Your search keyword '"Flagella physiology"' showing total 2,995 results

1. Molecular mechanism of flagellar motor rotation arrest in bacterial zoospores of Actinoplanes missouriensis before germination.

Author

Kato H, Tanemura H, Kimura T, Katsuyama Y, Tezuka T, and Ohnishi Y

Subjects

Spores, Bacterial genetics, Spores, Bacterial metabolism, Flagella metabolism, Flagella physiology, Flagella genetics, Bacterial Proteins metabolism, Bacterial Proteins genetics, Chemotaxis genetics

Abstract

Zoospores of the filamentous actinomycete Actinoplanes missouriensis swim vigorously using flagella and stop swimming to initiate germination in response to nutrient exposure. However, the molecular mechanisms underlying swimming cessation remain unknown. A protein (FtgA) of unknown function encoded by a chemotaxis gene cluster (che cluster-1) was found to be required for flagellar rotation arrest; the zoospores of ftgA-knockout mutants kept swimming awkwardly after germination. An ftgA-overexpressing strain exhibited a non-flagellated phenotype. Isolation of a suppressor strain from this strain and further in vivo experiments revealed that the extended N-terminal region of FliN, a component of the C-ring of the flagellar basal body, was involved in the function of FtgA; FliN-P101S canceled the flagellar rotation arrest by FtgA, as well as the negative effect of ftgA-overexpression on flagellation. Furthermore, bacterial two-hybrid assays suggested that FtgA interacted not only with the C-terminal core region of FliN but also with chemotaxis regulatory proteins CheA1 and CheW1-2, which are encoded by che cluster-1. We propose the following working model of motility regulation in A. missouriensis zoospores: the chemotaxis sensory complex initially captures FtgA to allow zoospores to swim and then releases FtgA to stop flagellar rotation (i.e., swimming) in response to external nutrient signals., (© 2024. The Author(s).)

Published

2024

2. Adhesion of Crithidia fasciculata promotes a rapid change in developmental fate driven by cAMP signaling.

Author

Denecke S, Malfara MF, Hodges KR, Holmes NA, Williams AR, Gallagher-Teske JH, Pascarella JM, Daniels AM, Sterk GJ, Leurs R, Ruthel G, Hoang R, Povelones ML, and Povelones M

Subjects

Flagella physiology, Flagella metabolism, Protozoan Proteins metabolism, Protozoan Proteins genetics, Animals, Cyclic AMP metabolism, Signal Transduction, Cell Adhesion, Crithidia fasciculata genetics, Crithidia fasciculata metabolism, Crithidia fasciculata growth & development

Abstract

Trypanosomatids are single-celled parasites responsible for human and animal disease. Typically, colonization of an insect host is required for transmission. Stable attachment of parasites to insect tissues via their single flagellum coincides with differentiation and morphological changes. Although attachment is a conserved stage in trypanosomatid life cycles, the molecular mechanisms are not well understood. To study this process, we elaborate upon an in vitro model in which the swimming form of the trypanosomatid Crithidia fasciculata rapidly differentiates following adhesion to artificial substrates. Live imaging of cells transitioning from swimming to attached shows parasites undergoing a defined sequence of events, including an initial adhesion near the base of the flagellum immediately followed by flagellar shortening, cell rounding, and the formation of a hemidesmosome-like attachment plaque between the tip of the shortened flagellum and the substrate. Quantitative proteomics of swimming versus attached parasites suggests differential regulation of cyclic adenosine monophosphate (cAMP)-based signaling proteins. We have localized two of these proteins to the flagellum of swimming C. fasciculata ; however, both are absent from the shortened flagellum of attached cells. Pharmacological inhibition of cAMP phosphodiesterases increased cAMP levels in the cell and prevented attachment. Further, treatment with inhibitor did not affect the growth rate of either swimming or established attached cells, indicating that its effect is limited to a critical window during the early stages of adhesion. These data suggest that cAMP signaling is required for attachment of C. fasciculata and that flagellar signaling domains may be reorganized during differentiation and attachment.IMPORTANCETrypanosomatid parasites cause significant disease burden worldwide and require insect vectors for transmission. In the insect, parasites attach to tissues, sometimes dividing as attached cells or producing motile, infectious forms. The significance and cellular mechanisms of attachment are relatively unexplored. Here, we exploit a model trypanosomatid that attaches robustly to artificial surfaces to better understand this process. This attachment recapitulates that observed in vivo and can be used to define the stages and morphological features of attachment as well as conditions that impact attachment efficiency. We have identified proteins that are enriched in either swimming or attached parasites, supporting a role for the cyclic AMP signaling pathway in the transition from swimming to attached. As this pathway has already been implicated in environmental sensing and developmental transitions in trypanosomatids, our data provide new insights into activities required for parasite survival in their insect hosts., Competing Interests: The authors declare no conflict of interest.

Published

2024

3. Exploring flagellar contributions to motility and virulence in Arcobacter butzleri.

Author

Santos R, Mateus C, Oleastro M, and Ferreira S

Subjects

Humans, Virulence, Caco-2 Cells, Bacterial Proteins genetics, Bacterial Proteins metabolism, Bile Acids and Salts metabolism, Bile Acids and Salts pharmacology, Fatty Acids, Volatile metabolism, Flagella genetics, Flagella physiology, Flagella metabolism, Arcobacter genetics, Arcobacter pathogenicity, Arcobacter metabolism, Biofilms growth & development, Bacterial Adhesion, Mucins metabolism

Abstract

Flagella is a well-known bacterial structure crucial for motility, which also plays pivotal roles in pathogenesis. Arcobacter butzleri, an enteropathogen, possesses a distinctive polar flagellum whose functional aspects remain largely unexplored. Upon investigating the factors influencing A. butzleri motility, we uncovered that environmental conditions like temperature, oxygen levels, and nutrient availability play a significant role. Furthermore, compounds that are found in human gut, such as short-chain fatty acids, mucins and bile salts, have a role in modulating the motility, and in turn, the pathogenicity of A. butzleri. Further investigation demonstrated that A. butzleri ΔflaA mutant showed a reduction in motility with a close to null average velocity, as well as a reduction on biofilm formation. In addition, compared with the wild-type, the ΔflaA mutant showed a decreased ability to invade Caco-2 cells and to adhere to mucins. Taken together, our findings support the role of environmental conditions and gut host associated compounds influencing key physiological aspects of the gastrointestinal pathogen A. butzleri, such as motility, and support the role of the flagellum on bacterial virulence., (© 2024. The Author(s), under exclusive licence to Springer Nature B.V.)

Published

2024

4. Hybrid Exb/Mot stators require substitutions distant from the chimeric pore to power flagellar rotation.

Author

Ridone P and Baker MAB

Subjects

Escherichia coli genetics, Escherichia coli metabolism, Rotation, Recombinant Fusion Proteins metabolism, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins chemistry, Flagella physiology, Molecular Motor Proteins metabolism, Molecular Motor Proteins genetics, Molecular Motor Proteins chemistry, Bacterial Proteins genetics, Bacterial Proteins metabolism

Abstract

Powered by ion transport across the cell membrane, conserved ion-powered rotary motors (IRMs) drive bacterial motility by generating torque on the rotor of the bacterial flagellar motor. Homologous heteroheptameric IRMs have been structurally characterized in ion channels such as Tol/Ton/Exb/Gld, and most recently in phage defense systems such as Zor. Functional stator complexes synthesized from chimeras of PomB/MotB (PotB) have been used to study flagellar rotation at low ion-motive force achieved via reduced external sodium concentration. The function of such chimeras is highly sensitive to the location of the fusion site, and these hybrid proteins have thus far been arbitrarily designed. To date, no chimeras have been constructed using interchange of components from Tol/Ton/Exb/Gld and other ion-powered motors with more distant homology. Here, we synthesized chimeras of MotAB, PomAPotB, and ExbBD to assess their capacity for cross-compatibility. We generated motile strains powered by stator complexes with B-subunit chimeras. This motility was further optimized by directed evolution. Whole-genome sequencing of these strains revealed that motility-enhancing residue changes occurred in the A-subunit and at the peptidoglycan binding domain of the B-unit, which could improve motility. Overall, our work highlights the complexity of stator architecture and identifies the challenges associated with the rational design of chimeric IRMs., Importance: Ion-powered rotary motors (IRMs) underpin the rotation of one of nature's oldest wheels, the flagellar motor. Recent structures show that this complex appears to be a fundamental molecular module with diverse biological utility where electrical energy is coupled to torque. Here, we attempted to rationally design chimeric IRMs to explore the cross-compatibility of these ancient motors. We succeeded in making one working chimera of a flagellar motor and a non-flagellar transport system protein. This had only a short hybrid stretch in the ion-conducting channel, and function was subsequently improved through additional substitutions at sites distant from this hybrid pore region. Our goal was to test the cross-compatibility of these homologous systems and highlight challenges arising when engineering new rotary motors., Competing Interests: The authors declare no conflict of interest.

Published

2024

5. Flagellar point mutation causes social aggregation in laboratory-adapted Bacillus subtilis under conditions that promote swimming.

