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Buruli Ulcer: Reductive Evolution Enhances Pathogenicity Of Mycobacterium Ulcerans

The human skin disease that results from infection with Mycobacterium ulcerans is commonly known as Buruli ulcer (BU), but would have been called Bairnsdale ulcer if microbiological history had been strictly respected. In 1935, a series of unusual, painless ulcers in patients from a remote farming community in the Bairnsdale district of south-east Australia was reported1. Some 13 years later, Australian researchers discovered the aetiological agent of Bairnsdale ulcer, a previously unknown mycobacterium that they named M. Ulcerans2. During the 1960s, many cases of infection with M. Ulcerans were reported in Uganda, particularly in Buruli County (now known as the Nakasongola district), and thus the disease became more generally known as BU. Today, the disease is far more widespread in West and Central Africa, especially among impoverished rural communities, although other parts of the world are also affected. Thirty countries, mainly in the tropics, have reported cases of BU and in some settings, such as Ghana or Benin, BU is now more prevalent than leprosy3.

During the past 10 years, there has been considerable progress in our understanding of the ecology, aetiology and microbiology of BU, which has led to better definition of risk factors and awareness of the potential role of insects in transmission of the disease. Comparative mycobacterial genomics has underpinned these advances and provided compelling evidence for the emergence of M. Ulcerans as a pathogen through horizontal gene transfer of a virulence plasmid. Here, we review the current state of our knowledge and comment on prospects for disease control.

Physiopathology and medical interventions

M. Ulcerans produces mycolactone, a macrolide cytotoxin with immunosuppressive properties that is present in the extracellular matrix surrounding large clusters of M. Ulcerans cells organized as a biofilm4. BU begins as a small, painless, raised skin papule, nodule, plaque or oedema. Osteomyelitis may occur in bone adjacent to a cutaneous lesion. Later, destruction of the subcutaneous adipose tissue leads to collapse of the epidermis and formation of a characteristic ulcer with undermined edges5,6,7 (Fig. 1). Advanced lesions display massive tissue destruction and minimal inflammation, with extracellular microcolonies of M. Ulcerans in the superficial necrotic areas8. Despite some anti-phagocytic activity of mycolactone, phagocytes can internalize M. Ulcerans in vitro, although this culminates in host cell death9,10. In contrast to wild-type strains, mycolactone-deficient mutants generate inflammation in the guinea pig model11, suggesting that production of mycolactone by intracellular bacteria can suppress innate inflammatory responses to infection in vivo.

Figure 1: Disease progression.

The progression from the pre-ulcerative to the ulcerative and healing stages of Buruli ulcer disease is shown. The width of the green, red and yellow shapes denotes the extent of the progression for bacterial load, necrosis and inflammatory responses, respectively.

The physiopathology of BU is closely associated with diffusion of the toxin from bacterial foci, as first suspected from histopathological studies of infected tissues12. Injection of mycolactone is sufficient to induce necrotic lesions in the skin of guinea pigs13, by an apoptosis-dependent mechanism14. Consistent with the extensive tissue damage observed, mycolactone kills a range of mammalian cells15, but the molecular basis of mycolactone-induced apoptosis nevertheless remains unclear. Indeed, studies that used mouse fibroblasts in vitro indicate that apoptosis follows cytopathic effects, including cytoskeletal rearrangements and cell-cycle arrest13,14.

Although M. Ulcerans displays no tropism for schwann cells, nerve invasion occurs at the perineural and endoneural levels, causing degeneration16. Similar alterations are induced by injecting purified toxin into mice17, suggesting that mycolactone diffuses into Schwann cells in vivo to cause the painlessness that characterizes the disease. A surprising feature of BU is the scarcity of secondary infections of these immunosuppressed open wounds, which raises the possibility that M. Ulcerans produces secondary metabolites with anti-microbial activity (WHO provides a method for diagnosing secondary bacterial infection in M. Ulcerans disease; see Further information).

BU is usually diagnosed on the basis of clinical findings, occasionally confirmed by microscopy, but to treat disease more effectively it is essential to develop novel, field-friendly diagnostic approaches to allow earlier identification of patients. The extensive cross-reactivity among mycobacterial antigens complicates the use of specific serological assays18, although the unique ability of M. Ulcerans to produce mycolactone makes this toxin an attractive candidate for the development of diagnostic tests. However, this hydrophobic molecule is not immunogenic, and attempts to raise anti-mycolactone antibodies have been unsuccessful.

Treatment of BU remains complicated and generally requires both surgery, sometimes accompanied by skin grafts, and prolonged courses of antibiotics. WHO recommends that a combination of rifampicin (oral) and streptomycin (intramuscular) be administered daily for 8 weeks19. However, although results from this treatment are encouraging (4 weeks of treatment leads to culture negativity), most patients need to be hospitalized owing to the frequency, duration and route of antibiotic administration. New drugs are clearly needed to treat this disease and better biomarkers are required to monitor the therapeutic response of patients.

There is no vaccine against M. Ulcerans, although significant, but short-lasting, protection against BU has been reported following immunization with the Mycobacterium bovis bacille Calmette–GuĂ©rin (BCG) vaccine20. Prospects for vaccine development include modified BCGs and subunit-based vaccines21. DNA vaccines that encode antigen 85A and the heat-shock protein Hsp65 have been shown to protect mice against M. Ulcerans infection22,23,24,25. However, these vaccines remain less protective than BCG in mice, even when administered in DNA-prime–boost protocols. Comparative genomics could open new avenues for vaccine research and improved diagnostics.

