ABSTRACT
Since their discovery as important determinants of virulence and growth, the type VII ESX secretion systems (ESX-1 to ESX-5) of slow-growing pathogenic mycobacteria have been the focus of intense scrutiny. Genetic studies have been instrumental in identifying the core components and substrates of these molecular secretion machines and have helped uncover the multifunctional properties of some of them. For instance, the mycosin MycP1 of ESX-1, a membrane-associated subtilisin-like serine protease, was shown to have dual functions: the entire protein is essential for ESX-1 function, but only the serine protease regulates secretion activity. MycP5 of ESX-5, on the other hand, is required for ESX-5 secretion activity, but the function of its predicted serine protease remains unknown. Recently, van Winden and colleagues (mBio 7:e01471-16, 2016, http://dx.doi.org/10.1128/mBio.01471-16) reported compelling evidence that MycP1 and MycP5 serve to stabilize the interactions of core ESX-1 and ESX-5 components, respectively, thus explaining how they facilitate the secretion activities of their associated systems.
COMMENTARY
Mycobacteria have evolved specialized type VII secretion systems to transport molecular cargo across their thick and complex cell envelopes (1). In slow-growing pathogenic mycobacteria, like Mycobacterium tuberculosis and Mycobacterium bovis, the causative agents of tuberculosis (TB), and Mycobacterium marinum, the agent of TB in fish and amphibians and a less hazardous surrogate model often used to study TB pathogenesis, there are five paralogous type VII secretion systems, called ESX-1 to ESX-5 (1). All five share a set of common features, in that the genetic clusters encoding each ESX system contain genes for (i) small secreted proteins of about 100 amino acids with a conserved Trp-X-Gly (WXG) motif located in the middle of the polypeptide (e.g., EsxA of ESX-1, EsxN of ESX-5, etc.), (ii) one putative cell membrane-associated protein (e.g., EccB1 of ESX-1, EccB5 of ESX-5, etc.), (iii) transmembrane ATPases of the FtsK-SpoIIIE family (e.g., EccCa1 and EccCb1 of ESX-1, EccC5 of ESX-5, etc.), (iv) one 11-transmembrane domain protein that presumably forms a channel in the mycobacterial cell membrane (e.g., EccD1 of ESX-1, EccD5 of ESX-5, etc.), (v) with the exception of ESX-4, another putative cell membrane-associated protein (e.g., EccE1 of ESX-1, EccE5 of ESX-5, etc.), and (vi) one subtilisin-like mycosin (e.g., MycP1 of ESX-1, MycP5 of ESX-5, etc.) (1).
Of the five mycobacterial type VII secretion systems, ESX-1 has been the most studied and is reviewed in excellent detail elsewhere (1). Briefly, ESX-1 in M. tuberculosis, M. bovis, and M. marinum is crucial for the secretion of its associated protein substrates (namely, EsxA, EsxB, EspA, EspB, and EspC) and for mediating virulence through an incredibly diverse number of ways (1). Indeed, it was a spontaneous genetic deletion resulting in the inactivation of ESX-1 in a virulent isolate of M. bovis that set it on its inexorable march toward attenuation and the eventual derivation of the live TB vaccine M. bovis BCG (1, 2). ESX-3 has been implicated in metal homeostasis and is indispensable for M. tuberculosis growth in vitro and in vivo (1, 3–5). ESX-5 is essential for M. tuberculosis and M. marinum viability under standard in vitro growth conditions and for the secretion of select Pro- and Gln-rich (Pro-Gln [PE] and Pro-Pro-Gln [PPE]) proteins, EsxN, and a posttranslationally cleaved lipase called LipY (1, 6–9). ESX-5 is also involved in modulating the host immune response to M. tuberculosis and M. marinum (1, 6–9). Meanwhile, ESX-2 and ESX-4 have remained uncharacterized (1).
