Microfilament association of ASGP-2, the concanavalin A-binding glycoprotein of the cell-surface sialomucin complex of 13,762 rat mammary ascites tumor cells

Microfilament-associated proteins and membrane-microfilament interactions are being investigated in microvilli isolated from 13,762 rat mammary ascites tumor cells. "Phalloidin shift" analyses on velocity sedimentation gradients of Triton X-100 extracts of [3H]-glucosamine-labeled microvilli identified a 120-kDa cell-surface glycoprotein associated with the microvillar microfilament core. The identification was verified by concanavalin A (Con A) blots of one- and two-dimensional (2D) electrophoresis gels of sedimented microfilament cores. By 2D-electrophoresis and lectin analyses the 120-kDa protein appeared to be a fraction of ASGP-2, the major Con A-binding glycoprotein of the sialomucin complex of the 13,762 cells. This identity was confirmed by immunoblot analyses using immunoblot-purified anti-ASGP-2 from anti-membrane serum prepared against microvillar membranes. Proteolysis of the microvilli with subtilisin or trypsin resulted in an increase in the amount of ASGP-2 associated with the microfilament cores. An increase was also observed with sialidase treatment of the microvilli, suggesting that negative charges, probably present on the highly sialated sialomucin ASGP-1 of the ASGP-1/ASGP-2 sialomucin complex, reduce ASGP-2 association with the microfilament core. Proteolysis of isolated microvillar membranes, which contain actin but not microfilaments, also increased the association of ASGP-2 with a Triton-insoluble, actin-containing membrane fraction. Purified ASGP-2 does not bind to microfilaments in sedimentation assays. Since the Triton-insoluble membrane residue is enriched in an actin-containing transmembrane complex, which contains a different glycoprotein, we suggest that the ASGP-2 is binding indirectly via this complex to the microfilament core in the intact microvilli.     

Membrane-microfilament interactions in ascites tumor cell microvilli. Identification and isolation of a large microfilament-associated membrane glycoprotein complex

[14C]Glucosamine metabolic labeling and concanavalin A blots were used to identify four major glycoprotein species associated with ascites tumor cell microvillar microfilament cores and with a transmembrane complex containing actin. Phalloidin shift analysis of glucosamine-labeled microvilli showed that glycoproteins of 110-120, 80, 65, and 55 kDa are stably associated with the microfilament cores. Analysis of large (greater than 10(6) kDa) transmembrane complexes from microvillar membranes made under microfilament-depolymerizing conditions (Carraway, C. A. C., Jung, G., and Carraway, K. L. (1983) Proc. Natl. Acad. Sci. U. S. A. 80, 430-434) revealed glycoproteins of the same Mr values, showing the same relative staining or labeling patterns as those observed with the microfilament cores. Gel filtration of high salt, high pH extracts of intact microvilli, microfilament cores, or transmembrane complexes showed that in all of these fractions the glycoproteins are associated in a very large, stable complex. The glycoprotein multimer was isolated essentially free of actin and other components by Sephacryl S-1000 chromatography of microvilli, microvillar membranes prepared at pH 11, microfilament cores, or transmembrane complex fractions in Triton X-100, 1 M KCl, glycine, pH 9.5. Purified glycoprotein complex bound actin when incubated under polymerizing conditions. The presence of the glycoprotein heteromultimer in both microfilament cores and transmembrane complex from isolated membranes and the association of the purified glycoprotein complex with actin are consistent with our hypothesis that the glycoprotein-containing transmembrane complex is an association site for microfilaments at the plasma membrane.     

