Regional differentiation of the sperm surface as studied with 125I- diiodofluorescein isothiocyanate, an impermeant reagent that allows isolation of the labeled components

The regional differentiation of the sperm surface has been studied with the aid of a novel covalent labeling technique that permits concurrent cytological, biochemical, and immunological analyses. For these studies isothiocyanate derivatives of fluorescein (FITC) and diiodofluorescein (IFC) were employed: the latter can be prepared with radioiodine to high specific activity (125IFC) and is an impermeant reagent for the erythrocyte surface. Sperm of sea urchin (Strongylocentrotus purpuratus), medaka )Oryzias latipes), and golden hamster bind the fluorescent chromophores with a nonuniform distribution, most of the fluorescence being associated with the midpiece. The radioactive derivative 125IFC permits an analysis of the proteins that are responsible for most of the binding. Additionally, 125 IFC-labeled sperm are capable of fertilizing eggs, as assessed by autoradiography. That IFC labels the surface of the sperm was inferred from the following: (a) the labeling of the surfaces of other cells by fluorescein isothiocyanate and its derivatives; (b) the agglutination of labeled sperm by antibodies directed against IFC; (c) the use of peroxidase-dependent immunocytochemical reaction using anti-IFC antibodies, with analysis by electron microscopy; and (d) extraction of labeled sea urchin sperm with Triton X-100 under conditions that preferentially solubilize the plasma membrane. The antiserum directed against IFC was used to isolate the labeled surface components from Triton X-100 extracts of whole sperm, by immunoprecipitation, with Staphylococcus-A protein serving as a coprecipitant. The results support previous data showing that the sperm surface is a heterogeneous mosaic of restricted domains, one notable zone being the midpiece, where common molecular properties may be shared by sperm with distinctly different morphologies. In addition, IFC-mediated covalent alteration of specific cell surface proteins may be used to label, to identify, and, with the use of anti-IFC antibodies, to isolate such proteins from other cellular constituents.     

Sperm surface proteins persist after fertilization

Certain sperm components labeled with fluorescein isothiocyanate or its radioactive derivative, 125I-diiodofluorescein isothiocyanate (125IFC), are transferred at fertilization to the egg, where they persist throughout early cleavage stages at a localized site in the embryo cytoplasm (Gabel, C. A., E. M. Eddy, and B. M. Shapiro, 1979, Cell, 18:207-215; Gundersen, G. G., C. A. Gabel, and B. M. Shapiro, 1982, Dev. Biol., 93:59-72). By using image intensification we have extended these observations in the sea urchin to the pluteus larval stage, in which greater than 60% of the embryos have localized fluorescent sperm components. Because of the unusual persistence of the sperm components in the embryo, a characterization of the nature of the labeled species in sea urchin sperm was undertaken. Approximately 10% of the 125IFC was in sperm polypeptides of Mr greater than 15,000. These proteins were on the sperm surface as shown by their sensitivity to externally added proteases. The remainder of the 125IFC in sperm was in several low- molecular-weight species, none of which was 125IFC-derivatized phospholipid. To determine if any labeled sperm polypeptides remained intact in the embryo after fertilization, 125IFC-labeled sperm proteins were recovered from one-cell and late gastrula stage embryos by using an anti-IFC immunoadsorbent. Most of the labeled sperm proteins were degraded shortly after fertilization; however, distinct sets of labeled polypeptides were recovered from both one-cell and gastrula stage embryos. Six of the labeled polypeptides recovered from both embryonic stages had identical SDS gel mobilities as labeled sperm polypeptides. Other polypeptides in the embryos appeared to arise from limited proteolysis of sperm proteins. Thus, in this physiological cell fusion system, individual sperm proteins are transferred to the egg at fertilization, and some persist intact or after specific, limited degradation long after gamete fusion, until at least the late gastrula stage.     

Immunoassay of serum polypeptide hormones by using 125I-labelled anti(-immunoglobulin G) antibodies.

