A unique cytoskeleton associated with crawling in the amoeboid sperm of the nematode, Ascaris suum

Nematode sperm extend pseudopods and pull themselves over substrates. They lack an axoneme or the actin and myosins of other types of motile cells, but their pseudopods contain abundant major sperm protein (MSP), a family of 14-kD polypeptides found exclusively in male gametes. Using high voltage electron microscopy, a unique cytoskeleton was discovered in the pseudopod of in vitro-activated, crawling sperm of the pig intestinal nematode Ascaris suum. It consists of 5-10-nm fuzzy fibers organized into 150-250-nm-thick fiber complexes, which connect to each of the moving pseudopodial membrane projections, villipodia, which in turn make contact with the substrate. Individual fibers in a complex splay out radially from its axis in all directions. The centripetal ends intercalate with fibers from other complexes or terminate in a thickened layer just beneath the pseudopod membrane. Monoclonal antibodies directed against MSP heavily label the fiber complexes as well as individual pseudopodial filaments throughout their length. This represents the first evidence that MSP may be the major filament protein in the Ascaris sperm cytoskeleton. The large fiber complexes can be seen clearly in the pseudopods of live, crawling sperm by computer-enhanced video, differential-interference contrast microscopy, forming with the villipodia at the leading edge of the sperm pseudopod. Even before the pseudopod attaches, the entire cytoskeleton and villipodia move continuously rearwards in unison toward the cell body. During crawling, complexes and villipodia in the pseudopod recede at the same speed as the spermatozoon moves forward, both disappearing at the pseudopod-cell body junction. Sections at this region of high membrane turnover reveal a band of densely packed smooth vesicles with round and tubular profiles, some of which are associated with the pseudopod plasma membrane. The exceptional anatomy, biochemistry, and phenomenology of Ascaris sperm locomotion permit direct study of the involvement of the cytoskeleton in amoeboid motility.     

Centripetal flow of pseudopodial surface components could propel the amoeboid movement of Caenorhabditis elegans spermatozoa

Latex beads and wheat germ agglutinin (WGA) were used to examine the movement of membrane components on amoeboid spermatozoa of Caenorhabditis elegans. The behavior of beads attached to the cell revealed continuous, directed movement from the tip of the pseudopod to its base, but no movement on the cell body. Lectin receptors are also cleared from the pseudopod (4). Blocking preexisting lectin receptors with unlabeled WGA followed by pulse-labeling wih fluorescent WGA showed that new lectin receptors are continuously inserted at the tip of the pseudopod. Like latex beads, these new lectin receptors move continuously over the pseudopod surface to the cell body-pseudopod junction where they are probably internalized. Mutants altering the rate of membrane flow, and eliminating its topographical asymmetry, have been identified. Together with the observation that fluorescent phospholipids are cleared from the pseudopod of developing spermatozoa at the same rate as lectin receptors (25), these results show that there is bulk membrane flow over the pseudopod with assembly at the tip and apparent disassembly at the base. There are no vesicles visible at either the pseudopodial tip or base, so these spermatozoa must have a novel mechanism for insertion and uptake of membrane components. This membrane flow could provide the forward propulsion of spermatozoa attached to a substrate by their pseudopods.     

Relationship between plasma membrane mobility and substrate attachment in the crawling movement of spermatozoa from Caenorhabditis elegans

Caenorhabditis elegans sperm are nonflagellated cells that lack actin and myosin yet can form pseudopods to propel themselves over solid substrates. Surface-attached probes such as latex beads, lectins, and antimembrane protein monoclonal antibodies move rearward over the dorsal pseudopod surface of sessile cells. Using monoclonal antibodies against membrane proteins of C. elegans sperm to examine the role of localized membrane assembly and rearward flow in crawling movement, we determined that substrates prepared by coating glass with antimembrane protein antibodies, but not naked glass or other nonmembrane-binding proteins, promote sperm motility. Sperm locomotion is inhibited in a concentration-dependent fashion when cells are bathed with soluble antimembrane protein monoclonal antibodies but not with antimouse Ig antibodies or a monoclonal antibody against a sperm cytoplasmic protein. Our results suggest that C. elegans sperm crawl by gaining traction with substrate-attached ligands via their surface proteins and by using the motor that moves those proteins rearward on unattached cells to pull the entire cell forward. Continuous insertion of new proteins at the front of the cell and their subsequent adhesion to the substrate allows this process to continue.     

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.     

