Mechanistic insight into mycobacterial MmpL protein function

Mycobacterial cell walls are complex structures containing a broad range of unusual lipids, glycolipids and other polymers, some of which act as immunomodulators or virulence determinants. Better understanding of the enzymes involved in export processes would enlighten cell wall biogenesis. Bernut et al. ( 2015 ) present the findings of a structural and functional investigation of one of the most important transporter families, the MmpL proteins, members of the resistance‐nodulation‐cell division (RND) superfamily. A Tyr842His missense mutation in the mmpL4a gene was shown to be responsible for the smooth‐to‐rough morphotype change of the near untreatable opportunistic pathogen Mycobacterium bolletii due to its failure to export a glycopeptidolipid (GPL). This mutation was pleiotropic and markedly increased virulence in infection models. Tyr842 is well conserved in all actinobacterial MmpL proteins suggesting that it is functionally important and this was confirmed by several approaches including replacing the corresponding residue in MmpL3 of Mycobacterium tuberculosis. Structural modelling combined with experimental results showed Tyr842 to be a critical residue for mediating the proton motive force required for GPL export. This mechanistic insight applies to all MmpL proteins and probably to all RND transporters.     

Insights into the smooth‐to‐rough transitioning in Mycobacterium bolletii unravels a functional Tyr residue conserved in all mycobacterial MmpL family members

In mycobacteria, MmpL proteins represent key components that participate in the biosynthesis of the complex cell envelope. Whole genome analysis of a spontaneous rough morphotype variant of Mycobacterium abscessus subsp. bolletii identified a conserved tyrosine that is crucial for the function of MmpL family proteins. Isogenic smooth (S) and rough (R) variants differed by a single mutation linked to a Y842H substitution in MmpL4a. This mutation caused a deficiency in glycopeptidolipid production/transport in the R variant and a gain in the capacity to produce cords in vitro. In zebrafish, increased virulence of the M. bolletii R variant over the parental S strain was found, involving massive production of serpentine cords, abscess formation and rapid larval death. Importantly, this finding allowed us to demonstrate an essential role of Tyr842 in several different MmpL proteins, including Mycobacterium tuberculosis MmpL3. Structural homology models of MmpL4a and MmpL3 identified two additional critical residues located in the transmembrane regions TM10 and TM4 that are facing each other. We propose that these central residues are part of the proton‐motive force that supplies the energy for substrate transport. Hence, we provide important insights into mechanistic/structural aspects of MmpL proteins as lipid transporters and virulence determinants in mycobacteria.     

Interaction between polyketide synthase and transporter suggests coupled synthesis and export of virulence lipid in M. tuberculosis

Virulent mycobacteria utilize surface-exposed polyketides to interact with host cells, but the mechanism by which these hydrophobic molecules are transported across the cell envelope to the surface of the bacteria is poorly understood. Phthiocerol dimycocerosate (PDIM), a surface-exposed polyketide lipid necessary for Mycobacterium tuberculosis virulence, is the product of several polyketide synthases including PpsE. Transport of PDIM requires MmpL7, a member of the MmpL family of RND permeases. Here we show that a domain of MmpL7 biochemically interacts with PpsE, the first report of an interaction between a biosynthetic enzyme and its cognate transporter. Overexpression of the interaction domain of MmpL7 acts as a dominant negative to PDIM synthesis by poisoning the interaction between synthase and transporter. This suggests that MmpL7 acts in complex with the synthesis machinery to efficiently transport PDIM across the cell membrane. Coordination of synthesis and transport may not only be a feature of MmpL-mediated transport in M. tuberculosis, but may also represent a general mechanism of polyketide export in many different microorganisms.     