In the earliest study of M. tuberculosis mycosins, beginning in the year 2000, amino acid sequence analysis of its five MycP proteins led to the identification of an Asp-His-Ser catalytic triad also found in bacterial serine proteases of the subtilisin family (10). Moreover, MycP1, MycP2, and MycP3 were shown to be expressed only in the slow-growing M. bovis and M. tuberculosis species but not in the fast-growing saprophyte M. smegmatis (10). In a subsequent study, M. tuberculosis MycP1 was found to localize to the cell envelope and possess proteolytic activity sensitive to inhibition by serine/cysteine protease inhibitors and activation by Ca2+, properties typical of subtilisins (11). Almost a decade later, a mycP1 deletion mutant of M. tuberculosis was reported to be defective in ESX-1 secretion activity and attenuated for virulence (12). In addition, the serine-protease domain of MycP1 was found to mediate post-translational cleavage of the ESX-1-secreted protein EspB but appeared expendable for overall ESX-1 secretion activity (12). Surprisingly however, the M. tuberculosis mycP1 deletion mutant complemented with and expressing serine protease-dead MycP1 displayed ESX-1-mediated hypersecretion (12). Based on these observations, it was concluded that MycP1 serves a dual function, with the entire protein being essential for ESX-1 activity and the serine-protease domain being required for cleaving EspB and regulating secretion (12). MycP5 was also found to be a functionally integral part of ESX-5, essential for M. marinum and M. bovis BCG growth and for the secretion of PE/PPE proteins (6). Exactly how MycP1 and MycP5 facilitate the secretion activities of their respective ESX systems remained poorly understood.
In a recent study reported in mBio, van Winden and colleagues presented findings on M. marinum MycP1 and MycP5 that addresses this question (13). The authors first generated a mycP1 deletion mutant of M. marinum and found its ESX-1 secretion activity to be completely abolished. Moreover, the mycP1 deletion mutant was unable to mediate ESX-1-dependent lysis of erythrocytes. Complementation of the mutant with mycP1 restored the wild-type (WT) secretion and virulence phenotype. However, complementation with a serine protease-dead version of mycP1 (mycP1S354A) resulted in the secretion of unprocessed EspB and enhanced ESX-1-mediated secretion and erythrocyte lysis (13). They then went one step further and also complemented the mycP1 deletion mutant with a “bulky” variant of mycP1 (mycP1N239Y), the construction of which was informed by previous structural work detailing the EspB-binding site of MycP1 (14). Replacement of Asn-239 with a larger Tyr residue in the EspB-binding groove of MycP1 was predicted to effectively block protease activity. Indeed, complementation with mycP1N239Y also resulted in unprocessed EspB secretion, ESX-1 substrate hypersecretion, and enhanced erythrocyte lysis. These results, taken together, confirm in M. marinum what was previously observed with M. tuberculosis MycP1: the protein has a dual function with respect to the ESX-1 system.
To determine if the conserved serine protease domain of MycP5 plays a similar role in MycP1, van Winden et al. complemented a mycP5 deletion mutant of M. marinum defective in PE/PPE and EsxN secretion with genes encoding predicted protease-dead (mycP5S461A) and “bulky” (mycP5D362Y) variants of mycP5. Both variant genes restored WT ESX-5 function to the mycP5 deletion mutant, but hypersecretion of PE/PPE and EsxN was not observed. Moreover, differential processing of LipY, a presumed substrate of MycP5, was not observed. These results indicate MycP5 is required for ESX-5-mediated secretion but, unlike MycP1, its serine protease does not appear to be involved in regulating secretion or processing of ESX-5 substrates.
van Winden and colleagues had previously devised a biochemical approach involving n-dodecyl beta-d-maltoside (DDM) solubilization of WT M. marinum cell envelope proteins, Blue native polyacrylamide gel electrophoresis (PAGE), immunoblotting, and mass spectrometry to show that the core ESX-5 secretion complex is approximately 1,500 kDa in size and contains EccB5, EccC5, EccD5, and EccE5 (15). By immunoprecipitating EccB5 and pulling down EccC5, EccD5, and EccE5, they confirmed the core ESX-5 secretion complex consists of these interacting proteins (15). Taking the same approach in this study, van Winden et al. resolved DDM-solubilized WT M. marinum cell envelope proteins by Blue native PAGE and by immunoblotting identified an EccB1-containing complex similar in size (~1,500 kDa) to the core ESX-5 secretion complex. To isolate the putative core ESX-1 complex itself, van Winden et al. complemented an M. marinum eccCb1 transposon mutant with twin Strep-tagged eccCb1. Having verified the Strep tags did not affect EccCb1 function by fully complementing the eccCb1 transposon mutant, the authors resolved cell envelope extracts from the complemented mutant by using Blue native PAGE and immunoblotting with Strep antibodies, and identified a corresponding EccCb1-containing complex also 1,500 kDa in size. Using Strep-Tactin beads, the tagged EccCb1 protein was pulled down along with a number of interacting proteins. Subsequent mass spectrometry analysis revealed these to be EccB1, EccCa1, EccD1, and EccE1. The authors also complemented an eccC5-deficient mutant with Strep-tagged eccC5 and pulled down tagged EccC5 along with proteins subsequently identified by mass spectrometry to be EccB5, EccD5, and EccE5, as seen previously in immunoprecipitation experiments with EccB5 (15). These results, taken together, confirm that the core ESX-1 and ESX-5 secretion complexes in M. marinum are similar.