Developmental Genetics of Chromosome I Spermatogenesis-Defective Mutants in the Nematode Caenorhabditis Elegans

Mutations affecting Caenorhabditis elegans spermatogenesis can be used to dissect the processes of meiosis and spermatozoan morphological maturation. We have obtained 23 new chromosome I mutations that affect spermatogenesis (spe mutations). These mutations, together with six previously described mutations, identify 11 complementation groups, of which six are defined by multiple alleles. These spe mutations are all recessive and cause normally self-fertile hermaphrodites to produce unfertilized oocytes that can be fertilized by wild-type male sperm. Five chromosome I mutation/deficiency heterozygotes have similar phenotypes to the homozygote showing that the probable null phenotype of these genes is defective sperm. Spermatogenesis is disrupted at different steps by mutations in these genes. The maturation of 1 degree spermatocytes is disrupted by mutations in spe-4 and spe-5. Spermatids from spe-8 and spe-12 mutants develop into normal spermatozoa in males, but not in hermaphrodites. fer-6 spermatids are abnormal, and fer-1 spermatids look normal but subsequently become abnormal spermatozoa. Mutations in five genes (fer-7, spe-9, spe-11, spe-13 and spe-15) allow formation of normal looking motile spermatozoa that appear to be defective in either sperm-spermathecal or sperm-oocyte interactions.     

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.     

Evidence for phosphorylation in the MSP cytoskeletal filaments of amoeboid spermatozoa

Nematode spermatozoa are highly specialized cells that lack flagella and, instead, extend a pseudopod to initiate motility. Crawling spermatozoa display classic features of amoeboid motility (e.g. protrusion of a pseudopod that attaches to the substrate and the assembly and disassembly of cytoskeletal filaments involved in cell traction and locomotion), however, cytoskeletal dynamics in these cells are powered exclusively by Major Sperm Protein (MSP) rather than actin and no other molecular motors have been identified. Thus, MSP-based motility is regarded as a simple locomotion machinery suitable for the study of plasma membrane protrusion and cell motility in general. This recent focus on MSP dynamics has increased the necessity of a standardized methodology to obtain C. elegans sperm extract that can be used in biochemical assays and proteomic analysis for comparative studies. In the present work we have modified a method to reproducibly obtain relative high amounts of proteins from C. elegans sperm extract. We show that these extracts share some of the properties observed in sperm extracts from the parasitic nematode Ascaris including Major Sperm Protein (MSP) precipitation and MSP fiber elongation. Using this method coupled to immunoblot detection, Mass Spectrometry identification, in silico prediction of functional domains and biochemical assays, our results indicate the presence of phosphorylation sites in MSP of Caenorhabditis elegans spermatozoa.     

ACTIN AND MYOSIN REGULATE PSEUDOPODIA OF PORPHYRA PULCHELLA (RHODOPHYTA) ARCHEOSPORES1

Archeospores of Porphyra pulchella Ackland, J. A. West et Zuccarello (Rhodophyta) display amoeboid and gliding motility. Time‐lapse videomicroscopy revealed that amoeboid cells extend and retract pseudopodia as they translocate through the media. We investigated the involvement of actin and myosin in generating the force for amoeboid motility using immunofluorescence, time‐lapse videomicroscopy, and cytoskeletal inhibitors. Actin filaments were seen as short and long rodlike bundles around the periphery of spores. The actin inhibitors cytochalasin D (CD) and latrunculin B (Lat B), and the myosin inhibitor butanedione monoxime (BDM) disrupted the actin filament network and reversibly inhibited pseudopodial activity, resulting in the rounding and immobilization of spores. It was uncertain whether forward translocation of archeospores resumed following drug removal. These results demonstrate that actin and myosin have a role in generating force for pseudopodial activity. This is the first report of cytoskeletal involvement in red algal cell movement. The involvement of actin and myosin in forward translocation of amoeboid archeospores can only be speculated upon.     