MmpL11 Protein Transports Mycolic Acid-containing Lipids to the Mycobacterial Cell Wall and Contributes to Biofilm Formation in Mycobacterium smegmatis

A growing body of evidence indicates that MmpL (mycobacterial membrane protein large) transporters are dedicated to cell wall biosynthesis and transport mycobacterial lipids. How MmpL transporters function and the identities of their substrates have not been fully elucidated. We report the characterization of Mycobacterium smegmatis MmpL11. We showed previously that M. smegmatis lacking MmpL11 has reduced membrane permeability that results in resistance to host antimicrobial peptides. We report herein the further characterization of the M. smegmatis mmpL11 mutant and identification of the MmpL11 substrates. We found that biofilm formation by the M. smegmatis mmpL11 mutant was distinct from that by wild-type M. smegmatis. Analysis of cell wall lipids revealed that the mmpL11 mutant failed to export the mycolic acid-containing lipids monomeromycolyl diacylglycerol and mycolate ester wax to the bacterial surface. In addition, analysis of total lipids indicated that the mycolic acid-containing precursor molecule mycolyl phospholipid accumulated in the mmpL11 mutant compared with wild-type mycobacteria. MmpL11 is encoded at a chromosomal locus that is conserved across pathogenic and nonpathogenic mycobacteria. Phenotypes of the M. smegmatis mmpL11 mutant are complemented by the expression of M. smegmatis or M. tuberculosis MmpL11, suggesting that MmpL11 plays a conserved role in mycobacterial cell wall biogenesis.     

Heavy metal transport by the CusCFBA efflux system

It is widely accepted that the increased use of antibiotics has resulted in bacteria with developed resistance to such treatments. These organisms are capable of forming multi‐protein structures that bridge both the inner and outer membrane to expel diverse toxic compounds directly from the cell. Proteins of the resistance nodulation cell division (RND) superfamily typically assemble as tripartite efflux pumps, composed of an inner membrane transporter, a periplasmic membrane fusion protein, and an outer membrane factor channel protein. These machines are the most powerful antimicrobial efflux machinery available to bacteria. In Escherichia coli, the CusCFBA complex is the only known RND transporter with a specificity for heavy metals, detoxifying both Cu⁺ and Ag⁺ ions. In this review, we discuss the known structural information for the CusCFBA proteins, with an emphasis on their assembly, interaction, and the relationship between structure and function.     

鲍曼不动杆菌中外排泵介导耐药机制的研究进展

外排泵的过表达是目前导致鲍曼不动杆菌多重耐药的最重要机制之一,详细了解这一复杂机制有助于尽快找到有效的防治策略。目前,鲍曼不动杆菌中已被报道的外排泵家族包括耐药结节细胞分化(resistance-nodulation-cell division,RND)家族、主要协同转运蛋白超家族(major facilitator superfamily,MFS)、多药及毒性化合物外排(multidrug and toxic compound extrusion,MATE)家族、小多重耐药(small multidrug resistance,SMR)家族。它们之中既有通过染色体介导的外排泵,也有通过质粒等遗传元件介导的外排泵。外排底物可呈现多样性,也可呈现专一性。本文就上述外排泵的种类、功能和调控机制进行综述。     

Role of mycobacterial efflux transporters in drug resistance: an unresolved question

Two mechanisms are thought to be involved in the natural drug resistance of mycobacteria: the mycobacterial cell wall permeability barrier and active multidrug efflux pumps. Genes encoding drug efflux transporters have been isolated from several mycobacterial species. These proteins transport tetracycline, fluoroquinolones, aminoglycosides and other compounds. Recent reports have suggested that efflux pumps may also be involved in transporting isoniazid, one of the main drugs used to treat tuberculosis. This review highlights recent advances in our understanding of efflux-mediated drug resistance in mycobacteria, including the distribution of efflux systems in these organisms, their substrate profiles and their contribution to drug resistance. The balance between the drug transport into the cell and drug efflux is not yet clearly understood, and further studies are required in mycobacteria.     

