Alcohol and Temperature Induced Conformational Transitions in Ervatamin B: Sequential Unfolding of Domains

Kundu, Suman; Sundd, Monica; Jagannadham, Medicherla V.

doi:10.5483/bmbrep.2002.35.2.155

Cited by 8 publications

(6 citation statements)

References 37 publications

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“…Because the temperature-induced denaturing of proteins is affected by these noncovalent interactions (24), the enhanced thermotolerance, including the 7°C increase in melting temperature, in mutant A58E P65S Q191R T271R could be attributed to the introduced hydrogen bonding and salt bridges by the four amino acid substitutions. The two peaks seen in the thermogram of the mutant may represent independent folding of the two protein domains, the ␣ domain and the ␣/␤ domain (11). The increased melting temperature of mutant A58E P65S Q191R T271R will help the enzyme to resist heat inactivation during feed pelleting (18).…”

Section: Discussionmentioning

confidence: 99%

Adopting Selected Hydrogen Bonding and Ionic Interactions fromAspergillus fumigatusPhytase Structure Improves the Thermostability ofAspergillus nigerPhyA Phytase

Zhang

Mullaney

Lei

2007

Appl Environ Microbiol

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Although it has been widely used as a feed supplement to reduce manure phosphorus pollution of swine and poultry, Aspergillus niger PhyA phytase is unable to withstand heat inactivation during feed pelleting. Crystal structure comparisons with its close homolog, the thermostable Aspergillus fumigatus phytase (Afp), suggest associations of thermostability with several key residues (E35, S42, R168, and R248) that form a hydrogen bond network in the E35-to-S42 region and ionic interactions between R168 and D161 and between R248 and D244. In this study, loss-of-function mutations (E35A, R168A, and R248A) were introduced singularly or in combination into seven mutants of Afp. All seven mutants displayed decreases in thermostability, with the highest loss (25% [P < 0.05]) in the triple mutant (E35A R168A R248A). Subsequently, a set of corresponding substitutions were introduced into nine mutants of PhyA to strengthen the hydrogen bonding and ionic interactions. While four mutants showed improved thermostability, the best response came from the quadruple mutant (A58E P65S Q191R T271R), which retained 20% greater (P < 0.05) activity after being heated at 80°C for 10 min and had a 7°C higher melting temperature than that of wild-type PhyA. This study demonstrates the functional importance of the hydrogen bond network and ionic interaction in supporting the high thermostability of Afp and the feasibility of adopting these structural units to improve the thermostability of a homologous PhyA phytase.Phytase catalyzes the hydrolysis of phytate (myo-inositol hexakisphosphate), the major storage form of phosphorus in plant seeds (20), to phosphate and myo-inositol. The enzyme has been effectively used as an animal feed supplement to improve the bioavailability of phytate phosphorus to simplestomached swine and poultry (4, 13). Because temperatures in the practical feed pelleting process can reach as high as 70 to 90°C (18), phytase enzymes with sufficiently high thermal stability are desirable but rare among the naturally occurring sources (14). Therefore, different strategies have been used to enhance the thermal stability of phytase (22).Aspergillus fumigatus phytase (Afp) (19) is a well-known heat-resilient phytase; it retains 90% of its initial activity after being heated at 100°C for 20 min (21). In comparison, Aspergillus niger PhyA phytase (30) displays much less heat resistance, despite a higher specific activity and a better pH profile than those of Afp (17,29,33,34). More intriguingly, these two phytases have 66% sequence homology and very similar overall crystal structures (9,15,35). Both enzymes contain a small ␣ domain and a large ␣/␤ domain. The small ␣ domain is composed of a long ␣ helix and seven short ␣ helices, and the large ␣/␤ domain contains a six-stranded ␤ sheet surrounded by two long ␣ helices at one side and several short ␣ helices at the other side. Nevertheless, detailed structure comparisons between these two enzymes indicate that three amino acid residues in Afp-E35, R168, and R248-may be critical...

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Section: Discussionmentioning

confidence: 99%

Adopting Selected Hydrogen Bonding and Ionic Interactions fromAspergillus fumigatusPhytase Structure Improves the Thermostability ofAspergillus nigerPhyA Phytase

Zhang

Mullaney

Lei

2007

Appl Environ Microbiol

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“…Extensive studies on the folding of papain as well as other related proteins have been carried out in our laboratory ( − ). Two other cysteine proteases, ervatamin C and B, isolated in our laboratory, have also been used as model systems ( − ) in understanding the folding of cysteine proteases. Folding studies on similar proteins from different sources and proteins within a family with individual variations would certainly help in generalizing the folding behavior of cysteine proteases as well as complementing the mechanisms proposed thereafter.…”

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confidence: 99%

Differences in the Unfolding of Procerain Induced by pH, Guanidine Hydrochloride, Urea, and Temperature

