Isolation of cDNA and genomic DNA clones encoding a calmodulin-binding protein related to a family of ATPases involved in cell division and vesicle fusion

Calmodulin (CaM), a primary Ca2+ receptor in all eukaryotic cells, is a multifunctional protein that functions by interacting with and modulating the activities of a wide variety of target proteins. Identifying and characterizing these CaM-binding target proteins is essential to define the pathways by which Ca(2+)-regulated signals are transduced. An Arabidopsis thaliana L. flower cDNA expression library constructed in lambda ZAPII was screened for CaM-binding proteins with 35S-labeled CaM. A partial cDNA whose encoded protein shares a high level of similarity with yeast CDC48p was isolated. A genomic clone was isolated using the partial length cDNA clone as a probe, and its nucleotide sequence was determined. The genomic DNA sequence was used to design oligonucleotide primers for polymerase-chain-reaction (PCR) experiments that facilitated cloning and reconstructing a full-length, 3.4-kb cDNA clone. The cDNA encodes a 111-kDa CaM-interacting protein (CIP111) containing motifs characteristic of a diverse family of ATPases, including proteins involved in cell cycle regulation, protein degradation, and vesicle-mediated protein transport. A truncated fusion protein encoded by the carboxy-terminal region of CIP111 was produced in Escherichia coli and shown to bind CaM in a Ca(2+)-dependent manner by protein gel blot and affinity chromatography binding assays. Reverse-transcription PCR analyses demonstrated that CIP111 mRNA is expressed in all organs examined including flowers, siliques, floral stalks, leaves, and roots. DNA blot hybridization analyses indicate that a single-copy gene in Arabidopsis is likely to encode CIP111.

Interaction of a kinesin-like protein with calmodulin isoforms from Arabidopsis

In Arabidopsis and other plants there are multiple calmodulin isoforms. However, the role of these isoforms in regulating the activity of target proteins is obscure. Here, we analyzed the interaction between a kinesin-like calmodulin-binding motor protein (Reddy, A. S. N., Safadi, F., Narasimhulu, S. B., Golovkin, M., and Hu, X. (1996) J. Biol. Chem. 271, 7052-7060) and three calmodulin isoforms (calmodulin-2, -4, and -6) from Arabidopsis using different approaches. Gel mobility and fluorescence shift assays revealed that the motor binds to all calmodulin isoforms in a calcium-dependent manner. Furthermore, all calmodulin isoforms were able to activate bovine calcium/calmodulin-dependent phosphodiesterase. However, the concentration of calmodulin-2 required for half-maximal activation of phosphodiesterase is 2- and 6-fold lower compared with calmodulin-4 and -6, respectively. The dissociation constants of the motor to calmodulin-2, -4, and -6 are 12.8, 27.0, and 27.8 nM, respectively, indicating that calmodulin-2 has 2-fold higher affinity for the motor than calmodulin-4 and -6. Similar results were obtained using another assay that involves the binding of (35)S-labeled calmodulin isoforms to the motor. The binding saturation curves of the motor with calmodulin isoforms have confirmed that calmodulin-2 has 2-fold higher affinity to the motor. However, the affinity of calmodulin-4 and -6 isoforms for the motor was about the same. Based on these studies, we conclude that all calmodulin isoforms bind to the motor protein but with different affinities.

Calmodulin isoforms differentially enhance the binding of cauliflower nuclear proteins and recombinant TGA3 to a region derived from the Arabidopsis Cam-3 promoter

Many stimuli increase cytoplasmic Ca2+ concentrations as an early signal transduction event and alter the patterns of nuclear gene transcription, but the mechanisms by which Ca2+ signals are transduced to the nucleus are not known. This article shows that at least four DNA binding proteins from cauliflower nuclear extracts are also calmodulin (CaM) binding proteins. CaM enhances the binding of these proteins to a C/G-box sequence element in the Arabidopsis Cam-3 promoter. Binding to the C/G-box is enhanced preferentially by the CaM isoform encoded by Cam-3. However, it is not clear whether the effect is mediated directly by CaM or indirectly through the activity of a CaM-regulated protein phosphatase. CaM also binds recombinant TGA3 and enhances its binding to the same Cam-3 promoter element. These results are consistent with the idea that a Ca(2+)-mediated signalling pathway eliciting some changes in gene expression may consist of CaM, or a structurally related Ca2+ binding protein, and transcription factors.

