Calcium binding to calmodulin mutants monitored by domain-specific intrinsic phenylalanine and tyrosine fluorescence

Cooperative calcium binding to the two homologous domains of calmodulin (CaM) induces conformational changes that regulate its association with and activation of numerous cellular target proteins. Calcium binding to the pair of high-affinity sites (III and IV in the C-domain) can be monitored by observing calcium-dependent changes in intrinsic tyrosine fluorescence intensity (lambda(ex)/lambda(em) of 277/320 nm). However, calcium binding to the low-affinity sites (I and II in the N-domain) is more difficult to measure with optical spectroscopy because that domain of CaM does not contain tryptophan or tyrosine. We recently demonstrated that calcium-dependent changes in intrinsic phenylalanine fluorescence (lambda(ex)/lambda(em) of 250/280 nm) of an N-domain fragment of CaM reflect occupancy of sites I and II (VanScyoc, W. S., and M. A. Shea, 2001, Protein Sci. 10:1758-1768). Using steady-state and time-resolved fluorescence methods, we now show that these excitation and emission wavelength pairs for phenylalanine and tyrosine fluorescence can be used to monitor equilibrium calcium titrations of the individual domains in full-length CaM. Calcium-dependent changes in phenylalanine fluorescence specifically indicate ion occupancy of sites I and II in the N-domain because phenylalanine residues in the C-domain are nonemissive. Tyrosine emission from the C-domain does not interfere with phenylalanine fluorescence signals from the N-domain. This is the first demonstration that intrinsic fluorescence may be used to monitor calcium binding to each domain of CaM. In this way, we also evaluated how mutations of two residues (Arg74 and Arg90) located between sites II and III can alter the calcium-binding properties of each of the domains. The mutation R74A caused an increase in the calcium affinity of sites I and II in the N-domain. The mutation R90A caused an increase in calcium affinity of sites III and IV in the C-domain whereas R90G caused an increase in calcium affinity of sites in both domains. This approach holds promise for exploring the linked energetics of calcium binding and target recognition.     

Glutamate 85 and glutamate 228 contribute to the pH-response of the soluble form of chloride intracellular channel 1

The chloride intracellular channel protein, CLIC1, is synthesised as a soluble monomer that can reversibly bind membranes. Soluble CLIC1 is proposed to respond to the low pH found at a membrane surface by partially unfolding and restructuring into a membrane-competent conformation. This transition is proposed to be controlled by strategically located “pH-sensor” residues that become protonated at acidic pH. In this study, we investigate the role of two conserved glutamate residues, Glu85 in the N-domain and Glu228 in the C-domain, as pH-sensors. E85L and E228L CLIC1 variants were created to reduce pH sensitivity by permanently breaking the bonds these residues form. The structure and stability of each variant was compared to the wild type at both pH 7.0 and pH 5.5. Neither substitution significantly altered the structure but both decreased the conformational stability. Furthermore, E85L CLIC1 formed a urea-induced unfolding intermediate state at both pH 7 and pH 5.5 compared to wild-type and E228L CLIC1 which only formed the intermediate at pH 5.5. We conclude that Glu85 and Glu228 are two of the five pH-sensor residues of CLIC1 and contribute to the pH-response in different ways. Glu228 lowers the stability of the native state at pH 5.5, while Glu85 contributes both to the stability of the native state and to the formation of the intermediate state. By putting these interactions into the context of the three previously described CLIC1 pH-sensor residues, we propose a mechanism for the conversion of CLIC1 from the soluble state to the pre-membrane form.     

Dissecting the domain structure of Cdc4p, a myosin essential light chain involved in Schizosaccharomyces pombe cytokinesis

Cytokinesis is the process by which one cell divides into two. Key in the cytokinetic mechanism of Schizosaccharomyces pombe is the contractile ring myosin, which consists of two heavy chains (Myo2p), two essential light chains (Cdc4p), and two regulatory light chains (Rlc1p). Cdc4p is a dumbbell-shaped EF-hand protein composed of N- and C-terminal domains separated by a flexible linker. The properties of these two domains are of particular interest because each is hypothesized to have independent functions in binding different components of the cytokinesis machinery. To help define these properties, we used NMR spectroscopy to compare the structure, stability, and dynamics of the isolated N- and C-terminal domains with one another and with native Cdc4p. On the basis of invariant chemical shifts, the N-domain retains the same structure in isolation as in the context of the full-length Cdc4p, whereas the C-domain appears markedly perturbed. This perturbation results from intramolecular binding of the residual linker sequence at the N-terminus of the C-domain in a mode similar to that used by native Cdc4p to associate with target polypeptide sequences. NMR relaxation, thermal denaturation, and amide hydrogen exchange experiments also indicate that the C-domain is less stable and more dynamic than the N-domain, both in isolation and in the full-length protein. We hypothesize that these properties reflect a conformational plasticity of the C-domain, which may allow Cdc4p to interact with several regulatory or contractile ring proteins necessary for cytokinesis.     

