Microsphere attachment induces glycoprotein redistribution and transmembrane signaling in theChlamydomonas flagellum

Summary The biflagellate green algaChlamydomonas can exhibit substrate-associated gliding motility in addition to its ability to swim through a liquid medium. The flagella are the organelles responsible for both forms of whole-cell locomotion although the mechanism in each case is very different. In this study, we demonstrate that the binding of polystyrene microspheres to the flagellar surface ofChlamydomonas initiates clustering of the major flagellar-membrane glycoprotein, which is known to be involved in motility-associated substrate adhesion. In addition, we demonstrate that microsphere binding to the flagellar surface initiates the same transmembrane signaling pathway that is initiated by antibody- or lectin-induced crosslinking of the major flagellar-membrane glycoprotein. In each case, the signaling pathway involves the activation of a calciumdependent protein phosphatase that dephosphorylates a flagellar phosphoprotein known to be associated with the major flagellar-membrane glycoprotein. Bound microspheres are translocated along the flagellar surface at approximately the same velocity as whole-cell gliding motility. Previous observations suggest that microsphere binding and translocation along the flagellar surface may be a reflection of the same force-transducing system responsible for whole-cell gliding motility. In which case, these observations suggest that the transmembrane signaling pathway initiated by crosslinking the major flagellar-membrane glycoprotein is the same one that is activated when the cell contacts a physiological substrate by its flagellar surface.     

Gliding defective mutant cell lines ofChlamydomonas moewusii exhibit alterations in a 240 kDa surface-exposed flagellar glycoprotein

Summary TheChlamydomonas flagellar surface exhibits a number of dynamic properties associated with whole cell locomotion and the mating process. In this report, we quantitate the ability of a series of gliding defective mutant cell lines (Lewin 1982) to move polystyrene microspheres along their flagellar surface and describe alterations in the flagellar surfaces of three of these cell lines (fg-2, fg-3 and fg-7). Although all three of these mutant cell strains exhibit less than 16% of the control level of microsphere movement, they differ from each other and the parental cell line (M 475) in the level of flagellar surface adhesiveness as judged by the binding of polystyrene microspheres. SDS-polyacrylamide gel analysis of purified whole flagella from the nongliding mutant cell strains and M 475 demonstrates a correlation between the amount of a surface exposed glycoprotein and the level of flagellar surface adhesiveness. This surface exposed glycoprotein binds the lectin concanavalin A and has an apparent molecular weight of 240 kDa. Strains with low levels of flagellar surface adhesiveness (fg-3 and fg-7) exhibit a low amount of this glycoprotein while the strain with a high level of adhesiveness (fg-2) has an elevated amount of this glycoprotein relative to the parental strain, suggesting that this 240 kDa glycoprotein may be responsible for the adhesive properties of the flagellar surface. Concanavalin A inhibits microsphere binding to the flagellar surface, suggesting that the carbohydrate component of the 240 kDa glycoprotein may be involved in flagellar surface adhesiveness. Biotinylation of surface-exposed flagellar proteins demonstrates differences in the surfaces of these mutant cell lines, especially in terms of the amount of surface labelling of the 240 kDa flagellar glycoprotein. A rabbit polyclonal antibody (designated P-19) that binds to the flagellar surface and recognizes the 240 kDa glycoprotein on Western blots confirms the altered level of this glycoprotein in the mutant cell lines. The results of these experiments suggest that the major flagellar glycoprotein ofC. moewusii may be involved in adhesion of polystyrene microspheres to the flagellar surface and presumably also in the adhesive interaction of the flagellar surface with a solid substrate, which is a necessary prerequisite for the expression of gliding motility.Abbreviations BSA bovine serum albumin - DAB 3,3-diaminobenzidine - HRP horseradish peroxidase - kDa kilodaltons - LBB lectin blot buffer - NHS-LC biotin sulfosuccinimidyl 6-(biotinamido) hexanoate - PBS phosphate buffered saline - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis     

