Identification of a 34-kD polypeptide as a light chain of microtubule- associated protein-1 (MAP-1) and its association with a MAP-1 peptide that binds to microtubules

We examined the association of a 34-kD light chain component to the heavy chains of MAP-1 using a monoclonal antibody that specifically binds the 34-kD component and labels neuronal microtubules in a specific and saturable manner. Immunoprecipitation of MAP-1 heavy chains together with the 34-kD component by the antibody indicates that the 34-kD polypeptide forms a complex with MAP-1 heavy chains. Both major isoforms of MAP-1 heavy chains (MAP-1A and MAP-1B) were found in the immunoprecipitate. Digestion of MAP-1 with alpha-chymotrypsin and analysis of the chymotryptic peptides reveals a 120-kD fragment of the MAP-1 heavy chain that binds to microtubules and is precipitable with the 34-kD light chain antibody, suggesting that the 34-kD light chain also binds to this domain of the molecule. Since microtubules that contain the 120-kD fragment lack the long lateral projections characteristic of microtubules with intact MAP-1, the 34-kD light chains may be localized at or near the microtubule surface.     

Glutamate receptor-interacting protein 1 protein binds to the microtubule-associated protein

To identify the interaction proteins for the alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionate (AMPA) receptor subunit glutamate receptor-interacting protein 1 (GRIP1), GRIP1 interactions with microtubule-associated protein (MAP)-1B light chain (LC) were investigated. GRIP1 interacts with MAP-1A and MAP-1B in the yeast two-hybrid assay, as is indicated also by glutathione S-transferase (GST) pull-down and coimmunoprecipitation with MAP-1B LC antibody in brain fractions. These results suggest a novel mechanism for localizing AMPA receptors to synaptic sites.     

Microtubule-associated protein 1S, a short and ubiquitously expressed member of the microtubule-associated protein 1 family

The related high molecular mass microtubule-associated proteins (MAPs) MAP1A and MAP1B are predominantly expressed in the nervous system and are involved in axon guidance and synaptic function. MAP1B is implicated in fragile X mental retardation, giant axonal neuropathy, and ataxia type 1. We report the functional characterization of a novel member of the microtubule-associated protein 1 family, which we termed MAP1S (corresponding to sequence data bank entries for VCY2IP1 and C19ORF5). MAP1S contains the three hallmark domains of the microtubule-associated protein 1 family but hardly any additional sequences. It decorates neuronal microtubules and copurifies with tubulin from brain. MAP1S is synthesized as a precursor protein that is partially cleaved into heavy and light chains in a tissue-specific manner. Heavy and light chains interact to form the MAP1S complex. The light chain binds, bundles, and stabilizes microtubules and binds to actin. The heavy chain appears to regulate light chain activity. In contrast to MAP1A and MAP1B, MAP1S is expressed in a wide range of tissues in addition to neurons and represents the non-neuronal counterpart of this cytolinker family.     

Separation of active tubulin and microtubule-associated proteins by ultracentrifugation and isolation of a component causing the formation of microtubule bundles

A new method for separating microtubule-associated proteins (MAPs) and tubulin, appropriate for relatively large-scale preparations, was developed. Most of the active tubulin was separated from the MAPs by centrifugation after selective polymerization of the tubulin was induced with 1.6 M 2-(N-morpholino)ethanesulfonate (Mes) and GTP. The MAPs-enriched supernatant was concentrated and subsequently clarified by prolonged centrifugation. The supernatant (total soluble MAPs) contained almost no tubulin, most of the nucleosidediphosphate kinase activity of the microtubule protein, good activity in promoting microtubule assembly in 0.1 M Mes, and proteins with the electrophoretic mobility of MAP-1, MAP-2, and tau factor. The pellet, inactive in supporting microtubule assembly, contained denatured tubulin, most of the ATPase activity of the microtubule protein, and significant amounts of protein with the electrophoretic mobility of MAP-2. Insoluble material at this and all previous stages, including the preparation of the microtubule protein, could be heat extracted to yield soluble protein active in promoting microtubule assembly and containing MAP-2 as a major constituent. The total soluble MAPs were further purified by DEAE-cellulose chromatography into bound and unbound components, both of which induced microtubule assembly. The bound component (DEAE-MAPs) contained proteins with the electrophoretic mobility of MAP-1, MAP-2, and tau factor. The polymerization reaction induced by the unbound component (flow-through MAPs) produced very high turbidity readings. This was caused by the formation of bundles of microtubules. Although the flow-through MAPs contained significantly more ATPase, tubulin-independent GTPase, and, especially, nucleosidediphosphate kinase activity than the DEAE-MAPs, preparation of a MAPs fraction without these enzymes required heat treatment.     