1. A technique for indirectly labelling antibodies to polypeptide hormones, by combining them with radioactively labelled anti-(immunoglobulin G) is described. (a) 125I-labelled anti-(rabbit immunoglobulin G) and anti-(guinea-pig immunoglobulin G) antibodies with high specific radioactivity were prepared after purification of the antibodies on immunoadsorbents containing the respective antigens. (b) Rabbit immunoglobulin G antibodies to human growth hormone, porcine glucagon and guinea-pig immunoglobulin G antibodies to bovine insulin and bovine parathyroid hormone were combined with immunoadsorbents containing the respective polypeptide hormone antigen. (c) The immunoglobulin G antibodies to the polypeptide hormones were reacted with 125-I-labelled anti-(immunoglobulin G) antibodies directed against the appropriate species of immunoglobulin G,and the anti-hormone antibodies were combined with the hormone-containing immunoadsorbent. (d) 125I-labelled anti-(immunoglobulin G) antibodies and anti-hormone antibodies were simultaneously eluted from the hormone-containing immunoadsorbent by dilute HCl, pH 2.0. After elution the anti-(immunoglobulin G) antibodies and antihormone antibodies were allowed to recombine at pH 8.0 and 4 degrees C. 2. The resultant immunoglobulin G-anti-immunoglobulin G complex was used in immunoradiometric (labelled antibody) and two-site assays of the respective polypeptide hormone. 3. By using these immunoassays, concentrations down to 90pg of human growth hormone/ml, 100 pg of bovine insulin/ml, 80 pg of bovine parathyroid hormone/ml and 150 pg of glucagon/ml were readily detected. Assays of human plasma for growth hormone and insulin by these methods showed good agreement with results obtained by using a directly 125I-labelled anti-hormone antibody in an immunoradiometric assay of human growth hormone or by radioimmunoassay of human insulin. 4. The method described allows immunoradiometric or two-site assays to be performed starting with as little as 450 ng of polypeptide hormone-antibody protein. An additional advantage of the method is that a single iodination of the readily available antibodies to immunoglobulin G allows the establishemnt of several polypeptide hormone assays     

After fertilization, sperm surface components remain as a patch in sea urchin and mouse embryos

Sea urchin and mouse sperm that are labeled on their surfaces with fluorescein isothiocyanate (FITC), tetramethylrhodamine isothiocyanate (TMRTC) or 125I-diiodofluorescein isothiocyanate (125IFC) remain viable and can fertilize eggs. When sea urchin eggs were fertilized with 125IFC-labeled sperm, the radioactivity from the sperm was quantitatively transferred to the egg (at a ratio of one sperm equivalent per egg) and persisted in the embryo as it developed to the pluteus larval state (5 days at 12 degrees C). The radioactivity was acid-precipitable and was associated with the particulate fraction of embryo homogenates. In addition, FITC-labeled sea urchin sperm were used to fertilize eggs, and the labeled components were followed by fluorescence microscopy. In the embryo, labeled sperm components were present as a discrete patch that was partitioned unequally during early cleavages. In experiments using mouse sperm labeled with TMRTC, the labeled sperm components were also transferred to the embryo as a discrete patch that was again distributed unequally after cleavage. This physiological cell fusion system therefore has distinctive characteristics: there is limited lateral mobility of surface components, which have a low turnover rate unlike that see in other systems. In this paper, we discussed the possible morphogenetic role of this unusual behavior.     

Covalent linkage of 125I-insulin to a cytosolic insulin-degrading enzyme

Cytosol extracts high in insulin-degrading activity were cross-linked to 125I-insulin with the bifunctional cross-linker disuccinimidyl suberate. With cytosols from either rat muscle, liver, kidney or brain or human erythrocytes, only a single protein (Mr = 110,000) was specifically labeled. Three different lines of evidence indicated that this labeled protein is insulin-degrading enzyme, a cysteine protease which accounts for most of the insulin-degrading activity in cell extracts. Firstly, the cross-linking of 125I-insulin to this protein is inhibited by unlabeled insulin over the same concentration range of insulin which inhibits degradation. Separated insulin A and B chain were less potent at inhibiting cross-linking, whereas bovine serum albumin and cytochrome c were without effect. Secondly, antibodies to purified insulin-degrading enzyme precipitated the labeled protein in parallel with their ability to precipitate the insulin-degrading activity of the extracts. Thirdly, when the insulin-degrading activity was purified 40,000-fold from erythrocytes, this Mr 110,000 protein co-purified. These results indicate that cross-linking 125I-insulin may be a convenient method for labeling the insulin-degrading enzyme.     