Gliding movement in Peranema trichophorum is powered by flagellar surface motility

A colorless euglenoid flagellate Peranema trichophorum shows unique unidirectional gliding cell locomotion on the substratum at velocities up to 30 micro m/s by an as yet unexplained mechanism. In this study, we found that (1) treatment with NiCl(2) inhibited flagellar beating without any effect on gliding movement; (2) water currents applied to a gliding cell from opposite sides caused detachment of the cell body from the substratum. With only the anterior flagellum adhering to the substratum, gliding movement continued along the direction of the anterior flagellum; (3) gentle pipetting induced flagellar severance into various lengths. In these cells, gliding velocity was proportional to the flagellar length; and (4) Polystyrene beads were translocated along the surface of the anterior flagellum. All of these results indicate that a cell surface motility system is present on the anterior flagellum, which is responsible for cell gliding in P. trichophorum.     

Flagellar transformation in the heterokontEpipyxis pulchra (Chrysophyceae): Direct observations using image enhanced light microscopy

Summary Cells ofEpipyxis pulchra possess two heteromorphic flagella that differ markedly in function, particularly during motility and prey capture. Flagellar heterogeneity is achieved during the course of at least three cell cycles. Prior to cell division, cells produce two new long, hairy flagella while the parental long flagellum is transformed into a new short, smooth flagellum. The parental short flagellum remains a short flagellum for this and subsequent cell division cycles. Although flagellar transformation requires only two cell cycles, developmental differences exist between daughter cells and the maturation of a flagellum/basal body requires at least three cycles.     

Evidence for a functional membrane barrier in the transition zone between the flagellum and cell body of Chlamydomonas eugametos gametes

Evidence is presented which supports the concept of a functional membrane barrier in the transition zone at the base of each flagellum of Chlamydomonas eugametos gametes. This makes it unlikely that agglutination factors present on the surface of the cell body can diffuse or be transported to the flagellar membrane. The evidence is as follows: 1) The glycoprotein composition of the flagellar membrane is very different to that of the cell-body plasma membrane. 2) The flagella of gametes treated with cycloheximide, tunicamycin or , -dipyridyl become non-agglutinable but the source of agglutination factors on the cell body is not affected. 3) Even under natural conditions when the flagella are non-agglutinable, for example in vis-à-vis pairs or in appropriate cell strains that are non-agglutinable in the dark, the cell bodies maintain the normal complement of active agglutinins. 4) When flagella of living cells are labeled with antibodies bound to fluorescein, the label does not diffuse onto the cell-body surface. 5) When gametes fuse to form vis-à-vis pairs, the original mating-type-specific antigenicity of each cell body is slowly lost (probably due to the antigens diffusing over both cell bodies), while the specific antigenicity of the flagellar surface is maintained. Even when the flagella of vis-à-vis pairs are regenerated from cell bodies with mixed antigenicity, the antigenicity of the flagella remains matingtype-specific. 6) Evidence is presented for the existence of a pool of agglutination factors within the cell bodies but not on the outer surface of the cells.Abbreviations and symbols CHI cycloheximide - GTC guaniline thiocyanate - mt ⁺/mt ^- mating type plus or minus - PAS Periodic-acid-Schiff reagent - SDS sodium dodecyl sulphate     

A phylogenetic analysis of the purple photosynthetic bacteria

It is proposed that gliding motility in bacteria is based on rotary assemblies located in the cell envelope and that these assemblies may be analogous to basal regions of bacterial flagella. This proposal rests on the following evidence: (i) Structures resembling flagellar basal regions have been demonstrated in cells ofCytophaga johnsonae andFlexibacter columnaris, and such structures are absent from one nonmotile mutant ofF. columnaris. (ii) The effects of inhibitors of energy metabolism on gliding motility are identical with their effects on prokaryotic fiagellar motility. (iii) The active movement of latex spheres along surfaces of gliding bacteria appears to depend on mechanisms responsible for motility and can be explained by the presence of rotary surface assemblies.     

