Bacterial flagella hijack type IV pili proteins to control motility

Structural differences in the outer membrane-associated flagellar rings between sheathed and unsheathed flagella

The bacterial flagellar motor generates a torque to move the bacterium in its environment. Despite sharing a conserved core, flagellar motors of different species exhibit structural diversity with species-specific embellishments. These embellishments are classified into various types, including integrated (spanning the whole periplasmic space) or outer membrane (OM)-associated ones. Here, we used cryo-electron tomography to investigate the structural differences between the embellishments of sheathed and unsheathed flagella in various species. We discovered that the integrated embellishments of sheathed flagella have disks and rings with a constant diameter, while those of unsheathed flagella have components that vary significantly in diameter. Both unsheathed and sheathed flagella with OM-associated embellishments have components with constant diameter with a subset of motors having an additional extracellular ring. In this Hypothesis article, we propose that these differences may play a role in the formation of the sheath, as having large protein disks of various diameters underneath the OM may interfere with membrane bending to form the sheath.

FlgY, PflA, and PflB form a spoke-ring network in the high-torque flagellar motor of Helicobacter pylori

Helicobacter pylori has evolved distinct flagellar motility to colonize the human stomach. Rotation of the H. pylori flagella is driven by one of the largest known bacterial flagellar motors. In addition to the core motor components found in Escherichia coli and Salmonella enterica, the flagellar motor in H. pylori possesses many accessories that enable the bacteria to penetrate the gastric mucus layer. Here, we utilize cryoelectron tomography with molecular genetics and biochemical approaches to characterize three accessory proteins, FlgY, PflA, and PflB, and their roles in H. pylori flagellar assembly and motility. Comparative analyses of in situ flagellar motor structures from pflA, pflB, and flgY mutants and wild-type H. pylori reveal that FlgY forms a 13-fold proximal spoke-ring around the MS-ring and that PflA and PflB form an 18-fold distal spoke-ring enclosing 18 torque-generating stator complexes. We build a pseudoatomic model of the H. pylori motor by leveraging AlphaFold-predicted structures, protein-protein interactions, and in situ motor structures. Our model suggests that the FlgY spoke-ring functions as a bearing around the rotating MS-ring and as a template for stabilizing the PflA-PflB spoke-ring, thus enabling the recruitment of 18 stator complexes for high-torque generation. Overall, our study sheds light on how this spoke-ring network between the MS-ring and stator complexes enables the unique motility of H. pylori. As these accessory proteins are conserved in the phylum Campylobacterota, our findings apply broadly to a better understanding of how polar flagella help bacteria thrive in gastric and enteric niches.

The architecture, assembly, and evolution of a complex flagellar motor

Bacterial flagella drive motility in many species, likely including the last bacterial common ancestor 1,2 . Knowledge of flagellar assembly and function has mainly come from studies of Escherichia coli and Salmonella enterica , which have simple flagellar motors 3-7 . However, most flagellated bacteria possess complex motors with unique, species-specific adaptations whose mechanisms and evolution remain largely unexplored 8-10 . Here, we deploy a multidisciplinary approach to build a near-complete model of the flagellar motor in Campylobacter jejuni , revealing its remarkable complexity in architecture and composition. We identify an E-ring around the MS-ring, a periplasmic cage with two distinctive conformations, and an intricate interaction network between the E-ring and cage. These scaffolds play critical roles in stabilizing and regulating 17 torque-generating stator complexes for optimal motility. In-depth evolutionary analyses uncover the ancient origin and prevalence of the E-ring in flagellated species of the domain Bacteria as well as a unique exaptation of type IV pili components PilMNOPQF in the ancestral motor of the phylum Campylobacterota . Collectively, our studies reveal novel mechanisms of assembly and function in complex flagellar motors and shed light on the evolution of flagella and modern bacterial species.

