If so, TraQ is not the only protein that controls expression of transfer genes because production of TraG and TraN in the traQ disruption mutant was still dependent on tetracycline stimulation.

Identification of genes required for excision of CTnDOT, a Bacteroides conjugative transposon

Integrated self-transmissible elements called conjugative transposons have been found in many different bacteria, but little is known about how they excise from the chromosome to form the circular intermediate, which is then transferred by conjugation. We have now identified a gene, exc, which is required for the excision of the Bacteroides conjugative transposon, CTnDOT. The int gene of CTnDOT is a member of the lambda integrase family of recombinases, a family that also contains the integrase of the Gram-positive conjugative transposon Tn916. The exc gene was located 15 kbp from the int gene, which is located at one end of the 65 kbp element. The exc gene, together with the regulatory genes, rteA, rteB and rteC, were necessary to excise a miniature form of CTnDOT that contained only the ends of the element and the int gene. Another open reading frame (ORF) in the same operon and upstream of exc, orf3, was not essential for excision and had no significant amino acid sequence similarity to any proteins in the databases. The deduced amino acid sequence of the CTnDOT Exc protein has significant similarity to topoisomerases. A small ORF (orf2) that could encode a small, basic protein comparable with lambda and Tn916 excision proteins (Xis) was located immediately downstream of the CTnDOT int gene. Although Xis proteins are required for excision of lambda and Tn916, orf2 had no effect on excision of the element. Excision of the CTnDOT mini-element was not affected by the site in which it was integrated, another difference from Tn916. Our results demonstrate that the Bacteroides CTnDOT excision system is tightly regulated and appears to be different from that of any other known integrated transmissible element, including those of some Bacteroides mobilizable transposons that are mobilized by CTnDOT.

Characterization of the 13-kilobase ermF region of the Bacteroides conjugative transposon CTnDOT

The conjugative transposon CTnDOT is virtually identical over most of its length to another conjugative transposon, CTnERL, except that CTnDOT carries an ermF gene that is not found on CTnERL. In this report, we show that the region containing ermF appears to consist of a 13-kb chimera composed of at least one class I composite transposon and a mobilizable transposon (MTn). Although the ermF region contains genes also carried on Bacteroides transposons Tn4351 and Tn4551, it does not contain the IS4351 element which is found on these transposons. In CTnDOT, insertion of the ermF region occurred near a stem-loop structure at the end of orf2, an open reading frame located immediately downstream of the integrase (int) gene of CTnDOT, and in a region known to be important for excision of CTnERL and CTnDOT. The chimera that comprises the ermF region can apparently no longer excise and circularize, but it contains a functional mobilization region related to that described for the Bacteroides MTn Tn4399. Analysis of 19 independent Bacteroides isolates showed that the ermF region is located in the same position in all of the strains analyzed and that the compositions of the ermF region are almost identical in these strains. Therefore, it appears that CTnDOT-like elements present in community and clinical isolates of Bacteroides were derived from a common ancestor and proliferated in the diverse Bacteroides population.

Evidence for extensive resistance gene transfer among Bacteroides spp. and among Bacteroides and other genera in the human colon

Transfer of antibiotic resistance genes by conjugation is thought to play an important role in the spread of resistance. Yet virtually no information is available about the extent to which such horizontal transfers occur in natural settings. In this paper, we show that conjugal gene transfer has made a major contribution to increased antibiotic resistance in Bacteroides species, a numerically predominant group of human colonic bacteria. Over the past 3 decades, carriage of the tetracycline resistance gene, tetQ, has increased from about 30% to more than 80% of strains. Alleles of tetQ in different Bacteroides species, with one exception, were 96 to 100% identical at the DNA sequence level, as expected if horizontal gene transfer was responsible for their spread. Southern blot analyses showed further that transfer of tetQ was mediated by a conjugative transposon (CTn) of the CTnDOT type. Carriage of two erythromycin resistance genes, ermF and ermG, rose from <2 to 23% and accounted for about 70% of the total erythromycin resistances observed. Carriage of tetQ and the erm genes was the same in isolates taken from healthy people with no recent history of antibiotic use as in isolates obtained from patients with Bacteroides infections. This finding indicates that resistance transfer is occurring in the community and not just in clinical environments. The high percentage of strains that are carrying these resistance genes in people who are not taking antibiotics is consistent with the hypothesis that once acquired, these resistance genes are stably maintained in the absence of antibiotic selection. Six recently isolated strains carried ermB genes. Two were identical to erm(B)-P from Clostridium perfringens, and the other four had only one to three mismatches. The nine strains with ermG genes had DNA sequences that were more than 99% identical to the ermG of Bacillus sphaericus. Evidently, there is a genetic conduit open between gram-positive bacteria, including bacteria that only pass through the human colon, and the gram-negative Bacteroides species. Our results support the hypothesis that extensive gene transfer occurs among bacteria in the human colon, both within the genus Bacteroides and among Bacteroides species and gram-positive bacteria.

Transfer region of a bacteroides conjugative transposon, CTnDOT

Bacteroides species harbor large self-transmissible integrated elements called conjugative transposons (CTns). In this paper, we report the first complete sequence analysis of the transfer region of a Bacteroides CTn. The transfer region contained 17 genes (designated orfA-orfQ). Only 2 of the genes shared sequence similarity with genes in the databases and only 1 of these genes was associated with self-transmissible elements.

Characterization of four outer membrane proteins involved in binding starch to the cell surface of Bacteroides thetaiotaomicron

Bacteroides thetaiotaomicron, a gram-negative obligate anaerobe, utilizes polysaccharides by binding them to its cell surface and allowing cell-associated enzymes to hydrolyze them into digestible fragments. We use the starch utilization system as a model to analyze the initial steps involved in polysaccharide binding and breakdown. In a recent paper, we reported that one of the outer membrane proteins involved, SusG, had starch-degrading activity but was not sufficient for growth on starch. Moreover, SusG alone did not have detectable starch binding activity. Previous studies have shown that starch binding is essential for starch utilization. In this paper, we report that four other outer membrane proteins, SusC through SusF, are responsible for starch binding. Results of (14)C-starch binding assays show that SusC and SusD both contribute a significant amount of starch binding. SusE also appears to contribute substantially to starch binding. Using affinity chromatography, we show in vitro that these Sus proteins interact to bind starch. Moreover, protease accessibility of either SusC or SusD greatly increased when one was expressed without the other. This finding supports the hypothesis that SusC and SusD interact in the outer membrane. Evidence from additional protease accessibility studies suggests that SusC, SusE, and SusF are exposed on the cell surface. Our results demonstrate that SusC and SusD act as the major starch binding proteins on the cell surface, with SusE enhancing binding. SusF's role in starch utilization has yet to be determined, although the fact that starch protected it from proteolytic attack suggests that it does bind starch.