Despite mass spectrometry results that indicated that MycP1 and MycP5 are not integral components of their respective core secretion complexes, van Winden speculated that the two proteins might still be required for their proper functioning. Comparative Blue native PAGE of cell envelope extracts from WT, mycP5-deficient, and complemented M. marinum cells followed by immunoblotting with anti-EccB5 antibody revealed the 1,500-kDa core ESX-5 complex to be absent in the mycP5-deficient mutant. Comparison of WT, mycP1-deficient, and complemented M. marinum strains also revealed the 1,500-kDa core ESX-1 complex to be absent in the mycP1-deficient mutant. The authors then correctly speculated that MycP1 and MycP5 may be required to stabilize their respective core secretion complexes. To test this, they pretreated mycP1- and mycP5-deficient M. marinum cells with chemical cross-linkers prior to extraction and analysis, working off the assumption that the cross-linkers would help stabilize the core complexes in the absence of MycP1 and MycP5. Indeed, only upon such treatment were both core ESX-1 and ESX-5 membrane complexes stabilized at WT levels. These results taken together indicate that MycP1 and MycP5 facilitate the secretion activities of ESX-1 and ESX-5, respectively, by stabilizing their core secretion complexes.
This study by van Winden and colleagues is important for several reasons. First, the authors have confirmed in another slow-growing pathogenic mycobacterium that MycP1 does indeed perform dual roles. However, unlike MycP1, MycP5 in M. marinum at least does not appear to share the same dual-function property, even though it has a conserved serine-protease domain. This may well be a reflection of or an underlying reason for the functional differences between the ESX-1 and ESX-5 systems in mycobacterial biology. Further studies to identify the substrates for MycP5 and ascertain the role of its serine-protease domain are warranted. Additional studies should also be done to determine the consequences for M. marinum expressing protease-dead MycP1 in host-pathogen interactions, given that in M. tuberculosis, ESX-1 hypersecretion appears to compromise the bacterium’s virulence in chronic infections (12). Second, the authors have clearly demonstrated that the core ESX-1 complex, at least in M. marinum, is composed of EccB1, EccCa1, EccCb1, EccD1, and EccE1. Efforts should now focus on assessing these complexes in either M. tuberculosis, M. bovis, or recombinant M. bovis BCG with a restored ESX-1 system (e.g., BCG::RD1). Third, the authors addressed how MycP1 and MycP5 facilitate secretion by showing that the proteins help stabilize the formation of their respective core secretion complexes. The same approaches used by these investigators might also be valuable in determining if ESX-1-associated proteins, such as EspA, EspC, EspD, and EccA1, are also needed to stabilize the core ESX-1 secretion complex and, in doing so, enable secretion. Finally, the van Winden et al. study nicely demonstrates how the judicious use of ESX mutants in combination with biochemical approaches can yield further insights into the functional and temporal organization of these incredibly dynamic molecular machines. Experimental schemes using these approaches will surely reveal more details about the mycobacterial ESX systems in the future.
ACKNOWLEDGMENT
This commentary is published with the permission of the Director of VIDO-InterVac.
The views expressed in this Commentary do not necessarily reflect the views of this journal or of ASM.
Funding Statement
Work in the author's laboratory is supported by grants from the Banting Research Foundation, Natural Sciences and Engineering Research Council of Canada, and the Saskatchewan Health Research Foundation.
Footnotes
For the article discussed, see http://dx.doi.org/10.1128/mBio.01471-16.
Citation Chen JM. 2016. Mycosins of the mycobacterial type VII ESX secretion system are the glue that holds the party together. mBio 7(6):e02062-16. doi:10.1128/mBio.02062-16.
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