Genomic characteristics and virulence of common but overlooked Yersinia intermedia, Y. frederiksenii, and Y. kristensenii in food

Yersinia intermedia, Y. frederiksenii, and Y. kristensenii are a group of pathogens that are commonly found in food and are often overlooked in terms of their pathogenic potential. This study conducted a systematic and comprehensive genomic analysis of 114 Y. intermedia genomes, 20 Y. frederiksenii genomes, and 65 Y. kristensenii genomes from public database and our previous study. The results showed that these species were most frequently detected in Europe (56.28 %, 112/199), followed by in Asia (20.6 %, 41/199). Additionally, 33.17 % (66/199) genomes were isolated from food. Y. intermedia were grouped into Bayesian analysis of population structure (Baps) groups 3 and 4, demonstrating significant genomic diversity. This species has a high proportion of accessory genes (79.43 %), approximately 50 % of which have unknown functions, indicating a high degree of genomic plasticity. The three species carried a large number of mobile genetic elements (MGEs), including plasmids such as ColRNAI_1, ColE10_1, Col440II_1, Col440I_1, and Col (Ye4449) _1; insertion sequences (ISs) like MITEYpe1, MITEEc1, and IS1635; genomic islands (GIs); and prophages. In Y. intermedia, the following antibiotics resistance genes (ARGs) were detected: qnrD1 in 3.51 % (4/114), aph(3')-Ia in 2.63 % (3/114), blaA in 1.75 % (2/114), and catA1, vat(F), and tet(C) each in 0.88 % (1/114). In Y. kristensenii, vat(F) was present in 98.46 % (64/65), blaTEM-116 in 7.69 % (5/65), and aph(3')-Ia in 1.54 % (1/65). However, only one Y. frederiksenii genome carried vat(F). There were differences in the virulence gene composition of the three species, with Y. kristensenii having the highest number of virulence genes, particularly its complete cytotoxic genes (yaxA and yaxB) and flagellar motor proteins genes (motA and motB). The pathogenic mechanisms of Y. intermedia and Y. frederiksenii were more similar, especially in the carriage of O-antigen related genes. Y. frederiksenii's unique mechanisms also include the yapC gene, which encodes the autotransporter protein YapC from Y. pestis. After co-cultured with human colonic epithelial cell lines Caco-2 and HT-29, Y. intermedia and Y. kristensenii demonstrated different adhesive and invasive capabilities, particularly the Y. intermedia strain y7, which exhibited stronger adhesion and invasion in both cell lines. In strains y118 and y119 of Y. intermedia, an Arg378del mutation in the UreC protein was identified, resulting in the loss of urease activity. Therefore, this study revealed the pathogenic potential of Y. intermedia, Y. frederiksenii, and Y. kristensenii. Future research should focus on identifying their unknown virulence genes and strengthening public food safety measures to mitigate potential risks.

Helicobacter pylori and gastric cancer: mechanisms and new perspectives

Gastric cancer remains a significant global health challenge, with Helicobacter pylori (H. pylori) recognized as a major etiological agent, affecting an estimated 50% of the world's population. There has been a rapidly expanding knowledge of the molecular and pathogenetic mechanisms of H. pylori over the decades. This review summarizes the latest research advances to elucidate the molecular mechanisms underlying the H. pylori infection in gastric carcinogenesis. Our investigation of the molecular mechanisms reveals a complex network involving STAT3, NF-κB, Hippo, and Wnt/β-catenin pathways, which are dysregulated in gastric cancer caused by H. pylori. Furthermore, we highlight the role of H. pylori in inducing oxidative stress, DNA damage, chronic inflammation, and cell apoptosis-key cellular events that pave the way for carcinogenesis. Emerging evidence also suggests the effect of H. pylori on the tumor microenvironment and its possible implications for cancer immunotherapy. This review synthesizes the current knowledge and identifies gaps that warrant further investigation. Despite the progress in our previous knowledge of the development in H. pylori-induced gastric cancer, a comprehensive investigation of H. pylori's role in gastric cancer is crucial for the advancement of prevention and treatment strategies. By elucidating these mechanisms, we aim to provide a more in-depth insights for the study and prevention of H. pylori-related gastric cancer.