Nuclear magnetic resonance studies of isolated structural domains of yeast phosphoglycerate kinase

The structural integrity and substrate binding properties of the two genetically engineered domains of yeast phosphoglycerate kinase were investigated using one- and two-dimensional nuclear magnetic resonance techniques. Both domains were found to fold with regions of native-like structure, with the N-domain showing greater conformational flexibility than the C-domain. The 'basic patch' region of the N-domain is, however, clearly perturbed by removal of the C-domain. This is most likely due to the absence of stabilizing interactions between the C-terminal peptide (including alpha-helices XIII and XIV) and the N-domain. The C-domain is able to bind nucleotide with an affinity only three times less than that of the native protein.     

Volume and free energy of folding for troponin C C-domain: linkage to ion binding and N-domain interaction

Troponin C (TnC) is an 18-kDa acidic protein of the EF-hand family that serves as the trigger for muscle contraction. In this study, we investigated the thermodynamic stability of the C-domain of TnC in all its occupancy states (apo, Mg (2+)-, and Ca (2+)-bound states) using a fluorescent mutant with Phe 105 replaced by Trp (F105W/C-domain, residues 88-162) and (1)H NMR spectroscopy. High hydrostatic pressure was employed as a perturbing agent, in combination with urea or without it. On the basis of changes in Trp emission, the C-domain apo state was denatured by pressure (in the range of 1-1000 bar) in the absence of urea. The fluorescence data were corroborated by following the changes in the (1)H NMR signal of Histidine 128. Addition of Ca (2+) or Mg (2+) increased the C-domain stability so that complete denaturation was attained only by the combined use of high hydrostatic pressure and either 7-8 M or 1.5-2 M urea, respectively. The (1)H NMR spectra in the presence of Ca (2+) was typical of a highly structured protein and allowed us to follow the changes in the local environment of several amino-acid residues as a function of pressure at 4 M Urea. Different residues presented different volume changes, but those that are in the hydrophobic core portrayed values very similar to that obtained for tryptophan 105 as measured by fluorescence, indicating that it is indeed a good probe for the overall tertiary structure. From these experiments, we calculated the thermodynamic parameters (Delta G degrees atm and Delta V) that govern the folding of the C-domain in all its possible physiological states and constructed a thermodynamic cycle. Furthermore, a comparison of the volume and free-energy changes of folding of isolated C-domain with those of intact TnC (F105W) revealed that the N-domain has little effect on the structure of the C-domain, even in the presence of Ca (2+). The volume and free-energy diagrams reveal a landscape of different conformations from the less structured, denatured apo form to the highly structured, Ca (2+)-bound form. The large change in folding free energy of the C-domain that takes place when Ca (2+) binds may explain the much higher Ca (2+) affinity of sites III and IV, 2 orders of magnitude higher than the affinity of sites I and II.     

An acidic amino acid cluster regulates the nucleolar localization and ribosome assembly of human ribosomal protein L22

The control of human ribosomal protein L22 (rpL22) to enter into the nucleolus and its ability to be assembled into the ribosome is regulated by its sequence. The nuclear import of rpL22 depends on a classical nuclear localization signal of four lysines at positions 13-16. RpL22 normally enters the nucleolus via a compulsory sequence of KKYLKK (I-domain, positions 88-93). An acidic residue cluster at the C-terminal end (C-domain) plays a nuclear retention role. The retention is concealed by the N-domain (positions 1-9) which weakly interacts with the C-domain as demonstrated in the yeast two-hybrid system. Once it reaches the nucleolus, the question of whether rpL22 is assembled into the ribosome depends upon the presence of the N-domain. This suggests that the N-domain, on dissociation from its interaction with the C-domain, binds to a specific region of the 28S rRNA for ribosome assembly.     