Dealing with several flagella in the same cell

Flagella are sophisticated organelles found in many eukaryotic microbes where they perform functions related to motility, signal detection, or cell morphogenesis. In many cases, several flagella are present per cell, and these can have a different composition, length, age, or function, raising the question of how this is managed. When the flagella are equivalent and constructed simultaneously such as in Chlamydomonas or Naegleria, we propose an equal access model where molecular components have free access to each organelle. By contrast, Trypanosoma and Leishmania contain temporally distinct organelles and elongate a new flagellum whilst maintaining the existing one. The equal access model could function providing that the mature flagellum is “locked” so that it can no longer be elongated or shortened. Alternatively, access of flagellar components could be restricted at the level of the basal body, the transition zone, or the loading on intraflagellar transport trains. In organisms that contains flagella of different age and composition such as Giardia, a temporal dimension is necessary, with the production of protein components of flagella spreading over one or more cell cycles. In the future, deciphering the molecular mechanisms involved in these processes should reveal new insights in flagellum assembly and function.     

MOTILITY IN PROCARYOTIC ORGANISMS: PROBLEMS, POINTS OF VIEW, AND PERSPECTIVES

1. Procaryotic motility mechanisms are more difficult to investigate than those of the generally larger, hence more easily observable, eucaryotic forms. Furthermore, although the function—namely translational locomotion—is the same, the biomechanisms by which this end is accomplished may be, in fact, quite distinct in the two forms. 2. Observational techniques for studying procaryotic motility are relatively crude and qualitative. Progress toward a greater understanding of motility phenomena will be made correlative with advances derived from devising specific techniques involving approaches adapted from electrical engineering, biophysics and cybernetics. 3. There is a great amount of information at hand concerning the qualitative and quantitative chemical composition of procaryotic flagella, but there is no assurance that preparatory techniques include either the entire organelle on the one hand, or do not introduce subtle errors on the other hand. Similarly, the structural features of flagella as derived from electron-microscope studies of fixed preparations may be themselves influenced by the techniques employed to reveal them. 4. Chemotactic responses of bacteria have been noted almost since the beginning of bacteriology as a formal scientific endeavour, yet the study of transduction of environmental stimuli, using motile bacteria as experimental subjects, is a relatively recent development. We have proposed that the cytoplasmic membrane may act as a non-specific receptor-transmitter of such signals in motile bacteria. If this is found to be the case, perhaps a sensory code may be more amenable to discovery here than with more complex forms of organisms. 5. Knowledge of the physical aspects in procaryotic flagellar movement is extremely fragmentary. There is some information on the movements of living functional flagellar fascicles, but this form of movement of an individual flagellum is purely speculative. We have proposed that the procaryotic flagellum is a rigid or semi-rigid helix, which does not transmit helical waves of contraction, and that its movements are governed by a specialized area of the cytoplasmic membrane. The flagellum may rotate or wobble within the flagellar basal bulb to produce the motion necessary for propulsion. This view ‘explains’ many of the known properties of procaryotic flagella. 6. The basis of gliding motility remains unknown even after a great deal of experimental work. In our view, the secretion of slime is necessary for adhesion to a solid surface, and movement is believed to be mediated by a mechanism involving contractile waves. 7. Studies on procaryotic motility may yield valuable information on certain areas of general biological interest. Among these are: (a) the transduction of environmental stimuli and the sensory code; (b) the development of reproducible observational techniques for quantitative data on the hydrodynamic and biophysical parameters of cell motion in procaryotic forms; (c) the phenomenon of unicellular ‘behaviour’ and the survival value and evolutionary significance of motility; and (d) the elucidation of the mechanism of gliding with perhaps an assessment of its utility in a wide variety of micro-organisms. All of these areas are ripe for imaginative and innovative experimentation; let us hope it will be forthcoming!     