PilY1 regulates the dynamic architecture of the type IV pilus machine in Pseudomonas aeruginosa

Type IV pili (T4P) produced by the pathogen Pseudomonas aeruginosa play a pivotal role in adhesion, surface motility, biofilm formation, and infection in humans. Despite the significance of T4P as a potential therapeutic target, key details of their dynamic assembly and underlying molecular mechanisms of pilus extension and retraction remain elusive, primarily due to challenges in isolating intact T4P machines from the bacterial cell envelope. Here, we combine cryo-electron tomography with subtomogram averaging and integrative modelling to resolve in-situ architectural details of the dynamic T4P machine in P. aeruginosa cells. The T4P machine forms 7-fold symmetric cage-like structures anchored in the cell envelope, providing a molecular framework for the rapid exchange of major pilin subunits during pilus extension and retraction. Our data suggest that the T4P adhesin PilY1 forms a champagne-cork-shaped structure, effectively blocking the secretin channel in the outer membrane whereas the minor-pilin complex in the periplasm appears to contact PilY1 via the central pore of the secretin gate. These findings point to a hypothetical model where the interplay between the secretin protein PilQ and the PilY1-minor-pilin priming complex is important for optimizing conformations of the T4P machine in P. aeruginosa, suggesting a gate-keeping mechanism that regulates pilus dynamics.

Functional and biochemical characterisation of remote homologues of type IV pili proteins PilN and PilO in Helicobacter pylori

Helicobacter pylori encodes homologues of PilM, PilN and PilO from bacteria with Type IV pili, where these proteins form a pilus alignment complex. Inactivation of pilO changes H. pylori motility in semi-solid media, suggesting a link to the chemosensory pathways or flagellar motor. Here, we showed that mutation of the pilO or pilN gene in H. pylori strain SS1 reduced the mean linear swimming speed in liquid media, implicating PilO and PilN in the function, or regulation of, the flagellar motor. We also demonstrated that the soluble variants of H. pylori PilN and PilO share common biochemical properties with their Type IV pili counterparts which suggests their adapted function in the bacterial flagellar motor may be similar to that in the Type IV pili.

Biochemical characterization of paralyzed flagellum proteins A (PflA) and B (PflB) from Helicobacter pylori flagellar motor

Motility by means of flagella plays an important role in the persistent colonization of Helicobacter pylori in the human stomach. The H. pylori flagellar motor has a complex structure that includes a periplasmic scaffold, the components of which are still being identified. Here, we report the isolation and characterization of the soluble forms of two putative essential H. pylori motor scaffold components, proteins PflA and PflB. We developed an on-column refolding procedure, overcoming the challenge of inclusion body formation in Escherichia coli. We employed mild detergent sarkosyl to enhance protein recovery and n-dodecyl-N,N-dimethylamine-N-oxide (LDAO)-containing buffers to achieve optimal solubility and monodispersity. In addition, we showed that PflA lacking the β-rich N-terminal domain is expressed in a soluble form, and behaves as a monodisperse monomer in solution. The methods for producing the soluble, folded forms of H. pylori PflA and PflB established in this work will facilitate future biophysical and structural studies aimed at deciphering their location and their function within the flagellar motor.