Numerous phosphates of microtubule-associated protein 2 in living rat brain

Microtubule-associated protein 2 (MAP 2) purified from microwave-irradiated rat head contained about 46 esterified phosphates (mole/mol), which were not bound covalently to lipids and did not assemble with microtubules. After some phosphates were released by calf intestinal alkaline phosphatase, the phosphate content of MAP-2 decreased to 16 mol of phosphate and the protein assembled in vitro. MAP-2 purified after microtubule assembly cycles and also the cytosolic heat-stable fraction without assembly cycles had 10 mol of phosphate, and both assembled with microtubules. The MAP-2 with 46 phosphates and that with 10 had different pI in isoelectric focusing, but the components, MAP-2a and -2b, were always near each other. In high-pressure liquid chromatography, MAP-2 containing 46 mol of phosphate appeared after that 10 mol of phosphate. Phosphoserine, phosphothreonine, and phosphotyrosine were recovered from tryptic digestion of MAP-2 with 46 mol of phosphate. These findings suggest that two kinds of MAP-2, one with 46 phosphates and not bound to tubulin and the other with 10-16 phosphates and bound to tubulin, are present in the living rat brain.     

Quantitation of microtubule-associated protein MAP-1B in brain and other tissues

1. The presence of microtubule-associated protein MAP-1B in all mammalian tissues tested, as well as in brain, has been demonstrated by immunoblotting using a monospecific polyclonal antibody. 2. The expression of brain MAP-1B is developmentally controlled, as it is less abundant in adult than in newborn rat brain, where it is a major microtubule assembly promoting factor. 3. The level of MAP-1B in tissues other than brain is lower than it is in brain; but the relative ratios of MAP-1B to tubulin are very similar in all tissues, thus differing from the observed for MAP-2 or tau. 4. The amount of MAP-1B in non-nervous tissues seems not to be under developmental control. 5. These results are consistent with a role for MAP-1B in the assembly of microtubules in most cells.     

Interaction of microtubule-associated protein 2 with actin filaments

The interaction of unphosphorylated and phosphorylated microtubule-associated protein 2 (MAP-2) with actin filaments was examined by electron microscopic, electrophoretic, and dark-field light microscopic techniques. Unphosphorylated MAP-2 was observed to cross-link and bundle individual actin filaments. Chymotryptic fragments of MAP-2 protein were produced which bound to, but could not cross-link, actin polymer; these fragments encompassed the tubulin binding domain of MAP-2. The phosphorylation of intact MAP-2, by means of endogenous protein kinases, inhibited the ability of this molecule to cross-link and bundle actin filaments. Phosphorylation did not, however, inhibit the binding of MAP-2 to F-actin. The chymotryptic fragments of phosphorylated MAP-2 that retained their ability to bind to actin and promote microtubule assembly also encompassed the tubulin binding domain of this molecule. An analysis of MAP-2 fragments by nonequilibrium pH gradient electrophoresis indicated that most of the polypeptide backbone is relatively acidic with the exception of the tubulin binding domain. This region was determined to be the most basic (positively charged) region of the MAP-2 molecule. Biochemical and morphological evidence is presented to demonstrate that both unphosphorylated MAP-2 and phosphorylated MAP-2 have the capacity to use actin, in addition to microtubules, as a separate anchoring substrate. The presence of tubulin, however, strongly inhibits the interaction of MAP-2 with actin filaments.     

Common antigenic determinants of the tubulin binding domains of the microtubule-associated proteins MAP-2 and tau.

The structural-functional aspects of the tubulin binding domain on the microtubule-associated protein MAP-2, and its relationship with the tubulin binding domain on tau, were studied using anti-idiotypic antibodies that react specifically with the epitope(s) on MAPs involved in their interaction with tubulin in addition to other tau and MAP-2 specific antibodies. Previous studies showed that MAP-2 and tau share common binding sites on tubulin defined by the peptide sequences alpha (430-441) and beta (422-434) of tubulin subunits. Furthermore, binding experiments revealed the existence of multiple sites for the interaction of the alpha- and beta-tubulin peptides with MAP-2 and tau. Most recent studies showed that the synthetic tau peptide Val187-Gly204 (VRSKIGSTENLKHQPGGG) from the repetitive sequence on tau defines a tubulin binding site on tau. Our present immunological studies using anti-idiotypic antibodies which interact with the synthetic tau peptide and antibodies against the Val187-Gly204 tau peptide indicate that MAP-2 and tau share common antigenic determinants at the level of their respective tubulin binding domains. These antigenic determinants appear to be present in the 35 kDa tubulin binding fragment of MAP-2 and in 18-20 kDa chymotryptic fragments containing the tubulin binding site(s) on MAP-2. These findings, along with structural information on these proteins, provide strong evidence in favor of the hypothesis that tubulin binding domains on MAP-2 and tau share similar structural features.     