Epidemiology, risk factors and insect vectors

The epidemiology of BU is poorly understood and outbreaks are sporadic and unpredictable; however, proximity to, or contact with, slowly flowing or stagnant watercourses is a recognized risk factor26,27,28. Furthermore, disease is often confined to specific areas and has sometimes appeared following major environmental changes, such as deforestation, flooding, or the introduction of dams and irrigation systems29. In Benin, for example, the incidence of BU is tenfold greater in areas that have undergone environmental perturbation compared with control areas29.

In these settings, M. Ulcerans is associated with aquatic vegetation, such as plants and algae30, whereas snails and other organisms that feed on this vegetation can serve as passive hosts31. Portaels and colleagues were the first to use PCR-based detection methods to investigate a role for insect vectors in transmission32. Other groups have performed similar environmental surveys to uncover likely niches of M. Ulcerans. M. Ulcerans from environmental specimens is notoriously difficult and unreliable to culture owing to the long generation time of the pathogen (>48 hours) and overgrowth by contaminants, including other mycobacteria. PCR is more reliable but is not foolproof, as one of the diagnostic PCR targets, Insertion sequence (IS) 2404, is not restricted to M. Ulcerans. Other targets also reside on the virulence plasmid, and the plasmid can be transferred to other species33. Such PCR methods have been used to detect M. Ulcerans in aquatic samples, including water, mud, plants, insects, molluscs and fish, from endemic areas.

An important series of experiments performed by Marsollier and colleagues34 showed that M. Ulcerans is carried and multiplies in the water bug, Naucoris cimicoides. Using two different methods of infection, either feeding N. Cimicoides with larvae containing M. Ulcerans or directly injecting the bacteria, these investigators showed not only that the bacterium became established in N. Cimicoides but also that the transmission of M. Ulcerans to laboratory mice occurred through biting, leading to the appearance of necrotic lesions that were reminiscent of BU in humans34.

Details are available of the trafficking of M. Ulcerans through N. Cimicoides in captivity35,36. The plasmatocytes in the coelomic cavity of the water bug phagocytose M. Ulcerans and, as part of their circulatory process, transport the bacteria to the salivary glands where large-scale multiplication occurs35. Only toxin-producing M. Ulcerans isolates can invade the salivary glands, and mycolactone is therefore key to both the early and long-term establishment of M. Ulcerans in members of the Naucoridae family. Later, the raptorial legs of the insect are covered by biofilms that contain M. Ulcerans, which could be important for transmission of the disease without biting35,36.

N. Cimicoides is a carnivorous organism that preys on other insects, snails and small fish, but it does not normally bite humans, which weakens the possibility that biting is the main route of infection of humans. However, in a recent serological survey of healthy individuals in a BU-endemic region, high titres of antibodies were found to N. Cimicoides salivary proteins37, indicating that humans can indeed be bitten. Importantly, immunization of mice with saliva from uninfected N. Cimicoides conferred protection against subsequent infection with M. Ulcerans from contaminated water bugs.

In a landmark study from Benin, M. Ulcerans was isolated from the water strider (Gerris sp. From the aquatic order Hemiptera) in pure culture. Following isolation of the pathogen and infection of mice, the M. Ulcerans strain was shown to be genetically and phenotypically identical to that isolated from patients living in the same region38. However, the water strider, like the Naucoridae, generally avoids humans.

During the past decade, there have been several outbreaks of BU disease, both in residents and visitors, in parts of south-east Australia, and this provided an ideal setting to study disease transmission. Using PCR, a strong association was found between M. Ulcerans and mosquitoes, predominantly Aedes camptorhynchus39. The incidence of BU rose in the spring and summer, and was followed by a cluster of human cases in the autumn and winter months. From this survey, it was estimated that the incubation period for BU was 3–4 months39. Furthermore, a bimodal pattern was observed, in which peaks represented young children and the elderly; this was similar to the pattern observed in West Africa, with the exception that in south-east Australia the disease was less common in children40,41. One possible explanation for this difference lies in the more pronounced exposure to possible insect vectors, and the accompanying immunity to M. Ulcerans, among the adult African population37.

A parallel case-control study revealed that the risk of BU was halved in the group that took precautions against insect bites by applying insect repellent, wearing protective clothing or washing minor skin wounds42. This strongly suggests that M. Ulcerans is transmitted to humans by mosquito bites but, in turn, raises questions as to how the mosquitoes themselves become infected. Such contamination could occur at the larval stage from the water where the mosquitoes breed or through blood meals from other infected hosts. The conclusions of an extensive case-control study in a BU-endemic region of Cameroon are also consistent with transmission through insect bites, as protection was observed if bed nets were used in the home43. However, a large temporal and spatial survey conducted across Ghana of 15 BU-endemic and 12 BU-non-endemic areas revealed no association between biting hemipterans and M. Ulcerans44. From these and other epidemiological studies, there is little evidence for person-to-person transmission. In summary, although there is now a substantial body of evidence to indicate an association between M. Ulcerans and different insects that share the same aquatic ecosystem, the actual means of transmission to humans remains elusive. Here, the availability of new molecular and immunological tools should help.

