African 1, an Epidemiologically Important Clonal Complex of Mycobacterium bovis Dominant in Mali,Nigeria, Cameroon,and Chad

We have identified a clonal complex of Mycobacterium bovis present at high frequency in cattle in population samples from several sub-Saharan west-central African countries. This closely related group of bacteria is defined by a specific chromosomal deletion (RDAf1) and can be identified by the absence of spacer 30 in the standard spoligotype typing scheme. We have named this group of strains the African 1 (Af1) clonal complex and have defined the spoligotype signature of this clonal complex as being the same as the M. bovis BCG vaccine strain but with the deletion of spacer 30. Strains of the Af1 clonal complex were found at high frequency in population samples of M. bovis from cattle in Mali, Cameroon, Nigeria, and Chad, and using a combination of variable-number tandem repeat typing and spoligotyping, we show that the population of M. bovis in each of these countries is distinct, suggesting that the recent mixing of strains between countries is not common in this area of Africa. Strains with the Af1-specific deletion (RDAf1) were not identified in M. bovis isolates from Algeria, Burundi, Ethiopia, Madagascar, Mozambique, South Africa, Tanzania, and Uganda. Furthermore, the spoligotype signature of the Af1 clonal complex has not been identified in population samples of bovine tuberculosis from Europe, Iran, and South America. These observations suggest that the Af1 clonal complex is geographically localized, albeit to several African countries, and we suggest that the dominance of the clonal complex in this region is the result of an original introduction into cows naïve to bovine tuberculosis.Mycobacterium bovis causes bovine tuberculosis (TB), an important disease of domesticated cattle that has a major economic and health impact throughout the world (61, 64, 65). The pathogen is a member of the Mycobacterium tuberculosis complex, which includes many species and subspecies that cause similar pathologies in a variety of mammalian hosts. The most notable member of the complex is M. tuberculosis, the most important bacterial pathogen of humans. In contrast to M. tuberculosis, which is largely host restricted to humans, M. bovis is primarily maintained in bovids, in particular, domesticated cattle, although the pathogen can frequently be recovered from other mammals, including humans (61). Bovine TB is found in cattle throughout the world and has been reported on every continent where cattle are farmed (3).Bovine TB has been reduced or eliminated from domestic cattle in many developed countries by the application of a test-and-cull policy that removes infected cattle (3, 8, 16, 17, 61, 64, 65). However, in Africa, although bovine TB is known to be common in both cattle and wildlife, control policies have not been enforced in many countries due to cost implications, lack of capacity, and infrastructure limitations (8, 16, 17, 57). In 1998, Cosivi et al. reported of bovine TB, “Of all nations in Africa, only seven apply disease control measures as part of a test-and-slaughter policy and consider bovine TB a notifiable disease; the remaining 48 control the disease inadequately or not at all” (16). In the intervening years, the situation is not thought to have improved (8); however, preliminary surveys of bovine TB have been carried out in some African countries (4, 7, 12, 37, 44, 49, 53, 54, 56).The most common epidemiological molecular-typing method applied to strains of M. bovis is spoligotyping. This method identifies polymorphism in the presence of spacer units in the direct-repeat (DR) region in strains of the M. tuberculosis complex (36, 67). The DR is composed of multiple, virtually identical 36-bp regions interspersed with unique DNA spacer sequences of similar size (direct variant repeat [DVR] units). Spacer sequences are unique to the DR region, and copies are not located elsewhere in the chromosome (68). The DR region may contain over 60 DVR units; however, 43 of the spacer units were selected from the spacer sequences of the M. tuberculosis reference strain H37Rv and M. bovis BCG strain P3 and are used in the standard application of spoligotyping to strains of the M. tuberculosis complex (29, 36). The DR region is polymorphic because of the loss (deletion) of single or multiple spacers, and each spoligotype pattern from strains of M. bovis is given an identifier (http://www.Mbovis.org).Several studies of the DR regions in closely related strains of M. tuberculosis have concluded that the evolutionary trend for this region is primarily loss of single DVRs or multiple contiguous DVRs (22, 29, 68); duplication of DVR units or point mutations in spacer sequences were found to be rare. The loss of discrete units observed by Groenen et al. (29) led them to suggest that the mechanism for spacer loss was homologous recombination between repeat units. However, a study by Warren et al. (69) suggested that for strains of M. tuberculosis, insertion of IS6110 sequences into the DR region and recombination between adjacent IS6110 elements were more important mechanisms for the loss of spacer units.The population structure of the M. tuberculosis group of organisms is apparently highly clonal, without any transfer and recombination of chromosomal sequences between strains (15, 30, 60, 61). In a strictly clonal population, the loss by deletion of unique chromosomal DNA cannot be replaced by recombination from another strain, and the deleted region will act as a molecular marker for the strain and all its descendants. Deletions of specific chromosomal regions (regions of difference [RDs] or large sequence polymorphisms) have been very successful at identifying phylogenetic relationships in the M. tuberculosis complex (11, 25, 26, 35, 48, 50, 61, 62, 66). However, because the loss of spoligotype spacer sequences is so frequent, identical spoligotype patterns can occur independently in unrelated lineages (homoplasy), and therefore, the deletion of spoligotype spacers may be an unreliable indicator of phylogenetic relationship (61, 69).In samples of M. bovis strains from Cameroon, Nigeria, Chad, and Mali, spoligotyping was used to show that many of the strains had similar spoligotype patterns that lacked spacer 30, and it has been suggested that strains from these four countries are phylogenetically related (12, 18, 49, 53). We have extended the previous observations of spoligotype similarities between strains from these countries and confirmed the existence of a unique clonal complex of M. bovis, all descended from a single strain in which a specific deletion of chromosomal DNA occurred. We have named this clonal complex of M. bovis strains African 1 (Af1), and we show that this clonal complex is dominant in these four west-central African countries but rare in eastern and southern Africa. Extended genotyping, using variable-number tandem repeats (VNTR), of strains with the most common spoligotype patterns suggests that each of these four west-central African countries has a unique population structure. Evolutionary scenarios that may have led to the present day distribution of the Af1 clonal complex are discussed.     