Differential stimulation of NAD kinase and binding of peptide substrates by wild-type and mutant plant calmodulin isoforms

Calmodulin from Arabidopsis thaliana consists of at least four isoforms, which differ in their deduced amino acid sequences by as many as six conservative substitutions. To determine whether these differences are biochemically significant, cDNAs encoding three of the four isoforms were engineered to produce recombinant proteins in Escherichia coli, purified to apparent homogeneity, and assayed for their abilities to activate pea leaf NAD kinase in vitro. The CaM-2 isoform was a significantly more efficient activator of NAD kinase compared with the CaM-4 and -6 isoforms based on both the apparent Vmax it elicited and the K0.5 activation. These results are consistent with the hypothesis that the Arabidopsis CaM isoforms have evolved to optimize the protein's interaction with different Ca2+/CaM-regulated target enzymes. The ability to activate NAD kinase was also investigated for a carboxy-terminal nonsense mutant of CaM-6 (CaM-6M), which substituted 14 hydrophilic amino acids for a region of seven amino acids that normally form an exposed hydrophobic surface when wt CaM-6 binds Ca2+. CaM-6M-activated NAD kinase displayed an apparent V. that was reduced 40% and a K0.5 that was an order of magnitude greater than the CaM-6-activated enzyme. The Ca2+-dependence of CaM-GM to activate NAD kinase was identical to that of CaM-6, but CaM-6M bound synthetic peptide substrates with lower apparent affinity than did CaM-6. Thus, the carboxy-terminal hydrophobic domain of CaM appears to be critical for its interaction with NAD kinase. In contrast, amino-terminal fusions of a hydrophilic, alpha-helical 12-residue c-myc epitope tag to CaM-2 and -4 yielded proteins that activated NAD kinase to apparent Vmax values within 10% of those obtained with the wild-type CaM proteins.

Cognitive-behavioral prevention of postconcussion syndrome

The symptoms of postconcussion syndrome (PCS) are persistent, and no empirically tested treatment is available. The treatment group (n = 29) in this study received a printed manual and met with a therapist prior to hospital discharge to review the nature and incidence of expected symptoms, the cognitive-behavioral model of symptom maintenance and treatment, techniques for reducing symptoms, and instructions for gradual resumption of premorbid activities. The control group (n = 29) received routine hospital treatment and discharge instructions. Both groups had sustained mild head injuries characterized by Glascow Coma Scale scores of 13-15 on admission without any measurable period of posttraumatic amnesia. Group assignment was random. Groups did not differ significantly on age, Glascow scores, litigation status, gender, or initial number of PCS symptoms. Patients were contacted 6 months following injury by an interviewer who was unaware of group assignment to obtain outcome data. Treated patients reported significantly shorter average symptom duration (33 vs. 51 days) and significantly fewer of the 12 symptoms at followup (1.6 vs. 3.1). Subjects were also asked how often each symptom had occurred in the previous week, and how severe the symptom typically was. The treatment group experienced significantly fewer symptomatic days (.5 vs. 1.3) and lower mean severity levels. Results suggest that brief, early psychological intervention can reduce the incidence of PCS.