Author

Alvi S, Mondelo VD, Boyle J, Buck A, Gejo J, Mason M, Matta S, Sheridan A, Kreutzberger MAB, Egelman EH, and McLoon A

Subjects

Bacterial Proteins genetics, Bacterial Proteins metabolism, Gene Expression Regulation, Bacterial, Bacillus subtilis genetics, Bacillus subtilis physiology, Flagella genetics, Flagella physiology, Point Mutation, Flagellin genetics, Flagellin metabolism

Abstract

Motility allows microbes to explore and maximize success in their environment; however, many laboratory bacterial strains have a reduced or altered capacity for motility. Swimming motility in Bacillus subtilis depends on peritrichous flagella and is carried out individually as cells move by biased random walks toward attractants. Previously, we adapted Bacillus subtilis strain 3610 to the laboratory for 300 generations in lysogeny broth (LB) batch culture and isolated lab-adapted strains. Strain SH2 is motility-defective and in broth culture forms large, frequently spherical aggregates of cells. A single point mutation in the flagellin gene hag that causes amino acid 259 to switch from A to T is necessary and sufficient to cause these social cell aggregates, and aggregation occurs between flagellated cells bearing this point mutation regardless of the strain background. Cells associate when bearing this mutation, but flagellar rotation is needed to pull associating cells into spherical aggregates. Using electron microscopy, we are able to show that the SH2 flagellar filament has limited polymorphism when compared to other flagellar structures. This limited polymorphism hinders the flagellum's ability to function as a motility apparatus but appears to alter its function to that of cell aggregation/adhesion. We speculate that the genotype-specific aggregation of cells producing Hag A259T flagella could have increased representation in a batch-culture experiment by allowing similar cells to go through a transfer together and also that this mutation could serve as an early step to evolve sociality in the natural world.IMPORTANCEThe first life forms on this planet were prokaryotic, and the earliest environments were aquatic, and from these relatively simple starting conditions, complex communities of microbes and ultimately multicellular organisms were able to evolve. Usually, motile cells in aqueous environments swim as individuals but become social by giving up motility and secreting extracellular substances to become a biofilm. Here, we identify a single point mutation in the flagellum that is sufficient to allow cells containing this mutation to specifically form large, suspended groups of cells. The specific change in the flagellar filament protein subunits causes a unique change in the flagellar structure. This could represent a distinct way for closely related cells to associate as an early precursor to sociality., Competing Interests: The authors declare no conflict of interest.

Published

2024

6. Interspecies surfactants serve as public goods enabling surface motility in Pseudomonas aeruginosa .

Author

Warrell DL, Zarrella TM, Machalek C, and Khare A

Subjects

Staphylococcus aureus genetics, Staphylococcus aureus drug effects, Staphylococcus aureus physiology, Staphylococcus aureus metabolism, Movement, Pseudomonas aeruginosa genetics, Pseudomonas aeruginosa physiology, Pseudomonas aeruginosa metabolism, Pseudomonas aeruginosa drug effects, Surface-Active Agents pharmacology, Surface-Active Agents metabolism, Flagella physiology

Abstract

In most natural environments, bacteria live in polymicrobial communities where secreted molecules from neighboring species alter bacterial behaviors, including motility, but such interactions are understudied. Pseudomonas aeruginosa is a motile opportunistic pathogen that exists in diverse multispecies environments, such as the soil, and is frequently found in human wound and respiratory tract co-infections with other bacteria, including Staphylococcus aureus . Here, we show that P. aeruginosa can co-opt secreted surfactants from other species for flagellar-based surface motility. We found that exogenous surfactants from S. aureus , other bacteria, and interkingdom species enabled P. aeruginosa to switch from swarming to an alternative surface spreading motility on semi-solid surfaces and allowed for the emergence of surface motility on hard agar where P. aeruginosa was otherwise unable to move. Although active flagellar function was required for surface spreading, known motility regulators were not essential, indicating that surface spreading may be regulated by an as yet unknown mechanism. This motility was distinct from the response of most other motile bacterial species in the presence of exogenous surfactants. Mutant analysis indicated that this P. aeruginosa motility was similar to a previously described mucin-based motility, "surfing," albeit with divergent regulation. Thus, our study demonstrates that secreted surfactants from the host as well as neighboring bacterial and interkingdom species act as public goods facilitating P. aeruginosa flagella-mediated surfing-like surface motility, thereby allowing it to access different environmental niches., Importance: Bacterial motility is an important determinant of bacterial fitness and pathogenesis, allowing expansion and invasion to access nutrients and adapt to new environments. Here, we demonstrate that secreted surfactants from a variety of foreign species, including other bacterial species, infection hosts, fungi, and plants, facilitate surface spreading motility in the opportunistic pathogen Pseudomonas aeruginosa that is distinct from established motility phenotypes. This response to foreign surfactants also occurs in Pseudomonas putida , but not in more distantly related bacterial species. Our systematic characterization of surfactant-based surface spreading shows that these interspecies surfactants serve as public goods to enable P. aeruginosa to move and explore environmental conditions when it would be otherwise immotile., Competing Interests: The authors declare no conflict of interest.

Published

2024

7. Fly-fishing for flagella.

Author

Caulton SG and Lovering AL

Subjects

Bacterial Adhesion, Bacteroidetes physiology, Flagella physiology, Flagella ultrastructure, Vibrio physiology

Abstract

Molecular grappling hooks are the tools of a sticky bacterial predator.

Published

2024

8. The HmrABCX pathway regulates the transition between motile and sessile lifestyles in Caulobacter crescentus by a mechanism independent of hfiA transcription.

Author

Zappa S, Berne C, Morton Iii RI, Whitfield GB, De Stercke J, and Brun YV

Subjects

Histidine Kinase metabolism, Histidine Kinase genetics, Cyclic GMP metabolism, Cyclic GMP analogs & derivatives, Flagella genetics, Flagella metabolism, Flagella physiology, Transcription, Genetic, Bacterial Adhesion, Locomotion, Caulobacter crescentus genetics, Caulobacter crescentus physiology, Caulobacter crescentus metabolism, Gene Expression Regulation, Bacterial, Biofilms growth & development, Bacterial Proteins genetics, Bacterial Proteins metabolism

Abstract

During its cell cycle, the bacterium Caulobacter crescentus switches from a motile, free-living state, to a sessile surface-attached cell. During this coordinated process, cells undergo irreversible morphological changes, such as shedding of their polar flagellum and synthesis of an adhesive holdfast at the same pole. In this work, we used genetic screens to identify genes involved in the regulation of the transition from the motile to the sessile lifestyle. We identified a predicted hybrid histidine kinase that inhibits biofilm formation and promotes the motile lifestyle: HmrA ( h oldfast and m otility r egulator A). Genetic screens and genomic localization led to the identification of additional genes that form a putative phosphorelay pathway with HmrA. We postulate that the Hmr pathway acts as a rheostat to control the proportion of cells harboring a flagellum or a holdfast in the population. Further genetic analysis suggests that the Hmr pathway impacts c-di-GMP synthesis through the diguanylate cyclase DgcB pathway. Our results also indicate that the Hmr pathway is involved in the regulation of motile to sessile lifestyle transition as a function of various environmental factors: biofilm formation is repressed when excess copper is present and derepressed under non-optimal temperatures. Finally, we provide evidence that the Hmr pathway regulates motility and adhesion without modulating the transcription of the holdfast synthesis regulator HfiA., Importance: Complex communities attached to a surface, or biofilms, represent the major lifestyle of bacteria in the environment. Such a sessile state enables the inhabitants to be more resistant to adverse environmental conditions. Thus, having a deeper understanding of the underlying mechanisms that regulate the transition between the motile and the sessile states could help design strategies to improve biofilms when they are beneficial or impede them when they are detrimental. For Caulobacter crescentus motile cells, the transition to the sessile lifestyle is irreversible, and this decision is regulated at several levels. In this work, we describe a putative phosphorelay that promotes the motile lifestyle and inhibits biofilm formation, providing new insights into the control of adhesin production that leads to the formation of biofilms., Competing Interests: The authors declare no conflict of interest.

Published

2024

9. Microfluidic sperm trap array for single-cell flagellar analysis with unrestricted 2D flagellar movement.

Author

Wang K, Tao A, Zhang R, and Yuan J

Subjects

Male, Animals, Cattle, Microfluidic Analytical Techniques instrumentation, Sperm Tail physiology, Flagella physiology, Equipment Design, Sperm Motility, Single-Cell Analysis instrumentation, Spermatozoa cytology, Spermatozoa physiology, Lab-On-A-Chip Devices

Abstract

Sperm capture techniques that immobilize sperm to halt their motility are essential for the long-term analysis of individual sperm. These techniques are beneficial in assisted reproductive technologies such as intracytoplasmic sperm injection (ICSI) by allowing selective screening of sperm. However, there is a notable lack of high-throughput and non-destructive sperm capture methods that allow the flagellum to beat freely, which is crucial for accurately reflecting the behavior of unfettered, freely swimming sperm. To bridge this gap, we introduce a novel microfluidic device specifically engineered to capture sperm without restricting flagellar motion. The design utilizes sperm's innate boundary-following behavior in both 3D and 2D environments to direct them into a capture zone. Once captured, the sperm head is restrained while the flagellum remains free to exhibit natural beating patterns. Utilizing this device, we explore the effects of hyperactivating agents, temperature, and their combined influence on the dynamics of bovine sperm flagella. The unrestricted flagellar motion offered by our device yields two prominent advantages: it mirrors the flagellar behavior of free-swimming sperm, ensuring research findings are consistent with natural sperm activity, and it prevents imaging overlap between the flagellum and the capture structures, simplifying the automation of flagellar tracking and analysis. This technological advancement facilitates the collection of waveform parameters along the entire flagellum, addressing inconsistencies that have arisen in previous research due to differing measurement sites, and enabling precise extraction of sperm behavioral properties.

