The binding site of bisphenol A to protein disulphide isomerase

Protein disulphide isomerase (PDI) has been isolated as a binding protein of bisphenol A (BPA) in the rat brain. In this study, we determined binding sites of BPA to PDI and characterized the binding site. First, we identified the BPA-binding domain with ab, b'a'c, a, b, b' and a'c fragment peptides of PDI by surface plasmon resonance spectroscopy. BPA interacted with ab, b'a 'c, a and b', suggesting that a and b' domains are important in their interaction. Second, ab, b'a'c, a,b,b',a', abb'a', abb', b'a', Δb' and a'c fragment peptides were used for their isomerase activity with RNase as a substrate. BPA could inhibit the activity of peptide fragments including b', suggesting that b' domain contributes to inhibition of catalytic activity of PDI by BPA. Next, we investigated the BPA-binding capacity of PDI by amino acid substitution. PDI lost the BPA-binding activity by the mutation of H258 and mutation of Q245 and N300 also decreased its activity. Furthermore, acidic condition increased the BPA-binding activity of PDI. These results suggest that the charge of these amino acid especially, H258, is important for the BPA to bind to PDI.     

Mutations in domain a' of protein disulfide isomerase affect the folding pathway of bovine pancreatic ribonuclease A

Protein disulfide isomerase (PDI, EC 5.3.4.1), an enzyme and chaperone, catalyses disulfide bond formation and rearrangements in protein folding. It is also a subunit in two proteins, the enzyme collagen prolyl 4-hydroxylase and the microsomal triglyceride transfer protein. It consists of two catalytically active domains, a and a', and two inactive ones, b and b', all four domains having the thioredoxin fold. Domain b' contains the primary peptide binding site, but a' is also critical for several of the major PDI functions. Mass spectrometry was used here to follow the folding pathway of bovine pancreatic ribonuclease A (RNase A) in the presence of three PDI mutants, F449R, Delta455-457, and abb', and the individual domains a and a'. The first two mutants contained alterations in the last alpha helix of domain a', while the third lacked the entire domain a'. All mutants produced genuine, correctly folded RNase A, but the appearance rate of 50% of the product, as compared to wild-type PDI, was reduced 2.5-fold in the case of PDI Delta455-457, 7.5-fold to eightfold in the cases of PDI F449R and PDI abb', and over 15-fold in the cases of the individual domains a and a'. In addition, PDI F449R and PDI abb' affected the distribution of folding intermediates. Domains a and a' catalyzed the early steps in the folding but no disulfide rearrangements, and therefore the rate observed in the presence of these individual domains was similar to that of the spontaneous process.     

Structure-function analysis of the endoplasmic reticulum oxidoreductase TMX3 reveals interdomain stabilization of the N-terminal redox-active domain

Disulfide bond formation in the endoplasmic reticulum is catalyzed by enzymes of the protein disulfide-isomerase family that harbor one or more thioredoxin-like domains. We recently discovered the transmembrane protein TMX3, a thiol-disulfide oxidoreductase of the protein disulfide-isomerase family. Here, we show that the endoplasmic reticulum-luminal region of TMX3 contains three thioredoxin-like domains, an N-terminal redox-active domain (named a) followed by two enzymatically inactive domains (b and b'). Using the recombinantly expressed TMX3 domain constructs a, ab, and abb', we compared structural stability and enzymatic properties. By structural and biophysical methods, we demonstrate that the reduced a domain has features typical of a globular folded domain that is, however, greatly destabilized upon oxidization. Importantly, interdomain stabilization by the b domain renders the a domain more resistant toward chemical denaturation and proteolysis in both the oxidized and reduced form. In combination with molecular modeling studies of TMX3 abb', the experimental results provide a new understanding of the relationship between the multidomain structure of TMX3 and its function as a redox enzyme. Overall, the data indicate that in addition to their role as substrate and co-factor binding domains, redox-inactive thioredoxin-like domains also function in stabilizing neighboring redox-active domains.     