Role of the DinB Homologs Rv1537 and Rv3056 in Mycobacterium tuberculosis

The environment encountered by Mycobacterium tuberculosis during infection is genotoxic. Most bacteria tolerate DNA damage by engaging specialized DNA polymerases that catalyze translesion synthesis (TLS) across sites of damage. M. tuberculosis possesses two putative members of the DinB class of Y-family DNA polymerases, DinB1 (Rv1537) and DinB2 (Rv3056); however, their role in damage tolerance, mutagenesis, and survival is unknown. Here, both dinB1 and dinB2 are shown to be expressed in vitro in a growth phase-dependent manner, with dinB2 levels 12- to 40-fold higher than those of dinB1. Yeast two-hybrid analyses revealed that DinB1, but not DinB2, interacts with the β-clamp, consistent with its canonical C-terminal β-binding motif. However, knockout of dinB1, dinB2, or both had no effect on the susceptibility of M. tuberculosis to compounds that form N²-dG adducts and alkylating agents. Similarly, deletion of these genes individually or in combination did not affect the rate of spontaneous mutation to rifampin resistance or the spectrum of resistance-conferring rpoB mutations and had no impact on growth or survival in human or mouse macrophages or in mice. Moreover, neither gene conferred a mutator phenotype when expressed ectopically in Mycobacterium smegmatis. The lack of the effect of altering the complements or expression levels of dinB1 and/or dinB2 under conditions predicted to be phenotypically revealing suggests that the DinB homologs from M. tuberculosis do not behave like their counterparts from other organisms.The emergence and global spread of multi- and extensively drug-resistant strains of Mycobacterium tuberculosis have further complicated the already daunting challenge of controlling tuberculosis (TB) (15). The mechanisms that underlie the evolution of drug resistance in M. tuberculosis by chromosomal mutagenesis and their association with the conditions that tubercle bacilli encounter during the course of infection are poorly understood (6). It has been postulated that hypoxia, low pH, nutrient deprivation, and nitrosative and oxidative stress impose environmental and host immune-mediated DNA-damaging insults on infecting bacilli (64). In addition, the observed importance of excision repair pathways for the growth and survival of M. tuberculosis in murine models of infection (13, 55) and the upregulation of M. tuberculosis genes involved in DNA repair and modification in pulmonary TB in humans provide compelling evidence that the in vivo environment is DNA damaging (51).Damage tolerance constitutes an integral component of an organism''s response to genotoxic stress, preventing collapse of the replication fork at persisting, replication-blocking lesions through the engagement of specialized DNA polymerases that are able to catalyze translesion synthesis (TLS) across the sites of damage (19, 21, 60). Most TLS polymerases belong to the Y family, which comprises a wide range of structurally related proteins present in bacteria, archaea, and eukaryotes (44). Of these, the DinB subfamily of Y family polymerases, whose founder member is Escherichia coli Pol IV (63), is conserved among all domains of life (44). The association of Y family polymerases with inducible mutagenesis has implicated these enzymes in the adaptation of bacteria to environmental stress (17, 20, 39, 54, 58, 59, 66). Their key properties are exemplified in E. coli Pol IV: the polymerase catalyzes efficient and accurate TLS across certain N²-dG adducts (27, 28, 34, 40, 45, 67) and has been implicated in the tolerance of alkylation damage (4); furthermore, overexpression of Pol IV significantly increases mutation rates in E. coli (reviewed in references 21 and 26), and dinB is the only SOS-regulated gene required at induced levels for stress-induced mutagenesis in this organism (20). Furthermore, overproduction of E. coli Pol IV inhibits replication fork progression through replacement of the replicative polymerase to form an alternate replisome in which Pol IV modulates the rate of unwinding of the DnaB helicase (25) and also reduces colony-forming ability (61).The M. tuberculosis genome encodes two Y family polymerase homologs belonging to the DinB subfamily, designated herein as DinB1 (DinX, encoded by Rv1537) and DinB2 (DinP, encoded by Rv3056), as well as a third, distantly related homolog encoded by Rv3394c (see Fig. S1 in the supplemental material) (9). On the basis of sequence similarity with their counterparts from E. coli (63) and Pseudomonas aeruginosa (54), including the complete conservation of key acidic residues essential for catalysis, DinB1 and DinB2 may be functional DNA polymerases (see Fig. S1). In contrast, Rv3394c lacks these residues and as such is unlikely to have polymerase activity (see Fig. S1). Unlike most Y family polymerase-encoding genes investigated with other bacteria (17, 26, 54, 58), dinB1 and dinB2 expression in M. tuberculosis is not dependent on RecA, the SOS response, or the presence of DNA damage (5, 7, 52). That these genes are regulated by other mechanisms and so may serve distinct roles in DNA metabolism in M. tuberculosis is suggested by the observation that dinB1 is differentially expressed in pulmonary TB (51) and is a member of the SigH regulon (30), whereas expression of dinB2 is induced following exposure to novobiocin (5).In this study, we adopted a genetic approach to investigate the function of dinB1 and dinB2 in M. tuberculosis. Mutants with altered complements or expression levels of dinB1 and/or dinB2 were analyzed in vitro and in vivo under conditions predicted to be phenotypically revealing based on DinB function established with other model organisms. The lack of discernible phenotypes in any of the assays employed suggests that the DinB homologs from M. tuberculosis do not behave like their counterparts from other organisms.     

A Monoacylglycerol Lipase from Mycobacterium smegmatis Involved in Bacterial Cell Interaction

MSMEG_0220 from Mycobacterium smegmatis, the ortholog of the Rv0183 gene from M. tuberculosis, recently identified and characterized as encoding a monoacylglycerol lipase, was cloned and expressed in Escherichia coli. The recombinant protein (rMSMEG_0220), which exhibits 68% amino acid sequence identity with Rv0183, showed the same substrate specificity and similar patterns of pH-dependent activity and stability as the M. tuberculosis enzyme. rMSMEG_0220 was found to hydrolyze long-chain monoacylglycerol with a specific activity of 143 ± 6 U mg⁻¹. Like Rv0183 in M. tuberculosis, MSMEG_0220 was found to be located in the cell wall. To assess the in vivo role of the homologous proteins, an MSMEG_0220 disrupted mutant of M. smegmatis (MsΔ0220) was produced. An intriguing change in the colony morphology and in the cell interaction, which were partly restored in the complemented mutant containing either an active (ComMsΔ0220) or an inactive (ComMsΔ0220S111A) enzyme, was observed. Growth studies performed in media supplemented with monoolein showed that the ability of both MsΔ0220 and ComMsΔ0220S111A to grow in the presence of this lipid was impaired. Moreover, studies of the antimicrobial susceptibility of the MsΔ0220 strain showed that this mutant is more sensitive to rifampin and more resistant to isoniazid than the wild-type strain, pointing to a critical structural role of this enzyme in mycobacterial physiology, in addition to its function in the hydrolysis of exogenous lipids.Tuberculosis, which is caused by Mycobacterium tuberculosis, is a major public health issue worldwide. Because of the emergence of multidrug-resistant (MDR) and extensively drug-resistant (XDR) strains and the high incidence of HIV and tuberculosis coinfection (16), it is becoming increasingly difficult to combat the spread of this disease, and the global health burden of tuberculosis is extremely heavy. The reasons for the persistence of the tubercle bacillus include not only its ability to enter into a state of dormancy in its host for decades, evading the immune system by forming structures called granulomas (17), but also its unique and complex cell wall composed of specific lipids (8). These characteristics are thought to be good focus points for drug development. In granulomas, during the nonreplicative stage, the bacteria have been found to accumulate lipids in the form of intracellular lipid inclusion bodies (LIBs) (13). These lipids are composed mainly of triacylglycerols (TAG) (9, 13) and may originate from the lipolysis of host lipids and/or fatty acid uptake. In fact, M. tuberculosis in the granuloma center can even accumulate lipids originating from the degradation of immune cells (20). In addition, it has been reported that M. tuberculosis internalized by foamy macrophages accumulated LIBs when it joined cell lipid droplets composed of neutral lipids (32). Lipid storage may provide the bacillus with energy via the β-oxidation pathway followed by the glyoxylate cycle, during the chronic phase and the reactivation step (3, 17). These lipids may also supply precursors for the synthesis of bacterial cell membrane lipids, which play a key role in the pathogenicity of M. tuberculosis (4, 23). To investigate the molecular basis of the virulence and pathogenicity of M. tuberculosis, it was therefore proposed to study the lipid metabolism and cell wall remodeling processes in this bacterium.The enzymes involved in the lipid degradation processes induced by this bacterium have attracted considerable attention during the last few years. Based on the complete M. tuberculosis H37Rv genome sequence (6), several open reading frames (ORFs) encoding proteins potentially involved in the lipid metabolism of this strain have been identified, among which are the two lipases from M. tuberculosis that have been purified and characterized so far. Deb et al. identified an enzyme, Rv3097c (LipY), belonging to the hormone-sensitive lipase family, which is able to hydrolyze long-chain TAG (10). A study of LIB mobilization in a lipY-deficient mutant has shown that LipY was involved in TAG hydrolysis under nutriment-deprived conditions (10). LipY may therefore be involved in the degradation of TAG stored during the dormant stage and the subsequent reactivation of the pathogen. In addition, electron microscopy immunolabeling studies of LipY clearly showed that the enzyme had a cell surface localization, thus in direct contact with the host immune system (28). The last identified lipase to date is a monoacylglycerol lipase annotated Rv0183 (7). Like LipY, Rv0183 is located in the cell wall, but its exact physiological function has not yet been elucidated. One hypothesis could be that, like some mammalian cells (e.g., adipocytes), M. tuberculosis expresses several lipolytic enzymes sequentially involved in the lipolysis of TAG (37). The Rv0183 enzyme is conserved in M. bovis (Mb0189) and M. leprae (ML2603), as well as in M. smegmatis (MSMEG_0220), a nonpathogenic mycobacterium which provides a useful model organism and a surrogate host for molecular analysis of M. tuberculosis (19). In order to decipher the cellular role of Rv0183 in M. tuberculosis H37Rv and its contribution to the lipid metabolism of this bacterium, biochemical studies were performed on the homologue MSMEG_0220. For this purpose, the MSMEG_0220 gene from M. smegmatis, encoding a protein showing 68% amino acid sequence identity with Rv0183, was cloned, and the recombinant MSMEG_0220 enzyme (rMSMEG_0220) was produced in Escherichia coli, purified, and biochemically characterized. An M. smegmatis mutant with an MSMEG_0220 disrupted gene was produced to investigate the physiological role of MSMEG_0220.     

