Ultrastructure and location of cytoplasmic fibrils inSpiroplasma floricola OBMG

The ultrastructure ofSpiroplasma floricola OBMG was investigated to identify subcellular structures that might be involved in motility and helicity. Optimal preservation for thin sectioning was achieved with either glutaraldehyde or a mixture of glutaraldehyde plus paraformaldehyde followed by OsO₄ and uranyl acetate. In thin sections, a 94-nm-wide band consisting of 4-nm-diameter fibrils was observed apposed to the cytoplasmic side of the plasma membrane. The band of fibrils extended axially the entire length of the cell. The addition of rethenium red to fixative solutions resulted in condensation of the fibrils. Freeze-substitution increased the apparent thickness of membranes but did not improve preservation of the fibrils. Freeze-fracturing revealed a 99-nm-wide zone containing few particles in fractured membrane surfaces. Treatment with deoxycholate or Triton X-100 to dissolve membranes yielded bands of fibrils comparable to those seen in thin sections. Based on these findings, a model indicating the intracellular location of the fibrils is proposed.     

THE CELL WALL OF PYROCYSTIS SPP. (DINOCOCCALES)1,2

The cell of Pyrocystis spp. is covered by an outer layer of material resistant to strong acids and bases. Internal to this layer much of the cell wall is composed of cellulose fibrils. The presence of cellulose fibrils was established by staining raw and ultra-violet–peroxide-cleaned cell walls and by combining X-ray diffraction spectroscopy with electron microscope observation. Carbon replicas of freeze-etched preparations and thin sections of P. lunula walls show outer layers, inside them ca. 24 layers of crossed parallel cellulose fibrils (4–5 nm thick, ca. 12 nm wide), then a region of smaller (ca. 6–12 nm diameter) fibrils in a disperse texture, and then the plasma membrane. Cellulose fibrils in the parallel texture are constructed of 3–5 elementary fibrils ca. 3 nm in diameter. Walls of P. fusiformis and P. pseudonctiluca also have cellulose fibrils in a crossed parallel texture similar to those of P. lunula. The Gymnodinium-type swarmer from lunate P. lunula appears to have a cell wall ultrastructure typical of other “naked” dinoflagellates.     

Regulation of cohesion-dependent cell interactions in Myxococcus xanthus.

Myxococcus xanthus has two nearly independent genetic systems, A and S, which appear to mediate adventurous (single-cell) movement and social (group) movement, respectively. In addition to a notable reduction in group movement, social motility mutants exhibit decreased biofilm formation, cell cohesion, dye binding, fibril production, and fruiting body formation. The stk-1907 allele, containing transposon Tn5 insertion omega DK1907, was introduced into wild-type cells and many social motility mutants. This allele, which was epistatic to most social motility mutations, caused wild-type and most mutant cells to exhibit increased group movement, cell cohesion, dye binding, and production of cell surface fibrils. The presence of the stk-1907 allele in dsp mutants, which almost completely lack cell surface fibrils, did not result in these phenotypic changes; therefore, stk-1907 is hypostatic to dsp mutations. Those mutants which exhibited increased group movement and cell cohesion with the stk-1907 allele also had increased fruiting body formation, but no significant changes in spore production were observed. These results suggest that fibrils may mediate cell cohesion, dye binding, and group movement. Additionally, the results suggest that the dsp locus contains genes involved in subunit synthesis, transport, and/or assembly of fibrils. The wild-type and mutant alleles of stk were cloned and studied in merodiploids. The mutant allele is recessive, suggesting that Tn5 omega DK1907 caused a null mutation in a gene which acts as a negative regulator of fibril synthesis. The stk-1907 allele appears to cause utilization of the A motility system for group movement, possibly because of increased fibril production.     

Mutants of Myxococcus xanthus dsp defective in fibril binding.