Neuraxin corresponds to a C-terminal fragment of microtubule-associated protein 5 (MAP5)

From cloned DNA, neuraxin has been identified as a tubulin binding protein of predicted molecular weight of 94 kDa. The deduced sequence of the rat protein exhibits high homology to the C-terminal region of mouse microtubule-associated protein 5 (MAP5). Here, we show that different neuraxin antibodies recognize MAP5, but fail to detect a protein of 94 kDa, in subcellular and microtubular fractions of the rat central nervous system. Furthermore, tubulin binding by neuraxin was found to be dependent on taxol. These data are consistent with neuraxin corresponding to a C-terminal fragment of MAP5 that contains a low-affinity tubulin binding site.     

Efficacy of protein A-HRP in an immunological study of black rockfish (Sebastes schlegeli Higendorf) humoral immune responses

The efficacy of protein A-horse radish peroxidase (HRP), as compared to that of mouse polyclonal antibody raised against purified Ig, in detection of black rockfish (Sebastes schlegeli Higendorf) immunoglobulin (Ig) was examined. Protein A affinity chromatography successfully purified Ig from black rockfish serum; the purified-Ig could be visualised as two protein bands (MW 70 and 25kDa) following resolution with sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE) under reducing conditions. In SDS-PAGE immunoblot profiles of the purified-Ig, the mouse polyclonal antibody recognised both the light chain and heavy chains of rockfish Ig, whereas protein A-HRP immunostained only the heavy chain of rockfish Ig. These results suggest that protein A-HRP may be used to detect rockfish antibody-antigen complexes in immunoassays. In a 2-DE immunoblot assay for exploring antigenic profiles of Lactococcus garvieae KG9408, protein A-HRP successfully detected specific antibodies to antigenic proteins of L. garvieae in the rockfish Ig. In addition, enzyme linked immunosorbent assay (ELISA) showed a high correlation between the results obtained for positivity of L. garvieae when protein A-HRP and the mouse polyclonal antibody-was used to analyse samples from 25 diseased rockfish. These results collectively indicate that protein A-HRP has a high affinity for Ig, and may be useful for new investigations into the humoral immune responses of rockfish.     

Cellular distribution of a protein related to neuronal microtubule-associated protein MAP-2 in Leydig cells

A monoclonal antibody to neuronal microtubule-associated protein MAP-2 was produced. Immunoblotting of lysates of cultured cells revealed that the antibody, called MA-01, bound to a protein of Mr 210 kDa. Double immunofluorescence microscopy showed that the antibody stained microtubules. No fibrillar structures were observed in cells treated with Colcemid, but the antibody stained vinblastine paracrystals. In cytochalasin B-treated Leydig cells, MA-01 antibody stained star-like structures that codistributed with actin patches and with a star-like arrangement of vimentin. These observations indicate that the protein immunologically related to MAP-2 in Leydig cells could be involved in the interaction of microtubules with intermediate filaments or microfilaments.     

Heterotypic complex formation between subunits of microtubule-associated proteins 1A and 1B is due to interaction of conserved domains

The microtubule-associated proteins MAP1A and MAP1B are related but distinct multi-subunit protein complexes that consist of heavy and light chains. The predominant forms of these complexes are homotypic, i.e. they consist of a MAP1A heavy chain associated with MAP1A light chains or a MAP1B heavy chain associated with MAP1B light chains, respectively. In addition, MAP1A and MAP1B can exchange subunits and form heterotypic complexes consisting of a MAP1A heavy chain associated with MAP1B light chains which might play a role in a transition period of neuronal differentiation. Here we extend previous findings by confirming that heterotypic MAP1B heavy chain-MAP1A light chain complexes also exist in the developing murine brain. We show that these complexes form through interaction of homologous domains conserved in heavy and light chains of MAP1A and MAP1B. Likewise, conserved domains of the MAP1A and MAP1B light chains account for formation of light chain heterodimers. By yeast 2-hybrid analysis we located the light chain binding domain on the heavy chain to amino acids 211-508, thereby defining a new functional subdomain.     

