Capsaicin attenuates spermatogenic cell death induced by scrotal hyperthermia through its antioxidative and anti-apoptotic activities.

This study was performed to examine whether capsaicin, the main pungent ingredient of red peppers, exerts protective effects against testicular injuries induced by transient scrotal hyperthermia. Capsaicin (0.33 mg kg-1 ) was administered subcutaneously to mice one hour before heat stress (HS) in a 43°C water bath for 20 min. After 7 days, mice exposed to HS showed low testicular weight, severe vacuolisation of seminiferous tubules followed by loss of spermatogenic cells, and appearance of multinucleated giant cells and remarkable TUNEL-positive apoptotic cells, as well as weak immunoreactivity of phospholipid hydroperoxide glutathione peroxidase (PHGPx) in spermatogenic cells. Levels of lipid peroxidation and heat shock 70-kDa protein 1 (Hsp72) and BCL2-associated X protein (Bax) mRNA were greatly increased, but PHGPx, manganese superoxide dismutase (MnSOD), and B-cell lymphoma-extra large (Bcl-xL) mRNAs were significantly diminished in the testes by HS. However, capsaicin pre-treatment significantly suppressed the spermatogenic cell death, oxidative stress (levels of MDA, PHGPx immunoreactivity, and Hsp72, PHGPx, and MnSOD mRNA) and apoptosis (levels of TUNEL-positive cells, and Bcl-xL and Bax mRNA) in testes by HS. These suggest that capsaicin has a protective effect against spermatogenic cell death induced by scrotal hyperthermia through its antioxidative and anti-apoptotic activities.

Kinetic studies of the refolding of yeast phosphoglycerate kinase: comparison with the isolated engineered domains.

Unfolding and refolding kinetics of yeast phosphoglycerate kinase were studied by following the time-dependent changes of two signals: the ellipticity at 218 nm and 222 nm, and the fluorescence emission at 330 nm (following excitation at 295 nm). The protein is composed of two similar-sized structural domains. Each domain has been produced by recombinant DNA techniques. It has been previously demonstrated that the engineered isolated domains are able to fold into a quasinative structure (Minard, P., et al., 1989b, Protein Eng. 3, 55-60; Missiakas, D., Betton, J.M., Minard, P., & Yon, J.M., 1990, Biochemistry 29, 8683-8689). The behavior of the isolated domains was studied using the same two conformational probes as for the whole enzyme. We found that the refolding kinetics of each domain are multiphasic. In the whole protein, domain folding and pairing appeared to be simultaneous events. However, it was found that some refolding steps occurring during the refolding of the isolated C-domain are masked during the refolding of yeast phosphoglycerate kinase. The N-domain was also found to refold faster when it was isolated than when integrated.

Separation and chemical differentiation of alpha and beta subunits in yeast phosphofructokinase.

The two types of subunits alpha and beta constitutive of yeast phosphofructokinase have been separated by ion-exchange chromatography under denaturating conditions. Amino acid analysis and peptide mapping were performed on the isolated subunits. The frequence of most of the amino acids significantly differs between the two types of polypeptide chains. Moreover, tryptic peptide maps of alpha and beta subunits are clearly not superimposable. These chemical differences seem sufficient to account for the distinct catalytic and regulatory functions of beta and alpha subunits in the yeast phosphofructokinase reaction.

The effect of phosphate on the unfolding-refolding of phosphoglycerate kinase induced by guanidine hydrochloride.

Phosphate ions were found to stabilize the native structure of phosphoglycerate kinase without modifying the folding pathway. The transition curves obtained from different signals: enzyme activity, ellipticity at 220 nm and fluorescence intensity at 336 nm (excitation at 292 nm) are shifted to smaller guanidine hydrochloride cm values in the absence of phosphate. The kinetic characteristics are qualitatively similar, unfolding rate constants being slightly smaller in the presence of phosphate. The mechanism by which the native structure of phosphoglycerate kinase is stabilized by phosphate probably occurs upon specific phosphate binding to the nucleotide beta- or gamma-phosphate binding site of nucleotides.

Conformational modification of muscle phosphofructokinase from Jaculus orientalis upon ligand binding.

Phosphofructokinase from Jaculus orientalis muscle is an allosteric enzyme regulated by substrates and nucleotide effectors. The conformational modifications upon ligand binding were probed by UV difference spectra and reactivities of thiol groups towards dithiobisnitrobenzoate and N-ethylmaleimide. The binding of Fru-6-P induced significant perturbations in the environment of the aromatic residues and buried the most reactive on the three accessible cysteines per protomer. The same effect on thiol reactivity was observed upon binding of the activator AMP. Various perturbations of both difference spectra and thiol reactivity were detected in the presence of either Mg-ATP, an allosteric inhibitor, or Mg-ITP which is not an effector.

Some aspects of protein folding.

The mechanisms by which a polypeptide chain reaches the three dimensional structure which generates its functional properties are not yet totally understood. The great amount of data now available in the field of protein structure and the data already obtained on protein folding by in vitro experiments allow some schematic representation as, at least, a working hypothesis. In this respect the emphasis is put on the hierarchy in protein structure and the possibility of a folding by stages, some elements or "building blocks" being able to reach independently a native structure and to refine this structure by interacting with each other in the whole molecule.

