Carboxyl group modification significantly altered the kinetic properties of purified carboxymethylcellulase from Aspergillus niger

Carboxymethylcellulase (CMCase) from Aspergillus niger NIAB280 was purified by a combination of ammonium sulphate precipitation, ion-exchange, hydrophobic interaction and gel filtration chromatography on FPLC with 9-folds increase in specific activity. Native and subunit molecular weights were found to be 36 kDa each. The purified CMCase was modified by 1-ethyl-3(3-dimethylaminopropyl) carbodiimide (EDC) in the presence of glycinamide for 15 min (GAM15) and glycinamide plus cellobiose for 75 min (GAM75). Similarly, the enzyme was modified by EDC in the presence of ethylenediamine dihydrochloride plus cellobiose for 75 min (EDAM75). The neutralization (GAM15 and GAM75) and reversal (EDAM75) of negative charges of carboxyl groups of CMCase had profound effect on the specificity constant (k(cat)/K(m)), pH optima, pK(a)'s of the active-site residues and thermodynamic parameters of activation. The specificity constants of native, GAM15, GAM75, and EDAM75 were 143, 340, 804, and 48, respectively. The enthalpy of activation (DeltaH(#)) of Carboxymethylcellulose (CMC) hydrolysis of native (50 and 15 kJ mol(-1)) and GAM15 (41 and 16 kJ mol(-1)) were biphasic whereas those of GAM75 (43 kJ mol(-1)) and EDAM75 (41 k J mol(-1)) were monophasic. Similarly, the entropy of activation (DeltaS(#)) of CMC hydrolysis of native (-61 and -173 J mol(-1) K(-1)) and GAM15 (-91 and -171 J mol(-1) K(-1)) were biphasic whereas those of GAM75 (-82 J mol(-1) K(-1)) and EDAM75 (-106 J mol(-1) K(-1)) were monophasic. The pH optima/pK(a)'s of both acidic and basic limbs of charge neutralized CMCases increased compared with those of native enzyme. The CMCase modification in the presence of glycinamide and absence of cellobiose at different pH's periodically activated and inhibited the enzyme activity indicating conformational changes. We believe that the alteration of the surface charges resulted in gross movement of loops that surround the catalytic pocket, thereby inducing changes in the vicinity of active site residues with concomitant alteration in kinetic and thermodynamic properties of the modified CMCases.     

Coupling of surface carboxyls of carboxymethylcellulase with aniline via chemical modification: extreme thermostabilization in aqueous and water-miscible organic mixtures

We wish to report the attainment of the highest ever T(opt) by introducing approximately two aromatic rings through chemical modification of surface carboxyl groups in carboxymethylcellulase from Scopulariopsis sp. with concomitant decrease in V(max), K(m), and optimum pH! This extraordinary enhancement in thermophilicity of aniline-coupled CMCase (T(opt) = 122 degrees C) by a margin of 73 degrees C as compared with the native enzyme (T(opt) = 49 degrees C) is the highest reported for any mesophilic enzyme that has been modified either through chemical modification or site-directed mutagenesis. It is also reported for the first time that aniline coupled CMCase (ACC) is simultaneously thermostable in aqueous as well as water-miscible organic solvents. The T(opt) of native CMCase and ACC were 25 and 90 degrees C, respectively, in 40% (v/v) aqueous dioxan. The modified enzyme was also stabilized against irreversible thermal denaturation. Therefore, at 55 degrees C, ACC had a half-life of 136 min as compared with native CMCase whose half-life was only 5 min. We believe that the reasons for this elevated thermostability and thermophilicity are surface aromatic-aromatic interactions and aromatic interactions with the sugar backbone of the substrate, respectively.     

