Calcium-induced conformational changes and mutual interactions of troponin components as studied by spin labeling.

The three troponin components, TN-C, TN-I, and TN-T, were spin-labeled with two different derivatives of the nitroxide radical, a maleimide and an imidazole reagent. The ESR spectra of various combinations of labeled and unlabeled components were measured both in the presence and absence of calcium. Conformational changes due to the binding of the components and also due to the binding of calcium were sensitively detected in many combinations as large changes in the spectrum. The conformation of TN-C was modified by both TN-T and TN-I. The effects were larger in the presence of calcium than in its absence. In the presence of calcium, TN-T and TN-I both showed large effects with the maleimide label, while TN-I showed a larger effect than TN-T with the imidazole label. In the absence of calcium, the effect of TN-I was larger than that of TN-T. The senstivitiy of TN-C to calcium was magnified by component binding, since the conformation of TN-C itself was not greatly affected by calcium. The conformation of TN-I was greatly altered only in the presence of both TN-C and calcium. This indicates that the calcium-induced conformational change in TN-C is transmitted to the adjacent TN-I. In reconstituted troponin, the conformation of TN-C was more influenced by TN-I in the presence of calcium and by TN-T in its absence as indicated by the imidazole label. With the maleimide label, TN-I was more influential in the absence of calcium. The effect of calcium on the troponin complex was to make the local environment of the label more rigid. The half-maximal effect was observed at 2 X 10(-6)M calcium with TN-I in various complexes, while it was 10(-5)M with TN-C in the complexes. In any case the calcium effects became discernible at 10(-6)M and saturated at 10(-4)M.     

Kinetic studies of calcium and magnesium binding to troponin C

The kinetic mechanism of calcium binding was investigated for the high-affinity calcium-magnesium sites of troponin C (TN-C), for the C-terminal fragment containing only the high-affinity sites (TR2) and for the TN-C:TN-I (where TN-I represents the inhibitory subunit of troponin) complex. Rate constants were measured by the change in fluorescence of the proteins labeled with 4-(N-iodoacetoxyethyl-N-methyl-7-nitrobenz-2-oxa-1,3-diazole at Cys 98. Rate constants for calcium dissociation were also measured using the fluorescent calcium chelating agent quin 2. Calcium binding to TR2 at 4 degrees C is a two-step process at each binding site. (formula; see text) A first order transition (k1 = 700 s-1) follows the formation of a weakly bound collision complex (K0 = 2.5 X 10(3) M-1). The two sits of the labeled protein are distinguishable because of a 2-4-fold difference in rate constants of calcium dissociation. The kinetic evidence is consistent with additive changes in structure induced by calcium binding to two identical or nearly identical high-affinity sites. The mechanism for TN-C:TN-I is similar to TR2. TN-C gave complex kinetic behavior for calcium binding but calcium dissociation occurred with the same rate constants found for TR2. Calcium binding to the high-affinity sites of TnC can be interpreted by the same mechanism as for TR2 but an additional reaction possibly arriving from calcium binding to the low-affinity sites leads to a high-fluorescence intermediate state which is detected by the fluorophore. The interactions between the two classes of sites are interpreted by a model in which calcium binding at the high-affinity sites reverses the fluorescence change induced by calcium binding at the low-affinity sites. Magnesium binding to the calcium-magnesium sites of TR2 and TN-C occurs by the same two-step binding mechanism with a smaller value for K0 and a 5-fold larger rate constant of dissociation.     

