Membrane regulation of the chromosomal replication activity of E. coli DnaA requires a discrete site on the protein.

The capacity of DnaA protein to initiate DNA synthesis at the chromosomal origin is influenced profoundly by the tightly bound nucleotides ATP and ADP. Acidic phospholipids can catalyze the conversion of inactive ADP-DnaA protein into the active ATP form. Proteolytic fragments of the nucleotide form of DnaA protein were examined to determine regions of the protein critical for functional interaction with membranes. A 35 kDa chymotryptic and 29 kDa tryptic fragment retained the tightly bound nucleotide. The fragments, whose amino-termini are within three residues of each other, but differ at their carboxyl ends, showed strikingly different behavior when treated with acidic phospholipids. The larger chymotryptic fragment released the bound nucleotide in the presence of acidic, but not neutral phospholipids. In contrast, the smaller tryptic fragment was inert to both forms of phospholipids. Acidic membranes, but not those composed of neutral phospholipids, protect from tryptic digestion a small portion of the segment that constitutes the difference between the 29 and 35 kDa fragments. The resulting 30 kDa tryptic fragment, which possesses this protected region, interacts functionally with acidic membranes to release the bound effector nucleotide. Inasmuch as the anionic ganglioside GM1, a compound structurally dissimilar to acidic glycerophospholipids, efficiently releases the nucleotide from DnaA protein, an acidic surface associated with a hydrophobic environment is the characteristic of the membrane that appears crucial for regulatory interaction with DnaA protein.     

Acidic phospholipids inhibit the DNA-binding activity of DnaA protein,the initiator of chromosomal DNA replication in Escherichia coli

In order to initiate chromosomal DNA replication in Escherichia coli, the DnaA protein must bind to both ATP and the origin of replication (oriC). Acidic phospholipids are known to inhibit DnaA binding to ATP, and here we examine the effects of various phospholipids on DnaA binding to oriC. Among the phospholipids in E. coli membrane, cardiolipin showed the strongest inhibition of DnaA binding to oriC. Synthetic phosphatidylglycerol containing unsaturated fatty acids inhibited binding more potently than did synthetic phosphatidylglycerol containing saturated fatty acids, suggesting that membrane fluidity is important. Thus, acidic phospholipids seem to inhibit DnaA binding to both oriC and adenine nucleotides in the same manner. Adenine nucleotides bound to DnaA did not affect the inhibitory effect of cardiolipin on DnaA binding to oriC. A mobility-shift assay re-vealed that acidic phospholipids inhibited formation of a DnaA-oriC complex containing several DnaA molecules. DNase I footprinting of DnaA binding to oriC showed that two DnaA binding sites (R2 and R3) were more sensitive to cardiolipin than other DnaA binding sites. Based on these in vitro data, the physiological relevance of this inhibitory effect of acidic phospholipids on DnaA binding to oriC is discussed.     

The chromosome origin of Escherichia coli stabilizes DnaA protein during rejuvenation by phospholipids.

DnaA protein (the initiator protein) binds and clusters at the four DnaA boxes of the Escherichia coli chromosomal origin (oriC) to promote the strand opening for DNA replication. DnaA protein activity depends on the tight binding of ATP; the ADP form of DnaA protein, generated by hydrolysis of the bound ATP, is inactive. Rejuvenation of ADP-DnaA protein, by replacement with ATP, is catalyzed by acidic phospholipids in a highly fluid bilayer. We find that interaction of DnaA protein with oriC DNA is needed to stabilize DnaA protein during this rejuvenation process. Whereas DnaA protein bound to oriC DNA responds to phospholipids, free DnaA protein is inactivated by phospholipids and then fails to bind oriC. Furthermore, oriC DNA facilitates the high affinity binding of ATP to DnaA protein during treatment with phospholipids. A significant portion of the DnaA protein associated with oriC DNA can be replaced by the ADP form of the protein, suggesting that all of the DnaA protein bound to oriC DNA need not be rejuvenated between rounds of replication.     