Cyclic nucleotide- and Ca2+-independent phosphorylation of tubulin and microtubule-associated protein-2 by glycogen synthase (casein) kinase-1

MAP-2 and tubulin are both shown to be substrates for glycogen synthase (casein) kinase-1 (CK-1). Greater than 40 mol 32P is incorporated into MAP-2 by CK-1 compared to only 14 mol 32P observed when cyclic AMP-dependent protein kinase (A-kinase) is the catalyst. Peptide mapping shows that CK-1 and A-kinase recognize a few common sites; the majority of the sites phosphorylated on MAP-2 by CK-1 are quite distinct. Up to 4 mol 32P can be incorporated into the tubulin dimer by CK-1 compared to only 0.9 mol 32P by A-kinase. The preferred substrate for both kinases is beta-tubulin.     

Estramustine binds a MAP-1-like protein to inhibit microtubule assembly in vitro and disrupt microtubule organization in DU 145 cells

The twofold purpose of the study was (a) to determine if a MAP-1-like protein was expressed in human prostatic DU 145 cells and (b) to demonstrate whether a novel antimicrotubule drug, estramustine, binds the MAP-1-like protein to disrupt microtubules. SDS-PAGE and Western blots showed that a 330-kD protein was associated with microtubules isolated in an assembly buffer containing 10 microM taxol and 10 mM adenylylimidodiphosphate. After purification to homogeneity on an A5m agarose column, the 330-kD protein was found to promote 6 S tubulin assembly. Turbidimetric (A350), SDS-PAGE, and electron microscopic studies revealed that micromolar estramustine inhibited assembly promoted by the 330-kD protein. Similarly, estramustine inhibited binding of the 330-kD protein to 6-S microtubules independently stimulated to assemble with taxol. Immunofluorescent studies with beta- tubulin antibody (27B) and MAP-1 antibody (MI-AI) revealed that 60 microM estramustine (a) caused disassembly of MAP-1 microtubules in DU 145 cells and (b) removed MAP-1 from the surfaces of microtubules stabilized with 0.1 microM taxol. Taken together the data suggested that estramustine binds to a 330-kD MAP-1-like protein to disrupt microtubules in tumor cells.     

Light chain dependent effects of actin binding on the S-1/S-2 swivel in myosin

The S-1/S-2 swivel in myosin provides a flexible link between the head and tail portions of the molecule. We have investigated the properties of the swivel by employing limited proteolysis methods. Our results indicate that the binding of actin to heavy meromyosin inhibits both the chymotryptic and papain cleavage of the S-1/S-2 swivel, and that this effect is dependent on the presence of intact LC-2 light chains. Actin did not slow digestions carried out using heavy meromyosin previously treated with proteases to nick the LC-2 chains to 17,000 or 14,000 Mr fragments. Although the integrity of the LC-2 light chain appears to be required to transmit the effects of actin binding from the myosin head to the S-1/S-2 swivel, the binding of Ca2+ to the 17,000 Mr LC-2 fragment can still affect the chemical reactivity of SH1 thiol groups. Both chymotryptic and papain digestions of heavy meromyosin containing intact or fragmented LC-2 light chain show substantial temperature sensitivity between 5 degrees C and 35 degrees C. Calculated apparent activation energies for this process indicate that the S-1/S-2 swivel in myosin can undergo temperature-dependent structural changes independently of the state of the LC-2 light chain. Thus, both actin binding and temperature variations can induce structural transitions in the S-1/S-2 swivel.     

Pepsin digestion of a mouse monoclonal antibody of IgG1 class formed F(ab')(2) fragments in which the light chains as well as the heavy chains were truncated

In the preparation of F(ab')(2) fragments of monoclonal antibodies (mAbs) of IgG class, heavy (H) chains are truncated by pepsin and light (L) chains are remained intact. However, F(ab')(2) fragments formed by pepsin-digestion of a mouse mAb PM373, which was of the IgG1 class and raised against human prostate specific antigen (PSA), indicated that the L chains of 31 kDa were cleaved into 23-kDa fragments as well as the cleavage of H chains of 50 kDa into 28-kDa fragments. On the other hand, F(ab')(2) fragments formed by digesting the mAb by cathepsin D showed that the L chains were intact and the H chains were truncated. The immunoreactivities against PSA of the F(ab')(2) fragments containing the intact L chains and those containing the truncated L chains were almost the same as that of the parental mAb, suggesting that the truncation of the L chains does not affect the interaction of the mAb with its specific antigen.     