Calmodulin isoforms in Arabidopsis encoded by multiple divergent mRNAs

Three new, unique cDNA sequences encoding isoforms of calmodulin (CaM) were isolated from an Arabidopsis cDNA library cloned in lambda gt10. These sequences (ACaM-4, -5, and -6) represent members of the Arabidopsis CaM gene family distinct from the three DNA sequences previously reported. ACaM-4 and -6 encode full-length copies of CaM mRNAs of ca. 0.75 kb. The ACaM-5 sequence encodes a partial length copy of CaM mRNA that is lacking sequences encoding the amino-terminal 10 amino acids of mature CaM and the initiator methionine. The derived amino acid sequence of ACaM-5 is identical to the sequences encoded by two of the previously characterized ACaM cDNAs, and is identical to TCH-1 mRNA, whose accumulation was increased by touch stimulation. The polypeptides encoded by ACaM-4 and -6 differ from that encoded by ACaM-5 by six and two amino acid substitutions, respectively. Most of the deduced amino acid sequence substitutions in the Arabidopsis CaM isoforms occurred in the fourth Ca(2+)-binding domain. Polymerase chain reaction amplification assays of ACaM-4, -5 and -6 mRNA sequences indicated that each accumulated in Arabidopsis leaf RNA fractions, but only ACaM-4 and -5 mRNAs were detected in silique total RNA. The six different CaM cDNA sequences each hybridize with unique EcoRI restriction fragments in genomic Southern blots of Arabidopsis DNA, indicating that these sequences were derived from distinct structural genes. Our results suggest that CaM isoforms in Arabidopsis may have evolved to optimize the interaction of this Ca(2+)-receptor protein with specific subsets of response elements.

Isolation of an Arabidopsis cDNA sequence encoding a 22 kDa calcium-binding protein (CaBP-22) related to calmodulin

Complementary DNA sequences were isolated from a library of cloned Arabidopsis leaf mRNA sequences in lambda gt10 that encoded a 21.7 kDa polypeptide (CaBP-22), which shared 66% amino acid sequence identity with Arabidopsis calmodulin. The putative Ca(2+)-binding domains of CaBP-22 and calmodulin, however, were more conserved and shared 79% sequence identity. Ca2+ binding by CaBP-22, which was inferred from its amino acid sequence similarity with calmodulin, was demonstrated indirectly by Ca(2+)-induced mobility shifting of in vitro translated CaBP-22 during SDS-polyacrylamide gel electrophoresis. CaBP-22 is encoded by a ca. 0.9 kb mRNA that was detected by northern blotting of leaf poly(A)+ RNA; this mRNA was slightly larger than the 809 bp CaBP-22 cDNA insert, indicating that the deduced amino acid sequence of CaBP-22 is near full-length. CaBP-22 mRNA was detected in RNA fractions isolated from leaves of both soil-grown and hydroponically grown Arabidopsis, but below the limits of detection in RNA isolated from roots, and developing siliques. Thus, CaBP-22 represents a new member of the EF-hand family of Ca(2+)-binding proteins with no known animal homologue and may participate in transducing Ca2+ signals to a specific subset of response elements.

Synthesis and Accumulation of Calmodulin in Suspension Cultures of Carrot (Daucus carota L.) : Evidence for Posttranslational Control of Calmodulin Expression

The expression of calmodulin mRNA and protein were measured during a growth cycle of carrot (Daucus carota L.) cells grown in suspension culture. A full-length carrot calmodulin cDNA clone isolated from a lambdagt10 library was used to measure steady-state calmodulin mRNA levels. During the exponential phase of culture growth when mitotic activity and oxidative respiration rates were maximal, calmodulin mRNA levels were 4- to 5-fold higher than they were during the later stages of culture growth, when respiration rates were lower and growth was primarily by cell expansion. Net calmodulin polypeptide synthesis, as measured by pulse-labeling in vivo with [(35)S]methionine, paralleled the changes in calmodulin steady-state mRNA level during culture growth. As a consequence, net calmodulin polypeptide synthesis declined 5- to 10-fold during the later stages of culture growth. The qualitative spectrum of polypeptides synthesized and accumulated by the carrot cells during the course of a culture cycle, however, remained largely unchanged. Calmodulin polypeptide levels, in contrast to its net synthesis, remained relatively constant during the exponential phases of the culture growth cycle and increased during the later stages of culture growth. Our data are consistent with increased calmodulin polypeptide turnover associated with periods of rapid cell proliferation and high levels of respiration.