Ca2+-induced conformational changes in cardiac troponin C as measured by N-(1-pyrene)maleimide fluorescence

Bovine cardiac troponin C was modified by N-(1-pyrene)maleimide at Cys-35 and Cys-84; the Ca2+-induced conformational changes were followed by measuring pyrene fluorescence. In isolated troponin C, the saturation of Ca2+, Mg2+-sites leads to a simultaneous increase in the pyrene monomer as well as to a decrease in the pyrene excimer fluorescence, whereas the saturation of Ca2+-specific sites results in a slight decrease in the fluorescence of pyrene monomer. Troponin T does not influence the dependence of pyrene-troponin C fluorescence on Ca2+ concentration. Within the equimolar complex of troponin C and troponin I, the saturation of Ca2+, Mg2+-sites has no effect on pyrene fluorescence, whereas the saturation of Ca2+-specific sites leads to a simultaneous decrease of both pyrene monomer and pyrene excimer fluorescence. It is supposed that troponin I diminishes the conformational changes in troponin C that are induced by the saturation of Ca2+, Mg2+-sites and enhances the conformational changes induced by the saturation of Ca2+-specific sites of troponin C.     

The isolation and characterization of the ATPase inhibitory protein (TN-I) from bovine cardiac muscle.

The inhibitory component of the troponin complex (TN-I) was purified from bovine cardiac muscle, using a combination of ion exchange and molecular exclusion chromatographies in the presence of urea. It has the ability to inhibit the Mg2+-activated APTase (EC 3.6.1.3) of a synthetic cardiac actomyosin preparation and this inhibition is reversed by the addition of cardiac calcium binding component of troponin (TN-C). Conventional sedimentation equilibrium experiments suggest a molecular weight for cardiac TN-I of 22 900 +/- 500. However, sodium dodecyl sulfate (SDS) gels indicate a molecular weight of 27 000 +/- 1000. The mobility of TN-I on SDS gels may be anomalous due to the high proportion of basic amino acid residues in the protein. Cardiac TN-I and TN-C interact to form a tight complex, even in the presence of 6 M urea. The results of this study invite direct comparison with results published for rabbit skeletal TN-I.     

Troponin C of the Antarctic icefish (Champsocephalus gunnari) white muscle

• 1.1. The troponin C (TN-C) from the Antarctic icefish (_{Champsocephalus gunnari}) has been isolated to homogeneity by a procedure involving extraction from acetone powder, DEAE-Sepharose 4B and AcA 54 column chromatography.
• 2.2. The calcium-induced conformational changes of apo TN-C have been studied by absorption difference spectroscopy, circular dichroism and intrinsic fluorescence.
• 3.3. The results indicate that the overall characteristics of icefish TN-C (such as amino acid composition, modifications of helix content and of the microenvironment of aromatic residues as a function of calcium binding) are quite similar to those of rabbit TN-C.
• 4.4. The intrinsic fluorescence properties are close to those reported for pike and carp TN-C.

     

Calcium-binding properties of cardiac and skeletal troponin C as determined by circular dichroism and ultraviolet difference spectroscopy.