Strong association of bovine IgM with microvilli and their microfilament core from 13762 ascites tumor cells

Microfilament cores, obtained by extracting 13762 mammary ascites tumor cell microvilli with Triton X-100, contain a major glycoprotein migrating at an apparent molecular weight of 80 kDa by dodecyl sulfate-polyacrylamide gel electrophoresis. The 80-kDa component is a disulfide-linked multimer, as demonstrated by velocity sedimentation and agarose-acrylamide gel electrophoresis analyses under nonreducing conditions. This 80-kDa species is not metabolically labeled, as is a minor 80-kDa glycoprotein found in the cores, membranes, and an isolated transmembrane complex with actin. Antibodies prepared against the 80-kDa glycoprotein react strongly with bovine IgM and more weakly with rat IgM. These antibodies were used to demonstrate that the 80-kDa component is present in microvilli, microvillar microfilament cores, and microvillar membranes only if the microvilli are prepared in the presence of calf serum. The 80-kDa component, purified by velocity sedimentation in dodecyl sulfate, reacts with anti-rat IgM by immunoblot analyses. Moreover, immunoprecipitation of detergent extracts of microvilli with anti-rat IgM specifically sediments the 80-kDa component. The 80-kDa glycoprotein fractionates with the actin-containing transmembrane complex prepared by gel filtration of Triton-solubilized microvillar membranes. These results indicate that the disulfide-linked, multi-meric 80-kDa component is bovine IgM, which binds strongly to a cell-surface component of the microvilli, and is indirectly associated with the microfilament cores. Thus, the IgM provides a marker by which the transmembrane complexes to the microfilaments can be identified.     

Isolation of microvillar microfilaments and associated transmembrane complex from ascites tumor cell microvilli

The association of microvillar microfilaments with the microvillar membrane actin-containing transmembrane complex of MAT-C1 13762 ascites tumor cell microvilli has been investigated by differential centrifugation, gel electrophoresis and electron microscopy of detergent extracts of the isolated microvilli. Several methods have been used to reduce breakdown and solubilization of the microfilament core actin during the detergent extractions for preparation of microvillar core microfilaments. Gel electrophoresis of differential centrifugation fractions demonstrated that over 70% of the total microvillus actin could be pelleted with microfilament cores at 10 000 g under extraction conditions which reduce filament breakdown. Transmission electron microscopy (TEM) of all of the core preparations showed arrays of microfilaments and small microfilament bundles. The major protein components of the microfilament cores, observed by sodium dodecyl sulfate (SDS) electrophoresis, were actin and alpha-actinin. Among the less prominent polypeptide components was a 58 000 Dalton polypeptide (58 K), previously identified as a member of the MAT-Cl transmembrane complex. This three-component complex contains, in addition to 58 K, actin associated directly and stably with a cell surface glycoprotein (Carraway, CAC, Jung, G & Carraway, K L, Proc. natl acad. sci. US 80 (1983) 430). Evidence that the apparent association of complex with the microfilament core was not due simply to co-sedimentation was provided by myosin affinity precipitation. These results provide further evidence that the transmembrane complex is a site for the interaction of microfilaments with the microvillar plasma membrane.     

Topography and microfilament core association of a cell surface glycoprotein of ascites tumor cell microvilli

Membrane-microfilament interactions are being investigated in microvilli isolated from 13762 rat mammary ascites tumor cells. These microvilli are covered by a sialomucin complex, composed of the sialomucin ascites sialoglycoprotein-1 (ASGP-1) and the associated concanavalin A (Con A)-binding glycoprotein ASGP-2. Limited proteolysis of the microvilli releases large, highly glycosylated fragments of ASGP-1 from the microvilli and increases the association of ASGP-2 with the Triton-insoluble microvillar microfilament core (Vanderpuye OA, Carraway CAC, Carraway, KL: Exp Cell Res 178:211, 1988). To analyze the topography of ASGP-2 in the membrane and its association with the microfilament core, microvilli were treated with proteinase K for timed intervals and centrifuged. The pelleted microvilli were extracted with Triton X-100 for the preparation of microfilament cores and Triton-soluble proteins or with 0.1 M carbonate, pH 11, for the preparation of microvillar membranes depleted of peripheral membrane proteins. These microvilli fractions were analyzed by dodecyl sulfate gel electrophoresis, lectin blotting with Con A and L-phytohemagglutinin, and immunoblotting with anti-ASGP-2. The earliest major proteolysis product from this procedure was a 70 kDa membrane-bound fragment. At longer times a 60 kDa released fragment, 30-40 kDa Triton-soluble fragments, and 25-30 kDa membrane- and microfilament-associated fragments were observed. Phalloidin shift analysis of microfilament-associated proteins on velocity sedimentation gradients indicated that the 25-30 kDa fragments were strongly associated with the microfilament core. From these studies we propose that ASGP-2 has a site for indirect association with the microfilament core near the membrane on a 15-20 kDa segment.     