Structure and expression of the Arabidopsis CaM-3 calmodulin gene

Genomic and cDNA sequences encoding a calmodulin (CaM) gene from Arabidopsis (ACaM-3) have been isolated and characterized. ACaM-3 represents a sequence distinct from two previously isolated Arabidopsis CaM cDNA clones. A 2.3 kb Eco RI restriction fragment was sequenced and found to encode a complete CaM-coding sequence interrupted by a single 491 bp intron, together with 750 bp and 600 bp of 5' and 3' flanking sequences, respectively. The polypeptide encoded by ACaM-3 is identical to that encoded by ACaM-2 and it differs from the one encoded by ACaM-1 by four of 148 residues. The putative promoter of ACaM-3 was atypical of CaM genes previously isolated from animals in that it contained consensus TATA and CAAT box sequences and lacked GC-rich regions. Two DNA sequence elements closely resembling cyclic AMP regulatory elements, which have been identified in animal CaM genes, were located in the 5' flanking region of ACaM-3. Northern blot and polymerase chain reaction amplification assays confirmed that each of the three ACaM mRNAs were expressed in similar but distinct patterns in different organs. ACaM-1 mRNA was the only species detectable in root RNA fractions, and ACaM-3 mRNA could not be detected in floral stalks. Accumulation of the three CaM mRNAs in leaves was induced by a touch stimulus, but the kinetics and extent of the induction varied among the three mRNA species. Run-on transcription assays indicated that a portion of the differences in accumulation of ACaM-1, 2, and 3 mRNAs in leaves and siliques was attributable to differences in their net rates of transcription.

Alterations in barley ribulose-1,5-bisphosphate carboxylase/oxygenase activase gene expression during development and in response to illumination

Two genes encode Rbu-P2-carboxylase activase in barley (RcaA and RcaB): RcaA encodes polypeptides of 46 and 42 kDa, which are generated by the alternatively spliced RcaA1 and RcaA2 mRNAs, respectively; RcaB encodes a 42-kDa polypeptide (Rundle, S. J., and Zielinski, R. E. (1991) J. Biol. Chem. 266, 4677-4685). In the cellular differentiation gradient of the first leaf of barley, the three Rca mRNAs accumulate differentially. RcaA1 and A2 mRNAs accumulate predominantly in the mature, most photosynthetically active regions of the leaf in a pattern that parallels accumulation of total Rbu-P2-carboxylase activase protein. However, the kinetics of accumulation of RcaA1 and RcaA2 mRNA differ slightly, indicating that either changes in RcaA pre-mRNA splicing or mRNA turnover occur during development. RcaB mRNA, in contrast, accumulates in the youngest and oldest cell populations at the base and tip of the leaf, respectively. In the mid-region of the leaf, the difference in accumulation between RcaA and RcaB mRNAs is largely attributable to differences in the rates of transcription of the two Rca genes. In this region of the leaf, the three Rca mRNAs accumulate differentially throughout the course of the diurnal cycle. Steady state levels of the three Rca mRNA species increase in parallel in response to increasing irradiance; these changes were accompanied by increased Rbu-P2-carboxylase activase protein accumulation.

