Synthesis and conformational studies of peptides encompassing the carboxy-terminal helix of thermolysin

The 21-residue fragment Tyr-Gly-Ser-Thr-Ser-Gln-Glu-Val-Ala-Ser-Val-Lys-Gln-Ala-Phe-Asp-Ala-Val- Gly-Val-Lys, corresponding to sequence 296-316 of thermolysin and thus encompassing the COOH-terminal helical segment 301-312 of the native protein, was synthesized by solid-phase methods and purified to homogeneity by reverse-phase high performance liquid chromatography. The peptide 296-316 was then cleaved with trypsin at Lys307 and Staphylococcus aureus V8 protease at Glu302, producing the additional fragments 296-307, 308-316, 296-302, and 303-316. All these peptides, when dissolved in aqueous solution at neutral pH, are essentially structureless, as determined by circular dichroism (CD) measurements in the far-ultraviolet region. On the other hand, fragment 296-316, as well as some of its proteolytic fragments, acquires significant helical conformation when dissolved in aqueous trifluoroethanol or ethanol. In general, the peptides mostly encompassing the helical segment 301-312 in the native thermolysin show helical conformation in aqueous alcohol. In particular, quantitative analysis of CD data indicated that fragment 296-316 attains in 90% aqueous trifluoroethanol the same percentage (approximately 58%) of helical secondary structure of the corresponding chain segment in native thermolysin. These results indicate that peptide 296-316 and its subfragments are unable to fold into a stable native-like structure in aqueous solution, in agreement with predicted location and stabilities of isolated subdomains of the COOH-terminal domain of thermolysin based on buried surface area calculations of the molecule.     

Folding of thermolysin fragments. Correlation between conformational stability and antigenicity of carboxyl-terminal fragments

Circular dichroism (CD) and immunochemical measurements have been used to examine conformational properties of COOH-terminal fragments 121-316, 206-316 and 225(226)-316 of thermolysin, and to compare these properties to those of native thermolysin and thermolysin S, the stable partially active two-fragment complex composed of fragments 5-224(225) and 225(226)-316. In aqueous solution at neutral pH, all the COOH-terminal fragments attain a native-like conformation, as judged both by the content of secondary structure deduced from far-ultraviolet CD spectra and by the recognition of rabbit polyclonal antibodies specific for the COOH-terminal region in native thermolysin. The three fragments showed reversible cooperative unfolding transitions mediated by both heat and guanidine hydrochloride (Gdn X HCl). The phase transition curves were analyzed for Tm (temperature of half-denaturation) and Gibbs free energies (delta GD) of unfolding from native to denatured state. The observed order of thermal stability is 225(226)-316 less than or equal to 206-316 less than 121-316 less than thermolysin S less than thermolysin. The ranking of delta GD values for the three fragments correlates with the size of each fragment. Competitive binding studies by radioimmunoassay using 14C-labeled thermolysin and affinity purified antibodies specific for native antigenic determinants in segment 206-316 of native thermolysin indicate that the COOH-terminal fragments adopt native-like conformations which are in equilibrium with non-native conformations. These equilibria are shifted towards the native state as the fragment size increases from 225(226)-316, to 206-316, to 121-316. Fragment 225(226)-316, when combined with fragment 5-224(225) in the thermolysin S complex, adopts a more stable native-like conformation and becomes much more antigenic. It has been shown that the degree of antigenicity of COOH-terminal fragments towards thermolysin antibodies correlates directly with their conformational stability. The results of this study are discussed in relation to the recently proposed correlation between antigenicity and segmental mobility of globular proteins.     

