UBA domains mediate protein-protein interactions between two DNA damage-inducible proteins.

The Saccharomyces cerevisiae genes RAD23 and DDI1 were identified in a screen for multicopy suppressors of the temperature-sensitivity of a mutant allele of S. cerevisiae PDS1. Pds1 is a regulator of anaphase that needs to accumulate and then be degraded by the ubiquitin-proteasome pathway at the metaphase-anaphase transition for cells to progress normally through mitosis. Both the Rad23 and Ddi1 pds1 suppression phenotypes depend on a shared motif known as a UBA domain found in a variety of proteins associated with ubiquitin metabolism. UBA domains were found to be essential for homodimerization of Rad23 and heterodimerization between Rad23 and Ddi1, but not for homodimerization of Ddi1. This observation, coupled with the findings that Rad23 and Ddi1 UBA domains bind ubiquitin and that dimerization of Rad23 blocks ubiquitin binding, suggests a possible mechanism for regulating Rad23 and Ddi1 function.

UBA domains of DNA damage-inducible proteins interact with ubiquitin.

Rad23 is a highly conserved protein involved in nucleotide excision repair (NER) that associates with the proteasome via its N-terminus. Its C-terminal ubiquitin-associated (UBA) domain is evolutionarily conserved from yeast to humans. However, the cellular function of UBA domains is not completely understood. Recently, RAD23 and DDI1, both DNA damage-inducible genes encoding proteins with UBA domains, were implicated genetically in Pds1-dependent mitotic control in yeast. The UBA domains of RAD23 and DDI1 are required for these interactions. Timely degradation of Pds1 via the ubiquitin/proteasome pathway allows anaphase onset and is crucial for chromosome maintenance. Here, we show that Rad23 and Ddi1 interact directly with ubiquitin and that this interaction is dependent on their UBA domains, providing a possible mechanism for UBA-dependent cell cycle control. Moreover, we show that a hydrophobic surface on the UBA domain, which from structural work had been predicted to be a protein-protein interaction interface, is indeed required for ubiquitin binding. By demonstrating that UBA domains interact with ubiquitin, we have provided the first indication of a cellular function for the UBA domain.

Crystal structure and mutational analysis of the Saccharomyces cerevisiae cell cycle regulatory protein Cks1: implications for domain swapping, anion binding and protein interactions.

BACKGROUND: The Saccharomyces cerevisiae protein Cks1 (cyclin-dependent kinase subunit 1) is essential for cell-cycle progression. The biological function of Cks1 can be modulated by a switch between two distinct molecular assemblies: the single domain fold, which results from the closing of a beta-hinge motif, and the intersubunit beta-strand interchanged dimer, which arises from the opening of the beta-hinge motif. The crystal structure of a cyclin-dependent kinase (Cdk) in complex with the human Cks homolog CksHs1 single-domain fold revealed the importance of conserved hydrophobic residues and charged residues within the beta-hinge motif. RESULTS: The 3.0 A resolution Cks1 structure reveals the strict structural conservation of the Cks alpha/beta-core fold and the beta-hinge motif. The beta hinge identified in the Cks1 structure includes a novel pivot and exposes a cluster of conserved tyrosine residues that are involved in Cdk binding but are sequestered in the beta-interchanged Cks homolog suc1 dimer structure. This Cks1 structure confirms the conservation of the Cks anion-binding site, which interacts with sidechain residues from the C-terminal alpha helix of another subunit in the crystal. CONCLUSIONS: The Cks1 structure exemplifies the conservation of the beta-interchanged dimer and the anion-binding site in evolutionarily distant yeast and human Cks homologs. Mutational analyses including in vivo rescue of CKS1 disruption support the dual functional roles of the beta-hinge residue Glu94, which participates in Cdk binding, and of the anion-binding pocket that is located 22 A away and on an opposite face to Glu94. The Cks1 structure suggests a biological role for the beta-interchanged dimer and the anion-binding site in targeting Cdks to specific phosphoproteins during cell-cycle progression.

