Membrane flow during nematode spermiogenesis

Two distinct types of surface membrane rearrangement occur during the differentiation of Caenorhabditis elegans spermatids into amoeboid spermatozoa. The first, detected by the behavior of latex beads attached to the surface, is a nondirected, intermittent movement of discrete portions of the membrane. This movement starts when spermatids are stimulated to differentiate and stops when a pseudopod is formed. The second type of movement is a directed, continual flow of membrane components from the tip of the pseudopod to its base. Both membrane glycoproteins and fluorescent phospholipids inserted in the membrane flow backward at the same rate, approximately 4 micrometers/min, although their lateral diffusion coefficients in the membrane differ by at least a factor of 5. These observations suggest that pseudopodial membrane movement is due to bulk flow of membrane components away from the tip of the pseudopod.     

Caenorhabditis elegans spermatozoan locomotion: amoeboid movement with almost no actin

The pseudopods of Caenorhabditis elegans spermatozoa move actively causing some cells to translocate when the sperm are dissected into a low osmotic strength buffered salts solution. On time-lapse video tapes, pseudopodial projections can be seen moving at 20-45 micrometers/min from the tip to the base of the pseudopod. This movement occurs whether or not the cell is attached to a substrate. Translocation of the cell is dependent on the substrate. Some spermatozoa translocate on acid-washed glass, but a better substrate is prepared by drying an extract of Ascaris uteri (the normal site of nematode sperm motility) onto glass slides. On this substrate more than half the spermatozoa translocate at a velocity (21 micrometers/min) similar to that observed in vivo. Translocating cells attach to the substrate by their pseudopodial projections. They always move toward the pseudopod; changes in direction are caused by changes in pseudopod shape that determine points of detachment and reattachment of the cell to the substrate. Actin comprises less than 0.02% of the proteins in sperm, and myosin is undetectable. No microfilaments are found in the sperm. Immunohistochemistry shows that some actin is localized in patches in the pseudopod. The movement of spermatozoa is unaffected by cytochalasins, however, so there is no evidence that actin participates in locomotion. Fertilization-defective mutants in genes fer-2, fer-4, and fer-6 produce spermatozoa with defective pseudopodial projections, and these spermatozoa are largely immotile. Mutants in the spermatozoa do not translocate. Thus pseudopod movement is correlated with the presence of normal projections. Twelve mutants with defective muscles have spermatozoa with normal movement, so these genes do not specify products needed for both muscle and nonmuscle cell motility.     

Molecular demarcation of surface domains as established by label-fracture cytochemistry of boar spermatozoa

We used "label-fracture" (J Cell Biol 99:1156, 1984) to establish high-resolution maps of wheat germ agglutinin (WGA) and concanavalin A (ConA) receptor sites on the cell surface of boar spermatozoa and to investigate the possible association of these receptors to integral membrane components. Label-fracture reveals intense WGA labeling over the region of the plasma membrane that overlies the acrosome, including the equatorial segment. The density of WGA receptors decreases from the post-acrosomal area to the posterior ring. The WGA receptor domain changes abruptly into a microdomain with an unusually high density of WGA receptors over a sharply delimited, particle-free zone at the base of the head. Over the tail, the density of WGA receptors in the tail is high and uniform over the midpiece, annulus, and principal piece, but narrow patches of rectilinear arrays of pits close to the annulus are not labeled. Labeling of the entire sperm head by ConA is both intense and uniform, except for the particle-free zone at the base of the head, which is barren of receptors. Over the tail, ConA labeling is strong over the midpiece, absent over the annulus, and sparse over the principal piece and the end piece. In contrast to WGA, ConA receptors co-distribute with the intramembrane particles. Our results confirm the potential of label-fracture for high-resolution mapping of the distribution of cell surface receptors. They show that in this specialized cell membrane domains can be sharply defined, i.e., apparent without free lateral diffusion of components.     