The dsp mutant of Myxococcus xanthus lacks extracellular fibrils and as a result is unable to undergo cohesion, group motility, or development (J. W. Arnold and L. J. Shimkets, J. Bacteriol. 170:5765-5770, 1983; J. W. Arnold and L. J. Shimkets, J. Bacteriol. 170:5771-5777, 1983; R. M. Behmlander and M. Dworkin, J. Bacteriol. 173:7810-7821, 1991; L. J. Shimkets, J. Bacteriol. 166:837-841, 1986; L. J. Shimkets, J. Bacteriol. 166:842-848, 1986). However, cohesion and development can be phenotypically restored by the addition of isolated fibrils (R. M. Behmlander, Ph.D. thesis, University of Minnesota, Minneapolis, 1994; B.-Y. Chang and M. Dworkin, J. Bacteriol. 176:7190-7196, 1994). As part of our attempts to examine the interaction of fibrils and cells of M. xanthus, we have isolated a series of secondary mutants of M. xanthus dsp in which cohesion, unlike that of the parent strain, could not be rescued by the addition of isolated fibrils. Cells of M. xanthus dsp were mutagenized either by ethyl methanesulfonate or by Tn5 insertions. Mutagenized cultures were enriched by selection of those cells that could not be rescued, i.e., that failed to cohere in the presence of isolated fibrils. Seven mutants of M. xanthus dsp, designated fbd mutants, were isolated from 6,983 colonies; these represent putative fibril receptor-minus mutants. The fbd mutants, like the parent dsp mutant, still lacked fibrils, but displayed a number of unexpected properties. They regained group motility and the ability to aggregate but not the ability to form mature fruiting bodies. In addition, they partially regained the ability to form myxospores. The fbd mutant was backcrossed into the dsp mutant by Mx4 transduction. Three independently isolated transconjugants showed essentially the same properties as the fbd mutants--loss of fibril rescue of cohesion, partial restoration of myxospore morphogenesis, and restoration of group motility. These results suggest that the physical presence of fibrils is not necessary for group motility, myxospore formation, or the early aggregative stage of development. We propose, however, that the perception of fibril binding is required for normal social behavior and development. The dsp fbd mutants (from here on referred to as fbd mutants) open the possibility of isolating and characterizing a putative fibril receptor gene.     

GLIDING MOTILITY IN THE BLUE-GREEN ALGA OSCILLATORIA PRINCEPS1

Gliding is an active movement displayed by a microorganism in contact with a solid substrate where there is no evidence of a motility organelle or of a conformational change in the organism. Gliding may be accompanied by rotations, reversals, flectional activity, and mucilage sheath production, as well as linear translation. Previous explanations of the mechanism responsible did not consider all these aspects of behavior. The gliding behavior and ultrastructure of the blue-green alga Oscillatoria princeps Vaucher were examined. O. princeps has a maximum observed gliding rate of 11.1 μm/sec. The trichomes can glide in either longitudinal direction following rapid and occasionally frequent reversals. Right-handed trichome rotation was always observed, which means that any surface point on these trichomes traces a 60-deg right-handed helix. A mucilage sheath envelopes the moving trichomes. The rate of gliding was reduced by viscous substrates, extreme pH, lysozyme, DNP, and cyanide, while sustained darkness had no inhibitory effect. Ultrastructurally, the cell wall is composed of an L-1 layer which is 10 nm thick and often ill-defined. The L-2 layer which is outside this is 200 nm thick and participates in septum formation. The L-3 layer is outside the L-2 and is continuous over the trichome surface. The L-4 “membrane” lies outside the L-3 layer. Grazing surface sections and freeze-etch replicas show a parallel and tight array of 6–9 nm wide continuous fibrils in the cell wall on the surface of the distinctive L-2 layer. Isolated wall fragments were tightly coiled inside out with the fibrils on the inside. The angle of orientation for the fibrils was to the right in a helix with a pitch of 60 deg. O. animalis, a blue-green alga with a movement tracing a left-handed helix, showed a similar array of fibrils oriented in a left-handed helix with a pitch of 60 deg. It is proposed that gliding is produced by unidirectional waves of bending in the fibrils which, act against the sheath or substrate, tints displacing the trichome.     