Resting energy expenditure and prediction equations in young children with failure to thrive.

OBJECTIVE: To compare predicted and measured resting energy expenditure (REE) in young children (birth to 3 years) with failure to thrive (FTT). METHODS: REE (kcal/d) was measured by indirect calorimetry and compared with predicted REE from 3 sex and age group equations: World Health Organization (WHO), Schofield weight-based (SCH-WT), and Schofield weight- and height-based (SCH-WT-HT). The clinical characteristics associated with inaccuracy of predicted REE were examined. RESULTS: Forty-five subjects (47% female) were evaluated. Their clinical characteristics (mean +/- SD) included age 1.2 +/- 0.7 years, length/height z score -2.1 +/- 1.3, weight z score -2.7 +/- 1.0, and measured REE 438 +/- 111 kcal/d. All prediction equations were within 10% accuracy <50% of the time. However, SCH-WT-HT did not significantly differ from measured REE (450 +/- 138 vs 438 +/- 111 kcal/d, P =.2) and was least likely to underestimate REE. Younger age and more severe growth failure (based on weight, length/height, or both) were associated with underestimation of REE by prediction equations. CONCLUSION: REE should be measured in young infants and children with moderate to severe FTT when knowledge of caloric needs is required for optimal clinical care. The SCH-WT-HT equation was least likely to underestimate REE and is therefore preferred when REE cannot be measured in this group of children.

Nutritional aspects of manganese from experimental studies.

In experimental animals, dietary manganese deficiency can result in numerous biochemical and structural abnormalities. Deficient animals can be characterized by impaired insulin production, alterations in lipoprotein metabolism, an impaired oxidant defense system, and perturbations in growth factor metabolism. If the deficiency occurs during early development, there can be pronounced skeletal abnormalities and an irreversible ataxia. Several lines of evidence suggest that manganese deficiency may be a problem in some human populations. Manganese toxicity can also pose a significant health risk. In experimental animals, acute manganese toxicity can result in numerous biochemical pathologies. However, the above occurs typically when the manganese is given via injection; most animals show considerable resistance to dietary manganese toxicosis. Similarly, confirmed cases of manganese toxicity in humans are currently restricted to cases of exposure to high levels of airborne manganese, and to cases when manganese excretory pathways are compromised.

Cyclin-dependent kinase and Cks/Suc1 interact with the proteasome in yeast to control proteolysis of M-phase targets.

Cell cycle-specific proteolysis is critical for proper execution of mitosis in all eukaryotes. Ubiquitination and subsequent proteolysis of the mitotic regulators Clb2 and Pds1 depend on the cyclosome/APC and the 26S proteasome. We report here that components of the cell cycle machinery in yeast, specifically the cell cycle regulatory cyclin-dependent kinase Cdc28 and a conserved associated protein Cks1/Suc1, interact genetically, physically, and functionally with components of the 26S proteasome. A mutation in Cdc28 (cdc28-1N) that interferes with Cks1 binding, or inactivation of Cks1 itself, confers stabilization of Clb2, the principal mitotic B-type cyclin in budding yeast. Surprisingly, Clb2-ubiquitination in vivo and in vitro is not affected by mutations in cks1, indicating that Cks1 is not essential for cyclosome/APC activity. However, mutant Cks1 proteins no longer physically interact with the proteasome, suggesting that Cks1 is required for some aspect of proteasome function during M-phase-specific proteolysis. We further provide evidence that Cks1 function is required for degradation of the anaphase inhibitor Pds1. Stabilization of Pds1 is partially responsible for the metaphase arrest phenotype of cks1 mutants because deletion of PDS1 partially relieves the metaphase block in these mutants.

Insurance reimbursement for the treatment of obesity in children.