Genetically similar, phenotypically distinct

Despite their contrasting phenotypes, M. Ulcerans and M. Marinum have almost identical genome sequences (Fig. 2a). M. Ulcerans replicates slowly and produces no photochromogenic pigments. By contrast, M. Marinum doubles every 6–11 hours and produces no mycolactone, but is photochromogenic and has a dichotomous lifestyle: M. Marinum lives in diverse aquatic niches as well as a range of different intracellular environments, from free-living aquatic amoebae and fish to macrophages from both frogs and humans45. In aquatic species, M. Marinum causes a disseminated granulomatous disease that resembles dermal infection with Mycobacterium tuberculosis 46. In humans, however, it provokes relatively minor granulomatous skin lesions, usually on the cooler extremities of the body.

Figure 2: Phylogenetic analysis and evolutionary scenario for Mycobacterium ulcerans, Mycobacterium marinum and Mycobacterium tuberculosis inferred from genomics.

a16S rRNA phylogeny of the slow-growing mycobacteria, showing the relationship of M. Ulcerans (highlighted in red) and M. Marinum (highlighted in green) to M. Tuberculosis (highlighted in blue) and other mycobacterial pathogens101. The purple line indicates defined clusters, such as M. Marinum, M. Ulcerans and the mycolactone-producing mycobacteria. BThe evolutionary history of M. Marinum, M. Ulcerans (indicated by a dashed red oval) and other mycolactone-producing mycobacteria (indicated by a dashed green oval) was inferred using the neighbour-joining method102 from multilocus sequence data33. The bootstrap consensus tree was inferred from 1,000 replicates and was assumed to represent the evolutionary history of the taxa analysed103. Branches that correspond to partitions reproduced in less than 50% of the replicates were collapsed. The tree is drawn to scale, and branch lengths represent the evolutionary distances used to infer the phylogenetic tree. The first, second and third codon positions were included, and a total of 3,210 positions were included in the final data set. Phylogenetic analyses were conducted in MEGA4 (molecular evolutionary genetics analysis 4)104. Complete genome sequences were available for strains of the sequence types (STs) highlighted in red; the number of genome sequences available and their phylogenetic and geographical origin are indicated in brackets. The strain isolated from humans is indicated in pink. The yellow triangle shows that part b is an expansion of a section of the tree shown in part a. CWhole-genome DNA-composition analyses of four mycobacterial genomes generated with gene spaghetti, a method for visualizing DNA base composition variation and the use of codons in a genome. The gradient of colours reflects the AT skew (T − A)/(T + A), from 60% T-rich (dark red) to 60% A-rich (dark blue). The florid gene-spaghetti patterns for M. Ulcerans, M. Marinum and M. Tuberculosis reflect the important contribution of lateral gene transfer to the evolution of these species compared with M. Smegmatis. The average percentage amino-acid identity between each species is also indicated (in bold) for a core set of 1,072 orthologous coding DNA sequences that were identified by whole genome comparisons between these species.

Early phylogenetic work that applied multilocus sequence analysis (MLSA) revealed a clear delineation between strains of M. Ulcerans and M. Marinum, and indicated that all M. Ulcerans strains have evolved from a common M. Marinum progenitor47,48,49,50. MLSA also highlighted phylogeographical clonality among M. Ulcerans strains (Fig. 2b), in which isolates from several African countries, South East Asia and both northern and south-eastern Australia belonged to three distinct genotypes, whereas strains from Japan and China were represented by two closely related genotypes and strains from Mexico and Suriname were represented by distinct genotypes50,51. These data have been corroborated and refined by microarray analyses52,53. Structural differences in mycolactone are also observed in strains of different genotype. Interestingly, the M. Ulcerans isolates from South East Asia and Australia are more closely related to the African genotype than to strains from elsewhere. The lack of sequence diversity among the African isolates suggests that this M. Ulcerans clone spread recently throughout Africa. The availability of complete genome sequences from an African epidemic strain of M. Ulcerans (strain Agy99, isolated from Ghana in 1999) and a strain of clinical M. Marinum (strain M) confirmed this evolutionary scenario, highlighting how horizontal gene transfer and reductive evolution have remodelled an M. Marinum progenitor into M. Ulcerans (Fig. 2c).

In silico genomic comparisons of M. Ulcerans with M. Marinum confirmed the close genetic relationship between these species, as they shared more than 4,000 orthologous and syntenic protein-coding DNA sequences (CDSs) (Table 1) and had an average sequence identity of 98.3%. This analysis also revealed that M. Ulcerans had lost over 1.1 Mb of DNA owing to deletions (Table 1), whereas 168 kb had been acquired by M. Marinum, mostly in the form of 10 prophages. Also evident were many chromosome rearrangements that were facilitated, at least in part, by the high number of IS2404 (213 copies) and IS2606 (91 copies), which disrupt >110 genes54. All M. Ulcerans strains tested have 11 chromosomal CDSs that seem to be specific to this bacterium and might, in conjunction with mycolactone, contribute to the pathology associated with BU. These genes, and their products, could also be used to develop new diagnostic tests54.