Published

2024

10. Flagellar motility is mutagenic.

Author

Bhattacharyya S, Lopez S, Singh A, and Harshey RM

Subjects

Mutation, Mutation Rate, Movement, Escherichia coli Proteins metabolism, Escherichia coli Proteins genetics, Biological Evolution, Flagella metabolism, Flagella physiology, Flagella genetics, Escherichia coli genetics, Escherichia coli metabolism

Abstract

Flagella are highly complex rotary molecular machines that enable bacteria to not only migrate to optimal environments but also to promote range expansion, competitiveness, virulence, and antibiotic survival. Flagellar motility is an energy-demanding process, where the sum of its production (biosynthesis) and operation (rotation) costs has been estimated to total ~10% of the entire energy budget of an Escherichia coli cell. The acquisition of such a costly adaptation process is expected to secure short-term benefits by increasing competitiveness and survival, as well as long-term evolutionary fitness gains. While the role of flagellar motility in bacterial survival has been widely reported, its direct influence on the rate of evolution remains unclear. We show here that both production and operation costs contribute to elevated mutation rates. Our findings suggest that flagellar movement may be an important player in tuning the rate of bacterial evolution., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published

2024

11. Evolutionarily diverse fungal zoospores show contrasting swimming patterns specific to ultrastructure.

Author

Galindo LJ, Richards TA, and Nirody JA

Subjects

Cytoskeleton physiology, Blastocladiomycota physiology, Tubulin metabolism, Flagella physiology, Flagella ultrastructure, Spores, Fungal physiology, Spores, Fungal ultrastructure, Biological Evolution

Abstract

Zoosporic fungi, also called chytrids, produce single-celled motile spores with flagellar swimming tails (zoospores). 1 , 2 These fungi are key components of aquatic food webs, acting as pathogens, saprotrophs, and prey. 3 , 4 , 5 , 6 , 7 , 8 Little is known about the swimming behavior of fungal zoospores, a crucial factor governing dispersal, biogeographical range, ecological function, and infection dynamics. 6 , 9 Here, we track the swimming patterns of zoospores from 12 evolutionarily divergent species of zoosporic fungi from across seven orders of the Chytridiomycota and the Blastocladiomycota. We report two major swimming patterns that correlate with the cytoskeletal ultrastructure of these zoospores. Specifically, we show that species without major cytoplasmic tubulin components swim in a circular fashion, while species with prominent cytoplasmic tubulin structures swim in a pattern akin to a random walk (move-stop-redirect-move). We confirm cytoskeletal architecture by performing fluorescence confocal microscopy across all 12 species. We then treat representative species with variant swimming behaviors and cytoplasmic-cytoskeletal arrangements with tubulin-stabilizing (Taxol) and depolymerizing (nocodazole) pharmacological compounds. We observed that when treating the "random walk" species with nocodazole, their swimming behavior changed to a circular-swimming pattern. Confocal imaging of the nocodazole-treated zoospores demonstrates that these cells maintain flagellum tubulin structures but lack their characteristic cytoplasmic tubulin structures. Our data demonstrate that the capability of zoospores to perform "complex" random-walk movement is linked to the presence of prominent cytoplasmic tubulin structures and suggest a link between cytology, sensory systems, and swimming behavior in a diversity of zoosporic fungi., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2024 Elsevier Inc. All rights reserved.)

Published

2024

12. CCDC181 is required for sperm flagellum biogenesis and male fertility in mice.

Author

Zhang XJ, Hou XN, Zhou JT, Shi BL, Ye JW, Yang ML, Jiang XH, Xu B, Wu LM, and Shi QH

Subjects

Animals, Male, Mice, Fertility physiology, Flagella metabolism, Flagella physiology, Sperm Motility, Spermatozoa physiology, Mice, Knockout, Sperm Tail metabolism, Sperm Tail physiology, Microtubule Proteins genetics, Microtubule Proteins metabolism

Abstract

The structural integrity of the sperm flagellum is essential for proper sperm function. Flagellar defects can result in male infertility, yet the precise mechanisms underlying this relationship are not fully understood. CCDC181, a coiled-coil domain-containing protein, is known to localize on sperm flagella and at the basal regions of motile cilia. Despite this knowledge, the specific functions of CCDC181 in flagellum biogenesis remain unclear. In this study, Ccdc181 knockout mice were generated. The absence of CCDC181 led to defective sperm head shaping and flagellum formation. Furthermore, the Ccdc181 knockout mice exhibited extremely low sperm counts, grossly aberrant sperm morphologies, markedly diminished sperm motility, and typical multiple morphological abnormalities of the flagella (MMAF). Additionally, an interaction between CCDC181 and the MMAF-related protein LRRC46 was identified, with CCDC181 regulating the localization of LRRC46 within sperm flagella. These findings suggest that CCDC181 plays a crucial role in both manchette formation and sperm flagellum biogenesis.

Published

2024

13. Surface conversion of the dynamics of bacteria escaping chemorepellents.

Author

Braham A, Lemelle L, Ducasse R, Toukabri H, Mottin E, Fabrèges B, Calvez V, and Place C

Subjects

Surface Properties, Flagella physiology, Flagella metabolism, Movement, Nickel chemistry, Nitrates metabolism, Nitrates chemistry, Escherichia coli physiology, Hydrodynamics

Abstract

Flagellar swimming hydrodynamics confers a recognized advantage for attachment on solid surfaces. Whether this motility further enables the following environmental cues was experimentally explored. Motile E. coli (OD ~ 0.1) in a 100 µm-thick channel were exposed to off-equilibrium gradients set by a chemorepellent Ni(NO 3 ) 2 -source (250 mM). Single bacterial dynamics at the solid surface was analyzed by dark-field videomicroscopy at a fixed position. The number of bacteria indicated their congregation into a wave escaping from the repellent source. Besides the high velocity drift in the propagation direction within the wave, an unexpectedly high perpendicular component drift was also observed. Swimming hydrodynamics CW-bends the bacteria trajectories during their primo approach to the surface (< 2 µm), and a high enough tumbling frequency likely preserves a notable lateral drift. This comprehension substantiates a survival strategy tailored to toxic environments, which involves drifting along surfaces, promoting the inception of colonization at the most advantageous sites., (© 2024. The Author(s).)

Published

2024

14. Statistical Mobility of Multicellular Colonies of Flagellated Swimming Cells.

Author

Ashenafi Y and Kramer PR

Subjects

Hydrodynamics, Models, Biological, Mathematical Concepts, Stochastic Processes, Flagella physiology, Choanoflagellata physiology, Choanoflagellata cytology, Cell Movement physiology

Abstract

We study the stochastic hydrodynamics of colonies of flagellated swimming cells, typified by multicellular choanoflagellates, which can form both rosette and chainlike shapes. The objective is to link cell-scale dynamics to colony-scale dynamics for various colonial morphologies. Via autoregressive stochastic models for the cycle-averaged flagellar force dynamics and statistical models for demographic cell-to-cell variability in flagellar properties and placement, we derive effective transport properties of the colonies, including cell-to-cell variability. We provide the most quantitative detail on disclike geometries to model rosettes, but also present formulas for the dynamics of general planar colony morphologies, which includes planar chain-like configurations., (© 2024. The Author(s), under exclusive licence to the Society for Mathematical Biology.)

Published

2024

15. Flagellar stator genes control a trophic shift from obligate to facultative predation and biofilm formation in a bacterial predator.

Author

Mookherjee A, Mitra M, Sason G, Jose PA, Martinenko M, Pietrokovski S, and Jurkevitch E

Subjects

Mutation, Gene Expression Regulation, Bacterial, Cyclic GMP analogs & derivatives, Cyclic GMP metabolism, Biofilms growth & development, Flagella genetics, Flagella physiology, Bacterial Proteins genetics, Bacterial Proteins metabolism, Bdellovibrio bacteriovorus genetics, Bdellovibrio bacteriovorus physiology

Abstract

The bacterial predator Bdellovibrio bacteriovorus is considered to be obligatorily prey (host)-dependent (H-D), and thus unable to form biofilms. However, spontaneous host-independent (H-I) variants grow axenically and can form robust biofilms. A screen of 350 H-I mutants revealed that single mutations in stator genes fliL or motA were sufficient to generate flagellar motility-defective H-I strains able to adhere to surfaces but unable to develop biofilms. The variants showed large transcriptional shifts in genes related to flagella, prey-invasion, and cyclic-di-GMP (CdG), as well as large changes in CdG cellular concentration relative to the H-D parent. The introduction of the parental fliL allele resulted in a full reversion to the H-D phenotype, but we propose that specific interactions between stator proteins prevented functional complementation by fliL paralogs. In contrast, specific mutations in a pilus-associated protein (Bd0108) mutant background were necessary for biofilm formation, including secretion of extracellular DNA (eDNA), proteins, and polysaccharides matrix components. Remarkably, fliL disruption strongly reduced biofilm development. All H-I variants grew similarly without prey, showed a strain-specific reduction in predatory ability in prey suspensions, but maintained similar high efficiency in prey biofilms. Population-wide allele sequencing suggested additional routes to host independence. Thus, stator and invasion pole-dependent signaling control the H-D and the H-I biofilm-forming phenotypes, with single mutations overriding prey requirements, and enabling shifts from obligate to facultative predation, with potential consequences on community dynamics. Our findings on the facility and variety of changes leading to facultative predation also challenge the concept of Bdellovibrio and like organisms being obligate predators., Importance: The ability of bacteria to form biofilms is a central research theme in biology, medicine, and the environment. We show that cultures of the obligate (host-dependent) "solitary" predatory bacterium Bdellovibrio bacteriovorus , which cannot replicate without prey, can use various genetic routes to spontaneously yield host-independent (H-I) variants that grow axenically (as a single species, in the absence of prey) and exhibit various surface attachment phenotypes, including biofilm formation. These routes include single mutations in flagellar stator genes that affect biofilm formation, provoke motor instability and large motility defects, and disrupt cyclic-di-GMP intracellular signaling. H-I strains also exhibit reduced predatory efficiency in suspension but high efficiency in prey biofilms. These changes override the requirements for prey, enabling a shift from obligate to facultative predation, with potential consequences on community dynamics., Competing Interests: The authors declare no conflict of interest.

Published

2024

16. The Ugd, a capsular polysaccharide synthesis protein, regulates the bacterial motility in Vibrio alginolyticus.

Author

Li X, Fei X, Chen Q, Gao Z, Yin H, Zhang C, Li S, and Zhao Z

Subjects

Polysaccharides, Bacterial biosynthesis, Polysaccharides, Bacterial metabolism, Polysaccharides, Bacterial genetics, Virulence, Animals, Gene Expression Profiling, Gene Deletion, Humans, Vibrio Infections microbiology, Vibrio alginolyticus genetics, Vibrio alginolyticus physiology, Vibrio alginolyticus metabolism, Gene Expression Regulation, Bacterial, Biofilms growth & development, Bacterial Proteins genetics, Bacterial Proteins metabolism, Flagella genetics, Flagella metabolism, Flagella physiology, Bacterial Capsules metabolism, Bacterial Capsules genetics

Abstract

Vibrio alginolyticus is one of the most common opportunistic pathogens in marine animals and humans. In this study, A transposon mutation library of the V. alginolyticus E110 was used to identify motility-related genes, and we found three flagellar and one capsular polysaccharide (CPS) synthesis-related genes were linked to swarming motility. Then, gene deletion and complementation further confirmed that CPS synthesis-related gene ugd is involved in the swarming motility of V. alginolyticus. Phenotype assays showed that the Δugd mutant reduced CPS production, decreased biofilm formation, impaired swimming ability, and increased cytotoxicity compared to the wild-type strain. Transcriptome analysis showed that 655 genes (15%) were upregulated and 914 genes (21%) were downregulated in the Δugd strain. KEGG pathway and heatmap analysis revealed that genes involved in two-component systems (TCSs), chemotaxis, and flagella assembly pathways were downregulated in the Δugd mutant. On the other hand, genes involved in pathways of human diseases, biosynthesis ABC transporters, and metabolism were upregulated in the Δugd mutant. The RT-qPCR further validated that ugd-regulated genes are associated with motility, biofilm formation, virulence, and TCSs. These findings imply that ugd may be an important player in the control of some physiological processes in V. alginolyticus, highlighting its potential as a target for future research and potential therapeutic interventions., Competing Interests: Declaration of Competing Interest The authors declare no competing interests., (Copyright © 2024 Elsevier GmbH. All rights reserved.)