Enhanced Protein Thermostability by Ala --> Aib Replacement

The introduction into peptide chains of alpha-aminoisobutyric acid (Aib) has proven to stabilize the helical structure in short peptides by restricting the available range of polypeptide backbone conformations. In order to evaluate the potential stabilizing effect of Aib at the protein level, we have studied the conformational and stability properties of Aib-containing analogs of the carboxy-terminal subdomain 255-316 of thermolysin. Previous NMR studies have shown that this disulfide-free 62-residue fragment forms a dimer in solution and that the global 3D structure of each monomer (3 alpha-helices encompassing residues 260-274, 281-295, and 301-311) is largely coincident with that of the corresponding region in the X-ray structure of intact thermolysin. The Aib analogs of fragment 255-316 were prepared by a semisynthetic approach in which the natural fragment 255-316 was coupled to synthetic analogs of peptide 303-316 using V8-protease in 50% (v/v) aqueous glycerol [De Filippis, V., and Fontana, A. (1990) Int. J. Pept. Protein Res. 35, 219-227]. The Ala residue in position 304, 309, or 312 of fragment 255-316 was replaced by Aib, leading to the singly substituted fragments Ala304Aib, Ala309Aib, and Ala312Aib. Moreover, fragment Ala304Aib/Ala309Aib with a double Ala --> Aib exchange in positions 304 and 309 was produced. Far- and near-UV circular dichroism measurements demonstrated that both secondary and tertiary structures of the natural fragment 255-316 are fully retained upon Ala --> Aib substitution(s). Thermal unfolding measurements, carried out by recording the ellipticity at 222 nm upon heating, showed that the melting temperatures (Tm) of analogs Ala304Aib and Ala309Aib were 2.2 and 5.4 °C higher than that of the Ala-containing natural species (Tm = 63.5 °C), respectively, whereas the Tm of the Ala312Aib analog was lowered by -0.6 °C. The enhanced stability of the Ala304Aib analog can be quantitatively explained on the basis of a reduced backbone entropy of unfolding due to the restriction of the conformational space allowed to Aib in respect to Ala, while the larger stabilization observed for the Ala309Aib analog can be accounted for by both entropic and hydrophobic effects. In fact, whereas Ala304 is a surface residue, Ala309 is shielded from the solvent, and thus the enhanced stability of fragment Ala309Aib is also due to the burial of an additional -CH3 group with respect to the natural fragment. The slightly destabilizing effect of the Ala --> Aib exchange in position 312 appears to derive from unfavorable strain energy effects, since phi and psi values for Ala312 are out of the allowed angles for Aib. Of interest, the simultaneous incorporation of Aib at positions 304 and 309 leads to a significant and additive increase of +8 °C in Tm. The results of this study indicate that the rational incorporation of Aib into a polypeptide chain can be a general procedure to significantly stabilize proteins.     

Folding of thermolysin fragments. Identification of the minimum size of a carboxyl-terminal fragment that can fold into a stable native-like structure

The COOH-terminal cyanogen bromide fragment 206-316 of thermolysin has been shown to possess protein domain characteristics that are able to refold into a stable native-like structure (Fontana et al., 1982). We now report the results of limited proteolysis of this fragment with the aim of identifying the minimum size of a COOH-terminal fragment of thermolysin that is able to fold by itself. Proteolysis with subtilisin, chymotrypsin, thermolysin and trypsin allowed us to isolate to homogeneity eight different subfragments, which can be grouped in two sets of peptides, i.e. (218-222)-316 and (252-255)-316. These subfragments are able to acquire a stable conformation of native-like characteristics, as judged by quantitative analysis of secondary structure from far-ultraviolet circular dichroism spectra and immunochemical properties using rabbit anti-thermolysin antibodies. In addition, even the smallest fragment isolated (sequence 255-316) shows co-operative and reversible unfolding transitions mediated by heat (tm 65 degrees C) and guanidine hydrochloride (midpoint transition at 2.5 M denaturant), as often observed with globular proteins. From the kinetics of the proteolytic digestion and analysis of the isolated subfragments, it is concluded that proteases lead to a stepwise degradation of fragment 206-316 from its NH2-terminal region, leading to the highly helical fragment (252-255)-316, quite resistant to further proteolytic digestion. The results of this study provide evidence that it is possible to isolate stable supersecondary structures of globular proteins and correlate well with predictions of subdomains of the COOH-terminal structural domain of thermolysin.     

Conformationally driven protease-catalyzed splicing of peptide segments: V8 protease-mediated synthesis of fragments derived from thermolysin and ribonuclease A.