Dopamine neurons derived from embryonic stem cells efficiently induce behavioral recovery in a Parkinsonian rat model

The Mycobacterium tuberculosis serine/threonine protein kinases are attractive potential drug targets, and protein kinase D (PknD) is particularly interesting, as it is autophosphorylated on 11 residues, binds proteins containing forkhead associated domains, and contains a beta-propeller motif that likely functions as an anchoring sensor domain. We created a pknD knockout of a clinical M. tuberculosis isolate, and found that on in vitro phosphorylation of cell wall fractions it lacked a family of phosphorylated polypeptides seen in the WT. Mass spectrometry identified the phosphorylated polypeptides as MmpL7, a transporter of the RND family. MmpL7 is essential for virulence, presumably because it transports polyketide virulence factors such as phthiocerol dimycocerosate (PDIM) to the cell wall. Phosphorylation of the MmpL family of transporters has not been previously described, but these results suggest that PknD, and perhaps other serine/threonine kinases, could regulate their critical role in the formation of the M. tuberculosis envelope.     

Proton-dependent multidrug efflux systems.

Multidrug efflux systems display the ability to transport a variety of structurally unrelated drugs from a cell and consequently are capable of conferring resistance to a diverse range of chemotherapeutic agents. This review examines multidrug efflux systems which use the proton motive force to drive drug transport. These proteins are likely to operate as multidrug/proton antiporters and have been identified in both prokaryotes and eukaryotes. Such proton-dependent multidrug efflux proteins belong to three distinct families or superfamilies of transport proteins: the major facilitator superfamily (MFS), the small multidrug resistance (SMR) family, and the resistance/ nodulation/cell division (RND) family. The MFS consists of symporters, antiporters, and uniporters with either 12 or 14 transmembrane-spanning segments (TMS), and we show that within the MFS, three separate families include various multidrug/proton antiport proteins. The SMR family consists of proteins with four TMS, and the multidrug efflux proteins within this family are the smallest known secondary transporters. The RND family consists of 12-TMS transport proteins and includes a number of multidrug efflux proteins with particularly broad substrate specificity. In gram-negative bacteria, some multidrug efflux systems require two auxiliary constituents, which might enable drug transport to occur across both membranes of the cell envelope. These auxiliary constituents belong to the membrane fusion protein and the outer membrane factor families, respectively. This review examines in detail each of the characterized proton-linked multidrug efflux systems. The molecular basis of the broad substrate specificity of these transporters is discussed. The surprisingly wide distribution of multidrug efflux systems and their multiplicity in single organisms, with Escherichia coli, for instance, possessing at least nine proton-dependent multidrug efflux systems with overlapping specificities, is examined. We also discuss whether the normal physiological role of the multidrug efflux systems is to protect the cell from toxic compounds or whether they fulfil primary functions unrelated to drug resistance and only efflux multiple drugs fortuitously or opportunistically.     

Mutations in MexB that affect the efflux of antibiotics with cytoplasmic targets

Drug efflux pumps such as MexAB-OprM from Pseudomonas aeruginosa confer resistance to a wide range of chemically different compounds. Within the tripartite assembly, the inner membrane protein MexB is mainly responsible for substrate recognition. Recently, considerable advances have been made in elucidating the drug efflux pathway through the large periplasmic domains of resistance-nodulation-division (RND) transporters. However, little is known about the role of amino acids in other parts of the protein. We have investigated the role of two conserved phenylalanine residues that are aligned around the cytoplasmic side of the central cavity of MexB. The two conserved phenylalanine residues have been mutated to alanine residues (FAFA MexB). The interaction of the wild-type and mutant proteins with a variety of drugs from different classes was investigated by assays of cytotoxicity and drug transport. The FAFA mutation affected the efflux of compounds that have targets inside the cell, but antibiotics that act on cell wall synthesis and membrane probes were unaffected. Combined, our results indicate the presence of a hitherto unidentified cytoplasmic-binding site in RND drug transporters and enhance our understanding of the molecular mechanisms that govern drug resistance in Gram-negative pathogens.     