Caenorhabditis elegans spermatozoa assemble membrane proteins onto the surface at the tips of pseudopodial projections

The crawling movement of nematode sperm, like that of many other crawling metazoan cells, is accompanied by movement of membrane components from the leading edge of the cell rearward. We used colloidal gold conjugates of monoclonal antibodies (CGP-ABY) to membrane proteins on Caenorhabditis elegans sperm to examine this surface movement by electron microscopy. Antibody binding sites on fixed sperm are distributed uniformly over the cell surface. However, blocking these sites on live sperm with unlabelled antibody or removing them with protease and then pulse-labelling the cell with CGP-ABY revealed that new antigen is assembled onto the surface at the tips of the stubby projections that stud the pseudopod surface. These proteins then move rearward rapidly so that the pseudopod surface pool of antigen is replaced within 2 min. The same pattern of surface movement was observed when live cells were labelled with CGP-ABY and then washed with buffer before fixation. Bound CGP-ABY was cleared first from the tips of the projections and subsequently from the entire pseudopod surface. These gold particles accumulated at the base of the pseudopod without moving onto the cell body or being internalized. We did, however, detect a pool of antigen in the pseudopod cytoplasm that may be available for assembly onto the pseudopod surface. We propose that the localized assembly of new membrane and its subsequent rearward movement may play an important role in sperm locomotion.     

In vitro induction of crawling in the amoeboid sperm of the nematode parasite, Ascaris suum

In a highly synchronous process, the immotile spermatids of Ascaris suum extend pseudopods and become rapidly crawling sperm when treated with an extract from the glandular vas deferens of the male under strict anaerobic conditions. Within 9-12 min, a pseudopod develops, elongates rapidly, and exhibits a continuous flow of membrane specializations, the villipodia, from tip toward base. When attached to acid-washed glass, the pseudopod pulls the cell body along at speeds exceeding 70 microns/min. The pseudopod length remains constant while retrograde flow of villipodia proceeds at the same rate as the sperm's forward movement. Cohorts of about 15 villipodia form at the leading edge, move rearward together, and disappear at the junction of pseudopod and cell body. These are the terminations of branched, refringent fibers, which extend the length of the pseudopod. The latter are the fiber complexes that form its cytoskeleton (Sepsenwol et al.: Journal of Cell Biology 108:55-66, 1989). Locomoting cells sometimes change direction when another crawls by and follow each other. When cells are exposed to air, forward movement ceases in a predictable pattern: the forward extension of the leading edge ceases, the pseudopod shortens from the base, and the cell body continues to be pulled forward. These data contribute to a model for Ascaris sperm amoeboid motility in which independent processes of continuous extension at the leading edge and continuous shortening at the base of the pseudopod act to propel the cell forward.     

Differences in the redistribution of concanavalin A and wheat germ agglutinin binding sites on mouse neuroblastoma cells

Concanavalin A (Con A), wheat germ agglutinin (WGA), and Ricinus communis agglutinin (RCA) bound with either ¹²⁵I, fluorescent dyes, or fluorescent polymeric microspheres were used to quantitate and visualize the distribution of lectin binding sites on mouse neuroblastoma cells. As viewed by fluorescent light and scanning electron microscopy, over 10⁷ binding sites for Con A, WGA, and RCA appeared to be distributed randomly over the surface of differentiated and undifferentiated cells. An energy-dependent redistribution of labeled sites into a central spot occurred when the cells were labeled with a saturating dose of fluorescent lectin and maintained at 37°C for 60 min. Reversible labeling using appropriate saccharide inhibitors indicated that the labeled sites had undergone endocytosis by the cell. A difference in the mode of redistribution of WGA or RCA and Con A binding sites was observed in double labeling experiments. When less than 10% of the WGA or RCA lectin binding sites were labeled, only these labeled sites appeared to be removed from the cell surface. In contrast, when less than 10% of the Con A sites were labeled, both labeled and unlabeled Con A binding sites were removed from the cell surface. Cytochalasin B uncoupled the coordinate redistribution of labeled and unlabeled Con A sites, suggesting the involvement of microfilaments. Finally, double labeling experiments employing fluorescein-tagged Con A and rhodamine-tagged WGA indicate that most Con A and WGA binding sites reside on different membrane components and redistribute independenty of each other.     