Different Roles of DosS and DosT in the Hypoxic Adaptation of Mycobacteria

The DosS (DevS) and DosT histidine kinases form a two-component system together with the DosR (DevR) response regulator in Mycobacterium tuberculosis. DosS and DosT, which have high sequence similarity to each other over the length of their amino acid sequences, contain two GAF domains (GAF-A and GAF-B) in their N-terminal sensory domains. Complementation tests in conjunction with phylogenetic analysis showed that DevS of Mycobacterium smegmatis is more closely related to DosT than DosS. We also demonstrated in vivo that DosS and DosT of M. tuberculosis play a differential role in hypoxic adaptation. DosT responds to a decrease in oxygen tension more sensitively and strongly than DosS, which might be attributable to their different autooxidation rates. The different responsiveness of DosS and DosT to hypoxia is due to the difference in their GAF-A domains accommodating the hemes. Multiple alignment analysis of the GAF-A domains of mycobacterial DosS (DosT) homologs and subsequent site-directed mutagenesis revealed that just one substitution of E87, D90, H97, L118, or T169 of DosS with the corresponding residue of DosT is sufficient to convert DosS to DosT with regard to the responsiveness to changes in oxygen tension.Oxygen sensing is important for facultative anaerobes to adapt to changes in metabolic necessities during the transition between aerobic and anaerobic conditions. Although Mycobacterium tuberculosis (MTB) is an obligate aerobe, a gradual depletion of O₂ from its culture is known to lead to a drastic change in gene expression (8, 21, 24, 28, 34, 37, 39). Approximately 48 genes of M. tuberculosis were reported to be induced under early hypoxic conditions, which is mediated by the DosSR (DevSR) two-component system (16, 24, 34). The induction of the DosR regulon is important for survival of M. tuberculosis under hypoxic conditions and for it to enter the nonreplicating dormant state (2, 19). The DosSR two-component system consists of the DosS histidine kinase (HK) and its cognate DosR response regulator (RR) (24, 26, 29). The DosT HK, which shares high sequence similarity to DosS over the length of their primary structures, was also found to cross talk with DosR (26, 30). The N-terminal domains of DosS and DosT contain two tandem GAF domains (GAF-A and GAF-B from their N termini), and the three-dimensional structure of the GAF-A and GAF-B domains was determined (5, 25). A b-type heme is embedded in the GAF-A domain, composed of one five-stranded antiparallel β-sheet and four α-helices (5, 14, 25, 32). The heme is positioned nearly perpendicular to the β-sheet, and H149 and H147 of the polypeptides serve as the proximal axial ligands for DosS and DosT, respectively (5, 25). The ligand-binding state at the distal axial position of heme and the redox state of the heme iron modulate the autokinase activity of DosS and DosT. The O₂-bound (oxyferrous) and ferric forms of the HKs are inactive, whereas the unliganded ferrous (deoxyferrous) form as well as NO- and CO-bound forms are active (17, 36). The heme iron of DosT is stable against autooxidation of Fe²⁺ to Fe³⁺ in the presence of O₂, indicating that its conversion between deoxyferrous and oxyferrous forms is the mechanism by which DosT recognizes O₂ (17). However, the autooxidation property of oxyferrous DosS remains controversial. Kumar et al. (17) and Cho et al. (5) reported that DosS undergoes autooxidation on exposure to O₂, while other research groups demonstrated that the oxyferrous form of DosS is stable against autooxidation (13, 14, 36). Recently, different roles of DosS and DosT in O₂ sensing by M. tuberculosis were suggested. DosT plays a more important role in the early phase of hypoxic conditions than DosS when the growth of M. tuberculosis is transferred from aerobic to hypoxic conditions (11).Mycobacterium smegmatis possesses a single DevS HK that phosphorylates the DevR RR (20). The DevSR two-component system is also implemented in hypoxic adaptation of this bacterium (20). Like DosT of M. tuberculosis, the autokinase activity of M. smegmatis DevS was shown to be controlled by the ligand-binding state of its heme (18). Regarding the autooxidation property, DevS of M. smegmatis was suggested to be similar to DosT rather than DosS; i.e., the heme iron in DevS is resistant to autooxidation from an oxyferrous to a ferric state in the presence of O₂ (18).In this paper we report several lines of evidence for the functional difference between DosS and DosT in the hypoxic adaptation of mycobacteria and discuss the implications of these findings.     

The Mycobacterium tuberculosis DosR Regulon Assists in Metabolic Homeostasis and Enables Rapid Recovery from Nonrespiring Dormancy