THE CELL WALL OF COSMARIUM BOTRYTIS12

The cell wall of Cosmarium botrytis was studied through the use of the freeze-etch technique. The cell wall consists of many thin layers. Fracturing along one layer reveals the positioning of the wall sculpturing, wall pores, and wall microfibrils. The individual microfibrils are grouped together in bands of parallel oriented fibrils. The different bands of parallel microfibrils were apparently arranged at random angles with regard to each other. Small particles may also be present in the cell walls. The cell wall pore unit of Cosmarium botrytis was studied through the use of scanning, freeze-etching, and thin sectioning techniques. The pore sheaths, on the outside of the cell wall, form a collar around the mouth of each pore. The pore sheath is composed of needle-like fibrils radiating outward from the pore. A pore channel traverses the cell wall and leads to a complex pore bulb region between the cell wall and the plasmalemma. The pore bulb contains many small fibrils which radiate toward the plasmalemma from a number of net-like fibril layers which in turn merge into a very electron dense region near the base of the pore.     

THE FINE STRUCTURE OF CHONDROCOCCUS COLUMNARIS : III. The Surface Layers of Chondrococcus columnaris

An electron microscope study of the myxobacterium Chondrococcus columnaris has revealed the following structures in the peripheral layers of the cells: (1) a plasma membrane, (2) a single dense layer (probably the mucopeptide component of the cell wall), (3) peripheral fibrils, (4) an outer membrane, and (5) a material coating the surfaces of the cells which could be stained with the dye ruthenium red.The ruthenium red-positive material is probably an acid mucopolysaccharide and may be involved in the adhesive properties of the cells. The outer membrane and plasma membrane both have the appearance of unit membranes: an electron-translucent layer sandwiched between two electron-opaque layers. The peripheral fibrils span the gap between the outer membrane and the mucopeptide layer, a distance of about 100 A, and run parallel to each other along the length of the cell. The fibrils appear to be continuous across the ends of the cells. The location of these fibrillar structures suggests that they may play a role in the gliding motility of these bacteria.     

Purification and preliminary characterization of Spiroplasma fibrils.

Fibrils 3.5 nm in diameter were released from the honeybee spiroplasma (BC3) by treatment with detergents and then purified by isopycnic centrifugation. Purified fibrils were flexuous, of indeterminate length, and had an axial repeat of 8.5 nm. The fibrils were associated in pairs, but in 1 M salt formed aggregates with a marked striated appearance. Pronase completely degraded the fibrils, but trypsin had little effect. The fibrils were composed of a single protein of molecular weight 55,000 which represented about 1% of the total cell protein. A protein of molecular weight 26,000 appeared to be associated with the fibrils. The significance of this in relation to membrane attachment and the possible role of fibrils in maintenance of cell shape and in motility are discussed.     

FURTHER CYTOLOGICAL STUDIES OF A PERIODIC ACID-SCHIFF'S SUBSTANCE IN THE OVULES OF PASPALUM ORBICULARE AND P. LONGIFOLIUM

A periodic acid-Schiff's substance present in the micropylar end of the ovules of Paspalum orbiculare and P. longifolium was further studied by light and electron microscopy of glutaraldehyde-osmium-fixed and freeze-substituted, osmium-fixed tissues. The PAS substance is water soluble and is found in intercellular spaces between the nucellus and inner integument, the inner and outer integuments, the outer integument and ovary wall, and in the micropyle. Structurally the substance consists of fibrils embedded in a dense, amorphous matrix and may be associated with membranous structures in special layers between the plasmalemma and the cell wall in nucellar and integumentary cells. Part of the water soluble substance is believed to be secreted from the nucellar and integumentary cells. A large amount of this substance may be formed as a result of the dissolution of about one third of the distal micopylar portion of the outer integument prior to anthesis. Many of the electron-dense fibrils seem to be fibrillar intercellular substances and others appear to originate from the cell walls, including the cuticle. Both the matrix and the fibrils may be chemically heterogeneous and together form a mucilagenous substance which may facilitate the final growth of pollen tubes in these two species.     