Mutants in the Dictyostelium Arp2/3 complex and chemoattractant-induced actin polymerization

We have investigated the role of the Arp2/3 complex in Dictyostelium cell chemotaxis towards cyclic-AMP and in the actin polymerization that is triggered by this chemoattractant. We confirm that the Arp2/3 complex is recruited to the cell perimeter, or into a pseudopod, after cyclic-AMP stimulation and that this is coincident with actin polymerization. This recruitment is inhibited when actin polymerization is blocked using latrunculin suggesting that the complex binds to pre-existing actin filaments, rather than to a membrane associated signaling complex. We show genetically that an intact Arp2/3 complex is essential in Dictyostelium and have produced partially active mutants in two of its subunits. In these mutants both phases of actin polymerization in response to cyclic-AMP are greatly reduced. One mutant projects pseudopodia more slowly than wild type and has impaired chemotaxis, together with slower movement. The second mutant chemotaxes poorly due to an adhesion defect, suggesting that the Arp2/3 complex plays a crucial part in adhering cells to the substratum as they move. We conclude that the Arp2/3 complex largely mediates the actin polymerization response to chemotactic stimulation and contributes to cell motility, pseudopod extension and adhesion in Dictyostelium chemotaxis.     

Tumor cell pseudopodial protrusions. Localized signaling domains coordinating cytoskeleton remodeling, cell adhesion, glycolysis, RNA translocation, and protein translation

The pseudopodial protrusions of Moloney sarcoma virus (MSV)-Madin-Darby canine kidney (MDCK)-invasive (INV) variant cells were purified on 1-microm pore polycarbonate filters that selectively allow passage of the pseudopodial domains but not the cell body. The purified pseudopodial fraction contains phosphotyrosinated proteins, including Met and FAK, and various signaling proteins, including Raf1, MEK1, ERK2, PKBalpha (Akt1), GSK3alpha, GSK3beta, Rb, and Stat3. Pseudopodial proteins identified by liquid chromatography tandem mass spectrometry included actin and actin-regulatory proteins (ERM, calpain, filamin, myosin, Sra-1, and IQGAP1), tubulin, vimentin, adhesion proteins (vinculin, talin, and beta1 integrin), glycolytic enzymes, proteins associated with protein translation, RNA translocation, and ubiquitin-mediated protein degradation, as well as protein chaperones (HSP90 and HSC70) and signaling proteins (RhoGDI and ROCK). Inhibitors of MEK1 (U0126) and HSP90 (geldanamycin) significantly reduced MSV-MDCK-INV cell motility and pseudopod expression, and geldanamycin treatment inhibited Met phosphorylation and induced the expression of actin stress fibers. ROCK inhibition did not inhibit cell motility but transformed the pseudopodial protrusions of MSV-MDCK-INV cells into extended lamellipodia. Dominant negative Rho disrupted pseudopod expression and, in serum-starved cells, L-alpha-lysophosphatidic acid (oleoyl) activation of Rho induced pseudopodial protrusions or, in the presence of the ROCK inhibitor, extended lamellipodia. RNA was localized to the actin-rich pseudopodial domains of MSV-MDCK-INV cells, but the extent of colocalization with dense actin ruffles was reduced in the extended lamellipodia formed upon ROCK inhibition. Rho/ROCK activation in epithelial tumor cells therefore regulates RNA translocation to a pseudopodial domain that contains proteins involved in signaling, cytoskeleton remodeling, cell adhesion, glycolysis, and protein translation and degradation.     

Gliding mutants of Myxococcus xanthus with high reversal frequencies and small displacements

Myxococcus xanthus cells move on a solid surface by gliding motility. Several genes required for gliding motility have been identified, including those of the A- and S-motility systems as well as the mgl and frz genes. However, the cellular defects in gliding movement in many of these mutants were unknown. We conducted quantitative, high-resolution single-cell motility assays and found that mutants defective in mglAB or in cglB, an A-motility gene, reversed the direction of gliding at frequencies which were more than 1 order of magnitude higher than that of wild type cells (2.9 min-1 for DeltamglAB mutants and 2.7 min-1 for cglB mutants, compared to 0.17 min-1 for wild-type cells). The average gliding speed of DeltamglAB mutant cells was 40% of that of wild-type cells (on average 1.9 micrometers/min for DeltamglAB mutants, compared to 4.4 micrometers/min for wild-type cells). The mglA-dependent reversals and gliding speeds were dependent on the level of intracellular MglA protein: mglB mutant cells, which contain only 15 to 20% of the wild-type level of MglA protein, glided with an average reversal frequency of about 1.8 min-1 and an average speed of 2.6 micrometers/min. These values range between those exhibited by wild-type cells and by DeltamglAB mutant cells. Epistasis analysis of frz mutants, which are defective in aggregation and in single-cell reversals, showed that a frzD mutation, but not a frzE mutation, partially suppressed the mglA phenotype. In contrast to mgl mutants, cglB mutant cells were able to move with wild-type speeds only when in close proximity to each other. However, under those conditions, these mutant cells were found to glide less often with those speeds. By analyzing double mutants, the high reversing movements and gliding speeds of cglB cells were found to be strictly dependent on type IV pili, encoded by S-motility genes, whereas the high-reversal pattern of mglAB cells was only partially reduced by a pilR mutation. These results suggest that the MglA protein is required for both control of reversal frequency and gliding speed and that in the absence of A motility, type IV pilus-dependent cell movement includes reversals at high frequency. Furthermore, mglAB mutants behave as if they were severely defective in A motility but only partially defective in S motility.     

