Mechanism of Lys6 poly-ubiquitin specificity by the L. pneumophila deubiquitinase LotA.

The versatility of ubiquitination to control vast domains of eukaryotic biology is due, in part, to diversification through differently linked poly-ubiquitin chains. Deciphering signaling roles for some chain types, including those linked via K6, has been stymied by a lack of specificity among the implicated regulatory proteins. Forged through strong evolutionary pressures, pathogenic bacteria have evolved intricate mechanisms to regulate host ubiquitin during infection. Herein, we identify and characterize a deubiquitinase domain of the secreted effector LotA from Legionella pneumophila that specifically regulates K6-linked poly-ubiquitin. We demonstrate the utility of LotA for studying K6 poly-ubiquitin signals. We identify the structural basis of LotA activation and poly-ubiquitin specificity and describe an essential "adaptive" ubiquitin-binding domain. Without LotA activity during infection, the Legionella-containing vacuole becomes decorated with K6 poly-ubiquitin as well as the AAA ATPase VCP/p97/Cdc48. We propose that LotA's deubiquitinase activity guards Legionella-containing vacuole components from ubiquitin-dependent extraction.

Reversible modification of mitochondrial ADP/ATP translocases by paired Legionella effector proteins.

Adenosine diphosphate (ADP) ribosylation is a reversible posttranslational modification involved in the regulation of numerous cellular processes. Prototype ADP ribosyltransferases (ARTs) from many pathogenic bacteria are known to function as toxins, while other bacterial ARTs have just recently emerged. Recent studies have shown that bacteria also possess enzymes that function as poly-ADP ribose (ADPr) glycohydrolases (PARGs), which reverse poly-ADP ribosylation. However, how bacteria manipulate host target proteins by coordinated reactions of ARTs and ADPr hydrolases (ARHs) remains elusive. The intracellular bacterial pathogen Legionella pneumophila, the causative agent of Legionnaires' disease, transports a large array of effector proteins via the Dot/Icm type IV secretion system to host cells. The effector proteins, which mostly function as enzymes, modulate host cellular processes for the bacteria's benefit. In this study, we identified a pair of L. pneumophila effector proteins, Lpg0080 and Lpg0081, which function as an ART and an ARH, respectively. The two proteins were shown to coordinately modulate mitochondrial ADP/adenosine triphosphate (ATP) translocases (ANTs) by their enzymatic activities to conjugate ADPr to, and remove it from, a key arginine residue. The crystal structures of Lpg0081 and the Lpg0081:ADPr complex indicated that Lpg0081 is a macroD-type ARH with a noncanonical macrodomain, whose folding topology is strikingly distinct from that of the canonical macrodomain that is ubiquitously found in eukaryotic PARGs and ARHs. Our results illustrate that L. pneumophila has acquired an effector pair that coordinately manipulate mitochondrial activity via reversible chemical modification of ANTs.

Synthetic engineering and biological containment of bacteriophages.

The serious threats posed by drug-resistant bacterial infections and recent developments in synthetic biology have fueled a growing interest in genetically engineered phages with therapeutic potential. To date, many investigations on engineered phages have been limited to proof of concept or fundamental studies using phages with relatively small genomes or commercially available "phage display kits". Moreover, safeguards supporting efficient translation for practical use have not been implemented. Here, we developed a cell-free phage engineering and rebooting platform. We successfully assembled natural, designer, and chemically synthesized genomes and rebooted functional phages infecting gram-negative bacteria and acid-fast mycobacteria. Furthermore, we demonstrated the creation of biologically contained phages for the treatment of bacterial infections. These synthetic biocontained phages exhibited similar properties to those of a parent phage against lethal sepsis in vivo. This efficient, flexible, and rational approach will serve to accelerate phage biology studies and can be used for many practical applications, including phage therapy.

Requirement of phosphatidic acid binding for distribution of the bacterial protein Lpg1137 targeting syntaxin 17.

The gram-negative bacterium, Legionella pneumophila is known to manipulate the host cellular functions. L. pneumophila secretes bacterial proteins called Legionella effectors into the host cytosol that are necessary for these manipulations. The Legionella effector Lpg1137 was identified as a serine protease responsible for the degradation of syntaxin 17 (Stx17). However, how Lpg1137 specifically recognizes and degrades Stx17 remained unknown. Given that Stx17 is localized in the ER, mitochondria-associated membrane (MAM), and mitochondria, Lpg1137 likely distributes to these compartments to recognize Stx17. Here, we show that the C-terminal region of Lpg1137 binds to phosphatidic acid (PA), a MAM and mitochondria-enriched phospholipid, and that this binding is required for the correct intracellular distribution of Lpg1137. Two basic residues in the C-terminal region of Lpg1137 are required for PA binding and their mutation causes mislocalization of Lpg1137. This mutant also fails to degrade Stx17 while retaining protease activity. Taken together, our data reveal that Lpg1137 utilizes PA for its distribution to the membranous compartments in which Stx17 is localized.