Synthesis and assembly of flagellar surface antigens during zoosporogenesis inPhytophthora cinnamomi

Summary Cryomicrotomy and immunofluorescence microscopy employing three different categories of monoclonal antibody (MAb) that label antigens on the surface of one or both flagella ofPhytophthora dnnamomi have been used to follow the synthesis and assembly of flagellar surface components. MAb Zf 1 binds to the surface of both the anterior tinsel and posterior whiplash flagella, as well as to a nuclear component. The labeling of the flagella is punctate in nature, is brighter at the flagellar base, and does not always extend to the distal tip of the flagella. MAbs in the Zt group recognise an antigen that is located along the sides of the tinsel flagellum and may be associated with the base of the mastigonemes. Immunodot-blot analysis has shown that binding of Zt MAbs is abolished by pretreatment with either pronase or periodate oxidation indicating that the antigen is a glycoprotein. MAbs in the Zg group bind to the mastigonemes on the tinsel flagellum and to packets of mastigonemes in the cytoplasm of zoospores. Zt and Zg antigens increase in abundance during zoosporogenesis and are present throughout the life cycle of the fungus, whereas the non-nuclear localisation of the Zf antigen appears only during sporulation. Prior to association with the flagellar surface, all three components become clustered in the groove region of zoospores. They do not become associated with the flagellar surface until at least 15 min after the flagellar axoneme has formed.Abbreviations BSA bovine serum albumin - DAPI 4,6-diamidino-2-phenylindole - DMF dimethylformamide - lgG₁ immunoglobulin G₁ - MAbs monoclonal antibodies - NIM non-immune mouse antibodies - PBS phosphate-buffered saline - PBST phosphate-buffered saline with 0.5% Tween 20 - PIPES 1,4-piperazinediethanesulfonic acid - PPD paraphenylenediamine dihydrochloride - RT room temperature - TBS tris-buffered saline - TEST tris-buffered saline with 0.05% Tween 20     

The flagellar apparatus structure inMicrospora (Chlorophyceae) confirms a close evolutionary relationship with unicellular green algae

The spatial configuration of the flagellar apparatus of the biflagellate zoospores of the green algal genusMicrospora is reconstructed by serial sectioning analysis using transmission electron microscopy. Along with the unequal length of the flagella, the most remarkable characteristics of the flagellar apparatus are: (1) the subapical emergence of the flagella (especially apparent with scanning electron microscopy); (2) the parallel orientation of the two basal bodies which are interconnected by a prominent one-piece distal connecting fiber; (3) the unique ultrastructure of the distal connecting fiber composed of a central tubular region which is bordered on both sides by a striated zone; (4) the different origin of the d-rootlets from their relative basal bodies; (5) the asymmetry of the papillar region which together with the subapical position of the basal bodies apparently cause the different paths of corresponding rootlets in the zoospore anterior; (6) the presence of single-membered d-rootlets and multi-membered s-rootlets resulting in a 7-1-7-1 cruciate microtubular root system which, through the different rootlet origin, does not exhibit a strict 180° rotational symmetry. It is speculated that the different basal body origin of the d-rootlets is correlated with the subapical implant of flagella. It is further hypothesized that in the course of evolution the ancestors ofMicrospora had a flagellar papilla that has migrated from a strictly apical position towards a subapical position. Simultaneously, ancestral shift of flagella along the apical cell body periphery has taken place as can be concluded from the presence of an upper flagellum overlying a lower flagellum in the flagellar apparatus ofMicrospora. The basic features of the flagellar apparatus of theMicrospora zoospore resemble those of the coccoid green algal generaDictyochloris andBracteacoccus and also those of the flagellate green algal genusHeterochlamydomonas. This strengthens the general supposition thatMicrospora is evolutionarily closely related to taxa which were formerly classified in the traditionalChlorococcales.     

Directed movements of ciliary and flagellar membrane components: a review.