Plasma membrane-microfilament interaction in animal cells

Microfilament interactions with the plasma membranes of animal cells appear to vary with cell type and localization. In the erythrocyte, actin oligomers are associated with the membrane via spectrin and ankyrin. The ends of stress fibers in cultured cells, such as fibroblasts, are attached to the plasma membrane at focal adhesion sites and may involve the protein vinculin as a linking protein. In intestinal brush border microvilli a 110,000 dalton protein links the microfilament bundles to sites on the microvillus. A transmembrane complex containing actin stably associated with a cell surface glycoprotein can be isolated from ascites tumor cell microvilli and can be obtained still associated with microfilaments by gentle extraction and gradient centrifugation of the microvilli. These varied interaction mechanisms are believed to be needed to satisfy the different structural and dynamic requirements of the particular systems.     

Nonmuscle tropomyosin from ascites tumor cell microvilli

Tropomyosin has been isolated from microvilli preparations from 13762 rat mammary adenocarcinoma ascites tumor cells by Triton extraction and pelleting of the microvillar microfilament core, extraction of the microfilament core with 1 M KCl, heat treatment, and hydroxyapatite chromatography. Three major isoforms, designated 31K-a (acidic), 31K-b (basic), and 29K, were identified as tropomyosins by two-dimensional isoelectric focusing-dodecyl sulfate electrophoresis, a urea shift on dodecyl sulfate electrophoresis, chemical cross-linking, amino acid analysis, and molecular weight determinations. The native (60,000) and subunit (31,000 and 29,000) molecular weights, the amino acid composition, and the stoichiometry for binding to F-actin (actin/tropomyosin, 6:1) were typical of nonmuscle tropomyosins. The amount of tropomyosin present in the microvilli preparations is sufficient to saturate about half of the microvillar F-actin. By two-dimensional isoelectric focusing-dodecyl sulfate electrophoresis, the 31K isoforms appeared similar to isoforms of normal rat kidney cells but the 29K isoform was apparently smaller than any normal rat kidney isoforms. All three isoforms bound to F-actin, but the 29K form bound most strongly. Its behavior was similar to that of muscle tropomyosin, exhibiting saturable binding as a function of both ionic strength and Mg2+ concentration. In contrast, the 31K isoforms bound more weakly and required higher concentrations of Mg2+ for binding than that required for saturation with 29K (4 mM). These results clearly indicate that nonmuscle tropomyosin isoforms from a single source and location (subplasmalemmal) in the cell can exhibit different properties.     

Isolation of a calcium-sensitive, 35,000-dalton microfilament- and liposome-binding protein from ascites tumor cell microvilli: identification as monomeric calpactin

Microvilli isolated from the MAT-C1 ascites subline of the 13762 rat mammary adenocarcinoma contain a major calcium-sensitive microfilament-binding protein, AMV-p35 (ascites microvillar p35). Association of AMV-p35 with microfilament cores during Triton X-100 extraction of the microvilli is half-maximal at 0.1-0.2 mM calcium. The protein, which comprises 6% of the total microvillar protein, can be isolated from microfilament cores prepared in the presence of calcium by extraction with EGTA and purification by ion-exchange chromatography. Alternatively, the protein can be isolated from Triton extracts of microvilli prepared in the absence of calcium by precipitation with calcium, solubilization of the precipitate with EGTA, and chromatography on an ion-exchange column. AMV-p35 binds to phosphatidylserine liposomes and F-actin with half-maximal calcium concentrations of about 10 microM and 0.2 mM, respectively. Treatment of AMV-p35 with chymotrypsin yields a 33,000-dalton fragment, behavior similar to the tyrosine kinase substrates calpactins I and II and lipocortins I and II. Immunoblot analyses using antibodies directed against calpactin I, lipocortin I, and lipocortin II showed strong reactivity of AMV-p35 with anti-calpactin I and anti-lipocortin II, but little reactivity toward anti-lipocortin I. The close relationship between AMV-p35 and calpactin I was verified by amino acid sequence analyses of peptides isolated from cyanogen bromide digests of AMV-p35. By gel filtration and velocity sedimentation analyses purified AMV-p35 is a 35,000-dalton monomer. Moreover, AMV-p35 extracted directly from microvilli in Triton/EGTA also behaves as a 35,000-dalton menomer. These findings indicate that AMV-p35 is closely related to the pp60src kinase substrate calpactin I (p36). However, AMV-p35 occurs in the microvilli as a monomer rather than as the heterotetrameric calpactin found in several other cell types.     