Actin- and tubulin-dependent functions during Saccharomyces cerevisiae mating projection formation.

Several conditional-lethal mutant alleles of the single-copy Saccharomyces cerevisiae beta-tubulin and actin genes were used to evaluate the roles of microtubules and actin filaments in the pheromone-induced extension of mating projections. Mutants defective in tubulin assembly form projections indistinguishable in appearance from those formed by wild-type cells. However, the tubulin mutants are unable to move their nuclei into the projections and to orient the spindle pole body associated with each nucleus toward the projection tip. Actin mutants are defective in spatial orientation of cell-surface growth required for formation of normal mating projections. Migration of nuclei into mating projections and Spa2p segregation to projection tips are also defective in actin mutants. Studies with abp1 null mutants showed that the function of the Abp1p actin-binding protein is either not required for projection formation or there are other proteins in yeast with similar functions. Our findings demonstrate that actin is required to restrict cell-surface growth to a defined region for pheromone-induced morphogenesis and suggest that nuclear position and orientation in mating projections depend on direct or indirect interaction of microtubules with actin filaments.     

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.     

The physiological acquisition of amoeboid motility in nematode sperm: Is the tail the only thing the sperm lost?

Nematode spermatozoa are highly specialized amoeboid cells that must acquire motility through the extension of a single pseudopod. Despite morphological and molecular differences with flagellated spermatozoa (including a non‐actin‐based cytoskeleton), nematode sperm must also respond to cues present in the female reproductive tract that render them motile, thereby allowing them to locate and fertilize the egg. The factors that trigger pseudopod extension in vivo are unknown, although current models suggest the activation through proteases acting on the sperm surface resulting in a myriad of biochemical, physiological, and morphological changes. Compelling evidence shows that pseudopod extension is under the regulation of physiological events also observed in other eukaryotic cells (including flagellated sperm) that involve membrane rearrangements in response to extracellular cues that initiate various signal transduction pathways. An integrative approach to the study of nonflagellated spermatozoa will shed light on the identification of unique and conserved processes during fertilization among different taxa. Mol. Reprod. Dev. 77: 739–750, 2010. © 2010 Wiley‐Liss, Inc.     

CAENORHABDITIS ELEGANS Fertilization-Defective Mutants with Abnormal Sperm

Seven new fertilization-defective mutants of C. elegans have been isolated and characterized; six are temperature sensitive, one is absolute and all are autosomal recessive. One mutation is in a previously described gene, while the other six define six new fer genes that appear to code for sperm-specific functions necessary for normal fertilization. In all fer mutants, both males and hermaphrodites accumulate sperm in near normal numbers. In hermaphrodites, mutant sperm contact the oocytes, but fail to fertilize them. Instead, the sperm are swept into the uterus by the passing oocytes and are expelled when oocytes are laid. Males of two fer mutants do not transfer sperm during copulation, but the other mutant males transfer sperm that fail to move to the spermatheca. Spermatozoa from fer-1 and fer-4 mutants are motility-defective in vitro as well as in vivo, and their pseudopods have an altered morphology. The period of development during which mutant hermaphrodites are temperature sensitive for fertility overlaps the time of sperm development. Some mutants are temperature sensitive throughout the entire period, and others are temperature sensitive during or just prior to spermiogenesis. In fer-4/+ and fer-7/+ males, the fertility of the mutation-bearing sperm is diminished, reducing the transmission ratio. This implies some post-meiotic expression of these genes.—This set of mutants provides a variety of functional and structural alterations in nematode sperm that should help identify and analyze gene products involved in sperm morphogenesis and motility.     