Structures of the mycobacterial membrane protein MmpL3 reveal its mechanism of lipid transport

The mycobacterial membrane protein large 3 (MmpL3) transporter is essential and required for shuttling the lipid trehalose monomycolate (TMM), a precursor of mycolic acid (MA)-containing trehalose dimycolate (TDM) and mycolyl arabinogalactan peptidoglycan (mAGP), in Mycobacterium species, including Mycobacterium tuberculosis and Mycobacterium smegmatis. However, the mechanism that MmpL3 uses to facilitate the transport of fatty acids and lipidic elements to the mycobacterial cell wall remains elusive. Here, we report 7 structures of the M. smegmatis MmpL3 transporter in its unbound state and in complex with trehalose 6-decanoate (T6D) or TMM using single-particle cryo-electron microscopy (cryo-EM) and X-ray crystallography. Combined with calculated results from molecular dynamics (MD) and target MD simulations, we reveal a lipid transport mechanism that involves a coupled movement of the periplasmic domain and transmembrane helices of the MmpL3 transporter that facilitates the shuttling of lipids to the mycobacterial cell wall.

Mycobacterial membrane protein Large 3 (MmpL3) is a transporter required for shuttling trehalose monomycolate. Structures of M. smegmatis MmpL3 with and without substrate reveal the mechanism by which MmpL3 transports this essential precursor of lipids for the mycobacterial cell wall.     

The three‐component system EsrISR regulates a cell envelope stress response in Corynebacterium glutamicum

When the cell envelope integrity is compromised, bacteria trigger signaling cascades resulting in the production of proteins that counteract these extracytoplasmic stresses. Here, we show that the two‐component system EsrSR regulates a cell envelope stress response in the Actinobacterium Corynebacterium glutamicum. The sensor kinase EsrS possesses an amino‐terminal phage shock protein C (PspC) domain, a property that sets EsrSR apart from all other two‐component systems characterized so far. An integral membrane protein, EsrI, whose gene is divergently transcribed to the esrSR gene locus and which interestingly also possesses a PspC domain, acts as an inhibitor of EsrSR under non‐stress conditions. The resulting EsrISR three‐component system is activated among others by antibiotics inhibiting the lipid II cycle, such as bacitracin and vancomycin, and it orchestrates a broad regulon including the esrI‐esrSR gene locus itself, genes encoding heat shock proteins, ABC transporters, and several putative membrane‐associated or secreted proteins of unknown function. Among those, the ABC transporter encoded by cg3322‐3320 was shown to be directly involved in bacitracin resistance of C. glutamicum. Since similar esrI‐esrSR loci are present in a large number of actinobacterial genomes, EsrISR represents a novel type of stress‐responsive system whose components are highly conserved in the phylum Actinobacteria.     

The AbgT family: A novel class of antimetabolite transporters

The AbgT family of transporters was thought to contribute to bacterial folate biosynthesis by importing the catabolite p‐aminobenzoyl‐glutamate for producing this essential vitamin. Approximately 13,000 putative transporters of the family have been identified. However, before our work, no structural information was available and even functional data were minimal for this family of membrane proteins. To elucidate the structure and function of the AbgT family of transporters, we recently determined the X‐ray structures of the full‐length Alcanivorax borkumensis YdaH and Neisseria gonorrhoeae MtrF membrane proteins. The structures reveal that these two transporters assemble as dimers with architectures distinct from all other families of transporters. Both YdaH and MtrF are bowl‐shaped dimers with a solvent‐filled basin extending from the cytoplasm halfway across the membrane bilayer. The protomers of YdaH and MtrF contain nine transmembrane helices and two hairpins. These structures directly suggest a plausible pathway for substrate transport. A combination of the crystal structure, genetic analysis and substrate accumulation assay indicates that both YdaH and MtrF behave as exporters, capable of removing the folate metabolite p‐aminobenzoic acid from bacterial cells. Further experimental data based on drug susceptibility and radioactive transport assay suggest that both YdaH and MtrF participate as antibiotic efflux pumps, importantly mediating bacterial resistance to sulfonamide antimetabolite drugs. It is possible that many of these AbgT‐family transporters act as exporters, thereby conferring bacterial resistance to sulfonamides. The AbgT‐family transporters may be important targets for the rational design of novel antibiotics to combat bacterial infections.     