Published

2024

17. Quantitative assessment of the nanoanatomy of the contractile vacuole complex in Trypanosoma cruzi .

Author

Augusto I, Girard-Dias W, Schoijet A, Alonso GD, Portugal RV, de Souza W, Jimenez V, and Miranda K

Subjects

Protozoan Proteins metabolism, Protozoan Proteins genetics, Osmoregulation, Flagella metabolism, Flagella physiology, Chagas Disease metabolism, Mutation, Trypanosoma cruzi physiology, Vacuoles metabolism, Osmotic Pressure

Abstract

Trypanosoma cruzi uses various mechanisms to cope with osmotic fluctuations during infection, including the remodeling of organelles such as the contractile vacuole complex (CVC). Little is known about the morphological changes of the CVC during pulsation cycles occurring upon osmotic stress. Here, we investigated the structure-function relationship between the CVC and the flagellar pocket domain where fluid discharge takes place-the adhesion plaque-during the CVC pulsation cycle. Using TcrPDEC2 and TcVps34 overexpressing mutants, known to have low and high efficiency for osmotic responses, we described a structural phenotype for the CVC that matches their corresponding physiological responses. Quantitative tomography provided data on the volume of the CVC and spongiome connections. Changes in the adhesion plaque during the pulsation cycle were also quantified and a dense filamentous network was observed. Together, the results suggest that the adhesion plaque mediates fluid discharge from the central vacuole, revealing new aspects of the osmoregulatory system in T. cruzi ., (© 2024 Augusto et al.)

Published

2024

18. Swimming ability and flagellar motility of sperm packets of the volvocine green alga Pleodorina starrii.

Author

Kage A, Takahashi K, Nozaki H, Higashiyama T, Baba SA, and Nishizaka T

Subjects

Sperm Motility physiology, Spermatozoa physiology, Chlorophyta physiology, Flagella physiology

Abstract

Eukaryotic flagella collectively form metachronal waves that facilitate the ability to cause flow or swim. Among such flagellated and planktonic swimmers, large volvocine genera such as Eudorina, Pleodorina and Volvox form bundles of small male gametes (sperm) called "sperm packets" for sexual reproduction. Although these sperm packets reportedly have flagella and the ability to swim, previous studies on volvocine motility have focused on asexual forms and the swimming characteristics of sperm packets remain unknown. However, it is important to quantify the motility of sperm packets and sperm in order to gain insights into the significance of motility in the sexual reproduction of planktonic algae. In this study, we quantitatively described the behavior of three flagellated forms of a male strain of Pleodorina starrii-asexual colonies, sperm packets, and single dissociated sperm-with emphasis on comparison of the two multicellular forms. Despite being smaller, sperm packets swam approximately 1.4 times faster than the asexual colonies of the same male strain. Body length was approximately 0.5 times smaller in the sperm packets than in asexual colonies. The flagella from sperm packets and asexual colonies showed asymmetric waveforms, whereas those from dissociated single sperm showed symmetric waveforms, suggesting the presence of a switching mechanism between sperm packets and dissociated sperm. Flagella from sperm packets were approximately 0.5 times shorter and had a beat period approximately twice as long as those from asexual colonies. The flagella of sperm packets were densely distributed over the anterior part of the body, whereas the flagella of asexual colonies were sparse and evenly distributed. The distribution of flagella, but not the number of flagella, appear to illustrate a significant difference in the speeds of sperm packets and asexual colonies. Our findings reveal novel aspects of the regulation of eukaryotic flagella and shed light on the role of flagellar motility in sexual reproduction of planktonic algae., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2024 Kage et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2024

19. Development of functional spermatozoa in mammalian spermiogenesis.

Author

Miyata H, Shimada K, Kaneda Y, and Ikawa M

Subjects

Animals, Male, Humans, Mammals physiology, Mice, Axoneme metabolism, Flagella physiology, Flagella metabolism, Spermatogenesis physiology, Spermatozoa physiology, Spermatozoa metabolism, Acrosome metabolism, Acrosome physiology

Abstract

Infertility is a global health problem affecting one in six couples, with 50% of cases attributed to male infertility. Spermatozoa are male gametes, specialized cells that can be divided into two parts: the head and the flagellum. The head contains a vesicle called the acrosome that undergoes exocytosis and the flagellum is a motility apparatus that propels the spermatozoa forward and can be divided into two components, axonemes and accessory structures. For spermatozoa to fertilize oocytes, the acrosome and flagellum must be formed correctly. In this Review, we describe comprehensively how functional spermatozoa develop in mammals during spermiogenesis, including the formation of acrosomes, axonemes and accessory structures by focusing on analyses of mouse models., Competing Interests: Competing interests The authors declare no competing or financial interests., (© 2024. Published by The Company of Biologists Ltd.)

Published

2024

20. Influence of bacterial swimming and hydrodynamics on attachment of phages.

Author

Lohrmann C, Holm C, and Datta SS

Subjects

Flagella physiology, Bacteria virology, Molecular Dynamics Simulation, Virus Attachment, Movement, Hydrodynamics, Bacteriophages physiology

Abstract

Bacteriophages ("phages") are viruses that infect bacteria. Since they do not actively self-propel, phages rely on thermal diffusion to find target cells-but can also be advected by fluid flows, such as those generated by motile bacteria themselves in bulk fluids. How does the flow field generated by a swimming bacterium influence how it encounters phages? Here, we address this question using coupled molecular dynamics and lattice Boltzmann simulations of flagellated bacteria swimming through a bulk fluid containing uniformly-dispersed phages. We find that while swimming increases the rate at which phages attach to both the cell body and flagellar propeller, hydrodynamic interactions strongly suppress this increase at the cell body, but conversely enhance this increase at the flagellar bundle. Our results highlight the pivotal influence of hydrodynamics on the interactions between bacteria and phages, as well as other diffusible species, in microbial environments.

Published

2024

21. Calaxin is a key factor for calcium-dependent waveform control in zebrafish sperm.

Author

Morikawa M, Yamaguchi H, and Kikkawa M

Subjects

Animals, Male, Animals, Genetically Modified, Calcium metabolism, Cilia metabolism, Dyneins metabolism, Dyneins genetics, Flagella metabolism, Flagella physiology, Sperm Motility genetics, Sperm Motility physiology, Cytoskeletal Proteins metabolism, Calcium-Binding Proteins metabolism, Calcium-Binding Proteins genetics, Spermatozoa metabolism, Spermatozoa physiology, Zebrafish, Zebrafish Proteins metabolism, Zebrafish Proteins genetics

Abstract

Calcium is critical for regulating the waveform of motile cilia and flagella. Calaxin is currently the only known molecule involved in the calcium-dependent regulation in ascidians. We have recently shown that Calaxin stabilizes outer arm dynein (OAD), and the knockout of Calaxin results in primary ciliary dyskinesia phenotypes in vertebrates. However, from the knockout experiments, it was not clear which functions depend on calcium and how Calaxin regulates the waveform. To address this question, here, we generated transgenic zebrafish expressing a mutant E130A-Calaxin deficient in calcium binding. E130A-Calaxin restored the OAD reduction of calaxin -/- sperm and the abnormal movement of calaxin -/- left-right organizer cilia, showing that Calaxin's stabilization of OADs is calcium-independent. In contrast, our quantitative analysis of E130A-Calaxin sperms showed that the calcium-induced asymmetric beating was not restored, linking Calaxin's calcium-binding ability with an asymmetric flagellar beating for the first time. Our data show that Calaxin is a calcium-dependent regulator of the ciliary beating and a calcium-independent OAD stabilizer., (© 2024 Morikawa et al.)

Published

2024

22. Counterclockwise rotation of the flagellum promotes biofilm initiation in Helicobacter pylori .

Author

Liu X, Lertsethtakarn P, Mariscal VT, Yildiz F, and Ottemann KM

Subjects

Signal Transduction, Mutation, Rotation, Biofilms growth & development, Helicobacter pylori physiology, Helicobacter pylori genetics, Chemotaxis, Flagella physiology, Flagella genetics, Bacterial Proteins genetics, Bacterial Proteins metabolism

Abstract

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., Competing Interests: The authors declare no conflict of interest.