OBJECTIVE: Although the prevalence of obesity among children in the United States is rapidly increasing, third party payer reimbursement for evaluation and management may be limited. The purpose of this analysis is to evaluate third party payer reimbursement rates for a pediatric weight management program for obese children and associations among child characteristics (eg, degree of obesity), insurance policy type, and reimbursement rates. STUDY DESIGN: Cross-sectional survey in a tertiary care pediatric medical center. Reimbursement rate of charges for initial evaluation and management and patient characteristics were evaluated for children 2 years or older enrolled in the Children's Hospital Weight Management Program. RESULTS: From October 17, 1995, to December 23, 1997, 191 children were evaluated in the Children's Hospital Weight Management Program. The children were on average 10.1 0.3 years old, with a mean body mass index z-score of 4.9 0.2; 46% were black, and 65% were female. The median reimbursement rate was 11% and varied widely (0% to 100%). Reimbursement rates differed significantly among policy types. Reimbursement rates did not differ between boys and girls or white and black children, nor were reimbursement rates associated with the degree of obesity. CONCLUSIONS: Despite the need for weight management services for obese children, these low reimbursement rates preclude the long-term financial viability of such programs without external support or a significant proportion of patients who can pay "out-of-pocket."

Bmk1/Erk5 is required for cell proliferation induced by epidermal growth factor.

Epidermal growth factor (EGF) induces cell proliferation in a variety of cell types by binding to a prototype transmembrane tyrosine kinase receptor. Ligation of this receptor by EGF activates Erk1 and Erk2, members of the mitogen-activated protein (MAP) kinase family, through a Ras-dependent signal transduction pathway. Despite our detailed understanding of these events, the exact mechanism by which EGF causes cells to proliferate is unclear. Big MAP kinase (Bmk1), also known as Erk5, is a member of the MAP kinase family that is activated in cells in response to oxidative stress, hyperosmolarity and treatment with serum. Here we show that EGF is a potent activator of Bmk1. In contrast to Erk1/2, EGF-mediated activation of Bmk1 occurs independently of Ras and requires the MAP-kinase kinase Mek5. Expression of a dominant-negative form of Bmk1 blocks EGF-induced cell proliferation and prevents cells from entering the S phase of the cell cycle. These results demonstrate that Bmk1 is part of a distinct MAP-kinase signalling pathway that is required for EGF-induced cell proliferation and progression through the cell cycle.

A mutation in the human cyclin-dependent kinase interacting protein, CksHs2, interferes with cyclin-dependent kinase binding and biological function, but preserves protein structure and assembly.

A mutation directing an amino acid substitution in the conserved beta-hinge region of one of the human Cks isoforms, CksHs2, was constructed by site-directed mutagenesis. Replacement of glutamine for glutamate 63 (E63Q) was predicted to stabilize the beta-interchanged dimeric and hexameric assembly of CksHs2. However, such an effect was seen only at high, non-physiological pH. Three-dimensional structures of the E63Q hexameric mutant protein were determined to 2.6 A resolution in a P4(3)2(1)2 space group and 2.1 A in the C2 space group isostructural with wild-type, and both were shown to be virtually identical to the refined 1.7 A wild-type structure. Thus, the E63Q mutation did not alter the wild-type structure and assembly of CksHs2 but, surprisingly, disrupted the essential biological function of the protein and significantly reduced its ability to bind to cyclin-dependent kinases. The Kd of wild-type CksHs2 for CDK2 was 5.05 x 10(-8) M, whereas the affinity of the mutant protein for CDK2 was too low to allow a determination. These data, coupled with the observation that monomeric but not hexameric CksHs2 interacts with cyclin-dependent kinases, suggest that glutamine 63 is likely to be directly involved in cyclin-dependent kinase binding in vitro and in vivo.

Crystal structure and mutational analysis of the human CDK2 kinase complex with cell cycle-regulatory protein CksHs1.