Kinetics of interactions of sendai virus envelope glycoproteins, F and HN, with endoplasmic reticulum-resident molecular chaperones, BiP, calnexin, and calreticulin

Sendai virus envelope glycoproteins, F and HN, mature during their transport through the endoplasmic reticulum (ER) and Golgi complex. To better understand their maturation processes in the ER, we investigated the time course of their interactions with three ER- resident molecular chaperones, BiP, calnexin (CNX), and calreticulin (CRT), in Sendai virus-infected HeLa cells. Pulse-chase and immunoprecipitation analyses using antibodies against each virus glycoprotein or ER chaperone revealed that F precursor interacted with CNX transiently (t(1/2)=8 min), while HN protein displayed longer and sequential interactions with BiP (t(1/2)=8 min), CNX (t(1/2)=15 min), and CRT (t(1/2)=20 min). HN interacted with the three ER chaperones not only as a monomer but also as a tetramer for several hours, suggesting mechanism(s) to undergo chaperone-mediated quality control of an assembled HN oligomer in the ER. The kinetics of dissociation of the HN-chaperone complexes exhibited a marked delay in the presence of proteasome inhibitors, suggesting that a part of HN associated with BiP, CNX, and CRT is destined to be degraded in the proteasome-dependent pathway. Further, the associations between virus glycoproteins and CNX or CRT were impaired by castanospermine, an inhibitor of ER glucosidase I and II, confirming that these interactions require monoglucosylated oligosaccharide on F(0) and HN peptides. These findings together suggest that newly synthesized F protein undergoes rapid maturation in the ER through a transient interaction with CNX, whereas HN protein requires more complex processes involving prolonged association with BiP, CNX, and CRT for its quality control in the ER.     

Cooperation of ER-60 and BiP in the oxidative refolding of denatured proteins in vitro

ER-60 is a PDI family protein that has protein thiol-disulfide oxidoreductase activity. It has been shown to associate with BiP in the endoplasmic reticulum. Here, we analyzed the cooperation of ER-60 and BiP in the oxidative refolding of denatured proteins in vitro. ER-60 facilitated the refolding of 20 or 30% of denatured alpha-lactalbumin or ribonuclease B during incubation for 80 min, and these levels of nearly doubled on the addition of BiP to the reaction mixture. BiP alone could not refold denatured ribonuclease B, but could refold denatured alpha-lactalbumin a little. Enhancement of oxidative refolding of alpha-lactalbumin by ER-60 could be detected only when ER-60 was present from the start of refolding. On surface plasmon resonance analysis, ER-60 was shown to associate with BiP. The association was not influenced by ATP or ADP. Domains a and/or b' of ER-60 were implicated in the association with BiP.     

Delineation of the lectin site of the molecular chaperone calreticulin

Calreticulin (CRT) is a soluble molecular chaperone of the endoplasmic reticulum that functions to promote protein folding as well as to retain misfolded proteins. Similar to its membrane-bound paralog calnexin (CNX), CRT is a lectin that preferentially interacts with glycoproteins bearing Glc1Man5-9GlcNAc2 oligosaccharides. Although the lectin site of CNX has been delineated through X-ray crystallographic and mutagenic studies, the corresponding site for CRT has not been as well characterized. To address this issue, we attempted to construct lectin-deficient CRT mutants, using the structure of CNX as a guide to identify potential oligosaccharide-binding residues. Mutation of 4 such CRT residues (Y109, K111, Y128, D317) completely abrogated oligosaccharide binding. In contrast, mutation of CRT residues M131 and D160, which correspond to important residues in the lectin site of CNX, had no effect on oligosaccharide binding. These findings suggest that the organization of the lectin site in CRT largely resembles that of CNX but is not identical. The deficiency in oligosaccharide binding by the mutants was not due to misfolding because they exhibited wild-type protease digestion patterns, were capable of binding the thiol oxidoreductase ERp57, and functioned just as efficiently as wild-type CRT in suppressing the aggregation of the nonglycosylated substrate citrate synthase. However, they were impaired in their ability to suppress the aggregation of the glycosylated substrate jack bean alpha-mannosidase. This provides the first direct demonstration of the importance of CRT's lectin site in suppressing the aggregation of nonnative glycoproteins.     

Ca2+-dependent redox modulation of SERCA 2b by ERp57

We demonstrated previously that calreticulin (CRT) interacts with the lumenal COOH-terminal sequence of sarco endoplasmic reticulum (ER) calcium ATPase (SERCA) 2b to inhibit Ca2+ oscillations. Work from other laboratories demonstrated that CRT also interacts with the ER oxidoreductase, ER protein 57 (also known as ER-60, GRP58; ERp57) during folding of nascent glycoproteins. In this paper, we demonstrate that ERp57 overexpression reduces the frequency of Ca2+ oscillations enhanced by SERCA 2b. In contrast, overexpression of SERCA 2b mutants defective in cysteines located in intralumenal loop 4 (L4) increase Ca2+ oscillation frequency. In vitro, we demonstrate a Ca2+-dependent and -specific interaction between ERp57 and L4. Interestingly, ERp57 does not affect the activity of SERCA 2a or SERCA 2b mutants lacking the CRT binding site. Overexpression of CRT domains that disrupt the interaction of CRT with ERp57 behave as dominant negatives in the Ca2+ oscillation assay. Our results suggest that ERp57 modulates the redox state of ER facing thiols in SERCA 2b in a Ca2+-dependent manner, providing dynamic control of ER Ca2+ homeostasis.     