Function and Global Regulation of Type III Secretion System and Flagella in Entomopathogenic Nematode Symbiotic Bacteria

Currently, it is widely accepted that the type III secretion system (T3SS) serves as the transport platform for bacterial virulence factors, while flagella act as propulsion motors. However, there remains a noticeable dearth of comparative studies elucidating the functional disparities between these two mechanisms. Entomopathogenic nematode symbiotic bacteria (ENS), including Xenorhabdus and Photorhabdus, are Gram-negative bacteria transported into insect hosts by Steinernema or Heterorhabdus. Flagella are conserved in ENS, but the T3SS is only encoded in Photorhabdus. There are few reports on the function of flagella and the T3SS in ENS, and it is not known what role they play in the infection of ENS. Here, we clarified the function of the T3SS and flagella in ENS infection based on flagellar inactivation in X. stockiae (flhDC deletion), T3SS inactivation in P. luminescens (sctV deletion), and the heterologous synthesis of the T3SS of P. luminescens in X. stockiae. Consistent with the previous results, the swarming movement of the ENS and the formation of biofilms are dominated by the flagella. Both the T3SS and flagella facilitate ENS invasion and colonization within host cells, with minimal impact on secondary metabolite formation and secretion. Unexpectedly, a proteomic analysis reveals a negative feedback loop between the flagella/T3SS assembly and the type VI secretion system (T6SS). RT-PCR testing demonstrates the T3SS's inhibition of flagellar assembly, while flagellin expression promotes T3SS assembly. Furthermore, T3SS expression stimulates ribosome-associated protein expression.

Counterclockwise rotation of the flagellum promotes biofilm initiation in Helicobacter pylori

Motility promotes biofilm initiation during the early steps of this process: microbial surface association and attachment. Motility is controlled in part by chemotaxis signaling, so it seems reasonable that chemotaxis may also affect biofilm formation. There is a gap, however, in our understanding of the interactions between chemotaxis and biofilm formation, partly because most studies analyzed the phenotype of only a single chemotaxis signaling mutant, e.g., cheA. Here, we addressed the role of chemotaxis in biofilm formation using a full set of chemotaxis signaling mutants in Helicobacter pylori, a class I carcinogen that infects more than half the world's population and forms biofilms. Using mutants that lack each chemotaxis signaling protein, we found that chemotaxis signaling affected the biofilm initiation stage, but not mature biofilm formation. Surprisingly, some chemotaxis mutants elevated biofilm initiation, while others inhibited it in a manner that was not tied to chemotaxis ability or ligand input. Instead, the biofilm phenotype correlated with flagellar rotational bias. Specifically, mutants with a counterclockwise bias promoted biofilm initiation, e.g., ∆cheA, ∆cheW, or ∆cheV1; in contrast, those with a clockwise bias inhibited it, e.g., ∆cheZ, ∆chePep, or ∆cheV3. We tested this correlation using a counterclockwise bias-locked flagellum, which induced biofilm formation independent of the chemotaxis system. These CCW flagella, however, were not sufficient to induce biofilm formation, suggesting there are downstream players. Overall, our work highlights the new finding that flagellar rotational direction promotes biofilm initiation, with the chemotaxis signaling system operating as one mechanism to control flagellar rotation.

IMPORTANCE

Chemotaxis signaling systems have been reported to contribute to biofilm formation in many bacteria; however, how they regulate biofilm formation remains largely unknown. Chemotaxis systems are composed of many distinct kinds of proteins, but most previous work analyzed the biofilm effect of loss of only a few. Here, we explored chemotaxis' role during biofilm formation in the human-associated pathogenic bacterium Helicobacter pylori. We found that chemotaxis proteins are involved in biofilm initiation in a manner that correlated with how they affected flagellar rotation. Biofilm initiation was high in mutants with counterclockwise (CCW) flagellar bias and low in those with clockwise bias. We supported the idea that a major driver of biofilm formation is flagellar rotational direction using a CCW-locked flagellar mutant, which stays CCW independent of chemotaxis input and showed elevated biofilm initiation. Our data suggest that CCW-rotating flagella, independent of chemotaxis inputs, are a biofilm-promoting signal.