The ability to rapidly translocate polystyrene microspheres attached to the surface of a plasma membrane domain reflects a unique form of cellular force transduction occurring in association with the plasma membrane of microtubule based cell extensions. This unusual form of cell motility can be utilized by protistan organisms for whole cell locomotion, the early events in mating, and transport of food organisms along the cell surface, and possibly intracellular transport of certain organelles. Since surface motility is observed in association with cilia and flagella of algae, sea urchin embryos and cultured mammalian cells, it is likely that it serves an additional role beyond those already cited; this is likely to be the transport of precursors for the assembly and turnover of ciliary and flagellar membranes and axonemes. In the case of the Chlamydomonas flagellum, where surface motility has been most extensively studied, it appears that cross-linking of flagellar surface exposed proteins induces a transmembrane signaling pathway that activates machinery for moving flagellar membrane proteins in the plane of the flagellar membrane. This signaling pathway in vegetative Chlamydomonas reinhardtii appears to involve an influx of calcium, a rise in intraflagellar free calcium concentration and a change in the level of phosphorylation of specific membrane-matrix proteins. It is hypothesized that flagellar surface contact with a solid substrate (during gliding), a polystyrene microsphere or another flagellum (during mating) will all activate a signaling pathway similar to the one artificially activated by the use of monoclonal antibodies to flagellar membrane glycoproteins. A somewhat different signaling pathway, involving a transient rise in intracellular cAMP level, may be associated with the mating of Chlamydomonas gametes, which is initiated by flagellum-flagellum contact. The hypothesis that the widespread observation of microsphere movements on various ciliary and flagellar surfaces may reflect a mechanism normally utilized to transport axonemal and membrane subunits along the internal surface of the organelle membrane presents a paradox in that one would expect this to be a constitutive mechanism, not one necessarily activated by a signaling pathway.     

Thrust reversal by tubular mastigonemes: immunological evidence for a role of mastigonemes in forward motion of zoospores ofPhytophthora cinnamomi

Summary The role of tubular mastigonemes in the reversal of thrust of the anterior flagellum ofPhytophthora cinnamomi was analysed using mastigoneme-specific monoclonal antibodies and immunoflu-orescence and video microscopy. Exposure of live zoospores ofP. cinnamomi to the mastigoneme-specific Zg antibodies caused alterations in the arrangement of mastigonemes on the flagellar surface and at Zg concentrations above 0.3 /ml, mastigonemes became detached from the flagellum. As a consequence of antibody binding to the mastigonemes there were concentration-dependent perturbations in zoospore swimming behaviour and anterior flagellum beat pattern. With increasing antibody concentration zoospores swam more slowly and other parameters of their swimming pattern, such as the wavelength of the swimming helix and the frequency of rotation, were also reduced. The effects of Zg antibodies were specific at two levels: control immunoglobulins or antibodies that bound to other flagellar surface components did not have an effect on motility, and Zg antibodies did not interfere with the motility of zoospores of oomycete species to which they did not bind. The effects of antibody-induced disruption of mastigoneme arrangement strongly support previous hypotheses that tubular mastigonemes are responsible for thrust reversal by the anterior flagellum, enabling it to pull the cell through the surrounding medium.     

Gliding motility in cyanobacteria: observations and possible explanations

Cyanobacteria are a morphologically diverse group of phototrophic prokaryotes that are capable of a peculiar type of motility characterized as gliding. Gliding motility requires contact with a solid surface and occurs in a direction parallel to the long axis of the cell or filament. Although the mechanistic basis for gliding motility in cyanobacteria has not been established, recent ultrastructural work has helped to identify characteristic structural features that may play a role in this type of locomotion. Among these features are the distinct cell surfaces formed by specifically arranged protein fibrils and organelle-like structures, which may be involved in the secretion of mucilage during locomotion. The possible role of these ultrastructural features, as well as consequences for understanding the molecular basis of gliding motility in cyanobacteria, are the topic of this review.     