Hydrolysis by somatic angiotensin-I converting enzyme of basic dipeptides from a cholecystokinin/gastrin and a LH-RH peptide extended at the C-terminus with gly-Arg/Lys-arg, but not from diarginyl insulin.

Endoproteolytic cleavage of protein prohormones often generates intermediates extended at the C-terminus by Arg-Arg or Lys-Arg, the removal of which by a carboxypeptidase (CPE) is normally an important step in the maturation of many peptide hormones. Recent studies in mice that lack CP activity indicate the existence of alternative tissue or plasma enzymes capable of removing C-terminal basic residues from prohormone intermediates. Using inhibitors of angiotensin I-converting enzyme (ACE) and CP, we show that both these enzymes in mouse serum can remove the basic amino acids from the C-terminus of CCK5-GRR and LH-RH-GKR, but only CP is responsible for converting diarginyl insulin to insulin. ACE activity removes C-terminal dipeptides to generate the Gly-extended peptides, whereas CP hydrolysis gives rise to CCK5-GR and LH-RH-GK, both of which are susceptible to the dipeptidyl carboxypeptidase activity of ACE. Somatic ACE has two similar protein domains (the N-domain and the C-domain), each with an active site that can display different substrate specificities. CCK5-GRR is a high-affinity substrate for both the N-domain and C-domain active sites of human sACE (Km of 9.4 microm and 9.0 microm, respectively) with the N-domain showing greater efficiency (kcat : Km ratio of 2.6 in favour of the N-domain). We conclude that somatic forms of ACE should be considered as alternatives to CPs for the removal of basic residues from some Arg/Lys-extended peptides.     

Calcium binding to calmodulin mutants having domain-specific effects on the regulation of ion channels

Calmodulin (CaM) is an essential, eukaryotic protein comprised of two highly homologous domains (N and C). CaM binds four calcium ions cooperatively, regulating a wide array of target proteins. A genetic screen of Paramecia by Kung [Kung, C. et al. (1992) Cell Calcium 13, 413-425] demonstrated that the domains of CaM have separable physiological roles: "under-reactive" mutations affecting calcium-dependent sodium currents mapped to the N-domain, while "over-reactive" mutations affecting calcium-dependent potassium currents localized to the C-domain of CaM. To determine whether and how these mutations affected intrinsic calcium-binding properties of CaM domains, phenylalanine fluorescence was used to monitor calcium binding to sites I and II (N-domain) and tyrosine fluorescence was used to monitor sites III and IV (C-domain). To explore interdomain interactions, binding properties of each full-length mutant were compared to those of its corresponding domain fragments. The calcium-binding properties of six under-reactive mutants (V35I/D50N, G40E, G40E/D50N, D50G, E54K, and G59S) and one over-reactive mutant (M145V) were indistinguishable from those of wild-type CaM, despite their deleterious physiological effects on ion-channel regulation. Four over-reactive mutants (D95G, S101F, E104K, and H135R) significantly decreased the calcium affinity of the C-domain. Of these, one (E104K) also increased the calcium affinity of the N-domain, demonstrating that the magnitude and direction of wild-type interdomain coupling had been perturbed. This suggests that, while some of these mutations alter calcium-binding directly, others probably alter CaM-channel association or calcium-triggered conformational change in the context of a ternary complex with the affected ion channel.     

Monoclonal Antibodies 1G12 and 6A12 to the N-domain of human angiotensin-converting enzyme: fine epitope mapping and antibody-based detection of ACE inhibitors in human blood

Angiotensin I-converting enzyme (ACE), a key enzyme in cardiovascular pathophysiology, consists of two homologous domains (N- and C-), each bearing a Zn-dependent active site. ACE inhibitors are among the most prescribed drugs in the treatment of hypertension and cardiac failure. Fine epitope mapping of two monoclonal antibodies (mAb), 1G12 and 6A12, against the N-domain of human ACE, was developed using the N-domain 3D-structure and 21 single and double N-domain mutants. The binding of both mAbs to their epitopes on the N-domain of ACE is significantly diminished by the presence of the C-domain in the two-domain somatic tissue ACE and further diminished by the presence of sialic acid residues on the surface of blood ACE. The binding of these mAbs to blood ACE, however, increased dramatically (5-10-fold) in the presence of ACE inhibitors or EDTA, whereas the effect of these compounds on the binding of the mAbs to somatic tissue ACE was less pronounced and even less for truncated N-domain. This implies that the binding of ACE inhibitors or removal of Zn2+ from ACE active centers causes conformational adjustments in the mutual arrangement of N- and C-domains in the two-domain ACE molecule. As a result, the regions of the epitopes for mAb 1G12 and 6A12 on the N-domain, shielded in somatic ACE by the C-domain globule and additionally shielded in blood ACE by sialic acid residues in the oligosaccharide chains localized on Asn289 and Asn416, become unmasked. Therefore, we demonstrated a possibility to employ these mAbs (1G12 or 6A12) for detection and quantification of the presence of ACE inhibitors in human blood. This method should find wide application in monitoring clinical trials with ACE inhibitors as well as in the development of the approach for personalized medicine by these effective drugs.     