Primary structures of Arabidopsis calmodulin isoforms deduced from the sequences of cDNA clones

Complementary DNA (cDNA) clones encoding calmodulin isoforms were isolated from an Arabidopsis leaf lambdagt10 library by screening with cloned barley calmodulin cDNA probes. Two cDNAs, one a 626-base pair partial-length clone (ACaM-1) and one a 1400-base pair full-length clone (ACaM-2), encode calmodulin polypeptides that differ by four conservative amino acid substitutions. None of the amino acid sequence differences occur within the four Ca(2+)-binding domains of the proteins. Whereas the deduced amino acid sequences of the two Arabidopsis calmodulin isoforms share 97% identity, the nucleotide sequences encoding the two isoforms share 87% sequence identity. Most of these nucleotide sequence differences (80%) occur in codon wobble positions. ACaM-1 and ACaM-2 both hybridize with a distinct set of restriction fragments of Arabidopsis total DNA, indicating that they were derived from transcripts of separate genes; these genes are single- or very low-copy in the Arabidopsis genome. Both cDNAs hybridize to messenger RNA (mRNA) species of 0.8 kilobases that are expressed to a greater extent in developing siliques compared with leaves, flowers, and stems. Northern blot and polymerase chain reaction assays both indicate that ACaM-1 mRNA is more highly expressed than ACaM-2 mRNA in developing siliques. The steady-state levels of both isoform mRNAs increase as a result of touch stimulation; the kinetics and extent of increase are comparable for the two mRNAs.

Organization and expression of two tandemly oriented genes encoding ribulosebisphosphate carboxylase/oxygenase activase in barley

We have isolated and structurally characterized genomic DNA and cDNA sequences encoding ribulose-1,5-bisphosphate carboxylase/oxygenase (Rbu-P2 carboxylase) activase from barley (Hordeum vulgare L.). Three Rbu-P2 carboxylase activase (Rca) polypeptides are encoded in the barley genome by two closely linked, tandemly oriented nuclear genes (RcaA and RcaB); cDNAs encoding each of the three Rbu-P2 carboxylase activase polypeptides were isolated from cDNA libraries of barley leaf mRNA. RcaA produces two mRNAs, which encode polypeptides of 42 and 46 kDa, by an alternative splicing mechanism identical to that previously reported for spinach and Arabidopsis Rca genes (Werneke, J.M., Chatfield, J.M., and Ogren, W. L. (1989) Plant Cell 1, 815-825). RcaB is transcribed to produce a single mRNA, which encodes a mature peptide of 42 kDa. Genomic Southern blots indicate that RcaA and RcaB represent the entire Rbu-P2 carboxylase activase gene family in barley. The genes share 80% nucleotide sequence identity, and the 42-kDa polypeptides encoded by RcaA and RcaB share 87% amino acid sequence identity. Coding regions of the two barley Rca genes are separated by 1 kilobase pair of flanking DNA. DNA sequence motifs similar to those thought to control light-regulated gene expression in other nuclear-encoded plastid polypeptide genes are found at the 5' end of both barley Rca genes. Probes specific to three mRNAs were used to determine the relative contribution each species makes to the total Rca mRNA pool.

Effect of Ca and Calmodulin on DeltapH Formation in Tonoplast Vesicles from Corn Roots

The effects of calmodulin (CaM) on ATPase activity and ATP-dependent formation of a proton gradient (DeltapH) were studied in tonoplast membrane vesicles from corn (Zea mays L.) roots. At 0.6 micromolar, CaM stimulated ATPase activity by about 20% in the absence of an uncoupler, but by only 4% in its presence. Thus, the uncoupler-dependent increment of activity was decreased 30 to 45% by CaM. The formation of a proton gradient across the membrane vesicle, measured by quinacrine fluorescence quench, was inhibited about 20% by CaM. Its effect was additive to the effect of Ca(2+) and was completely abolished by EGTA. These effects of CaM could be due to stimulation of H(+) efflux or due to inhibition of the H(+)-ATPase. To distinguish between these possibilities, we examined the effect of CaM on dissipation of preformed DeltapH after the ATPase was inhibited. CaM stimulated the dissipation of a preformed DeltapH by 40% after the H(+)-ATPase was inhibited with NO(3) (-). This indicates that CaM facilitates the recycling of protons across the tonoplast membranes and does not regulate the H(+)-ATPase by direct inhibition.