Unusual distribution of a glycolipid antigen in the flagella ofChlamydomonas

Summary Mouse hybridomas were obtained that secrete monoclonal antibodies recognizing glycolipid antigens located in the flagellar membrane of the biflagellate alga,Chlamydomonas reinhardtii. The antigen is an acidic lipid that migrates slightly slower than a GM1 ganglioside on thin layer chromotography. The binding of the antibodies to the thin layer plate was inhibited by periodate oxidation suggesting that the antibodies are recognizing a carbohydrate epitope. In a variety ofChlamydomonas strains, these antibodies were found to stain the flagella of only a sub-set of the cells in the population, generally varying from 50% to 75% of the cells. Even after cloning, the population of cells continued to express this variability in staining, and presumably, expression of the glycolipid epitope. Although most cells showed either strong staining of both flagella or no detectable staining of both flagella, a subset of the cells in the culture exhibited differential antibody labeling of the two flagella, suggesting that an individualChlamydomonas can exhibit a different glycolipid composition in each of its two flagellar membranes and even differential expression along the length of an individual flagellum.     

Use of a novel Chlamydomonas mutant to demonstrate that flagellar glycoprotein movements are necessary for the expression of gliding motility

As an alternative to swimming through liquid medium by the coordinated bending activity of its two flagella, Chlamydomonas can exhibit whole cell gliding motility through the interaction of its flagellar surfaces with a solid substrate. The force transduction occurring at the flagellar surface can be visualized as the saltatory movements of polystyrene microspheres. Collectively, gliding motility and polystyrene microsphere movements are referred to as flagellar surface motility. The principal concanavalin A binding, surface-exposed glycoproteins of the Chlamydomonas reinhardtii flagellar surface are a pair of glycoproteins migrating with apparent molecular weight of 350 kDa. It has been hypothesized that these glycoproteins move within the plane of the flagellar membrane during the expression of flagellar surface motility. A novel mutant cell line of Chlamydomonas (designated L-23) that exhibits increased binding of concanavalin A to the flagellar surface has been utilized in order to restrict the mobility of the concanavalin A-binding flagellar glycoproteins. Under all conditions where the lateral mobility of the flagellar concanavalin A binding glycoproteins is restricted, the cells are unable to express whole cell gliding motility or polystyrene microsphere movements. Conversely, whenever cells can redistribute their concanavalin A binding glycoproteins in the plane of the flagellar membrane, they express flagellar surface motility. Since the 350 kDa glycoproteins are the major surface-exposed flagellar proteins, it is likely that most of the signal being followed using fluorescein isothiocyanate (FITC)-concanavalin A is attributable to these high molecular weight glycoproteins.(ABSTRACT TRUNCATED AT 250 WORDS)     

The flagellar developmental cycle in algae: flagellar transformation inCyanophora paradoxa (Glaucocystophyceae)

Summary Flagellar development during cell division was studied inCyanophora paradoxa using agarose-embedded cells, Nomarski optics and electronic flash photography. The cells bear two heterodynamic and differently oriented (anterior and posterior) flagella. Prior to cell division, cells produce two new anterior flagella while the parental anterior flagellum transforms into a posterior flagellum. The parental posterior flagellum remains a posterior flagellum throughout this and subsequent cell divisions. The development of a single flagellum thus extends through at least two cell cycles and flagellar heterogeneity is achieved by semiconservative distribution of the flagella during cell division. Based on these principles a universal numbering system for basal bodies and flagella of eukaryotic cells is proposed.     