We have studied the conformation as well as V8 protease-mediated synthesis of peptide fragments, namely amino acid residues 295-316 (TC-peptide) of thermolysin and residues 1-20 (S-peptide) of ribonuclease A, to examine whether "conformational trapping" of the product can facilitate reverse proteolysis. The circular dichroism study showed cosolvent-mediated cooperative helix formation in TC-peptide with attainment of about 30-35% helicity in the presence of 40% 1-propanol and 2-propanol solutions at pH 6 and 4 degrees C. The thermal melting profiles of TC-peptide in the above cosolvents were very similar. V8 protease catalyzed the synthesis of TC-peptide from a 1:1 mixture of the non-interacting complementary fragments (TC295-302 and TC303-316) in the presence of the above cosolvents at pH 6 and 4 degrees C. In contrast, V8 protease did not catalyze the ligation of S1-9 and S10-20, although S-peptide could assume helical conformation in the presence of the cosolvent used for the semisynthetic reaction. V8 protease was able to synthesize an analog of S-peptide (SA-peptide) in which residues 10-14 were substituted (RQHMD-->VAAAK). While S-peptide exhibited helical conformation in the presence of aqueous propanol solutions, SA-peptide displayed predominantly beta-sheet conformation. SA-peptide showed enhanced resistance to proteolysis as compared with S-peptide. Thus, failure of semisynthesis of S-peptide may be a consequence of high flexibility around the 9-10 peptide bond due to its proximity to the helix stop signal. The results suggest that protease-mediated ligations may be achieved by design and manipulation of the conformational aspects of the product.     

Hierarchic organization of globular proteins: Experimental studies on thermolysin

Previous studies from this laboratory have shown that the thermolysin fragment 121–316, comprising entirely the“all-α” COOH-terminal structural domain 158–316, as well as fragment 206–316 (fragment FII) are able to refold into a native-like, stable structure independently from the rest of the protein molecule. The present report describes conformational properties of fragments 228–316 and 255–316 obtained by chemical and enzymatic cleavage of fragment FII, respectively. These subfragments are able to acquire a stable conformation of native-like characteristics, as judged by quantitative analysis of secondary structure from far-ultra-violet circular dichroism spectra and immunochemical properties using rabbit anti-thermolysin antibodies. Melting curves of the secondary structure of the fragments show cooperativity with a temperature of half-denaturationT _mof 65–66°C. The results of this study provide evidence that it is possible to isolate stable supersecondary structures (folding units) of globular proteins and correlate well with predictions of subdomains of the COOH-terminal structural domain 158–316 of thermolysin.     

Independent folding of the carboxyl-terminal fragment 228-316 of thermolysin

The COOH-terminal fragment 206-316 of thermolysin was shown previously to maintain a stable folded structure in aqueous solution comparable to that of the corresponding region in native thermolysin and thus to possess protein domain characteristics [Fontana, A., Vita, C., & Chaiken, I. M. (1983) Biopolymers 22, 69-78]. In order to study the effect of polypeptide chain length on folding and stability of an isolated domain, the 111 amino acid residue fragment was shortened on the NH2-terminal side by removal of a 22-residue segment. Treatment of fragment 206-316 with hydroxylamine under alkaline conditions permitted selective cleavage of the Asn227-Gly228 peptide bond, and from the reaction mixture fragment 228-316 was isolated in homogeneous form. This fragment appeared to attain in aqueous solution the folding properties of the corresponding segment in the intact protein, as indicated by quantitative analysis of secondary structure from far-ultraviolet circular dichroism spectra and immunological properties. Thus, double-immunodiffusion analyses showed that fragment 228-316 is able to recognize and precipitate anti-thermolysin antibodies raised in rabbits with native thermolysin as immunogen. The fragment displayed fully reversible and cooperative conformational transitions mediated by pH, heat, and guanidine hydrochloride (Gdn.HCl), as expected for a globular protein species. Thermal denaturation of the fragment in aqueous solution at pH 7.8 showed a Tm of 66 degrees C and the Gdn.HCl-mediated unfolding a midpoint transition at 2.2 M denaturant concentration.(ABSTRACT TRUNCATED AT 250 WORDS)     

Synthetic potential of Staphylococcus aureus V8-protease: an approach toward semisynthesis of covalent analogs of alpha-chain of hemoglobin S