Coordinate Expression of Rubisco Activase and Rubisco during Barley Leaf Cell Development

We have utilized the cellular differentiation gradient and photomorphogenic responses of the first leaf of 7-day-old barley (Hordeum vulgare L.) to examine the accumulation of mRNA and protein encoded by the ribulose-1,5-biphosphate carboxylase holoenzyme (rubisco) activase gene (rca). Previous studies have revealed a pattern of coordinate expression of rubisco subunit polypeptides during development. We compared the expression of rubisco polypeptides and mRNAs with those encoded by rca. The mRNAs encoding both rubisco activase and rubisco are expressed exclusively in leaf tissue of 7-day-old barley seedlings; mRNAs and polypeptides of rca accumulate progressively from the leaf base in a pattern that is qualitatively similar to that of rubisco subunit mRNAs and polypeptides. The parallel pattern of rca protein and mRNA accumulation indicate that a primary control of rca gene expression in this system lies at the level of mRNA production. Light-induced expression of rca in etiolated barley follows a different pattern from that of the acropetal barley leaf gradient, however. Etiolated, 7-day-old barley seedlings contain levels of rca mRNA near the limit of detection in Northern blot hybridization assays. White light induces a 50- to 100-fold accumulation of rca mRNA, which is detectable within 30 min after the onset of illumination. In contrast, steady state levels of mRNAs encoding the small rubisco subunit are affected little by light, and mRNAs encoding the large subunit accumulate about 5-fold in response to illumination. While rca mRNA levels are low in etiolated barley leaves, levels of the protein are approximately 50 to 75% of those found in fully green leaves.

Cloning of cDNA Sequences Encoding the Calcium-Binding Protein, Calmodulin, from Barley (Hordeum vulgare L.)

Full- and partial-length cDNAs encoding calmodulin mRNA have been cloned and sequenced from barley (Hordeum vulgare L.). Barley leaf mRNA, size-fractionated in sucrose density gradients, was used to synthesize double-stranded cDNA. The cDNA was cloned in lambdagt10 and screened with a synthetic, 14-nucleotide oligonucleotide probe, which was designed using the predicted coding sequences of the carboxy termini of spinach and wheat calmodulin proteins. The primary structure of barley calmodulin, predicted from DNA sequencing experiments, consists of 148 amino acids and differs from that of wheat calmodulin in only three positions. In two of the three positions, the amino acid changes are conservative, while the third change consists of an apparent deletion/insertion. The overall nucleotide sequence similarity between the amino acid coding regions of barley and vertebrate calmodulin mRNAs is approximately 77%. However, a region encoding 11 amino acids of the second Ca(2+)-binding domain is very highly conserved at the nucleotide level compared with the rest of the coding sequences (94% sequence identity between barley and chicken calmodulin mRNAs). Genomic Southern blots reveal that barley calmodulin is encoded by a single copy gene. This gene is expressed as a single size class of mRNA in all tissues of 7-day-old barley seedlings. In addition, these analyses indicate that a barley calmodulin cDNA coding region subclone is suitable as a probe for isolating calmodulin genes from other plants.