Molecular-scale topographic cues induce the orientation and directional movement of fibroblasts on two-dimensional collagen surfaces

Collagen fibres within the extracellular matrix lend tensile strength to tissues and form a functional scaffold for cells. Cells can move directionally along the axis of fibrous structures, in a process important in wound healing and cell migration. The precise nature of the structural cues within the collagen fibrils that can direct cell movement are not known. We have investigated the structural features of collagen that are required for directional motility of mouse dermal fibroblasts, by analysing cell movement on two-dimensional collagen surfaces. The surfaces were prepared with aligned fibrils of collagen type I, oriented in a predefined direction. These collagen-coated surfaces were generated with or without the characteristic 67 nm D-periodic banding. Quantitative analysis of cell morphodynamics showed a strong correlation of cell elongation and motional directionality with the orientation of D-periodic collagen microfibrils. Neither directed motility, nor cell body alignment, was observed on aligned collagen lacking D-periodicity, or on D-periodic collagen in the presence of peptide containing an RGD motif. The directional motility of fibroblast cells on aligned collagen type I fibrils cannot be attributed to contact guidance, but requires additional structural information. This allows us to postulate a physiological function for the 67 nm periodicity.     

PHOTOTACTIC MOTILITY OF SYNECHOCYSTIS SP. UNIWG (CYANOBACTERIA) FROM BRACKISH ENVIRONMENT1

Although type IV pilus has been implicated in the phototactic motility of some unicellular cyanobacteria, its regulatory mechanism and the effect of environmental factors on motility are still unknown. Equally important is the ability of cyanobacterial cells to anchor themselves to an environment that is conducive for survival. We compared the motility of a newly isolated unicellular brackish cyanobacterium, Synechocystis sp. UNIWG, with the morphologically and phylogenetically similar freshwater cyanobacterium Synechocystis sp. PCC6803 under different environmental conditions. The phototactic motility of Synechocystis sp. UNIWG on semisolid BG‐11 medium with various concentrations of nitrogen source was significantly faster than that of Synechocystis PCC6803. Interestingly, the cell surface of Synechocystis sp. UNIWG showed the presence of rigid spicules when grown in liquid BG‐11, a phenomenon that was absent in Synechocystis PCC6803. Negative staining of Synechocystis sp. UNIWG revealed the presence of two distinct pilus morphotypes, which resembled type IV pili and thin pili of Synechocystis PCC6803. This finding suggested a similar pattern of phototactic motility in both strains. However, the rigid spicules on Synechocystis sp. UNIWG seem to be more of a hindrance during type IV motility. It was determined that the spicules were degraded when the cells moved, such as under prolonged darkness and/or depletion of nitrogen source, indicating that the function of the spicules is to attach the cell to an environment that is conducive for its survival. Thus, Synechocystis sp. UNIWG shows phototaxis regulation that is more complex than Synechocystis PCC6803.     

Fibrillar Array in the Cell Wall of a Gliding Filamentous Cyanobacterium

The cell walls of a number of filamentous, gliding cyanobacteria of the genus Oscillatoria were examined by transmission electron microscopy of ultrathin sections, of freeze-etched replicas, and of whole cells crushed between glass slides and negatively stained. All three techniques revealed the presence of a highly ordered array of parallel fibrils, seen in transverse sections to be situated between the peptidoglycan and the outer membrane. Approximately 200 individual fibrils, each 25 to 30 nm in width, form a parallel, helical array that completely surrounds each cyanobacterial filament, running at an angle of 25 to 30° to its long axis. This highly regular arrangement of the fibrillar layer may imply some underlying symmetry responsible for its organization. A possible source of such symmetry would be the peptidoglycan, and some form of interaction between this layer and the fibrils might provide the necessary scaffolding for the fibrillar array. In crushed, negatively stained samples of fresh cells, individual fibrils were seen outside the filament, released from the cell wall. These released fibrils were of the same width as those observed in situ but were in short lengths, mostly of 100 to 200 nm, and were invariably bent, sometimes even into U shapes, implying great flexibility. Negative staining of released fibrils showed no evidence that they were hollow tubes but did give some indication of a substructure, implying that they were composed of many subunits. The function of this fibrillar array is unknown, although its position in the cell wall, as well as the correspondence between the angle of the fibrils with respect to the long axis of the filament and the rotation of the filament during gliding, may imply an involvement in gliding motility.     