Legionella hijacks the host Golgi-to-ER retrograde pathway for the association of Legionella-containing vacuole with the ER.

Legionella pneumophila (L. pneumophila) is a gram-negative bacterium that replicates in a compartment that resembles the host endoplasmic reticulum (ER). To create its replicative niche, L. pneumophila manipulates host membrane traffic and fusion machineries. Bacterial proteins called Legionella effectors are translocated into the host cytosol and play a crucial role in these processes. In an early stage of infection, Legionella subverts ER-derived vesicles (ERDVs) by manipulating GTPase Rab1 to facilitate remodeling of the Legionella-containing vacuole (LCV). Subsequently, the LCV associates with the ER in a mechanism that remains elusive. In this study, we show that L. pneumophila recruits GTPases Rab33B and Rab6A, which regulate vesicle trafficking from the Golgi to the ER, to the LCV to promote the association of LCV with the ER. We found that recruitment of Rab6A to the LCV depends on Rab33B. Legionella effector SidE family proteins, which phosphoribosyl-ubiquitinate Rab33B, were found to be necessary for the recruitment of Rab33B to the LCV. Immunoprecipitation experiments revealed that L. pneumophila facilitates the interaction of Rab6 with ER-resident SNAREs comprising syntaxin 18, p31, and BNIP1, but not tethering factors including NAG, RINT-1, and ZW10, which are normally required for syntaxin 18-mediated fusion of Golgi-derived vesicles with the ER. Our results identified a Rab33B-Rab6A cascade on the LCV and the interaction of Rab6 with ER-resident SNARE proteins for the association of LCV with the ER and disclosed the unidentified physiological role of SidE family proteins.

Structural Basis of Ubiquitin Recognition by a Bacterial Ovarian Tumor Deubiquitinase LotA.

Pathogenic bacteria have acquired a vast array of eukaryotic-protein-like proteins via intimate interaction with host cells. Bacterial effector proteins that function as ubiquitin ligases and deubiquitinases (DUBs) are remarkable examples of such molecular mimicry. LotA, a Legionella pneumophila effector, belongs to the ovarian tumor (OTU) superfamily, which regulates diverse ubiquitin signals by their DUB activities. LotA harbors two OTU domains that have distinct reactivities; the first one is responsible for the cleavage of the K6-linked ubiquitin chain, and the second one shows an uncommon preference for long chains of ubiquitin. Here, we report the crystal structure of a middle domain of LotA (LotAM), which contains the second OTU domain. LotAM consists of two distinct subdomains, a catalytic domain having high structural similarity with human OTU DUBs and an extended helical lobe (EHL) domain, which is characteristically conserved only in Legionella OTU DUBs. The docking simulation of LotAM with ubiquitin suggested that hydrophobic and electrostatic interactions between the EHL of LotAM and the C-terminal region of ubiquitin are crucial for the binding of ubiquitin to LotAM. The structure-based mutagenesis demonstrated that the acidic residue in the characteristic short helical segment termed the "helical arm" is essential for the enzymatic activity of LotAM. The EHL domain of the three Legionella OTU DUBs, LotA, LotB, and LotC, share the "helical arm" structure, suggesting that the EHL domain defines the Lot-OTUs as a unique class of DUBs. IMPORTANCE To successfully colonize, some pathogenic bacteria hijack the host ubiquitin system. Legionella OTU-like-DUBs (Lot-DUBs) are novel bacterial deubiquitinases found in effector proteins of L. pneumophila. LotA is a member of Lot-DUBs and has two OTU domains (OTU1 and OTU2). We determined the structure of a middle fragment of LotA (LotAM), which includes OTU2. LotAM consists of the conserved catalytic domain and the Legionella OTUs-specific EHL domain. The docking simulation with ubiquitin and the mutational analysis suggested that the acidic surface in the EHL is essential for enzymatic activity. The structure of the EHL differs from those of other Lot-DUBs, suggesting that the variation of the EHL is related to the variable cleaving specificity of each DUB.

Recent advances in structural studies of the Legionella pneumophila Dot/Icm type IV secretion system.