Chemical modification results in hyperactivation and thermostabilization of Fusarium solani glucoamylase

Chemical modification of carboxyl groups of glucoamylase from a mesophilic fungus, Fusarium solani, was carried out using ethylenediamine as nucleophile in the presence of water-soluble 1-ethyl-3(3-dimethylaminopropyl)carbodiimide. Modification brought about a dramatic enhancement of catalytic activity and thermal stability of glucoamylase. Temperature and pH optima of ethylenediamine-coupled glucoamylase (ECG) increased as compared with those of native enzyme. The specificity constant (k(cat)/K(m)) of native, ECG-2, ECG-11, and ECG-17 was 136, 173, 225, and 170, respectively, at 55 degrees C. The enthalpy of activation (Delta H*) and free energy of activation (Delta G*) for soluble starch hydrolysis were lower for the chemically modified forms. All of the modified forms were stable at higher temperatures and possessed high Delta G* against thermal unfolding. The effects of alpha-chymotrypsin and subtilisin on the modified forms were activating as compared with native. Moreover, denaturation of ECG-2, ECG-11, and ECG-17 in urea at 4 mol x L(-1) also showed an activation trend. A possible explanation for the thermal denaturation of native and increased thermal stability of ECG-2, ECG-11, and ECG-17 at higher temperatures is also discussed.     

Effect of elevated temperature on Trichoderma viride SL-1 in solid state fermentations

Cellulase productions in solid state fermentation (SSF) by Trichoderma viride SL-1 were conducted in a column. Periodically oscillating the temperature in the range of 30-50¡C in symmetrical or asymmetrical modes had no adverse effect on productivity. Effective activation of spore germination was found when the spores were treated twice at 30¡C for 30 min. The results are useful in the performances of SSF processes.     

Native Enzyme Mobility Shift Assay (NEMSA): a new method for monitoring carboxyl group modification of carboxymethylcellulase from Aspergillus niger

A simple, sensitive, accurate and more informative assay for determining the number of modified groups during the course of carboxyl group modification is described. Monomeric carboxymethylcellulase (CMCase) from Aspergillus niger was modified by 1-ethyl-3(3-dimethylaminopropyl)carbodiimide (EDC) in the presence of glycinamide. The different time-course aliquots were subjected to non-denaturing PAGE and the gel stained for CMCase activity. The number of carboxyl groups modified are directly read from the ladder of the enzyme bands developed at given time. This method showed that after 75 min of modification reaction there were five major species of modified CMCases in which 6 to 10 carboxyls were modified.     

Two-state irreversible thermal denaturation of Euphorbia characias latex amine oxidase

Thermal denaturation of Euphorbia latex amine oxidase (ELAO) has been studied by enzymatic activity, circular dichroism and differential scanning calorimetry. Thermal denaturation of ELAO is shown to be an irreversible process. Checking the validity of two-state it really describes satisfactorily the thermal denaturation of ELAO. Based on this model we obtain the activation energy, parameter T(*) (the absolute temperature at which the rate constant of denaturation is equal to 1 min(-1)), and total enthalpy of ELAO denaturation. HPLC experiments show that the thermal denatured enzyme conserves its dimeric state. The N(2)-->kD(2) model for thermal denaturation of ELAO is proposed: where N(2) and D(2) are the native and denatured dimer, respectively.     

Stabilization of restriction endonuclease Bam HI by cross-linking reagents

Bacillus amyloliquefaciens H produces a restriction endonuclease enzyme BamHl which is heat labile even at low temperatures. Studies were conducted to enhance thermal stability of BamHl using cross-linking reagents, namely, glutaraldehyde, dimethyl adipimidate (DMA), dimethyl suberimidate (DMS), and dimethyl 3,3'-dithiobispropionimidate (DTBP). Reaction with glutaraldehyde did not result in a preparation with enhanced thermal stability. However, the DMA-, DMS-, and DTBP-cross-linked preparations of BamHI exhibited significant improvement in thermal stability. Studies on thermal denaturation of the cross-linked enzyme preparations revealed that these do not follow a true first-order kinetics A possible deactivation scheme has been proposed in which the enzyme has been envisaged to go through a fully active but more susceptible transient state which, on prolonged heat exposure, exhibits a first-order decay kinetics. At 35 degrees C, which is close to the optimum reaction temperature of 37 degrees C for BamHl activity, the half-line of DMA-, DMS-, and DTBP-cross-linked preparations were 4.0, 5.25, and 5.5 h, respectively, whereas the native enzyme exhibited a half-line of 1.2 h only. The apparent values of deactivation rate constants for native, DMA-, DMS-, and DTBP-cross-linked BamHl were 1.13, 0.39, 0.29, and 0.26 h(-1), respectively, at the same temperature, and the apparent values of activation energies for denaturation of native, DMA-, DMS-, and DTBP-cross-linked BamHl were 2.63, 5.24, 6.55, and 9.2 kcal/mol, respectively. The DTBP-cross-linked Bam HI was, therefore, the best heat-stable preparation among those tested. The unusually low values of activation energies for denaturation of Bam Hl represent their highly thermolabile nature compared to other commonly encountered enzymes such as trypsin, having activation energies of more than 40 kcal/mol for their denaturation.     

