Microvillus 110K-calmodulin: effects of nucleotides on isolated cytoskeletons and the interaction of the purified complex with F-actin

Introduction

This book, a collection of chapters written by some of the leading researchers in the field of molecular motors, highlights the current understanding of the structure, molecular mechanism, and cellular roles of members of the myosin superfamily. Here, I briefly review the discovery of the first myosin motor, skeletal muscle myosin-II, and preview the contents of subsequent chapters.

Calcium and the regulation of cytoskeletal assembly, structure and contractility

Calcium plays a central role in the regulation of cytoskeletal assembly, structure and contractility. In the case of actin there are a number of functional classes of actin-binding proteins which confer on a given actin filament its specific function in the cell. Among these various classes of actin-binding proteins are a subset of proteins whose activity is either regulated directly or indirectly (for example, through calmodulin) by Ca2+. This includes the regulation of actin-myosin interaction, actin assembly, actin filament interaction and the formation of supramolecular cytoskeletal networks, and the interaction of actin with membranes. Examples of these various modes of Ca2+-dependent regulation of cytoskeletal structure and contractility are discussed.

Myosin I phosphorylation is increased by chemotactic stimulation

Directed cell migration occurs in response to extracellular cues. Following stimulation of a cell with chemoattractant, a significant rearrangement of the actin cytoskeleton is mediated by intracellular signaling pathways and results in polarization of the cell and movement via pseudopod extension. Amoeboid myosin Is play a critical role in regulating pseudopod formation in Dictyostelium, and their activity is activated by heavy chain phosphorylation. The effect of chemotactic stimulation on the in vivo phosphorylation level of a Dictyostelium myosin I, myoB, was tested. The myoB heavy chain is phosphorylated in vivo on serine 322 (the myosin TEDS rule phosphorylation site) in chemotactically competent cells. The level of myoB phosphorylation increases following stimulation of starving cells with the chemoattractant cAMP. A 3-fold peak increase in the level of phosphorylation is observed at 60 s following stimulation, a time at which the Dictyostelium cell actively extends pseudopodia. These findings suggest that chemotactic stimulation results in increased myoB activity via heavy chain phosphorylation and contributes to the global extension of pseudopodia that occurs prior to polarization and directed motility.

Regulation of calmodulin binding to the ATP extractable 110 kDa protein (myosin I) from chicken duodenal brush border by 1,25-(OH)2D3

In earlier studies we observed that the active vitamin D metabolite 1,25-(OH)2D3 increased the calmodulin content of purified duodenal brush-border membrane vesicles where it bound principally to the 110 kDa protein myosin I. In this study we further evaluated the regulation of calmodulin binding to ATP releasable myosin I. Whole brush borders (BB) or purified brush-border membrane vesicles (BBMV) were prepared from duodena of vitamin D-deficient rachitic chicks treated 12-18 h before killing with either 625 pmol 1,25-(OH)2D3 or vehicle. The ATP extractable myosin I from BB resulted in an 1.6-fold increase of calmodulin binding to the 110 kDa band after treatment with 1,25-(OH)2D3. In contrast to BB, ATP extraction of myosin I from purified BBMV required alamethicin for ATP entry. As for BB extracts, calmodulin binding to the 110 kDa band in BBMV extracts was also increased about 2.4-fold by 1,25-(OH)2D3. It was concluded that both intact BB and purified BBMV showed the same type of increase in calmodulin binding to ATP releasable myosin I by 1,25-(OH)2D3. To see whether 1,25-(OH)2D3 increased the intrinsic affinity of calmodulin binding to myosin I, the ATP extractable myosin I from BB was purified from rachitic chicks treated with 1,25-(OH)2D3 or vehicle. In contrast to ATP extracts of BB or BBMV, calmodulin binding to the purified myosin I was not different between preparations from 1,25-(OH)2D3- or vehicle-treated chicks. We conclude that 1,25-(OH)2D3 does not change the affinity of calmodulin binding to myosin I but increases the amount of myosin I in the membrane or alters its ATP releasability. It was further investigated whether phosphorylation is involved in these 1,25-(OH)2D3 dependent posttranslational changes of myosin I. Phosphorylation of brush-border membrane proteins in vivo was performed by incubation of [32P]P(i) in the lumen of a ligated duodenal loop in situ for 15 min. Brush-border membrane proteins were phosphorylated in vitro by incubating BB or BBMV with [gamma-32P]ATP for 1 min. Incubation experiments in vivo and in vitro in fact resulted in phosphorylation of several proteins including 110 kDa proteins. However, there was no specific effect of 1,25-(OH)2D3 on phosphorylation of 110 kDa proteins. We conclude that the effects of 1,25-(OH)2D3 on protein phosphorylation are minimal and not likely to explain 1,25-(OH)2D3 stimulated calmodulin binding to ATP extractable brush-border membrane myosin I and 1,25-(OH)2D3 stimulated changes of calcium uptake across the brush-border membrane.