The intracellular bacterial pathogen Legionella pneumophila utilizes the Dot/Icm type IV secretion system to translocate approximately 300 effector proteins to establish a replicative niche known as the Legionella-containing vacuole. The Dot/Icm system is classified as a type IVB secretion system, which is evolutionarily closely related to the I-type conjugation systems and is distinct from type IVA secretion systems, such as the Agrobacterium VirB/D4 system. Although both type IVA and IVB systems directly transport nucleic acids or proteins into the cytosol of recipient cells, the components and architecture of type IVB systems are much more complex than those of type IVA systems. Taking full advantage of rapidly developing cryo-electron microscopy techniques, the structural details of the transport apparatus and coupling complexes in the Dot/Icm system have been clarified in the past few years. In this review, we summarize recent progress in the structural studies of the L. pneumophila type IVB secretion system and the insights gained into the mechanisms of substrate recognition and transport.

Isolation and Characterization of a Novel Phage SaGU1 that Infects Staphylococcus aureus Clinical Isolates from Patients with Atopic Dermatitis.

The bacterium Staphylococcus aureus, which colonizes healthy human skin, may cause diseases, such as atopic dermatitis (AD). Treatment for such AD cases involves antibiotic use; however, alternate treatments are preferred owing to the development of antimicrobial resistance. This study aimed to characterize the novel bacteriophage SaGU1 as a potential agent for phage therapy to treat S. aureus infections. SaGU1 that infects S. aureus strains previously isolated from the skin of patients with AD was screened from sewage samples in Gifu, Japan. Its genome was sequenced and analyzed using bioinformatics tools, and the morphology, lytic activity, stability, and host range of the phage were determined. The SaGU1 genome was 140,909 bp with an average GC content of 30.2%. The viral chromosome contained 225 putative protein-coding genes and four tRNA genes, carrying neither toxic nor antibiotic resistance genes. Electron microscopy analysis revealed that SaGU1 belongs to the Myoviridae family. Stability tests showed that SaGU1 was heat-stable under physiological and acidic conditions. Host range testing revealed that SaGU1 can infect a broad range of S. aureus clinical isolates present on the skin of AD patients, whereas it did not kill strains of Staphylococcus epidermidis, which are symbiotic resident bacteria on human skin. Hence, our data suggest that SaGU1 is a potential candidate for developing a phage therapy to treat AD caused by pathogenic S. aureus.

LotA, a Legionella deubiquitinase, has dual catalytic activity and contributes to intracellular growth.

The intracellular bacterial pathogen, Legionella pneumophila, establishes the replicative niche as a result of the actions of a large array of effector proteins delivered via the Legionella Type 4 secretion system. Many effector proteins are expected to be involved in biogenesis and regulation of the Legionella-containing vacuole (LCV) that is highly decorated with ubiquitin. Here, we identified a Legionella deubiquitinase, designated LotA, by carrying out a genome analysis to find proteins resembling the eukaryotic ovarian tumour superfamily of cysteine proteases. LotA exhibits a dual ability to cleave ubiquitin chains that is dependent on 2 distinctive catalytic cysteine residues in the eukaryotic ovarian tumour domains. One cysteine dominantly contributes to the removal of ubiquitin from the LCVs by its polyubiquitin cleavage activity. The other specifically cleaves conjugated Lys6-linked ubiquitin. After delivered by the Type 4 secretion system, LotA localises on the LCVs via its PI(3)P-binding domain. The lipid-binding ability of LotA is crucial for ubiquitin removal from the vacuoles. We further analysed the functional interaction of the protein with the recently reported noncanonical ubiquitin ligases of L. pneumophila, revealing that the effector proteins are involved in coordinated regulation that contributes to bacterial growth in the host cells.

Subversion of Host Membrane Dynamics by the Legionella Dot/Icm Type IV Secretion System.

Legionella species are Gram-negative ubiquitous environmental bacteria, which thrive in biofilms and parasitize protozoa. Employing an evolutionarily conserved mechanism, the opportunistic pathogens also replicate intracellularly in mammalian macrophages. This feature is a prerequisite for the pathogenicity of Legionella pneumophila, which causes the vast majority of clinical cases of a severe pneumonia, termed "Legionnaires' disease." In macrophages as well as in amoeba, L. pneumophila grows in a distinct membrane-bound compartment, the Legionella-containing vacuole (LCV). Formation of this replication-permissive pathogen compartment requires the bacterial Dot/Icm type IV secretion system (T4SS). Through the T4SS as many as 300 different "effector" proteins are injected into host cells, where they presumably subvert pivotal processes. Less than 40 Dot/Icm substrates have been characterized in detail to date, a number of which show unprecedented biological activities. Some of these effector proteins target host cell small GTPases, phosphoinositide lipids, the chelator phytate, the ubiquitination machinery, the retromer complex, the actin cytoskeleton, or the autophagy pathway. A recently discovered class of L. pneumophila effectors modulates the activity of other effectors and is termed "metaeffectors." Here, we summarize recent insight into the cellular functions and biochemical activities of L. pneumophila effectors and metaeffectors targeting the host's endocytic, retrograde, or autophagic pathways.