Isolation of a domain of villin retaining calcium-dependent interaction with G-actin, but devoid of F-actin fragmenting activity

Villin is an F-actin binding protein located in the microfilament bundle of intestinal epithelial cell microvilli. Extensive in vitro proteolysis with Staphylococcus aureus V8 protease results in the production of a stable domain (apparent Mr 44000) which can be isolated due to its Ca2+-dependent interaction with G-actin bound to immobilized DNase-I, the standard procedure for the purification of villin. This 44-kDa fragment retains a single Ca2+ binding site with an apparent Kd = 2 X 10(-6) M, binds to G-actin, and inhibits the rate of actin polymerization. However, the 44-kDa domain does not shown any Ca2+-activated severing activity nor does it compete with villin for F-actin binding. These results suggest that villin contains three domains: headpiece containing an F-actin binding site, 44-kDa fragment containing a G-actin binding site, and an amino-terminal fragment responsible for the Ca2+-dependent severing activity.     

Phalloidin shift on velocity sedimentation sucrose gradient centrifugation for identification of microfilament-associated proteins

Velocity sedimentation by sucrose density gradient centrifugation has been used to characterize ascites microvillar microfilament cores and to identify microfilament-associated proteins. Fluoride, calcium, phalloidin and chemical cross-linking treatments of microvilli during Triton X-100 extractions increase the sedimentation rate of the microfilament core, compared with untreated control samples. Electrophoretic analyses of the distributions of actin, alpha-actinin and other microfilament-associated proteins across the gradients indicate that the primary mechanism for stabilization of the microfilament core is the reduction of fragmentation of the microfilaments. Significantly, alpha-actinin could be completely removed from the microfilaments by calcium treatment without causing a decrease in the size of the microfilament core. Because of the specificity of phalloidin in the stabilization of microfilaments, the shift on the gradients of microfilaments and their associated proteins in the presence of phalloidin provides a diagnostic tool for the identification of microfilament-associated proteins. This phalloidin shift technique should have widespread utility in the analysis of actin forms and microfilament-associated proteins from complex cell fractions.     

Villin is a major protein of the microvillus cystoskeleton which binds both G and F actin in a calcium-dependent manner

The cores of the microvilli present on intestinal epithelial cells are currently the only microfilament arrangement which can be isolated ultrastructurally intact and in sufficient quantities for biochemical analysis. We have isolated and characterized villin, a major protein of the microvillus core. Using villin's ability to bind very tightly to immobilized monomeric actin in a calcium-dependent manner, we have developed a method for its rapid purification by affinity chromatography on G actin, which itself was bound to immobilized pancreatic deoxyribonuclease I (DNAase I). The villin-G actin complex on DNAase I is resistant to high ionic strength, and villin, but not actin, is released when the calcium concentration is less than 10⁶ M. Purified villin behaves as a globular monomeric protein of molecular weight 95,000, and is free of carbohydrate. Villin also interacts with F actin. In the absence of calcium, villin cross-links F actin having the properties of an F actin bundling or gelation factor. In the presence of calcium (>10^?7 M), villin apparently restricts the polymerization of actin to short filaments which cannot be readily sedimented. The properties of villin are not compatible with its previously suggested role as the cross-filament between the microvillus microfilament core and the plasma membrane, but rather indicate a function as a calcium-dependent F actin-bundling protein. The role of villin is discussed in terms of the other protein components of the microvillus core and in relation to recently described calcium-dependent gelation factors.     