Characterization of Temperature-Sensitive, Fertilization-Defective Mutants of the Nematode CAENORHABDITIS ELEGANS

The isolation and characterization of three Caenorhabditis elegans temperature-sensitive mutants that are defective at fertilization are described. All three are alleles of the gene fer-1. At the restrictive temperature of 25 degrees, mutant hermaphrodites make sperm and oocytes in normal numbers. No oocytes are fertilized, although they pass through the spermatheca and uterus normally. The oocytes can be fertilized by sperm transferred by wild-type males, indicating that the mutant defect is in the sperm. The temperature-sensitive period for the mutants coincides with spermatogenesis. Sperm made by mutants at 25 degrees cannot be distinguished from wild-type sperm by light microscopy. The sperm do contact oocytes in mutant hermaphrodites, but do not fertilize. Mutant sperm appear to be nonmotile. Mutant males are also steril when grown at 25 degrees. They trnasfer normal numbers of sperm to hermaphrodites at mating, but these sperm fail to migrate to the spermatheca and are infertile. The phenotype of these mutants is consistent with a primary defect in sperm motility, but the cause of this defect is not known.     

A new model of reticulopodial motility and shape: evidence for a microtubule-based motor and an actin skeleton

Cytoskeletal inhibitors were used as probes to test the involvement of microtubules and actin microfilaments in the development, motility, and shape maintenance of the pseudopodial networks (i e, reticulopodia) of the foraminifers Allogromia sp strain NF and Allogromia laticollaris. Agents that disassemble cytoplasmic microtubules (cold, colchicine, and nocodazole) arrest all movement but have variable effects on reticulopodial shape. Electron microscopy reveals a granulofibrillar matrix but few, if any, microtubules in these motility-arrested reticulopods. Allogromiids treated with cytochalasin B or D lose substrate adhesion and undergo dramatic changes in shape and motile behavior, highlighted by the coalescence of reticulopodial cytoplasm into irregularly shaped bodies with chaotic motility. Serial semithick sections of such preparations, viewed by high-voltage electron microscopy, document a striking rearrangement of microtubules within these cytochalasin-induced bodies. All aspects of cytochalasin-altered motility are completely inhibited by colchicine. Actin is present in reticulopodia, as determined by staining with rhodamine-phalloidin; this staining is not observed in cytochalasin-treated organisms. These data provide compelling evidence that microtubules are required for reticulopodial motility. An actin-based cytoskeleton is thought to play a role in maintaining shape, mediating pseudopod/substrate adhesion, and coordinating the various microtubule-dependent processes.     

The location of the major protein in Caenorhabditis elegans sperm and spermatocytes

Using an affinity-purified antibody to the major sperm protein (MSP) in Caenorhabditis elegans sperm we have shown by immunofluorescence that the MSP is localized in the fibrous bodies of spermatocytes and early spermatids, in the cytoplasm of late spermatids, and in the pseudopods of spermatozoa. The MSP can also form crystalline inclusions in mutant and wild-type sperm. The function of this protein is still unknown, but its ability to form filaments and its localization in the pseudopod, together with the lack of actin in these sperm suggest that the MSP may be required for amoeboid motility.     

Re-expression of ABP-120 rescues cytoskeletal, motility, and phagocytosis defects of ABP-120- Dictyostelium mutants.

The actin binding protein ABP-120 has been proposed to cross-link actin filaments in nascent pseudopods, in a step required for normal pseudopod extension in motile Dictyostelium amoebae. To test this hypothesis, cell lines that lack ABP-120 were created independently either by chemical mutagenesis or homologous recombination. Different phenotypes were reported in these two studies. The chemical mutant shows only a subtle defect in actin cross-linking, while the homologous recombinant mutants show profound defects in actin cross-linking, cytoskeletal structure, pseudopod number and size, cell motility and chemotaxis and, as shown here, phagocytosis. To resolve the controversy as to what the ABP-120- phenotype is, ABP-120 was re-expressed in an ABP-120- cell line created by homologous recombination. Two independently "rescued" cell lines that express wild-type levels of ABP-120 were analyzed. In both rescued cell lines, actin incorporation into the cytoskeleton, pseudopod formation, cell morphology, instantaneous velocity, phagocytosis, and chemotaxis were restored to wild-type levels. There is no alteration in the expression levels of several related actin binding proteins in either the original ABP-120- cell line or in the rescued cell lines, leading to the conclusion that neither the aberrant phenotype observed in ABP-120- cells nor the normal phenotype reasserted in rescued cells can be attributed to alterations in the levels of other abundant and related actin binding proteins. Re-expression of ABP-120 in ABP-120- cells reestablishes normal structural and behavioral parameters, demonstrating that the severity and properties of the structural and behavioral defects of ABP-120- cell lines produced by homologous recombination are the direct result of the absence of ABP-120.