Acid and Chemical Induced Conformational Changes of Ervatamin B. Presence of Partially Structured Multiple Intermediates

Heat, Acid and Chemically Induced Unfolding Pathways, Conformational Stability and Structure-Function Relationship in Wheat α-Amylase

Wheat α-amylase, a multi-domain protein with immense industrial applications, belongs to α+β class of proteins with native molecular mass of 32 kDa. In the present study, the pathways leading to denaturation and the relevant unfolded states of this multi-domain, robust enzyme from wheat were discerned under the influence of temperature, pH and chemical denaturants. The structural and functional aspects along with thermodynamic parameters for α-amylase unfolding were probed and analyzed using fluorescence, circular dichroism and enzyme assay methods. The enzyme exhibited remarkable stability up to 70°C with tendency to aggregate at higher temperature. Acid induced unfolding was also incomplete with respect to the structural content of the enzyme. Strong ANS binding at pH 2.0 suggested the existence of a partially unfolded intermediate state. The enzyme was structurally and functionally stable in the pH range 4.0–9.0 with 88% recovery of hydrolytic activity. Careful examination of biophysical properties of intermediate states populated in urea and GdHCl induced denaturation suggests that α-amylase unfolding undergoes irreversible and non-coincidental cooperative transitions, as opposed to previous reports of two-state unfolding. Our investigation highlights several structural features of the enzyme in relation to its catalytic activity. Since, α-amylase has been comprehensively exploited for use in a range of starch-based industries, in addition to its physiological significance in plants and animals, knowledge regarding its stability and folding aspects will promote its biotechnological applications.

Structural functional and folding scenario of an anti platelet and thrombolytic enzyme crinumin

A folding pattern, conformational stability and therapeutic role of a protein helps in developing a suitable drug. Crinumin, a thrombolytic and anti platelet agent, has been studied for its functional and conformational properties by equilibrium unfolding methods. The crinumin belongs to α+β class of protein and exhibits a non native structure and two molten globule states at different conditions. Two domains in the molecular structure of the protein with altered stability are present that unfold sequentially. The enzyme maintains activity as well as structural integrity even in adverse conditions. These observations provide an understanding of protein folding as well as facilitate the development of a potential drug.

Thermal, chemical and pH induced denaturation of a multimeric β-galactosidase reveals multiple unfolding pathways

BACKGROUND

In this case study, we analysed the properties of unfolded states and pathways leading to complete denaturation of a multimeric chick pea β-galactosidase (CpGAL), as obtained from treatment with guanidium hydrochloride, urea, elevated temperature and extreme pH.

METHODOLOGY/PRINCIPAL FINDINGS

CpGAL, a heterodimeric protein with native molecular mass of 85 kDa, belongs to α+β class of protein. The conformational stability and thermodynamic parameters of CpGAL unfolding in different states were estimated and interpreted using circular dichroism and fluorescence spectroscopic measurements. The enzyme was found to be structurally and functionally stable in the entire pH range and upto 50 °C temperature. Further increase in temperature induces unfolding followed by aggregation. Chemical induced denaturation was found to be cooperative and transitions were irreversible, non-coincidental and sigmoidal. Free energy of protein unfolding (ΔG(0)) and unfolding constant (K(obs)) were also calculated for chemically denatured CpGAL.

SIGNIFICANCE

The protein seems to use different pathways for unfolding in different environments and is a classical example of how the environment dictates the path a protein might take to fold while its amino acid sequence only defines its final three-dimensional conformation. The knowledge accumulated could be of immense biotechnological significance as well.

Selective and reversible thiol-pegylation, an effective approach for purification and characterization of five fully active ficin (iso)forms from Ficus carica latex

The latex of Ficus carica constitutes an important source of many proteolytic components known under the general term of ficin (EC 3.4.22.3) which belongs to the cysteine proteases of the papain family. So far, no data on the purification and characterization of individual forms of these proteases are available. An effective strategy was used to fractionate and purify to homogeneity five ficin forms, designated A, B, C, D1 and D2 according to their sequence of elution from a cation-exchange chromatographic support. Following rapid fractionation on a SP-Sepharose Fast Flow column, the different ficin forms were chemically modified by a specific and reversible monomethoxypolyethylene glycol (mPEG) reagent. In comparison with their un-derivatized counterparts, the mPEG-protein derivatives behaved differently on the ion-exchanger, allowing us for the first time to obtain five highly purified ficin molecular species titrating 1mol of thiol group per mole of enzyme. The purified ficins were characterized by de novo peptide sequencing and peptide mass fingerprinting analyzes, using mass spectrometry. Circular dichroism measurements indicated that all five ficins were highly structured, both in term of secondary and tertiary structure. Furthermore, analysis of far-UV CD spectra allowed calculation of their secondary structural content. Both these data and the molecular masses determined by MS reinforce the view that the enzymes belong to the family of papain-like proteases. The five ficin forms also displayed different specific amidase activities against small synthetic substrates like dl-BAPNA and Boc-Ala-Ala-Gly-pNA, suggesting some differences in their active site organization. Enzymatic activity of the five ficin forms was completely inhibited by specific cysteine and cysteine/serine proteases inhibitors but was unaffected by specific serine, aspartic and metallo proteases inhibitors.