Phospholipids promote dissociation of ADP from the Mycobacterium avium DnaA protein

The biochemical aspects of the initiation of DNA replication in Mycobacterium avium are unknown. As a first step towards understanding this process, M. avium DnaA protein, the counterpart of Escherichia coli replication initiator protein, was overproduced in E. coli with an N-terminal histidine tag and purified to homogeneity on a nickel affinity column. The recombinant DnaA protein bound both ATP and ADP with high affinity and showed a weak ATPase activity. ADP, following the hydrolysis of ATP, remained bound to the protein strongly and the exchange of ATP for bound ADP was found to be weak. Acidic phospholipids such as phosphatidylinositol, phosphatidylglycerol, and cardiolipin, promoted the dissociation of ADP from the DnaA protein, whereas the neutral phospholipid, phosphatidylethanolamine, did not. The phospholipid promoted dissociation of ADP from DnaA protein was stimulated in the presence of the M. avium origin of replication. We suggest that the initiation of DNA replication in M. avium involves an interplay among DnaA, adenine nucleotides and phospholipids.     

Membrane-catalyzed nucleotide exchange on DnaA. Effect of surface molecular crowding

DnaA is the initiator protein for chromosomal replication in bacteria; its activity plays a central role in the timing of the primary initiations within the Escherichia coli cell cycle. A controlled, reversible conversion between the active ATP-DnaA and the inactive ADP forms modulates this activity. In a DNA-dependent manner, bound ATP is hydrolyzed to ADP. Acidic phospholipids with unsaturated fatty acids are capable of reactivating ADP-DnaA by promoting the release of the tightly bound ADP. The nucleotide dissociation kinetics, measured in the present study with the fluorescent derivative 3'-O-(N-methylantraniloyl)-5'-adenosine triphosphate, was dependent on the density of DnaA on the membrane in a cooperative manner: it increased 5-fold with decreased protein density. At all surface densities the nucleotide was completely released, presumably due to protein exchange on the membrane. Distinct temperature dependences and the effect of the crowding agent Ficoll suggest that two functional states of DnaA exist at high and low membrane occupancy, ascribed to local macromolecular crowding on the membrane surface. These novel phenomena are thought to play a major role in the mechanism regulating the initiation of chromosomal replication in bacteria.     

Inhibitory effects of basic or neutral phospholipid on acidic phospholipid-mediated dissociation of adenine nucleotide bound to DnaA protein,the initiator of chromosomal DNA replication

DnaA protein activity, the initiator of chromosomal DNA replication in bacteria, is regulated by acidic phospholipids such as phosphatidylglycerol (PG) or cardiolipin (CL) via facilitation of the exchange reaction of bound adenine nucleotide. Total lipid isolated from exponentially growing Staphylococcus aureus cells facilitated the release of ATP bound to S. aureus DnaA protein, whereas that from stationary phase cells was inert. Fractionation of total lipid from stationary phase cells revealed that the basic phospholipid, lysylphosphatidylglycerol (LPG), inhibited PG- or CL-facilitated release of ATP from DnaA protein. There was an increase in LPG concentration during the stationary phase. A fraction of the total lipid from stationary phase cells of an integrational deletion mprF mutant, in which LPG was lost, facilitated the release of ATP from DnaA protein. A zwitterionic phospholipid, phosphatidylethanolamine, also inhibited PG-facilitated ATP release. These results indicate that interaction of DnaA protein with acidic phospholipids might be regulated by changes in the phospholipid composition of the cell membrane at different growth stages. In addition, the mprF mutant exhibited an increased amount of origin per cell in vivo, suggesting that LPG is involved in regulating the cell cycle event(s).     

Electrostatic interactions during acidic phospholipid reactivation of DnaA protein, the Escherichia coli initiator of chromosomal replication.

The initiation of Escherichia coli chromosomal replication by DnaA protein is strongly influenced by the tight binding of the nucleotides ATP and ADP. Anionic phospholipids in a fluid bilayer promote the conversion of inactive ADP-DnaA protein to replicatively active ATP-DnaA protein in vitro, and thus likely play a key role in regulating DnaA activity. Previous studies have revealed that, during this reactivation, a specific region of DnaA protein inserts into the hydrophobic portion of the lipid bilayer in an acidic phospholipid-dependent manner. To elucidate the requirement for acidic phospholipids in the reactivation process, the contribution of electrostatic forces in the interaction of DnaA and lipid was examined. DnaA-lipid binding required anionic phospholipids, and DnaA-lipid binding as well as lipid-mediated release of DnaA-bound nucleotide were inhibited by increased ionic strength, suggesting the involvement of electrostatic interactions in these processes. As the vesicular content of acidic phospholipids was increased, both nucleotide release and DnaA-lipid binding increased in a linear, parallel manner. Given that DnaA-membrane binding, the insertion of DnaA into the membrane, and the consequent nucleotide release all require anionic phospholipids, the acidic headgroup may be necessary to recruit DnaA protein to the membrane for insertion and subsequent reactivation for replication.     