Mycobacterium tuberculosis survives in latently infected individuals, likely in a nonreplicating or dormancy-like state. The M. tuberculosis DosR regulon is a genetic program induced by conditions that inhibit aerobic respiration and prevent bacillus replication. In this study, we used a mutant incapable of DosR regulon induction to investigate the contribution of this regulon to bacterial metabolism during anaerobic dormancy. Our results confirm that the DosR regulon is essential for M. tuberculosis survival during anaerobic dormancy and demonstrate that it is required for metabolic processes that occur upon entry into and throughout the dormant state. Specifically, we showed that regulon mechanisms shift metabolism away from aerobic respiration in the face of dwindling oxygen availability and are required for maintaining energy levels and redox balance as the culture becomes anaerobic. We also demonstrated that the DosR regulon is crucial for rapid resumption of growth once M. tuberculosis exits an anaerobic or nitric oxide-induced nonrespiring state. In summary, the DosR regulon encodes novel metabolic mechanisms essential for M. tuberculosis to survive in the absence of respiration and to successfully transition rapidly between respiring and nonrespiring conditions without loss of viability.Mycobacterium tuberculosis, a major human pathogen, infects nearly one-third of the people in the world and causes two million deaths per year (8). Most infections are latent, and a substantial number of new infections are transmitted by individuals in whom latent infections are being reactivated. Latency is a clinical term describing people that are infected with M. tuberculosis but lack symptoms of active disease. Traditionally, it has been thought that bacilli in latently infected individuals reside almost exclusively inside granulomas and mature tubercle lesions. Recent studies indicate that in latently infected individuals M. tuberculosis may also be found outside granulomas in places such as endothelial cells, fibroblasts, and adipose tissue (17, 28). The evidence for M. tuberculosis metabolic activity in vivo is more limited, but two studies by Lillebaek et al. are informative (24, 25). In these studies the researchers used detailed records of tuberculosis epidemiology and strain types in the fairly static population of Denmark. They found that strains isolated from patients thought to have reactivated disease (rather than a primary infection) were nearly identical to strains present 30 years earlier in the same geographic population. The near-identity of the strains and the fact that infections were attributed to reactivation suggest that bacteria in latently infected individuals experience little genetic change during years of latent infection. The researchers concluded that during latency, M. tuberculosis divides infrequently and is likely in a minimal metabolic state.One approach to study the M. tuberculosis metabolic state during latent infection is to use in vitro models that mimic conditions thought to exist in vivo. Such conditions include hypoxia produced in avascular calcified granulomas (40) and nitric oxide (NO) (27) or carbon monoxide (CO) (33) produced by activated immune cells. A widely used model is the “Wayne model” pioneered by Lawrence Wayne. In this model, a low-inoculum culture is sealed in a tube with stirring and allowed to slowly consume oxygen until the culture is anaerobic, resulting in a nonreplicating and apparently dormant state (45, 46). Another model used to look at dormant M. tuberculosis is a constant-hypoxia model that maintains a 0.2% oxygen tension in culture flasks (31).The common theme in these in vitro models used to obtain M. tuberculosis dormancy is inhibition of respiration. The DosR regulon is a set of at least 48 coregulated genes that are induced by three conditions that inhibit aerobic respiration: hypoxia, NO, and CO (42). Induction of the DosR regulon closely mirrors inhibition of respiration, indicating that control of the regulon is linked to the aerobic respiratory state of the bacilli (43). Several studies have shown that the DosR regulon is controlled by a three-component regulatory system composed of two sensor histidine kinases, DosS and DosT, and a response regulator, DosR (42). DosS and DosT both bind the respiration-impairing gases NO and CO (19, 20, 38), further supporting the hypothesis that the DosR regulon responds to, and is important during, conditions that do not allow aerobic respiration. Although the majority of the DosR-regulated genes have not been characterized, the timing of their induction combined with the conditions under which they respond suggests that they may play a role in adaptation of M. tuberculosis to its host environment. Consistent with this notion, DosR regulon genes are induced in the lungs of M. tuberculosis-infected mice (43), as well as in interferon-gamma-activated murine macrophages (34) and guinea pigs (37).Several studies have suggested that the DosR regulon plays a role in latent infection and in persistence in animal models that resemble human infection in some respects. Leyten et al. found that latently infected humans are more likely than humans with active infections to bear T cells specific for DosR regulon antigens (23), suggesting that the regulon is expressed during latency. Two recent studies confirmed that there is an immune response to DosR regulon antigens during latent infection (4, 36). Further evidence for clinical relevance in humans comes from a study showing that M. tuberculosis in sputum expresses the DosR regulon (15). The importance of this regulon for persistence in rabbit and guinea pig models was demonstrated by data showing a 2-log decrease in recovery of a DosR mutant 2 weeks (guinea pig) and 8 weeks (rabbit) after aerosol infection (11). A DosR mutant was also found to be significantly attenuated in guinea pig infection (26), further supporting the notion that the DosR regulon is required for persistence in vivo. It should be noted that in both studies showing the DosR phenotype (11, 26), full complementation and reversion to full virulence were not observed. However, it is now known that regulation of dosR expression is quite complex. Multiple regulatory sequences exist in and upstream of Rv3134c, the gene directly upstream of dosR (8). Failure to include such a regulatory sequence in a complemented strain would likely result in misregulation of dosR and poor complementation. Studies of DosR regulon mutants for murine infection have produced inconsistent findings that vary from hypervirulent (30) to attenuated (11) and not attenuated (3, 31). When animal models are compared, it is important to remember that M. tuberculosis-induced granulomas in primates, rabbits, and guinea pigs develop caseous necrosis and are hypoxic and/or anaerobic, while M. tuberculosis induced-granulomas in mice are neither hypoxic nor anaerobic (2, 21, 41). Furthermore, M. tuberculosis divides regularly in chronic murine infections (16), in contrast to the replication during latent infections, as demonstrated in the studies of Lillebaek et al. (24, 25). Such studies underscore the significant differences between models.A previous study with a DosR mutant in a closely related Mycobacterium bovis BCG strain showed that DosR expression is required for survival in an in vitro Wayne-like model of dormancy (5). Unexpectedly, two similar studies in M. tuberculosis did not show a strong survival defect for a DosR mutant (31, 43). The most recent study showed that there was only a modest survival defect in an H37Rv DosR mutant and concluded that the DosR regulon is a short-term phenomenon and is not responsible for the adaptation necessary to survive under primarily hypoxic conditions in vitro (31, 32).In this study we showed that the DosR regulon is required for M. tuberculosis survival during anaerobic dormancy. We also used a combination of genetic and biochemical approaches to demonstrate that this regulon is necessary to shift away from oxygen consumption, maintain ATP levels, and balance the redox state (NAD/NADH ratio) of the cell as oxygen becomes scarce. Furthermore, we showed that the DosR regulon is necessary for optimal transition of M. tuberculosis back to aerobic growth from an anaerobic or nitric oxide-induced nonrespiring state.     

Mycobacterium tuberculosis Is Able To Accumulate and Utilize Cholesterol

It is expected that the obligatory human pathogen Mycobacterium tuberculosis must adapt metabolically to the various nutrients available during its cycle of infection, persistence, and reactivation. Cholesterol, which is an important part of the mammalian cytoplasmic membrane, is a potential energy source. Here, we show that M. tuberculosis grown in medium containing a carbon source other than cholesterol is able to accumulate cholesterol in the free-lipid zone of its cell wall. This cholesterol accumulation decreases the permeability of the cell wall for the primary antituberculosis drug, rifampin, and partially masks the mycobacterial surface antigens. Furthermore, M. tuberculosis was able to grow on mineral medium supplemented with cholesterol as the sole carbon source. Targeted disruption of the Rv3537 (kstD) gene inhibited growth due to inactivation of the cholesterol degradation pathway, as evidenced by accumulation of the intermediate, 9-hydroxy-4-androstene-3,17-dione. Our findings that M. tuberculosis is able to accumulate cholesterol in the presence of alternative nutrients and use it when cholesterol is the sole carbon source in vitro may facilitate future studies into the pathophysiology of this important deadly pathogen.Mycobacterium tuberculosis, the causative agent of tuberculosis, is a very successful pathogen that infects one-third of the human population (21). Only 10% of primary infected individuals develop active disease during their lifetimes. Tubercle bacilli are able to persist in a dormant state, from which they may reactivate and induce the contagious disease state (13). In asymptomatic hosts, M. tuberculosis exists in reservoirs called granulomas, which are cellular aggregates that restrict bacterial spreading (40). Granulomas are organized collections of mature macrophages that exhibit a certain typical morphology and that arise in response to persistent intracellular pathogens (1, 4). Pathogenic mycobacteria can induce the formation of foamy macrophages filled with lipid-containing bodies; these have been postulated to act as a secure, nutrient-rich reservoir for tubercle bacilli (31). Moreover, M. tuberculosis DNA has been detected in fatty tissues surrounding the kidneys, as well as those of the stomach, lymph nodes, heart, and skin. Tubercle bacilli are able to enter adipocytes, where they accumulate within intracytoplasmic lipid inclusions and survive in a nonreplicating state (26). In vivo, it is expected that M. tuberculosis adapts metabolically to nutrient-poor conditions characterized by glucose deficiency and an abundance of fatty acids (25, 26). The presence of a complex repertoire of lipid metabolism genes in the genome of M. tuberculosis suggests that lipids, including steroids, are important alternative carbon and energy sources for this pathogen (7).One attractive potential alternative nutrient that is readily available in the mammalian host is cholesterol, a major sterol of the plasma membrane. The presence of cholesterol in lipid rafts is required in order for microorganisms to enter the intracellular compartment (14). Studies have shown that cholesterol is essential for the uptake of mycobacteria by macrophages, and it has been found to accumulate at the site of M. tuberculosis entry (2, 12, 30). Moreover, cholesterol depletion overcomes the phagosome maturation block experienced by Mycobacterium avium-infected macrophages (10).It is well known that cholesterol can be utilized by fast-growing, nonpathogenic mycobacteria (5, 20, 22), but it was previously thought that pathogenic mycobacteria might not be able to use cholesterol as a carbon and energy source (3). Recently, however, bioinformatic analysis identified a cassette of cholesterol catabolism genes in actinomycetes, including the M. tuberculosis complex (41). Microarray analysis of Rhodococcus sp. grown in the presence of cholesterol revealed the upregulation of 572 genes, most of which fell within six clearly discernible clusters (41). Most of the identified genes had significant homology to known steroid degradation genes from other organisms and were distributed within a single 51-gene cluster that appears to be very similar to a cluster present in the genome of M. tuberculosis (41). Many of the cholesterol-induced genes had been previously selected by transposon site hybridization analysis of genes that are essential for survival of tubercle bacilli (33) and/or are upregulated in gamma interferon-activated macrophages (37, 42). It was also demonstrated that the M. tuberculosis complex can grow on mineral medium with cholesterol as a primary source of carbon (27, 41). Moreover, the growth of tubercle bacilli on cholesterol was significantly affected by knockout of the mce4 gene, which encodes an ABC transporter responsible for cholesterol uptake (24, 27). Earlier studies had shown that disruption of mce4 attenuated bacterial growth in the spleens of infected animals that had developed adaptive immunity (17, 35).In the present study, we demonstrate for the first time that M. tuberculosis utilizes cholesterol via the 4-androstene-3,17-dione/1,4-androstadiene-3,17-dione pathway (AD/ADD) and that this process requires production of an intact KstD enzyme. We also show that tubercle bacilli growing in medium containing an alternative carbon source can accumulate cholesterol in the free-lipid zone of their cell walls, and this accumulation affects cell wall permeability.     