Multiple folding states and disorder of ribosomal protein SA, a membrane receptor for laminin, anticarcinogens, and pathogens

The human ribosomal protein SA (RPSA) is a multilocus protein, present in most cellular compartments. It is a multifunctional protein, which belongs to the ribosome but is also a membrane receptor for laminin, growth factors, prion, pathogenic microorganisms, toxins, and the anticarcinogen epigallocatechin gallate. It contributes to the crossing of the blood-brain barrier by neurotropic viruses and bacteria and is used as a biomarker of metastasis. RPSA includes an N-terminal domain, which is homologous to the prokaryotic ribosomal proteins S2, and a C-terminal extension, which is conserved in vertebrates. The structure of its N-domain has been determined from crystals grown at 17 °C. The structure of its C-domain remains unknown. We produced in Escherichia coli and purified the full-length RPSA and its N- and C-domains. We characterized the folding states of these recombinant proteins mainly by methods of fluorescence and circular dichroism spectrometry, in association with quantitative analyses of their unfolding equilibria, induced with heat or urea. The necessary equations were derived from first principles. The results showed that the N-domain unfolded according to a three-state equilibrium. The monomeric intermediate was predominant at the body temperature of 37 °C. It also existed in the full-length RPSA and bound ANS, a small fluorescent molecule. The C-domain was in an intrinsically disordered state. The recombinant N- and C-domains weakly interacted together. These results indicated a high plasticity of RPSA, which could be important for its multiple cellular localizations and functional interactions.     

Effect of N-linked glycosylation on the aspartic proteinase porcine pepsin expressed from Pichia pastoris

A study was undertaken to examine the effects of N-linked glycosylation on the structure-function of porcine pepsin. The N-linked motif was incorporated into four sites (two on the N-terminal domain and two on the C-terminal domain), and the recombinant protein expressed using Pichia pastoris. All four N-linked recombinants exhibited similar secondary and tertiary structure to nonglycosylated pepsin, that is, wild type. Similar K(m) values were observed, but catalytic efficiencies were approximately one-third for all mutants compared with the wild type; however, substrate specificity was not altered. Activation of pepsinogen to pepsin occurred between pH 1.0 to 4.0 for wild-type pepsin, whereas the glycosylated recombinants activated over a wider range, pH 1.0 to 6.0. Glycosylation on the C-terminal domain exhibited similar pH activity profiles to nonglycosylated pepsin, and glycosylation on the N-domain resulted in a change in activity profile. Overall, glycosylation on the C-domain led to a more global stabilization of the structure, which translated into enzymatic stability, whereas on the N-domain, an increase in structural stability had little effect on enzymatic stability. Finally, glycosylation on the flexible loop region also appeared to increase the overall structural stability of the protein compared with wild type. It is postulated that the presence of the carbohydrate residues added rigidity to the protein structure by reducing conformational mobility of the protein, thereby increasing the structural stability of the protein.     

Interdomain cooperativity of calmodulin bound to melittin preferentially increases calcium affinity of sites I and II