Integration and excision of a Bacteroides conjugative transposon, CTnDOT

Bacteroides conjugative transposons (CTns) are thought to transfer by first excising themselves from the chromosome to form a nonreplicating circle, which is then transferred by conjugation to a recipient. Earlier studies showed that transfer of most Bacteroides CTns is stimulated by tetracycline, but it was not known which step in transfer is regulated. We have cloned and sequenced both ends of the Bacteroides CTn, CTnDOT, and have used this information to examine excision and integration events. A segment of DNA that contains the joined ends of CTnDOT and an adjacent open reading frame (ORF), intDOT, was necessary and sufficient for integration into the Bacteroides chromosome. Integration of this miniature form of the CTn was not regulated by tetracycline. Excision of CTnDOT and formation of the circular intermediate were detected by PCR, using primers designed from the end sequences. Sequence analysis of the PCR products revealed that excision and integration involve a 5-bp coupling sequence-type mechanism possibly similar to that used by CTn Tn916, a CTn found originally in enterococci. PCR analysis also demonstrated that excision is a tetracycline-regulated step in transfer. The integrated minielement containing intDOT and the ends of CTnDOT did not excise, nor did a larger minielement that also contained an ORF located immediately downstream of intDOT designated orf2. Thus, excision involves other genes besides intDOT and orf2. Both intDOT and orf2 were disrupted by single-crossover insertions. Analysis of the disruption mutants showed that intDOT was essential for excision but orf2 was not. Despite its proximity to the integrase gene, orf2 appears not to be essential for excision.

Characterization of a Bacteroides mobilizable transposon, NBU2, which carries a functional lincomycin resistance gene

The mobilizable Bacteroides element NBU2 (11 kbp) was found originally in two Bacteroides clinical isolates, Bacteroides fragilis ERL and B. thetaiotaomicron DOT. At first, NBU2 appeared to be very similar to another mobilizable Bacteroides element, NBU1, in a 2.5-kbp internal region, but further examination of the full DNA sequence of NBU2 now reveals that the region of near identity between NBU1 and NBU2 is limited to this small region and that, outside this region, there is little sequence similarity between the two elements. The integrase gene of NBU2, intN2, was located at one end of the element. This gene was necessary and sufficient for the integration of NBU2. The integrase of NBU2 has the conserved amino acids (R-H-R-Y) in the C-terminal end that are found in members of the lambda family of site-specific integrases. This was also the only region in which the NBU1 and NBU2 integrases shared any similarity (28% amino acid sequence identity and 49% sequence similarity). Integration of NBU2 was site specific in Bacteroides species. Integration occurred in two primary sites in B. thetaiotaomicron. Both of these sites were located in the 3' end of a serine-tRNA gene NBU2 also integrated in Escherichia coli, but integration was much less site specific than in B. thetaiotaomicron. Analysis of the sequence of NBU2 revealed two potential antibiotic resistance genes. The amino acid sequences of the putative proteins encoded by these genes had similarity to resistances found in gram-positive bacteria. Only one of these genes was expressed in B. thetaiotaomicron, the homolog of linA, a lincomycin resistance gene from Staphylococcus aureus. To determine how widespread elements related to NBU1 and NBU2 are in Bacteroides species, we screened 291 Bacteroides strains. Elements with some sequence similarity to NBU2 and NBU1 were widespread in Bacteroides strains, and the presence of linA(N) in Bacteroides strains was highly correlated with the presence of NBU2, suggesting that NBU2 has been responsible for the spread of this gene among Bacteroides strains. Our results suggest that the NBU-related elements form a large and heterogeneous family, whose members have similar integration mechanisms but have different target sites and differ in whether they carry resistance genes.

Multiple gene products and sequences required for excision of the mobilizable integrated Bacteroides element NBU1

NBU1 is an integrated 10.3-kbp Bacteroides element, which can excise and transfer to Bacteroides or Escherichia coli recipients, where it integrates into the recipient genome. NBU1 relies on large, >60-kbp, conjugative transposons for factors that trigger excision and for mobilization of the circular form to recipients. Previously, we showed that a single integrase gene, intN1, was necessary and sufficient for integration of NBU1 into its target site on the Bacteroides or E. coli genome. We now show that an unexpectedly large region of NBU1 is required for excision. This region includes, in addition to intN1, four open reading frames plus a large region downstream of the fourth gene, prmN1. This downstream sequence was designated XRS, for "excision-required sequence." XRS contains the oriT of the circular form of NBU1 and about two-thirds of the adjacent mobilization gene, mobN1. This is the first time an oriT, which is involved in conjugal transfer of the circular form, has been implicated in excision. Disruption of the gene immediately downstream of intN1, orf2, completely abolished excision. The next open reading frame, orf2x, was too small to be disrupted, so we still do not know whether it plays a role in the excision reaction. Deletions were made in each of two open reading frames downstream of orf2x, orf3 and prmN1. Both of these deletions abolished excision, indicating that these genes are also essential for excision. Attempts to complement various mutations in the excision region led us to realize that a portion of the excision region carrying prmN1 and part of the XRS (XRS(HIII)) inhibited excision when provided in trans on a multicopy plasmid (8 to 10 copies per cell). However, a fragment carrying prmN1, XRS, and the entire mobilization gene, mobN1, did not have this effect. The smaller fragment may be interfering with excision by attracting proteins made by the intact NBU1 and thus removing them from the excision complex. Our results show clearly that excision is a complex process that involves several proteins and a cis-acting region (XRS) which includes the oriT. We suggest that this complex excision machinery may be necessary to allow NBU1 to coordinate nicking at the ends during excision and nicking at the oriT during conjugal transfer, to prevent premature nicking at the oriT before NBU1 has excised and circularized.

Starting a new genetic system: lessons from bacteroides

Despite the fact that genetic manipulation is an essential adjunct of studies of microbial physiology, many important bacterial species are still not accessible to genetic manipulation. In many cases, the people who know the organism best and have studied its physiology extensively have little experience with genetic techniques and are uncertain how to set up a new system. In this article, we describe what we have learned in the process of developing a genetic system for Bacteroides spp. and helping to develop genetic tools for two related species of bacteria: Porphromonas gingivalis and Prevotella ruminicola. We discuss the relative usefulness of different types of genetic tools and make some suggestions about how to construct them.