Characterization of radiolabeled components of human sperm surface and seminal plasma

Externally oriented components on the human sperm cell surface and components in human seminal plasma were labeled by enzymatic iodination with lactoperoxidase and [¹²⁵I] NaI. SDS-7.5% PAGE of labeled sperm surface resolved one minor and four major components with approximate molecular weights of 92, 72, 46, 30, and 20K daltons, respectively. SDS-7.5% PAGE of labeled seminal plasma resolved five components with approximate molecular weights of 74, 51, 43, 28, and 20K daltons. Three of the five moieties seen on the sperm surface and in seminal plasma were similar in molecular weight. This suggested that these surface components were adsorbed from seminal secretions. Because the iodination procedure used labels both proteins and lipids, labeled sperm surface and labeled seminal plasma were subjected to isopycnic density gradient centrifugation to identify the chemical composition of the radioiodinated components. With human sperm surface, two areas of radioactivity were resolved in CsCl gradients, one corresponding to protein and the other to lipid. With human seminal plasma, only one area of radioactivity, corresponding to protein, was identified. Electrophoretic analysis of each peak of radioactivity obtained from the gradients demonstrated that all of the sperm surface and four of five seminal plasma components were in the protein fractions. All three of the seminal plasma components which correspond to sperm surface components were recovered in the protein fraction. This observation supports our hypothesis that some of the proteins labeled on the human sperm cell surface are adsorbed from seminal secretions.     

Synthesis and secretion of proteins by perifused caput epididymal tubules, and association of secreted proteins with spermatozoa

We have used perifusion organ culture of proximal and distal caput epididymal tubules of the rat to study the secretion of proteins by epididymal epithelium and uptake of the luminal radioactive proteins by sperm. The amount of incorporation of L-[35S]methionine into luminal fluid proteins was time dependent and completely inhibited by cycloheximide. The association of labeled proteins with cultured sperm was also dependent on time and continuous, with sperm still acquiring labeled luminal proteins after protein synthesis was arrested. A Mr = 46,000 molecule was found to be heavily labeled in luminal fluid and sperm extracts. Fluorograms of all L-[35S]methionine extracts immunoprecipitated using an antiepididymal alpha-lactalbumin antibody (Klinefelter and Hamilton, 1984) showed labeling of an Mr = 18,000 molecule and, in addition, the Mr = 46,000 molecule, but immunostaining was specific only for the Mr = 18,000 molecule and the heavy chain of the immunoglobulin. We suggest that the Mr = 46,000 molecule may be galactosyltransferase. Galactose oxidase-NaB[3H]4 labeling of the cultured caput sperm cell surface revealed a Mr = 23,000 molecule that was able to be immunoprecipitated with antiepididymal alpha-lactalbumin antibody. Our data suggest that this cell surface molecule is similar to one component of the fluid epididymal alpha-lactalbumin-like complex and, in addition, show that glycosylation of the sperm surface can occur in the caput epididymidis.     

Spatially distinct allodeterminants of the H-2Kk molecule as detected by monoclonal anti-H-2 antibodies

In an attempt to delineate spatial relationships between various allodeterminants of cell surface MHC antigens, competitive binding studies were performed using 4 different monoclonal antibodies, each of which reacted with the H-2Kk antigen but with different serologic specificities. Competition was studied by examining the effect of unlabeled antibodies on the binding of each 125I-labeled antibody to spleen cells of the H-2a haplotype. Mutual inhibition was observed between 2 of the antibodies, and a 3rd antibody of lower affinity was inhibited by the first 2 antibodies but did not itself inhibit the binding of these antibodies. The 4th antibody did not block the binding of the other 3 labeled antibodies, and binding of this 4th labeled antibody was only partially inhibitable by the other 3 antibodies. These results indicate the presence of at least 2 spatially distinct allodeterminants on H-2Kk molecules expressed on the cell surface.     

