A site-directed mutagenesis study of yeast calmodulin

Conserved properties of individual Ca2+-binding sites in calmodulin

Calmodulin (CaM) is a Ca(2+)-sensing protein that is highly conserved and ubiquitous in eukaryotes. In humans it is a locus of life-threatening cardiomyopathies. The primary function of CaM is to transduce Ca(2+) concentration into cellular signals by binding to a wide range of target proteins in a Ca(2+)-dependent manner. We do not fully understand how CaM performs its role as a high-fidelity signal transducer for more than 300 target proteins, but diversity among its four Ca(2+)-binding sites, called EF-hands, may contribute to CaM's functional versatility. We therefore looked at the conservation of CaM sequences over deep evolutionary time, focusing primarily on the four EF-hand motifs. Expanding on previous work, we found that CaM evolves slowly but that its evolutionary rate is substantially faster in fungi. We also found that the four EF-hands have distinguishing biophysical and structural properties that span eukaryotes. These results suggest that all eukaryotes require CaM to decode Ca(2+) signals using four specialized EF-hands, each with specific, conserved traits. In addition, we provide an extensive map of sites associated with target proteins and with human disease and correlate these with evolutionary sequence diversity. Our comprehensive evolutionary analysis provides a basis for understanding the sequence space associated with CaM function and should help guide future work on the relationship between structure, function, and disease.

The many faces of calmodulin in cell proliferation, programmed cell death, autophagy, and cancer

Calmodulin (CaM) is a ubiquitous Ca(2+) receptor protein mediating a large number of signaling processes in all eukaryotic cells. CaM plays a central role in regulating a myriad of cellular functions via interaction with multiple target proteins. This review focuses on the action of CaM and CaM-dependent signaling systems in the control of vertebrate cell proliferation, programmed cell death and autophagy. The significance of CaM and interconnected CaM-regulated systems for the physiology of cancer cells including tumor stem cells, and processes required for tumor progression such as growth, tumor-associated angiogenesis and metastasis are highlighted. Furthermore, the potential targeting of CaM-dependent signaling processes for therapeutic use is discussed.

Specific conformation and Ca(2+)-binding mode of yeast calmodulin: insight into evolutionary development

The vertebrate calmodulin is configured with two structurally independent globular lobes in N- and C-terminus, and a flexible central linker. Distinctly, two lobes of calmodulin from Saccharomyces cerevisiae (yCaM) interact and influence the Ca(2+)-binding profile of each other. We explored this further using the mutant proteins with eliminated Ca(2+)-binding ability in one of the lobes and found that the Ca(2+)-bound N-lobe associates with the Ca(2+)-free C-lobe to gain the Ca(2+) affinity of a wild-type level. Next, analysing series of C-terminal residue truncation mutant, we found that the truncation of C-terminal three residues induce the hyper Ca(2+) affinity. These residues are also important for the general structural behaviour of calmodulin, such as Ca(2+)-induced slow mobility shift in polyacrylamide gel electrophoresis and for the ability to activate Cmk1p (yeast calmodulin kinase). These suggest: (i) when Ca(2+) occupies only N-lobe, two lobes interact and form the stable intermediate leading to a proper level of Ca(2+) affinity; (ii) the C-terminal three residues are required to prohibit abnormal stabilization of the intermediate promoting abnormally high Ca(2+) affinity and for recognition of target enzymes. A model for Ca(2+) and target bindings of yCaM is proposed. Evolutional aspect concerning the biological significance of this model was discussed.