The use of inhibitors in the study of glycosidases.

The use of non-covalent as well as covalent inhibitors can be a useful tool to approach the mechanism of activity of glycosidases. An efficient method to determine the essential amino-acid groups directly or indirectly involved in the catalytic process is the use of active site directed irreversible inhibitors. Epoxide derivatives from conduritol B and conduritol C are the most important inhibitors in this group. The use of active site reversible inhibitors: cationic and basic glycosyl derivatives, glycals, glyconolactones, thioglycosides, is effective to study the different charges at the active site or the transition state during catalysis and also to detect conformational adaptability of an enzyme. Furthermore, inhibitors can be valuable tools to investigate various aspects of the physiological role of glycosidases.

Conformational dynamics and enzyme activity.

Conformational flexibility and structural fluctuations play an important role in enzyme activity. A great variety of internal motions ranging over different time scales and of different amplitudes are involved in the catalytic cycle. These different types of motions and their functional consequences are considered in the light of experimental data and theoretical analyses. The conformational changes upon substrate binding, and particularly the hinge-bending motion which occurs in enzymes made of two domains, are analyzed from several well documented examples. The conformational events accompanying the different steps of the catalytic cycle are discussed. The last section concerns the motions involved in the allosteric transition which regulates the enzyme activity.

Studies on the structure of yeast phosphofructokinase.

In this paper, we describe an efficient procedure for the purification of yeast phosphofructokinase. This procedure eliminates any time delay and enables to obtain an enzyme with minimum proteolytic alterations. The molecular weights of the oligomeric enzyme and of its constitutive subunits were both evaluated by means of several independent methods. However, the accuracy of each measurement was not sufficient to discriminate between an hexameric and an octameric structure of the enzyme oligomer. On the other hand, crosslinking experiments demonstrated the octameric structure of yeast phosphofructokinase. Obviously, some methods of molecular weight determination have led to erroneous results. In particular, our experiments show that the reliability of molecular weight determinations performed by gel filtration of native proteins must be considered with caution.

Flexibility and folding of phosphoglycerate kinase.

Flexibility and folding of phosphoglycerate kinase, a two-domain monomeric enzyme, have been studied using a wide variety of methods including theoretical approaches. Mutants of yeast phosphoglycerate kinase have been prepared in order to introduce cysteinyl residues as local probes throughout the molecule without perturbating significantly the structural or the functional properties of the enzyme. The apparent reactivity of a unique cysteine in each mutant has been used to study the flexibility of PGK. The regions of larger mobility have been found around residue 183 on segment beta F in the N-domain and residue 376 on helix XII in the C-domain. These regions are also parts of the molecule which unfold first. Ligand binding induces conformational motions in the molecule, especially in the regions located in the cleft. Moreover, the results obtained by introducing a fluorescent probe covalently linked to a cysteine are in agreement with the helix scissor motion of helices 7 and 14 assumed by Blake to direct the hinge bending motion of the domains during the catalytic cycle. The folding process of both horse muscle and yeast phosphoglycerate kinases involves intermediates. These intermediates are more stable in the horse muscle than in the yeast enzyme. In both enzymes, domains behave as structural modules capable of folding and stabilizing independently, but in the horse muscle enzyme the C-domain is more stable and refolds prior to the N-domain, contrary to that which has been observed in the yeast enzyme. A direct demonstration of the independence of domains in yeast phosphoglycerate kinase has been provided following the obtention of separated domains by site-directed mutagenesis. These domains have a native-like structure and refold spontaneously after denaturation by guanidine hydrochloride.

Protein folding: a perspective for biology, medicine and biotechnology.

At the present time, protein folding is an extremely active field of research including aspects of biology, chemistry, biochemistry, computer science and physics. The fundamental principles have practical applications in the exploitation of the advances in genome research, in the understanding of different pathologies and in the design of novel proteins with special functions. Although the detailed mechanisms of folding are not completely known, significant advances have been made in the understanding of this complex process through both experimental and theoretical approaches. In this review, the evolution of concepts from Anfinsen's postulate to the "new view" emphasizing the concept of the energy landscape of folding is presented. The main rules of protein folding have been established from in vitro experiments. It has been long accepted that the in vitro refolding process is a good model for understanding the mechanisms by which a nascent polypeptide chain reaches its native conformation in the cellular environment. Indeed, many denatured proteins, even those whose disulfide bridges have been disrupted, are able to refold spontaneously. Although this assumption was challenged by the discovery of molecular chaperones, from the amount of both structural and functional information now available, it has been clearly established that the main rules of protein folding deduced from in vitro experiments are also valid in the cellular environment. This modern view of protein folding permits a better understanding of the aggregation processes that play a role in several pathologies, including those induced by prions and Alzheimer's disease. Drug design and de novo protein design with the aim of creating proteins with novel functions by application of protein folding rules are making significant progress and offer perspectives for practical applications in the development of pharmaceuticals and medical diagnostics.

Differential expression of gastrointestinal glutathione peroxidase (GI-GPx) gene during mouse organogenesis.