Physiological characterization of SusG, an outer membrane protein essential for starch utilization by Bacteroides thetaiotaomicron

Results from previous studies had suggested that Bacteroides thetaiotaomicron utilizes starch by binding the polysaccharide to the bacterial surface and subsequently degrading the polymer by using cell-associated enzymes. Most of the starch-degrading activity was localized to the periplasm, but a portion appeared to be membrane associated. This raised the possibility that some breakdown might occur in the outer membrane prior to exposure of the polysaccharide to the periplasmic polysaccharide-degrading enzymes. In this study, we show that SusG, an outer membrane protein which has been shown genetically to be essential for starch utilization, has enzymatic activity. Results of protease accessibility experiments support the hypothesis that SusG is exposed on the cell surface. Results of [(14)C]starch binding assays, however, show that SusG plays a negligible role in binding of starch to the cell surface. Consistent with this, SusG has a relatively high K(m) for starch and by itself is not sufficient to allow cells to grow on starch or to bind starch. Hence, the main role of SusG is to hydrolyze starch, but the binding of starch to the cell surface is evidently mediated by other proteins presumably interacting with SusG.

Construction and characterization of a Bacteroides thetaiotaomicron recA mutant: transfer of Bacteroides integrated conjugative elements is RecA independent

We report the construction and analysis of a Bacteroides thetaiotaomicron recA disruption mutant and an investigation of whether RecA is required for excision and integration of Bacteroides mobile DNA elements. The recA mutant was deficient in homologous recombination and was more sensitive than the wild-type strain to DNA-damaging agents. The recA mutant was also more sensitive to oxygen than the wild type, indicating that repair of DNA contributes to the aerotolerance of B. thetaiotaomicron. Many Bacteroides clinical isolates carry self-transmissible chromosomal elements known as conjugative transposons. These conjugative transposons can also excise and mobilize in trans a family of unlinked integrated elements called nonreplicating Bacteroides units (NBUs). The results of a previous study had raised the possibility that RecA plays a role in excision of Bacteroides conjugative transposons, but this hypothesis could not be tested in Bacteroides spp. because no RecA-deficient Bacteroides strain was available. We report here that the excision and integration of the Bacteroides conjugative transposons, as well as NBU1 and Tn4351, were unaffected by the absence of RecA activity.

Characterization of four outer membrane proteins that play a role in utilization of starch by Bacteroides thetaiotaomicron

Results of earlier work had suggested that utilization of polysaccharides by Bacteroides spp. did not proceed via breakdown by extracellular polysaccharide-degrading enzymes. Rather, it appeared that the polysaccharide was first bound to a putative outer membrane receptor complex and then translocated into the periplasm, where the degradative enzymes were located. In a recent article, we reported the cloning and sequencing of susC, a gene from Bacteroides thetaiotaomicron that encoded a 115-kDa outer membrane protein. SusC protein proved to be essential for utilization not only of starch but also of intermediate-sized maltooligosaccharides (maltose to maltoheptaose). In this paper, we report the sequencing of a 7-kbp region of the B. thetaiotaomicron chromosome that lies immediately downstream of susC. We found four genes in this region (susD, susE, susF, and susG). Transcription of these genes was maltose inducible, and the genes appeared to be part of the same operon as susC. Western blot (immunoblot) analysis using antisera raised against proteins encoded by each of the four genes showed that all four were outer membrane proteins. Protein database searches revealed that SusE had limited similarity to a glucanohydrolase from Clostridium acetobutylicum and SusG had high similarity to amylases from a variety of sources. SusD and SusF had no significant similarity to any proteins in the databases. Results of 14C-starch binding assays suggested that SusD makes a major contribution to binding. SusE and SusF also appear to contribute to binding but not to the same extent as SusD. SusG is essential for growth on starch but appears to contribute little to starch binding. Our results demonstrate that the binding of starch to the B. thetaiotaomicron surface involves at least four outer membrane proteins (SusC, SusD, SusE, and SusF), which may form a surface receptor complex. The role of SusG in binding is still unclear.

Contribution of a neopullulanase, a pullulanase, and an alpha-glucosidase to growth of Bacteroides thetaiotaomicron on starch

Bacteroides thetaiotaomicron, a gram-negative colonic anaerobe, can utilize three forms of starch: amylose, amylopectin, and pullulan. Previously, a neopullulanase, a pullulanase, and an alpha-glucosidase from B. thetaiotaomicron had been purified and characterized biochemically. The neopullulanase and alpha-glucosidase appeared to be the main enzymes involved in the breakdown of starch, because they were responsible for most of the starch-degrading activity detected in B. thetaiotaomicron cell extracts. To determine the importance of these enzymes in the starch utilization pathway, we cloned the genes encoding the neopullulanase and alpha-glucosidase. The gene encoding the neopullulanase (susA) was located upstream of the gene encoding the alpha-glucosidase (susB). Both genes were closely linked to another starch utilization gene, susC, which encodes a 115-kDa outer membrane protein that is essential for growth on starch. The gene encoding the pullulanase, pulI, was not located in this region in the chromosome. Disruption of the neopullulanase gene, susA, reduced the rate of growth on starch by about 30%. Elimination of susA in this strain allowed us to detect a low residual level of enzyme activity, which was localized to the membrane fraction. Previously, we had shown that a disruption in the pulI gene did not affect the rate of growth on pullulan. We have now shown that a double mutant, with a disruption in susA and in the pullulanase gene, pulI, was also able to grow on pullulan. Thus, there is at least one other starch-degrading enzyme besides the neopullulanase and the pullulanase. Disruption of the alpha-glucosidase gene, susB, reduced the rate of growth on starch only slightly. No residual alpha-glucosidase activity was detectable in extracts from this strain. Since this strain could still grow on maltose, maltotriose, and starch, there must be at least one other enzyme capable of degrading the small oligomers produced by the starch-degrading enzymes. Our results show that the starch utilization system of B. thetaiotaomicron is quite complex and contains a number of apparently redundant degradative enzymes.

Resistance gene transfer in anaerobes: new insights, new problems

Investigations of antibiotic-resistance gene transfer elements in Bacteroides species have generated some new insights into how bacteria transfer resistance genes and what environmental conditions foster gene transfer. Integrated gene transfer elements, called conjugative transposons, appear to be responsible for much of the transfer of resistance genes among Bacteroides species. Conjugative transposons not only transfer themselves but also mobilize coresident plasmids and excise and mobilize unlinked integrated elements. Less is known about resistance gene transfer elements of the gram-positive anaerobes, but there are some indications that similar elements may be found in them as well. An unusual feature of the Bacteroides conjugative transposons is that transfer of many of them is stimulated considerably by low concentrations of antibiotics. Thus, antibiotics not only select for resistant strains but also can stimulate transfer of the resistance gene in the first place. This finding raises questions about whether use of low-dose tetracycline therapy may have a greater effect on the resident microflora than had been previously thought. Finally, investigations of resistance genes in Bacteroides species and other genera of bacteria have begun to provide evidence that the resident microflora of the human body does indeed act as a reservoir for resistance genes, which may be acquired from and passed on the transient colonizers of the site.