Partial purification of presynaptic plasma membrane by immunoadsorption

Chlamydomonas flagella exhibit force transduction in association with their surface. This flagellar surface motility is probably used both for whole cell gliding movements (flagella-substrate interaction) and for reorientation of flagella during mating (flagella-flagella interaction). The present study seeks to identify flagellar proteins that may function as exposed adhesive sites coupled to a motor responsible for their translocation in the plane of the plasma membrane. The principal components of the flagellar membrane are a pair of glycoproteins (approximately 350,000 mol wt), with similar mobility on SDS polyacrylamide gels. A rabbit IgG preparation has been obtained which is specific for these two glycoproteins; this antibody preparation binds to and agglutinates cells by their flagellar surfaces only. Treatment of cells with 0.1 mg/ml pronase results in a loss of motility-coupled flagellar membrane adhesiveness. This effect is totally reversible, but only in the presence of new protein synthesis. The major flagellar protein modified by this pronase treatment is the faster migrating of the two high molecular weight glycoproteins; the other glycoprotein does not appear to be accessible to external proteolytic digestion. Loss and recovery of flagella surface binding sites for the specific antibody parallels the loss and recovery of the motility-coupled flagellar surface adhesiveness, as measured by the binding and translocation of polystyrene microspheres. These observations suggest, but do not prove, that the faster migrating of the major high molecular weight flagellar membrane glycoproteins may be the component which provides sites for substrate interaction and couples these sites to the cytoskeletal components responsible for force transduction.     

FLAGELLAR ELONGATION AND SHORTENING IN CHLAMYDOMONAS : The Use of Cycloheximide and Colchicine to Study the Synthesis and Assembly of Flagellar Proteins

Flagella can be removed from the biflagellate Chlamydomonas and the cells begin to regenerate flagella almost immediately by deceleratory kinetics. Under usual conditions of deflagellation, more than 98% of all flagella are removed. Under less drastic conditions, cells can be selected in which one flagellum is removed and the other left intact. When only one of the two flagella is amputated, the intact flagellum shortens by linear kinetics while the amputated one regenerates. The two flagella attain an equal intermediate length and then approach their initial length at the same rate. A concentration of cycloheximide which inhibits protein synthesis permits less than one-third of each flagellum to form when both flagella are amputated. When only one is amputated in cycloheximide, shortening proceeds normally and the degree of elongation in the amputated flagellum is greater than if both were amputated in the presence of cycloheximide. The shortening process is therefore independent of protein synthesis, and the protein from the shortening flagellum probably enters the pool of precursors available for flagellar formation. Partial regeneration of flagella occurs in concentrations of cycloheximide inhibitory to protein synthesis suggesting that some flagellar precursors are present. Cycloheximide and flagellar pulse-labeling studies indicate that precursor is used during the first part of elongation, is resynthesized at mid-elongation, and approaches its original level as the flagella reach their initial length. Colchicine completely blocks regeneration without affecting protein synthesis, and extended exposure of deflagellated cells to colchicine increases the amount of flagellar growth upon transfer to cycloheximide. When colchicine is applied to cells with only one flagellum removed, shortening continues normally but regeneration is blocked. Therefore, colchicine can be used to separate the processes of shortening and elongation. Radioautographic studies of the growth zone of Chlamydomonas flagella corroborate previous findings that assembly is occurring at the distal end (tip growth) of the organelle.     

Giant flagellar bundles ofVibrio alginolyticus (NCMB 1803)

Summary Following swarming ofVibrio alginolyticus on solid medium a large number of giant flagellar bundles appear behind the growth front. The suggested sequence of events leading to bundle formation is as follows. After inoculation from liquid to solid media the short rods with a single polar sheathed flagellum develop peritrichous nonsheathed flagella and elongate into long filamentous swarmers. After division into short rods, some of the cells become spherical in shape with many peritrichous flagella concentrated at one pole in close association with the sheathed polar flagellum. These tufted spherical bodies form the template upon which masses of loose peritrichous flagella spontaneously aggregate.Flagellar bundles formed when bacteria are grown at pH 8.5 are longer than those formed at pH 7.2 and shorter when grown at pH 6.5. In distilled water the flagellar bundles disintegrate into masses of flagellar fragments.