Table 1 Genomic comparisons of Mycobacterium marinum and Mycobacterium ulcerans

M. Ulcerans has thus evolved through lateral gene transfer and reductive evolution, acquisition of the virulence plasmid pMUM001 (the role of which is discussed below), massive expansion of IS2404 and IS2606, extensive pseudogene formation, genome rearrangements and gene deletion. Like Yersinia pestis 55 and Bordetella pertussis 56, M. Ulcerans has all the characteristics of a bacterium that has recently passed through an evolutionary bottleneck and is adapting to a new niche environment. The challenge remains to find that niche, and in this respect, genomics may hold some clues.

Loss or gain of virulence and immunogenicity?

The trend that has emerged from reductive evolution in M. Ulcerans is the loss of many virulence factors and immunogens compared with its M. Marinum progenitor (Table 1) and the gain of an immunosuppressive cytotoxin (Fig. 3). Most noteworthy is the drastic reduction in the cell surface proteins PE and PPE from 281 in M. Marinum to 115 in M. Ulcerans, accompanied by depletion of the related ESX secretion systems and their effector proteins. PE and PPE proteins have characteristic amino-terminal domains and biased amino-acid content, as they are particularly rich in glycine and alanine. They are restricted to mycobacteria, where they are found in the cell envelope, but their precise function is unknown. The ESX loci, which encode type VII secretion systems57, are required to export members of the ESAT-6 (6 kDa early secretory antigenic target) protein family and specific effectors, such as EspA (ESX-1 secretion-associated protein A)58. In at least one case, ESX-1, they are major contributors to mycobacterial virulence.

Figure 3: Proposed pathway for the biosynthesis of mycolactone A and B.

The mls cluster and accessory gene arrangement of pMUM001, as well as the domain and module organization of the mycolactone polyketide synthase (PKS) genes, are shown. The different domains of each of the three Mls proteins (MlsA1, MlsA2 and MlsB) are represented by the coloured blocks described in the key. Module arrangements are depicted below each protein. The module responsible for a particular chain extension and the modified substrate are shown tethered to the acyl carrier protein domain of each extension module. Key steps in the biosynthesis pathway are shown and the enzyme involved is indicated if known. A question mark indicates that the enzymes involved have not yet been identified or in the case of MUP_038 and MUP_045 have not been definitively proven. The dashed red circle indicates that the hydroxyl group is catalysed by MUP_053. LM, loading module.

A few examples merit comment. In M. Marinum, LipY is an immunodominant PPE protein with triacylglycerol hydrolase activity59, yet its gene has been deleted by M. Ulcerans. In another example, the ESX secretome was depleted from five systems to three54. Consequently, the protein substrates these systems export — including potent T-cell antigens, such as ESAT-6, which have important roles in granuloma formation and other aspects of pathogenesis58, and the EspA effector proteins60, which have been reduced from 18 paralogues in M. Marinum to two in M. Ulcerans — will be missing or less abundant. A recent study examined a wide range of M. Ulcerans strains for disruption to the ESX loci, and found that although some strains exhibit the same pattern as M. Ulcerans Agy99, others have acquired independent deletions or loss-of-function mutations in these regions. This suggests that loss of ESX loci provides a selective advantage for mycolactone producers61 or, alternatively, that gain of a powerful cytotoxin renders these virulence factors superfluous.

Phenolic glycolipids (PGLs) are abundant cell-wall components, antigens and major virulence factors for several mycobacterial pathogens and can modulate innate immunity62. In M. Marinum, PGLs are synthesized by glycosylation of a highly apolar and abundant polyketide-derived methyl-branched lipid intermediate called phenolphthiodiolone. M. Ulcerans also synthesizes prodigious quantities of phenolphthiodiolone but cannot make PGL, as the gene for the glycosyl transferase that adds the rhamnosyl moiety (locus tag MUL_1998) is inactive54,63. These observations are summarized in Table 1.

Other gene losses from M. Ulcerans give some clues as to its habitat. For example, phytoene dehydrogenase, encoded by crti, is an essential enzyme for the biosynthesis of light-inducible carotenoid pigments by M. Marinum. These pigments protect the bacterium from damage following exposure to sunlight64. M. Ulcerans has an identical pigment locus to M. Marinum but its crtI gene has a premature stop codon, suggesting that its pigments are not required for survival, presumably because the bacterium is not exposed to sunlight. Another observation from the M. Ulcerans genome is that the pathways for anaerobic respiration have been lost, indicating that the bacterium might occupy an aerobic or microaerophilic environment. Together, these data provide a profile of a bacterium that has adapted to a dark and aerobic environment where slow growth, decreased ESX-mediated virulence and production of mycolactone provide an advantage for survival. This profile also suggests that we may need to think more broadly and look more widely than aquatic invertebrates to find the true reservoir of this pathogen.

Mycolactone production

A major finding from the M. Ulcerans genome project was the virulence plasmid pMUM001 (Refs 65, 66), which carries a cluster of three large genes (mlsA1, mlsA2 and mlsB, which are 51 kb, 7.6 kb and 43 kb in size, respectively) that encode type I polyketide synthases (PKSs) (Fig. 3). Like type I fatty acid synthases, type I PKSs contain the multiple enzymatic activities that are required for one round of chain extension and modification in a single polypeptide. Detailed analysis of their predicted module and domain structure strongly suggested that these PKSs produce mycolactone, and this was subsequently confirmed by transposon mutagenesis66.