Roles of the C-terminal residues of calmodulin in structure and function

Electrospray ionization mass spectrometry (ESI-MS), circular dichroism (CD), nuclear magnetic resonance (NMR) spectroscopy, flow dialysis, and bioactivity measurements were employed to investigate the roles of the C-terminal residues of calmodulin (CaM). In the present study, we prepared a series of truncated mutants of chicken CaM that lack four (CCMΔ4) to eight (CCMΔ8) residues at the C-terminal end. It was found that CCMΔ4, lacking the last four residues (M145 to K148), binds four Ca²⁺ ions. Further deletion gradually decreased the ability to bind the fourth Ca²⁺ ion, and CCMΔ8 completely lost the ability. Interestingly, both lobes of Ca²⁺-sturated CCMΔ5 showed instability in the conformation, although limited part in the C-lobe of Ca²⁺-saturated CCMΔ4 was instable. Moreover, unlike CCMΔ4, structure of the C-lobe in CCMΔ5 bound to the target displayed dissimilarity to that of CaM, suggesting that deletion of M144 changes the binding manner. Deletion of the last five residues (M144 to K148) and further truncation of the C-terminal region decreased apparent capacity for target activation. Little contribution of the last four residues including M145 was observed for structural stability, Ca²⁺-binding, and target activation. Although both M144 and M145 have been recognized as key residues for the function, the present data suggest that M144 is a more important residue to attain Ca²⁺ induced conformational change and to form a proper Ca²⁺-saturated conformation.

Stimulatory effects of arachidonic acid on myosin ATPase activity and contraction of smooth muscle via myosin motor domain

We have been searching for a mechanism to induce smooth muscle contraction that is not associated with phosphorylation of the regulatory light chain (RLC) of smooth muscle myosin (Nakamura A, Xie C, Zhang Y, Gao Y, Wang HH, Ye LH, Kishi H, Okagaki T, Yoshiyama S, Hayakawa K, Ishikawa R, Kohama K. Biochem Biophys Res Commun 369: 135–143, 2008). In this article, we report that arachidonic acid (AA) stimulates ATPase activity of unphosphorylated smooth muscle myosin with maximal stimulation (Rmax) of 6.84 ± 0.51 relative to stimulation by the vehicle and with a half-maximal effective concentration (EC50) of 50.3 ± 4.2 μM. In the presence of actin, Rmax was 1.72 ± 0.08 and EC50 was 26.3 ± 2.3 μM. Our experiments with eicosanoids consisting of the AA cascade suggested that they neither stimulated nor inhibited the activity. Under conditions that did not allow RLC to be phosphorylated, AA stimulated contraction of smooth muscle tissue with an Rmax of 1.45 ± 0.07 and an EC50 of 27.0 ± 4.4 μM. In addition to the ATPase activities of the myosin, AA stimulated those of heavy meromyosin, subfragment 1 (S1), S1 from which the RLC was removed, and a recombinant heavy chain consisting of the myosin head. The stimulatory effects of AA on these preparations were about twofold. The site of AA action was indicated to be the step-releasing inorganic phosphate (Pi) from the reaction intermediate of the myosin-ADP-Pi complex. The enhancement of Pi release by AA was supported by computer simulation indicating that AA docked in the actin-binding cleft of the myosin motor domain. The stimulatory effect of AA was detectable with both unphosphorylated myosin and the myosin in which RLC was fully phosphorylated. The AA effect on both myosin forms was suggested to cause excess contraction such as vasospasm.

Yeast telomerase subunit Est1p has guanine quadruplex-promoting activity that is required for telomere elongation

Telomeres are eukaryotic protein-DNA complexes found at the ends of linear chromosomes that are essential for maintaining genome integrity and are implicated in cellular aging and cancer. The guanine (G)-rich strand of telomeric DNA, usually elongated by the telomerase reverse transcriptase, can form a higher-order structure known as a G-quadruplex in vitro and in vivo. Several factors that promote or resolve G-quadruplexes have been identified, but the functional importance of these structures for telomere maintenance is not well understood. Here we show that the yeast telomerase subunit Est1p, known to be involved in telomerase recruitment to telomeres, can convert single-stranded telomeric G-rich DNA into a G-quadruplex structure in vitro in a Mg(2+)-dependent manner. Cells carrying Est1p mutants deficient in G-quadruplex formation in vitro showed gradual telomere shortening and cellular senescence, indicating a positive regulatory role for G-quadruplex in the maintenance of telomere length.