Hepatic Ah receptor from the Wistar rat: role of solvation in receptor structure and inactivation

Repeated freezing and thawing, the addition of salts, and elevated temperatures all promote the inactivation of the rat hepatic Ah receptor. The reduced availability of bulk water to solvate the protein is proposed to be the factor linking all these routes for inactivation. Prospective protocols for purification of unliganded Ah receptor should therefore minimize the number of freeze/thaw cycles; long-term freezing of cytosolic samples at -20 degrees C is inadequate to maintain long-term viability of the unliganded receptor. The stability of rat hepatic receptor is greatly increased upon binding the ligand, and the extent of ligand-induced stabilization is much greater than what is observed with steroid hormone receptors. Concentrations of NaCl and K2HPO4 up to 0.5 M inactivate the unbound Ah receptor irreversibly, with the loss of approximately 50% of the specific binding. At 2.0 M NaCl, a further reversible reduction in ligand binding activity is observed. The results at lower salt concentrations are interpreted in terms of the irreversible dissociation of a single binding unit from the trimeric cytosolic Ah receptor (which consists of two ligand-binding units and a 90-kDa heat shock protein), with the release of bound ligand from that subunit.     

Phenothiazine binding by a homolog of calpactin, the pp60src tyrosine kinase substrate

Microvilli isolated from 13762 mammary ascites tumor cells contain a major calcium-sensitive protein (AMV-p35) that can be isolated with microvillar microfilament cores prepared by Triton X-100 extraction in the presence but not absence of calcium. AMV-p35 can be readily purified from ethylene glycol bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid extracts of the microfilament cores by chromatography on an anion exchange column, to which it does not bind. Immunoblot analysis indicates that AMV-p35 is related to calpactin I, the pp60src tyrosine kinase substrate. In the presence of calcium, AMV-p35 binds approximately 4 mol of chlorpromazine per mole of protein in a binding process showing apparent positive cooperativity, similar to calmodulin; however, in contrast to calmodulin, AMV-p35 also binds phenothiazine in the absence of calcium.     

Identification of a heparin-releasable lipoprotein lipase binding protein from endothelial cells.

Triglycerides in circulating plasma lipoproteins are hydrolyzed by lipoprotein lipase (LPL) which is thought to bind to proteoglycans on the luminal endothelial cell surface. Previous studies from this laboratory using LPL-Sepharose affinity chromatography identified a 220-kDa LPL binding proteoglycan. Using ligand blotting with 125I-LPL, we now report a 116-kDa LPL binding protein in plasma membrane preparations of endothelial cells. 125I-LPL binding to this protein was abolished by addition of unlabeled LPL. When the cell surface of endothelial cells was labeled with biotin, a 116-kDa protein was biotinylated. Furthermore, the biotinylated 116-kDa protein bound to LPL-Sepharose and eluted with 0.4 M NaCl suggesting that the 116-kDa LPL binding protein is present on the cell surface. When detergent extracts of endothelial cells were applied to LPL-Sepharose in the presence of 0.15 M NaCl, the 116-kDa, but not the 220-kDa, protein still bound to LPL-Sepharose. The 116-kDa protein was not labeled with 35SO4 and eluted from DEAE-cellulose prior to proteoglycans, suggesting that it is not a proteoglycan. However, a 116-kDa endothelial cell surface protein was metabolically labeled with [35S]methionine. This protein was dissociated from the cell surface by incubating cells with heparin (50 units/ml)-containing buffer. After heparin treatment of endothelial cells, LPL binding to and internalization by the cells decreased greater than 70% compared to control cells. These results suggest that endothelial cells synthesize a heparin-releasable, high affinity 116-kDa LPL binding protein. We postulate that this protein is associated with proteoglycans on luminal endothelial surfaces and mediates LPL binding, internalization, and recycling. We name this protein hrp (heparin-releasable protein)-116.     