Calmodulin (CaM) is the primary transducer of calcium fluxes in eukaryotic cells. Its two domains allosterically regulate myriad target proteins through calcium-linked association and conformational change. Many of these proteins have a basic amphipathic alpha-helix (BAA) motif that binds one or both CaM domains. Previously, we demonstrated domain-specific binding of melittin, a model BAA peptide, to Paramecium CaM (PCaM): C-domain mutations altered the interaction with melittin, whereas N-domain mutations had no discernable effect. Here, we report on the use of fluorescence and NMR spectroscopy to measure the domain-specific association of melittin with calcium-saturated ((Ca(2+))(4)-PCaM) or calcium-depleted (apo) PCaM, which has enabled us to determine the free energies of calcium binding to the PCaM-melittin complex, and to estimate interdomain cooperativity. Under apo conditions, melittin associated with each PCaM domain fragment (PCaM(1-80) and PCaM(76-148)), as well as with the C-domain of full-length PCaM (PCaM(1-148)). In the presence of calcium, all of these interactions were again observed, in addition to which an association with the N-domain of (Ca(2+))(4)-PCaM(1-148) occurred. This new association was made possible by the fact that melittin changed the calcium-binding preferences for the domains from sequential (C > N) to concomitant, decreasing the median ligand activity of calcium toward the N-domain 10-fold more than that observed for the C-domain. This selectivity may be explained by a free energy of cooperativity of -3 kcal/mol between the N- and C-domains. This study demonstrates multiple domain-selective differences in the interactions between melittin and PCaM. Our findings support a model that may apply more generally to ion channels that associate with the C-domain of CaM under low (resting) calcium conditions, but rearrange when calcium binding triggers an association of the N- domain with the channel.     

Domain structure of CAF1M protein from Yersinia pestis. Structure and the role of various domains

The cooperative structure of Caf1M from Yersinia pestis was studied using scanning microcalorimetry, fluorescence, and limited proteolysis. It was shown that, in Caf1M-Hg (a derivative in which the disulfide bond is replaced by an S-Hg-S bond), the first to melt is the N-domain. Then the C-domain melts. After renaturation in a buffer with a low NaCl concentration, only the C-domain is in the native state, and it can be obtained by limited proteolysis. After renaturation in a buffer with a high NaCl concentration, only the N-domain is in the native state, and it can be obtained by limited proteolysis. Both domains have native structure; however, only the N-domain interacts with Cafl (natural substrate for Caf1M).     

The neuronal voltage-dependent sodium channel type II IQ motif lowers the calcium affinity of the C-domain of calmodulin

Calmodulin (CaM) is the primary calcium sensor in eukaryotes. Calcium binds cooperatively to pairs of EF-hand motifs in each domain (N and C). This allows CaM to regulate cellular processes via calcium-dependent interactions with a variety of proteins, including ion channels. One neuronal target is NaV1.2, voltage-dependent sodium channel type II, to which CaM binds via an IQ motif within the NaV1.2 C-terminal tail (residues 1901-1938) [Mori, M., et al. (2000) Biochemistry 39, 1316-1323]. Here we report on the use of circular dichroism, fluorescein emission, and fluorescence anisotropy to study the interaction between CaM and NaV1.2 at varying calcium concentrations. At 1 mM MgCl2, both full-length CaM (CaM1-148) and a C-domain fragment (CaM76-148) exhibit tight (nanomolar) calcium-independent binding to the NaV1.2 IQ motif, whereas an N-domain fragment of CaM (CaM1-80) binds weakly, regardless of calcium concentration. Equilibrium calcium titrations of CaM at several concentrations of the NaV1.2 IQ peptide showed that the peptide reduced the calcium affinity of the CaM C-domain sites (III and IV) without affecting the N-domain sites (I and II) significantly. This leads us to propose that the CaM C-domain mediates constitutive binding to the NaV1.2 peptide, but that interaction then distorts calcium-binding sites III and IV, thereby reducing their affinity for calcium. This contrasts with the CaM-binding domains of voltage-dependent Ca2+ channels, kinases, and phosphatases, which increase the calcium binding affinity of the C-domain of CaM.     

Conformational and metal-binding properties of androcam, a testis-specific, calmodulin-related protein from Drosophila

Androcam is a testis-specific protein of Drosophila melanogaster, with 67% sequence identity to calmodulin and four potential EF-hand calcium-binding sites. Spectroscopic monitoring of the thermal unfolding of recombinant calcium-free androcam shows a biphasic process characteristic of a two-domain protein, with the apo-N-domain less stable than the apo-C-domain. The two EF hands of the C-domain of androcam bind calcium cooperatively with 40-fold higher average affinity than the corresponding calmodulin sites. Magnesium competes with calcium binding [Ka(Mg) approximately 3 x 10(3) M(-1)]. Weak calcium binding is also detected at one or more N-domain sites. Compared to apo-calmodulin, apo-androcam has a smaller conformational response to calcium and a lower alpha-helical content over a range of experimental conditions. Unlike calmodulin, a tryptic cleavage site in the N-domain of apo-androcam remains trypsin sensitive in the presence of calcium, suggesting an altered calcium-dependent conformational change in this domain. The affinity of model target peptides for androcam is 10(3)-10(5) times lower than for calmodulin, and interaction of the N-domain of androcam with these peptides is significantly reduced. Thus, androcam shows calcium-induced conformational responses typical of a calcium sensor, but its properties indicate calcium sensitivity and target interactions significantly different from those of calmodulin. From the sequence differences and the altered calcium-binding properties it is likely that androcam differs from calmodulin in the conformation of residues in the second calcium-binding loop. Molecular modeling supports the deduction that there are significant conformational differences in the N-domain of androcam compared to calmodulin, and that these could affect the surface, conferring a different specificity on androcam in target interactions related to testis-specific calcium signaling functions.     