Lectin-coated agarose beads in the investigation of sperm capacitation in the hamster

Sperm surface changes during in vitro capacitation were examined with the help of an assay system using lectincoated agarose beads. The nature and intensity of binding of epididymal spermatozoa to beads depended entirely on the particular stage of capacitation and the type of lectin attached to the bead surface. Fresh epididymal spermatozoa bound readily to beads coated with Con A, LCA, WGA, and PNA, but not with seven other lectins. During capacitation there was a constant decline in sperm binding to beads, and spermatozoa cultured for 4–5 hr bound only to those coated with Con A. A dramatic increase in sperm binding to Con A-coated agarose beads occurred between 4.5 and 5 hr, when large numbers of hyperactivated spermatozoa adhered, predominantly through their flagellae, to form large clumps on the beads. The clumping of spermatozoa on Con A-coated beads was enhanced in the presence of stimulators of capacitation (i.e., taurine, hypotaurine, and phosphodiesterase inhibitors) and was suppressed in the presence of various metabolic inhibitors (i.e., sodium azide and local anesthetics). The implications of these results are that the carbohydrate components of the entire surface of spermatozoa undergo striking changes during capacitation, and a close relationship may exist between the sperm surface and the metabolic changes occurring within capacitating spermatozoa. Sperm-bead binding assays are clearly able to recognize surface changes in asynchronous populations of motile spermatozoa and, due to their simplicity and speed, should prove to be valuable in gaining a greater understanding of the biochemistry of sperm capacitation.     

Analogous ultrastructure and surface properties during capping and phagocytosis in leukocytes

Ultrastructural analyses have revealed striking similarities between Concanavalin A capping and phagocytosis in leukocytes. Both processes involve extensive membrane movement to form a protuberance or pseudopods; a dense network of microfilaments is recruited into both the protuberance and the pseudopods; microtubules are disassembled either generally (capping) or in the local region of the pseudopods (phagocytosis); and cells generally depleted of microtubules by colchicine show polarized phagocytosis via the microfilament-rich protuberance rather than uniform peripheral ingestion of particles via individual pseudopods. Cap formation can thus be viewed as occurring as an exaggeration of the same ultrastructural events that mediate phagocytosis. Similar changes in cell surface topography also accompany capping and phagocytosis. Thus, in nonfixed cells, Concanavalin A-receptor complexes aggregate into the region of the protuberance in colchicine-treated leukocytes (conventional capping) or into the region of pseudopod formation in phagocytizing leukocytes. In the latter case, the movement of lectin-receptor complexes occurs from membrane overlying peripheral microtubules into filament-rich pseudopods that exclude microtubules. These data provide evidence against a role for microtubules as "anchors" for lectin receptors. Rather, they indicate a preferential movement of cell surface Concanavalin A-receptor complexes towards areas of extensive (the protuberance) or localized (pseudopods) microfilament concentration. In conventional capping, Concanavalin A must be added to the colchicine-treated cells before fixation in order to demonstrate movement of receptors from a diffuse distribution into the protuberance. However, Convanavalin A receptors are enriched in the membrane associated with phagocytic particles as compared to the remaining membrane. This particle-induced redistribution of receptors is particularly prominent in colchicine-treated cells that phagocytize and are then fixed and Concanavalin A labeled; both lectin receptors and beads are concentrated over the protuberance. Thus, the final analogy between conventionally capped and phagocytic cells is that in both cases the properties of the plasma membrane in regions of microfilament concentration are modified by Concanavalin A itself (capping) or by the phagocytized particle, to limit locally the diffusion of Concanavalin A receptors.     

Surface alterations during the capacitation of mammalian spermatozoa

Capacitation is the process by which mammalian sperm acquire the ability to undergo the acrosome reaction which, in turn, is a prerequisite for sperm-egg fusion and penetration. Until recently, it was thought that capacitation involved subtle physiological and chemical changes which had no morphological counterparts even at the electron microscopic level. However, it has now been shown by a number of investigators that material associated with the plasma membrane surface is either lost or extensively redistributed during in vitro or in vivo capacitation. We have made use of lectins and antibodies as probes of the sperm surface during capacitation and the acrosome reaction. Concanavalin A (Con A), wheat germ agglutinin (WGA) and soybean agglutinin (SBA) have been used in conjunction with fluorescent tags (FITC) and ultrastructural markers (ferritin, hemocyanin) to study the surface of golden hamster, guinea pig, mouse and human spermatozoa. Con A and WGA label the plasma membrane overlying the acrosomal region quite uniformly on these species. After capacitation there is a specific loss (or masking) of lectin binding sites over the acrosomal region of the sperm head in all species examined. Antibodies prepared against sperm and specific antibodies to a cell surface protein (fibronectin) were also tagged with fluorescent or ultrastructural markers and used to label the surfaces of sperm before and after capacitation. These probes also indicate a specific loss of surface associated material over the acrosomal surface after capacitation. These results are consistent with the notion that there is a general removal of surface components during capacitation and that this denuding of the surface is a prerequisite for the following membrane fusion events involved in the acrosome reaction and sperm-egg fusion.     