The Amino Terminus of Herpes Simplex Virus Type 1 Glycoprotein K (gK) Modulates gB-Mediated Virus-Induced Cell Fusion and Virion Egress

Herpes simplex virus type 1 (HSV-1)-induced cell fusion is mediated by viral glycoproteins and other membrane proteins expressed on infected cell surfaces. Certain mutations in the carboxyl terminus of HSV-1 glycoprotein B (gB) and in the amino terminus of gK cause extensive virus-induced cell fusion. Although gB is known to be a fusogenic glycoprotein, the mechanism by which gK is involved in virus-induced cell fusion remains elusive. To delineate the amino-terminal domains of gK involved in virus-induced cell fusion, the recombinant viruses gKΔ31-47, gKΔ31-68, and gKΔ31-117, expressing gK carrying in-frame deletions spanning the amino terminus of gK immediately after the gK signal sequence (amino acids [aa] 1 to 30), were constructed. Mutant viruses gKΔ31-47 and gKΔ31-117 exhibited a gK-null (ΔgK) phenotype characterized by the formation of very small viral plaques and up to a 2-log reduction in the production of infectious virus in comparison to that for the parental HSV-1(F) wild-type virus. The gKΔ31-68 mutant virus formed substantially larger plaques and produced 1-log-higher titers than the gKΔ31-47 and gKΔ31-117 mutant virions at low multiplicities of infection. Deletion of 28 aa from the carboxyl terminus of gB (gBΔ28syn) caused extensive virus-induced cell fusion. However, the gBΔ28syn mutation was unable to cause virus-induced cell fusion in the presence of the gKΔ31-68 mutation. Transient expression of a peptide composed of the amino-terminal 82 aa of gK (gKa) produced a glycosylated peptide that was efficiently expressed on cell surfaces only after infection with the HSV-1(F), gKΔ31-68, ΔgK, or UL20-null virus. The gKa peptide complemented the gKΔ31-47 and gKΔ31-68 mutant viruses for infectious-virus production and for gKΔ31-68/gBΔ28syn-mediated cell fusion. These data show that the amino terminus of gK modulates gB-mediated virus-induced cell fusion and virion egress.Herpes simplex virus type 1 (HSV-1) specifies at least 11 virally encoded glycoproteins, as well as several nonglycosylated and lipid-anchored membrane-associated proteins, which serve important functions in virion infectivity and virus spread. Although cell-free enveloped virions can efficiently spread viral infection, virions can also spread by causing cell fusion of adjacent cellular membranes. Virus-induced cell fusion, which is caused by viral glycoproteins expressed on infected cell surfaces, enables transmission of virions from one cell to another, avoiding extracellular spaces and exposure of free virions to neutralizing antibodies (reviewed in reference 56). Most mutations that cause extensive virus-induced cell-to-cell fusion (syncytial or syn mutations) have been mapped to at least four regions of the viral genome: the UL20 gene (5, 42, 44); the UL24 gene (37, 58); the UL27 gene, encoding glycoprotein B (gB) (9, 51); and the UL53 gene, coding for gK (7, 15, 35, 53, 54, 57).Increasing evidence suggests that virus-induced cell fusion is mediated by the concerted action of glycoproteins gD, gB, and gH/gL. Recent studies have shown that gD interacts with both gB and gH/gL (1, 2). Binding of gD to its cognate receptors, including Nectin-1, HVEM, and others (12, 29, 48, 59, 60, 62, 63), is thought to trigger conformation changes in gH/gL and gB that cause fusion of the viral envelope with cellular membranes during virus entry and virus-induced cell fusion (32, 34). Transient coexpression of gB, gD, and gH/gL causes cell-to-cell fusion (49, 68). However, this phenomenon does not accurately model viral fusion, because other viral glycoproteins and membrane proteins known to be important for virus-induced cell fusion are not required (6, 14, 31). Specifically, gK and UL20 were shown to be absolutely required for virus-induced cell fusion (21, 46). Moreover, syncytial mutations within gK (7, 15, 35, 53, 54, 57) or UL20 (5, 42, 44) promote extensive virus-induced cell fusion, and viruses lacking gK enter more slowly than wild-type virus into susceptible cells (25). Furthermore, transient coexpression of gK carrying a syncytial mutation with gB, gD, and gH/gL did not enhance cell fusion, while coexpression of the wild-type gK with gB, gD, and gH/gL inhibited cell fusion (3).Glycoproteins gB and gH are highly conserved across all subfamilies of herpesviruses. gB forms a homotrimeric type I integral membrane protein, which is N glycosylated at multiple sites within the polypeptide. An unusual feature of gB is that syncytial mutations that enhance virus-induced cell fusion are located exclusively in the carboxyl terminus of gB, which is predicted to be located intracellularly (51). Single-amino-acid substitutions within two regions of the intracellular cytoplasmic domain of gB were shown to cause syncytium formation and were designated region I (amino acid [aa] positions 816 and 817) and region II (aa positions 853, 854, and 857) (9, 10, 28, 69). Furthermore, deletion of 28 aa from the carboxyl terminus of gB, disrupting the small predicted alpha-helical domain H17b, causes extensive virus-induced cell fusion as well as extensive glycoprotein-mediated cell fusion in the gB, gD, and gH/gL transient-coexpression system (22, 49, 68). The X-ray structure of the ectodomain of gB has been determined and is predicted to assume at least two major conformations, one of which may be necessary for the fusogenic properties of gB. Therefore, perturbation of the carboxyl terminus of gB may alter the conformation of the amino terminus of gB, thus favoring one of the two predicted conformational structures that causes membrane fusion (34).The UL53 (gK) and UL20 genes encode multipass transmembrane proteins of 338 and 222 aa, respectively, which are conserved in all alphaherpesviruses (15, 42, 55). Both proteins have multiple sites where posttranslational modification can occur; however, only gK is posttranslationally modified by N-linked carbohydrate addition (15, 35, 55). The specific membrane topologies of both gK and UL20 protein (UL20p) have been predicted and experimentally confirmed using epitope tags inserted within predicted intracellular and extracellular domains (18, 21, 44). Syncytial mutations in gK map predominantly within extracellular domains of gK and particularly within the amino-terminal portion of gK (domain I) (18), while syncytial mutations of UL20 are located within the amino terminus of UL20p, shown to be located intracellularly (44). A series of recent studies have shown that HSV-1 gK and UL20 functionally and physically interact and that these interactions are necessary for their coordinate intracellular transport and cell surface expression (16, 18, 21, 26, 45). Specifically, direct protein-protein interactions between the amino terminus of HSV-1 UL20 and gK domain III, both of which are localized intracellularly, were recently demonstrated by two-way coimmunoprecipitation experiments (19).According to the most prevalent model for herpesvirus intracellular morphogenesis, capsids initially assemble within the nuclei and acquire a primary envelope by budding into the perinuclear spaces. Subsequently, these virions lose their envelope through fusion with the outer nuclear lamellae. Within the cytoplasm, tegument proteins associate with the viral nucleocapsid and final envelopment occurs by budding of cytoplasmic capsids into specific trans-Golgi network (TGN)-associated membranes (8, 30, 47, 70). Mature virions traffic to cell surfaces, presumably following the cellular secretory pathway (33, 47, 61). In addition to their significant roles in virus-induced cell fusion, gK and UL20 are required for cytoplasmic virion envelopment. Viruses with deletions in either the gK or the UL20 gene are unable to translocate from the cytoplasm to extracellular spaces and accumulated as unenveloped virions in the cytoplasm (5, 15, 20, 21, 26, 35, 36, 38, 44, 55). Current evidence suggests that the functions of gK and UL20 in cytoplasmic virion envelopment and virus-induced cell fusion are carried out by different, genetically separable domains of UL20p. Specifically, UL20 mutations within the amino and carboxyl termini of UL20p allowed cotransport of gK and UL20p to cell surfaces, virus-induced cell fusion, and TGN localization, while effectively inhibiting cytoplasmic virion envelopment (44, 45).In this paper, we demonstrate that the amino terminus of gK expressed as a free peptide of 82 aa (gKa) is transported to infected cell surfaces by viral proteins other than gK or UL20p and facilitates virus-induced cell fusion caused by syncytial mutations in the carboxyl terminus of gB. Thus, functional domains of gK can be genetically separated, as we have shown previously (44, 45), as well as physically separated into different peptide portions that retain functional activities of gK. These results are consistent with the hypothesis that the amino terminus of gK directly or indirectly interacts with and modulates the fusogenic properties of gB.     