Limited tissue distribution of the intestinal brush border myosin I protein

A myosinlike 105-110-kilodalton calmodulin-binding protein, brush border myosin I, found in the intestinal brush border has been linked to two seemingly disparate but possibly interacting functions of the brush border, namely, microvillar motility and vitamin D regulated calcium transport. If brush border myosin I were to function primarily as a myosinlike molecule powering cellular or microvillar motility, one might expect it to be found in a variety of tissues with microvilli such as the renal brush border and bile canaliculus. On the other hand, a more specialized function such as participation in vitamin D regulated calcium transport might dictate a more restricted tissue distribution for brush border myosin I. To determine the tissue distribution of brush border myosin I, we purified this protein to apparent homogeneity, generated antisera to it, and used the antisera to localize the protein within the intestinal epithelial cell by immunocytochemistry. We then screened a variety of other tissues (brain, lung, heart, liver, spleen, pancreas, kidney, and skeletal muscle) both for calmodulin-binding proteins as well as for brush border myosin I using Western blots and immunofluorescence. Our results indicate that the intestinal brush border myosin I is limited in its distribution to the intestinal brush border.

Evidence for a direct, nucleotide-sensitive interaction between actin and liver cell membranes

We have investigated the association of actin with membranes isolated from rat liver. A plasma membrane-enriched fraction prepared by homogenization in a low salt/CaCl2 buffer was found to contain a substantial amount of residual actin which could be removed by treatment with 1 M Na2CO3/NaHCO3, pH 10.5. Using a sedimentation binding assay that uses gelsolin to shorten actin filaments and render membrane binding saturable (Schwartz, M. A., and E. J. Luna. 1986. J. Cell Biol. 102:2067-2075), we found that membranes stripped of endogenous actin bound 125I-actin in a specific and saturable manner. Scatchard plots of binding data were linear, indicating a single class of binding sites with a Kd of 1.6 microns; 66 micrograms actin bound/mg membrane protein at saturation. Binding of actin to liver cell membranes was negligible with unstripped membranes, was competed by excess unlabeled actin, and was greatly reduced by preheating or proteolytic digestion of the membranes. Kinetic measurements showed that binding had an initial lag phase and was strongly temperature dependent. The binding of actin to liver cell membranes was also found to be competitively inhibited by ATP and other nucleotides, including the nonhydrolyzable analogue AMP-PNP. We conclude that we have reconstituted an interaction between actin and integral membrane proteins from the rat liver. This interaction exhibits a number of distinctive features which have not been observed in other actin-membrane systems.