ULTRASTRUCTURAL ASPECTS OF EARLY STAGES IN COTTON FIBER ELONGATION

Fine structural alterations associated with early stages of cotton fiber elongation in Gossypium hirsutum L. var. dunn 56 C occur rapidly following anthesis and appear to be correlated with the formation of the central vacuole, plasma membrane, and primary cell wall as well as with increased protein synthesis necessary for cell elongation. Association of dilated cisternae of the endoplasmic reticulum with the tonoplast suggests that the endoplasmic reticulum is involved in the formation of the central vacuole. Dictyosome involvement in both plasma membrane and primary cell wall formation was suggested from observations of similarities between dictyosome associated vesicles, containing fibrils appearing similar in morphology to fibrils found in the primary cell wall, and plasma membrane associated vesicles. The single nucleolus found in cotton fibers enlarges following anthesis, shows segregation of granular and fibrillar components by 1 day postanthesis, develops a large “vacuole,” thus appearing ring-shaped, and occupies much of the nuclear volume by 2 days postanthesis. Prominent nucleoli were not observed in nuclei after 10 days postanthesis.     

OBSERVATIONS ON THE MORPHOLOGY AND PHYSIOLOGY OF MARSILEA SPERM

The multiciliated sperm of the water fern Marsilea vestita was examined with a view to establishing its suitability as an experimental subject. Time-course experiments revealed spermatid development to be temperature dependent. Sterile techniques were devised for observation of sperm on both a population and an individual basis. Sperm discharge, active and senescing sperm were examined by phase-contrast microscopy. A regular pattern of senescence was ascertained. This included vacuolation of the cytoplasmic vesicle, loss of motility, and ultimate loss of the helical structure of the sperm coil. Sperm life spans were recorded using motility and O₂ uptake as criteria. Sperm populations are active 3–3½ hr at ambient temperature (22–25 C). Individual sperm are active less than 1 hr. Sperm suspensions show a decline in O₂ uptake which parallels the loss of motility. Various constituents affecting the life span were investigated. A twofold prolongation of the sperm life span occurred in the presence of 0.1 m sucrose. An ultrastructural examination of the mature sperm was made to aid in assessing its metabolic potential. The sperm shows little ultrastructural differentiation. The cytoplasmic vesicle is predominantly composed of starch-containing plastids. The main structural components of the sperm coil are a continuous mitochondrial band, an elongate nucleus, and a series of microtubules which separate the basal bodies from the nucleus and mitochondrion. A comparison of ultrastructural features common to Pteridium and Marsilea was made and factors affecting senescence discussed.     

The role of type V collagen fibril as an ECM that induces the motility of glomerular endothelial cells

Although type V collagen (Col V) is present in developing and mature connective tissues of glomeruli, its primary function has not been elucidated yet. The purpose of this study was to elucidate the role of Col V fibrils in glomerular cells. We isolated primary cells from porcine kidney and cultured them on Col V fibrils reconstructed from purified Col V molecules extracted from porcine cornea. Time-lapse observation showed that Col V fibrils induce dynamic movement of glomerular endothelial cells (GEC) by stimulating them to extend long filopodial protrusions and wide lamellipodia. Col V signaling mediated through β1 integrin activated phosphorylation of paxillin at tyrosine 118 (paxillin-pY118) and of focal adhesion kinase at tyrosine 861 (FAKpY861) at the cell periphery; a second Col V signal was mediated through neuroglycan 2 and activated FAKpY397. FAKpY861 was present in loose attachment points between Col V fibrils and GEC, allowing the cells to migrate easily. Activation of FAKpY397 induced incomplete focal adhesion at the centers of cells and caused cell movement. Therefore both signaling pathways facilitated cell motility, which was inhibited by the addition of antibodies to β1 integrin, NG2, and Col V. We suggest that Col V fibrils activate ‘outside-in’ signaling in GEC and induce their dynamic motility.     