Calcium titration of the conformational change in cardiac and skeletal troponin C (TN-C) was followed by circular dichroism (CD) at pH values in the range from 5.2 to 7.4. Computer analysis was used to resolve the contributions from the different classes of Ca2+ -binding sites. At pH 6.94 in skeletal TN-C, apparent affinity constants for calcium of 1.8 x 10(7) and 4.5 x 10(5) M-1 were determined for the two classes of binding sites. The more sophisticated computer analysis of the data has revealed a substantial CD contribution from the low-affinity sites (approximately 30% of the high affinity contribution at pH 6.94) and suggests that skeletal TN-C with Ca2+ bound at the low-affinity sites is in a different conformation from that when just the high-affinity sites are occupied, in agreement with a recent nuclear magnetic resonance (NMR) study on this system (Seaman, K. B., Hartshorne, D. J. & Bothener-By, A. A. (1977) Biochemistry 16,4039-4046). With the cardiac protein at pH 7.07, an apparent affinity constant for calcium of 2.0 x 10(7) M-1 was calculated while no low-affinity site at this pH was detected by CD. On the other hand, at lower pH values, such as 6.05, a CD contribution from the cardiac low-affinity Ca2+ -binding site is detected with an apparent binding constant of 3.7 +/- 0.7 x 10(4) M-1. At the lower pH values, protonation of a class of carboxyl groups in each protein which possesses a high pKa (6.2-6.3) elicits the conformational change at the high-affinity sites with a corresponding decrease in the overall magnitude of the Ca2+ -evoked changes. The expression of a conformational change upon Ca2+ binding at the level of the low-affinity sites is enchanced by protonation of a class of carboxyls with a pKa of 6.3 in cardiac TN-C and 6.7-6.8 with the skeletal homologue. In both cases, this contribution is reduced upon protonation of carboxyls with pKa less than or equal to 5.5. It was also observed that the low-affinity sites of skeletal TN-C have a much larger role to play in the total conformational change than the low-affinity sites of cardiac TN-C, a finding probably related to the inability of site 1 in the cardiac protein to bind calcium. In the cardiac protein, the Ca2+ -induced tyrosine difference-spectrum maximum is reduced from deltaepsilonM,287nm =330M-1.cm-1 to 20M-1.cm-1 by protonation of a class of groups with a pKa of 6.4, presumably the same carboxyl groups as those invoved in the CD conformational contribution from the high-affinity binding sites. No such effect was observed for the skeletal protein where deltaepsilonM,287nm was constant at 110M-1 .cm-1 over the pH range studied. The dramatic alterations in the tyrosine environment of cardiac TN-C with pH are attributed to either or both of the tyrosines located in the two high-affinity Ca2+ -binding sites (sites 3 and 4)...     

Troponin I: Inhibitor or facilitator

TN-I occurs as a homologous group of proteins which form part of the regulatory system of vertebrate and invertebrate striated muscle. These proteins are present in vertebrate muscle as isoforms, Mr 21000-24000, that are specific for the muscle type and under individual genetic control. TN-I occupies a central position in the chain of events starting with the binding of calcium to troponin C and ending with activation of the Ca2+ stimulated MgATPase of the actomyosin filament in muscle. The ability of TN-I to inhibit the MgATPase of actomyosin in a manner that is accentuated by tropomyosin is fundamental to its role but the molecular mechanism involved is not yet completely understood. For the actomyosin ATPase to be regulated the interaction of TN-I with actin, TN-C and TN-T must undergo changes as the calcium concentration in the muscle cell rises, which result in the loss of its inhibitory activity. A variety of techniques have enabled the sites of interaction to be defined in terms of regions of the polypeptide chain that must be intact to preserve the biological properties of TN-I. There is also evidence for conformational changes that occur when the complex with TN-C binds calcium. Nevertheless a detailed high resolution structure of the troponin complex and its relation to actin/tropomyosin is not yet available. TN-I induces changes in those proteins with which it interacts, that are essential for their function. In the special case of cardiac TN-I its effect on the calcium binding properties of TN-C is modulated by phosphorylation. It has yet to be determined whether TN-I acts directly as an inhibitor or indirectly by interacting with associated proteins to facilitate their role in the regulatory system.     

Conformational analysis of trimeric maleimide substituted 1,5,9-triazacyclododecane HIV fusion scaffolds

An analysis of the conformational preferences of three trimeric maleimide substituted 1,5,9-triazacyclododecane derivatives, proposed as cross linking reagents for HIV-1 fusion inhibitors, is presented. Exhaustive sampling was performed using the mixed Low Mode Monte Carlo conformational searching technique on the corresponding OPLS2005/GBSA(water) potential energy surface. Geometric structure, molecular length, and hydrogen bonding patterns of the compounds are analyzed. Global minimum energy structures were verified as minima using B3LYP/6-31G1 geometry optimization. All structures adopt a crown-like 12-membered ring conformation; however, the system with the shortest maleimide arms (1a) can also adopt alternative ring orientations. Overall, derivatives with longer maleimide arms were more flexible and resulted in ensembles with a larger number of low energy structures. Comparison with biological inhibition data indicates that there is very little relationship between molecular size and the ability of the scaffold to orient CD4M9 miniproteins for optimal inhibition; however hydrophobicity may play a role.     