Kinetics and thermodynamics of the native and mutated extracellular endo-glucanases from Cellulomonas biazotea

The mutation had dramatic effect on the kinetic and thermodynamic parameters inferring thermostability of endo-glucanase from Cellulomonas biazotea mutant 51 SM(r). The denaturation activation energies of native and mutated enzymes were 73.3 and 68.8 kJ/mol respectively. They showed compensation effect at 55 degrees C. Both enthalpy and entropy values of irreversible thermal inactivation for mutated enzyme were decreased suggesting that the mutation partly stabilized the enzyme.     

Thermal denaturation and degradation of schizophyllan

Size exclusion chromatography and low-angle laser light scattering have been used for studying the evolution of schizophyllan polysaccharide during a thermal treatment (t > 100°C) in aerated solution. Thermal denaturation of the native triple helices into single chains is initiated above 135°C and is complete in 10 min at 160°C. Both conformations can coexist in the 130–140°C temperature range. In the presence of oxygen, both forms of the biopolymer undergo severe thermal degradation. The rate of degradation was found to be independent of chain length and conformation. An activation energy of 104 kJ mol⁻¹ was determined. The reaction was base-catalyzed. Analysis of chromatographic patterns indicate that the degradation probably occurs through an ‘all-or-none’ process.     

The effects of Na+ and Mg2+ on the thermal denaturation of native and acetylated spinach ferredoxins

The effects of metal ions on the thermal denaturation and Mg2+ binding of native spinach ferredoxin and its acetylated derivative were investigated. The denaturation of ferredoxin in a metal-free solution at 40 degrees C was quickly prevented by the addition of Mg2+ or Na+ at appropriate concentrations. The metal concentrations required for 50% protection from thermal denaturation were 1.54 x 10(-4) M Mg2+ or 8.0 x 10(-3) M Na+ for native ferredoxin and 1.05 x 10(-3) M Mg2+ or 6.0 x 10(-2) M Na+ for acetylated ferredoxin. It was also found that native ferredoxin in the presence of over 20 mM Mg2+ was almost completely protected from thermal denaturation at 40 degrees C. The D-form which has been observed in acetylated ferredoxin by Masaki et al. (1977) (J. Biochem. 81, 1-9) was confirmed to be present in native ferredoxin at high temperature (49 degrees C) and is suggested to be an important form in the denaturation processes of the ferredoxin molecule.     

Thermal behavior of fowl feather keratin

Differential scanning calorimetry (DSC) was applied to elucidate the thermal behavior of fowl feather keratins (barbs, rachis, and calamus) with different morphological features. The DSC curves exhibited a clear and relatively large endothermic peak at about 110-160 degrees C in the wet condition. A considerable decrease in transition temperature with urea and its helical structure content estimated by Fourier transform infrared spectroscopy (FT-IR), and the disappearance of one of the diffraction peaks with heating at 160 degrees C for 30 min, indicated that DSC could be used to evaluate the thermal behavior of keratin. Barbs showed a lower denaturation temperature than rachis and calamus. The pulverized samples showed a slightly higher denaturation temperature than the native samples. In the dry condition, thermal transition occurred in a markedly higher temperature region close to 170-200 degrees C. It is hence concluded that fowl feather keratins have very high thermal stability, and that the elimination of water brings about even greater thermal stability.     