The vacuolar transporter chaperone (VTC) complex is required for microautophagy

Microautophagy involves direct invagination and fission of the vacuolar/lysosomal membrane under nutrient limitation. This occurs by an autophagic tube, a specialized vacuolar membrane invagination that pinches off vesicles into the vacuolar lumen. In this study we have identified the VTC (vacuolar transporter chaperone) complex as required for microautophagy. The VTC complex is present on the ER and vacuoles and at the cell periphery. On induction of autophagy by nutrient limitation the VTC complex is recruited to and concentrated on vacuoles. The VTC complex is inhomogeneously distributed within the vacuolar membranes, showing an enrichment on autophagic tubes. Deletion of the VTC complex blocks microautophagic uptake into vacuoles. The mutants still form autophagic tubes but the production of microautophagic vesicles from their tips is impaired. In line with this, affinity-purified antibodies to the Vtc proteins inhibit microautophagic uptake in a reconstituted system in vitro. Our data suggest that the VTC complex is an important constituent of autophagic tubes and that it is required for scission of microautophagic vesicles from these tubes.

Microautophagic Vacuole Invagination Requires Calmodulin in a Ca2+-independent Function

Microautophagy is the uptake of cytosolic compounds by direct invagination of the vacuolar/lysosomal membrane. In Saccharomyces cerevisiae microautophagic uptake of soluble cytosolic proteins occurs via an autophagic tube, a highly specialized vacuolar membrane invagination. Autophagic tubes are topologically equivalent to the invaginations at multivesicular endosomes. At the tip of an autophagic tube, vesicles (autophagic bodies) pinch off into the vacuolar lumen for degradation. In this study we have identified calmodulin (Cmd1p) as necessary for microautophagy. Temperature-sensitive mutants for Cmd1p displayed reduced frequencies of vacuolar tube formation and/or abnormal tube morphologies. Microautophagic vacuole invagination was sensitive to Cmd1p antagonists as well as to antibodies to Cmd1p. cmd1 mutants with substitutions in the Ca2+-binding domains showed full invagination activity, and vacuolar membrane invagination was independent of the free Ca2+ concentration. Thus, rather than acting as a calcium-triggered switch, Cmd1p has a constitutive Ca2+-independent role in the formation of autophagic tubes. Kinetic analysis indicates that calmodulin is required for autophagic tube formation rather than for the final scission of vesicles from the tip of the tube.

Solution X-ray scattering data show structural differences among chimeras of yeast and chicken calmodulin: implications for structure and function

We present here the first evidence, obtained by the use of small-angle X-ray scattering, of the solution structures of chimeras constructed from yeast (Saccharomyces cerevisiae, Sc) and chicken (Gallus gallus, Gg) calmodulin (CaM). The chimeric proteins used in this study are Sc(1-129)/Gg(130-148), Sc(1-128)/Gg(129-148), Sc(1-87)/Gg(88-148), and Sc(1-72)/Gg(73-148) CaMs, in which Sc(1-)(n)() and Gg(()(n)(+1)-148) descend from yeast and chicken CaM in the chimeric proteins, respectively. Under the Ca(2+)-saturated condition, the solution structure of Sc(1-128)/Gg(129-148) CaM has a dumbbell-like shape which is characteristic of vertebrate-type CaM, while that of Sc(1-129)/Gg(130-148) CaM takes an intermediate structure between the dumbbell-like shape and a compact globular shape. The results provide the direct evidence that the replacement of Asp(129) with Ser(129) induces an interaction between two lobes of Sc(1-129)/Gg(130-148) CaM and brings them close together. It implies that a site interacting with the N-lobe is induced in the C-lobe, although site IV that is unable to bind Ca(2+) hinders the ability of the C-lobe to undergo the conformational change to the full open state. In the presence of both Ca(2+) and a peptide synthesized to mimic the CaM binding domain on myosin light chain kinase, MLCK-22p, the solution structures of these chimeric CaMs take a similar compact globular shape but their interactions are quite different. The solution structure and interactions of Sc(1-72)/Gg(73-148) CaM are similar to those of Sc(1-87)/Gg(88-148) CaM. The structure of Sc(1-87)/Gg(88-148) CaM is similar to that of Sc(1-128)/Gg(129-148) CaM, but their interactions are different. The result indicates that the replacement of Glu(119) with Ala(119) has a critical effect on their interactions. Thus, the functional differences among these chimeric CaMs, which have been reported previously [Nakashima, K., et al. (1996) Biochemistry 35, 5602-5610], have been interpreted on the basis of the structures and interactions.