EFFECTS OF ACIDIC SOLUTIONS ON SEXUAL REPRODUCTION OF PTERIDIUM AQUILINUM

Experiments were performed to determine the effects of acidic solutions on spermatozoid motility and fertilization of gametophytes of Pteridium aquilinum. Buffered solutions (0.0025 m ) were used to simulate exposures to acidic precipitation for up to a 3.5 hr exposure. Experimental results suggest that the spermatozoid population can be subdivided into several groups with respect to pH sensitivity; about 25% spermatozoids are immobile one min after exposure to pH 6.1 buffer while about an equal percentage remain motile after 30 min exposure to buffer of pH 5.1. Between these two response extremes are two other subpopulations. One is quite sensitive to pH but shows some recovery if pH is between 5.6 and 6.1, while the second subpopulation does not seem to exhibit any motility recovery at all but is more resistant to acidity than the first subpopulation. To complement experiments that evaluate spermatozoid responses, experiments were performed to view the process of fertilization under controlled environmental conditions as well as under the canopy of a forest. Fertilization of gametophytes in uncovered petri dishes under a forest canopy was similar to results in aseptic culture after gametophytes were exposed to various pH levels and 86.6 μM sulfate. Although there were some differences between results obtained under aseptic culture conditions and cultures maintained under a forest canopy, it is evident that a lower buffer pH decreased fertilization. Fertilization at pH 4.5 and 3.6 was about one-half that occurring at pH 6.1. Fertilization in gametophytes exposed to pH 3.0 was about 10-20% of that occurring at pH 6.1. Addition of 86.6 μM sulfate decreased fertilization under all culture conditions. These experimental results suggest that fertilization in P. aquilinum may be used as a bioindicator of contaminants in rainwater. The results demonstrate that spermatozoid motility (and the process of fertilization) is more acid sensitive than gametophytic and sporophytic tissues.     

Resource Level Affects Relative Performance of the Two Motility Systems of Myxococcus xanthus

The adventurous (A) and social (S) motility systems of the microbial predator Myxococcus xanthus show differential swarming performance on distinct surface types. Under standard laboratory conditions, A-motility performs well on hard agar but poorly on soft agar, whereas the inverse pattern is shown by S-motility. These properties may allow M. xanthus to swarm effectively across a greater diversity of natural surfaces than would be possible with one motility system alone. Nonetheless, the range of ecological conditions under which dual motility enhances effective swarming across distinct surfaces and how ecological parameters affect the complementarity of A-motility and S-motility remain unclear. Here we have examined the role of nutrient concentration in determining swarming patterns driven by dual motility on distinct agar surfaces, as well as the relative contributions of A-motility and S-motility to these patterns. Swarm expansion rates of dually motile (A⁺S⁺), solely A-motile (A⁺S⁻), and solely S-motile (A⁻S⁺) strains were compared on hard and soft agar across a wide range of casitone concentrations. At low casitone concentrations (0–0.1%), swarming on soft agar driven by S-motility is very poor, and is significantly slower than swarming on hard agar driven by A-motility. This reverses at high casitone concentration (1–3.2%) such that swarming on soft agar is much faster than swarming on hard agar. This pattern greatly constrained the ability of M. xanthus to encounter patches of prey bacteria on a soft agar surface when nutrient levels between the patches were low. The swarming patterns of a strain that is unable to produce extracellular fibrils indicate that these appendages are responsible for the elevated swarming of S-motility at high resource levels. Together, these data suggest that large contributions by S-motility to predatory swarming in natural soils may be limited to soft, wet, high-nutrient conditions that may be uncommon. Several likely benefits of S-motility to the M. xanthus life cycle are discussed, including synergistic interactions with A-motility across a wide variety of conditions.     