Surface changes in chimpanzee sperm during epididymal transit

Intact chimpanzee caput and cauda epididymal sperm, sperm cell lysates, and caput and cauda epididymal fluid were radiolabeled by enzymatic iodination with lactoperoxidase and Na125 I and were compared by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis. Caput epididymal sperm showed nine labeled macromolecular components of 90, 64, 56, 48, 38, 31, 20, 18 and 16 Kd and cauda epididymal sperm showed eleven macromolecular components of 90, 64, 55, 47, 42, 33, 27, 18, 17, 15 and 11 Kd. Six of the components labeled on caput sperm (90, 64, 56, 48, 18 and 16 Kd) were detected in equal amounts of cauda sperm and two (38 and 20 Kd) were detected at greatly reduced labeling intensities. In the cauda epididymidis, four new components (33, 27, 17 and 11 Kd) became prominent features of the sperm surface. Analysis of labeled caput and cauda sperm cell lysates resolved components distinct from those detected on sperm surfaces. Electrophoresis of caput epididymal fluid showed five labeled components of 66, 56, 47, 41 and 37 Kd, while electrophoresis of cauda epididymal fluid showed eight labeled components of 92, 66, 56, 48, 31, 27, 24 and 11 Kd. Three components (66, 56 and 47 Kd) were present in both caput and cauda fluid, two (41 and 37 Kd) in caput fluid only, and five (92, 31, 27, 24 and 11 Kd) in cauda fluid only. Components of 37 Kd were labeled in caput fluid and on caput sperm but not on cauda sperm, whereas components of 27 Kd and 11 Kd were labeled in cauda fluid and on cauda sperm but not on caput sperm. These data show that chimpanzee sperm undergo extensive surface modifications during epididymal maturation and that some of these modifications may be related to exogenous proteins/glycoproteins in epididymal fluids.     

Identification of human sperm surface glycoproteins recognized by autoantisera from immune infertile men, women, and vasectomized men

To identify the surface antigens of human sperm recognized by antisera from immune infertility patients and vasectomized men, we labeled sperm surface proteins with 125I- and used patient antisera for immunoprecipitation. Sera were studied from 27 infertile males, 18 infertile females, and 4 vasectomized males, each possessing anti-sperm antibodies detected by immunobead binding. Sera from different infertile males, different infertile females, and vasectomized males were remarkably similar in their surface antigen recognition. The different sera specifically immunoprecipitated the same small group of 125I-labeled surface proteins, which included polypeptides in the region 90 kDa, 40-45 kDa, and 26 kDa. Treatment with N-glycanase showed that the proteins of 90 kDa, 40-45 kDa, and 26 kDa were glycoproteins with N-linked carbohydrate. The immunoprecipitated 125I-labeled proteins and the total extract of 125I-labeled surface proteins were compared on two-dimensional (2D) gels. The results show the 90 kDa polypeptide is a major sperm surface component, whereas 40-45 kDa and 26 kDa polypeptides are minor components. The 2D gel comparison also indicates that 90 kDa, 40-45 kDa, and 26 kDa are a small subset of the total ensemble of sperm surface proteins. Clinical data suggest antibodies to these few proteins interfere with sperm function.     

Immunoelectron microscope localization of snRNP,hnRNP, and ribosomal proteins in mouse spermatogenesis

We have studied the ultrastructural distribution of heterogeneous nuclear ribonucleoproteins (hnRNPs), small nuclear ribonucleoproteins (snRNPs), and ribosomal proteins during mouse spermatogenesis and spermiogenesis by means of specific antibodies and immunocytochemistry. All the above components were detectable from primary spermatocytes until the spermatid elongation phase, when the RNA synthetic activity is known to cease. Ribosomal protein (P1/P2 and L7) labeling disappeared as early as during the acrosome phase, and nucleoli were no longer labeled even during the cap phase. The nucleoplasmic structures labeled with the different anti-nucleoplasmic RNP immunoprobes corresponded, until the acrosome phase, to those previously observed as targets of the same antibodies in the nucleoplasm of somatic cell nuclei. Clusters of interchromatin granules of spermatocyte and early spermatid nuclei exhibit some labeling for hnRNP when compared with nuclei of Sertoli cells or previously analyzed liver or tissue culture cells, where these structural constituents usually remain weakly labeled or unlabeled. In spermatids in step 10, another type of nuclear granule, resembling perichromatin granules, but occurring in aggregates, can be observed. These structural constituents were labeled with antibodies recognizing nucleoplasmic snRNP antigens and therefore suggesting a non-nucleolar origin of these granules. Finally, we have observed nucleoplasmic areas of fibrogranular material, occurring only in primary spermatocytes. These components were labeled with anti-ribosomal protein antibodies but did not contain either hnRNPs or snRNPs. © 1993 Wiley-Liss, Inc.     