The swimming defect caused by the absence of the transcriptional regulator LdtR in Sinorhizobium meliloti is restored by mutations in the motility genes motA and motS

The flagellar motor is a powerful macromolecular machine used to propel bacteria through various environments. We determined that flagellar motility of the alpha-proteobacterium Sinorhizobium meliloti is nearly abolished in the absence of the transcriptional regulator LdtR, known to influence peptidoglycan remodeling and stress response. LdtR does not regulate motility gene transcription. Remarkably, the motility defects of the ΔldtR mutant can be restored by secondary mutations in the motility gene motA or a previously uncharacterized gene in the flagellar regulon, which we named motS. MotS is not essential for S. meliloti motility and may serve an accessory role in flagellar motor function. Structural modeling predicts that MotS comprised an N-terminal transmembrane segment, a long-disordered region, and a conserved β-sandwich domain. The C terminus of MotS is localized in the periplasm. Genetics based substitution of MotA with MotAG12S also restored the ΔldtR motility defect. The MotAG12S variant protein features a local polarity shift at the periphery of the MotAB stator units. We propose that MotS may be required for optimal alignment of stators in wild-type flagellar motors but becomes detrimental in cells with altered peptidoglycan. Similarly, the polarity shift in stator units composed of MotB/MotAG12S might stabilize its interaction with altered peptidoglycan.

Helicobacter pylori cheV1 mutants recover semisolid agar migration due to loss of a previously uncharacterized Type IV filament membrane alignment complex homolog

The bacterial chemotaxis system is a well-understood signaling pathway that promotes bacterial success. Chemotaxis systems comprise chemoreceptors and the CheA kinase, linked by CheW or CheV scaffold proteins. Scaffold proteins provide connections between chemoreceptors and CheA and also between chemoreceptors to create macromolecular arrays. Chemotaxis is required for host colonization by many microbes, including the stomach pathogen Helicobacter pylori. This bacterium builds chemoreceptor-CheA contacts with two distinct scaffold proteins, CheW and CheV1. H. pylori cheW or cheV1 deletion mutants both lose chemoreceptor array formation, but show differing semisolid agar chemotaxis assay behaviors: ∆cheW mutants exhibit total migration failure, whereas ∆cheV1::cat mutants display a 50% reduction. On investigating these varied responses, we found that both mutants initially struggle with migration. However, over time, ∆cheV1::cat mutants develop a stable, enhanced migration capability, termed "migration-able" (Mig+). Whole-genome sequencing analysis of four distinct ∆cheV1::cat Mig+ strains identified single-nucleotide polymorphisms (SNPs) in hpg27_252 (hp0273) that were predicted to truncate the encoded protein. Computational analysis of the hpg27_252-encoded protein revealed it encoded a hypothetical protein that was a remote homolog of the PilO Type IV filament membrane alignment complex protein. Although H. pylori lacks Type IV filaments, our analysis showed it retains an operon of genes for homologs of PilO, PilN, and PilM. Deleting hpg27_252 in the ∆cheV1::cat or wild type strain resulted in enhanced migration in semisolid agar. Our study thus reveals that while cheV1 mutants initially have significant migration defects, they can recover the migration ability through genetic suppressors, highlighting a complex regulatory mechanism in bacterial migration.

IMPORTANCE

Chemotactic motility, present in over half of bacteria, depends on chemotaxis signaling systems comprising receptors, kinases, and scaffold proteins. In Helicobacter pylori, a stomach pathogen, chemotaxis is crucial for colonization, with CheV1 and CheW as key scaffold proteins. While both scaffolds are essential for building chemoreceptor complexes, their roles vary in other assays. Our research reexamines cheV1 mutants' behavior in semisolid agar, a standard chemotaxis test. Initially, cheV1 mutants exhibited defects similar to those of cheW mutants, but they evolved genetic suppressors that enhanced migration. These suppressors involve mutations in a previously uncharacterized gene, unknown in motility behavior. Our findings highlight the significant chemotaxis defects in cheV1 mutants and identify new elements influencing bacterial motility.