Effect of regulatory protein levels on utilization of starch by Bacteroides thetaiotaomicron

Bacteroides thetaiotaomicron, a gram-negative obligate anaerobe, appears to utilize starch by first binding the polymer to its surface and then translocating it into the periplasmic space. Several genes that encode enzymes or outer membrane proteins involved in starch utilization have been identified. These have been called sus genes, for starch utilization system. Previous studies have shown that sus structural genes are regulated at the transcriptional level and their expression is induced by maltose. We report here the identification and characterization of a gene, susR, which appears to be responsible for maltose-dependent regulation of the sus structural genes. The deduced amino acid sequence of SusR protein had a helix-turn-helix motif at its carboxy-terminal end, and this region had highest sequence similarity to the corresponding regions of known transcriptional activators. A disruption in susR eliminated the expression of all known sus structural genes, as expected if susR encoded an activator of sus gene expression. The expression of susR itself was not affected by the growth substrate and was not autoregulated, suggesting that binding of SusR to maltose might be the step that activates SusR. Three susR-controlled structural genes, susA, susB, and susC, are located immediately upstream of susR. These genes are organized into two transcriptional units, one containing susA and another containing susB and susC. susA was expressed at a lower level than susBC, and susA expression was more sensitive to the gene dosage of susR than was that of the susBC operon. An unexpected finding was that increasing the number of copies of susR in B. thetaiotaomicron increased the rate of growth on starch. This effect could be due to higher levels of susA expression. Whatever the explanation, the level of SusR in the cell appears to be a limiting factor for growth on starch.

NBU1, a mobilizable site-specific integrated element from Bacteroides spp., can integrate nonspecifically in Escherichia coli

NBU1 is an integrated Bacteroides element that can he mobilized from Bacteroides donors to Bacteroides recipients. Previous studies have shown that a plasmid carrying the internal mobilization region of NBU1 could be transferred by conjugation from Bacteroides thetaiotaomicron to Escherichia coli. In this report, we show that NBU1 can integrate in E. coli. Whereas integration of NBU1 in B. thetaiotaomicron is site specific, integration of NBU1 in E. coli was relatively random, and the insertion frequency of NBU1 into the E. coli chromosome was 100 to 1,000 times lower than the frequency of integration in B. thetaiotaomicron. The frequency of NBU1 integration in E. coli could be increased about 10- to 70-fold, to a value close to that seen with B. thetaiotaomicron, if the primary integration site from B. thetaiotaomicron, BT1-1, was provided on a plasmid in the E. coli recipient or the NBU1 integrase gene, intN1, was provided on a high-copy-number plasmid to increase the amount of integrase available in the recipient. When the primary integration site was available in the recipient, NBU1 integrated site specifically in E. coli. Our results show that NBUs have a very broad host range and are capable of moving from Bacteroides spp. to distantly related species such as E. coli. Moreover, sequence analysis of NBU1 integration sites provided by integration events in E. coli has helped to identify some regions of the NBU1 attachment site that may play a role in the integration process.

The Bacteroides mobilizable insertion element, NBU1, integrates into the 3' end of a Leu-tRNA gene and has an integrase that is a member of the lambda integrase family

NBU1 is a 10.3-kbp integrated Bacteroides element that can be induced to excise from the chromosome and can be mobilized to a recipient by trans-acting functions provided by certain Bacteroides conjugative transposons. The NBU1 transfer intermediate is a covalently closed circle, which is presumed to be the form that integrates into the recipient genome. We report here that a 2.4-kbp segment of NBU1 was all that was required for site-specific integration into the chromosome of Bacteroides thetaiotaomicron 5482. This 2.4-kbp region included the joined ends of the NBU1 circular form (attN1) and a single open reading frame, intN1, which encoded the integrase. Previously, we had found that NBU1 integrates preferentially into a single site in B. thetaiotaomicron 5482. We have now shown that the NBU1 target site is located at the 3' end of a Leu-tRNA gene. The NBU1 integrase gene, intN1, was sequenced. The predicted protein had little overall amino acid sequence similarity to any proteins in the databases but had limited carboxy-terminal similarity to the integrases of lambdoid phages and to the integrases of the gram-positive conjugative transposons Tn916 and Tn1545. We also report that the intN1 gene is expressed constitutively.

The erythromycin resistance gene from the Bacteroides conjugal transposon Tcr Emr 7853 is nearly identical to ermG from Bacillus sphaericus

Tcr Emr 7853, from Bacteroides thetaiotaomicron 7853, is a large chromosomal conjugative transposon which encodes resistance to both tetracycline (Tcr) and erythromycin (Emr). The erythromycin resistance gene of Tcr Emr 7853 did not cross-hybridize with ermF, the Emr gene found on previously studied Bacteroides regular and conjugative transposons. We have cloned and sequenced the erythromycin resistance gene from Tcr Emr 7853. The DNA sequence of this gene was 99.6% identical to that of ermG from Bacillus sphaericus.

A Bacteroides thetaiotaomicron outer membrane protein that is essential for utilization of maltooligosaccharides and starch

Previous studies suggested that the first step in utilization of starch by Bacteroides thetaiotaomicron was binding of the polysaccharide to the cell surface, followed by translocation of the polysaccharide across the outer membrane into the periplasm. In this study, we report the molecular characterization of a gene that encodes an outer membrane protein that is essential for utilization of both maltooligosaccharides and starch. The gene, susC, encoded a protein of 115.3 kDa. Antibodies were raised against SusC, and the outer membrane location of SusC could be confirmed by Western blot (immunoblot) analysis. SusC had a possible signal sequence of between 20 and 39 amino acids, depending on which N-terminal methionine initiates the start of the protein. It also had some features typical of well-characterized outer membrane proteins from members of the family Enterobacteriaceae, such as a terminal phenylalanine residue and a region in the amino portion of the protein thought to be involved in stabilizing the protein in the outer membrane. The amino acid sequence, together with results of gene disruption experiments, suggested that SusC was not an amylolytic enzyme. Transcriptional fusion experiments, using beta-glucuronidase as a reporter group, showed that expression of susC was maltose regulated at the transcriptional level. This is the first molecular characterization of a B. thetaiotaomicron outer membrane protein involved in maltooligosaccharide and starch utilization.

Conjugative transposons: an unusual and diverse set of integrated gene transfer elements

Conjugative transposons are integrated DNA elements that excise themselves to form a covalently closed circular intermediate. This circular intermediate can either reintegrate in the same cell (intracellular transposition) or transfer by conjugation to a recipient and integrate into the recipient's genome (intercellular transposition). Conjugative transposons were first found in gram-positive cocci but are now known to be present in a variety of gram-positive and gram-negative bacteria also. Conjugative transposons have a surprisingly broad host range, and they probably contribute as much as plasmids to the spread of antibiotic resistance genes in some genera of disease-causing bacteria. Resistance genes need not be carried on the conjugative transposon to be transferred. Many conjugative transposons can mobilize coresident plasmids, and the Bacteroides conjugative transposons can even excise and mobilize unlinked integrated elements. The Bacteroides conjugative transposons are also unusual in that their transfer activities are regulated by tetracycline via a complex regulatory network.