The 110-kD protein-calmodulin complex of the intestinal microvillus (brush border myosin I) is a mechanoenzyme

The 110-kD protein-calmodulin complex (110K-CM) of the intestinal brush border serves to laterally tether microvillar actin filaments to the plasma membrane. Results from several laboratories have demonstrated that this complex shares many enzymatic and structural properties with myosin. The mechanochemical potential of purified avian 110K-CM was assessed using the Nitella bead motility assay (Sheetz, M. P., and J. A. Spudich. 1983. Nature (Lond.). 303:31-35). Under low Ca2+ conditions, 110K-CM-coated beads bound to actin cables, but no movement was observed. Using EGTA/calcium buffers (approximately 5-10 microM free Ca2+) movement of 110K-CM-coated beads along actin cables (average rate of approximately 8 nm/s) was observed. The movement was in the same direction as that for beads coated with skeletal muscle myosin. The motile preparations of 110K-CM were shown to be free of detectable contamination by conventional brush border myosin. Based on these and other observations demonstrating the myosin-like properties of 110K-CM, we propose that this complex be named "brush border myosin I."

Characterization and partial purification of a high-molecular-mass, calmodulin-binding, tyrosyl-phosphorylated protein from lymphocyte plasma membranes

A plasma membrane phosphoprotein with a species-dependent molecular mass of 108 or 112 kDa (P108/112) was analyzed in lymphoid cells from rats and humans. After 24 h lectin stimulation its in vitro phosphorylation was raised to an important extent. Phosphotyrosine was analyzed by 2-D electrophoresis. Calmodulin was bound by P108/112 in a Ca2+-dependent manner. P108/112 remained insoluble after extraction with detergent, high salt, EDTA, or high pH. After chlorethanol extraction it was partially purified by gel filtration. P108/112 shows conspicuous similarities with the 110-kDa protein from chicken intestine microvilli.

Reassociation of microvillar core proteins: making a microvillar core in vitro

Intestinal epithelia have a brush border membrane of numerous microvilli each comprised of a cross-linked core bundle of 15-20 actin filaments attached to the surrounding membrane by lateral cross-bridges; the cross-bridges are tilted with respect to the core bundle. Isolated microvillar cores contain actin (42 kD) and three other major proteins: fimbrin (68 kD), villin (95 kD), and the 110K-calmodulin complex. The addition of ATP to detergent-treated isolated microvillar cores has previously been shown to result in loss of the lateral cross-bridges and a corresponding decrease in the amount of the 110-kD polypeptide and calmodulin associated with the core bundle. This provided the first evidence to suggest that these lateral cross-bridges to the membrane are comprised at least in part by a 110-kD polypeptide complexed with calmodulin. We now demonstrate that purified 110K-calmodulin complex can be readded to ATP-treated, stripped microvillar cores. The resulting bundles display the same helical and periodic arrangement of lateral bridges as is found in vivo. In reconstitution experiments, actin filaments incubated in EGTA with purified fimbrin and villin form smooth-sided bundles containing an apparently random number of filaments. Upon addition of 110K-calmodulin complex, the bundles, as viewed by electron microscopy of negatively stained images, display along their entire length helically arranged projections with the same 33-nm repeat of the lateral cross-bridges found on microvilli in vivo; these bridges likewise tilt relative to the bundle. Thus, reconstitution of actin filaments with fimbrin, villin, and the 110K-calmodulin complex results in structures remarkably similar to native microvillar cores. These data provide direct proof that the 110K-calmodulin is the cross-bridge protein and indicate that actin filaments bundled by fimbrin and villin are of uniform polarity and lie in register. The arrangement of the cross-bridge arms on the bundle is determined by the structure of the core filaments as fixed by fimbrin and villin; a contribution from the membrane is not required.