Kinetics of conformational change of troponin-C induced by binding or removal of calcium ion

The kinetics of conformational change of troponin-C (TN-C) induced by binding or removal of calcium ion were studied in the presence or absence of magnesium ion by measuring the fluorescence of tyrosyl residues by stopped-flow spectrofluorometry. The result was analyzed in terms of first-order kinetics. Two phases were observed both in pCa-up and in pCa-down experiments. The dependence of the rate constants on pCa was explained by a simple mechanism as follows; (see article). The dissociation constants of calcium bound to TN-C, K and K', calculated from the experimentally determined rate constants were K = 3.16 X 10(-7) M, K' = 1.58 X 10(-6) M in the absence of magnesium ion, and K = K' = 1 X 10(-6) M in the presence of 2 mM MgCl2.     

The predicted structure of the calcium-binding component of troponin.

The structure prediction of the calcium binding component of troponin (TN-C) incorporates the following assumptions: (1) TN-C contains four regions homologous to the calcium binding "EF hand" of parvalbumin. (2) The four EF hands are arranged in two pairs with overall symmetry, 222. (3) The regions of the calcium binding component of troponin which are not in the four EF hands connect the hands within each pair, one to two and three to four, and connect the pairs, region two to region three. In the resulting model there is a well-defined hydrophobic core made from side chains of all eight helical regions and of the four calcium binding loops. The Ca2+ within pairs are separated by 11 A; while the pairs of Ca2+ are separated from one another by over 30 A. Cys-98 and Tyr-109 are suggested to be sensitive spectroscopic probes. Calcium(1) is suggested to be solvent accessible and most readily replaced by a lanthanide. Because of the overall symmetry of the calcium binding component of troponin, one can anticipate that the inhibitory- and the tropomyosin binding components of troponin are similar to one another.     

Studies on calcium ion-induced conformation changes in the actin-tropomyosin-troponin system by fluorimetry. IV. Conformational changes in the region containing fluorescence-labeled sulfhydryl group(s) of troponin.

Conformational changes associated with the functional states of the molecule of troponin were studied using SH-direct fluorogenic reagents, N-(p-(2-benzimidazolyl)phenyl) maleimide (BIPM) and N-(1-anilinonaphthyl-4) maleimide (ANM). 1. The fluorescence parameters of ANM-troponin, intensity, and polarization, did not change on combining it with tropomyosin alone, but markedly changed when F-actin was further added to the system. 2. The conformation around the dye-labeled sulfhydryl group(s) was shown to be susceptible to Ca2+ in terms of fluorescence intensity of the label, thermal transition of the conformation, and the microenvironment near the label. 3. On addition of Ca2+, the fluorescence characteristics of the two systems, ANM-troponin . tropomyosin and ANM-troponin . tropomyosin . F-actin complexes, were altered in opposite directions. When BIPM was used in place of ANM, similar changes were observed: a simple decrease in the intensity when pCa was decreased from 7.4 to 5.5 in the system without F-actin and a sigmoidal increase in the range from pCa 7 to 6 in the system with F-actin. Heavy meromyosin, when added to the latter complex (the reconstituted thin filaments), made the profile of its Ca2+ concentration dependence of fluorescence similar to that of the former complex. When tropomyosin was labeled in place of troponin, similar results were obtained. The data obtained imply that the Ca2+-induced conformational changes of troponin are markedly modified when detached from actin, and that heavy meromyosin weakens the interaction of the troponin . tropomyosin complex with F-actin.     

Molecular and biological studies on cardiac muscle calcium-binding protein (TN-C).