Crystal structure of hyperthermophilic archaeal initiation factor 5A: a homologue of eukaryotic initiation factor 5A (eIF-5A)

Eukaryotic initiation factor 5A (eIF-5A) is ubiquitous in eukaryotes and archaebacteria and is essential for cell proliferation and survival. The crystal structure of the eIF-5A homologue (PhoIF-5A) from a hyperthermophilic archaebacterium Pyrococcus horikoshii OT3 was determined at 2.0 A resolution by the molecular replacement method. PhoIF-5A is predominantly composed of beta-strands comprising two distinct folding domains, an N-domain (residues 1-69) and a C-domain (residues 72-138), connected by a short linker peptide (residues 70-71). The N-domain has an SH3-like barrel, while the C-domain folds in an (oligonucleotide/oligosaccharide binding) OB fold. Comparison of the structure of PhoIF-5A with those of archaeal homologues from Methanococcus jannaschii and Pyrobaculum aerophilum showed that the N-domains could be superimposed with root mean square deviation (rmsd) values of 0.679 and 0.624 A, while the C-domains gave higher values of 1.824 and 1.329 A, respectively. Several lines of evidence suggest that eIF-5A functions as a biomodular protein capable of interacting with protein and nucleic acid. The surface representation of electrostatic potential shows that PhoIF-5A has a concave surface with positively charged residues between the N- and C-domains. In addition, a flexible long hairpin loop, L1 (residues 33-41), with a hypusine modification site is positively charged, protruding from the N-domain. In contrast, the opposite side of the concave surface at the C-domain is mostly negatively charged. These findings led to the speculation that the concave surface and loop L1 at the N-domain may be involved in RNA binding, while the opposite side of the concave surface in the C-domain may be involved in protein interaction.     

An engineered amino-terminal domain of yeast phosphoglycerate kinase with native-like structure.

Previous studies have suggested that the carboxy-terminal peptide (residues 401-415) and interdomain helix (residues 185-199) of yeast phosphoglycerate kinase, a two-domain enzyme, play a role in the folding and stability of the amino-terminal domain (residues 1-184). A deletion mutant has been created in which the carboxy-terminal peptide is attached to the amino-terminal domain (residues 1-184) plus interdomain helix (residues 185-199) through a flexible peptide linker, thus eliminating the carboxy-terminal domain entirely. CD, fluorescence, gel filtration, and NMR experiments indicated that, unlike versions described previously, this isolated N-domain is soluble, monomeric, compactly folded, native-like in structure, and capable of binding the substrate 3-phosphoglycerate with high affinity in a saturable manner. The midpoint of the guanidine-induced unfolding transition was the same as that of the native two-domain protein (Cm approximately 0.8 M). The free energy change associated with guanidine-induced unfolding was one-third that of the native enzyme, in agreement with previous studies that evaluated the intrinsic stability of the N-domain and the contribution of domain-domain interactions to the stability of PGK. These observations suggest that the C-terminal peptide and interdomain helix are sufficient for maintaining a native-like fold of the N-domain in the absence of the C-domain.     

Peptidase specificity characterization of C- and N-terminal catalytic sites of angiotensin I-converting enzyme