Native structure of a type IV secretion system core complex essential for Legionella pathogenesis.

Bacterial type IV secretion systems are evolutionarily related to conjugation systems and play a pivotal role in infection by delivering numerous virulence factors into host cells. Using transmission electron microscopy, we report the native molecular structure of the core complex of the Dot/Icm type IV secretion system encoded by Legionella pneumophila, an intracellular human pathogen. The biochemically isolated core complex, composed of at least five proteins--DotC, DotD, DotF, DotG, and DotH--has a ring-shaped structure. Intriguingly, morphologically distinct premature complexes are formed in the absence of DotG or DotF. Our data suggest that DotG forms a central channel spanning inner and outer membranes. DotF, a component dispensable for type IV secretion, plays a role in efficient embedment of DotG into the functional core complex. These results highlight a common scheme for the biogenesis of transport machinery.

Modulation of the ubiquitination machinery by Legionella.

The bacterial pathogen Legionella pneumophila manipulates its intracellular fate by co-opting host processes. Using bacterial proteins translocated into host cells, L. pneumophila targets pathways shared by unicellular protozoa and higher eukaryotes. In eukaryotes, an important mechanism that regulates numerous cellular processes, including those designed to kill invading microorganisms, is ubiquitination. Post-translational modification of proteins with ubiquitin is a highly regulated process that either targets proteins for degradation or modifies their activity. It is emerging that L. pneumophila possesses functional mimics of eukaryotic E3 ubiquitin ligases that function with the host ubiquitination machinery to select and modify substrates for polyubiquitination. L. pneumophila proteins have been identified that ubiquitinate both host and bacterial proteins, and ubiquitination of the bacterial protein SidH results in its degradation by the host proteasome. This pathway allows L. pneumophila to temporally regulate effector function inside host cells, and facilitates optimal L. pneumophila replication by undefined mechanisms. This review will focus on our current knowledge of the proteins used by L. pneumophila to co-opt the host ubiquitination machinery, and current progress toward understanding the ubiquitin-mediated processes manipulated by L. pneumophila to facilitate intracellular survival and propagation.

Multi-tiered actions of Legionella effectors to modulate host Rab10 dynamics.

Rab GTPases are representative targets of manipulation by intracellular bacterial pathogens for hijacking membrane trafficking. Legionella pneumophila recruits many Rab GTPases to its vacuole and exploits their activities. Here, we found that infection-associated regulation of Rab10 dynamics involves ubiquitin signaling cascades mediated by the SidE and SidC families of Legionella ubiquitin ligases. Phosphoribosyl-ubiquitination of Rab10 catalyzed by the SidE ligases is crucial for its recruitment to the bacterial vacuole. SdcB, the previously uncharacterized SidC-family effector, resides on the vacuole and contributes to retention of Rab10 at the late stages of infection. We further identified MavC as a negative regulator of SdcB. By the transglutaminase activity, MavC crosslinks ubiquitin to SdcB and suppresses its function, resulting in elimination of Rab10 from the vacuole. These results demonstrate that the orchestrated actions of many L. pneumophila effectors fine-tune the dynamics of Rab10 during infection.

A two-component system serves as a central hub for connecting energy metabolism and plasmid dissemination in bacteria.

Mobile genetic elements such as conjugative plasmids play a key role in the acquisition of antibiotic resistance by pathogenic bacteria. Resistance genes on plasmids can be transferred between bacteria using specialized conjugation machinery. Acinetobacter baumannii, the most common bacterium associated with nosocomial infections, harbors a large conjugative plasmid that encodes a type IV secretion system (T4SS). Feng et al. recently found that the A. baumannii T4SS is specialized for plasmid transfer, suggesting that it may be involved in multidrug resistance (Z. Feng, L. Wang, Q. Guan, X. Chu, and Z.-Q. Luo, mBio e02276-23, 2023, https://doi.org/10.1128/mbio.02276-23), T4SS-encoding genes are shown to be controlled by a versatile GacA/S two-component regulatory system. GacA/S is also found to regulate genes involved in central metabolism. The coordinated regulation of metabolism and plasmid conjugation may be a bacterial strategy for adapting to selective pressure from antibiotics.