Published

2024

23. Foraging mechanisms in excavate flagellates shed light on the functional ecology of early eukaryotes.

Author

Suzuki-Tellier S, Miano F, Asadzadeh SS, Simpson AGB, and Kiørboe T

Subjects

Animals, Eukaryota physiology, Models, Biological, Biological Evolution, Hydrodynamics, Flagella physiology

Abstract

The phagotrophic flagellates described as "typical excavates" have been hypothesized to be morphologically similar to the Last Eukaryotic Common Ancestor and understanding the functional ecology of excavates may therefore help shed light on the ecology of these early eukaryotes. Typical excavates are characterized by a posterior flagellum equipped with a vane that beats in a ventral groove. Here, we combined flow visualization and observations of prey capture in representatives of the three clades of excavates with computational fluid dynamic modeling, to understand the functional significance of this cell architecture. We record substantial differences amongst species in the orientation of the vane and the beat plane of the posterior flagellum. Clearance rate magnitudes estimated from flow visualization and modeling are both like that of other similarly sized flagellates. The interaction between a vaned flagellum beating in a confinement is modeled to produce a very efficient feeding current at low energy costs, irrespective of the beat plane and vane orientation and of all other morphological variations. Given this predicted uniformity of function, we suggest that the foraging systems of typical excavates studied here may be good proxies to understand those potentially used by our distant ancestors more than 1 billion years ago., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published

2024

24. Spatiotemporal dynamics of the proton motive force on single bacterial cells.

Author

Biquet-Bisquert A, Carrio B, Meyer N, Fernandes TFD, Abkarian M, Seduk F, Magalon A, Nord AL, and Pedaci F

Subjects

Flagella metabolism, Flagella physiology, Single-Cell Analysis methods, Bacteria metabolism, Adenosine Triphosphate metabolism, Spatio-Temporal Analysis, Protons, Proton-Motive Force

Abstract

Electrochemical gradients across biological membranes are vital for cellular bioenergetics. In bacteria, the proton motive force (PMF) drives essential processes like adenosine triphosphate production and motility. Traditionally viewed as temporally and spatially stable, recent research reveals a dynamic PMF behavior at both single-cell and community levels. Moreover, the observed lateral segregation of respiratory complexes could suggest a spatial heterogeneity of the PMF. Using a light-activated proton pump and detecting the activity of the bacterial flagellar motor, we perturb and probe the PMF of single cells. Spatially homogeneous PMF perturbations reveal millisecond-scale temporal dynamics and an asymmetrical capacitive response. Localized perturbations show a rapid lateral PMF homogenization, faster than proton diffusion, akin to the electrotonic potential spread observed in passive neurons, explained by cable theory. These observations imply a global coupling between PMF sources and consumers along the membrane, precluding sustained PMF spatial heterogeneity but allowing for rapid temporal changes.

Published

2024

25. Multiflagellate Swimming Controlled by Hydrodynamic Interactions.

Author

Hu S and Meng F

Subjects

Microalgae physiology, Hydrodynamics, Flagella physiology, Models, Biological, Swimming physiology

Abstract

Many eukaryotic microorganisms propelled by multiple flagella can swim very rapidly with distinct gaits. Here, we model a three-dimensional mutiflagellate swimmer, resembling the microalgae. When the flagella are actuated synchronously, the swimming efficiency can be enhanced or reduced by interflagella hydrodynamic interactions (HIs), determined by the intrinsic tilting angle of the flagella. The asynchronous gait with a phase difference between neighboring flagella can reduce oscillatory motion via the basal mechanical coupling. In the presence of a spherical body, simulations taking into account the flagella-body interactions reveal the advantage of anterior configuration compared with posterior configuration, where in the latter case an optimal flagella number arises. Apart from understanding the role of HIs in the multiflagellate microorganisms, this work could also guide laboratory fabrications of novel microswimmers.

Published

2024

26. The younger flagellum sets the beat for Chlamydomonas reinhardtii .

Author

Wei D, Quaranta G, Aubin-Tam ME, and Tam DSW

Subjects

Chlamydomonas reinhardtii physiology, Flagella physiology

Abstract

Eukaryotes swim with coordinated flagellar (ciliary) beating and steer by fine-tuning the coordination. The model organism for studying flagellate motility, Chlamydomonas reinhardtii , employs synchronous, breaststroke-like flagellar beating to swim, and it modulates the beating amplitudes differentially to steer. This strategy hinges on both inherent flagellar asymmetries (e.g. different response to chemical messengers) and such asymmetries being effectively coordinated in the synchronous beating. In C. reinhardtii , the synchrony of beating is known to be supported by a mechanical connection between flagella; however, how flagellar asymmetries persist in the synchrony remains elusive. For example, it has been speculated for decades that one flagellum leads the beating, as its dynamic properties (i.e. frequency, waveform, etc.) appear to be copied by the other one. In this study, we combine experiments, computations, and modeling efforts to elucidate the roles played by each flagellum in synchronous beating. With a non-invasive technique to selectively load each flagellum, we show that the coordinated beating essentially only responds to load exerted on the cis flagellum; and that such asymmetry in response derives from a unilateral coupling between the two flagella. Our results highlight a distinct role for each flagellum in coordination and have implication for biflagellates' tactic behaviors., Competing Interests: DW, GQ, MA, DT No competing interests declared, (© 2024, Wei et al.)

Published

2024

27. Effect of fluid elasticity on the emergence of oscillations in an active elastic filament.

Author

Link KG, Guy RD, Thomases B, and Arratia PE

Subjects

Viscosity, Flagella physiology, Rheology, Elasticity, Models, Biological, Chlamydomonas reinhardtii physiology

Abstract

Many microorganisms propel themselves through complex media by deforming their flagella. The beat is thought to emerge from interactions between forces of the surrounding fluid, the passive elastic response from deformations of the flagellum and active forces from internal molecular motors. The beat varies in response to changes in the fluid rheology, including elasticity, but there are limited data on how systematic changes in elasticity alter the beat. This work analyses a related problem with fixed-strength driving force: the emergence of beating of an elastic planar filament driven by a follower force at the tip of a viscoelastic fluid. This analysis examines how the onset of oscillations depends on the strength of the force and viscoelastic parameters. Compared to a Newtonian fluid, it takes more force to induce the instability in viscoelastic fluids, and the frequency of the oscillation is higher. The linear analysis predicts that the frequency increases with the fluid relaxation time. Using numerical simulations, the model predictions are compared with experimental data on frequency changes in the bi-flagellated alga Chlamydomonas reinhardtii . The model shows the same trends in response to changes in both fluid viscosity and Deborah number and thus provides a possible mechanistic understanding of the experimental observations.

Published

2024

28. CryoEM structures reveal how the bacterial flagellum rotates and switches direction.

Author

Singh PK, Sharma P, Afanzar O, Goldfarb MH, Maklashina E, Eisenbach M, Cecchini G, and Iverson TM

Subjects

Rotation, Models, Molecular, Binding Sites, Torque, Protein Conformation, Membrane Proteins, Flagella ultrastructure, Flagella physiology, Flagella metabolism, Cryoelectron Microscopy, Salmonella typhimurium ultrastructure, Salmonella typhimurium physiology, Salmonella typhimurium metabolism, Salmonella typhimurium chemistry, Bacterial Proteins metabolism, Bacterial Proteins chemistry, Bacterial Proteins genetics, Chemotaxis

Abstract

Bacterial chemotaxis requires bidirectional flagellar rotation at different rates. Rotation is driven by a flagellar motor, which is a supercomplex containing multiple rings. Architectural uncertainty regarding the cytoplasmic C-ring, or 'switch', limits our understanding of how the motor transmits torque and direction to the flagellar rod. Here we report cryogenic electron microscopy structures for Salmonella enterica serovar typhimurium inner membrane MS-ring and C-ring in a counterclockwise pose (4.0 Å) and isolated C-ring in a clockwise pose alone (4.6 Å) and bound to a regulator (5.9 Å). Conformational differences between rotational poses include a 180° shift in FliF/FliG domains that rotates the outward-facing MotA/B binding site to inward facing. The regulator has specificity for the clockwise pose by bridging elements unique to this conformation. We used these structures to propose how the switch reverses rotation and transmits torque to the flagellum, which advances the understanding of bacterial chemotaxis and bidirectional motor rotation., (© 2024. The Author(s).)

Published

2024

29. It's not all about flagella - sticky invasion by pathogenic spirochetes.

Author

Strnad M, Koizumi N, Nakamura S, Vancová M, and Rego ROM

Subjects

Humans, Animals, Spirochaetales Infections microbiology, Host-Pathogen Interactions, Flagella physiology, Spirochaetales physiology, Spirochaetales pathogenicity

Abstract

Pathogenic spirochetes cause a range of serious human diseases such as Lyme disease (LD), syphilis, leptospirosis, relapsing fever (RF), and periodontal disease. Motility is a critical virulence factor for spirochetes. From the mechanical perspective of the infection, it has been widely believed that flagella are the sole key players governing the migration and dissemination of these pathogens in the host. Here, we highlight the important contribution of spirochetal surface-exposed adhesive molecules and their dynamic interactions with host molecules in the process of infection, specifically in spirochetal swimming and crawling migration. We believe that these recent findings overturn the prevailing view depicting the spirochetal body to be just an inert elastic bag, which does not affect spirochetal cell locomotion., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2024 Elsevier Ltd. All rights reserved.)

Published

2024

30. Bacterial flagella hijack type IV pili proteins to control motility.

Author

Liu X, Tachiyama S, Zhou X, Mathias RA, Bonny SQ, Khan MF, Xin Y, Roujeinikova A, Liu J, and Ottemann KM

Subjects

Bacteria, Flagella physiology, Bacterial Proteins metabolism, Fimbriae, Bacterial genetics, Fimbriae, Bacterial metabolism

Abstract

Bacterial flagella and type IV pili (TFP) are surface appendages that enable motility and mechanosensing through distinct mechanisms. These structures were previously thought to have no components in common. Here, we report that TFP and some flagella share proteins PilO, PilN, and PilM, which we identified as part of the Helicobacter pylori flagellar motor. H. pylori mutants lacking PilO or PilN migrated better than wild type in semisolid agar because they continued swimming rather than aggregated into microcolonies, mimicking the TFP-regulated surface response. Like their TFP homologs, flagellar PilO/PilN heterodimers formed a peripheral cage that encircled the flagellar motor. These results indicate that PilO and PilN act similarly in flagella and TFP by differentially regulating motility and microcolony formation when bacteria encounter surfaces., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published

2024

31. Viscosity-dependent determinants of Campylobacter jejuni impacting the velocity of flagellar motility.

Author

Ribardo DA, Johnson JJ, and Hendrixson DR

Subjects

Viscosity, Flagella physiology, Bacterial Proteins genetics, Bacterial Proteins metabolism, Campylobacter jejuni physiology

Abstract

Importance: Bacteria can adapt flagellar motor output in response to the load that the extracellular milieu imparts on the flagellar filament to enable propulsion. Bacteria can adapt flagellar motor output in response to the load that the extracellular milieu imparts on the flagellar filament to enable propulsion through diverse environments. These changes may involve increasing power and torque in high-viscosity environments or reducing power and flagellar rotation upon contact with a surface. C. jejuni swimming velocity in low-viscosity environments is comparable to other bacterial flagellates and increases significantly as external viscosity increases. In this work, we provide evidence that the mechanics of the C. jejuni flagellar motor has evolved to naturally promote high swimming velocity in high-viscosity environments. We found that C. jejuni produces VidA and VidB as auxiliary proteins to specifically affect flagellar motor activity in low viscosity to reduce swimming velocity. Our findings provide some of the first insights into different mechanisms that exist in bacteria to alter the mechanics of a flagellar motor, depending on the viscosity of extracellular environments., Competing Interests: The authors declare no conflict of interest.