A liver-specific chromatin protein binding to the 5' far upstream region of the rat serum albumin gene

Chromatin proteins which were extracted with 0.3 M NaCl from rat liver, brain, and kidney nuclei were examined by the protein blotting technique for their ability to bind to the 5' upstream regions of the rat serum albumin gene. A 110-kDa protein from liver nuclei bound specifically to the most upstream fragment (between approximately equal to -7.3 kbp and -2.0 kbp from the cap site) of the cloned albumin genomic DNA, whereas no proteins from kidney and brain bound to this fragment. It is possible that the 110-kDa protein is concerned with the tissue-specific expression of the albumin gene.     

DNA and nucleotide-induced conformational changes in the Escherichia coli Rep and helicase II (UvrD) proteins

The domain structures of the Escherichia coli Rep and Helicase II proteins and their ligand-dependent conformational changes have been examined by monitoring the sensitivity of these helicases to proteolysis by trypsin and chymotrypsin. Limited treatment of unliganded Rep protein (73 kDa) with trypsin results in cleavage at a single site in its carboxyl-terminal region, producing a 68-kDa polypeptide which is stabilized in the presence of ATP, ADP, or adenosine 5'-O-thiotriphosphate) (ATP gamma S). The purified 68-kDa Rep tryptic polypeptide retains single-stranded (ss) DNA binding, DNA unwinding (helicase), and full ATPase activities. When bound to ssDNA, the Rep protein can be cleaved by trypsin at an additional site in its carboxyl-terminal region, producing a 58-kDa polypeptide that also retains ssDNA binding and ATPase activities. This 58-kDa Rep tryptic polypeptide can also be produced by further tryptic treatment of the 68-kDa Rep tryptic polypeptide when the latter is bound to ssDNA. This 58-kDa polypeptide displays a lower affinity for ssDNA indicating that the 10-kDa carboxyl-terminal peptide facilitates Rep protein binding to ssDNA. The 58-kDa Rep tryptic polypeptide is also stabilized in the presence of nucleotides. Based on these and previous studies that showed that the 68-kDa Rep tryptic polypeptide cannot support DNA replication in a system that is dependent upon the phi X174 cis-A protein (Arai, N. & Kornberg, A. (1981) J. Biol. Chem. 256, 5294-5298), we conclude that the carboxyl-terminal end (approximately 5 kDa) of the Rep protein is not required for its helicase or ATPase activities. However, we suggest that this region of the Rep protein is important for its interactions with the phi X174 cis-A protein. Limited treatment of unliganded Helicase II protein (82 kDa) with chymotrypsin results in cleavage after Tyr254, producing a 29-kDa amino-terminal polypeptide and a 53-kDa carboxyl-terminal polypeptide, which remain associated under nondenaturing conditions. This chymotrypsin cleavage reduces the ssDNA binding activity and eliminates the ssDNA-dependent ATPase and helicase activities of the Helicase II protein. The binding of ATP, ADP, ATP gamma S, and/or DNA to Helicase II protein results in protection of this site (Tyr254) from cleavage by chymotrypsin. Limited treatment of Helicase II protein with trypsin results in cleavage near its carboxyl-terminal end producing two polypeptides with apparent Mr = 72,000, in a manner similar to that observed with the Rep protein; these polypeptides are also stabilized by binding ATP or single-stranded DNA.(ABSTRACT TRUNCATED AT 400 WORDS)     

Purification and characterization of a 400-kDa nonhistone chromatin protein that serves as an effective phosphate acceptor for casein kinase II from Ehrlich ascites tumor cells