Calnexin and calreticulin promote folding, delay oligomerization and suppress degradation of influenza hemagglutinin in microsomes.

Calnexin (CNX) and calreticulin (CRT) are molecular chaperones that bind preferentially to monoglucosylated trimming intermediates of glycoproteins in the endoplasmic reticulum. To determine their role in the maturation of newly synthesized glycoproteins, we analyzed the folding and trimerization of in vitro translated influenza hemagglutinin (HA) in canine pancreas microsomes under conditions in which HA's interactions with CNX and CRT could be manipulated. While CNX bound to all folding intermediates (IT1, IT2 and NT), CRT was found to associate preferentially with the earliest oxidative form (IT1). If HA's binding to CNX and CRT was inhibited using a glucosidase inhibitor, castanospermine (CST), the rate of disulfide formation and oligomerization was doubled but the overall efficiency of maturation of HA decreased due to aggregation and degradation. If, on the other hand, HA was arrested in CNX-CRT complexes, folding and trimerization were inhibited. This suggested that the action of CNX and CRT, like that of other chaperones, depended on an 'on-and-off' cycle. Taken together, these results indicated that CNX and CRT promote correct folding by inhibiting aggregation, preventing premature oxidation and oligomerization, and by suppressing degradation of incompletely folded glycopolypeptides.     

Equilibrium unfolding of Escherichia coli ribonuclease H: characterization of a partially folded state.

We have examined the equilibrium unfolding of Escherichia coli ribonuclease HI (RNase H), a member of a family of enzymes that cleaves RNA from RNA:DNA hybrids. A completely synthetic gene was constructed that expresses a variant of the wild-type sequence with all 3 cysteines replaced with alanine. The resulting recombinant protein is active and folds reversibly. Denaturation studies monitored by circular dichroism and tryptophan fluorescence yield coincident curves that suggest the equilibrium unfolding reaction is a 2-state process. Acid denaturation, however, reveals a cooperative transition at approximately pH 1.8 to a partially folded state. This acid state can be further denatured in a reversible manner by the addition of heat or urea as monitored by either CD or tryptophan fluorescence. Analytical ultracentrifugation studies indicate that the acid state of RNase H is both compact and monomeric. Although compact, the acid state does not resemble the native protein: the acid state displays a near-UV CD spectrum similar to the unfolded state and binds to and enhances the fluorescence of the dye 1-anilinonaphthalene, 8-sulfonate much more than either the native or unfolded states. Therefore, the acid state of E. coli RNase H has the characteristics of a molten globule: it retains a high degree of secondary structure, remains compact, yet does not appear to contain a tightly packed core.     

Recognition of protein substrates by protein-disulfide isomerase. A sequence of the b' domain responds to substrate binding.

Refolding of partially folded mitochondrial malate dehydrogenase (mMDH) is assisted by protein-disulfide isomerase (PDI). The addition of a 20-fold molar excess of PDI over denatured protein (0. 1 microM) accelerates the recovery of catalytic activity. PDI fluorescence measurements show that 1 mol of PDI binds 1 mol of denatured mMDH when their concentrations approach 1 microM. The binding of PDI, derivatized with the fluorescence probe iodoacetamide fluorescein, to partially folded mMDH is characterized by a dissociation constant of 0.2 microM. It is shown that the fluorescence probe is covalently attached to a SH residue located in the b' domain. Based on the fluorescence measurements of native and derivatized PDI, it is suggested that recognition of the unfolded substrate involves conformational changes propagated to several domains of PDI.     