An intermediate state of fertilization involved in internalization of sperm components

The pathway of sperm entry during sea urchin fertilization was analyzed by using sperm covalently labeled with fluorescent and radioactive tracers. Sperm that have been covalently labeled on their surfaces with fluorescein isothiocyanate (FITC) or a radioactive congener, diiodofluorescein isothiocyanate (¹²⁵IFC), transfer labeled components to the egg that persist throughout early development. In order to study the transfer of sperm components and their fate after fertilization, cytochalasin B-dependent inhibition of fertilization, previously shown to permit the cortical reaction of sea urchin eggs but block sperm pronuclear incorporation, was investigated. Under certain conditions cytochalasin B or D (CB or CD) results in about half of the activated eggs having both the sperm nucleus and the fluorescently labeled sperm components arrested apparently at the level of the egg plasma membrane. This arrest of internalization was reversed by removal of CB or CD, and the sperm derivatives entered the egg. When sperm were labeled noncovalently with ethidium bromide or rhodamine 123, fluorescence was transferred to the egg in the cytochalasin-inhibited state in a fashion similar to that found in normal fertilization; in both cases the sperm fluorescence disappeared within a few minutes of fertilization, due to the repartitioning of the noncovalent dyes into the egg cytoplasm. It is concluded that cytochalasin arrests fertilization at an intermediate step in which the sperm has fused with the egg to achieve cytoplasmic continuity, but in which the subsequent internalization of sperm components is inhibited. After removal of cytochalasins the fluorescent sperm components move from the egg surface to an internal site, a process that can be monitored by time-lapse video microscopy with an image intensifier to permit extended observations of sperm fluorescence. The cytoplasmic location of labeled sperm components was substantiated by autoradiography of early embryos fertilized with ¹²⁵IFC-labeled sperm; transfer of sperm components to an internal site was seen after fertilization of either sea urchin or mouse eggs. Taken together, the data suggest that the fate of the labeled sperm surface components, as well as that of the sperm nucleus, is to be transferred to the egg cytoplasm, and that this transfer is mediated by the actin-dependent cytoskeleton of the egg.     

Purification of ornithine aminotransferase by immunoadsorption

Ornithine aminotransferase was purified by conventional biochemical methods from rat kidney, rat liver, and human liver. Affinity-purified antibodies raised to the rat kidney enzyme were used to produce an immunoadsorbent enabling a one-step purification of ornithine aminotransferase to be made from crude human liver extracts. The harsh chemical conditions often required to desorb immunoadsorbents were avoided by isolating antibodies with low functional affinity and employing an electrophoretic desorption method which allowed the enzyme activity to be retained. The close structural similarity between human and rat ornithine aminotransferase was demonstrated by immunodiffusion reactions. It was therefore possible to purify the enzyme from human liver using immobilized antibodies raised against rat kidney ornithine aminotransferase. Furthermore, desorption was more readily achieved due to the lower affinity for the human enzyme.     

AUTORADIOGRAPHIC ANALYSIS ON AGAR PLATES OF ANTIGENS FROM SUB CELLULAR FRACTIONS OF RAT LIVER SLICES

Slices of rat livers were incubated with 14C amino acids, homogenized, and subjected to differential centrifugation. The microsomes were further extracted with the non-ionic detergent Lubrol W and with EDTA. These extracts and the microsome free "cell sap," freed from the pH 5 precipitable fraction, were subsequently reacted with antisera using agar diffusion techniques. The antisera employed were obtained from rabbits injected with different subcellular fractions of rat liver or with rat serum proteins. When the agar diffusion plates were autoradiographed it was found that some of the precipitates were radioactive while others were not. Control experiments indicated that this labeling was due to the specific incorporation of ¹⁴C amino acids into various rat liver antigens during incubation of the slices rather than to a non-specific adsorption of radioactive material to the immunological precipitates. When the slices were incubated with the isotope for up to 30 minutes, the serum proteins which could be extracted from the microsomes with the detergent were strongly labeled, as were a number of additional microsomal antigens of unknown significance. In contrast, the serum proteins present in the cell sap were only weakly labeled. Most of the typical cell sap proteins, both those precipitable and those soluble at pH 5, seemed to remain unlabeled. No consistently reproducible results were obtained with the EDTA extracts of the ribosomal residues remaining after extraction of the microsomes with the detergent. Incubation of the liver slices for longer periods (up to 120 minutes) led to a strong labeling of the serum proteins in the cell sap as well as to the appearance of labeling in additional cell sap proteins. The results are discussed with regard to the subcellular site of synthesis and the metabolism of the different antigens.     