Protein kinase activities in tonoplast and plasmalemma membranes from corn roots

Protein kinase and phosphatase activities were studied in plasmalemma and tonoplast membrane fractions from corn (Zea mays L.) roots in order to test the hypothesis that the tonoplast H(+)-ATPase is regulated by intrinsic protein phosphorylation (G Zocchi, SA Rogers, JB Hanson 1983 Plant Sci Lett 31: 215-221), and to facilitate future purification of kinase activities from these membranes. Kinase activity in the plasmalemma was about three-fold higher than in the tonoplast, and displayed Michaelis Menten-type behavior with a K(m) value for MgATP(2-) of about 50 micromolar. Both activities were optimal at 3 millimolar free Mg(2+) and had pH optima at 6.6 and 7.0 for the plasmalemma and tonoplast, respectively. Kinase activities in both fractions were stimulated by 1 micromolar free Ca(2+), but calmodulin had no stimulatory effect, and chlorpromazine was inhibitory only at high concentrations. The pattern of phosphopeptides on SDS polyacrylamide gel electrophoresis was similar in both fractions except for one band of 50 kilodaltons that was present only in the tonoplast. A partially purified H(+)-ATPase fraction was prepared from tonoplast membranes, incubated under conditions optimal for protein phosphorylation. The three polypeptides (of 67, 57, and 36 kilodaltons), enriched in this fraction, did not become phosphorylated, suggesting that this protein is not regulated by endogenous protein phosphorylation. Protein phosphatase activity was detected only in the plasmalemma fraction. These results indicate that a regulatory cycle of protein phosphorylation and dephosphorylation may operate in the plasmalemma. The activity in the tonoplast appears to originate from plasmalemma contamination.

Structure and expression of spinach leaf cDNA encoding ribulosebisphosphate carboxylase/oxygenase activase

Ribulosebisphosphate carboxylase/oxygenase activase is a recently discovered enzyme that catalyzes the activation of ribulose-1,5-bisphosphate carboxylase/oxygenase ["rubisco"; ribulose-bisphosphate carboxylase; 3-phospho-D-glycerate carboxy-lyase (dimerizing), EC 4.1.1.39] in vivo. Clones of rubisco activase cDNA were isolated immunologically from spinach (Spinacea oleracea L.) and Arabidopsis thaliana libraries. Sequence analysis of the spinach and Arabidopsis cDNAs identified consensus nucleotide binding sites, consistent with an ATP requirement for rubisco activase activity. A derived amino acid sequence common to chloroplast transit peptides was also identified. After synthesis of rubisco activase in vitro, the transit peptide was cleaved and the protein was transported into isolated chloroplasts. Analysis of spinach and Arabidopsis nuclear DNA by hybridization indicated a single rubisco activase gene in each species. Leaves of spinach and Arabidopsis wild type contained a single 1.9-kilobase rubisco activase mRNA. In an Arabidopsis mutant lacking rubisco activase protein, mRNA species of 1.7 and 2.1 kilobases were observed under conditions of high-stringency hybridization with a wild-type cDNA probe. This observation indicates that the lesion in the mutant arises from an error in mRNA processing.

Calmodulin mRNA in Barley (Hordeum vulgare L.) : Apparent Regulation by Cell Proliferation and Light

Calmodulin is encoded by a 650-nucleotide mRNA in higher plants. This messenger was identified in barley and pea by a combination of in vitro translation and blot hybridization experiments using anti-sense RNA produced from an eel calmodulin cDNA probe. In all plant tissues tested, calmodulin mRNA represents between 0.01 and 0.1% of the total translatable mRNA population. Calmodulin mRNA levels are three- to fourfold higher in the meristematic zone of the first leaf of barley. At all other stages of leaf cell differentiation, calmodulin mRNA levels are nearly identical. During light-induced development in barley leaves, the relative proportion of translatable calmodulin mRNA declines about twofold. Cytoplasmic mRNAs that may encode calmodulin-like proteins were also detected. The levels of several of these putative Ca(2+)-binding protein mRNAs are modulated during the course of light-induced barley leaf cell development.