Role of Septins in the Orientation of Forespore Membrane Extension during Sporulation in Fission Yeast

During yeast sporulation, a forespore membrane (FSM) initiates at each spindle-pole body and extends to form the spore envelope. We used Schizosaccharomyces pombe to investigate the role of septins during this process. During the prior conjugation of haploid cells, the four vegetatively expressed septins (Spn1, Spn2, Spn3, and Spn4) coassemble at the fusion site and are necessary for its normal morphogenesis. Sporulation involves a different set of four septins (Spn2, Spn5, Spn6, and the atypical Spn7) that does not include the core subunits of the vegetative septin complex. The four sporulation septins form a complex in vitro and colocalize interdependently to a ring-shaped structure along each FSM, and septin mutations result in disoriented FSM extension. The septins and the leading-edge proteins appear to function in parallel to orient FSM extension. Spn2 and Spn7 bind to phosphatidylinositol 4-phosphate [PtdIns(4)P] in vitro, and PtdIns(4)P is enriched in the FSMs, suggesting that septins bind to the FSMs via this lipid. Cells expressing a mutant Spn2 protein unable to bind PtdIns(4)P still form extended septin structures, but these structures fail to associate with the FSMs, which are frequently disoriented. Thus, septins appear to form a scaffold that helps to guide the oriented extension of the FSM.Yeast sporulation is a developmental process that involves multiple, sequential events that need to be tightly coordinated (59, 68). In the fission yeast Schizosaccharomyces pombe, when cells of opposite mating type (h⁺ and h⁻) are mixed and shifted to conditions of nitrogen starvation, cell fusion and karyogamy occur to form a diploid zygote, which then undergoes premeiotic DNA replication, the two meiotic divisions, formation of the spore envelopes (comprising the plasma membrane and a specialized cell wall), and maturation of the spores (74, 81). At the onset of meiosis II, precursors of the spore envelopes, the forespore membranes (FSMs), are formed by the fusion of vesicles at the cytoplasmic surface of each spindle-pole body (SPB) and then extend to engulf the four nuclear lobes (the nuclear envelope does not break down during meiosis), thus capturing the haploid nuclei, along with associated cytoplasm and organelles, to form the nascent spores (55, 68, 81). How the FSMs recognize and interact with the nuclear envelope, extend in a properly oriented manner, and close to form uniformly sized spherical spores is not understood, and study of this model system should also help to elucidate the more general question of how membranes obtain their shapes in vivo.It has been shown that both the SPB and the vesicle trafficking system play important roles in the formation and development of the FSM and of its counterpart in the budding yeast Saccharomyces cerevisiae, the prospore membrane (PSM). In S. pombe, the SPB changes its shape from a compact dot to a crescent at metaphase of meiosis II (26, 29), and its outer plaque acquires meiosis-specific components such as Spo2, Spo13, and Spo15 (30, 57, 68). This modified outer plaque is required for the initiation of FSM assembly. In S. cerevisiae, it is well established that various secretory (SEC) gene products are required for PSM formation (58, 59). Similarly, proteins presumably involved in the docking and/or fusion of post-Golgi vesicles and organelles in S. pombe, such as the syntaxin-1A Psy1, the SNAP-25 homologue Sec9, and the Rab7 GTPase homologue Ypt7, are also required for proper FSM extension (34, 53, 54). Consistent with this hypothesis, Psy1 disappears from the plasma membrane upon exit from meiosis I and reappears in the nascent FSM.Phosphoinositide-mediated membrane trafficking also contributes to the development of the FSM. Pik3/Vps34 is a phosphatidylinositol 3-kinase whose product is phosphatidylinositol 3-phosphate [PtdIns(3)P] (35, 72). S. pombe cells lacking this protein exhibit defects in various steps of FSM formation, such as aberrant starting positions for extension, disoriented extension and/or failure of closure, and the formation of spore-like bodies near, rather than surrounding, the nuclei, suggesting that Pik3 plays multiple roles during sporulation (61). The targets of PtdIns(3)P during sporulation appear to include two sorting nexins, Vps5 and Vps17, and the FYVE domain-containing protein Sst4/Vps27. vps5Δ and vps17Δ mutant cells share some of the phenotypes of pik3Δ cells (38). sst4Δ cells also share some of the phenotypes of pik3Δ cells but are distinct from vps5Δ and vps17Δ cells, consistent with the hypothesis that Pik3 has multiple roles during sporulation (62).Membrane trafficking processes alone do not seem sufficient to explain how the FSMs and PSMs extend around and engulf the nuclei, suggesting that some other mechanism(s) must regulate and orient FSM/PSM extension. The observation that the FSM is attached to the SPB until formation of the immature spore is complete (68) suggests that the SPB may regulate FSM extension. In addition, the leading edge of the S. cerevisiae PSM is coated with a complex of proteins (the LEPs) that appear to be involved in PSM extension (51, 59). S. pombe Meu14 also localizes to the leading edge of the FSM, and deletion of meu14 causes aberrant FSM formation in addition to a failure in SPB modification (60). However, it has remained unclear whether the SPB- and LEP-based mechanisms are sufficient to account for the formation of closed FSMs and PSMs of proper size and position (relative to the nuclear envelope), and evidence from S. cerevisiae has suggested that the septin proteins may also be involved.The septins are a conserved family of GTP-binding proteins that were first identified in S. cerevisiae by analysis of the cytokinesis-defective cdc3, cdc10, cdc11, and cdc12 mutants (41). Cdc3, Cdc10, Cdc11, and Cdc12 are related to each other in sequence and form an oligomeric complex that localizes to a ring in close apposition to the plasma membrane at the mother-bud neck in vegetative cells (12, 20, 25, 41, 47, 77). The septin ring appears to be filamentous in vivo (12), and indeed, the septins from both yeast (11, 20) and metazoans (31, 36, 69) can form filaments in vitro. The yeast septin ring appears to form a scaffold for the localization and organization of a wide variety of other proteins (8, 22), and it forms a diffusion barrier that constrains movement of membrane proteins through the neck region (7, 8, 73). In metazoan cells, the septins are involved in cytokinesis but are also implicated in a variety of other cellular processes, such as vesicular transport, organization of the actin and microtubule cytoskeletons, and oncogenesis (27, 70).In S. cerevisiae, a fifth septin (Shs1) is also expressed in vegetative cells, but the remaining two septin genes, SPR3 and SPR28, are expressed at detectable levels only during sporulation (15, 17). In addition, at least some of the vegetatively expressed septins are also present in sporulating cells (17, 48), and one of them (Cdc10) is expressed at much higher levels there than in vegetative cells (32). The septins present during sporulation are associated with the PSM (15, 17, 48, 51), and their normal organization there depends on the Gip1-Glc7 protein phosphatase complex (71). However, it has been difficult to gain insight into the precise roles of the septins during sporulation in S. cerevisiae (59), because some septins are essential for viability during vegetative growth, and the viable mutants have only mild phenotypes during sporulation (15, 17), possibly because of functional redundancy among the multiple septins.S. pombe seemed likely to provide a better opportunity for investigating the role of septins during spore formation. There are seven septin genes (spn1⁺ to spn7⁺) in this organism (23, 41, 63). Four of these genes (spn1⁺ to spn4⁺) are expressed in vegetative cells, and their products form a hetero-oligomeric complex that assembles during cytokinesis into a ring at the division site (2, 3, 10, 76, 79). The septin ring is important for proper targeting of endoglucanases to the division site (44), and septin mutants show a corresponding delay in cell separation (10, 41, 44, 76). However, even the spn1Δ spn2Δ spn3Δ spn4Δ quadruple mutant is viable and grows nearly as rapidly as the wild type (our unpublished results), a circumstance that greatly facilitates studies of the septins'' role during sporulation.spn5⁺, spn6⁺, and spn7⁺ are expressed at detectable levels only during sporulation (1, 45, 78; our unpublished results), and spn2⁺, like its orthologue CDC10 (see above), is strongly induced (45), but the roles of the S. pombe septins in sporulation have not previously been investigated. In this study, we show that the septins are important for the orientation of FSM extension, suggesting that the septins may have a more general role in dynamic membrane organization and shape determination.     