Analysis of tegumental surface proteins of Schistosoma mansoni primary sporocysts

Axenically transformed primary sporocysts of Schistosoma mansoni (NMRI strain) were labeled with 125I in an effort to identify sporocyst proteins exposed at the tegumental surface. Using the 125I activating reagent, 1,3,4,6-tetrachloro-3 alpha,6 alpha-diphenylglycoluril, in conjunction with SDS-PAGE and autoradiography, up to 12 bands were radiolabeled out of 60 components visualized by silver staining. Labeled proteins ranged in apparent Mr from greater than 200 to less than 12 kDa. Pronase treatment of living sporocysts after radioiodination removed all labeled material, suggesting that only surface proteins were being iodinated. Western blot analysis employing 5 monoclonal antibodies (MAB's) to sporocyst surface antigens revealed a wide range of reactivities which produced banding patterns closely reflecting autoradiograms of identical samples. The concomitant removal by Pronase of immunoreactive and radiolabeled surface proteins with identical Mr in the range of 90-130 kDa suggests that epitopes recognized by these antibodies are associated with these higher molecular weight surface proteins. However, although Pronase removes all labeled surface proteins, substantial nonradiolabeled, immunoreactive material with Mr less than 90 kDa still remains on enzyme-treated parasites. This indicates that MAB-reactive epitopes, in addition to their occurrence with surface proteins, are also associated with either unlabeled, protease-resistant surface components or internal antigens. The immunohistochemical localization of antibody-reactive material in gland-like structures within sporocysts supports an internal source for nonradiolabeled, immunoreactive components. Finally, the periodate sensitivity of the epitopes recognized by all tested MAB's suggests that carbohydrate moieties may represent a common and extremely immunogenic constituent of the sporocyst surface.(ABSTRACT TRUNCATED AT 250 WORDS)     

Dipetalonema viteae: Extraction and immunogenicity of cuticular antigens from female worms

The surface of adult female Dipetalonema viteae filarial worms was labeled with ¹²⁵I using 1,3,4,6-tetrachloro-3α, 6α-diphenylglycoluril as an iodinating reagent. Ultrastructural autoradiographs showed specific labeling of only the outermost cuticular layers. Surface-labeled worms were homogenized and were extracted with phosphate-buffered saline followed by NaOH. These extracts contained only minor amounts of radioactive TCA-precipitable material. Proteolytic digestion of the remaining sediment either with proteinase K, or thermolysin or subtilisin solubilized about 60% of the radioactive material of which 30% was TCA precipitable. Golden hamsters were injected with proteolytic extracts of unlabeled female worms. Subtilisin and thermolysin extracts provoked antibodies against somatic structures (e.g., gut, uterus, muscles) but not against the cuticle, whereas immunization with the proteinase K extract induced antibodies exclusively against cuticular and hypodermic structures of female and male worms.     

Surface receptors: Are they involved in transformation of spermatozoa of Ascaris?

Exposure of the spheroidal spermatozoa of Ascaris suum to an extract of the male accessory gland causes their transformation into ameboid cells. We have investigated the mechanism of this transformation, also termed activation, by labeling the proteins of accessory gland extracts with fluorescein isothiocyanate (FITC) or [125I], followed by qualitative localization of the sperm activating substances (SAS) and quantitative measurements of [125I]-SAS binding. Fluorescent patches of FITC-conjugated SAS were localized at the spermatozoan surface and were concentrated primarily at the posterior region. Few fluorescent patches were detectable in the region of the newly formed pseudopodia following transformation. Although spermatozoan transformation occurs within 2-5 min after exposure to SAS, the fluorescent patches became more distinct after a minimum of 8 min and reached maximum density at 15-30 min. Spermatozoa activated with [125I]-SAS became radioactively labeled in direct proportion to the amount of available [125I]-SAS until a saturation level was reached. SDS-polyacrylamide gel electrophoresis combined with autoradiography indicated that the cells bind two SAS components, of small (9,000 MW) and large (56,000 MW) sizes. These same two components were also detectable in a membrane fraction, obtained by differential centrifugation, of the spermatozoa after incubation with [125I]-SAS. binding of the two SAS components was not inhibited by preincubation of the spermatozoa with trypsin or Concanavalin A; however, the 56,000 MW component of SAS was not detectable in autoradiograms of spermatozoa incubated with periodic acid (1.6-10 mM) treated SAS. Such cells also failed to transform into ameboid spermatozoa. These results indicate that the two components of SAS that bind to the spermatozoan surface are possibly responsible for inducing the cell transformations associated with activation.     