Structural and Biochemical Analysis of the Sheath of Phormidium uncinatum

The sheath of the filamentous, gliding cyanobacterium Phormidium uncinatum was studied by using light and electron microscopy. In thin sections and freeze fractures the sheath was found to be composed of helically arranged carbohydrate fibrils, 4 to 7 nm in diameter, which showed a substantial degree of crystallinity. As in all other examined motile cyanobacteria, the arrangement of the sheath fibrils correlates with the motion of the filaments during gliding motility; i.e., the fibrils formed a right-handed helix in clockwise-rotating species and a left-handed helix in counterclockwise-rotating species and were radially arranged in nonrotating cyanobacteria. Since sheaths could only be found in old immotile cultures, the arrangement seems to depend on the process of formation and attachment of sheath fibrils to the cell surface rather than on shear forces created by the locomotion of the filaments. As the sheath in P. uncinatum directly contacts the cell surface via the previously identified surface fibril forming glycoprotein oscillin (E. Hoiczyk and W. Baumeister, Mol. Microbiol. 26:699–708, 1997), it seems reasonable that similar surface glycoproteins act as platforms for the assembly and attachment of the sheaths in cyanobacteria. In P. uncinatum the sheath makes up approximately 21% of the total dry weight of old cultures and consists only of neutral sugars. Staining reactions and X-ray diffraction analysis suggested that the fibrillar component is a homoglucan that is very similar but not identical to cellulose which is cross-linked by the other detected monosaccharides. Both the chemical composition and the rigid highly ordered structure clearly distinguish the sheaths from the slime secreted by the filaments during gliding motility.     

THE ULTRASTRUCTURE OF THE PELLICLE COMPLEX OF EUGLENA GRACILIS

The pellicle complex of E. gracilis is composed of the cell membrane, the ridge and groove with the notch, four fibrils, and the subpellicular ER. The cell membrane is of unit membrane configuration and covers the outside of the cell, the cytostome, the gullet, and the reservoir. The notch of the pellicle complex has always a close topographic relationship to two particular fibrils, as well as the subpellicular ER. The gullet is that region between the reservoir and the cytostome which, in addition to longitudinal fibrils, is surrounded by a single row of circular fibrils. The circumference of the cytostome has twenty large pellicular ridges alternating with small pellicular ridges. Alternating tall and small pellicular ridges cover the entire cell during division.     

Characterization of cell motility in single heart valve interstitial cells in vitro

Valve interstitial cells (VIC) are the most prevalent cells in the heart valve, regulating to a large extent the normal biology of the valve and its pathobiological response to disease. In the process of valve tissue repair by VICs, single cell motility is likely to be important, as it is in wound repair by most mesenchymal type cells. We designed in vitro experiments using low density monolayer cultures to study the association of morphology and motility in single VICs which expressed alpha-smooth muscle actin. We observed that the morphology of single VICs can be categorized into six types which are reminiscent of the shape of VICs seen in vivo during valve repair. Of these morphologies, round, rhomboid, tailed and spindled shaped VICs were the most common. VICs did change their morphology over time. Rhomboid cells could become tailed or spindle-shaped and vice versa. Using time-lapse imaging and immunofluorescent microscopy, we showed that VIC morphologies reflect differences in cell motility and cell-matrix interactions. Tailed and spindle-shaped VICs were the predominant motile types and were associated with few extracellular fibronectin fibrils and less focal adhesions, as demonstrated by vinculin staining. Round and rhomboid shaped VICs were less motile and were associated with prominent vinculin and extracellular fibronectin fibrils. We found that cell mitosis is an important determinant of VIC migration. Many of the motile VICs were associated with mitosis as the daughter cells separated by migrating as tailed and spindle shaped cells. Thus cell morphology is an important determinant of VIC motility.