The Pentapeptide Repeat Proteins MfpAMt and QnrB4 Exhibit Opposite Effects on DNA Gyrase Catalytic Reactions and on the Ternary Gyrase-DNA-Quinolone Complex

MfpA_Mt and QnrB4 are two newly characterized pentapeptide repeat proteins (PRPs) that interact with DNA gyrase. The mfpA_Mt gene is chromosome borne in Mycobacterium tuberculosis, while qnrB4 is plasmid borne in enterobacteria. We expressed and purified the two PRPs and compared their effects on DNA gyrase, taking into account host specificity, i.e., the effect of MfpA_Mt on M. tuberculosis gyrase and the effect of QnrB4 on Escherichia coli gyrase. Whereas QnrB4 inhibited E. coli gyrase activity only at concentrations higher than 30 μM, MfpA_Mt inhibited all catalytic reactions of the M. tuberculosis gyrase described for this enzyme (supercoiling, cleavage, relaxation, and decatenation) with a 50% inhibitory concentration of 2 μM. We showed that the D87 residue in GyrA has a major role in the MfpA_Mt-gyrase interaction, as D87H and D87G substitutions abolished MfpA_Mt inhibition of M. tuberculosis gyrase catalytic reactions, while A83S modification did not. Since MfpA_Mt and QnrB4 have been involved in resistance to fluoroquinolones, we measured the inhibition of the quinolone effect in the presence of each PRP. QnrB4 reversed quinolone inhibition of E. coli gyrase at 0.1 μM as described for other Qnr proteins, but MfpA_Mt did not modify M. tuberculosis gyrase inhibition by fluoroquinolones. Crossover experiments showed that MfpA_Mt also inhibited E. coli gyrase function, while QnrB4 did not reverse quinolone inhibition of M. tuberculosis gyrase. In conclusion, our in vitro experiments showed that MfpA_Mt and QnrB4 exhibit opposite effects on DNA gyrase and that these effects are protein and species specific.The pentapeptide repeat protein (PRP) family includes more than 500 proteins in the prokaryotic and eukaryotic kingdoms (45). PRPs are characterized by the repetition of the pentapeptide repeat motif [S,T,A,V][D,N][L,F][S,T,R][G] (6), which results in a right-handed β-helical structure (8, 17). The functions of the majority of the members of this large and heterogeneous family remain unknown, but three PRPs, McbG (from Escherichia coli), MfpA_Mt (from Mycobacterium tuberculosis), and Qnr (from Klebsiella pneumoniae and other enterobacteria) were reported to interact with DNA gyrase, at least with the E. coli enzyme (17, 33, 35, 44). McbG was shown to protect E. coli DNA gyrase from the toxic action of microcin B17 (33). Qnr and MfpA_Mt were involved in resistance to fluoroquinolones, which are synthetic antibacterial agents prescribed worldwide for the treatment of various infectious diseases, including tuberculosis (7).DNA gyrase is an essential ATP-dependent enzyme that transiently cleaves a segment of double-stranded DNA, passes another piece of DNA through the break, and reseals it (12). DNA gyrase is unique in catalyzing the negative supercoiling of DNA in order to facilitate the progression of RNA polymerase. Most eubacteria, such as E. coli, have two type II DNA topoisomerases, i.e., DNA gyrase and topoisomerase IV, but a few, such as M. tuberculosis, harbor only DNA gyrase (11).Quinolones target type II topoisomerases, and their activity is measured by the inhibition of supercoiling by gyrase or decatenation by topoisomerase IV and stabilization of complexes composed of topoisomerase covalently linked to cleaved DNA (16). The DNA gyrase active enzyme is a GyrA₂GyrB₂ heterotetramer. The quinolone-gyrase interaction site in gyrase is thought to be located at the so-called quinolone resistance-determining regions (QRDR) in the A subunit (amino acids 57 to 196 in GyrA) and the B subunit (amino acids 426 to 466 in GyrB), which contain the majority of mutations conferring quinolone resistance (19). The GyrB QRDR is thought to interact with the GyrA QRDR to form a drug-binding pocket (18). Resistance to quinolones is usually due to chromosomal mutations either in the structural genes encoding type II topoisomerases (QRDR) (19, 22) or in regulatory genes producing decreased cell wall permeability or enhancement of efflux pumps (36). The recent emergence of plasmid-borne resistance genes, such as qnr (9, 13, 31, 38, 46), aac(6′)-Ib-cr (32, 39) and qepA (34, 47), renewed interest in quinolone resistance, and especially interest in the new Qnr-based mechanism. Three qnr determinants have been identified so far: qnrA (variants A1 to A6), qnrB (variants B1 to B19), and qnrS (variants S1 and S2) (15, 21, 23, 27). Qnr confers a new mechanism of quinolone resistance by mediating DNA gyrase protection (42): in vitro, QnrA1 and QnrB1 protect E. coli DNA gyrase and topoisomerase IV from the inhibitory effect of fluoroquinolones in a concentration-dependent manner (23, 42-44). Although Qnr was shown to bind GyrA and GyrB and compete with DNA binding, the consequences of Qnr binding for enzyme performance are not yet clear.mfpA, a chromosomal gene that encodes a 192-amino-acid PRP, is an intrinsic quinolone resistance determinant of Mycobacterium smegmatis (29). A similar gene, mfpA_Mt, was found in the M. tuberculosis genome, and MfpA_Mt shows 67% identity with MfpA. Recent crystallography analysis of MfpA_Mt showed that its atomic structure displays size, shape, and electrostatic similarity to B-form DNA, and MfpA_Mt has been suggested to interact with DNA gyrase via DNA mimicry (17). The effect of MfpA_Mt was studied by testing E. coli DNA gyrase, and MfpA_Mt showed catalytic inhibition (17, 37), but whether it protects gyrase from quinolones was not assessed. Because the structure and functions of the M. tuberculosis gyrase, as well as its interaction with quinolones, differ from those of the E. coli gyrase (2, 3, 20, 26, 28), we suspected that the PRP-topoisomerase interaction exhibits species specificity, i.e., depends on the proteins issued from the same host.Our objective was to compare the effects of MfpA_Mt and Qnr on their respective targets, i.e., the effect of MfpA_Mt on the M. tuberculosis gyrase and the effect of Qnr on the E. coli gyrase, by assessing (i) the catalytic reactions of the enzyme and (ii) the interaction with the DNA gyrase-DNA-fluoroquinolone ternary complex. Among the Qnr proteins, we selected the QnrB4 protein, which is a frequent variant of QnrB and has not yet been purified and studied. We cloned, expressed, and purified the two PRPs, MfpA_Mt and QnrB4, as recombinant His tag fusion proteins and assessed their functions under the same experimental conditions.     