Structural and immunological characterization of the myosin-like 110-kD subunit of the intestinal microvillar 110K-calmodulin complex: evidence for discrete myosin head and calmodulin-binding domains

The actin bundle within each microvillus of the intestinal brush border is tethered laterally to the membrane by spirally arranged bridges. These bridges are thought to be composed of a protein complex consisting of a 110-kD subunit and multiple molecules of bound calmodulin (CM). Recent studies indicate that this complex, termed 110K-CM, is myosin-like with respect to its actin binding and ATPase properties. In this study, possible structural similarity between the 110-kD subunit and myosin was examined using two sets of mAbs; one was generated against Acanthamoeba myosin II and the other against the 110-kD subunit of avian 110K-CM. The myosin II mAbs had been shown previously to be cross-reactive with skeletal muscle myosin, with the epitope(s) localized to the 50-kD tryptic fragment of the subfragment-1 (S1) domain. The 110K mAbs (CX 1-5) reacted with the 110-kD subunit as well as with the heavy chain of skeletal but not with that of smooth or brush border myosin. All five of these 110K mAbs reacted with the 25-kD, NH2-terminal tryptic fragment of chicken skeletal S1, which contains the ATP-binding site of myosin. Similar tryptic digestion of 110K-CM revealed that these five mAbs all reacted with a 36-kD fragment of 110K (as well as larger 90- and 54-kD fragments) which by photoaffinity labeling was shown to contain the ATP-binding site(s) of the 110K subunit. CM binding to these same tryptic digests of 110K-CM revealed that only the 90-kD fragment retained both ATP- and CM-binding domains. CM binding was observed to several tryptic fragments of 60, 40, 29, and 18 kD, none of which contain the myosin head epitopes. These results suggest structural similarity between the 110K and myosin S1, including those domains involved in ATP- and actin binding, and provide additional evidence that 110K-CM is a myosin. These studies also support the results of Coluccio and Bretscher (1988. J. Cell Biol. 106:367-373) that the calmodulin-binding site(s) and the myosin head region of the 110-kD subunit lie in discrete functional domains of the molecule.

Immunofluorescent and immunochemical evidence for the expression of cytovillin in the microvilli of a wide range of cultured human cells

We have previously purified a Mr 75,000 protein, cytovillin, from cultured human choriocarcinoma cells (JEG-3) and shown that this protein was specifically confined to the microvillus membrane of these cells. I have now studied the expression and the subcellular distribution of cytovillin in eighteen normal and transformed human cell lines and strains by using immunoblotting and indirect immunofluorescence microscopy. In all cell types, cytovillin was highly enriched in cell surface protrusions. When cell types were ranked according to their staining intensity, choriocarcinoma was highest, then amniotic epithelial cells, other choriocarcinoma cells and tumor cells, and finally fibroblastoid cells. The latter only gave faint diffuse fluorescence on the plasma membrane and, occasionally, on the microvilli. However, detergent extracts of all cell types could be shown to contain cytovillin by the use of immunoblotting techniques. Metabolic pulse-chase labelling experiments with JEG-3 cells demonstrated synthesis of cytovillin as a single-chain polypeptide. No precursor forms or specific proteolytic cleavage products could be seen either by immunoblotting or immunoprecipitation. The protein was found to be very stable with a biologic half-life of about 25 hours. The pI determined by isoelectric focusing was 6.1. These results were consistent with cytovillin being an integral component of the microvilli and other surface extensions of all human cell types examined.

Organization of the actin filament cytoskeleton in the intestinal brush border: a quantitative and qualitative immunoelectron microscope study

In the present study we have used immunogold labeling of ultrathin sections of the intact chicken and human intestinal epithelium to obtain further insight into the molecular structure of the brush-border cytoskeleton. Actin, villin, and fimbrin were found within the entire microvillus filament bundle, from the tip to the basal end of the rootlets, but were virtually absent from the space between the rootlets. This suggests that the bulk of actin in the brush border is kept in a polymerized and cross-linked state and that horizontally deployed actin filaments are virtually absent. About 70% of the label specific for the 110-kD protein that links the microvillus core bundle to the lipid bilayer was found overlying the microvilli. The remaining label was associated with rootlets and the interrootlet space, where some label was regularly observed in association with vesicles. Since the terminal web did not contain any significant amounts of tubulin and microtubules, the present findings would support a recently proposed hypothesis that the 110-kD protein (which displays properties of an actin-activated, myosin-like ATPase) might also be involved in the transport of vesicles through the terminal web. Label specific for myosin and alpha-actinin was confined to the interrootlet space and was absent from the rootlets. About 10-15% of the myosin label and 70-80% of the alpha-actinin label was observed within the circumferential band of actin filaments at the zonula adherens, where myosin and alpha-actinin displayed a clustered, interrupted pattern that resembles the spacing of these proteins observed in other contractile systems. This circular filament ring did not contain villin, fimbrin, or the 110-kD protein. Finally, actin-specific label was observed in close association with the cytoplasmic aspect of the zonula occludens, suggesting that tight junctions are structurally connected to the microfilament system.