Together, MlsA1 and MlsA2 constitute a loading module and nine extension modules that synthesize the macrolactone core and upper side chain, whereas MlsB, with its loading module and seven extension modules, produces the acyl side chain. The proposed biosynthesis pathway for mycolactone is shown in Fig. 3, and highlights the sequential incorporation and modification of either acetate or propionate subunits at each extension module. PMUM001 also harbours three additional CDSs that encode putative auxiliary enzymes for mycolactone synthesis (Fig. 3). Cyp140A7 is a cytochrome P450 hydroxylase that probably hydroxlates C-12′ of the mycolactone side chain67,68,69. Experimental evidence is lacking for the remaining two enzymes, a type II thioesterase (locus tag MUP_038) and a FabH-like ketosynthase (locus tag MUP_045), but they may play parts in chain termination and transfer of the mycolactone acyl side chain to the core15 (Fig. 3).

There are only a few reports of biochemical studies of the mycolactone PKS. The ketoreductase domains have been expressed and their enzymatic function confirmed70. A similar study with the integral thioesterase domains of MlsA2 and MlsB71 (Fig. 3), which may release the mature polyketide chain, revealed little activity, suggesting that these domains may be inactive in the Mls complex71. A proteomic investigation identified MlsA1, MlsB, Cyp140A7 and MUP_045 in association with both the cytoplasmic and membrane fraction, indicating that synthesis occurs close to the membrane, which could facilitate mycolactone export72 (Fig. 3).

Different strains of M. Ulcerans, and close relatives from fish and frogs, produce at least five structurally distinct mycolactones, named mycolactone A/B, C, D, E and F73,74,75,76,77. M. Ulcerans strains from Africa, Malaysia and Japan produce mycolactone A/B, Australian strains produce mycolactone C, Chinese strains produce mycolactone D and Mycobacterium liflandii and Mycobacterium pseudoshottsii produce the unique mycolactones E and F, respectively15. The mycolactone type produced by South American strains is unknown. Immunosuppressive and cytotoxic activity measurements revealed a convenient 'alphabetical' gradient in which mycolactone A/B is the most potent and mycolactone F is the least potent67. Interestingly, all mycolactones have a conserved core structure, and any variation occurs in the length, methyl branching, oxidation state and stereochemistry of the acyl side chain15.

Mycolactone-producer evolution

Mycolactone-producing mycobacteria have been recovered from fish and frogs around the world, but so far have not been associated with human disease. Based on minor phenotypic differences, they were given species names, such as M. Pseudoshottsii, M. Liflandii and M. Marinum15,49,69,73,78. However, thorough phylogenetic comparisons (Fig. 2b) have shown that all mycolactone producers are closely related to M. Ulcerans and have evolved from a common M. Marinum progenitor to form a genetically cohesive group among a more diverse assemblage of M. Marinum strains49. Like M. Ulcerans, the fish and frog strains have a virulence plasmid and multiple copies of IS2404, but the pattern of DNA deletion and pseudogene accumulation seems to be different: only those strains that cause BU had reduced genomes. Comparisons of plasmid and chromosomal gene sequences show that plasmid acquisition, and the subsequent ability to produce mycolactone, was probably the key driver of speciation. As these mycolactone producers then radiated around the world, ongoing evolution produced at least two genetically distinct ecotypes that can be broadly divided into those that typically cause disease in ectotherms, such as fish and frogs, and those that typically cause disease in endotherms, such as humans.

Molecular target of mycolactone

Despite efforts from many research groups, the molecular target of mycolactone and the mechanism used by the toxin to suppress immune cell functions remain mysterious. The structure of mycolactone resembles that of the immunosuppressive agents FK506 and rapamycin (Box 1). However, mycolactone has different effects on dendritic cell (DC) and T-cell immunobiology, suggesting that the toxin might bind to a different receptor and interfere with distinct signalling pathways. A fluorescent derivative of mycolactone and a 14C-labelled form of the toxin were both found to accumulate in a time- and dose-dependent manner in the cytoplasm of treated cells79 (C.D., unpublished observations), which supports the idea that mycolactone diffuses passively into target cells to interact with a cytosolic receptor. So far, structure–function studies have been limited to natural mycolactones. Strategies for the generation of additional mycolactone variants are required to investigate further the molecular mechanism of mycolactone action. In addition, detoxified variants of mycolactone might compete with mycolactone for receptor binding, and could therefore constitute valuable functional inhibitors of toxin. These could eventually become novel anti-BU therapeutics.

Suppression of immune cell functions

Although the basis of mycolactone cytotoxicity remains obscure, our understanding of the mechanism of mycolactone-induced immunosuppression has progressed. However, drawing conclusions on the type of immune response that is mounted in humans against M. Ulcerans infection is rendered difficult by apparently contradictory results. In vitro studies show unambiguously that non-toxic doses of mycolactone are immunosuppressive on professional antigen-presenting cells. The most striking finding is the complete inhibition of tumour necrosis factor (TNF) production by monocytes and macrophages following infection with M. Ulcerans or incubation with exogenous mycolactone9,25,80. Notably, bacterial production of mycolactone was also found to suppress the capacity of DCs to prime cellular responses and produce chemotactic signals that are crucial for inflammatory responses81 (Fig. 4). This selective effect of mycolactone on the ability of immature DCs to secrete chemoattractants for monocytes and T helper 1 (TH1) lymphocytes is in accordance with the histopathology of BU, and supports the idea that local production of mycolactone in the skin prevents the trafficking of inflammatory cells to the ulcerative lesion.