The 2.6 Angstrom crystal structure for human cyclin-dependent kinase 2(CDK2) in complex with CksHs1, a human homolog of essential yeast cell cycle-regulatory proteins suc1 and Cks1, reveals that CksHs1 binds via all four beta strands to the kinase C-terminal lobe. This interface is biologically critical, based upon mutational analysis, but far from the CDK2 N-terminal lobe, cyclin, and regulatory phosphorylation sites. CDK2 binds the Cks single domain conformation and interacts with conserved hydrophobic residues plus His-60 and Glu-63 in their closed beta-hinge motif conformation. The beta hinge opening to form the Cks beta-interchanged dimer sterically precludes CDK2 binding, providing a possible mechanism regulating CDK2-Cks interactions. One face of the complex exposes the sequence-conserved phosphate-binding region on Cks and the ATP-binding site on CDK2, suggesting that CKs may target CDK2 to other phosphoproteins during the cell cycle.

Crystal structure of the cell cycle-regulatory protein suc1 reveals a beta-hinge conformational switch.

The Schizosaccharomyces pombe cell cycle-regulatory protein suc1, named as the suppressor of cdc2 temperature-sensitive mutations, is essential for cell cycle progression. To understand suc1 structure-function relationships and to help resolve conflicting interpretations of suc1 function based on genetic studies of suc1 and its functional homologs in both lower and higher eukaryotes, we have determined the crystal structure of the beta-interchanged suc1 dimer. Each domain consists of three alpha-helices and a four-stranded beta-sheet, completed by the interchange of terminal beta-strands between the two subunits. This beta-interchanged suc1 dimer, when compared with the beta-hairpin single-domain folds of suc1, reveals a beta-hinge motif formed by the conserved amino acid sequence HVPEPH. This beta-hinge mediates the subunit conformation and assembly of suc1: closing produces the intrasubunit beta-hairpin and single-domain fold, whereas opening leads to the intersubunit beta-strand interchange and interlocked dimer assembly reported here. This conformational switch markedly changes the surface accessibility of sequence-conserved residues available for recognition of cyclin-dependent kinase, suggesting a structural mechanism for beta-hinge-mediated regulation of suc1 biological function. Thus, suc1 belongs to the family of domain-swapping proteins, consisting of intertwined and dimeric protein structures in which the dual assembly modes regulate their function.

Alignment of caldesmon on the actin-tropomyosin filaments.

We have reported previously that each smooth-muscle caldesmon binds predominantly to a region within residues 142-227 of tropomyosin, but a weaker binding site also exists at the N-terminal region of tropomyosin [Watson, Kuhn, Novy, Lin and Mak (1990) J. Biol. Chem. 265, 18860-18866]. In view of recent evidence for the presence of tropomyosin-binding sites at both the N- and C-terminal domains of caldesmon, we have studied the binding of the N- and C-terminal fragments of human fibroblast caldesmon expressed in Escherichia coli to tropomyosin and its CNBr fragments. The N-terminal fragment, CaD40 (residues 1-152), binds tropomyosin, but the interaction is mostly abolished in the presence of actin. CaD40 binds strongly to Cn1B(142-281) of tropomyosin, but weakly to Cn1A(11-127). The C-terminal fragment, CaD39, which corresponds to residues 443-736 of gizzard caldesmon, binds tropomyosin, and the interaction is enhanced by actin. CaD39 binds to both Cn1A(11-127) and Cn1B(142-281) of tropomyosin. Our results suggest that the N-terminal domain of caldesmon interacts with the C-terminal half of one tropomyosin molecule, whereas the C-terminal domain binds to both N- and C-terminal regions of the adjacent tropomyosin molecule along the actin filament. In addition, the binding of the N-terminal domain of caldesmon to the actin-tropomyosin filament is weak, which may allow this domain to project off the thin filament to interact with myosin.

Phosphorylation of the precursor sequence of rat B-type natriuretic peptide by p34cdc2 and MAP kinase.