The solution structure of apocalmodulin from Saccharomyces cerevisiae implies a mechanism for its unique Ca2+ binding property

We have determined the solution structure of calmodulin (CaM) from yeast (Saccharomyces cerevisiae) (yCaM) in the apo state by using NMR spectroscopy. yCaM is 60% identical in its amino acid sequence with other CaMs, and exhibits its unique biological features. yCaM consists of two similar globular domains (N- and C-domain) containing three Ca(2+)-binding motifs, EF-hands, in accordance with the observed 3 mol of Ca(2+) binding. In the solution structure of yCaM, the conformation of the N-domain conforms well to the one of the expressed N-terminal half-domains of yCaM [Ishida, H., et al. (2000) Biochemistry 39, 13660-13668]. The conformation of the C-domain basically consists of a pair of helix-loop-helix motifs, though a segment corresponding to the forth Ca(2+)-binding site of CaM deviates in its primary structure from a typical EF-hand motif and loses the ability to bind Ca(2+). Thus, the resulting conformation of each domain is essentially identical to the corresponding domain of CaM in the apo state. A flexible linker connects the two domains as observed for CaM. Any evidence for the previously reported interdomain interaction in yCaM was not observed in the solution structure of the apo state. Hence, the interdomain interaction possibly occurs in the course of Ca(2+) binding and generates a cooperative Ca(2+) binding among all three sites. Preliminary studies on a mutant protein of yCaM, E104Q, revealed that the Ca(2+)-bound N-domain interacts with the apo C-domain and induces a large conformational change in the C-domain.

Genetic analysis of calmodulin and its targets in Saccharomyces cerevisiae

Calmodulin, a small, ubiquitous Ca2+-binding protein, regulates a wide variety of proteins and processes in all eukaryotes. CMD1, the single gene encoding calmodulin in S. cerevisiae, is essential, and this review discusses studies that identified many of calmodulin's physiological targets and their functions in yeast cells. Calmodulin performs essential roles in mitosis, through its regulation of Nuf1p/Spc110p, a component of the spindle pole body, and in bud growth, by binding Myo2p, an unconventional class V myosin required for polarized secretion. Surprisingly, mutant calmodulins that fail to bind Ca2+ can perform these essential functions. Calmodulin is also required for endocytosis in yeast and participates in Ca2+-dependent, stress-activated signaling pathways through its regulation of a protein phosphatase, calcineurin, and the protein kinases, Cmk1p and Cmk2p. Thus, calmodulin performs important physiological functions in yeast cells in both its Ca2+-bound and Ca2+-free form.