Construction of Mycobacterium abscessus Defined Glycopeptidolipid Mutants: Comparison of Genetic Tools

Mycobacterium abscessus is a rapidly growing mycobacterial species that can be involved in pulmonary and disseminated infections in immunosuppressed or young cystic fibrosis patients. It is an emerging pathogen and has attracted recent attention due to the numerous cases of infection; furthermore, genomic tools have been developed for this species. Nevertheless, the study of this species has until now been limited to spontaneous variants. We report here a comparison of three different mutagenesis systems—the ts-sacB, the phage, and the recombineering systems—and show that there are important differences in their efficiency for the construction of allelic-exchange mutants. We show, using the mmpL4b gene of the glycopeptidolipid pathway as a target, that allelic-exchange mutants can be constructed with a reasonable efficiency (∼7%) using the recombineering system. These observations will facilitate genetic and cellular microbiology experiments involving the construction and use of well-defined mutants to study the virulence determinant of this emerging pathogen.The mycobacterial genus contains plethora of species that are pathogenic for either humans or animals. The most well-known are undoubtedly Mycobacterium leprae, M. tuberculosis, and M. ulcerans, the etiologic agents of human leprosy, tuberculosis, and Buruli ulcer, respectively (47-49). M. avium subsp. paratuberculosis, responsible for Johnes disease in ruminants, is also a serious health concern since it is suspected to be a threat to human via infected milk (9, 10). M. abscessus is an emerging pathogen involved in pulmonary and disseminated infection in young cystic fibrosis patients (26, 36). M. abscessus can cause nosocomial infections of skin and soft tissues in immunosuppressed patients (28, 35). It is also able to cross the blood-brain barrier and to cause meningoencephalitis (42). M. abscessus is phylogenetically related to M. chelonae and, indeed, these species have long been grouped together under the designation of the “M. abscessus-chelonae complex” (6). M. abscessus is a rapid grower that forms colonies in 5 days. Like other mycobacterial species, M. abscessus is equipped with a robust waxy cell wall that, as in other species, probably contributes to virulence (12). The emerging and growing interest in M. abscessus has led to its genome being sequenced (accession no. NC010397) (F. Ripoll et al., unpublished data) and to the development of DNA microarrays (Jean-Yves Coppée, unpublished data).The availability of genomic resources and animal models (32) makes M. abscessus a very attractive system. However, there is no defined mutagenesis system for this species and, to the best of our knowledge, no defined mutants have been constructed thus far. The consequence is that the study of this organism has been restricted to spontaneous variants. Utilization of spontaneous mutants has, nevertheless, allowed the characterization of morphotypically rough isolates that are hypervirulent both in vitro and in vivo (7, 8, 17). These rough isolates are low glycopeptidolipid producers. Glycopeptidolipid is an extractable lipid found at the surface of the bacilli (4, 11, 13). However, its role in the virulence process is currently unknown. The lack of a suitable genetic system is certainly responsible for the rarity of studies on this species (fewer than 500 references in Medline, whereas there are more than 32,000 for M. tuberculosis). Other mycobacterial species, especially M. tuberculosis, have been genetically intractable for many years (15, 18, 24). This has forced researchers to develop dedicated systems for the construction of allelic-exchange mutants. Three major systems have mainly been used thus far in M. tuberculosis and in other mycobacteria: (i) a thermosensitive counterselectable plasmid based on sucrose sensitivity (21-23), (ii) a thermosensitive mycobacteriophage (2) and, more recently, (iii) a mycobacterial recombinase-based system (43, 44). These three systems are effective in M. tuberculosis, M. smegmatis, and other refractory species, including M. avium subsp. avium, and allow straightforward construction of both marked and unmarked mutants.The aim of the present study was to compare the three main mutagenesis systems available for mycobacteria and to determine which system is best adapted to M. abscessus. To this end, we used mmpL4b as a target gene and the three genetic tools described above. The mmpL4b gene is involved in glycopeptidolipid synthesis (29, 40) and is a good model target because its mutation results in a rough phenotype that can be visually distinguished. We show here that there are large differences in efficacy between the three systems and that the mycobacterial recombinase-based system is the most efficient. For an unknown reason, allelic exchange is much less frequent in M. abscessus than in other species, including M. tuberculosis; this complicates the construction of defined mutants. The availability of a suitable genetic system will undoubtedly facilitates the characterization of the virulence determinants in this emerging pathogen.     

Cytoskeletal Asymmetrical Dumbbell Structure of a Gliding Mycoplasma,Mycoplasma gallisepticum,Revealed by Negative-Staining Electron Microscopy

Several mycoplasma species feature a membrane protrusion at a cell pole, and unknown mechanisms provide gliding motility in the direction of the pole defined by the protrusion. Mycoplasma gallisepticum, an avian pathogen, is known to form a membrane protrusion composed of bleb and infrableb and to glide. Here, we analyzed the gliding motility of M. gallisepticum cells in detail. They glided in the direction of the bleb at an average speed of 0.4 μm/s and remained attached around the bleb to a glass surface, suggesting that the gliding mechanism is similar to that of a related species, Mycoplasma pneumoniae. Next, to elucidate the cytoskeletal structure of M. gallisepticum, we stripped the envelopes by treatment with Triton X-100 under various conditions and observed the remaining structure by negative-staining transmission electron microscopy. A unique cytoskeletal structure, about 300 nm long and 100 nm wide, was found in the bleb and infrableb. The structure, resembling an asymmetrical dumbbell, is composed of five major parts from the distal end: a cap, a small oval, a rod, a large oval, and a bowl. Sonication likely divided the asymmetrical dumbbell into a core and other structures. The cytoskeletal structures of M. gallisepticum were compared with those of M. pneumoniae in detail, and the possible protein components of these structures were considered.Mycoplasmas are commensal and occasionally pathogenic bacteria that lack a peptidoglycan layer (50). Several species feature a membrane protrusion at a pole; for Mycoplasma mobile, this protrusion is called the head, and for Mycoplasma pneumoniae, it is called the attachment organelle (25, 34-37, 52, 54, 58). These species bind to solid surfaces, such as glass and animal cell surfaces, and exhibit gliding motility in the direction of the protrusion (34-37). This motility is believed to be essential for the mycoplasmas'' pathogenicity (4, 22, 27, 36). Recently, the proteins directly involved in the gliding mechanisms of mycoplasmas were identified and were found to have no similarities to those of known motility systems, including bacterial flagellum, pilus, and slime motility systems (25, 34-37).Mycoplasma gallisepticum is an avian pathogen that causes serious damage to the production of eggs for human consumption (50). The cells are pear-shaped and have a membrane protrusion, consisting of the so-called bleb and infrableb (29), and gliding motility (8, 14, 22). Their putative cytoskeletal structures may maintain this characteristic morphology because M. gallisepticum, like other mycoplasma species, does not have a cell wall (50). In sectioning electron microscopy (EM) studies of M. gallisepticum, an intracellular electron-dense structure in the bleb and infrableb was observed, suggesting the existence of a cytoskeletal structure (7, 24, 29, 37, 58). Recently, the existence of such a structure has been confirmed by scanning EM of the structure remaining after Triton X-100 extraction (13), although the details are still unclear.A human pathogen, M. pneumoniae, has a rod-shaped cytoskeletal structure in the attachment organelle (9, 15, 16, 31, 37, 57). M. gallisepticum is related to M. pneumoniae (63, 64), as represented by 90.3% identity between the 16S rRNA sequences, and it has some open reading frames (ORFs) homologous to the component proteins of the cytoskeletal structures of M. pneumoniae (6, 17, 48). Therefore, the cytoskeletal structures of M. gallisepticum are expected to be similar to those of M. pneumoniae, as scanning EM images also suggest (13).The fastest-gliding species, M. mobile, is more distantly related to M. gallisepticum; it has novel cytoskeletal structures that have been analyzed through negative-staining transmission EM after extraction by Triton X-100 with image averaging (45). This method of transmission EM following Triton X-100 extraction clearly showed a cytoskeletal “jellyfish” structure. In this structure, a solid oval “bell,” about 235 nm wide and 155 nm long, is filled with a 12-nm hexagonal lattice. Connected to this bell structure are dozens of flexible “tentacles” that are covered with particles 20 nm in diameter at intervals of about 30 nm. The particles appear to have 180° rotational symmetry and a dimple at the center. The involvement of this cytoskeletal structure in the gliding mechanism was suggested by its cellular localization and by analyses of mutants lacking proteins essential for gliding.In the present study, we applied this method to M. gallisepticum and analyzed its unique cytoskeletal structure, and we then compared it with that of M. pneumoniae.