Fatty acid transport across the cell membrane: Regulation by fatty acid transporters

Transport of long-chain fatty acids across the cell membrane has long been thought to occur by passive diffusion. However, in recent years there has been a fundamental shift in understanding, and it is now generally recognized that fatty acids cross the cell membrane via a protein-mediated mechanism. Membrane-associated fatty acid-binding proteins (‘fatty acid transporters’) not only facilitate but also regulate cellular fatty acid uptake, for instance through their inducible rapid (and reversible) translocation from intracellular storage pools to the cell membrane. A number of fatty acid transporters have been identified, including CD36, plasma membrane-associated fatty acid-binding protein (FABP_pm), and a family of fatty acid transport proteins (FATP1–6). Fatty acid transporters are also implicated in metabolic disease, such as insulin resistance and type-2 diabetes. In this report we briefly review current understanding of the mechanism of transmembrane fatty acid transport, and the function of fatty acid transporters in healthy cardiac and skeletal muscle, and in insulin resistance/type-2 diabetes. Fatty acid transporters hold promise as a future target to rectify lipid fluxes in the body and regain metabolic homeostasis.     

Multidrug resistance ABC transporters

Clinical multidrug resistance is caused by a group of integral membrane proteins that transport hydrophobic drugs and lipids across the cell membrane. One class of these permeases, known as multidrug resistance ATP binding cassette (ABC) transporters, translocate these molecules by coupling drug/lipid efflux with energy derived from the hydrolysis of ATP. In this review, we examine both the structures and conformational changes of multidrug resistance ABC transporters. Together with the available biochemical and structural evidence, we propose a general mechanism for hydrophobic substrate transport coupled to ATP hydrolysis.     

Book reviews

Eukaryotic cells contain hundreds of different lipid species that are not uniformly distributed among their membranes. For example, sphingolipids and sterols form gradients along the secretory pathway with the highest levels in the plasma membrane and the lowest in the endoplasmic reticulum. Moreover, lipids in late secretory organelles display asymmetric transbilayer arrangements with the aminophospholipids concentrated in the cytoplasmic leaflet. This lipid heterogeneity can be viewed as a manifestation of the fact that cells exploit the structural diversity of lipids in organizing intracellular membrane transport. Lipid immiscibility and the generation of phase-separated lipid domains provide a molecular basis for sorting membrane proteins into specific vesicular pathways. At the same time, energy-driven aminophospholipid transporters participate in membrane deformation during vesicle biogenesis. This review will focus on how selective membrane transport relies on a dynamic interplay between membrane lipids and proteins.     

Emerging new paradigms for ABCG transporters

Every cell is separated from its external environment by a lipid membrane. Survival depends on the regulated and selective transport of nutrients, waste products and regulatory molecules across these membranes, a process that is often mediated by integral membrane proteins. The largest and most diverse of these membrane transport systems is the ATP binding cassette (ABC) family of membrane transport proteins. The ABC family is a large evolutionary conserved family of transmembrane proteins (> 250 members) present in all phyla, from bacteria to Homo sapiens, which require energy in the form of ATP hydrolysis to transport substrates against concentration gradients. In prokaryotes the majority of ABC transporters are involved in the transport of nutrients and other macromolecules into the cell. In eukaryotes, with the exception of the cystic fibrosis transmembrane conductance regulator (CFTR/ABCC7), ABC transporters mobilize substrates from the cytoplasm out of the cell or into specific intracellular organelles. This review focuses on the members of the ABCG subfamily of transporters, which are conserved through evolution in multiple taxa. As discussed below, these proteins participate in multiple cellular homeostatic processes, and functional mutations in some of them have clinical relevance in humans.