Mapping of the microvillar 110K-calmodulin complex: calmodulin-associated or -free fragments of the 110-kD polypeptide bind F-actin and retain ATPase activity

The 110K-calmodulin complex isolated from intestinal microvilli is an ATPase consisting of one polypeptide chain of 110 kD in association with three to four calmodulin molecules. This complex is presumably the link between the actin filaments in the microvillar core and the surrounding cell membrane. To study its structural regions, we have partially cleaved the 110K-calmodulin complex with alpha-chymotrypsin; calmodulin remains essentially intact under the conditions used. As determined by 125I-calmodulin overlays, ion exchange chromatography, and actin-binding assays, a 90-kD digest fragment generated in EGTA remains associated with calmodulin. The 90K-calmodulin complex binds actin in an ATP-reversible manner and decorates actin filaments with an arrow-head appearance similar to that found after incubation of F-actin with the parent complex; binding occurs in either calcium- or EGTA-containing buffers. ATPase activity of the 90-kD digest closely resembles the parent complex. In calcium a digest mixture containing fragments of 78 kD, a group of three at approximately 40 kD, and a 32-kD fragment (78-kD digest mixture) is generated with alpha-chymotrypsin at a longer incubation time; no association of these fragments with calmodulin is observed. Time courses of digestions and cyanogen bromide cleavage indicate that the 78-kD fragment derives from the 90-kD peptide. The 78-kD mixture can also hydrolyze ATP. Furthermore, removal of the calmodulin by ion exchange chromatography from this 78-kD mixture had no effect on the ATPase activity of the digest, indicating that the ATPase activity resides on the 110-kD polypeptide. The 78 kD, two of the three fragments at approximately 40 kD, and the 32-kD fragments associate with F-actin in an ATP-reversible manner. Electron microscopy of actin filaments after incubation with the 78-kD digest mixture reveals coated filaments, although the prominent arrowhead appearance characteristic of the parent complex is not observed. These data indicate that calmodulin is not required either for the ATPase activity or the ATP-reversible binding of the 110K-calmodulin complex to F-actin. In addition, since all the fragments that bind F-actin do so in an ATP-reversible manner, the sites required for F-actin binding and ATP reversibility likely reside nearby.

ATPase activity of the microvillar 110 kDa polypeptide-calmodulin complex is activated in Mg2+ and inhibited in K+-EDTA by F-actin

Highly purified microvillar 110 kDa polypeptide-calmodulin (110K-cam) complex was confirmed to have ATPase activities characteristic of a myosin. The effect of F-actin on these activities was investigated. The Mg2+-ATPase is activated about 2-fold by F-actin in a dose-dependent fashion, whereas the K+-EDTA-ATPase is inhibited by greater than 90% by F-actin. These data provide evidence for a functional relationship between the ATPase activity of 110K-cam and its interaction with F-actin. They also extend the similarities between 110K-cam and myosin. The results suggest that higher cells contain in addition to myosin a second class of myosin-like molecules represented by 110K-cam.