Temperature-induced denaturation and renaturation of triosephosphate isomerase from Saccharomyces cerevisiae: evidence of dimerization coupled to refolding of the thermally unfolded protein

The thermal denaturation of the dimeric enzyme triosephosphate isomerase (TIM) from Saccharomyces cerevisiae was studied by spectroscopic and calorimetric methods. At low protein concentration the structural transition proved to be reversible in thermal scannings conducted at a rate greater than 1.0 degrees C min(-1). Under these conditions, however, the denaturation-renaturation cycle exhibited marked hysteresis. The use of lower scanning rates lead to pronounced irreversibility. Kinetic studies indicated that denaturation of the enzyme likely consists of an initial first-order reaction that forms thermally unfolded (U) TIM, followed by irreversibility-inducing reactions which are probably linked to aggregation of the unfolded protein. As judged from CD measurements, U possesses residual secondary structure but lacks most of the tertiary interactions present in native TIM. Furthermore, the large increment in heat capacity upon denaturation suggests that extensive exposure of surface area occurs when U is formed. Above 63 degrees C, reactions leading to irreversibility were much slower than the unfolding process; as a result, U was sufficiently long-lived as to allow an investigation of its refolding kinetics. We found that U transforms into nativelike TIM through a second-order reaction in which association is coupled to the regain of secondary structure. The rate constants for unfolding and refolding of TIM displayed temperature dependences resembling those reported for monomeric proteins but with considerably larger activation enthalpies. Such large temperature dependences seem to be determinant for the occurrence of kinetically controlled transitions and thus constitute a simple explanation for the hysteresis observed in thermal scannings.     

Structure and thermal stability of the extracellular fragment of human transferrin receptor at extracellular and endosomal pH

Fourier transform infrared spectroscopy has been used to study the solution structure and thermal stability of the extracellular fragment of human transferrin receptor (tfRt) at extracellular and endosomal pH. At extracellular pH tfRt is composed of 56% -helix, 19% β-sheet and 14% turns. Upon acidification to endosomal pH the -helical content of the protein is reduced and the β-sheet content increased by nearly 10%. At extracellular pH, the midpoint temperature of thermal denaturation (T_m) for the loss of secondary and tertiary structure, and the formation of aggregated structures, is 71°C. At endosomal pH this temperature is reduced by ≈ 15°C. The apparent entropies of thermal denaturation indicate that the native structure of tfRt at endosomal pH is far more flexible than at extracellular pH.     

Heat-induced changes in porcine annulus fibrosus biomechanics

The intervertebral disc is implicated as the source of low-back pain in a substantial number of patients. Because thermal therapy has been thought to have a therapeutic effect on collagenous tissues, this technique has recently been incorporated into several minimally invasive back pain treatments. However, patient selection criteria and precise definition of optimum dose are hindered by uncertainty of treatment mechanisms. The purpose of this study was to quantify acute changes in annulus fibrosus biomechanics after a range of thermal exposures, and to correlate these results with tissue denaturation. Intact annulus fibrosus (attached to adjacent vertebrae) from porcine lumbar spines was tested ex vivo. Biomechanical behavior, microstructure, peak of denaturation endotherm, and enthalpy of denaturation (mDSC) were determined before and after hydrothermal heat treatment at 37 degrees C, 50 degrees C, 60 degrees C, 65 degrees C, 70 degrees C, 75 degrees C, 80 degrees C, and 85 degrees C. Shrinkage of excised annular tissue (removed from adjacent vertebrae) was also measured after treatment at 85 degrees C. Significant differences in intact annulus biomechanics were observed after treatment, but the effects were much smaller in magnitude than those observed in excised annulus and those reported previously for other tissues. Consistent with this, intact tissue was only minimally denatured by treatment at 85 degrees C for 15 min, whereas excised tissue was completely denatured by this protocol. Our data suggest that in situ constraint imposed by the joint structure significantly retards annular thermal denaturation. These findings should aid the interpretation of clinical outcomes and provide a basis for the future design of optimum dosing regimens.     

Purification and thermal characterization of a novel peroxidase from a local chick pea cultivar

A novel peroxidase isolated from a local chick pea (Cicer arietinum L.) cultivar (Balksar 2000) was purified by means of ammonium sulfate precipitation, DEAE-cellulose chromatography and two runs on gel filtration. The purified enzyme has a specific activity of 2045 U/mg with 17 % activity recovery. The molecular mass of the enzyme was estimated to be 39 kDa by SDS-polyacrylamide gel electrophoresis. Optimum pH and temperature of the enzyme were 5.5 and 45 degrees C respectively. The thermal denaturation of local chick pea peroxidase was studied in aqueous solution at temperatures ranging from 45 degrees C to 65 degrees C. The temperature of 50% inactivation of the enzyme was found to be 68 degrees C. The enthalpy (DeltaH*) and free energy (DeltaG*) of thermal denaturation of chick pea peroxidase were 101.4 and 103.4 k J/mol respectively at 65 degrees C.Metals like Zn2+, Mn2+, Hg2+, Co2+ and Al3+ slightly inhibited the peroxidase activity while Ca2+, Mg2+ and Ba2+ have no effect on enzyme activity. The high specific activity and thermal stability make chick pea peroxidase an alternative to horseradish peroxidase (HRP) in various applications.     