Restoration of growth to acidic phospholipid-deficient cells by DnaA(L366K) is independent of its capacity for nucleotide binding and exchange and requires DnaA

In the absence of adequate levels of cellular acidic phospholipids, Escherichia coli remain viable but are arrested for growth. Expression of a DnaA protein that contains a single amino acid substitution in the membrane-binding domain, DnaA(L366K), in concert with expression of wild-type DnaA protein, restores growth. DnaA protein has high affinity for ATP and ADP, and in vitro lipid bilayers that are fluid and contain acidic phospholipids reactivate inert ADP-DnaA by promoting an exchange of ATP for ADP. Here, nucleotide and lipid interactions and replication activity of purified DnaA(L366K) were examined to gain insight into the mechanism of how it restores growth to cells lacking acidic phospholipids. DnaA(L366K) behaved like wild-type DnaA with respect to nucleotide binding affinities and hydrolysis properties, specificity of acidic phospholipids for nucleotide release, and origin binding. Yet, DnaA(L366K) was feeble at initiating replication from oriC unless augmented with a limiting quantity of wild-type DnaA, reflecting the in vivo requirement that both wild-type and a mutant form of DnaA must be expressed and act together to restore growth to acidic phospholipid deficient cells.     

DnaA protein Lys-415 is close to the ATP-binding site: ATP-pyridoxal affinity labeling.

Binding of ATP, but not of ADP, activates Escherichia coli DnaA protein for replicational initiation of the chromosome. To elucidate this switching mechanism, we used the affinity-labeling agent ATP-pyridoxal, which forms a covalent bond with the Lys residue located at or near the gamma-phosphate of ATP. ATP-pyridoxal inhibited the ATP binding for DnaA protein, with a competitive mode. Binding stoichiometry was 0.28 ATP-pyridoxal/DnaA molecule, a value consistent with that of ATP. Thus, ATP-pyridoxal was a potent antagonist for the DnaA ATP-binding site. The labeled DnaA protein was inactive for minichromosome replication in vitro, suggesting that conformation of the region is important for DnaA activity. Isolation of the labeled, tryptic fragment and the Edman degradation revealed that ATP-pyridoxal modified Lys-415. Thus, this residue is likely close to the bound ATP. Since Lys-415 is located in the DNA-binding domain, these findings imply internal interaction between the domains for ATP binding and DNA binding.     

Facilitation of dissociation reaction of nucleotides bound to Mycobacterium tuberculosis DnaA

Acidic phospholipids have been shown to promote dissociation of bound nucleotides from Mycobacterium tuberculosis DnaA (DnaA(TB)) purified under denaturing conditions [Yamamoto et al., (2002) Modulation of Mycobacterium tuberculosis DnaA protein-adenine-nucleotide interactions by acidic phospholipids. Biochem. J., 363, 305-311]. In the present study, we show that a majority of DnaA(TB) in non-overproducing cells of M. tuberculosis is membrane associated. Estimation of phospholipid phosphorus following chloroform: methanol extraction of soluble DnaA(TB) purified under native conditions (nDnaA(TB)) confirmed the association with phospholipids. nDnaA(TB) exhibited weak ATPase activity, and rapidly exchanged ATP for bound ADP in the absence of any added phospholipids. We suggest that the outcome of intra-cellular DnaA(TB)-nucleotide interactions, hence DnaA(TB) activity, is influenced by phospholipids.     

Conformational transitions in the myosin head induced by temperature, nucleotide and actin. Studies on subfragment-1 of myosins from rabbit and frog fast skeletal muscle with a limited proteolysis method

Tryptic digestion patterns reveal a close similarity of the substructure of frog subfragment-1 (S1) to that established for rabbit S1. The 97-kDa heavy chain of chymotryptic S1 of frog myosin is preferentially cleaved into three fragments with apparent molecular masses of 29 kDa, 49 kDa and 20 kDa. These fragments correspond to the 27-kDa, 50-kDa and 20-kDa fragments of rabbit S1, respectively; this is indicated by the sequence of their appearance during digestion, by the suppression by actin of the generation of the 49-kDa and 20-kDa peptides, and by a nucleotide-promoted cleavage of the 29-kDa peptide to a 24-kDa fragment and the 49-kDa peptide to a 44-kDa fragment, analogous to the nucleotide-promoted cleavage of the 27-kDa and 50-kDa fragments of rabbit S1 to the 22-kDa and 45-kDa peptides. The same changes in the digestion patterns as those produced by the presence of nucleotide (ATP or its beta,gamma-imido analog AdoP P[NH]P) at 25 degrees C were observed when the digestion was carried out at 0 degrees C in the absence of nucleotide. The low-temperature-induced changes were particularly well seen in the preparations from frog myosin. The presence of ATP or AdoP P[NH]P at 0 degrees C enhanced, whereas the complex formation with actin prevented, the low-temperature-induced changes. The results are consistent with there being two fundamental conformational states of the myosin head in an equilibrium that is dependent on the temperature, the nucleotide bound at the active site, and the presence or absence of actin.     