Plucking of lectin receptors from erythrocytes: Isolation of cell surface components without the use of detergents

A new approach is described for the isolation of lectin receptors without the use of detergents, by plucking them from the cell surface. Cells bound to lectin-coated Sepharose beads are sheared off the beads by mechanical disruption, whereupon the receptors remain attached to the beads and are released specifically by inhibitory sugars. Material plucked from neuraminidase-treated human erythrocytes by beads coated with peanut agglutinin and released by D-galactose was identified as asialoglycophorin. The same membrane glycoprotein was plucked from neuraminidase-treated erythrocytes by beads coated with soybean agglutinin, but at considerably lower yield.     

Goat sperm membrane: lectin-binding sites of sperm surface and lectin affinity chromatography of the mature sperm membrane antigens.

The cell surface glycoproteins of goat epididymal maturing spermatozoa have been investigated using lectins as surface probes that interact with specific sugars with high affinity. Concanavalin A (ConA) and wheat-germ agglutinin (WGA) showed high affinity for mature cauda epididymal sperm agglutination, whereas RCA2, kidney beans lectin and peanut agglutinin caused much lower or little agglutination of the cells. The mature sperm exhibited markedly higher efficacy than the immature caput epididymal sperm for binding both ConA and WGA, as evidenced by sperm agglutination and the binding of the fluorescence isothiocyanate (FITC)-labelled lectins. FITC-ConA binds uniformly to the entire mature sperm surface whereas FITC-WGA binds to the acrosomal cap region of the head. The FITC-RCA2 mainly labelled the posterior head of mature cauda sperm. However, no WGA-specific glycoprotein receptors could be detected in sperm plasma membrane (PM) by WGA-Sepharose affinity chromatography. The data implied that the epididymal sperm maturation is associated with a marked increase in the ConA/WGA receptors and that WGA receptors may be glycolipids rather than glycoproteins. Analysis of the ConA receptors of cauda sperm PM identified by ConA-Sepharose affinity chromatography and subsequent resolution in SDS-PAGE demonstrated the presence of five glycopolypeptides of different concentrations (98, 96, 43, 27 and 17 kDa) of goat sperm membrane. The immunoblot of these ConA-specific glycopeptides with anti-sperm membrane antiserum showed that 98- and 96-kDa receptors are immunoresponsive.     

Comparative analysis of membrane glycoproteins of normal and chronic lymphatic leukemia B lymphocytes by lectins

Eight plant lectins were used to investigate membrane alterations in lymphocytes from patients with chronic lymphocytic leukemia (CLL). By rosetting with lectins attached to latex particles, the cell percentages with the abundance of each lectin receptor were compared in B normal and leukemic lymphocytes. Comparing these data with the number of lectin molecules bound to each cell and the affinity, which are values calculated with 125I-labeled lectins, it was possible to deduce differences in the composition of glycoproteins in B normal and B-CLL lymphocytes membrane. Compared to B normal, B-CLL lymphocytes had fewer receptors for WGA and more for Lens culinaris, SBA and Tetragonolobus purpureus lectins. Receptors for Concanavalin A, Pisum sativum, PHA and Tetragonolobus purpureus showed a higher affinity with B normal lymphocytes, while the other lectins assayed showed more affinity with B-CLL lymphocytes. So, it is possible to establish a comparative analysis about the plasma membrane glycoproteins in the B normal and CLL lymphocytes by lectin binding studies.     