Atrial natriuretic peptide (ANP) and B-type natriuretic peptide (BNP), two distinct members of the natriuretic peptide family, share many features in common. However, differences in expression indicate that the processing mechanisms must be different. The leader sequence of rat BNP contains three potential phosphorylation sites for proline-directed kinases that are not present in the leader sequence of ANP. This study has examined how these sites are used by two somewhat different proline-directed kinases. A peptide containing these sites was phosphorylated in vitro by HeLa p34cdc2 kinase and by sea star p44mpk kinase at rates that were comparable to the rates with peptide substrates that are used to assay these enzymes. Sequence analysis of the phosphopeptide shows that both kinases phosphorylate only the two potential phosphorylation sites surrounding the cleavage site of the BNP precursor. The enzymatic potential for such a phosphorylation of BNP in cardiac tissue is demonstrated by immunoblots and kinase assays, showing that in fetal and in adult rat heart both the atria and the ventricles contain a mitogen-activated protein kinase homologue that can phosphorylate this preproBNP sequence.

Smooth muscle cell proliferation. Expression and kinase activities of p34cdc2 and mitogen-activated protein kinase homologues.

Rat vascular smooth muscle cells were synchronized to the quiescent state (G0) by serum deprivation and then stimulated to enter the cell cycle by serum refeeding. At various times of the cell cycle, cells were analyzed for the expression of p34cdc2 and mitogen-activated protein kinase homologues by immunoblotting and for kinase activity toward histone H1, myelin basic protein, and caldesmon. A small amount of p34cdc2 was expressed in the G0/G1 phase (0 to 8 hours). At the G1/S transition (12 hours), the level of p34cdc2 started to accumulate and increased by 60-fold at G2/M (18 hours), accompanied by a more slowly migrating band. Histone H1 kinase activity was undetectable in anti-p34cdc2 immunoprecipitates in the G0/G1 cells but appeared around the G1/S boundary and peaked at G2/M (18 hours). The caldesmon kinase activity exhibited two distinct phases: the first appeared at G0/G1 (0 to 8 hours), and the second appeared at G1/S and continued through G2/M. Two mitogen-activated protein kinase isoforms were expressed throughout the cell cycle. Anti-mitogen-activated protein kinase immunoprecipitates possessed kinase activities toward myelin basic protein and caldesmon, which were activated within 15 minutes after serum stimulation and declined within a few hours. These findings suggest that p34cdc2 and mitogen-activated protein kinase homologues may play significant roles in regulating the progression of the cell cycle of smooth muscle cells, the former at the G2/M transition and the latter at the G0/G1 transition.

Differential expression and activity of p34cdc2 in cultured aortic adventitial fibroblasts derived from spontaneously hypertensive and Wistar-Kyoto rats.

OBJECTIVE: The present investigation was undertaken to determine whether p34cdc2, a cell-cycle regulatory kinase, is involved in the manifestation of the altered proliferation evident in fibroblasts isolated from spontaneously hypertensive rats (SHR). DESIGN: Experiments were performed on quiescent aortic adventitial fibroblasts stimulated to re-enter the cell cycle in order to examine the timing of cell cycle-related events. METHODS: The cell-cycle phase was determined by flow cytometry and was related to the cellular content and kinase activity of p34cdc2. RESULTS: SHR fibroblasts displayed a heightened basal level of p34cdc2 at quiescence relative to Wistar-Kyoto (WKY) rat cells. Both SHR and WKY fibroblasts showed a cell cycle-dependent increase in p34cdc2 content, beginning in S phase. However, the SHR adventitial fibroblasts exited G0-G1 several hours earlier than the WKY fibroblasts as indicated by the time of initiation of DNA synthesis and increase in activity of p34cdc2. CONCLUSIONS: SHR aortic adventitial fibroblasts appear to have a heightened proliferative capacity relative to WKY fibroblasts, which is evident in a quicker exit from G0 and faster transition to DNA synthesis, followed by the earlier activation of p34cdc2.