TN-C was purified from bovine cardiac muscle. In the absence of Ca-2+, cardiac TN-C has an intrinsic sedimentation coefficient of 1.93 S and a molecular weight of 18 000 daltons. Cardiac TN-C reverses the inhibitory effect of skeletal TN-I on the Mg-2+-activated ATPase of a skeletal synthetic actomyosin preparation in the presence of skeletal tropomyoson. Circular dichroism (CD) studies indicate that cardiac TN-C undergoes a major conformational change upon binding Ca-2+. A similar response is elicited by Sr-2+, whereas Mg-2+ has a much less pronounced effect. The presence of Mg-2+ does not alter the net effects of either Ca-2+ or Sr-2+. Cardiac TN-C is rich in acidic amino acid residues. UV absorption, near UV CD, and fluorimetric studies show that the protein lacks tryptophan and has a relatively high phenylalanine to tyrosine ratio. The results of this study invite direct comparisons with results reported for the skeletal muscle analogue of cardiac TN-C.     

The isolation and characterization of the tropomyosin binding component (TN-T) of bovine cardiac troponin.

The tropomyosin binding component (TN-T) of troponin was purified from bovine cardiac muscle using a combination of ion exchange chromatographies in the presence of urea. Sedimentation equilibrium experiments suggest a molecular weight for cardiac TN-T of 36 300 +/- 2 000, consistent with a value of 37 000 +/- 1 000 determining by polyacrylamide gel electrophoresis. Calculations based upon circular dichroism spectra indicate an apparent alpha-helical content of 43 +/- 3% for TN-T. Polyacrylamide gel electrophoresis and the effects of the calcium binding component (TN-C) upon the solubility of TN-T suggest that the two cardiac troponin components can interact with each other. Cosedimentation analysis of solutions containing cardiac tropomyosin and TN-T provide evidence for complex formation involving these two proteins. The data presented on the physical and chemical properties of TN-T, as well as the interaction studies indicate that the cardiac muscle regulatory system operates in a manner similar to that proposed for skeletal muscle.     

Synthesis of a troponin C cDNA and expression of wild-type and mutant proteins in Escherichia coli

An avian fast striated muscle troponin C cDNA was designed and synthesized from six oligonucleotides using the overlap-fill in method and overproduced in Escherichia coli for the purpose of developing recombinant DNA approaches to study structure-function relationships in this calcium-binding regulatory protein. The recombinant protein isolated from E. coli functions as a bona fide troponin C in all properties that were assayed: calcium binding, calcium-dependent conformational change, calcium-dependent interaction with troponin I, and formation of a functional ternary complex with troponin I and troponin T that can confer calcium sensitivity on the actomyosin MgATPase. The initiating methionine was removed by E. coli leaving alanine as the first amino acid, as in the muscle troponin C. The first amino acid was not acetylated, but this difference from the muscle protein has no apparent effect on the function. The presence of Glu at position 99, as in turkey, versus Ala in chicken resulted in no detectable difference in comparing recombinant with chicken troponin C. A mutant in which residues 91-93 (Lys-Gly-Lys) in the D/E helical linker were deleted differs in function from wild-type troponin C in the conformational change that takes place upon calcium binding and its interaction with troponin I. Also, the mutant troponin C is impaired in its ability to form a functional complex with troponin I and troponin T that will confer calcium sensitivity on the actomyosin MgATPase.     

Modulation of the interaction between the two halves of troponin C by the other troponin subunits

The interactions between troponin subunits have been studied by intrinsic fluorescence and electron spin resonance (ESR) spectroscopy. The tryptophan fluorescence of troponin T (TnT) and troponin I (TnI) when complexed with troponin C (TnC) undergoes a Ca2+-dependent transition. The midpoints of such spectral changes occur at pCa approximately equal to 6, suggesting that the conformational change of TnT and TnI is induced by Ca2+ binding to the low-affinity sites of TnC. When TnC is labelled at Cys-98 with a maleimide spin probe (MSL), the spin signal is sensitive to Ca2+ binding to both the high and the low-affinity sites of TnC in the presence of either or both of the other two troponin subunits. Since Cys-98 is located in the vicinity of one of the high-affinity sites, these results are indicative of a long-range interaction between the two halves of the TnC molecule. Our earlier kinetic studies [Wang, C.-L. A., Leavis, P. C. & Gergely, J. (1983) J. Biol. Chem. 258, 9175-9177] have shown such interactions in TnC alone. Since the ESR spectral change associated with metal binding to the low-affinity sites is only observed when MSL-TnC is complexed with TnT and/or TnI, this long-range interaction within TnC appears to be mediated through the other troponin subunits.     