Quenched fluorescence peptides were used to investigate the substrate specificity requirements for recombinant wild-type angiotensin I-converting enzyme (ACE) and two full-length mutants bearing a single functional active site (N- or C-domain). We assayed two series of bradykinin-related peptides flanked by o-aminobenzoic acid (Abz) and N-(2,4-dinitrophenyl)ethylenediamine (EDDnp), namely, Abz-GFSPFXQ-EDDnp and Abz-GFSPFRX-EDDnp (X = natural amino acids), in which the fluorescence appeared when Abz/EDDnp are separated by substrate hydrolysis. Abz-GFSPFFQ-EDDnp was preferentially hydrolyzed by the C-domain while Abz-GFSPFQQ-EDDnp exhibits higher N-domain specificity. Internally quenched fluorescent analogues of N-acetyl-SDKP-OH were also synthesized and assayed. Abz-SDK(Dnp)P-OH, in which Abz and Dnp (2,4-dinitrophenyl) are the fluorescent donor-acceptor pair, was cleaved at the D-K(Dnp) bond with high specificity by the ACE N-domain (k(cat)/K(m) = 1.1 microM(-)(1) s(-)(1)) being practically resistant to hydrolysis by the C-domain. The importance of hydroxyl-containing amino acids at the P(2) position for N-domain specificity was shown by performing the kinetics of hydrolysis of Abz-TDK(Dnp)P-OH and Abz-YDK(Dnp)P-OH. The peptides Abz-YRK(Dnp)P-OH and Abz-FRK(Dnp)P-OH which were hydrolyzed by wild-type ACE with K(m) values of 5.1 and 4.0 microM and k(cat) values of 246 and 210 s(-)(1), respectively, have been shown to be excellent substrates for ACE. The differentiation of the catalytic specificity of the C- and N-domains of ACE seems to depend on very subtle variations on substrate-specific amino acids. The presence of a free C-terminal carboxyl group or an aromatic moiety at the same substrate position determines specific interactions with the ACE active site which is regulated by chloride and seems to distinguish the activities of both domains.     

Stabilities and activities of the N- and C-domains of FKBP22 from a psychrotrophic bacterium overproduced in Escherichia coli

FKBP22 from a psychrotrophic bacterium Shewanella sp. SIB1, is a dimeric protein with peptidyl prolyl cis-trans isomerase (PPIase) activity. According to homology modeling, it consists of an N-terminal domain, which is involved in dimerization of the protein, and a C-terminal catalytic domain. A long alpha3 helix spans these domains. An N-domain with the entire alpha3 helix (N-domain+) and a C-domain with the entire alpha3 helix (C-domain+) were overproduced in Escherichia coli in a His-tagged form, purified, and their biochemical properties were compared with those of the intact protein. C-domain+ was shown to be a monomer and enzymatically active. Its optimum temperature for activity (10 degrees C) was identical to that of the intact protein. Determination of the PPIase activity using peptide and protein substrates suggests that dimerization is required to make the protein fully active for the protein substrate or that the N-domain is involved in substrate-binding. The differential scanning calorimetry studies revealed two distinct heat absorption peaks at 32.5 degrees C and 46.6 degrees C for the intact protein, and single heat absorption peaks at 44.7 degrees C for N-domain+ and 35.6 degrees C for C-domain+. These results indicate that the thermal unfolding transitions of the intact protein at lower and higher temperatures represent those of C- and N-domains, respectively. Because the unfolding temperature of C-domain+ is much higher than its optimum temperature for activity, SIB1 FKBP22 may adapt to low temperatures by increasing a local flexibility around the active site. This study revealed the relationship between the stability and the activity of a psychrotrophic FKBP22.     

Kinetic regulation of single DNA molecule denaturation by T4 gene 32 protein structural domains

Bacteriophage T4 gene 32 protein (gp32) specifically binds single-stranded DNA, a property essential for its role in DNA replication, recombination, and repair. Although on a thermodynamic basis, single-stranded DNA binding proteins should lower the thermal melting temperature of double-stranded DNA (dsDNA), gp32 does not. Using single molecule force spectroscopy, we show for the first time that gp32 is capable of slowly destabilizing natural dsDNA. Direct measurements of single DNA molecule denaturation and renaturation kinetics in the presence of gp32 and its proteolytic fragments reveal three types of kinetic behavior, attributable to specific protein structural domains, which regulate gp32's helix-destabilizing capabilities. Whereas the full-length protein exhibits very slow denaturation kinetics, a truncate lacking the acidic C-domain exhibits much faster kinetics. This may reflect a steric blockage of the DNA binding site and/or a conformational change associated with this domain. Additional removal of the N-domain, which is needed for binding cooperativity, further increases the DNA denaturation rate, suggesting that both of these domains are critical to the regulation of gp32's helix-destabilization capabilities. This regulation is potentially biologically significant because uncontrolled helix-destabilization would be lethal to the cell. We also obtain equilibrium measurements of the helix-coil transition free energy in the presence of these proteins for the first time.