Purification of myosin from Ehrlich ascites tumour cells (phosphorylation of its light chain and heavy chain)

1. The myosin molecule from Ehrlich ascites tumour cells consists of heavy chains of about 200 kDa and three species of light chains of 20, 19 and 15 kDa. 2. The heavy chain can be phosphorylated in vitro either by endogenous Ca2+-independent kinase or by casein kinase II. 3. The 20 and 19 kDa light chains can be phosphorylated either by an endogenous kinase or by myosin light chain kinase from chicken gizzard. 4. The Ca2+-ATPase activity of the purified myosin was 0.3 mumol/min mg protein. The Mg2+-ATPase activity was activated 14-fold by actin upon the light chain phosphorylation.     

Calmodulin binds to a tubulin binding site of the microtubule-associated protein tau

Previous studies have demonstrated that the microtubule - associated proteins MAP-2 and tau interact selectively with common binding domains on tubulin defined by the low-homology segments a (430–441) and (422–434). It has been also indicated that the synthetic peptide VRSKIGSTENLKHQPGGG corresponding to the first tau repetitive sequence represents a tubulin binding domain on tau. The present studies show that the calcium-binding protein calmodulin interacts with a tubulin binding site on tau defined by the second repetitive sequence VTSKCGSLGNIHHKPGGG. It was shown that both tubulin and calmodulin bind to tau peptide-Sepharose affinity column. Binding of calmodulin occurs in the presence of 1 mM Ca 2+ and it can be eluted from the column with 4 mM EGTA. These findings provide new insights into the regulation of microtubule assembly, since Ca 2+/calmodulin inhibition of tubulin polymerization into microtubules could be mediated by the direct binding of calmodulin to tau, thus preventing the interaction of this latter protein with tubulin.     

Inactivation of human factor VIII by activated protein C: evidence that the factor VIII light chain contains the activated protein C binding site

Factor VIII is represented as a series of heterodimers composed of an 83(81) kDa light chain noncovalently bound to a variable size (93 to 210 kDa) heavy chain. Activated protein C inactivates factor VIII causing several cleavages of the factor VIII heavy chain(s). When factor VIII subunits were dissociated and component heavy and light chains isolated, the heavy chains were no longer a substrate for proteolysis by activated protein C. However, when factor VIII heavy chains were recombined with light chain, the reconstituted factor VIII activity was inactivated by activated protein C. The rate of factor VIII inactivation catalyzed by activated protein C was reduced by the presence of free light chain. The extent of this inhibition was dependent upon the concentration of light chain. Control experiments indicated that this protective effect of free light chain was not the result of inhibition of the activated protein C - lipid interaction. Fluorescence analysis demonstrated binding between the factor VIII light chain, chemically modified with eosin maleimide, and activated protein C, modified at its active site by dansyl-Glu-Gly-Arg chloromethyl ketone. Similar to proteolysis of factor VIII by activated protein C, this binding was dependent upon a lipid surface. Based upon the degree of fluorescence quenching, a spatial distance of 26 A was calculated separating the two fluorophores. These results demonstrate direct binding of activated protein C to the factor VIII light chain and suggest that this binding is an obligate step for activated protein C-catalyzed inactivation of factor VIII.     

Characterization of DLC-A and DLC-B, two families of cytoplasmic dynein light chain subunits.

Cytoplasmic dynein is a minus-end-directed, microtubule-dependent motor composed of two heavy chains (approximately 530 kDa), three intermediate chains (approximately 74 kDa), and a family of approximately 52-61 kDa light chains. Although the approximately 530 kDa subunit contains the motor and microtubule binding domains of the complex, the functions of the smaller subunits are not known. Using two-dimensional gel electrophoresis and proteolytic mapping, we show here that the light chains are composed of two major families, a higher M(r) family (58, 59, 61 kDa; dynein light chain group A [DLC-A]) and lower M(r) family (52, 53, 55, 56 kDa; dynein light chain group B [DLC-B]). Dissociation of the cytoplasmic dynein complex with potassium iodide reveals that all light chain polypeptides are tightly associated with the approximately 530 kDa heavy chain, whereas the approximately 74 kDa intermediate chain polypeptides are more readily extracted. Treatment with alkaline phosphatase alters the mobility of four of the light chain polypeptides, indicating that these subunits are phosphorylated. Sequencing of a cDNA clone encoding one member of the DLC-A family reveals a predicted globular structure that is not homologous to any known protein but does contain numerous potential phosphorylation sites and a consensus nucleotide-binding motif.