Figure 4: Model of the cytotoxic and immunosuppressive actions of mycolactone in vivo.

The triangle illustrates the gradient of mycolactone concentration from infectious foci in the skin to internal tissues, and the associated biological effects. The multiple immunosuppressive properties of mycolactone on dendritic cells (DCs) are shown, and their consequences on the initiation of primary immune responses and recruitment of inflammatory cells to the site of infection indicated81. CCL, C-C motif chemokine; CXCL10, C-X-C motif chemokine 10; MHC, major histocompatibility complex, TCR, T-cell receptor.

However, these results seem to contradict quantitative studies of intralesional mRNA which indicate that the innate immune system is activated at the site of BU lesions, as shown by high mRNA levels for the cytokines interferon-γ (IFN-γ), interleukin-1β (IL-1β), IL-6, IL-10, IL-12, IL-15 and TNF, and the chemokine IL-8 (Refs 7, 82, 83). There are several possible, non-exclusive explanations for this discrepancy between in vitro and in vivo observations. Results from mouse studies84 indicate that the lack of inflammatory infiltrates in BU is caused by the continuous destruction of inflammatory cells, rather than local immunosuppression. Alternatively, mycolactone or some other M. Ulcerans component, may suppress the expression of inflammatory cytokines at a post-transcriptional level, by inhibiting protein translation or secretion. It will therefore be essential in the future to find ways of quantifying mycolactone in infected tissues, measure the local production of chemoattractants and further dissect the molecular mechanisms of mycolactone immunosuppression.

Several independent studies have reported modulation of the systemic IFN-Îł responses in patients with BU using restimulation assays of peripheral blood mononuclear cells ex vivo83,85,86,87,88,89,90. One of these studies reported an inverse ratio of IFN-Îł versus IL-10 in patients with ulcerative disease compared with subjects at the nodular stage83. Although the IFN-Îł responses of patients with BU were not always significantly different to those of healthy controls, they were lower at the early stages compared with the ulcerative or healing stages88,89,91. Cases of disseminated disease have been reported in patients with AIDS, and there is an increased prevalence of HIV-1 or HIV-2 in patients with BU. Importantly, the systemic suppression of IFN-Îł responses in patients with BU is not specific for mycobacterial antigens, and resolves after surgical excision of the lesion90. In mice, cellular response defects occur following infection with wild-type M. Ulcerans, but not with a mycolactone-deficient mutant95. Although there is no definitive evidence that mycolactone circulates in humans, it seems likely that the toxin is responsible for this systemic immunosuppression. In support of this idea, we found that subcutaneously delivered mycolactone diffuses into the peripheral blood of mice, and accumulates in internal organs with a tropism for lymphoid organs95. Furthermore, mycolactone is a potent suppressor of IL-2 and IFN-Îł production by human T cells in vitro96 (C.D., unpublished observations).

The generation of appropriate IFN-Îł responses is crucial for protective immunity against most mycobacterial infections. In BU, spontaneous healing often coincides with conversion to a positive delayed hypersensitivity against M. Ulcerans antigens, suggesting that TH1 cellular immune responses are beneficial and contribute to the eradication of bacilli97. Interestingly, antibiotic treatment of BU induces vigorous inflammation in different compartments of the skin98, indicating that patients can mount TH1 responses. During the disease, the generation of cellular immunity can thus be suppressed by mycolactone in two ways (Fig. 4): first, at the site of infection, where the mycolactone concentration is cytotoxic, by killing resident DCs and inflammatory infiltrates; and second, at the systemic level, by reducing the ability of DCs and T cells to respond to stimulation without any major impact on their viability. In this model, withholding the immunosuppression imposed by mycolactone using inhibitors of its biosynthesis, or ablating its biological activity in vivo, would be sufficient to trigger the development of cellular immunity and allow the host immune system to control the infection.

Concluding remarks

Although there has been impressive recent progress in our exploration of the role of aquatic insects in the transmission of BU, our understanding of the precise mechanisms that occur remains incomplete. The coming years will reveal whether insects truly act as disease vectors or if they have simply been incriminated by their association with M. Ulcerans. The highly sensitive molecular tools now available for tracking the BU bacillus will find increasing application and, like other genome-derived approaches, help to pinpoint the environmental source of infection. The history of BU provides a cautionary tale for other emerging diseases, as human intervention in the environment has clearly favoured emergence of the disease through the creation of new niches and habitats both for M. Ulcerans and the aquatic insects within which it resides. Acquisition of the virulence plasmid by an ancestral M. Marinum species though horizontal gene transfer was the main driver for disease emergence in humans and probably also for the infection of lower life forms. Unravelling the immunosuppressive pathways induced by mycolactone in mammalian cells will certainly be a profitable area of research, and improved understanding of the BU structure–activity relationship may enable the dissociation of cytotoxicity from immunosuppression. In turn, it would be satisfying if a version of a once disfiguring toxin could be engineered to afford therapeutic benefits similar to those of rapamycin to humans.