Published

2024

32. Molecular mechanisms and environmental adaptations of flagellar loss and biofilm growth of Rhodanobacter under environmental stress.

Author

Chen M, Trotter VV, Walian PJ, Chen Y, Lopez R, Lui LM, Nielsen TN, Malana RG, Thorgersen MP, Hendrickson AJ, Carion H, Deutschbauer AM, Petzold CJ, Smith HJ, Arkin AP, Adams MWW, Fields MW, and Chakraborty R

Subjects

Hydrogen-Ion Concentration, Nitrates metabolism, Groundwater microbiology, Bacterial Proteins genetics, Bacterial Proteins metabolism, Biofilms growth & development, Flagella genetics, Flagella physiology, Stress, Physiological, Aluminum toxicity, Adaptation, Physiological

Abstract

Biofilms aid bacterial adhesion to surfaces via direct and indirect mechanisms, and formation of biofilms is considered as an important strategy for adaptation and survival in suboptimal environmental conditions. However, the molecular underpinnings of biofilm formation in subsurface sediment/groundwater ecosystems where microorganisms often experience fluctuations in nutrient input, pH, and nitrate or metal concentrations are underexplored. We examined biofilm formation under different nutrient, pH, metal, and nitrate regimens of 16 Rhodanobacter strains isolated from subsurface groundwater wells spanning diverse levels of pH (3.5 to 5) and nitrates (13.7 to 146 mM). Eight Rhodanobacter strains demonstrated significant biofilm growth under low pH, suggesting adaptations for survival and growth at low pH. Biofilms were intensified under aluminum stress, particularly in strains possessing fewer genetic traits associated with biofilm formation, findings warranting further investigation. Through random barcode transposon-site sequencing (RB-TnSeq), proteomics, use of specific mutants, and transmission electron microscopy analysis, we discovered flagellar loss under aluminum stress, indicating a potential relationship between motility, metal tolerance, and biofilm growth. Comparative genomic analyses revealed the absence of flagella and chemotaxis genes and the presence of a putative type VI secretion system in the highly biofilm-forming strain FW021-MT20. In this study we identified genetic determinants associated with biofilm growth under metal stress in a predominant environmental genus, Rhodanobacter, and identified traits aiding survival and adaptation to contaminated subsurface environments., (Published by Oxford University Press on behalf of the International Society for Microbial Ecology 2024.)

Published

2024

33. Ecological relevance of flagellar motility in soil bacterial communities.

Author

Ramoneda J, Fan K, Lucas JM, Chu H, Bissett A, Strickland MS, and Fierer N

Subjects

Metagenomics, Bacterial Physiological Phenomena, Carbon metabolism, Soil chemistry, Metagenome, Genome, Bacterial, Flagella genetics, Flagella physiology, Soil Microbiology, Bacteria genetics, Bacteria classification, Bacteria metabolism, Bacteria isolation & purification

Abstract

Flagellar motility is a key bacterial trait as it allows bacteria to navigate their immediate surroundings. Not all bacteria are capable of flagellar motility, and the distribution of this trait, its ecological associations, and the life history strategies of flagellated taxa remain poorly characterized. We developed and validated a genome-based approach to infer the potential for flagellar motility across 12 bacterial phyla (26 192 unique genomes). The capacity for flagellar motility was associated with a higher prevalence of genes for carbohydrate metabolism and higher maximum potential growth rates, suggesting that flagellar motility is more prevalent in environments with higher carbon availability. To test this hypothesis, we applied a method to infer the prevalence of flagellar motility in whole bacterial communities from metagenomic data and quantified the prevalence of flagellar motility across four independent field studies that each captured putative gradients in soil carbon availability (148 metagenomes). We observed a positive relationship between the prevalence of bacterial flagellar motility and soil carbon availability in all datasets. Since soil carbon availability is often correlated with other factors that could influence the prevalence of flagellar motility, we validated these observations using metagenomic data from a soil incubation experiment where carbon availability was directly manipulated with glucose amendments. This confirmed that the prevalence of bacterial flagellar motility is consistently associated with soil carbon availability over other potential confounding factors. This work highlights the value of combining predictive genomic and metagenomic approaches to expand our understanding of microbial phenotypic traits and reveal their general environmental associations., (© The Author(s) 2024. Published by Oxford University Press on behalf of the International Society for Microbial Ecology.)

Published

2024

34. Flagellar dynamics reveal fluctuations and kinetic limit in the Escherichia coli chemotaxis network.

Author

Bano R, Mears P, Golding I, and Chemla YR

Subjects

Chemotaxis, Bacterial Proteins metabolism, Membrane Proteins metabolism, Flagella physiology, Escherichia coli genetics, Escherichia coli Proteins genetics, Escherichia coli Proteins metabolism

Abstract

The Escherichia coli chemotaxis network, by which bacteria modulate their random run/tumble swimming pattern to navigate their environment, must cope with unavoidable number fluctuations ("noise") in its molecular constituents like other signaling networks. The probability of clockwise (CW) flagellar rotation, or CW bias, is a measure of the chemotaxis network's output, and its temporal fluctuations provide a proxy for network noise. Here we quantify fluctuations in the chemotaxis signaling network from the switching statistics of flagella, observed using time-resolved fluorescence microscopy of individual optically trapped E. coli cells. This approach allows noise to be quantified across the dynamic range of the network. Large CW bias fluctuations are revealed at steady state, which may play a critical role in driving flagellar switching and cell tumbling. When the network is stimulated chemically to higher activity, fluctuations dramatically decrease. A stochastic theoretical model, inspired by work on gene expression noise, points to CheY activation occurring in bursts, driving CW bias fluctuations. This model also shows that an intrinsic kinetic ceiling on network activity places an upper limit on activated CheY and CW bias, which when encountered suppresses network fluctuations. This limit may also prevent cells from tumbling unproductively in steep gradients., (© 2023. The Author(s).)

Published

2023

35. Multiflagellarity leads to the size-independent swimming speed of peritrichous bacteria.

Author

Kamdar S, Ghosh D, Lee W, Tătulea-Codrean M, Kim Y, Ghosh S, Kim Y, Cheepuru T, Lauga E, Lim S, and Cheng X

Subjects

Flagella physiology, Rotation, Escherichia coli physiology, Swimming, Movement physiology

Abstract

To swim through a viscous fluid, a flagellated bacterium must overcome the fluid drag on its body by rotating a flagellum or a bundle of multiple flagella. Because the drag increases with the size of bacteria, it is expected theoretically that the swimming speed of a bacterium inversely correlates with its body length. Nevertheless, despite extensive research, the fundamental size-speed relation of flagellated bacteria remains unclear with different experiments reporting conflicting results. Here, by critically reviewing the existing evidence and synergizing our own experiments of large sample sizes, hydrodynamic modeling, and simulations, we demonstrate that the average swimming speed of Escherichia coli , a premier model of peritrichous bacteria, is independent of their body length. Our quantitative analysis shows that such a counterintuitive relation is the consequence of the collective flagellar dynamics dictated by the linear correlation between the body length and the number of flagella of bacteria. Notably, our study reveals how bacteria utilize the increasing number of flagella to regulate the flagellar motor load. The collective load sharing among multiple flagella results in a lower load on each flagellar motor and therefore faster flagellar rotation, which compensates for the higher fluid drag on the longer bodies of bacteria. Without this balancing mechanism, the swimming speed of monotrichous bacteria generically decreases with increasing body length, a feature limiting the size variation of the bacteria. Altogether, our study resolves a long-standing controversy over the size-speed relation of flagellated bacteria and provides insights into the functional benefit of multiflagellarity in bacteria., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published

2023

36. Regulation of major bacterial survival strategies by transcripts sequestration in a membraneless organelle.

Author

Szoke T, Goldberger O, Albocher-Kedem N, Barsheshet M, Dezorella N, Nussbaum-Shochat A, Wiener R, Schuldiner M, and Amster-Choder O

Subjects

Humans, Proteins, Flagella physiology, Escherichia coli genetics, Tyrosine, Biomolecular Condensates, Bacteria

Abstract

TmaR, the only known pole-localizer protein in Escherichia coli, was shown to cluster at the cell poles and control localization and activity of the major sugar regulator in a tyrosine phosphorylation-dependent manner. Here, we show that TmaR assembles by phase separation (PS) via heterotypic interactions with RNA in vivo and in vitro. An unbiased automated mutant screen combined with directed mutagenesis and genetic manipulations uncovered the importance of a predicted nucleic-acid-binding domain, a disordered region, and charged patches, one containing the phosphorylated tyrosine, for TmaR condensation. We demonstrate that, by protecting flagella-related transcripts, TmaR controls flagella production and, thus, cell motility and biofilm formation. These results connect PS in bacteria to survival and provide an explanation for the linkage between metabolism and motility. Intriguingly, a point mutation or increase in its cellular concentration induces irreversible liquid-to-solid transition of TmaR, similar to human disease-causing proteins, which affects cell morphology and division., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2023 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2023

37. Flagellar motors of swimming bacteria contain an incomplete set of stator units to ensure robust motility.

Author

Niu Y, Zhang R, and Yuan J

Subjects

Bacteria, Escherichia coli physiology, Flagella physiology, Bacterial Proteins, Swimming, Molecular Motor Proteins

Abstract

Flagellated bacteria, like Escherichia coli , swim by rotating helical flagellar filaments powered by rotary flagellar motors at their base. Motor dynamics are sensitive to the load it drives. It was previously thought that motor load was high when driving filament rotation in free liquid environments. However, torque measurements from swimming bacteria revealed substantially lower values compared to single-motor studies. We addressed this inconsistency through motor resurrection experiments, abruptly attaching a 1-micrometer-diameter bead to the filament to ensure high load. Unexpectedly, we found that the motor works with only half the complement of stator units when driving filament rotation. This suggests that the motor is not under high load during bacterial swimming, which we confirmed by measuring the torque-speed relationship by varying media viscosity. Therefore, the motor operates in an intermediate-load region, adaptively regulating its stator number on the basis of external load conditions. This ensures the robustness of bacterial motility when swimming in diverse load conditions and varying flagella numbers.