Kinetic studies of calcium binding to regulatory complexes from skeletal muscle

The kinetic mechanism of the binding and release of calcium by troponin and by the complexes troponin: tropomyosin, troponin:tropomyosin:actin, and troponin (TN)-tropomyosin (TM)-actin:myosin subfraction 1 (SF-1) was investigated using troponin labeled on the TN-I subunit with the fluorophore 4-(N-iodoac etoxyethyl-N-methyl)-7-nitrobenz-2-oxa-1,3-diazole. The apparent association constant is five to 10 times smaller for TN:TM:actin compared to TN:TM or TN and saturation of actin sites with SF-1 increased the binding constant approximately to the value for TN:TM. Kinetic measurements on TN or TN:TM fitted a single rate process for association or dissociation which is consistent with a model in which the calcium sites are equivalent and independent and each calcium induces a change in structure of the complex. TN:TM:actin gave biphasic transients for association and dissociation of calcium. The two binding sites are no longer equivalent and independent. The TN:TM:actin:SF-1 complex gave kinetic behavior essentially equivalent to TN:TM. The kinetics of calcium dissociation from the various complexes was also measured by the fluorescent calcium indicator quin 2, which gave the same values for the rate constants as for the labeled protein. The evidence is interpreted in terms of a model in which regulated actin can exist in two states and the binding of each calcium and SF-1 displaces the equilibrium between states. Formation of the complex of TN:TM with actin yielded an enhancement of the fluorescence of the labeled TN-I moiety of approximately 30%. The rate of constant for association of the complex decreased 6-fold in the presence of calcium while the rate constant for dissociation of the protein complex was essentially unchanged. Saturation of actin sites with SF-1 had no effect on the rate constant for association with TN:TM in the presence of calcium.     

Kinetics of the conformational change of skeletal troponin C induced by Ca2+-Mg2+ exchange at the high-affinity Ca2+-binding sites

The rate constant of the conformational change of skeletal troponin C (TnC) induced by the Ca2+ binding reaction with the high-affinity Ca2+-binding sites was determined in the presence of Mg2+ by the fluorescence stopped-flow method in 0.1 M KCl, 50 mM Na-cacodylate-HCl pH 7.0 at 20 degrees C. The [MgCl2] dependence of the rate constants of the observed biphasic conformational change leveled off at the high [MgCl2] region: the rate constants were 60 +/- 9 s-1 and 8 +/- 2 s-1, respectively. These values are larger than the rate constants of the biphasic fluorescence intensity change of TnC induced by Mg2+ removal reaction at the high-affinity Ca2+-binding sites (37 +/- 7 s-1 and 3.0 +/- 0.6 s-1) under the same experimental conditions. These results suggest that the Ca2+-Mg2+ exchange reaction at the high-affinity Ca2+-binding sites is faster than the resultant conformational change accompanying the fluorescence intensity change. Based on these results, we also reexamine the molecular kinetic mechanism of the conformational change of the protein induced by the Mg2+ binding or removal reaction with the high affinity Ca2+-binding sites of skeletal TnC.     