Enzyme-catalyzed reformation of peptide bonds in the noncovalent fragment systems of proteins has been emerging as a convenient procedure for the semisynthesis of covalent analogs of the respective proteins. Limited proteolysis of the alpha-chain of hemoglobin S with Staphylococcus aureus V8-protease converts the chain into a fragment-complementing system by hydrolyzing the peptide bond Glu(30)-Arg(31) of the chain. Therefore, it is conceivable that semisynthesis of covalent analogs of alpha-chain could be achieved if conditions for the V8-protease catalyzed formation of peptide bonds could be established. The synthetic potential of V8-protease has been now investigated by incubating V8-protease-derived fragments of alpha-chain, namely alpha 1-30 and alpha 31-47 with the enzyme at pH 6.0 in the presence of n-propanol as the organic cosolvent. RP high performance liquid chromatography analysis showed that a new chromatographically distinct component is generated on incubation, and this has been identified as alpha 1-47 by amino acid analysis, redigestion with V8-protease (in the absence of n-propanol), and tryptic peptide mapping. Optimal conditions for the synthesis of alpha 1-47 is at pH 6.0, 4 degrees C, and 24 hr of incubation with 25% n-propanol as organic cosolvent. This stereospecific condensation of the fragments proceeded to a high level of about 50% in 24 hr. Further incubation up to 72 hr did not increase the yield of alpha 1-47, suggesting that an equilibration of synthesis and hydrolysis reactions has been attained. The demonstration of the synthetic potential of V8-protease and the fact that alpha 1-30 and alpha 31-141 interact to form a native-like complex, opens up an approach for the semisynthesis of covalent analogs of alpha-chain of hemoglobin S.     

Isolation of large peptides derived by cyanogen bromide cleavage of thermolysin using fast protein liquid chromatography (FPLC)

The recently introduced fast protein liquid chromatography (FPLC) system of Pharmacia (Uppsala, Sweden) was employed to isolate rather large peptides derived from thermolysin by selective chemical fragmentation at methionine in positions 120 and 205 of the polypeptide chain of 316 amino acid residues. Thermolysin was cleaved under conditions of limited fragmentation in order to produce, besides fragments 1-120, 121-205 and 206-316, the overlapping fragments 1-205 and 121-316. These polypeptides were separated employing prepacked Mono Q or Mono S columns (quaternary ammonium and sulfonic acid support, respectively). The columns were equilibrated with acetate-7 M urea buffer, pH 5.0 or 6.0, and eluted with a gradient of sodium chloride or acetate. Separations were achieved in 10-20 min and were carried out also at a semi-preparative level (1-3 mg per run). All five protein fragments were isolated in homogeneous form, as judged by amino acid analysis and electrophoresis. Considering that protein fragmentation with cyanogen bromide is the most commonly used procedure to achieve selective chemical fragmentation of a polypeptide chain, these results indicate that FPLC with ionic exchangers can be usefully employed to isolate rather large protein fragments especially suitable for automatic sequence analysis with the sequenator.     

Involvement of Val 315 located in the C-terminal region of thermolysin in its expression in Escherichia coli and its thermal stability

Thermolysin is a thermophilic and halophilic zinc metalloproteinase that consists of β-rich N-terminal (residues 1–157) and α-rich C-terminal (residues 158–316) domains. Expression of thermolysin variants truncated from the C-terminus was examined in E. coli culture. The C-terminal Lys316 residue was not significant in the expression, but Val315 was critical. Variants in which Val315 was substituted with fourteen amino acids were prepared. The variants substituted with hydrophobic amino acids such as Leu and Ile were almost the same as wild-type thermolysin (WT) in the expression amount, α-helix content, and stability. Variants with charged (Asp, Glu, Lys, and Arg), bulky (Trp), or small (Gly) amino acids were lower in these characteristics than WT. All variants exhibited considerably high activities (50–100% of WT) in hydrolyzing protein and peptide substrates. The expression amount, helix content, and stability of variants showed good correlation with hydropathy indexes of the amino acids substituted for Val315. Crystallographic study of thermolysin has indicated that V315 is a member of the C-terminal hydrophobic cluster. The results obtained in the present study indicate that stabilization of the cluster increases thermolysin stability and that the variants with higher stability are expressed more in the culture. Although thermolysin activity was not severely affected by the variation at position 315, the stability and specificity were modified significantly, suggesting the long-range interaction between the C-terminal region and active site.     