Location and characteristics of the transfer region of a Bacteroides conjugative transposon and regulation of transfer genes

Many Bacteroides clinical isolates contain large conjugative transposons, which excise from the genome of a donor and transfer themselves to a recipient by a process that requires cell-to-cell contact. It has been suggested that the transfer intermediate of the conjugative transposons is a covalently closed circle, which is transferred by the same type of rolling circle mechanism used by conjugative plasmids, but the transfer origin of a conjugative transposon has not previously been localized and characterized. We have now identified the transfer origin (oriT) region of one of the Bacteroides conjugative transposons, TcrEmr DOT, and have shown that it is located near the middle of the conjugative transposon. We have also identified a 16-kbp region of the conjugal transposon which is necessary and sufficient for conjugal transfer of the element and which is located near the oriT. This same region proved to be sufficient for mobilization of coresident plasmids and unlinked integrated elements as well as for self-transfer, indicating that all of these activities are mediated by the same transfer system. Previously, we had reported that disruption of a gene, rteC, abolished self-transfer of the element. rteC is one of a set of rte genes that appears to mediate tetracycline induction of transfer activities of the conjugative transposons. On the basis of these and other data, we had proposed that RteC activated expression of transfer genes. We have now found, however, that when the transfer region of TcrEmr DOT was cloned as a plasmid that did not contain rteC and the plasmid (pLYL72) was tested for transfer out of a Bacteroides strain that did not have a copy of rteC in the chromosome, the plasmid was self-transmissible without tetracycline induction. This and other findings suggest that RteC is not an activator transfer genes but is stimulating transfer in some other way.

Identification and characterization of a Bacteroides gene, csuF, which encodes an outer membrane protein that is essential for growth on chondroitin sulfate

Bacteroides thetaiotaomicron can utilize a variety of polysaccharides, including charged mucopolysaccharides such as chondroitin sulfate (CS) and hyaluronic acid (HA). Since the enzymes (chondroitin lyases I and II) that catalyze the first step in breakdown of CS and HA are located in the periplasm, we had proposed that the first step in utilization of these polysaccharides was binding to one or more outer membrane proteins followed by translocation into the periplasm, but no such outer membrane proteins had been shown to play a role in CS or HA utilization. Previously we have isolated a transposon-generated mutant, CS4, which was unable to grow on CS or HA but retained the ability to grow on disaccharide components of CS. This phenotype suggested that the mutation in CS4 either blocked the transport of the mucopolysaccharides into the periplasmic space or blocked the depolymerization of the mucopolysaccharides into disaccharides. We have mapped the CS4 mutation to a single gene, csuF, which is capable of encoding a protein of 1,065 amino acids and contains a consensus signal sequence. Although CsuF had a predicted molecular weight and pI similar to those of chondroitin lyases, it did not show significant sequence similarity to the Bacteroides chondroitin lyase II, a Proteus chondroitin ABC lyase, or two hyaluronidases from Clostridium perfringens and Streptococcus pyogenes, nor was any CS-degrading enzyme activity associated with csuF expression in Bacteroides species or Escherichia coli. The deduced amino acid sequence of CsuF exhibited features suggestive of an outer membrane protein. We obtained antibodies to CsuF and demonstrated that the protein is located in the outer membrane. This is the first evidence that a nonenzymatic outer membrane protein is essential for utilization of CS and HA.

The mobilization regions of two integrated Bacteroides elements, NBU1 and NBU2, have only a single mobilization protein and may be on a cassette

Bacteroides conjugative transposons can act in trans to excise, circularize, and transfer unlinked integrated elements called NBUs (for nonreplicating Bacteroides units). Previously, we localized and sequenced the mobilization region of one NBU, NBU1, and showed that this mobilization region was recognized by the IncP plasmids RP4 and R751, as well as by the Bacteroides conjugative transposons. We report here that the single mobilization protein carried by NBU1 appears to be a bifunctional protein that binds to the oriT region and catalyzes the nicking reaction that initiates the transfer process. We have also localized and sequenced the mobilization region of a second NBU, NBU2. The NBU2 mobilization region was 86 to 90% identical at the DNA sequence to the oriT-mob region of NBU1. The high sequence similarity between NBU1 and NBU2 ended abruptly after the stop codon of the mob gene and about 1 kbp upstream of the oriT region, indicating that the oriT-mob regions of NBU1 and NBU2 may be on some sort of cassette. A region on NBU1 and NBU2 which lies immediately upstream of the oriT region had 66% sequence identity to a region upstream of the oriT region on a mobilizable transposon, Tn4399, an element that had previously appeared to be completely unrelated to the NBUs.

Use of suppressor analysis to find genes involved in the colonization deficiency of a Bacteroides thetaiotaomicron mutant unable to grow on the host-derived mucopolysaccharides chondroitin sulfate and heparin

Bacteroides thetaiotaomicron, one of the numerically predominant species of human colonic bacteria, can ferment two types of host-derived mucopolysaccharides, chondroitin sulfate (CS) and heparin (HP). Originally, the pathways for utilization of CS and HP appeared to be completely independent of each other, but we have recently identified a gene, chuR, that links the two utilization systems. chuR is probably a regulatory gene, but it controls only a small subset of genes involved in CS and HP utilization. Some of the genes controlled by chuR are important for survival of B. thetaiotaomicron in the colon because a mutant that no longer produced ChuR was unable to compete with the wild type for colonization of the intestinal tract of germfree mice. In an attempt to identify genes that either were controlled by ChuR or encoded proteins that interacted with ChuR, we used transposon mutagenesis to generate suppressor mutations that restored the ability of a chuR disruption mutant to grow on CS and HP. Two classes of suppressors were isolated. One class grew as well as the wild type on CS and HP and had recovered the ability to compete with the wild type for colonization of the germfree mouse intestinal tract. A second class grew more slowly on CS and HP and reached only a half-maximum level on CS. This mutant still had a colonization defect. Representatives of both classes of suppressor mutants have been characterized, and the results of this analysis suggest that the transposon insertions in the suppressor mutants probably affected regulatory genes whose products interact with ChuR.