Differential interaction of cardiac, skeletal muscle, and yeast tropomyosins with fluorescent (pyrene235) yeast actin

To monitor binding of tropomyosin to yeast actin, we mutated S235 to C and labeled the actin with pyrene maleimide at both C235 and the normally reactive C374. Saturating cardiac tropomyosin (cTM) caused about a 20% increase in pyrene fluorescence of the doubly labeled F-actin but no change in WT actin C374 probe fluorescence. Skeletal muscle tropomyosin caused only a 7% fluorescence increase, suggesting differential binding modes for the two tropomyosins. The increased cTM-induced fluorescence was proportional to the extent of tropomyosin binding. Yeast tropomyosin (TPM1) produced less increase in fluorescence than did cTM, whereas that caused by yeast TPM2 was greater than either TPM1 or cTM. Cardiac troponin largely reversed the cTM-induced fluorescence increase, and subsequent addition of calcium resulted in a small fluorescence recovery. An A230Y mutation, which causes a Ca(+2)-dependent hypercontractile response of regulated thin filaments, did not change probe235 fluorescence of actin alone or with tropomyosin +/- troponin. However, addition of calcium resulted in twice the fluorescence recovery observed with WT actin. Our results demonstrate isoform-specific binding of different tropomyosins to actin and suggest allosteric regulation of the tropomyosin/actin interaction across the actin interdomain cleft.     

N-(1-pyrene)maleimide: a fluorescent cross-linking reagent.

N-(1-Pyrene)maleimide is nonfluorescent in aqueous solution but forms strongly fluorescent adducts with sulfhydryl groups of organic compounds or proteins. The conjugation reactions of N-(1-pyrene)maleimide are relatively fast and can be monitored by the increase in fluorescence intensity of the pyrene chromophore. In cases where primary amino groups are also present in the system, we have observed a red shift of the emission spectra of the fluorescent adducts subsequent to the initial conjugation, as characterized by the disappearance of three emission peaks at 376, 396, and 416 nm, and the appearance of two new peaks at 386 and 405 nm. Model studies with N-(1-pyrene)maleimide adducts of L-cysteine and cysteamine indicate that the spectral shift is the result of an intramolecular aminolysis of the succinimido ring in the adducts. Evidence from both chemical analysis and nuclear magnetic resonance studies of the addition products supports this reaction scheme. N-(1-Pyrene)maleimide adducts of N-acetyl-L-cysteine and beta-mercaptoethanol, which have no free amino group, do not exhibit a spectral shift. Among several protein conjugates only the N-(1-pyrene)maleimide adduct of bovine serum albumin (PM-BSA) shows the spectral shift resembling that of PM-cysteine. N-(1-Pyrene)maleimide reacts with the sulfhydryl group of the single cysteine residue at position 34 in BSA. The finding that the alpha-amino group of the N-terminus in PM-BSA is blocked after the spectral shift is completed strongly suggests that N-(1-pyrene)maleimide cross-links the N-terminus and the cysteine residue in BSA. The relative proximity of the sulfhydryl and amino groups is very critical in the cross-linking as demonstrated by the observation that the spectral shift observed with PM-BSA can be prevented by addition of denaturing reagents such as 1% sodium dodecyl sulfate immediately after labeling, and by the failure of PM-glutathione to undergo the intramolecular aminolysis. Since the intramolecular rearrangement of PM adducts is associated with characteristic fluorescence changes, N-(1-pyrene)maleimide can serve as a fluorescent cross-linking reagent which provides information about the spatial proximity of sulfhydryl and amino groups in proteins.     

Reversed-phase ion-pair high-performance liquid chromatography of mercaptoacetate and N-acetylcysteine after derivatization with N-(1-pyrene)maleimide and N-(7-dimethylamino-4-methyl-3-coumarinyl)maleimide

We have developed a high-performance liquid chromatographic system capable of resolving mercaptoacetate and N-acetylcysteine as their N-(1-pyrene)maleimide (PM) and N-(7-dimethylamino-4-methyl-3-coumarinyl)maleimide (DACM) derivatives. Good resolution was obtained by ion pairing with tetramethylammonium hydroxide and chromatography on reversed phase. The detection limits for the thiols were about 50 fmol as their DACM derivatives and about 400 fmol as their PM derivatives. The method is illustrated by chromatography of urinary thiols which indicates that the derivatization and chromatography procedures should be well applicable in bioanalytical work.