Autolysis of thermolysin. Isolation and characterization of a folded three-fragment complex

Incubation of the neutral metalloendopeptidase thermolysin at pH 7.2 in the presence of EDTA and/or low concentrations of calcium ions produces fast enzyme inactivation as a result of autolysis. The 'nicked' protein is a folded species composed of three tightly associated protein fragments. Dissociation of this complex can be achieved under denaturing conditions, such as gel filtration on a column equilibrated with 5 M guanidine hydrochloride or reverse-phase high-performance liquid chromatography (HPLC) at acidic pH. The positions of the peptide bond cleavages were defined by isolation of the individual fragments by HPLC and their characterization by amino acid analysis after acid hydrolysis, end-group determination and partial amino acid sequencing. The results of these analyses indicated that the nicked protein is composed of fragments 1-196, 197-204 and 205-316 and thus that the corresponding sites of limited proteolysis occur at the polypeptide chain loop involved in the binding of Ca(4) in native thermolysin [Matthews, B. W., Weaver, L. H. and Kester, W. R. (1974) J. Biol. Chem. 249, 8030-8044]. The overall conformational properties of nicked thermolysin are quite similar to those of the intact protein, as judged by spectroscopic measurements and by the fact that rabbit antibodies against native thermolysin recognize and precipitate the nicked protein in immunodiffusion assays. The nicked protein was much less stable to heat and unfolding agents than intact thermolysin. These results contribute to a better knowledge of the molecular mechanism of stabilization of native thermolysin by the four bound calcium ions and demonstrate that the function of Ca(4) is to stabilize the loop 190-205 on the surface of the molecule against autolysis.     

Protease-catalyzed synthesis of melanocyte-stimulating hormone (MSH) fragments

In the present study on enzymatic peptide bond formation the proteosynthetic potential of several proteases was explored. Trypsin, α-chymotrypsin, papain, carboxypeptidase Y (CPD-Y), and thermolysin served as catalysts for the protease-controlled synthesis of some fragments of melanocyte-stimulating hormones. To obviate possible proteolytic cleavage of preexisting peptide bonds—a drawback often encountered during enzymatic peptide syntheses—several expedients leading to the target peptides were developed. The enzymatic procedure enabled under mild conditions the preparation of the desired peptides whose amino acid composition may give rise to severe complications during conventional syntheses.     

Identification of membrane-embedded domains of lipophilin from human myelin

The organization of lipophilin in the intact human myelin membrane has been studied by labeling with the carbene photogenerated from 3-(trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine ([125I]TID). This hydrophobic probe labels mostly lipophilin (the main intrinsic protein of myelin) and the lipids within the bilayer. The domains of lipophilin which are embedded within the membrane have been identified by proteolytic fragmentation of the [125I]TID-labeled myelin, extraction with organic solvents, and separation by chromatography. Four labeled peptides were purified in this way. Polyacrylamide gel electrophoresis, amino acid compositions, automated sequencing, and carboxy-terminal analyses identified a 15K molecular weight peptide, T1 (residues 1-143), as representing the amino-terminal fragment, a 10K peptide, T2 (residues 1-97), representing a smaller amino-terminal fragment, a 5K peptide, T4 (residues 53-97), which represented the COOH-terminal half of peptide T2, and a 7K peptide, T3 (residues 205-268), which represented a sequence near the COOH terminus of lipophilin. The specific radioactivities of the peptides were determined; peptides T1 and T2 had similar specific activities, which were twice the specific activities of peptides T3 and T4. The data provide direct chemical evidence that human lipophilin has membrane-embedded domains between residues 1-97, 53-97, and 205-268, in agreement with some of the predictions of other investigators based on the sequence of bovine myelin lipophilin (proteolipid apoprotein) and a hydrophobicity diagram.     

Folding of thermolysin fragments. Hydrodynamic properties of isolated domains and subdomains