Published

2023

38. FliL Functions in Diverse Microbes to Negatively Modulate Motor Output via Its N-Terminal Region.

Author

Liu X, Roujeinikova A, and Ottemann KM

Subjects

Flagella physiology, Periplasm metabolism, Helicobacter pylori, Bacterial Proteins metabolism, Membrane Proteins metabolism

Abstract

The flagellar motor protein FliL is conserved across many microbes, but its exact role has been obscured by varying fliL mutant phenotypes. We reanalyzed results from fliL studies and found they utilized alleles that differed in the amount of N- and C-terminal regions that were retained. Alleles that retain the N-terminal cytoplasmic and transmembrane helix (TM) regions in the absence of the C-terminal periplasmic domain result in loss of motility, while alleles that completely lack the N-terminal region, independent of the periplasmic domain, retain motility. We then tested this prediction in Helicobacter pylori fliL and found support for the idea. This analysis suggests that FliL function may be more conserved across bacteria than previously thought, that it is not essential for motility, and that the N-terminal region has the negative ability to regulate motor function. IMPORTANCE FliL is a protein found in the flagellar motor of bacteria, but what it does was not clear. To study FliL function, scientists often remove it and see what happens. Loss of FliL was thought to have different effects depending on the microbe. We uncovered, however, that part of the confusion arose because scientists inadvertently removed different parts of the protein. Our analysis and data suggest that leaving the N-terminal regions blocks motility, while fully removing FliL allows normal motility. This finding will help scientists understand FliL because it clarifies what needs to be removed to fully eliminate the protein, and also that the N-terminal region can block motility.

Published

2023

39. Precise Measurement of the Stoichiometry of the Adaptive Bacterial Flagellar Switch.

Author

Tao A, Liu G, Zhang R, and Yuan J

Subjects

Cryoelectron Microscopy, Methyl-Accepting Chemotaxis Proteins metabolism, Chemotaxis, Bacterial Proteins chemistry, Flagella physiology

Abstract

The cytoplasmic ring (C-ring) of the bacterial flagellar motor controls the motor rotation direction, thereby controlling bacterial run-and-tumble behavior. The C-ring has been shown to undergo adaptive remodeling in response to changes in motor directional bias. However, the stoichiometry and arrangement of the C-ring is still unclear due to contradiction between the results from fluorescence studies and cryo-electron microscopy (cryo-EM) structural analysis. Here, by using the copy number of FliG molecules (34) in the C-ring as a reference, we precisely measured the copy numbers of FliM molecules in motors rotating exclusively counterclockwise (CCW) and clockwise (CW). We surprisingly found that there are on average 45 and 58 FliM molecules in CW and CCW rotating motors, respectively, which are much higher than previous estimates. Our results suggested a new mechanism of C-ring adaptation, that is, extra FliM molecules could be bound to the primary C-ring with probability depending on the motor rotational direction. We further confirmed that all of the FliM molecules in the C-ring function in chemotaxis signaling transduction because all of them could be bound by the chemotactic response regulator CheY-P. Our measurements provided new insights into the structure and arrangement of the flagellar switch. IMPORTANCE The bacterial flagellar switch can undergo adaptive remodeling in response to changes in motor rotation direction, thereby shifting its operating point to match the output of the chemotaxis signaling pathway. However, it remains unclear how the flagellar switch accomplishes this adaptive remodeling. Here, via precise fluorescence studies, we measured the absolute copy numbers of the critical component in the switch for motors rotating counterclockwise and clockwise, obtaining much larger numbers than previous relative estimates. Our results suggested a new mechanism of adaptive remodeling of the flagellar switch and provided new insights for updating the conformation spread model of the switch.

Published

2023

40. Absence of CEP78 causes photoreceptor and sperm flagella impairments in mice and a human individual.

Author

Zhu T, Zhang Y, Sheng X, Zhang X, Chen Y, Zhu H, Guo Y, Qi Y, Zhao Y, Zhou Q, Chen X, Guo X, and Zhao C

Subjects

Humans, Male, Animals, Mice, Sperm Tail, Proteins, Photoreceptor Cells metabolism, Flagella physiology, Cell Cycle Proteins metabolism, Semen metabolism, Infertility, Male genetics

Abstract

Cone-rod dystrophy (CRD) is a genetically inherited retinal disease that can be associated with male infertility, while the specific genetic mechanisms are not well known. Here, we report CEP78 as a causative gene of a particular syndrome including CRD and male infertility with multiple morphological abnormalities of sperm flagella (MMAF) both in human and mouse. Cep78 knockout mice exhibited impaired function and morphology of photoreceptors, typified by reduced ERG amplitudes, disrupted translocation of cone arrestin, attenuated and disorganized photoreceptor outer segments (OS) disks and widen OS bases, as well as interrupted connecting cilia elongation and abnormal structures. Cep78 deletion also caused male infertility and MMAF, with disordered '9+2' structure and triplet microtubules in sperm flagella. Intraflagellar transport (IFT) proteins IFT20 and TTC21A are identified as interacting proteins of CEP78. Furthermore, CEP78 regulated the interaction, stability, and centriolar localization of its interacting protein. Insufficiency of CEP78 or its interacting protein causes abnormal centriole elongation and cilia shortening. Absence of CEP78 protein in human caused similar phenotypes in vision and MMAF as Cep78 -/- mice. Collectively, our study supports the important roles of CEP78 defects in centriole and ciliary dysfunctions and molecular pathogenesis of such multi-system syndrome., Competing Interests: TZ, YZ, XS, XZ, YC, HZ, YG, YQ, YZ, QZ, XC, XG, CZ No competing interests declared, (© 2023, Zhu, Zhang, Sheng et al.)

Published

2023

41. Testing the ion-current model for flagellar length sensing and IFT regulation.

Author

Ishikawa H, Moore J, Diener DR, Delling M, and Marshall WF

Subjects

Biological Transport, Flagella physiology, Cilia metabolism, Chlamydomonas reinhardtii metabolism, Chlamydomonas metabolism

Abstract

Eukaryotic cilia and flagella are microtubule-based organelles whose relatively simple shape makes them ideal for investigating the fundamental question of organelle size regulation. Most of the flagellar materials are transported from the cell body via an active transport process called intraflagellar transport (IFT). The rate of IFT entry into flagella, known as IFT injection, has been shown to negatively correlate with flagellar length. However, it remains unknown how the cell measures the length of its flagella and controls IFT injection. One of the most-discussed theoretical models for length sensing to control IFT is the ion-current model, which posits that there is a uniform distribution of Ca 2+ channels along the flagellum and that the Ca 2+ current from the flagellum into the cell body increases linearly with flagellar length. In this model, the cell uses the Ca 2+ current to negatively regulate IFT injection. The recent discovery that IFT entry into flagella is regulated by the phosphorylation of kinesin through a calcium-dependent protein kinase has provided further impetus for the ion-current model. To test this model, we measured and manipulated the levels of Ca 2+ inside of Chlamydomonas flagella and quantified IFT injection. Although the concentration of Ca 2+ inside of flagella was weakly correlated with the length of flagella, we found that IFT injection was reduced in calcium-deficient flagella, rather than increased as the model predicted, and that variation in IFT injection was uncorrelated with the occurrence of flagellar Ca 2+ spikes. Thus, Ca 2+ does not appear to function as a negative regulator of IFT injection, hence it cannot form the basis of a stable length control system., Competing Interests: HI, JM, DD, MD, WM No competing interests declared, (© 2023, Ishikawa et al.)

Published

2023

42. Swarming Motility Assays in Salmonella.

Author

Partridge JD and Harshey RM

Subjects

Humans, Cell Movement, Flagella physiology, Bacterial Proteins, Movement, Salmonella enterica

Abstract

Salmonella enterica has six subspecies, of which the subspecies enterica is the most important for human health. The dispersal and infectivity of this species are dependent upon flagella-driven motility. Two kinds of flagella-mediated movements have been described-swimming individually in bulk liquid and swarming collectively over a surface substrate. During swarming, the bacteria acquire a distinct physiology, the most significant consequence of which is acquisition of adaptive resistance to antibiotics. Described here are protocols to cultivate, verify, and study swimming and swarming motility in S. enterica, and an additional "border-crossing" assay, where cells "primed" to swarm are presented with an environmental challenge such as antibiotics to assess their propensity to handle the challenge., (© 2023. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2023

43. Conversion of anterograde into retrograde trains is an intrinsic property of intraflagellar transport.

Author

Nievergelt AP, Zykov I, Diener D, Chhatre A, Buchholz TO, Delling M, Diez S, Jug F, Štěpánek L, and Pigino G

Subjects

Biological Transport, Calcium metabolism, Cilia metabolism, Cytoplasmic Dyneins metabolism, Flagella physiology, Dyneins metabolism, Kinesins

Abstract

Cilia or eukaryotic flagella are microtubule-based organelles found across the eukaryotic tree of life. Their very high aspect ratio and crowded interior are unfavorable to diffusive transport of most components required for their assembly and maintenance. Instead, a system of intraflagellar transport (IFT) trains moves cargo rapidly up and down the cilium (Figure 1A). 1-3 Anterograde IFT, from the cell body to the ciliary tip, is driven by kinesin-II motors, whereas retrograde IFT is powered by cytoplasmic dynein-1b motors. 4 Both motors are associated with long chains of IFT protein complexes, known as IFT trains, and their cargoes. 5-8 The conversion from anterograde to retrograde motility at the ciliary tip involves (1) the dissociation of kinesin motors from trains, 9 (2) a fundamental restructuring of the train from the anterograde to the retrograde architecture, 8 , 10 , 11 (3) the unloading and reloading of cargo, 2 and (4) the activation of the dynein motors. 8 , 12 A prominent hypothesis is that there is dedicated calcium-dependent protein-based machinery at the ciliary tip to mediate these processes. 4 , 13 However, the mechanisms of IFT turnaround have remained elusive. In this study, we use mechanical and chemical methods to block IFT at intermediate positions along the cilia of the green algae Chlamydomonas reinhardtii, in normal and calcium-depleted conditions. We show that IFT turnaround, kinesin dissociation, and dynein-1b activation can consistently be induced at arbitrary distances from the ciliary tip, with no stationary tip machinery being required. Instead, we demonstrate that the anterograde-to-retrograde conversion is a calcium-independent intrinsic ability of IFT., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2022 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2022