Characterization of a new type of Bacteroides conjugative transposon, Tcr Emr 7853

Results of previous investigations suggested that the conjugative transposons found in human colonic Bacteroides species were all members of a closely related family of elements, exemplified by Tcr Emr DOT. We have now found a new type of conjugative transposon, Tcr Emr 7853, that does not belong to this family. Tcr Emr 7853 has approximately the same size as the Tcr Emr DOT-type elements (70 to 80 kbp) and also carries genes encoding resistance to tetracycline (Tcr) and erythromycin (Emr); however, it differs from previously described conjugative transposons in a number of ways. Its transfer is not regulated by tetracycline and its transfer genes are not controlled by the regulatory genes rteA and rteB, which are found on Tcr Emr DOT and related conjugative transposons. Its ends do not cross-hybridize with the ends of Tcr Emr DOT-type conjugative transposons, and the Emr gene it carries does not cross-hybridize with ermF, the Emr gene found on all previously studied Bacteroides conjugative transposons. There is only one region with high sequence similarity between Tcr Emr 7853 and previously characterized elements, the region that contains the Tcr gene, tetQ. This sequence similarity ends 145 bp upstream of the start codon and 288 bp downstream from the stop codon. A 2-kbp region upstream of tetQ on Tcr Emr 7853 cross-hybridized with four additional EcoRV fragments of Bacteroides thetaiotaomicron 7853 DNA other than the one that contained tetQ. These additional cross-hybridizing bands were not part of Tcr Emr 7853, but one of them cotransferred with Tcr Emr 7853 in some matings. Thus, at least one of the additional cross-hybridizing bands may be associated with another conjugative element or with an element that is mobilized by Tcr Emr 7853. DNA that cross-hybridized with the upstream region was found in one clinical isolate of Bacteroides ovatus and four Tcr isolates of Prevotella ruminicola.

An unusual type of cointegrate formation between a Bacteroides plasmid and the excised circular form of an integrated element (NBU1)

Evidence for an unusual type of cointegrate formation was found as the result of analyzing three integration events that fused a mobilization-deficient Bacteroides plasmid (pEG920) with the excised circular form of a nonreplicating Bacteroides element (NBU1). NBU1 is capable of inserting itself into DNA segments, but the cointegrates were the result of invasion of NBU1 by pEG920, not vice versa. The same site on pEG920 was involved in all cases. Sequence analysis of the cointegrates suggested that the integration events may have been the result of a multistep process in which a conjugative transposon was involved.

Evidence for natural horizontal transfer of tetQ between bacteria that normally colonize humans and bacteria that normally colonize livestock

Though numerous studies have shown that gene transfer occurs between distantly related bacterial genera under laboratory conditions, the frequency and breadth of horizontal transfer events in nature remain unknown. Previous evidence for natural intergeneric transfers came from studies of genes in human pathogens, bacteria that colonize the same host. We present evidence that natural transfer of a tetracycline resistance gene, tetQ, has occurred between bacterial genera that normally colonize different hosts. A DNA sequence comparative approach was taken to examine the extent of horizontal tetQ dissemination between species of Bacteroides, the predominant genus of the human colonic microflora, and between species of Bacteroides and of the distantly related genus Prevotella, a predominant genus of the microflora of the rumens and intestinal tracts of farm animals. Virtually identical tetQ sequences were found in a number of isolate pairs differing in taxonomy and geographic origin, indicating that extensive natural gene transmission has occurred. Among the exchange events indicated by the evidence was the very recent transfer of an allele of tetQ usually found in Prevotella spp. to a Bacteroides fragilis strain.

Excision, transfer, and integration of NBU1, a mobilizable site-selective insertion element

The Bacteroides species harbor a family of conjugative transposons called tetracycline resistance elements (Tcr elements) that transfer themselves from the chromosome of a donor to the chromosome of a recipient, mobilize coresident plasmids, and also mediate the excision and circularization of members of a family of 10- to 12-kbp insertion elements which share a small region of DNA homology and are called NBUs (for nonreplicating Bacteroides units). The NBUs are sometimes cotransferred with Tcr elements, and it was postulated previously that the excised circular forms of the NBUs were plasmidlike forms and were transferred like plasmids and then integrated into the recipient chromosome. We used chimeric plasmids containing one of the NBUs, NBU1, and a Bacteroides-Escherichia coli shuttle vector to show that this hypothesis is probably correct. NBU1 contained a region that allowed mobilization by both the Tcr elements and IncP plasmids, and we used these conjugal elements to allow us to estimate the frequencies of excision, mobilization, and integration of NBU1 in Bacteroides hosts to be approximately 10(-2), 10(-5) to 10(-4), and 10(-2), respectively. Although functions on the Tcr elements were required for the excision-circularization and mobilization of NBU1, no Tcr element functions were required for integration into the recipient chromosome. Analysis of the DNA sequences at the integration region of the circular form of NBU1, the primary insertion site in the Bacteroides thetaiotaomicron 5482 chromosome, and the resultant NBU1-chromosome junctions showed that NBU1 appeared to integrate into the primary insertion site by recombining within an identical 14-bp sequence present on both NBU1 and the target, thus leaving a copy of the 14-bp sequence at both junctions. The apparent integration mechanism and the target selection of NBU1 were different from those of both XBU4422, the only member of the conjugal Tcr elements for which these sequences are known, and Tn4399, a mobilizable Bacteroides transposon. The NBUs appear to be a distinct type of mobilizable insertion element.

Tetracycline regulation of genes on Bacteroides conjugative transposons

Human colonic Bacteroides species harbor a family of large conjugative transposons, called tetracycline resistance (Tcr) elements. Activities of these elements are enhanced by pregrowth of bacteria in medium containing tetracycline, indicating that at least some Tcr element genes are regulated by tetracycline. Previously, we identified a central regulatory locus on the Tcr elements that contained two genes, rteA and rteB, which appeared to encode a two-component regulatory system (A. M. Stevens, J. M. Sanders, N. B. Shoemaker, and A. A. Salyers, J. Bacteriol. 174:2935-2942, 1992). In the present study, we describe a gene which is located downstream of rteB in a separate transcriptional unit and which requires RteB for expression. Sequence analysis of this gene showed that it encoded a 217-amino-acid protein, which had no significant sequence similarity to any proteins in the GenBank or EMBL data base. An insertional disruption in the gene abolished self-transfer of the Tcr element to Bacteroides recipients, indicating that the gene was essential for self-transfer. The disruption also affected mobilization of coresident plasmids. Mobilization frequency was reduced 100- to 1,000-fold if the recipient was Escherichia coli but was not affected to the same extent if the recipient was an isogenic Bacteroides strain. The complex phenotype of the disruption mutant suggested that the newly identified gene, like rteA and rteB, had a regulatory function. Accordingly, it has been designated rteC. Our results indicate that regulation of Tc(r) element functions is unexpectedly complex and may involve a cascade of regulators, with RteA and RteB exerting central control over secondary regulators like RteC, which in turn control subsets of Tcr element structural genes.