Solution structures of the N-terminal domain of yeast calmodulin: Ca2+-dependent conformational change and its functional implication

We have determined solution structures of the N-terminal half domain (N-domain) of yeast calmodulin (YCM0-N, residues 1-77) in the apo and Ca(2+)-saturated forms by NMR spectroscopy. The Ca(2+)-binding sites of YCM0-N consist of a pair of helix-loop-helix motifs (EF-hands), in which the loops are linked by a short beta-sheet. The binding of two Ca(2+) causes large rearrangement of the four alpha-helices and exposes the hydrophobic surface as observed for vertebrate calmodulin (CaM). Within the observed overall conformational similarity in the peptide backbone, several significant conformational differences were observed between the two proteins, which originated from the 38% disagreement in amino acid sequences. The beta-sheet in apo YCM0-N is strongly twisted compared with that in the N-domain of CaM, while it turns to the normal more stable conformation on Ca(2+) binding. YCM0-N shows higher cooperativity in Ca(2+) binding than the N-domain of CaM, and the observed conformational change of the beta-sheet is a possible cause of the highly cooperative Ca(2+) binding. The hydrophobic surface on Ca(2+)-saturated YCM0-N appears less flexible due to the replacements of Met51, Met71, and Val55 in the hydrophobic surface of CaM with Leu51, Leu71, and Ile55, which is thought to be one of reasons for the poor activation of target enzymes by yeast CaM.

The whole is not the simple sum of its parts in calmodulin from S. cerevisiae

Calmodulin is an essential Ca(2+)-binding protein involved in a multitude of cellular processes. The calmodulin sequence is highly conserved among all eukaryotic species; calmodulin from the yeast S. cerevisiae (yCaM) is the most divergent form, while still sharing 60% sequence identity with vertebrate calmodulin (vCaM). Although yCaM can be functionally substituted by vCaM in vivo, the two calmodulin proteins possess significantly different Ca(2+)-binding properties as well as abilities to activate vertebrate target enzymes in vitro. In addition, it has been observed that certain properties of the N-terminal and C-terminal domains of Ca(2+)-yCaM differ depending on whether they are in the context of the whole protein or isolated as half-molecule fragments. To investigate the structural basis for these differing properties, we have undertaken nuclear magnetic resonance (NMR) studies on yCaM and the two half-molecule fragments representing its two individual domains, yTr1(residues 1-76) and yTr2 (residues 75-146). We present direct evidence that the two domains of Ca(2+)-yCaM interact via their exposed hydrophobic surfaces. Thus, the Ca(2+)-bound form of yCaM exists in a novel compact structure in direct contrast to the well-established structure of Ca(2+)-vCaM comprised of two independent globular domains.

Calcium binding induces interaction between the N- and C-terminal domains of yeast calmodulin and modulates its overall conformation

Calmodulin from the yeast Saccharomyces cerevisiae binds 3 mol of Ca2+ cooperatively. We report here lines of evidence supporting the intramolecular interaction between the N- and C-terminal domains which modulates the Ca2+ binding properties of yeast calmodulin. First, the sum of the Ca2+ binding curves of the N-terminal and the C-terminal half-molecule did not yield the Ca2+ binding curve of yeast calmodulin. Second, the mean residue CD of yeast calmodulin at 222 nm (-Delta epsilon222) decreased with increases in the concentration of Ca2+, whereas those of each half-molecule increased. Finally, the C2 proton of His107 in the C-terminal domain of yeast calmodulin showed three resonance peaks with increases in the concentration of Ca2+, each corresponding to the apo, the intermediate, and the Ca2+-saturated state. The intermediate peak could not be observed in the C-terminal half-molecule of yeast calmodulin. Computer simulation considering the macroscopic Ca2+ binding constants assigned this intermediate to a species consisting of the apo C-terminal domain and the N-terminal domain with at least one of the two sites occupied by Ca2+. Peptide segments spanning the defective fourth Ca2+ binding site may be involved in the interdomain interaction and the yeast-specific function of calmodulin.