44. Steady-state running rate sets the speed and accuracy of accumulation of swimming bacteria.

Author

Voliotis M, Rosko J, Pilizota T, and Liverpool TB

Subjects

Bacteria, Chemotactic Factors, Chemotaxis physiology, Models, Biological, Swimming, Flagella physiology, Running

Abstract

We study the chemotaxis of a population of genetically identical swimming bacteria undergoing run and tumble dynamics driven by stochastic switching between clockwise and counterclockwise rotation of the flagellar rotary system, where the steady-state rate of the switching changes in different environments. Understanding chemotaxis quantitatively requires that one links the measured steady-state switching rates of the rotary system, as well as the directional changes of individual swimming bacteria in a gradient of chemoattractant/repellant, to the efficiency of a population of bacteria in moving up/down the gradient. Here we achieve this by using a probabilistic model, parametrized with our experimental data, and show that the response of a population to the gradient is complex. We find the changes to the steady-state switching rate in the absence of gradients affect the average speed of the swimming bacterial population response as well as the width of the distribution. Both must be taken into account when optimizing the overall response of the population in complex environments., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2022 Biophysical Society. Published by Elsevier Inc. All rights reserved.)

Published

2022

45. Wrapped Up: The Motility of Polarly Flagellated Bacteria.

Author

Thormann KM, Beta C, and Kühn MJ

Subjects

Bacterial Proteins, Escherichia coli genetics, Flagellin ultrastructure, Bacterial Physiological Phenomena, Chemotaxis physiology, Flagella physiology, Flagella ultrastructure

Abstract

A huge number of bacterial species are motile by flagella, which allow them to actively move toward favorable environments and away from hazardous areas and to conquer new habitats. The general perception of flagellum-mediated movement and chemotaxis is dominated by the Escherichia coli paradigm, with its peritrichous flagellation and its famous run-and-tumble navigation pattern, which has shaped the view on how bacteria swim and navigate in chemical gradients. However, a significant amount-more likely the majority-of bacterial species exhibit a (bi)polar flagellar localization pattern instead of lateral flagella. Accordingly, these species have evolved very different mechanisms for navigation and chemotaxis. Here, we review the earlier and recent findings on the various modes of motility mediated by polar flagella.

Published

2022

46. Direct Measurement of the Stall Torque of the Flagellar Motor in Escherichia coli with Magnetic Tweezers.

Author

Wang B, Yue G, Zhang R, and Yuan J

Subjects

Bacterial Proteins, Magnetics methods, Protons, Torque, Escherichia coli chemistry, Escherichia coli metabolism, Flagella chemistry, Flagella physiology, Molecular Motor Proteins chemistry, Molecular Motor Proteins physiology

Abstract

The flagellar motor drives the rotation of flagellar filaments, propelling the swimming of flagellated bacteria. The maximum torque the motor generates, the stall torque, is a key characteristic of the motor function. Direct measurements of the stall torque carried out 3 decades ago suffered from large experimental uncertainties, and subsequently there were only indirect measurements. Here, we applied magnetic tweezers to directly measure the stall torque in E. coli. We precisely calibrated the torsional stiffness of the magnetic tweezers and performed motor resurrection experiments at stall, accomplishing a precise determination of the stall torque per torque-generating unit (stator unit). From our measurements, each stator passes 2 protons per step, indicating a tight coupling between motor rotation and proton flux. IMPORTANCE The maximum torque the bacterial flagellar motor generates, the stall torque, is a critical parameter that describes the motor energetics. As the motor operates in equilibrium near stall, from the stall torque one can determine how many protons each torque-generating unit (stator) of the motor passes per revolution and then test whether motor rotation and proton flux are tightly or loosely coupled, which has been controversial in recent years. Direct measurements performed 3 decades ago suffered from large uncertainties, and subsequently, only indirect measurements were attempted, obtaining a range of values inconsistent with the previous direct measurements. Here, we developed a method that used magnetic tweezers to perform motor resurrection experiments at stall, resulting in a direct precise measurement of the stall torque per stator. Our study resolved the previous inconsistencies and provided direct experimental support for the tight coupling mechanism between motor rotation and proton flux.

Published

2022

47. Encapsulated bacteria deform lipid vesicles into flagellated swimmers.

Author

Le Nagard L, Brown AT, Dawson A, Martinez VA, Poon WCK, and Staykova M

Subjects

Cytoplasmic Vesicles microbiology, Escherichia coli cytology, Flagella physiology, Lipids, Membranes, Artificial, Artificial Cells microbiology, Escherichia coli physiology

Abstract

We study a synthetic system of motile Escherichia coli bacteria encapsulated inside giant lipid vesicles. Forces exerted by the bacteria on the inner side of the membrane are sufficient to extrude membrane tubes filled with one or several bacteria. We show that a physical coupling between the membrane tube and the flagella of the enclosed cells transforms the tube into an effective helical flagellum propelling the vesicle. We develop a simple theoretical model to estimate the propulsive force from the speed of the vesicles and demonstrate the good efficiency of this coupling mechanism. Together, these results point to design principles for conferring motility to synthetic cells.

Published

2022

48. Ciliogenesis requires sphingolipid-dependent membrane and axoneme interaction.

Author

Wu D, Huang J, Zhu H, Chen Z, Chai Y, Ke J, Lei K, Peng Z, Zhang R, Li X, Huang K, Li W, Zhao C, and Ou G

Subjects

Ceramides metabolism, Protein Transport, Axoneme chemistry, Axoneme metabolism, Chlamydomonas physiology, Cilia physiology, Flagella physiology, Regeneration, Sphingolipids metabolism

Abstract

Cilium formation and regeneration requires new protein synthesis, but the underlying cytosolic translational reprogramming remains largely unknown. Using ribosome footprinting, we performed global translatome profiling during cilia regeneration in Chlamydomonas and uncovered that flagellar genes undergo an early transcriptional activation but late translational repression. This pattern guided our identification of sphingolipid metabolism enzymes, including serine palmitoyltransferase (SPT), as essential regulators for ciliogenesis. Cryo-electron tomography showed that ceramide loss abnormally increased the membrane-axoneme distance and generated bulged cilia. We found that ceramides interact with intraflagellar transport (IFT) particle proteins that IFT motors transport along axoneme microtubules (MTs), suggesting that ceramide-IFT particle-IFT motor-MT interactions connect the ciliary membrane with the axoneme to form rod-shaped cilia. SPT-deficient vertebrate cells were defective in ciliogenesis, and SPT mutations from patients with hereditary sensory neuropathy disrupted cilia, which could be restored by sphingolipid supplementation. These results reveal a conserved role of sphingolipid in cilium formation and link compromised sphingolipid production with ciliopathies.

Published

2022

49. Structural and biochemical analyses of the flagellar expression regulator DegU from Listeria monocytogenes.

Author

Oh HB, Lee SJ, and Yoon SI

Subjects

Bacterial Proteins metabolism, DNA metabolism, Flagella physiology, Gene Expression Regulation, Bacterial, Promoter Regions, Genetic, Listeria monocytogenes metabolism

Abstract

Listeria monocytogenes is a pathogenic bacterium that produces flagella, the locomotory organelles, in a temperature-dependent manner. At 37 °C inside humans, L. monocytogenes employs MogR to repress the expression of flagellar proteins, thereby preventing the production of flagella. However, in the low-temperature environment outside of the host, the antirepressor GmaR inactivates MogR, allowing flagellar formation. Additionally, DegU is necessary for flagellar expression at low temperatures. DegU transcriptionally activates the expression of GmaR and flagellar proteins by binding the operator DNA in the fliN-gmaR promoter as a response regulator of a two-component regulatory system. To determine the DegU-mediated regulation mechanism, we performed structural and biochemical analyses on the recognition of operator DNA by DegU. The DegU-DNA interaction is primarily mediated by a C-terminal DNA-binding domain (DBD) and can be fortified by an N-terminal receiver domain (RD). The DegU DBD adopts a tetrahelical helix-turn-helix structure and assembles into a dimer. The DegU DBD dimer recognizes the operator DNA using a positive patch. Unexpectedly, unlike typical response regulators, DegU interacts with operator DNA in both unphosphorylated and phosphorylated states with similar binding affinities. Therefore, we conclude that DegU is a noncanonical response regulator that is constitutively active irrespective of phosphorylation., (© 2022. The Author(s).)

Published

2022

50. Generation of ciliary beating by steady dynein activity: the effects of inter-filament coupling in multi-filament models.

Author

Woodhams LG, Shen Y, and Bayly PV

Subjects

Axoneme metabolism, Cilia metabolism, Flagella physiology, Dyneins chemistry, Models, Biological

Abstract

The structure of the axoneme in motile cilia and flagella is emerging with increasing detail from high-resolution imaging, but the mechanism by which the axoneme creates oscillatory, propulsive motion remains mysterious. It has recently been proposed that this motion may be caused by a dynamic 'flutter' instability that can occur under steady dynein loading, and not by switching or modulation of dynein motor activity (as commonly assumed). In the current work, we have built an improved multi-filament mathematical model of the axoneme and implemented it as a system of discrete equations using the finite-element method. The eigenvalues and eigenvectors of this model predict the emergence of oscillatory, wave-like solutions in the absence of dynein regulation and specify the associated frequencies and waveforms of beating. Time-domain simulations with this model illustrate the behaviour predicted by the system's eigenvalues. This model and analysis allow us to efficiently explore the potential effects of difficult to measure biophysical parameters, such as elasticity of radial spokes and inter-doublet links, on the ciliary waveform. These results support the idea that dynamic instability without dynamic dynein regulation is a plausible and robust mechanism for generating ciliary beating.

Published

2022