Binding of purified lectins to guinea pig lymphocytes. Studies of the number, binding constant, and distribution of lens culinaris lectin A and Agaricus bisporus lectin molecules on lymphocyte surfaces

The surface membrane of guinea pig lymphocytes contains discrete receptors for several different homogeneous lectins. Two very similar lectins from the lentil, LcL-A and LcL-B, bind to the same receptor. Three other lectins, AbL, WGA, and Con A, do not bind detectably to the LcL receptor. AbL binds to another discrete receptor to which none of the other lectin molecules bind. The LcL and AbL receptors are contained on different units, each of which is capable of independent movement on the cell surface. The normal distribution of LcL molecules on the surface is different than the distribution of AbL molecules. However, when lymphocytes are simultaneously incubated with LcL and AbL, the distribution of bound LcL molecules on the cell surface parallels the normal distribution of AbL molecules, which indicates that the movement of AbL molecules and AbL receptors on the surface can strongly influence the movement of LcL and LcL receptors. When lymphocytes are held in close contact by LcL or AbL, the lectin molecules and receptors appear to concentrate at the area of contact between two cells. A model is presented which suggests that the migration of lectins and lectin receptors can occur by a multicellular process.     

Effects of plant lectins on the adhesive properties of baby hamster kidney cells

We studied the effects of different lectins on the adhesive properties of baby hamster kidney (BHK) cells. The purpose of these studies was to learn more about the cell surface receptors involved in cell adhesion. Three adhesive phenomena were analyzed: 1) the adhesion of BHK cells to lectin-coated substrata; 2) the effects of lectins on the adhesion of cells to substrata coated by plasma fibronectin (pFN); and 3) the effects of lectins on the binding of pFN-coated beads to cells. Initial experiments with fluorescein-conjugated lectins indicated that concanavalin A (Con A), ricinus communis agglutinin I (RCA I), and wheat germ agglutinin (WGA) bound to BHK cells but peanut agglutinin (PNA), soybean agglutinin (SBA), and ulex europaeus agglutinin I (UEA I) dod not bind. All three of the lectins which bound to the cells promoted cell spreading on lectin substrata, and the morphology of the spread cells was similar to that observed with cells spread on pFN substrata. Protease treatment of the cells, however, was found to inhibit cell spreading on pFN substrata or WGA substrata more than on Con A substrata or RCA I substrata. In the experiment of cells with Con A or WGA inhibited cell spreading on pFN substrata, but RCA I treatment had no effect. Finally, treatment of cells with WGA inhibited binding to cells of pFN beads, but neither Con A nor RCA I affected this interaction. These results indicate that the lectins modify cellular adhesion in different ways, probably by interacting with different surface receptors. The possibility that the pFN receptor is a WGA receptor is discussed.     

Enucleation eliminates a differentiation-specific surface marker from normal and leukemic murine erythroid cells

Mammalian erythropoiesis includes a step in which the nucleus is extruded through the cell membrane. We have investigated the relationship between concanavalinA (conA) plasma membrane receptors, which are known to leave the incipient reticulocyte during enucleation, and regions of the plasma membrane which bind merocyanine 540, a differentiation-specific marker of hematopoietic cells. The distribution of these two fluorescent probes was examined on living cells from the spleens of neonatal mice and on erythroleukemia cells induced to enucleate in culture. In both cases, the region of the membrane extruded with the nucleus preferentially binds conA and merocyanine 540, whereas the plasma membrane which is left behind retains the capacity to bind another lectin, wheat germ agglutinin (WGA). The implications of these findings are discussed with respect to the mechanism by which markers are eliminated from the erythrocyte cell surface.     

Differential behavior of photoactivated microtubules in growing axons of mouse and frog neurons

To characterize the behavior of axonal microtubules in vivo, we analyzed the movement of tubulin labeled with caged fluorescein after activation to be fluorescent by irradiation of 365-nm light. When mouse sensory neurons were microinjected with caged fluorescein-labeled tubulin and then a narrow region of the axon was illuminated with a 365-nm microbeam, photoactivated tubulin was stationary regardless of the position of photoactivation. We next introduced caged fluorescein-labeled tubulin into Xenopus embryos and nerve cells isolated from injected embryos were analyzed by photoactivation. In this case, movement of the photoactivated zone toward the axon tip was frequently observed. The photoactivated microtubule segments in the Xenopus axon moved out from their initial position without significant spreading, suggesting that fluorescent microtubules are not sliding as individual filaments, but rather translocating en bloc. Since these observations raised the possibility that the mechanism of nerve growth might differ between two types of neurons, we further characterized the movement of another component of the axon structure, the plasma membrane. Analysis of the position of polystyrene beads adhering to the neurites of Xenopus neurons revealed anterograde movement of the beads at the rate similar to the rate of microtubule movement. In contrast, no movement of the beads relative to the cell body was observed in mouse sensory neurons. These results suggest that the mode of translocation of cytoskeletal polymers and some components of the axon surface differ between two neuron types and that most microtubules are stationary within the axon of mammalian neurons where the surface-related motility of the axon is not observed.     