Dubey

Jagannadham

2003

Biochemistry

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The structural and functional aspects along with equilibrium unfolding of procerain, a cysteine protease from Calotropis procera, were studied in solution. The energetic parameters and conformational stability of procerain in different states were also estimated and interpreted. Procerain belongs to the alpha + beta class of proteins. At pH 2.0, procerain exists in a partially unfolded state with characteristics of a molten globule-like state, and the protein is predominantly a beta-sheet conformation and exhibits strong ANS binding. GuHCl and temperature denaturation of procerain in the molten globule-like state is noncooperative, contrary to the cooperativity seen with the native protein, suggesting the presence of two parts in the molecular structure of procerain, possibly domains, with different stability that unfolds in steps. Moreover, tryptophan quenching studies suggested the exposure of aromatic residues to solvent in this state. At lower pH, procerain unfolds to the acid-unfolded state, and a further decrease in the pH drives the protein to the A state. The presence of 0.5 M salt in the solvent composition directs the transition to the A state while bypassing the acid-unfolded state. GuHCl-induced unfolding of procerain at pH 3.0 seen by various methods is cooperative, but the transitions are noncoincidental. Besides, a strong ANS binding to the protein is observed at low concentrations of GuHCl, indicating the presence of an intermediate in the unfolding pathway. On the other hand, even in the presence of urea (8 M), procerain retains all the activity as well as structural parameters at neutral pH. However, the protein is susceptible to unfolding by urea at lower pH, and the transitions are cooperative and coincidental. Further, the properties of the molten globule-like state and the intermediate state are different, but both states have the same conformational stability. This indicates that these intermediates may be located on parallel folding routes of procerain.

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“…When formaldehyde is dissolved in buffer to prepare formalin, it reacts instantaneously with water and exists predominately in the form of methylene glycol (Fox et al 1985;Le Botlan et al 1983). Methylene glycol, like other low molecular weight alcohols, can alter protein structure (Brandts et al 1989;Kundu et al 2002;Naseem and Khan 2003) through at least two mechanisms. The first mechanism involves promotion of protein unfolding through weakening of the hydrophobic stabilization within the protein core (Brandts et al 1989;Kundu et al 2002).…”

Section: Discussionmentioning

confidence: 99%

“…Methylene glycol, like other low molecular weight alcohols, can alter protein structure (Brandts et al 1989;Kundu et al 2002;Naseem and Khan 2003) through at least two mechanisms. The first mechanism involves promotion of protein unfolding through weakening of the hydrophobic stabilization within the protein core (Brandts et al 1989;Kundu et al 2002). The second mechanism involves the energetically unfavorable interaction of alcohols with the peptide backbone (Pace et al 2004).…”

Section: Discussionmentioning

confidence: 99%

Antigen Retrieval Causes Protein Unfolding

Fowler

Evers

O’Leary

et al. 2011

J Histochem Cytochem.

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Formalin fixation and paraffin embedding (FFPE) remains the preeminent technique for processing tissue specimens for pathologic examination, for the study of tissue morphology, and for archival preservation (Fox et al. 1985). The steps of FFPE tissue processing are generally as follows. Following fixation in a 3.7% solution of neutral-buffered formalin (fixation), tissue specimens are dehydrated through a series of solutions with increasing concentrations of alcohol (graded alcohols). Samples are then soaked in a transition solvent such as xylene (cleared) followed by liquid paraffin, which is then cooled for long-term storage as solid blocks that can be cut into thin slices for mounting on slides for microscopy.The early work of Fraenkel-Conrat (Fraenkel-Conrat et al. 1947;Fraenkel-Conrat and Ollcott 1948;Fraenkel-Conrat and Mecham 1949) and the more recent work of Metz et al. (2004Metz et al. ( , 2006 have identified four types of chemical modifications following treatment of peptides or proteins with formaldehyde. These modifications are as follows: hydroxymethyl (methylol) adducts, Schiff base adducts, 4-imidazolidinone adducts, and methylene bridges (cross-links). Methylol and Schiff base adducts form rapidly upon reaction with primary amino (lysine) and thiol (cysteine) groups. The SummaryAntigen retrieval (AR), in which formalin-fixed paraffin-embedded tissue sections are briefly heated in buffers at high temperature, often greatly improves immunohistochemical staining. An important unresolved question regarding AR is how formalin treatment affects the conformation of protein epitopes and how heating unmasks these epitopes for subsequent antibody binding. The objective of the current study was to use model proteins to determine the effect of formalin treatment on protein conformation and thermal stability in relation to the mechanism of AR. Sodium dodecyl sulfate polyacrylamide gel electrophoresis was used to identify the presence of protein formaldehyde cross-links, and circular dichroism spectropolarimetry was used to determine the effect of formalin treatment and high-temperature incubation on the secondary and tertiary structure of the model proteins. Results revealed that for some proteins, formalin treatment left the native protein conformation unaltered, whereas for others, formalin denatured tertiary structure, yielding a molten globule protein. In either case, heating to temperatures used in AR methods led to irreversible protein unfolding, which supports a linear epitope model of recovered protein immunoreactivity. Consequently, the core mechanism of AR likely centers on the restoration of normal protein chemical composition coupled with improved accessibility to linear epitopes through protein unfolding. (J Histochem Cytochem 59:366-381, 2011)

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Alcohol and Temperature Induced Conformational Transitions in Ervatamin B: Sequential Unfolding of Domains

Cited by 8 publications

References 37 publications

Adopting Selected Hydrogen Bonding and Ionic Interactions fromAspergillus fumigatusPhytase Structure Improves the Thermostability ofAspergillus nigerPhyA Phytase

Adopting Selected Hydrogen Bonding and Ionic Interactions fromAspergillus fumigatusPhytase Structure Improves the Thermostability ofAspergillus nigerPhyA Phytase

Differences in the Unfolding of Procerain Induced by pH, Guanidine Hydrochloride, Urea, and Temperature

Antigen Retrieval Causes Protein Unfolding

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