Biosynthesis of calmodulin in normal and virus-transformed chicken embryo fibroblasts

We report here that the higher levels of calmodulin in transformed chicken embryo fibroblasts are due to an increase in the rate of synthesis of calmodulin that results from an increased amount of calmodulin-specific mRNA in transformed cells. Transformation of several types of eucaryotic cells by oncogenic viruses results in a two- to threefold increase in the intracellular levels of calmodulin. We used the normal chicken embryo fibroblast and its Rous sarcoma virus-transformed counterpart to examine the biosynthesis of calmodulin. We show that the higher levels of calmodulin found in transformed fibroblasts appear to be the consequence of a selective increase in the rate of synthesis of calmodulin above that of total soluble or total cellular protein. A significant difference in the rate of degradation of calmodulin or total protein between transformed and normal cells was not detected. We also examined the mechanism of the increased synthesis rate of calmodulin and show that the levels of calmodulin mRNA are increased in transformed fibroblasts as measured by both translational activity and hybridization to a calmodulin cDNA probe. It is suggested by these data that the higher levels of calmodulin in transformed cells may result from a specific increase in the rate of either calmodulin gene transcription or mRNA processing.

Analysis of suborganellar fractions from spinach and pea chloroplasts for calmodulin-binding proteins

Purified chloroplasts from spinach and pea leaves were subfractionated into envelope, thylakoid, and stroma fractions and were analyzed for calmodulin-binding proteins using a 125I-calmodulin gel overlay assay. Calmodulin binding was primarily associated with a major polypeptide (Mr 33,000) in the envelope membrane fraction. In contrast, major calmodulin-binding proteins were not detected in the thylakoid or stroma fractions. Our results provide the first evidence of calmodulin-binding proteins in the chloroplast envelope, and raise the possibility that calmodulin may contribute to the regulation of chloroplast function through its interaction with calmodulin-binding proteins in the chloroplast envelope. In addition, our results combined with those of other investigators support the proposal that subcellular organelles may be a primary site of calmodulin action.

Synthesis of thylakoid membrane proteins by chloroplasts isolated from spinach. Cytochrome b559 and P700-chlorophyll a-protein

Intact chloroplasts, purified from spinach leaves by sedimentation in density gradients of colloidal silica, incorporate labeled amino acids into at least 16 different polypeptides of the thylakoid membranes, using light as the only source of energy. The thylakoid products of chloroplast translation were visualized by subjecting membranes purified from chloroplasts labeled with [35S]methionine to electrophoresis in high-resolution, SDS-containing acrylamide gradient slab gels and autoradiography. The apparent mol wt of the labeled products ranged from less than 10,000 to greater than 70,000. One of the labeled products is the apoprotein of the P700-chlorophyll a-protein (CPI). The CPI apoprotein is assembled into a pigment-protein complex which is electrophoretically indistinguishable from the native CPI complex. Isolated spinach chloroplasts also incorporate [3H]leucine and [35S]methionine into cytochrome b559. The radioactive label remains with the cytochrome through all stages of purification: extraction of the thylakoid membranes with Triton X-100 and urea, adsorption of impurities on DEAE cellulose, two cycles of electrophoresis in Triton-containing polyacrylamide gels and electrophoresis in SDS-containing gradient gels. Cytochrome b559 becomes labeled with both [3H]leucine and [35S]methionine and accounts for somewhat less than 1% of the total isotopic incorporation into thylakoid protein. The lipoprotein appears to be fully assembled during the time-course of our labeling experiments.

Relative Requirements for Magnesium of Protein and Chlorophyll Synthesis in Euglena gracilis

The relationships among Mg, growth, chlorophyll synthesis, and cytoplasmic polysome content were studied in Euglena gracilis grown in different levels of the metal. At all levels of magnesium from 20 to 1,600 mumolar, both protein and chlorophyll are formed with exponential kinetics. The apparent rates of synthesis and final yields of both components are greater at higher levels of Mg, but the rate of chlorophyll synthesis always exceeds the rate of protein formation; i.e. the most severely deficient cells contain proportionally more chlorophyll than the sufficient cells. Cytoplasmic polysomes isolated from Mg-deficient Euglena are indistinguishable from those isolated from control cells. We conclude that decreased rates of protein synthesis occur prior to and possibly are causal to decreased rates of chlorophyll synthesis, but that the mechanism of this inhibition remains unclear.