Structural organization of the human glucocorticoid receptor determined by one- and two-dimensional gel electrophoresis of proteolytic receptor fragments

The structural organization of the steroid-binding protein of the IM-9 cell glucocorticoid receptor was investigated by using one- and two-dimensional gel electrophoresis of proteolytic receptor fragments. One-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) of receptor fragments isolated after trypsin digestion of immunopurified [3H]dexamethasone 21-mesylate ([3H]DM-) labeled receptor revealed the presence of a stable 26.5-kilodalton (kDa) steroid-containing, non-DNA-binding fragment, derived from a larger, less stable, 29-kDa fragment. The 26.5-kDa tryptic fragment appeared to be completely contained within a 41-kDa, steroid-containing, DNA-binding species isolated after chymotrypsin digestion of the intact protein. Two-dimensional electrophoretic analysis of the [3H]DM-labeled tryptic fragments resolved two (pI congruent to 5.7 and 7.0) 26.5-kDa and two (pI congruent equal to 5.7 and 6.8) 29-kDa components. This was the same number of isoforms seen in the intact protein, indicating that the charge heterogeneity of the steroid-binding protein is the result of modification within the steroid-containing, non-DNA-binding, 26.5-kDa tryptic fragment. Two-dimensional analysis of the 41-kDa [3H]DM-labeled chymotryptic species revealed a pattern of isoforms more complex than that seen either in the intact protein or in the steroid-containing tryptic fragments. These results suggest that the 41-kDa [3H]DM-labeled species resolved by one-dimensional SDS-PAGE after chymotrypsin digestion may be composed of several distinct proteolytic fragments.     

Characterization of Escherichia coli DnaAcos protein in replication systems reconstituted with highly purified proteins

Excessive initiation of chromosomal replication occurs in the dnaAcos mutant at 30°C. Whereas purified wild-type DnaA protein binds ATP and ADP tightly, DnaAcos protein is defective for such nucleotide binding. As initiation is a multistep reaction and DnaA protein functions at each step, activities of DnaAcos protein need to be examined precisely. DnaAcos protein specifically bound a DNA fragment containing the chromosomal replication origin with an affinity similar to that seen with the wild-type protein. In a system reconstituted with purified proteins at 30°C, the mutant protein initiated replication of single-stranded DNA that contains a DnaA-binding hairpin structure. Thus, DnaAcos protein basically sustains affinity to a DnaA-binding sequence and functions in the loading of DnaB helicase onto single-stranded DNA. Thermal stabilities of wild-type DnaA and DnaAcos activities were comparable. Unlike wild-type DnaA protein, DnaAcos protein was inactive for minichromosomal replication in systems reconstituted with purified proteins in which the ATP-bound form of DnaA protein is required for initiation. Taken together, the data indicate that the prominent defect in DnaAcos protein appears to be the inability to bind nucleotide.     

Site-directed mutational analysis of DnaA protein, the initiator of chromosomal DNA replication in E. coli

DnaA protein, the initiator for chromosomal DNA replication in Escherichia coli, has various activities, such as oligomerization (DnaA-DnaA interaction), ATP-binding, ATPase activity and membrane-binding. Site-directed mutational analyses have revealed not only the amino acid residues that are essential for these activities but also the functions of these activities. Following is a summary of the functions and regulatory mechanisms of DnaA protein in the initiation of chromosomal DNA replication. ATP-bound DnaA protein, but not other forms of the protein binds to the origin of DNA replication and forms oligomers to open-up the duplex DNA. This oligomerization is mediated by a DnaA-DnaA interaction through the N-terminal region of the protein. After initiation of DNA replication, the ATPase activity of DnaA protein is stimulated and DnaA protein is inactivated to the ADP-bound form to suppress the re-initiation of DNA replication. DnaA protein binds to acidic phospholipids through an ionic interaction between basic amino acid residues of the protein and acidic residues of phospholipids. This interaction seems to be involved in the re-activation of DnaA protein (from the ADP-bound form to the ATP-bound form) to initiate DNA replication after the appropriate interval.     