The 110-kD protein-calmodulin complex of the intestinal microvillus is an actin-activated MgATPase

The microvillus 110-kD protein-calmodulin complex (designated 110K-CM) shares several properties with all myosins. In addition to its well-defined ATP-dependent binding interaction with F-actin, 110K-CM is an ATPase with diagnostically myosin-like divalent cation sensitivity. It exhibits maximum enzymatic activity in the presence of K+ and EDTA (0.24 mumol P1/mg per min) or in the presence of Ca++ (0.40 mumol P1/mg per min) and significantly less activity in physiological ionic conditions of salt and Mg++ (0.04 mumol P1/mg per min). This MgATPase is activated by F-actin in an actin concentration-dependent manner (up to 2.5-3.5-fold). The specific MgATPase activity of 110K-CM is also enhanced by the addition of 5-10 microM Ca++, but in the isolated complex, there is often also a decrease in the extent of actin activation in this range of free Ca++. Actin activation is maintained, however, in samples with exogenously added calmodulin; under these conditions, there is an approximately sevenfold stimulation of 110K-CM's enzymatic activity in the presence of 5-10 microM Ca++ and actin. 110K-CM is relatively indiscriminant in its nucleoside triphosphate specificity; in addition to ATP, GTP, CTP, UTP, and ITP are all hydrolyzed by the complex in the presence of either Mg++ or Ca++. Neither AMP nor the phosphatase substrate p-nitrophenyl phosphate are substrates for the enzymatic activity. The pH optimum for CaATPase activity is 6.0-7.5; maximum actin activation of MgATPase occurs over a broad pH range of 6.5-8.5. Finally, like myosins, purified 110K-CM crosslinks actin filaments into loosely ordered aggregates in the absence of ATP. Collectively these data support the proposal of Collins and Borysenko (1984, J. Biol. Chem., 259:14128-14135) that the 110K-CM complex is functionally analogous to the mechanoenzyme myosin.

Calcium-regulated cooperative binding of the microvillar 110K-calmodulin complex to F-actin: formation of decorated filaments

The 110K-calmodulin complex of intestinal microvilli is believed to be the link between the actin filaments comprising the core bundle and the surrounding cell membrane. Although not the first study describing a purification scheme for the 110K-calmodulin complex, a procedure for the isolation of stable 110K-calmodulin complex both pure and in high yield is presented; moreover, isolation is without loss of the associated calmodulin molecules since a previously determined ratio in isolated microvillar cytoskeletons of calmodulin to 110-kD polypeptide of 3.3:1 is preserved. We have found that removal of calmodulin from the complex by the calmodulin antagonists W7 or W13 results in precipitation of the 110-kD polypeptide with calmodulin remaining in solution. The interaction of 110K-calmodulin with beef skeletal muscle F-actin has been examined. Cosedimentation assays of 110K-calmodulin samples incubated with F-actin show the amount of 110K-calmodulin associating with F-actin to be ATP, calcium, and protein concentration dependent; however, relatively salt independent. In calcium, approximately 30% of the calmodulin remains in the supernatant rather than cosedimenting with the 110-kD polypeptide and actin. Electron microscopy of actin filaments after incubation with 110K-calmodulin in either calcium- or EGTA-containing buffers show polarized filaments often laterally associated. Each individual actin filament is seen to exhibit an arrowhead appearance characteristic of actin filaments after their incubation with myosin fragments, heavy meromyosin and subfragment 1. In some cases projections having a 33-nm periodicity are observed. This formation of periodically spaced projections on actin filaments provides further compelling evidence that the 110K-calmodulin complex is the bridge between actin and the microvillar membrane.