Bacterial usurpation of the OTU deubiquitinase fold.

The extensive cellular signalling events controlled by posttranslational ubiquitination are tightly regulated through the action of specialized proteases termed deubiquitinases. Among them, the OTU family of deubiquitinases can play very specialized roles in the regulation of discrete subtypes of ubiquitin signals that control specific cellular functions. To exert control over host cellular functions, some pathogenic bacteria have usurped the OTU deubiquitinase fold as a secreted virulence factor that interferes with ubiquitination inside infected cells. Herein, we provide a review of the function of bacterial OTU deubiquitinases during infection, the structural basis for their deubiquitinase activities and the bioinformatic approaches leading to their identification. Understanding bacterial OTU deubiquitinases holds the potential for discoveries not only in bacterial pathogenesis but in eukaryotic biology as well.

Legionella metaeffector exploits host proteasome to temporally regulate cognate effector.

Pathogen-associated secretion systems translocate numerous effector proteins into eukaryotic host cells to coordinate cellular processes important for infection. Spatiotemporal regulation is therefore important for modulating distinct activities of effectors at different stages of infection. Here we provide the first evidence of "metaeffector," a designation for an effector protein that regulates the function of another effector within the host cell. Legionella LubX protein functions as an E3 ubiquitin ligase that hijacks the host proteasome to specifically target the bacterial effector protein SidH for degradation. Delayed delivery of LubX to the host cytoplasm leads to the shutdown of SidH within the host cells at later stages of infection. This demonstrates a sophisticated level of coevolution between eukaryotic cells and L. pneumophila involving an effector that functions as a key regulator to temporally coordinate the function of a cognate effector protein.

Crystal structure of Legionella DotD: insights into the relationship between type IVB and type II/III secretion systems.

The Dot/Icm type IVB secretion system (T4BSS) is a pivotal determinant of Legionella pneumophila pathogenesis. L. pneumophila translocate more than 100 effector proteins into host cytoplasm using Dot/Icm T4BSS, modulating host cellular functions to establish a replicative niche within host cells. The T4BSS core complex spanning the inner and outer membranes is thought to be made up of at least five proteins: DotC, DotD, DotF, DotG and DotH. DotH is the outer membrane protein; its targeting depends on lipoproteins DotC and DotD. However, the core complex structure and assembly mechanism are still unknown. Here, we report the crystal structure of DotD at 2.0 Å resolution. The structure of DotD is distinct from that of VirB7, the outer membrane lipoprotein of the type IVA secretion system. In contrast, the C-terminal domain of DotD is remarkably similar to the N-terminal subdomain of secretins, the integral outer membrane proteins that form substrate conduits for the type II and the type III secretion systems (T2SS and T3SS). A short ß-segment in the otherwise disordered N-terminal region, located on the hydrophobic cleft of the C-terminal domain, is essential for outer membrane targeting of DotH and Dot/Icm T4BSS core complex formation. These findings uncover an intriguing link between T4BSS and T2SS/T3SS.

Assembly of the inner rod determines needle length in the type III secretion injectisome.

Assembly of multi-component supramolecular machines is fundamental to biology, yet in most cases, assembly pathways and their control are poorly understood. An example is the type III secretion machine, which mediates the transfer of bacterial virulence proteins into host cells. A central component of this nanomachine is the needle complex or injectisome, an organelle associated with the bacterial envelope that is composed of a multi-ring base, an inner rod, and a protruding needle. Assembly of this organelle proceeds in sequential steps that require the reprogramming of the secretion machine. Here we provide evidence that, in Salmonella typhimurium, completion of the assembly of the inner rod determines the size of the needle substructure. Assembly of the inner rod, which is regulated by the InvJ protein, triggers conformational changes on the cytoplasmic side of the injectisome, reprogramming the secretion apparatus to stop secretion of the needle protein.

Protocol for imaging proteins associated with Legionella-containing vacuoles in host cells.

The intracellular bacterial pathogen Legionella pneumophila exploits host cellular systems using approximately 300 effector proteins to establish a replicative niche known as the Legionella-containing vacuole (LCV). During infection, both host and bacterial proteins interactively function on the LCVs. Here, we describe a detailed step-by-step protocol to visualize proteins associated with LCVs in host cells. This protocol can aid in analyzing whether a protein of interest influences the subcellular localization of LCV-associated proteins during infection. For complete details on the use and execution of this protocol, please refer to Kitao et al. (2020).