Phosphorylation of smooth muscle caldesmon by mitogen-activated protein (MAP) kinase and expression of MAP kinase in differentiated smooth muscle cells.

Smooth muscle caldesmon was phosphorylated in vitro by sea star p44mpk up to 2.0 mol of phosphate/mol of protein at both Ser and Thr residues. The phosphorylation sites were contained mainly in the COOH-terminal 10-kDa cyanogen bromide fragment which houses the binding sites for calmodulin, tropomyosin, and F-actin. Tryptic peptide maps of 32P-labeled caldesmon by p44mpk and p34cdc2 showed that while both enzymes recognized similar sites of phosphorylation, they have different preferred sites. Phosphorylation of caldesmon attenuated slightly its interaction with actin and had no effect on its binding to calmodulin and tropomyosin. Smooth muscle cell extracts from chicken gizzard and rat aorta contained 42- and 44-kDa proteins, respectively, which were cross-reactive with an antibody to sea star p44mpk. Immunoprecipitates from gizzard and aorta cell extracts, generated with the p44mpk antibody, possessed kinase activities toward myelin basic protein as well as caldesmon. These results suggest that MAP kinase may have functions in the differentiated smooth muscle cells distinct from those involved in the cell cycle.

Calponin and tropomyosin interactions.

The interaction between chicken gizzard calponin and tropomyosin was examined using viscosity, light scattering, electron microscopy and affinity chromatography. At neutral pH, 10 mM NaCl and in the absence of Mg2+, calponin induced tropomyosin filaments to form paracrystals thus decreasing the viscosity while increasing dramatically the light scattering of the tropomyosin solution. Electron micrographs of the uranyl acetate stained calponin-tropomyosin complex showed the presence of spindle shaped paracrystals with regular striation patterns and repeating units of about 400 A. Under similar conditions, smooth muscle caldesmon also induced tropomyosin to form paracrystals. To localize the calponin-binding site on tropomyosin, binding of fragments of tropomyosin, generated by chemical and mutational means, to a calponin-affinity column was studied. The COOH-terminal tropomyosin fragment Cn1B(142-281) and the NH2-terminal fragment CSM-beta(1/8/12-227) bound to a calponin-affinity column with an affinity similar to that of intact tropomyosin; while the NH2-terminal fragment, Cn1A(11-127), did not bind, indicating that the calponin-binding site(s) resides within residues 142-227 of tropomyosin. To determine the involvement in calponin binding of the area around Cys-190 of tropomyosin, fragments with cleavage sites near or at Cys-190 were used. Thus, while fragments Cy2(190-284) and CSM-beta(1/8/12-200) bound weakly to the calponin-affinity column, fragment Cy1(1-189) did not. These results demonstrate that calponin binds to tropomyosin between residues 142 and 227, and that the integrity of the region around Cys-190 of tropomyosin is important for strong interaction between the two proteins.

Phosphorylation of caldesmon by cdc2 kinase.

A recent report that mitosis-specific phosphorylation causes the nonmuscle caldesmon to dissociate from microfilaments (Yamashiro, S., Yamakita, Y., Ishikawa, R., and Matsumura, F. (1990) Nature 344, 675-678) suggests that this process may contribute to the major structural reorganization of the eukaryotic cell at mitosis. In this study we have demonstrated that smooth muscle caldesmon is phosphorylated in vitro by cdc2 kinase from mitotic phase HeLa cells to 1.2 mol of phosphate/mol of caldesmon. Tryptic maps showed three major phosphorylated spots and approximately equal amounts of phosphorylated Ser and Thr were identified. F-actin or calmodulin in the presence of Ca2+ blocks the phosphorylation of caldesmon. Phosphorylation of caldesmon greatly reduced its binding to F-actin. The phosphorylation sites were located in a 10,000-Da CnBr fragment at the COOH-terminal end of the caldesmon molecule known to house the binding sites for actin and calmodulin (Bartegi A., Fattoum, A., Derancourt, J., and Kassab, R. (1990) J. Biol. Chem. 265, 15231-15238). Our finding supports the model that phosphorylation of caldesmon by cdc2 kinase at mitosis may contribute to the disassembly of the microfilament bundles during prophase.