Sedimentation analysis in the analytical ultracentrifuge has been used to characterize the size and shape of thermolysin and a number of its fragments obtained by chemical or enzymatic cleavage of the protein. Four fragments (121-316, 206-316, 225/226-316 and 255-316) originate from the C-terminal domain, and two (1-155 and 1-205) from the N-terminal domain of the intact molecule. In aqueous solution at neutral pH the hydrodynamic properties of the C-terminal fragments, except 255-316, are consistent with compact homogeneous monomers. Fragment 255-316 is a monomeric species below 0.08 mg/ml concentration and forms a dimer above this concentration. Dimerization does not lead to changes in fragment conformation, as determined by far-ultraviolet circular dichroic measurements, but to an increase of 5.6 degrees C (to 68.2 degrees C at 1.0 mg/ml) in the temperature for thermal unfolding and a corresponding increase of 4.6 kJ/mol in the free energy of unfolding. Fragments derived from the N-terminal domain show a strong tendency to form high-molecular-mass aggregates. Previous experiments utilizing circular dichroic measurements and antibody binding data suggested that the C-terminal fragments listed above are able to refold in aqueous solution at neutral pH into a stable conformation of native-like characteristics [Dalzoppo, D., Vita, C. & Fontana, A. (1985) J. Mol. Biol. 182, 331-340] (and references cited therein). Present data establish that all these C-terminal fragments are globular monomeric species in solution (at concentrations approximately 0.1 mg/ml) and thus represent 'isolated' domains (or subdomains) with intrinsic conformational stability typical of small globular proteins.     

Identification of fibronectin fragments that bind to carboxy-group-modified proteins.

Limited proteolysis of human plasma fibronectin with chymotrypsin, trypsin or thermolysin has been used to localize binding sites responsible for binding [Vuento, Korkolainen & Stenman (1982) Biochem. J. 205, 303-311] of fibronectin to carboxy-group-modified proteins. These bindings sites are different from those mediating binding of fibronectin to gelatin or heparin. They are located close to the C-terminus of the polypeptide chains of fibronectin, and apparently overlap with the C-terminal fibrin binding site.     

Catalytic effectiveness of human aldose reductase. Critical role of C-terminal domain.

Human aldose reductase and aldehyde reductase are members of the aldo-keto reductase superfamily that share three domains of homology and a nonhomologous COOH-terminal region. The two enzymes catalyze the NADPH-dependent reduction of a wide variety of carbonyl compounds. To probe the function of the domains and investigate the basis for substrate specificity, we interchanged cDNA fragments encoding the NH2-terminal domains of aldose and aldehyde reductase. A chimeric enzyme (CH1, 317 residues) was constructed in which the first 71 residues of aldose reductase were replaced with first 73 residues of aldehyde reductase. Catalytic effectiveness (kcat/Km) of CH1 for the reduction of various substrates remained virtually identical to wild-type aldose reductase, changing a maximal 4-fold. Deletion of the 13-residue COOH-terminal end of aldose reductase, yielded a mutant enzyme (AR delta 303-315) with markedly decreased catalytic effectiveness for uncharged substrates ranging from 80- to more than 600-fold (average 300-fold). The KmNADPH of CH1 and AR delta 303-315 were nearly identical to that of the wild-type enzyme indicating that cofactor binding is unaffected. The truncated AR delta 303-315 displayed a NADPH/D isotope effect in kcat and an increased D(kcat/Km) value for DL-glyceraldehyde, suggesting that hydride transfer has become partially rate-limiting for the overall reaction. We conclude that the COOH-terminal domain of aldose reductase is crucial to the proper orientation of substrates in the active site.     

Localization of a fibrinogen calcium binding site between gamma-subunit positions 311 and 336 by terbium fluorescence

Calcium is required for effective fibrin polymerization. The high affinity Ca2+ binding capacity of fibrinogen was directly localized to the gamma-chain by autoradiography of nitrocellulose membrane blots of fibrinogen subunits incubated with 45Ca2+. Terbium (Tb3+) competitively inhibited 45Ca2+ binding to fibrinogen during equilibrium dialysis, accelerated fibrin polymerization, and limited fibrinogen fragment D digestion by plasmin. The intrinsic fluorescence of Ca2+-depleted fibrinogen was maximally enhanced by Ca2+ and Tb3+, but not by Mg2+, at about 3 mol of cation/mol of fibrinogen. Protein-bound Tb3+ fluorescence at 545 nm was maximally enhanced by resonance energy transfer from tryptophan (excitation at 290 nm) at about 2 mol of Tb3+mol of fibrinogen and about 1 mol of Tb3+/mol of plasmic fragment D94 (Mr 94,000). Fibrinogen fragments D78 (Mr 78,000) and E did not show effective enhancement of Tb3+ fluorescence, suggesting that the Ca2+ site is located within gamma 303 to gamma 411, the peptide which is absent in fragment D78 but present in D94. When CNBr fragments of the carboxyamidated gamma-subunit were assayed for enhancement of Tb3+ fluorescence, peptide CBi (gamma 311-336) bound 1 mol of Tb3+/mol of CBi. Thus, the Ca2+ site is located within this peptide. The sequence between gamma 315 and gamma 329 is homologous to the calmodulin and parvalbumin Ca2+ binding sites.     