Gastrointestinal glutathione peroxidase (GI-GPx) is an antioxidant enzyme that has been known to be restricted to the gastrointestinal tract in rodents. In an effort to determine the expression pattern of GI-GPx mRNA during organogenesis, quantitative real-time PCR and in situ hybridization for GI-GPx mRNA were conducted in whole embryos or each developing organ of mice. GI-GPx mRNA was expressed more abundantly in the extraembryonic tissues, including placenta than in embryos on embryonic days (EDs) 7.5-18.5 (P < 0.05). When compared with the expression levels of cytosolic GPx (cGPx) mRNA, GI-GPx mRNA levels were low in the embryos, but relatively high in the extraembryonic tissues (P < 0.05). According to the results of whole mount in situ hybridizations, GI-GPx mRNA was principally expressed in the ectoplacental cone, neural tube and fold, and primitive heart at EDs 7.5-8.5. At EDs 9.5-12.5, GI-GPx mRNA was abundantly expressed in nervous tissues such as the telencephalon, mesencephalon and dorsal neural tube and was also detected in the forelimb and hindlimb at EDs 10.5-12.5. In the sectioned embryos after ED 13.5, GI-GPx mRNA levels were high in the cerebral cortex, metanephric corpuscle, pancreatic ducts, surface epithelia of the skin, inner ear, and nasal conchae, gastrointestinal tract, liver, urinary bladder, airway passages of lung, and whisker follicles. These findings indicate that GI-GPx is not only spatiotemporally expressed in a variety of embryonic organs during organogenesis but also may perform a mutual compensatory role with the cGPx in the protection of embryos and extraembryonic tissues against the reactive oxygen species generated in ontogenetic periods.

Protein folding: concepts and perspectives.

In this review, the main concepts of protein folding, as deduced from both theoretical and experimental in vitro studies, are presented. The thermodynamic aspects from Anfinsen's postulate, Levinthal's paradox to the concept of folding funnel as proposed by Wolynes and coworkers are described. Concerning the folding pathway(s), particular attention is brought to bear on the early steps that initiate the process in the light of the results of the fast and even ultrafast techniques presently being used. The role of structural domains as folding units is discussed. Last, from the recent studies, it can be concluded that the main rules deduced from the in vitro folding studies are valid for the folding of a nascent polypeptide chain in vivo.

Protein folding in vitro and in the cellular environment.

The main concepts concerning protein folding have been developed from in vitro refolding studies. They state that the folding of a polypeptide chain is a spontaneous process depending only on the amino-acid sequence in a given environment. It is thermodynamically controlled and driven by the hydrophobic effect. Consequently, it has been accepted that the in vitro refolding process is a valuable model to understand the mechanisms involved during the folding of a nascent polypeptide chain in the cell. Although it does not invalidate the main rules deduced from the in vitro studies, the discovery of molecular chaperones has led to a re-evaluation of this last point. Indeed, in cells molecular chaperones are able to mediate the folding of polypeptide chains and the assembly of subunits in oligomeric proteins. The possible mechanisms by which these folding helpers act are discussed in the light of the data available in the literature. The folding process is assisted in the cell in different ways, preventing premature folding of the polypeptide chain and suppressing the incorrectly folded species and aggregates. Molecular chaperones bind to incompletely folded proteins in a conformation which suggests that the latter are in the "molten globule" state. However, very little is known about the recognition process.

[Conformational coupling between structural units. A decisive step in the functional structure formation]. / Couplage conformationnel entre unités structurales. Etape décisive dans la formation de la structure fonctionnelle des protéines.

Proteins built up of several structural domains are compared with oligomeric proteins made up of several subunits. On this basis the functional consequences of a conformational coupling between domains are analyzed. From the data obtained on the elastase molecule it is proposed that the last step in protein folding insures the optimal coupling between domains and the energy of interaction is utilized for catalysis.

Evidence for intermediates during unfolding and refolding of a two-domain protein, phage T4 lysozyme: equilibrium and kinetic studies.

Equilibrium and kinetic studies of the unfolding-refolding of phage T4 lysozyme induced by guanidine hydrochloride are reported. Tryptophan fluorescence and circular dichroism (CD) were used as observables. Several results indicated the existence of intermediates in the unfolded-folded transition, including (1) the noncoincidence of the transition observed by fluorescence and CD, (2) the asymmetry of the transition recorded by CD, and (3) triphasic kinetics, followed by both observables, accounting for the forward and reverse processes. Our data were inconsistent with an independent unfolding or refolding of each domain. They indicated the existence of residual structured regions particularly resistant to denaturant, which involved one or more of the three tryptophans located in the C-terminal domain. Kinetic analysis has made it possible to propose a minimum pathway corresponding to a sequential refolding, with dead-end species arising from an intermediate. We compared our data with the experimental results of Elwell and Schellman [Elwell, M., & Schellman, J.A. (1975) Biochim. Biophys. Acta 386, 309-313] and the theoretical analysis of B. Maigret (unpublished results) and proposed that the C-terminal domain refolds first, after which the overall structure can be formed and stabilized.