Molecular mechanism for functional interaction between DnaA protein and acidic phospholipids: identification of important amino acids

DnaA protein, the initiator of chromosomal DNA replication in Escherichia coli, seems to be reactivated from the ADP-bound form to its ATP-bound form through stimulation of ADP release by acidic phospholipids such as cardiolipin. We previously reported that two potential amphipathic helices (Lys-327 to Ile-344 and Asp-357 to Val-374) of DnaA protein are involved in the functional interaction between DnaA and cardiolipin. In relation to one of these helices (Asp-357 to Val-374), we demonstrated that basic amino acids in the helix, especially Lys-372, are vital for this interaction. In this study, we have identified an amino acid in the second potential amphipathic helix (Lys-327 to Ile-344), which would also appear to be involved in the interaction. We constructed three mutant dnaA genes with a single mutation (dnaAR328E, dnaAR334E, and dnaAR342E) and examined the function of the mutant proteins. DnaAR328E, but not DnaAR334E and DnaAR342E, was found to be more resistant to inhibition of its ATP binding activity by cardiolipin than the wild-type protein. The stimulation of ADP release from DnaAR328E by cardiolipin was also weaker than that observed with the other mutants and the wild-type protein. These results suggest that Arg-328 of DnaA protein is involved in the functional interaction of this protein with acidic phospholipids. We propose that acidic phospholipids bind to two basic amino acid residues (Arg-328 and Lys-372) of DnaA protein and change the higher order structure of its ATP-binding pocket, which in turn stimulates the release of ADP from the protein.     

Structural and immunochemical analysis of the products of proteolysis of simian adenovirus hexons

Hexon capsomers of simian adenovirus sim16 (SA7) and of human adenoviruses h5 (Ad5) and h6 (Ad6) were proteolytically digested and the resulting products studied by SDS-polyacrylamide gel electrophoresis and by radioimmunoprecipitation analysis. The trypsinolysis of native SA7 hexon leads to a stable molecular "core" containing 4-5 fragment species of 10 to 65 kDa and resembling the intact capsomer in quarternary structure (trimer). Similar cores but consisting of smaller fragments (less than 40 kDa) were obtained after chymotryptic digestion of native SA7, Ad5 and Ad6 hexons. The chymotryptic hexon fragments were also held together in pseudotrimeric structures. The similarity of proteolytic hexon fragment patterns between different primate adenoviral hexons suggested a homology to exist in localisation of the exposed tryptic and chymotryptic cleavage sites in their respective hexon polypeptide chains. Papain caused a complete hydrolysis of native SA7 hexon (trimer) yielding small peptides, but at first stage of digestion a stable papain hexon core containing small fragments (less than 10 kDa) was observed. The tryptic SA7 hexon cores in native state retained their antigenicity in reactions with homo- and heterologous antibodies, but after core denaturation the resulting fragments had no antigenic activity of native capsomer. In contrast to the data previously published, chymotryptic cores of SA7, Ad5 and Ad6 hexons not only reacted with respective homologous antibodies but also retained (at least in part) cross-reactive antigenic determinants. The questions of formation and stability of native adenoviral hexon conformation are discussed as well as the possible nature of hexon antigenic determinants.     

Identification of amino acids involved in the functional interaction between DnaA protein and acidic phospholipids

DnaA protein, the initiator of chromosomal DNA replication in Escherichia coli, seems to be regulated through its binding to acidic phospholipids, such as cardiolipin. In our previous paper (Hase, M., Yoshimi, T., Ishikawa, Y., Ohba, A., Guo, L., Mima, S., Makise, M., Yamaguchi, Y., Tsuchiya, T., and Mizushima, T. (1998) J. Biol. Chem. 273, 28651-28656), we found that mutant DnaA protein (DnaA431), in which three basic amino acids (Arg(360), Arg(364), and Lys(372)) were mutated to acidic amino acids showed a decreased ability to interact with cardiolipin in vitro, suggesting that DnaA protein binds to cardiolipin through an ionic interaction. In this study, we construct three mutant dnaA genes each with a single mutation and examined the function of the mutant proteins in vitro and in vivo. All mutant proteins maintained activities for DNA replication and ATP binding. A mutant protein in which Lys(372) was mutated to Glu showed the weakest interaction with cardiolipin among these three mutant proteins. Thus, Lys(372) seems to play an important role in the interaction between DnaA protein and acidic phospholipids. Plasmid complementation analyses revealed that all these mutant proteins, including DnaA431 could function as an initiator for chromosomal DNA replication in vivo.     