Solution X-ray scattering data show structural differences between yeast and vertebrate calmodulin: implications for structure/function

We present here the first evidence, obtained by the use of solution X-ray scattering, of the solution structure of yeast calmodulin, a poor activator of vertebrate enzymes. The radius of gyration of yeast calmodulin decreased from 21.1 to 19.9 angstroms when excess Ca2+ ions were added. The profiles of the pair-distribution function suggested that yeast calmodulin without Ca2+ has a dumbbell-like shape which changes toward a rather asymmetric globular shape, from its dumbbell shape, by the binding of Ca2+. In the presence of a calmodulin binding peptide such as MLCK-22 (a synthetic peptide corresponding to residues 577-598 of skeletal myosin light chain kinase), the radius of gyration of yeast calmodulin decreased by 1.6 angstroms, and the molecular shape of it estimated from the profile of the pair-distribution function was globular but less compact than that of vertebrate calmodulin. These results for the structure of yeast calmodulin complexed with Ca2+ and with Ca(2+)-peptides are quite different from those of vertebrate calmodulin. Thus, the functional differences between yeast and vertebrate calmodulin which we reported previously [Matsuura, I., et al. (1993) J. Biol. Chem. 268, 13267-13273] have been interpreted on the basis of the structural differences between them. Moreover, the structural studies on chimeric proteins of chicken and yeast calmodulin suggest that Ca2+ binding at site IV is essential to form the full active dumbbell structure, which is characteristic of vertebrate-type calmodulin.

Centrin is a conserved protein that forms diverse associations with centrioles and MTOCs in Naegleria and other organisms

Centrin, a approximately or equal to 20 kDa calcium-binding protein also known as caltractin, is a component of centrosome-associated algal flagellar roots capable of calcium-mediated contraction, and is also found in the centrosomes of vertebrate cells. Our analysis of a centrin gene from a protist, the amoeboflagellate Naegleria gruberi, reveals conserved features that distinguish centrins from calmodulin. Antibodies to bacterially expressed Naegleria centrin, which also recognize yeast Cdc31p, were employed to localize centrin immunoreactivity in selected organisms possessing specialized microtubule-organizing centers (MTOCs) or accessory structures. There is a striking morphological diversity of such structures. In the simplest associations, as found in Naegleria flagellates and vertebrates tracheal epithelium, centrin is intimately associated with the cylinder of the basal bodies. In cells with unfocused mitotic spindles, Naegleria amoebae and onion root tips, no localization of centrin was detected. In Dictyostelium discoideum and Saccharomyces cerevisiae, which lack centrioles, centrin immunoreactivity was observed as punctate cytoplasmic bodies but not associated with spindle pole MTOCs. In Paramecium multimicronucleatum, centrin immunoreactivity is localized to the infraciliary lattice, previously shown to exhibit calcium-mediated contraction. In Vorticella microstoma, known for the calcium-induced rapid contraction of its stalk, centrin immunoreactivity is localized to the contractile spasmoneme and myonemes. Similar antigens from Paramecium and Vorticella are detected by anti-centrin and anti-spasmin. The pattern of localization of centrin immunoreactivity supports the conjecture that a contractile system involving centrin, initially associated with centriolar structures, was recruited during evolution to build specialized organelles in different organisms and cell types.

Ca2+ binding to calmodulin and its role in Schizosaccharomyces pombe as revealed by mutagenesis and NMR spectroscopy