Box 1Parallels between mycolactone and other immunosuppressors

Intriguingly, the structure of mycolactone is related to that of a family of natural products produced by actinomycetes15. In particular, it shares similar features with rapamycin, a macrocyclic triene produced by Streptomyces hygroscopicus and FK506, a macrolide lactone from Streptomyces tsukubaensis (see the figure). The molecular structure of the soil fungi metabolite cyclosporin A is more distant, but has a similar size and a similar proportion of hydrophobic groups81. FK506, rapamycin and cyclosporin A are all potent immunosuppressive drugs that alter the functional biology of lymphocytes and dendritic cells99. FK506 and rapamycin bind the same intracellular receptor, FKBP1A, although the resulting complex targets a different molecule. By contrast, FK506 and cyclosporin A bind different targets, but they both act by inhibiting calcineurin activity and produce similar biological effects. Similarly to mycolactone, FK506 modulates the production of β-chemokines. However, FK506 blocks dendritic cell production of inflammatory cytokines that are not altered by mycolactone, suggesting that mycolactone binds a different receptor and interferes with another signalling pathway that remains to be identified100. IFN, interferon; IL, interleukin; mTOR, mammalian target of rapamycin; TNF, tumour necrosis factor.


Ribosomal RNA Methylation By GidB Modulates Discrimination Of Mischarged TRNA

All clades of life have evolved multiple, redundant pathways to reduce translational error [1, 2]. Despite these mechanisms, errors in protein synthesis are remarkably common and are orders of magnitude more frequent than errors in DNA or RNA synthesis [3–7]. There is no one 'optimal' rate of error. Both the error rates and the dominant sources of error can be both species and even organelle specific [1, 8]. Furthermore, translational errors (mistranslation) may result in adaptive phenotypes, particularly in the context of environmental stressors [1, 5, 6, 9–20]. However, excess mistranslation can also cause protein aggregation [21, 22], organ degeneration [23, 24] and is the mechanism for the bactericidal activity of aminoglycosides [25]. Collectively, these lines of evidence suggest that no optimal balance for translational error exists and that selection favors tunable and context-specific mistranslation rates [1, 3, 5, 26]. However, the precise mechanisms by which mistranslation rates are tuned are poorly understood.

In addition, molecular mechanisms of translational error vary considerably, as do the proof-reading pathways that have evolved to reduce them. Generally, sources of error and proof-reading can be divided into pre-ribosomal and ribosomal mechanisms [1]. Pre-ribosomal errors arise from mischarging of the tRNA with a non-cognate amino acid and proof-reading mechanisms include pre- and post-transfer editing functions of aminoacyl tRNA synthetases [27]. Following aminoacyl-tRNA synthesis, trans-acting editing mechanisms can reject mischarged tRNAs [28, 29], and the aminoacyl-tRNA chaperone, EF-Tu optimally binds cognate aminoacyl-tRNAs compared with mischarged tRNAs [30]. These multiple and redundant pre-ribosomal proof-reading steps – solely concerned with the charging of tRNA with its cognate amino acid – have been proposed as necessary since previously described ribosomal proof-reading mechanisms ensure cognate codon·anticodon pairing [2, 31] and therefore are insensitive to the identity of the amino acid charged to the tRNA.

In mycobacteria, the dominant source of translational error is due to the pre-ribosomal indirect tRNA aminoacylation pathway [12, 32, 33]. Most bacteria, with the notable exception of a few proteo-bacteria such as Escherichia coli, lack either the glutaminyl- or asparaginyl-tRNA synthetases, or both [34]. Instead, a two-step indirect tRNA synthesis pathway is required to ensure cognate charging of glutamine and asparagine tRNAs. In the first step, a non-discriminatory glutamyl or aspartyl synthetases mischarge glutaminyl-tRNA with glutamate (i.E. Glu-tRNAGln) and asparaginyl-tRNA with aspartate (i.E. Asp-tRNAAsn) respectively. In the second step, the enzyme GatCAB corrects the mischarged aminoacyl moiety by transamidation [35] and see Fig. 1A. Despite its essential function, partial loss-of-function mutations in gatCAB can be readily selected in mycobacteria, which lacks both synthetases and mutations in gatCAB occur naturally in clinical isolates of pathogenic M. Tuberculosis [12, 36, 37]. These mutant strains exhibit extremely high (up to 10%/codon) rates of the mistranslation of Gln/Asn codons to Glu/Asp, respectively and specifically [12]. Even in wild-type mycobacteria, the specific mistranslation rates of Gln→Glu and Asn→Asp, measured using similar gain-of-function reporters, are orders of magnitude higher than in E. Coli – that has the full set of 20 aminoacyl tRNA synthetases and hence lacks GatCAB [38].

Figure 1.Suppressor screen identifies gidB as a potential fidelity factor.

A. Indirect aminoacylation pathway for tRNAAsn and tRNAGln in mycobacteria. B. Design of the suppressor screen: applying an increasing mistranslation stress to both strains makes HWS.19 more susceptible to stress and more likely to have mutation in suppressors. C. Workflow of suppressor screen. D. N to D mistranslation rate of suppressor candidates compared with WT and HWS.19 measured by Renilla-Firefly dual luciferase reporter as depicted in Figure1C. E. GidB mutation was mapped onto 3 candidates by whole genome sequencing. (*P < 0.05, **P < 0.01, ***P < 0.001, Student t test)

Here, we investigated whether further fidelity factors can be identified in mycobacteria. We identifed that deletion of the 16S ribosomal RNA (rRNA) methyltransferase gidB is necessary, but not sufficient for the discrimination of mischarged tRNAs. Deletion of gidB only increased discrimination of mischarged tRNAs in mycobacteria with elevated mistranslation rates – due to mutation or environmental context. Solving the structure of mycobacterial ribosomes purified from +/- gidB strains suggested that methylation of rRNA may interact with mistranslated ribosomal amino acids in the small subunit, implying a potential mechanism by which rRNA methylation contributes to fidelity. Collectively, these results point to an active ribosomal proof-reading of ribosomes beyond codon•anticodon pairing and suggest that nonmethylation of rRNA prevents catastrophic translational error.