Autophosphorylation of smooth-muscle caldesmon.

Caldesmon, a major actin- and calmodulin-binding protein of smooth muscle, has been implicated in regulation of the contractile state of smooth muscle. The isolated protein can be phosphorylated by a co-purifying Ca2+/calmodulin-dependent protein kinase, and phosphorylation blocks inhibition of the actomyosin ATPase by caldesmon [Ngai & Walsh (1987) Biochem. J. 244, 417-425]. We have examined the phosphorylation of caldesmon in more detail. Several lines of evidence indicate that caldesmon itself is a kinase and the reaction is an intermolecular autophosphorylation: (1) caldesmon (141 kDa) and a 93 kDa proteolytic fragment of caldesmon can be separated by ion-exchange chromatography: both retain caldesmon kinase activity, which is Ca2+/calmodulin-dependent; (2) chymotryptic digestion of caldesmon generates a Ca2+/calmodulin-independent form of caldesmon kinase; (3) caldesmon purified to electrophoretic homogeneity retains caldesmon kinase activity, and elution of enzymic activity from a fast-performance-liquid-chromatography ion-exchange column correlates with caldesmon of Mr 141,000; (4) caldesmon is photoaffinity-labelled with 8-azido-[alpha-32P]ATP; labelling is inhibited by ATP, GTP and CTP, indicating a lack of nucleotide specificity; (5) caldesmon binds tightly to Affi-Gel Blue resin, which recognizes proteins having a dinucleotide fold. Autophosphorylation of caldesmon occurs predominantly on serine residues (83.3%), with some threonine (16.7%) and no tyrosine phosphorylation. Autophosphorylation is site-specific: 98% of the phosphate incorporated is recovered in a 26 kDa chymotryptic peptide. Complete tryptic/chymotryptic digestion of this phosphopeptide followed by h.p.l.c. indicates three major phosphorylation sites. Caldesmon exhibits a high degree of substrate specificity: apart from autophosphorylation, brain synapsin I is the only good substrate among many potential substrates examined. These observations indicate that caldesmon may regulate its own function (inhibition of the actomyosin ATPase) by Ca2+/calmodulin-dependent autophosphorylation. Furthermore, caldesmon may regulate other cellular processes, e.g. neurotransmitter release, through the Ca2+/calmodulin-dependent phosphorylation of other proteins such as synapsin I.     

Characterization of a caldesmon fragment that competes with myosin-ATP binding to actin.

The protein caldesmon inhibits actin-activated ATP hydrolysis of myosin and inhibits the binding of myosin.ATP to actin. A fragment isolated from a chymotryptic digest of caldesmon contains features of the intact molecule that make it useful as a selective inhibitor of the binding of myosin.ATP complexes to actin without having the complexity of binding to myosin. The COOH-terminal 20 kDa region of caldesmon binds to actin with one-sixth the affinity of caldesmon with a stoichiometry of binding of one fragment per two actin monomers. This contrasts with the 1:6-9 stoichiometry of intact caldesmon. The binding of the 20 kDa fragments to actin is totally reversed by Ca(2+)-calmodulin and, like intact caldesmon, the 20 kDa fragments are competitive with the binding of myosin subfragments to actin. This competition with myosin binding is largely responsible for the inhibition of ATP hydrolysis, although both the fragments and intact caldesmon also reverse the potentiation of ATPase activity caused by tropomyosin. These polypeptides are useful both in defining the function of caldesmon and in studying the role of weakly bound cross-bridges in muscle.     

A novel role for cAMP in the control of the activity of the E. coli chromosome replication initiator protein, DnaA

DnaA protein interacts with cAMP with a KD of 1 microM. This interaction stimulates DnaA protein binding to the chromosome replication origin (oriC) and the mioC promoter region, protects DnaA protein from thermal inactivation, releases ADP but not ATP bound to DnaA protein, and restores normal DNA replication activity and ATPase activity in inactive ADP-DnaA protein preparations. A model is proposed in which cellular cAMP levels govern the replication activity of DnaA protein by promoting the recycling of the inactive ADP-DnaA protein form into the active ATP form.