A nonhistone chromatin protein (NHCP) has been purified to homogeneity from a 0.5 M NaCl extract of Ehrlich ascites tumor cell (EAT cell) nuclei as a phosphate acceptor for casein kinase II using ion-exchange column chromatographies and Sephacryl S300 gel filtration. The purified NHCP (approximate Mr = 400,000) was found to be a tetramer of an Mr = 98,000 polypeptide (pI = 6.9) and to have high contents of glycine (15%) and serine (11.6%). This protein (designated as 400-kDa NHCP) was highly phosphorylated by casein kinase II (Mr = 130,000), but not by histone kinase. Casein kinase II phosphorylated only seryl residues of the purified 400-kDa NHCP. The NHCP bound with DNA, but not with RNAs, and the DNA binding ability of the protein was reduced when it was phosphorylated by casein kinase II. Moreover, we found that (a) the 400-kDa NHCP is present in large quantities in malignant mouse cells, such as EAT, EL-4, and Meth-A cells, but only slightly in normal tissues and cells; (b) the protein level is rapidly increased when mouse lymphocytes are treated with recombinant interleukin 2 (T cell growth factor) or concanavalin A; and (c) the kinase responsible for the 400-kDa NHCP phosphorylation in the chromatin of various mouse cells is a casein kinase II. These experimental results suggest that the 400-kDa NHCP acts as an effective phosphate acceptor for casein kinase II at the chromatin level and that an increased phosphorylation of the protein by the kinase may be implicated in the progress of cell differentiation and proliferation.     

The 110,000-dalton actin- and calmodulin-binding protein from intestinal brush border is a myosin-like ATPase

A 110-kDa protein present in chicken intestinal brush-border microvilli is believed to laterally link the actin filament bundle that forms the structural core of the microvilli with the microvillar plasma membrane. We have purified a 110-kDa protein to greater than 95% homogeneity by extraction of brush borders with solution containing 0.6 M KCl and 5 mM ATP, followed by gel filtration chromatography, sedimentation as a complex with exogenous actin, and hydroxylapatite chromatography. The 110-kDa protein-calmodulin complex bound F-actin in the absence but not the presence of ATP and had K+,EDTA-ATPase (0.2 mumol/min/mg) and Ca2+-ATPase (0.2 mumol/min/mg) activities and Mg2+-ATPase activity (0.03 mumol/min/mg) that was not activated by F-actin. The actin-binding and ATPase activities of the complex were similar to those of purified brush-border myosin. However, immunoblot analysis showed no reactivity between the 110-kDa protein and polyclonal antibody against purified chicken brush-border myosin. Also, peptide maps of 110-kDa protein and myosin obtained by limited proteolysis with chymotrypsin and Staphylococcus aureus V8 protease had few, if any, peptides in common. Immunoblot analysis also showed that myosin heavy chain was stable under the conditions of the preparation.     

Syndecans,signaling, and cell adhesion

Syndecans are transmembrane proteoglycans which can participate in diverse cell surface interactions, involving extracellular matrix macromolecules, growth factors, protease inhibitors, and even viral entry. Currently, all extracellular interactions are believed to be mediated by distinct structures within the heparan sulfate chains, leaving the roles of chondroitin sulfate chains and extracellular portion of the core proteins to be elucidated. Evidence that syndecans are a class of receptor involved in cell adhesion is mounting, and their small cytoplasmic domains may link with the microfilament cytoskeleton, thereby mediating signaling events. The molecular details are unknown, but the conservation of regions of syndecan cytoplasmic domains, and a strong tendency for homotypic association, support the idea that the ligand-induced clustering may be a discrete source of specific transmembrane signaling from matrix to cytoskeleton, as proposed for other classes of adhesion receptors. © 1996 Wiley-Liss, Inc.     

Microvillar elongation following parthenogenetic activation of sea urchin eggs

Parthenogenetic activation of unfertilized sea urchin eggs with ammonium chloride at pH 8.0 resulted in a slow, but dramatic, reorganization of surface microvilli in four species of sea urchin eggs. Following NH4Cl treatment, elongation of microvilli on the egg surface was observed concomitant with the formation of microfilament bundles within the microvillar cores. A minimum of 2 h of treatment was required for elongation and microfilament bundle formation to occur. The maintenance of elongated microvilli was pH-sensitive; removal of the activating agent resulted in the retraction of extended microvilli while readdition of NH4Cl caused microvilli to elongate again. Accompanying microvillar elongation in activated eggs, there was an increased calcium uptake as measured by 45Ca uptake. Blocking calcium uptake by incubation in lanthanum chloride or zero-calcium seawater containing 2 mM EGTA prevented microvillar elongation. These results suggested that elongation of microvilli following parthenogenetic activation by NH4Cl is pH- and calcium-dependent and is similar to that observed during normal fertilization.