Identification of lipopolysaccharide-binding proteins in 70Z/3 cells by photoaffinity cross-linking

A radioiodinated, photoactivatable derivative of Salmonella minnesota Re595 lipopolysaccharide (LPS) was used to label LPS-binding proteins in 70Z/3 cells. The labeled proteins were resolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and visualized by autoradiography. 125I-Labeled-2-(p-azidosalycylamido)1,3'-dithiopropionamide S. minnesota Re595 LPS (125I-ASD-Re595) labeled a limited number of proteins. The most prominent of these had a apparent molecular mass of 18 kDa. Less prominent labeling of 25- and 28-kDa proteins was also seen. Labeling was saturated by 5 micrograms/ml 125I-ASD-Re595 and was inhibited by a 10-100-fold excess of unlabeled LPS or lipid A. Labeling was maximal within 30 min at 37 degrees C; much less labeling occurred at lower temperatures. The proteins labeled with 125I-ASD-Re595 appear to be on the surface of the cell, since they can be digested by trypsin and were found in the membrane fraction of the cell but not in the cytosol. Studies with competitive inhibitors suggested that the proteins bind to the lipid A region of the LPS molecule. Biologically inactive lipid A analogs were poor inhibitors of labeling, suggesting that the LPS-binding proteins could discriminate between active lipid A and inactive analogs. These studies suggest that the 18- and 25-kDa proteins bind specifically to the lipid A region of the LPS molecule and should be considered as candidates for a functional LPS receptor.     

Identification of a lipid-anchored heparan sulfate proteoglycan in Schwann cells

Schwann cells synthesize both hydrophobic and peripheral cell surface heparan sulfate proteoglycans (HSPGs). Previous analysis of the kinetics of radiolabeling suggested the peripheral HSPGs are derived from the membrane-anchored forms (Carey, D., and D. Evans. 1989. J. Cell Biol. 108:1891-1897). Peripheral cell surface HSPGs were purified from phytic acid extracts of cultured neonatal rat sciatic nerve Schwann cells by anion exchange, gel filtration, and laminin-affinity chromatography. Approximately 250 micrograms of HSPG protein was obtained from 2 X 10(9) cells with an estimated recovery of 23% and an overall purification of approximately 2000-fold. SDS-PAGE analysis indicated the absence of non-HSPG proteins in the purified material. Analysis of heparinase digestion products revealed the presence of at least six core protein species ranging in molecular weight from 57,000 to 185,000. The purified HSPGs were used to produce polyclonal antisera in rabbits. The antisera immunoprecipitated a subpopulation of 35SO4- labeled HSPGs that were released from Schwann cells by incubation in medium containing phosphatidylinositol-specific phospholipase C (PI- PLC); smaller amounts of immunoprecipated HSPGs were also present in phytic acid extracts. In the presence of excess unlabeled PI-PLC- released proteins, immunoprecipitation of phytic acid-solubilized HSPGs was inhibited. SDS-PAGE analysis of proteins immunoprecipitated from extracts of [35S]methionine labeled Schwann cells demonstrated that the antisera precipitated an HSPG species that was present in the pool of proteins released by PI-PLC, with smaller amounts present in phytic acid extracts. Nitrous acid degradation of the immunoprecipitated proteins produced a single 67,000-Mr core protein. When used for indirect immunofluorescence labeling, the antisera stained the external surface of cultured Schwann cells. Preincubation of the cultures in medium containing PI-PLC but not phytic acid significantly reduced the cell surface staining. The antisera stained the outer ring of Schwann cell membrane in sections of adult rat sciatic nerve but did not stain myelin or axonal membranes. This localization suggests the HSPG may play a role in binding the Schwann cell plasma membrane to the adjacent basement membrane surrounding the individual axon-Schwann cell units.     

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.