Immunodominance of CD4 T cells to foreign antigens is peptide intrinsic and independent of molecular context: implications for vaccine design

Immunodominance refers to the restricted peptide specificity of T cells that are detectable after an adaptive immune response. For CD4 T cells, many of the mechanisms used to explain this selectivity suggest that events related to Ag processing play a major role in determining a peptide's ability to recruit CD4 T cells. Implicit in these models is the prediction that the molecular context in which an antigenic peptide is contained will impact significantly on its immunodominance. In this study, we present evidence that the selectivity of CD4 T cell responses to peptides contained within protein Ags is not detectably influenced by the location of the peptide in a given protein or the primary sequence of the protein that bears the test peptide. We have used molecular approaches to change the location of peptides within complex protein Ags and to change the flanking sequences that border the peptide epitope to now include a protease site, and find that immunodominance or crypticity of a peptide observed in its native protein context is preserved. Collectively, these results suggest immunodominance of peptides contained in complex Ags is due to an intrinsic factor of the peptide, based upon the affinity of that peptide for MHC class II molecules. These findings are discussed with regard to implications for vaccine design.

Accumulation of partly folded states in the equilibrium unfolding of ervatamin A: spectroscopic description of the native, intermediate, and unfolded states

Ervatamin A, a cysteine proteases from Ervatamia coronaria, has been used as model system to examine structure-function relationship by equilibrium unfolding methods. Ervatamin A belongs to alpha+beta class of proteins and exhibit stability towards temperature and chemical denaturants. Acid induced unfolding of ervatamin A was incomplete with respect to the structural content of the enzyme. Between pH 0.5 and 2.0, the enzyme is predominantly in beta-sheet conformation and shows a strong ANS binding suggesting the existence of a partially unfolded intermediate state (I(A) state). Surprisingly, high concentrations of GuHCl required to unfold this state and the transition mid points GuHCl induced unfolding curves are significantly higher. GuHCl induced unfolding of ervatamin A at pH 3.0 as well as at pH 4.0 is complex and cannot be satisfactorily fit to a two-state model for unfolding. Besides, a strong ANS binding to the protein is observed at low concentration of GuHCl, indicating the presence of intermediate in the unfolding pathway. On the other hand, even in the presence of urea (8M) the enzyme retains all the activity as well as structural parameters at neutral pH. However, the protein is susceptible to urea unfolding at pH 3.0 and below. Urea induced unfolding of ervatamin A at pH 3.0 is cooperative and the transitions curves obtained by different probes are and non-coincidental. Temperature denaturation of ervatamin A in I(A) state is non-cooperative, contrary to the cooperativity seen with native protein, suggesting the presence of two parts in the molecular structure of ervatamin A may be domains, with different stability that unfolds in steps. Careful inspection of biophysical properties of intermediate states populated in urea and GuHCl (I(UG) state) induced unfolding suggests all these three intermediates are identical and populated in different conditions. However, the properties of the intermediate (I(A) state) identified at pH approximately 1.5 are different from those of the I(UG) state.

Multiple Intermediate Conformations of Jack Bean Urease at Low pH: Anion-induced Refolding

Structural and functional characteristics of jack bean urease (JBU), a hexameric enzyme having identical subunits, were investigated under neutral as well as acidic conditions by using CD, fluorescence, ANS binding and enzyme activity measurements. At low pH and low ionic strength, JBU exists in a partially unfolded state (U(A)-state), having predominantly beta structure and no tertiary interactions along with a strong ANS binding. Addition of salts like NaCl, KCl and Na(2)SO(4) to the U(A)-state induces refolding resulting in structural propensities similar to that of native hexamer. Moreover, at low concentrations, GuHCl behaves like an anion by inducing refolding of the U(A)-state. The anion-induced refolded state (I(A)-state) is more stable than U(A)-state and the stability is nearly equal to that of the native protein against chemical-induced and thermal denaturation. Overall, these observations support a model of protein folding for a multimeric protein where certain conformations (ensembles of substates) of low energy prevail and populated under non-native conditions with different stability.

Structural characterization of the papaya cysteine proteinases at low pH

Current control of gastrointestinal nematodes relies primarily on the use of synthetic drugs and encounters serious problems of resistance. Oral administration of plant cysteine proteinases, known to be capable of damaging nematode cuticles, has recently been recommended to overcome these problems. This prompted us to examine if plant cysteine proteinases like the four papaya proteinases papain, caricain, chymopapain, and glycine endopeptidase that have been investigated here can survive acidic pH conditions and pepsin degradation. The four papaya proteinases have been found to undergo, at low pH, a conformational transition that instantaneously converts their native forms into molten globules that are quite unstable and rapidly degraded by pepsin. As shown by activity measurements, the denatured state of these proteinases which finally results from acid treatment is completely irreversible. It is concluded that cysteine proteinases from plant origin may require to be protected against both acid denaturation and proteolysis to be effective in the gut after oral administration.

Effects of zinc on the activity and conformational changes of arginine kinase and its intermediate

The effects of zinc on arginine kinase and its collapsed-state intermediate were studied. Both arginine kinase and the collapsed-state intermediate were inactivated in the presence of zinc, following a biphasic kinetic course. The corresponding apparent rate constants of inactivation at different zinc concentrations and conformational changes in the presence of 0.5 mM zinc were obtained. The conformational changes of arginine kinase and the collapsed-state intermediate were followed by fluorescence spectra and circular dichroism spectra. Comparison of the results for arginine kinase and the collapsed-state intermediate showed that the collapsed-state intermediate was more susceptible to zinc, which indicated that the collapsed-state intermediate was more flexible and unstable than arginine kinase. The special structure of arginine kinase might explain these diverse phenomena.