Caldesmon-binding sites on tropomyosin.

The interaction of chicken gizzard caldesmon with fragments of tropomyosin, generated by chemical, enzymatic, and mutational means, was studied to determine the caldesmon-binding site(s) on tropomyosin. Binding was examined by fluorescence spectroscopy and affinity chromatography. Removal of residues 1-141 and 228-284, respectively, from the NH2 and COOH ends of tropomyosin did not affect its binding to caldesmon significantly, indicating that the major, caldesmon-binding region lies between residues 142-227. The Escherichia coli produced chicken gizzard beta-tropomyosin mutant, CSM-beta (1/8/12-227), bound caldesmon about 2-fold stronger than a similar mutant of residues 8-200. This further focused the primary caldesmon-binding site to residues 201-227. Cleavage of tropomyosin at CYS-190 weakened markedly the binding of the two resulting fragments, residues 1-189 and 190-284, to caldesmon suggesting the requirement for the integrity of the caldesmon-binding region between residues 142227 of tropomyosin for strong interaction with caldesmon. Based on data from this study and others, we have proposed models for the interaction of tropomyosin with caldesmon in vitro, as well as the possible arrangement of the smooth muscle thin filament proteins in vivo.

Caldesmon, calmodulin and tropomyosin interactions.

Binary complex interactions between caldesmon and tropomyosin, and calmodulin and tropomyosin, and ternary complex interaction involving the three proteins were studied using viscosity, electron microscopy, fluorescence and affinity chromatography techniques. In 10 mM NaCl, caldesmon decreased the viscosity of chicken gizzard tropomyosin by 7-8 fold with a concomitant increase in turbidity (A330nm). Electron micrographs showed spindle-shaped particles in the tropomyosin-caldesmon samples. These results suggest side-by-side aggregation of tropomyosin polymers induced by caldesmon. Binding studies in 10 mM NaCl between caldesmon and chicken gizzard tropomyosin labelled with the fluorescent probe N-(1-anilinonaphthyl-4)maleimide (ANM) gave association constants from 5.3.10(6) to 7.9.10(6) M-1 and stoichiometry from 1.0 to 1.4 tropomyosin per caldesmon. Similar binding was observed for rabbit cardiac tropomyosin and caldesmon. Removal of 18 and 11 residues from the COOH ends of the gizzard and cardiac tropomyosin by carboxypeptidase A, respectively, had no significant effect on their binding to caldesmon. In the presence of Ca2+, chicken gizzard tropomyosin bound to a calmodulin-Sepharose-4B column and was eluted with a salt concentration of 140 mM. This interaction was weakened in the absence of Ca2+, and the bound tropomyosin was eluted by 65 mM KCl. ANM-labelled tropomyosin bound calmodulin in the presence of Ca2+ with a binding constant of 3.5.10(6) M-1 and a binding stoichiometry of 1 to 1.4 tropomyosin per calmodulin. In 10 mM NaCl, calmodulin reduced the specific viscosity of chicken gizzard tropomyosin in the presence of Ca2+ by 5 fold, while a 1.5-fold reduction in viscosity was observed in the absence of Ca2+. In either case, no significant increase in turbidity was observed suggesting that calmodulin reduced head-to-tail polymerization of tropomyosin. The interaction of caldesmon with the calmodulin-ANM-tropomyosin complex in the presence and absence of Ca2+ was also examined. The result is consistent with a model that in the absence of Ca2+, calmodulin binds weakly to either caldesmon or tropomyosin and has little effect on the tropomyosin-caldesmon interaction; whereas, Ca2(+)-calmodulin interacts with caldesmon and reduces its affinity to tropomyosin.