Stability and reconstitution of D-glyceraldehyde-3-phosphate dehydrogenase from the hyperthermophilic eubacterium Thermotoga maritima.

The molecular basis of thermal stability of globular proteins is a highly significant yet unsolved problem. The most promising approach to its solution is the investigation of the structure-function relationship of homologous enzymes from mesophilic and thermophilic sources. In this context, D-glyceraldehyde-3-phosphate dehydrogenase has been the most extensively studied model system. In the present study, the most thermostable homolog isolated so far is described with special emphasis on the stability of the enzyme under varying solvent conditions. D-Glyceraldehyde-3-phosphate dehydrogenase from the hyperthermophilic eubacterium Thermotoga maritima is an intrinsically thermostable enzyme with a thermal transition temperature around 110 degrees C. The amino acid sequence, electrophoresis, and sedimentation analysis prove the enzyme to be a homotetramer with a gross structure similar to its mesophilic counterparts. The enzyme in the absence and in the presence of its coenzyme, NAD+, exhibits no drastic structural differences except for a 3% change in sedimentation velocity reflecting slight alterations in the quaternary structure of the enzyme. At low temperature, in the absence of denaturants, neither "cold denaturation" nor subunit dissociation are detectable. Guanidinium chloride and pH-dependent deactivation precede the decrease in fluorescence emission and ellipticity, suggesting a complex denaturation mechanism. An up to 3-fold activation of the enzyme at low guanidinium concentration may be interpreted in terms of a compensation of the tight packing of the thermophilic enzyme at low temperature. Under destabilizing conditions, e.g. moderate concentrations of chaotropic agents, low temperature favors denaturation. The effect becomes important in reconstitution experiments after preceding guanidinium denaturation; the reactivation yield at low temperature drops to zero, whereas between 35 and 80 degrees C reactivation exceeds 80%. Shifting the temperature from approximately 0 degrees C to greater than or equal to 30 degrees C releases a trapped tetrameric intermediate in a fast reaction. Concentration-dependent reactivation experiments prove renaturation of the enzyme to involve consecutive folding and association steps. Reconstitution at room temperature yields the native protein, in spite of the fact that the temperature of the processes in vitro and in vivo differ by more than 60 degrees C.     

Stabilization of cellobiase by covalent coupling to soluble polysaccharide.

Cellobiase from Aspergillus niger was glycosylated by covalent coupling to cyanogen bromide activated dextran. The conjugated enzyme retained 62% of the original specific activity exhibited by the native cellobiase. The optimum pH as well as the pH stability of the conjugated form remain almost the same as for the native enzyme. Compared to the native enzyme, the conjugated form exhibited a higher optimal reaction temperature and energy of activation, a higher K(m) (Michaelis constant) and lower Vmax (maximal reaction rate), and improved thermal stability. The thermal deactivation of the native and conjugated cellobiase obeyed the first-order kinetics. The calculated half-life values of heat inactivation at 60, 70 and 80 degrees C was 10.7, 6.25, and 4.05 h, respectively, whereas at these temperatures the native enzyme was less stable (half-life of 3.5, 1.69, and 0.83 h, respectively). The deactivation rate constant at 80 degrees C for the conjugated cellobiase is about 7.9 x 10(-2) h-1, which is lower than that of the native enzyme (36.0 x 10(-2) h-1). The activation energy for denaturation of the native enzyme is about 10.58 kcal/mol, which is 7.25 kcal/mol lower than that of the conjugated enzyme. The effect of different surfactants and some metal ions on the activity of the conjugated cellobiase has been investigated.     

Physicochemical properties of chromatin digested with trypsin.