Characterization of the mobilization region of a Bacteroides insertion element (NBU1) that is excised and transferred by Bacteroides conjugative transposons

Many Bacteroides clinical isolates carry large conjugative transposons that, in addition to transferring themselves, excise, circularize, and transfer smaller, unlinked chromosomal DNA segments called NBUs (nonreplicating Bacteroides units). We report the localization and DNA sequence of a region of one of the NBUs, NBU1, that was necessary and sufficient for mobilization by Bacteroides conjugative transposons and by IncP plasmids. The fact that the mobilization region was internal to NBU1 indicates that the circular form of NBU1 is the form that is mobilized. The NBU1 mobilization region contained a single large (1.4-kbp) open reading frame (ORF1), which was designated mob. The oriT was located within a 220-bp region upstream of mob. The deduced amino acid sequence of the mob product had no significant similarity to those of mobilization proteins of well-characterized Escherichia coli group plasmids such as RK2 or of either of the two mobilization proteins of Bacteroides plasmid pBFTM10. There was, however, a high level of similarity between the deduced amino acid sequence of the mob product and that of the product of a Bacteroides vulgatus cryptic open reading frame closely linked to a cefoxitin resistance gene (cfxA).

Gene transfer in the mammalian intestinal tract

During the past year, new information has appeared about conjugative transposons, a type of broad host-range gene-transfer element that may make an important contribution to gene transfer between bacteria in the mammalian gastrointestinal tract. Evidence that broad host-range transfers actually occur in the intestine is just beginning to emerge.

A locus that contributes to colonization of the intestinal tract by Bacteroides thetaiotaomicron contains a single regulatory gene (chuR) that links two polysaccharide utilization pathways

Previously, we isolated two Tn4351-generated mutants of Bacteroides thetaiotaomicron (46-1 and CS3) that were unable to grow either on heparin or on chondroitin sulfate. This phenotype was unexpected, since the heparin and chondroitin sulfate utilization pathways had appeared from earlier studies to be independent of each other. Mutants 46-1 and CS3 were also of interest because both were unable to compete successfully with wild-type B. thetaiotaomicron in the intestinal tracts of germfree mice. Thus, both appeared to have a colonization defect. We have now cloned the chromosomal locus in which the transposon insertions in 46-1 and CS3 occurred. Southern blot analysis showed that the Tn4351 insertions in 46-1 and CS3 were about 100 bp apart. Using complementation and insertional mutagenesis, we localized the region affected by the 46-1 and CS3 insertions to within 2.5 kbp. This DNA segment was sequenced and found to contain a 401-codon open reading frame (ORF1) and the N-terminal segment of a second open reading frame (ORF2), which was downstream of ORF1 and transcribed in the same direction. The deduced amino acid sequence of ORF1 showed significant homology to that of a putative positive regulator of an arylsulfatase gene in Klebsiella aerogenes. ORF2 was at least 381 amino acids long and did not exhibit homology to any proteins in the data bases searched. Transposon insertions in both mutants 46-1 and CS3 disrupted ORF1. The results of insertional mutagenesis and complementation experiments indicated that ORF2 was not essential for growth on chondroitin sulfate or heparin. Thus, the chondroitin sulfate-negative and heparin-negative phenotypes of 46-1 and CS3 appear to be due to the interruption of a regulatory gene encoded by ORF1 and not to a polar effect of the insertions on a downstream gene(s). The gene encoding ORF1 has been designated chuR, for regulation of chondroitin sulfate and heparin utilization. Transcriptional fusion studies showed that the expression of chuR occurred at the same level under inducing and noninducing conditions, in contrast to the regulated expression of structural genes of the chondroitin sulfate utilization system. chuR was not autoregulated, nor was its expression affected by a mutation (46-4) that eliminated the expression of all chondroitin sulfate utilization genes but did not affect the utilization of heparin.

Chromosomal gene transfer elements of the Bacteroides group

Many human colonic Bacteroides strains carry large ( > 60 kbp) chromosomal elements that can transfer themselves from the chromosome of the donor to the chromosome of the recipient. Most of these elements carry a tetracycline resistance gene (tetQ) and many also carry an erythromycin resistance gene (ermF), but at least one cryptic member of the family has been identified. Molecular analysis of excision and integration events has shown that the self-transmissible Bacteroides elements are not transposons but may represent a new class of integrating elements. The Bacteroides elements are most similar to the streptococcal conjugative transposons, such as Tn916. The Bacteroides Tcr/TcrEmr elements can mobilize DNA that is not contained within the elements themselves. They not only mobilize co-resident plasmids but also cause the excision, circularization and mobilization of discrete unlinked 10-11 kbp segments of chromosomal DNA. Self-transfer and other activities of the Tcr/TcrEmr elements are regulated by tetracycline. Thus, tetracycline not only selects for acquisition of an element but also stimulates element transfer in the first place.

Bacterial resistance to tetracycline: mechanisms, transfer, and clinical significance

Tetracycline has been a widely used antibiotic because of its low toxicity and broad spectrum of activity. However, its clinical usefulness has been declining because of the appearance of an increasing number of tetracycline-resistant isolates of clinically important bacteria. Two types of resistance mechanisms predominate: tetracycline efflux and ribosomal protection. A third mechanism of resistance, tetracycline modification, has been identified, but its clinical relevance is still unclear. For some tetracycline resistance genes, expression is regulated. In efflux genes found in gram-negative enteric bacteria, regulation is via a repressor that interacts with tetracycline. Gram-positive efflux genes appear to be regulated by an attenuation mechanism. Recently it was reported that at least one of the ribosome protection genes is regulated by attenuation. Tetracycline resistance genes are often found on transmissible elements. Efflux resistance genes are generally found on plasmids, whereas genes involved in ribosome protection have been found on both plasmids and self-transmissible chromosomal elements (conjugative transposons). One class of conjugative transposon, originally found in streptococci, can transfer itself from streptococci to a variety of recipients, including other gram-positive bacteria, gram-negative bacteria, and mycoplasmas. Another class of conjugative transposons has been found in the Bacteroides group. An unusual feature of the Bacteroides elements is that their transfer is enhanced by preexposure to tetracycline. Thus, tetracycline has the double effect of selecting for recipients that acquire a resistance gene and stimulating transfer of the gene.