Calmodulin and calmodulin-binding proteins in the renal brush border

The calmodulin content of renal brush-border membrane vesicles, prepared by Mg2+-precipitation in EGTA-containing solutions, amounts to 1.8 micrograms per mg protein. The amount and the distribution of this EGTA-insensitive calmodulin was determined in membrane and cytoskeletal fractions prepared from the brush-border membrane vesicles by extraction with Triton X-100. The Triton X-100 insoluble pellet contains 21.2% of the protein and 52.2% of the EGTA-insensitive calmodulin, which amounts in this fraction to 4.4 micrograms per mg protein. Treatment of the Triton X-100 insoluble pellet, consisting of the microvillar core residue, with ATP and Mg2+ results in the solubilization of a relatively small number of proteins among which are actin, myosin, calmodulin and several calmodulin-binding proteins. The solubilization is partially reversible and a fraction of the proteins can be precipitated by centrifugation after the enzymatic hydrolysis of ATP. Readdition of ATP to the pellet results in the resolubilization of myosin, part of the actin, an 115-kDa calmodulin-binding protein and calmodulin. The calmodulin content of the final extract was 61.8 micrograms per mg protein. We have found roughly the same distribution pattern of calmodulin and ATP-solubilized, calmodulin-binding proteins in renal and intestinal brush-border preparations. The calmodulin content, however, as well as the relative amount of the calmodulin-binding proteins versus actin are about 4 to 5-times higher in intestinal than in renal microvillar core residues.

Ciliary membrane tubulin and associated proteins: a complex stable to Triton X-114 dissociation

When either membranes from scallop gill cilia or reconstituted membranes from the same source are solubilized with Triton X-114 and the detergent is condensed by warming, no significant fraction of any major membrane protein partitions into the micellar detergent. Rather, most of the membrane lipids condense with the detergent phase, forming mixed micelles from which nearly pure lipid vesicles may be produced by adsorption of detergent with polystyrene beads. One minor membrane protein, with a molecular weight of about 20 000, is associated consistently with these vesicles. The aqueous phase contains a fairly homogeneous protein-Triton X-114 micelle sedimenting at 2.6 S in the analytical ultracentrifuge. Sucrose gradient velocity analysis in a detergent-free gradient indicates moderate size polydispersity but constant polypeptide composition throughout the sedimenting protein zone. Sucrose gradient equilibrium analysis (also in a detergent-free gradient) results in a protein-detergent complex banding at a density of 1.245 g/cm3. Sedimentation of the protein-detergent complex in the ultracentrifuge, followed by fixation and normal processing for electron microscopy, reveals a fine, reticular material consisting of 5-10-nm granules. These data are consistent with previous evidence that membrane tubulin and most other membrane proteins exist together as a discrete lipid-protein complex in molluscan gill ciliary membranes.

1,25-Dihydroxyvitamin D increases calmodulin binding to specific proteins in the chick duodenal brush border membrane

In previous studies we demonstrated that the biologically active vitamin D metabolite 1,25-dihydroxyvitamin D [1,25(OH)2D] increased the calmodulin (CaM) content of chick duodenal brush border membranes (BBM) without increasing the total cellular CaM content. Therefore, we evaluated the binding of CaM to discrete proteins in the BBM and determined whether 1,25(OH)2D could influence such binding. We observed one major and several minor CaM-binding bands on autoradiograms of sodium dodecyl sulfate polyacrylamide gels incubated with [125I]CaM. The major band had a molecular weight of 102,000-105,000. It bound CaM even in the presence of EGTA, but not in the presence of trifluoperazine or excess nonradioactive CaM. The administration of 1,25(OH)2D increased the apparent binding of CaM to this protein as assessed by densitometry of the autoradiogram. This increase in CaM binding coincided with the increased ability of the same BBM vesicles to accumulate calcium. Cycloheximide in doses that markedly reduced the incorporation of [35S]methionine into BBM proteins did not reduce the ability of 1,25-dihydroxyvitamin D3 to stimulate either calcium uptake by the BBM vesicles or CaM binding to the 102,000-105,000-mol-wt protein. These results suggest that 1,25(OH)2D administration increases the CaM content of duodenal BBM by increasing the ability of a 102,000-105,000-mol-wt protein to bind CaM. This mechanism may underlie the ability of 1,25(OH)2D to stimulate calcium movement across the intestinal BBM.