Chromatin was prepared from calf thymus and digested with trypsin. Some physicochemical properties of chromatin were examined in connection with the time-course of the tryptic digestion. As the tryptic digestion proceeded, chromatin showed increases in viscosity and susceptibility to DNAase II and exhibited considerable alteration in thermal denaturation. A monophasic melting profile was found in the trypsic (digested) chromatin, but a biphasic one in the native (undigested) chromatin. The melting temperature descended from 78.2 degrees C for the native chromatin to 70.2 degrees C for the chromatin after only 10 min and further to 65.3 degrees C after 180 min tryptic digestions. The molar percent of total basic amino acid or lysine plus arginine in the chromatin increased with the time-course of the tryptic digestion whereas that of the total hydrophobic amino acid decreased. The molar ratio of hydrophobic amino acids to basic amino acids thus descended from 1.46 for the native chromatin to 1.05 for the chromatin after a 180-min tryptic digestion. These findings suggest that the neutral or hydrophobic portions in chromatin protein might play a role in the maintenance of the tertiary structure of chromatin.     

A simple preparation of beta-trypsin based on a calorimetric study of the thermal stabilities of alpha- and beta-trypsin

Bovine trypsin preparations contain, in addition to the single chain form of the enzyme, an active two-chain autolysis product (Schroeder, D. D., and Shaw, E., J. Biol. Chem. (1968), 243, 2943–2949). Differential scanning calorimetric (DSC) studies showed that the single chain form, β-trypsin, is more stable to thermal denaturation than the two-chain form, α-trypsin. Rate constants and activation energies for the thermal denaturation of β-trypsin are 5 × 10^?5 sec^?1 and 69 kcal/mole and of α-trypsin are 5 × 10^?3 sec^?1 and 38 kcal/mole at pH 4.4 and 48 °C. Preparation of pure β-trypsin can be greatly simplified by prior thermal denaturation of the α form. At least 75% of the α form is denatured by heating a 10–15% solution of commercial crystalline trypsin for 30–45 min at 48 °C, pH 4.4, 0.02 m Ca²⁺. The native β-trypsin is then easily isolated from the denatured α-trypsin by batchwise adsorption onto ovoinhibitor-agarose at pH 8. After elution at pH 2, dialysis, and lyophilization an average preparation contained approximately 85% β-trypsin, 10% α-trypsin, and 5% inactive material. Benzamidine was used during the isolation to decrease the rate of conversion of β- to α-trypsin. Because the separation of active β-trypsin from heat-denatured α-trypsin is relatively easy, the total preparation time has been reduced to 1 day.     

The role of the native lipids and lattice structure in bacteriorhodopsin protein conformation and stability as studied by temperature-dependent Fourier transform-infrared spectroscopy

We report the effect of partial delipidation and monomerization on the protein conformational changes of bacteriorhodopsin (bR) as a function of temperature. Removal of up to 75% of the lipids is known to have the lattice structure of the purple membrane, albeit as a smaller unit cell, whereas treatment by Triton monomerizes bR into micelles. The effects of these modifications on the protein secondary structure is analyzed by monitoring the protein amide I and amide II bands in the Fourier transform-infrared (FT-IR) spectra. It is found that removal of the first 75% of the lipids has only a slight effect on the secondary structure at physiological temperature, whereas monomerizing bR into micelles alters the secondary structure considerably. Upon heating, the bR monomer is found to have a very low thermal stability compared with the native bR with its melting point reduced from 97 to 65 degrees C, and the pre-melting transition in which the protein changes conformation in native bR at 80 degrees C could not be observed. Also, the N[bond]H to N[bond]D exchange of the amide II band is effectively complete at room temperature, suggesting that there are no hydrophobic regions that are protected from the aqueous medium, possibly explaining the low thermal stability of the monomer. On the other hand, 75% delipidated bR has its melting temperature close to that of the native bR and does have a pre-melting transition, although the pre-melting transition occurs at significantly higher temperature than that of the native bR (91 degrees C compared with 80 degrees C) and is still reversible. Furthermore, we have also observed that the reversibility of this pre-melting transition of both native and partially delipidated bR is time-dependent and becomes irreversible upon holding at 91 degrees C between 10 and 30 min. These results are discussed in terms of the lipid and lattice contribution to the protein thermal stability of native bR.