Location and characterization of genes involved in binding of starch to the surface of Bacteroides thetaiotaomicron

Previous studies of starch utilization by the gram-negative anaerobe Bacteroides thetaiotaomicron have demonstrated that the starch-degrading enzymes are cell associated rather than extracellular, indicating that the first step in starch utilization is binding of the polysaccharide to the bacterial surface. Five transposon-generated mutants of B. thetaiotaomicron which were defective in starch binding (Ms-1 through Ms-5) had been isolated, but initial attempts to identify membrane proteins missing in these mutants were not successful. We report here the use of an immunological approach to identify four maltose-inducible membrane proteins, which were missing in one or more of the starch-binding mutants of B. thetaiotaomicron. Three of the maltose-inducible proteins were outer membrane proteins (115, 65, and 43 kDa), and one was a cytoplasmic membrane protein (80 kDa). The genes encoding these proteins were shown to be clustered in an 8.5-kbp segment of the B. thetaiotaomicron chromosome. Two other loci defined by transposon insertions, which appeared to contain regulatory genes, were located within 7 kbp of the cluster of membrane protein genes. The 115-kDa outer membrane protein was essential for utilization of maltoheptaose (G7), whereas loss of the other proteins affected growth on starch but not on G7. Not all of the proteins missing in the mutants were maltose regulated. We also detected two constitutively produced proteins (32 and 50 kDa) that were less prominent in all of the mutants than in the wild type. Both of these were outer membrane proteins.

Genetic analysis of a locus on the Bacteroides ovatus chromosome which contains xylan utilization genes

Bacteroides ovatus, a gram-negative obligate anaerobe found in the human colon, can utilize xylan as a sole source of carbohydrate. Previously, a 3.8-kbp segment of B. ovatus chromosomal DNA, which contained genes encoding a xylanase (xylI) and a bifunctional xylosidase-arabinosidase (xsa), was cloned, and expression of the two genes was studied in Escherichia coli (T. Whitehead and R. Hespell, J. Bacteriol. 172:2408-2412, 1990). In the present study, we have used segments of the cloned region to construct insertional disruptions in the B. ovatus chromosomal locus containing these two genes. Analysis of these insertional mutants demonstrated that (i) xylI and xsa are probably part of the same operon, with xylI upstream of xsa, (ii) the true B. ovatus promoter was not cloned on the 3.5-kbp DNA fragment which expressed xylanase and xylosidase in E. coli, (iii) there is at least one gene upstream of xylI which could encode an arabinosidase, and (iv) xylosidase rather than xylanase may be a rate-limiting step in xylan utilization. Insertional mutations in the xylI-xsa locus reduced the rate of growth on xylan, but the concentration of residual sugars at the end of growth was the same as that with the wild type. Thus, a slower rate of growth on xylan was not accompanied by less extensive digestion of xylan. Mutants in which xylI had been disrupted still expressed some xylanase activity. This second activity was associated with membranes and produced xylose from xylan, whereas the xylI gene product partitioned primarily with the soluble fraction and produced xylobiose from xylan.

Use of inducible disaccharidases to assess the importance of different carbohydrate sources for Bacteroides ovatus growing in the intestinal tracts of germfree mice

Patterns of disaccharidase expression were used to determine which polysaccharides were the major sources of carbohydrate for Bacteroides ovatus growing in the intestinal tracts of monocolonized germfree mice. Results indicate that B. ovatus grows on a variety of different carbohydrates, which are present in low concentrations, rather than relying on one type of carbohydrate as the major carbohydrate source.

Genes involved in production of plasmidlike forms by a Bacteroides conjugal chromosomal element share amino acid homology with two-component regulatory systems

Many human colonic Bacteroides strains carry large (greater than 70-kbp) self-transmissible chromosomal tetracycline resistance (Tcr) elements. These Tcr elements can also mediate the excision and circularization of discrete nonadjacent segments of chromosomal DNA which are designated NBUs (nonreplicating Bacteroides units). We have localized a 6.5-kbp segment of Tcr element DNA that mediates NBU excision and circularization. Analysis of the DNA sequence of this region indicated that it contained three open reading frames, all transcribed in the same direction. The first gene was the Tcr gene, tetQ. The second two open reading frames exhibited amino acid similarity to known two-component regulatory systems. Complementation and gene fusion data supported the hypothesis that the three genes were organized in an operon. Transcription from the tetQ promoter region was inducible by tetracycline, as might be expected from the previous finding that NBU excision was detectable only in cells preexposed to tetracycline. The 6.5-kbp region appeared to be essential not only for NBU excision but also for self-transfer of the elements, another activity that is enhanced by preexposure to tetracycline. Accordingly, the two genes downstream of tetQ have been designated rteA and rteB (regulation of Tcr elements).

A Bacteroides tetracycline resistance gene represents a new class of ribosome protection tetracycline resistance

The ribosome protection type of tetracycline resistance (Tcr) has been found in a variety of bacterial species, but the only two classes described previously, Tet(M) and Tet(O), shared a high degree of amino acid sequence identity (greater than 75%). Thus, it appeared that this type of resistance emerged recently in evolution and spread among different species of bacteria by horizontal transmission. We obtained the DNA sequence of a Tcr gene from Bacteroides, a genus of gram-negative, obligately anaerobic bacteria that is phylogenetically distant from the diverse species in which tet(M) and tet(O) have been found. The Bacteroides Tcr gene defines a new class of ribosome protection resistance genes, Tet(Q), and has a deduced amino acid sequence that was only 40% identical to Tet(M) or Tet(O). Like tet(M) and tet(O), tet(Q) appears to have spread by horizontal transmission, but only within the Bacteroides group.

Analysis of proteins associated with growth of Bacteroides ovatus on the branched galactomannan guar gum

Bacteroides ovatus, a gram-negative obligate anaerobe from the human colon, can ferment the branched galactomannan guar gum. Previously, three enzymes involved in guar gum breakdown were characterized. The expression of these enzymes appeared to be regulated; i.e., specific activities were higher in extracts from bacteria grown on guar gum than in extracts from bacteria grown on the monosaccharide constituents of guar gum, mannose and galactose. In the present study, we used two-dimensional gel analysis to determine the total number of B. ovatus proteins enhanced during growth on guar gum. Twelve soluble proteins and 20 membrane proteins were expressed at higher levels in guar gum-grown cells than in galactose-grown cells. An unexpected finding was that the expression of the two galactomannanases was induced by glucose as well as guar gum. Three other proteins, one membrane protein and two soluble proteins, had this same expression pattern. The remainder of the guar gum-associated proteins seen on two-dimensional gels and the guar gum-associated alpha-galactosidase were induced in cells grown on guar gum but not in cells grown on glucose. Two transposon-generated mutants (M-5 and M-7) that could not grow on guar gum were isolated. Both mutants still expressed the galactomannanases and the alpha-galactosidase. They also still expressed all of the guar gum-associated proteins that could be detected in two-dimensional gels of glucose-grown or galactose-grown cells. A second transposon insertion that suppressed the guar gum-negative phenotype of M-5 was isolated and characterized. The characteristics of this suppressor mutant indicated that the original transposon insertion was probably in a regulatory locus.