As a first step toward identifying the important structural elements of calmodulin from Schizosaccharomyces pombe, we examined the ability of heterologous calmodulins and Ca(2+)-binding site mutant S. pombe calmodulins to replace the essential cam1+ gene. A cDNA encoding vertebrate calmodulin allows growth of S. pombe. However, calmodulin from Saccharomyces cerevisiae does not support growth even though the protein is produced at high levels. With one exception, all mutant S. pombe calmodulins with one or more intact Ca(2+)-binding sites allow growth at 21 degrees C. A mutant containing only an intact Ca(2+)-binding site 3 fails to support growth, as does S. pombe calmodulin with all four Ca(2+)-binding sites mutated. Several of the mutant proteins confer a temperature-sensitive phenotype. Analysis of the degree of temperature sensitivity allows the Ca(2+)-binding sites to be ranked by their ability to support fission yeast proliferation. Site 2 is more important than site 1, which is more important than site 4, which is more important than site 3. A visual colony color screen based on the fission yeast ade1+ gene was developed to perform these genetic analyses. To compare the Ca(2+)-binding properties of individual sites to their functional importance for viability, Ca2+ binding to calmodulin from S. pombe was studied by 1H NMR spectroscopy. NMR analysis indicates a Ca(2+)-binding profile that differs from those previously determined for vertebrate and S. cerevisiae calmodulins. Ca(2+)-binding site 3 has the highest relative affinity for Ca2+, while the affinities of sites 1, 2, and 4 are indistinguishable. A combination of an in vivo functional assay and an in vitro physical assay reveals that the relative affinity of a site for Ca2+ does not predict its functional importance.

Molecular modelling of malaria calmodulin suggests that it is not a suitable target for novel antimalarials

The recent cloning and sequencing of many calmodulin genes permits alignment of DNA and protein sequences, as well as structural comparison based on homology modelling. The crystal structure of calmodulin places the four Ca(2+)-binding domains in a dumbbell-like configuration, with a large hydrophobic cleft in each half of the molecule. Calmodulin from Plasmodium falciparum has a high level of sequence identity (89%) with its mammalian counterpart. However, a lower degree of sequence conservation is observed among calmodulins from other lower eukaryotes. Potentially important differences in calmodulin sequences involve amino acids with side-chains forming the hydrophobic clefts as well as in the central helix; these differences could alter interactions with small hydrophobic molecules such as chloroquine and with enzymes modulated by calmodulin. Our modelling studies suggest that neither of the antimalarials examined (chloroquine and quinine) bind tightly to calmodulin. We conclude that the differences between host and parasite calmodulins are insufficient to merit this protein being chosen as a realistic target for antimalarial drug design. By contrast, our sequence comparisons reveal that the fungal calmodulins are significantly divergent from those of higher eukaryotes suggesting that at least in these species, calmodulin might be a target for novel antimycotic drugs.

Similarities and differences between yeast and vertebrate calmodulin: an examination of the calcium-binding and structural properties of calmodulin from the yeast Saccharomyces cerevisiae

The Ca(2+)-binding and structural properties of calmodulin (CaM) from the yeast Saccharomyces cerevisiae (yCaM) were analyzed by flow dialysis and NMR spectroscopy. Full-length yCaM and two truncated versions of yCaM were expressed in Escherichia coli and purified. yTR1 (residues 1-76) and yTR2 (residues 75-147) are similar to the vertebrate CaM fragments TR1 and TR2, which are generated by limited proteolysis with trypsin. As was found for the fragments of vertebrate CaM, the yCaM fragments retain native conformation and are useful for examining structure and metal-binding properties by NMR. Evidence for a short beta-sheet in each domain, as well as characteristic NOEs to aromatic residues, suggests that yCaM folds similarly to vertebrate CaM. Furthermore, although the previously considered "invariant" glycine at position 6 is replaced by a histidine in site II of yCaM, the far downfield chemical shift of His-61's amide proton suggests that this site adopts a conformation similar to that found in other EF-hand sites. Macroscopic Ca(2+)-binding constants were determined for yCaM by flow dialysis, revealing three high-affinity sites (dissociation constants were 5.2, 3.3, and 2.3 microM in the presence of 1 mM MgCl2 and 100 mM KCl). Positive cooperativity was observed among all sites. Ca2+ binding was also monitored indirectly by one-dimensional NMR. Titrations of the fragment molecules reveal that two binding sites reside in the N-terminal domain (sites I and II) and one in the C-terminal domain (site III). All three sites exhibit slow-exchange behavior in the intact protein, but site III exhibits fast-exchange behavior in the isolated C-terminal domain fragment (yTR2). Thus, an interaction between the two domains of intact yCaM affects the behavior of site III. These results with yCaM differ from those of vertebrate CaM in terms of Ca(2+)-binding stoichiometry, affinity of sites I and II, relative affinity of sites in the N- and C-terminal domains, and the exchange behaviors observed.