Alternative model for the internal structure of laminin

A monoclonal antibody to laminin, LMN-1, was generated by immunizing rats with laminin from the EHS tumor and fusing the rat spleen cells with mouse NS-1 myeloma cells. Laminin fragments were generated by proteolytic digestion with thrombin, thermolysin, and chymotrypsin. Monoclonal antibody binding fragments were identified by immunoblotting. Fragments which bound monoclonal antibody LMN-1 included a 440-kilodalton (kDa) chymotrypsin fragment and thermolysin fragments of 440 and 110 kDa. These fragments could also be generated from within a 600-kDa thrombin fragment. Digestion of the 440-kDa chymotrypsin fragment with thermolysin generated the 110-kDa antibody binding fragment and a 330-kDa nonbinding fragment. Immunoblotting was performed on extracts of PYS-2 cells and EHS cells using polyclonal and monoclonal antibodies to laminin. Polyclonal antibodies stained the intact 850-kDa complex and the 200- and 400-kDa subunits, while monoclonal LMN-1 stained only the 400-kDa subunit and the complete molecule. Rotary shadowing of monoclonal LMN-1 bound to laminin molecules indicated that the binding site was within the long arm of laminin. Changes in the model of the internal organization of the laminin molecule are proposed, based on the binding of LMN-1 to the 400-kDa subunit and specific proteolytic fragments. The locations of the major thrombin and chymotrypsin fragments in the model are rotated 180 degrees relative to the previously described model [Ott, U., Odermatt, E., Engel, J., Furthmayr, H., & Timpl, R. (1982) Eur. J. Biochem. 123, 63-72] to include part of the 400-kDa subunit of laminin.     

Domain characteristics of the carboxyl-terminal fragment 206-316 of thermolysin: immunochemical studies

The extent of nativeness of the stable conformation of the thermolysin fragment containing the carboxyl-terminal third of the protein (from residues 206 to 316, denoted fragment FII) was examined by its immunogenic and antigenic characteristics. Antisera elicited in rabbits by either intact thermolysin or fragment FII were fractionated serially on two affinity columns, containing either the isolated fragment or intact protein. Both sera gave rise to substantial antibody populations which recognized the fragment FII region in native thermolysin. The relative affinities of these specific antibodies for isolated fragment FII and intact thermolysin were evaluated by radioimmunoassay, by assessing the relative extents of competition by these for binding of either 14C-labeled thermolysin or 14C-labeled fragment FII to each antibody population. Competition by fragment FII was substantial, though generally weaker than that for intact thermolysin, for antibody binding of both labeled antigens. The data demonstrate that the stable structure of fragment FII as observed spectroscopically likely is one which possesses conformational features similar to those of this region in intact thermolysin, but with perhaps less conformational rigidity. The results support the view that the region of thermolysin composed primarily of residues 206-316 is a conformational domain of the intact protein and that isolated fragment FII retains domain-like characteristics of stable and native-like conformation.     

Domain characteristics of the carboxyl-terminal fragment 206-316 of thermolysin

The existence, location, and characteristics of protein domains have been investigated by studying the structural properties of the carboxyl-terminal cyanogen bromide fragment 206–316 of thermolysin. As judged by far-uv CD measurements in aqueous solution under neutral conditions, the fragment attains a substantial degree of α-helical structure comparable to that exhibited by the corresponding region in native thermolysin. By radioimmunoassay techniques, a considerable degree of nativeness of fragment conformation has been deduced from comparison of the relative affinities of thermolysin and fragment 206–316 for antibodies specific for the 206–316 region in the intact protein. The fragment shows noteworthy stability to protein denaturants. The overall spectroscopic and immunochemical data suggest that fragment 206–316 is able to refold into a stable, nativelike structure independently from the rest of the molecule, thus providing support for the view that this fragment may contain a substantial part, if not all, of a protein domain structure.