Transmembrane effects of lectins : I. Effects of wheat germ agglutinin and soybean agglutinin on furrow formation and cortical wound healing in Xenopus laevis eggs

Studies on the binding of FITC-WGA and FITC-SBA to normal and cytochalasin (CB)-treated Xenopus eggs have demonstrated the presence of lectin receptors all over the egg surface; there are aggregates of receptors in the region where microvilli are numerous and microfilaments well organized. Addition of WGA or SBA to the incubation medium provokes inhibition of furrow formation provided that the lectins are added before the streak stage, or arrest of contraction when added during furrow formation. This arrest of contraction is followed by furrow regression. The lectins also affect wound healing. All these effects may be explained by an inhibition of membrane proteins movement and an alteration of the relations between the surface and the cytoskeleton.     

Lectin-binding sites on the plasma membranes of rabbit spermatozoa: Changes in surface receptors during epididymal maturation and after ejaculation

Modifications in rabbit sperm plasma membranes during epididymal passage and after ejaculation were investigated by used of three lectins: concanavalin A (Con A); Ricinus communis I (RCA(I)); and wheat germ agglutinin (WGA). During sperm passage from caput to cauda epididymis, agglutination by WGA drastically decreased, and agglutination by RCA(I) slightly decreased, although agglutination by Con A remained approximately unchanged. After ejaculation, spermatozoa were agglutinated to a similar degree or slightly less by Con A, WGA, and RCA(I), compared to cauda epididymal spermatozoa. Ultrastructural examination of sperm lectin-binding sites with ferritin- lectin conjugates revealed differences in the densities of lectin receptors in various sperm regions, and changes in the same regions during epididymal passage and after ejaculation. Ferritin-RCA(I) showed abrupt changes in lectin site densities between acrosomal and postacrosomal regions of sperm heads. The relative amounts of ferritin-RCA(I) bound to heads of caput epididymal or ejaculated spermatozoa. Tail regions were labeled by ferritin RCA(I) almost equally on caput and cauda epididymal spermatozoa, but the middle-piece region of ejaculated spermatozoa was slightly more densely labeled than the principal-piece region, and these two regions on ejaculated spermatozoa were labeled less than on caput and cuada epididymal spermatozoa. Ferritin-WGA densely labeled the acrosomal region of caput epididymal spermatozoa, although labeling of cauda epidiymal spermatozoa was relatively sparse except in the apical area of the acrosomal region. Ejaculated spermatozoa bound only a few molecules of ferritin-WGA, even at the highest conjugate concentrations used. Caput epididymal, but not cauda epididymal or ejaculated spermatozoa, bound ferritin-WGA in the tail regions. Dramatic differences in labeling densities during epididymal passage and after ejaculation were not found with ferritin-Con A.     

Movement of surface markers along the pinocytotic pseudopodia ofAmoeba proteus

Summary The movement of latex beads over pinocytotic pseudopodia produced byAmoeba proteus was recorded in the presence of 117.65 mM EGTA as an inducer of pinocytosis. The results show that all particles flow in the direction of pseudopodial growth, with a slightly higher velocity than the advancing frontal edge. This means that markers are removed from the base of a pinocytotic pseudopodium and gradually approach the pseudopodium tip. Two particles on the surface of the same pseudopodium can move at the same rate or differ slightly in the velocity of their forward flow. A bead can move even if another blocks the channel orifice. Retrograde particle movement has never been observed. Whether all latex spheres bound to pinocytotic pseudopodia flow with the laterally mobile plasma membrane fraction, which slides over submembranous contractile layer, or whether the whole cortical complex, the actin network and the plasma membrane, move together towards the invagination site is discussed.