A suppressor screen in mycobacteria identifies gidB as a potential translational fidelity factor

We previously used forward genetic screens to identify strains of Mycobacterium smegmatis with extremely high specific rates of mistranslation – i.E. Mistranslation of Asn→Asp. These screens identified mutations in the essential amidotransferase genes gatCAB that resulted in high rates of mistranslation of Gln/Asn, specifically [12, 36]. We hypothesized that the mycobacterial genome may encode for other 'fidelity factors' that could modulate mistranslation rates in the background of a compromised indirect tRNA aminoacylation pathway. We, therefore, designed a suppressor screen strategy in the strain HWS19 [12], which encodes a three amino acid deletion in gatA and, consequently, has extremely high rates of translational error of Gln→Glu and Asn→Asp specifically (Fig 1B). We wondered whether HWS19, with a high background mistranslation rate of Gln/Asn codons, is more susceptible to aminoglycosides, such as streptomycin that are known to increase ribosomal decoding errors across multiple codons [33, 39]. Plating of equivalent colony forming units (CFU) of strain HWS19 on low-dose streptomycin-agar led to the recovery of significantly fewer colonies compared with wild-type (Fig. S1), confirming HWS19 was hypersusceptible to streptomycin. The basis of our suppressor screen, therefore, was as follows: plating of HWS19 onto low-dose streptomycin-agar should select for strains with mutations that decrease mistranslation on this high mistranslating background (Fig. 1B, 1C). Suppressors identified from selection on low-dose streptomycin agar were then tested using our custom dual-luciferase mistranslation reporter system to verify that they had decreased error rates (Fig. 1C).

To identify mutants leading to decreased mistranslation, we plated 1x107 CFU onto each of 6 agar plates containing 1 µg/mL streptomycin. The remaining survivors were transformed with dual-luciferase reporter plasmids that measured specific mistranslation errors of asparagine for aspartate [12, 17, 40] to identify low mistranslating candidates (Fig. 1C). We initially identified 4 suppressor mutants with lower mistranslation rates compared with the parent HWS19 strain, and comparable to wild-type M. Smegmatis (Fig. 1D). Sequencing the strains revealed three of the four had mutations in the 16S rRNA methyltransferase gidB (Msmeg_6940) – Table S1. The remaining suppressor (C-23) had multiple mutations including in the gene, tuf, coding for the aminoacyl-tRNA chaperone EF-Tu. (Table S1). We subsequently sequenced just the gidB gene of a further 10 candidate suppressors and identified a further seven with a total of three additional independent mutations in gidB (Table S2). All but one of these further suppressors also had reduced mistranslation rates (Fig. S2), strongly supporting that mutations in gidB are able to suppress the high specific mistranslation rates in strain HWS19 that arise from mischarging tRNA.

Deletion of gidB increases ribosomal discrimination against misacylated tRNA in mycobacteria with high mistranslation

Loss of function mutations in GidB can cause low-level streptomycin resistance: lack of methylation in 16S rRNA interferes with streptomycin binding [41, 42]. We were, therefore, concerned that our candidates from the screen may simply represent selection against streptomycin. To determine whether the observed phenotype was independent of streptomycin selection, we deleted gidB in both the HWS19 and parental (wild-type) M. Smegmatis backgrounds in the complete absence of streptomycin selection. Deletion strains were complemented with a chromosomally integrated plasmid expressing gidB from its native promoter (Fig. S3). We measured specific mistranslation rates using two complementary reporter systems: the dual-luciferase system, used in the initial screen, as well as a dual-fluorescent reporter system (Fig. S4, S5) that uses flow cytometry to measure relative mistranslation rates [12]. This reporter, a GFP-mRFP fusion protein had a glutamate necessary for GFP fluorescence mutated to glutamine, abrogating green, but not red fluorescence [12]. Increased specific mistranslation of Gln→Glu would result in increased GFP fluorescence and hence increased GFP/RFP ratios. Measurement of specific mistranslation rates with both reporters verified that deletion of gidB significantly increased translational fidelity in strain HWS19, and this phenotype could be readily complemented (Fig. 2A, B, left panel). Surprisingly, deletion of gidB had no phenotype using the same reporters on a wild-type background (Fig. 2A, B, right panel).

Figure 2.Deletion of GidB in mycobacteria increases translation fidelity in high mistranslation mutant.

A. N to D Mistranslation rate measured by gain-of-function Renilla-Firefly dual luciferase reporter in high mistranslation HWS19 strain (Left) and wild-type strain (Right). B. Q to E Mistranslation rate measured by gain-of-function dual fluorescent reporter in high mistranslation HWS19 strain (Left) and wild-type strain (Right).

GidB is necessary for discrimination of mischarged tRNA under conditions that enrich for relatively high mistranslation rates

Our results suggested that deletion of gidB increased translational

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