The heterodimer calmodulin: myosin light-chain kinase as a prototype vertebrate calcium signal transduction complex

The heterodimer complex of calmodulin (CaM) and the protein kinase catalytic subunit of myosin light chain kinase from vertebrate smooth muscle and non-muscle tissues (sm/nmMLCK) is one of the most extensively characterized CaM-regulated enzyme complexes and it has an established in vivo role in the transduction of calcium signals into biological responses. We have used a combination of approaches to the study of CaM and sm/nmMLCK in order to derive initial insight into the key features of each protein and of the CaM-MLCK heterodimeric complex that are involved in protein-protein and calcium-protein recognition and regulation of enzyme activity. On-going studies are described here that include site-specific mutagenesis, fluorescence spectroscopy, enzymology and peptide analog analysis. These and previous results indicate that: (1), both electrostatic and hydrophobic features are important in the functionally correct interactions between CaM and MLCK; (2), even the interactions between CaM and peptide analogs of the CaM binding site of MLCK are heterogeneous and non-trivial in nature; (3), amino-acid residues that have been conserved in CaM across millions of years of evolution and that are conserved in CaMs with quantitative MLCK activator activity can be mutated without any detectable effect on activity and (4), structures different from the prototypical EF-hand domain of CaM can have similar calcium-binding activity in the presence of a CaM binding structure.

Yeast calmodulin: structural and functional elements essential for the cell cycle

The budding yeast Saccharomyces cerevisiae is a suitable organism for studying calmodulin function in cell proliferation. Genetic studies in yeast demonstrate that vertebrate calmodulin can functionally replace yeast calmodulin. In addition, expression of half of the yeast calmodulin molecule is found to be sufficient for cell growth. Characterization of conditional-lethal mutants of yeast calmodulin as well as the intracellular distribution of calmodulin have suggested that at least two cell cycle steps require calmodulin function. One is nuclear division and the other is the maintenance of cell polarity. A current focus is to understand which kinds of target proteins are involved in mediating the essential functions of yeast calmodulin in these processes. Thus far, three yeast enzymes whose activity is regulated by calmodulin have been identified.

Structural analysis of wild-type and mutant yeast calmodulins by limited proteolysis and electrospray ionization mass spectrometry

Calmodulin from Saccharomyces cerevisiae was expressed in Escherichia coli and purified. The purified protein was structurally characterized using limited proteolysis followed by ESI mass spectrometry to identify the fragments. In the presence of Ca2+, yeast calmodulin is sequentially cleaved at arginine 126, then lysine 115, and finally at lysine 77. The rapid cleavage at Arg-126 suggests that the fourth Ca(2+)-binding loop does not bind Ca2+. In the presence of EGTA, yeast calmodulin is more susceptible to proteolysis and is preferentially cleaved at Lys-106. In addition, mutant proteins carrying I100N, E104V or both mutations, which together confer temperature sensitivity to yeast, were characterized. The mutant proteins are more susceptible than wild-type calmodulin to proteolysis, suggesting that each mutation disrupts the structure of calmodulin. Furthermore, whereas wild-type calmodulin is cut at Lys-106 only in the presence of EGTA, this cleavage site is accessible in the mutants in the presence of Ca2+ as well. In these ways, the structural consequence of each mutation mimics the loss of a calcium ion in the third loop. In addition, although wild-type calmodulin binds to four proteins in a yeast crude extract in the presence of Ca2+, the mutants bind only to a subset of these. Thus, the inability to adopt the stable Ca(2+)-bound conformation in the third Ca(2+)-binding loop alters the ability of calmodulin to interact with yeast proteins in a Ca(2+)-dependent manner.