Structural basis of carbohydrate recognition by calreticulin

The calnexin cycle is a process by which glycosylated proteins are subjected to folding cycles in the endoplasmic reticulum lumen via binding to the membrane protein calnexin (CNX) or to its soluble homolog calreticulin (CRT). CNX and CRT specifically recognize monoglucosylated Glc₁Man₉GlcNAc₂ glycans, but the structural determinants underlying this specificity are unknown. Here, we report a 1.95-Å crystal structure of the CRT lectin domain in complex with the tetrasaccharide α-Glc-(1→3)-α-Man-(1→2)-α-Man-(1→2)-Man. The tetrasaccharide binds to a long channel on CRT formed by a concave β-sheet. All four sugar moieties are engaged in the protein binding via an extensive network of hydrogen bonds and hydrophobic contacts. The structure explains the requirement for glucose at the nonreducing end of the carbohydrate; the oxygen O₂ of glucose perfectly fits to a pocket formed by CRT side chains while forming direct hydrogen bonds with the carbonyl of Gly¹²⁴ and the side chain of Lys¹¹¹. The structure also explains a requirement for the Cys¹⁰⁵–Cys¹³⁷ disulfide bond in CRT/CNX for efficient carbohydrate binding. The Cys¹⁰⁵–Cys¹³⁷ disulfide bond is involved in intimate contacts with the third and fourth sugar moieties of the Glc₁Man₃ tetrasaccharide. Finally, the structure rationalizes previous mutagenesis of CRT and lays a structural groundwork for future studies of the role of CNX/CRT in diverse biological pathways.     

Equilibrium unfolding mechanism of chicken muscle triose phosphate isomerase

Triose phosphate isomerase (TIM) was prepared and purified from chicken breast muscle. The equilibrium unfolding of TIM by urea was investigated by following the changes of intrinsic fluorescence and circular dichroism spectroscopy, and the equilibrium thermal unfolding by differential scanning calorimetry (DSC). Results show that the unfolding of TIM in urea is highly cooperative and no folding intermediate was detected in the experimental conditions used. The thermodynamic parameters of TIM during its urea induced unfolding were calculated as DeltaG degrees =3.54 kcal.mol(-1), and m(G) = 0.67 kcal.mol(-1)M(-1), which just reflect the unfolding of dissociated folded monomer to fully unfolded monomer transition, while the dissociation energy of folded dimer to folded monomer is probe silence. DSC results indicate that TIM unfolding follows an irreversible two-state step with a slow aggregation process. The cooperative unfolding ratio, DeltaH(cal)/DeltaH(vH), was measured close to 2, indicating that the two subunits of chicken muscle TIM unfold independently. The van't Hoff enthalpy, DeltaH(vH), was estimated as about 200 kcal.mol(-1). These results support the unfolding mechanism with a folded monomer formation before its tertiary structure and secondary structure unfolding.     

Thermodynamic analysis of unfolding and dissociation in lactose repressor protein.

Lactose repressor protein, regulator of lac enzyme expression in Escherichia coli, maintains its structure and function at extremely low protein concentrations (<10(-)12 M). To examine the unfolding and dissociation of this tetrameric protein, structural transitions in the presence of varying concentrations of urea were monitored by fluorescence and circular dichroism spectroscopy, analytical ultracentrifugation, and functional activities. The spectroscopic data demonstrated a single cooperative transition with no evidence of folded dimeric or monomeric species of this protein. These spectroscopic transitions were reversible provided a long incubation step was employed in the refolding reaction at approximately 3 M urea. The refolded repressor protein possessed the same functional and structural properties as wild-type repressor protein. The absence of concentration dependence expected for tetramer dissociation to unfolded monomer (M4 <--> 4U) in the spectral transitions indicates that the disruption of the monomer-monomer interface and monomer unfolding are a concerted reaction (M4 <--> U4) that may occur prior to the dissociation of the dimer-dimer interface. Thus, we propose that the unfolded monomers remain associated at the C-terminus by the 4-helical coiled-coil structure that forms the dimer-dimer interface and that this intermediate is the end point detected in the spectral transitions. Efforts to confirm the existence of this species by ultracentrifugation were inhibited by the aggregation of this intermediate. Based upon these observations, the wild-type fluorescence and CD data were fit to a model, M4 <--> U4, which resulted in an overall DeltaG degrees for unfolding of 40 kcal/mol. Using a mutant protein, K84L, in which the monomer-monomer interface is stabilized, sedimentation equilibrium results demonstrated that the dimer-dimer interface of lac repressor could persist at higher levels of urea than the monomer-monomer interface. The tetramer-dimer transition monitored using this mutant repressor yields a DeltaG degrees of 20.4 kcal/mol. Using this free energy value for the dissociation process of U4 <--> 4U, an overall free energy change of approximately 60 kcal/mol was calculated for dissociation of all interfaces and unfolding of the tetrameric lac repressor, reflecting the exceptional stability of this protein.     

Combinations of protein-disulfide isomerase domains show that there is little correlation between isomerase activity and wild-type growth

Protein-disulfide isomerase (PDI) has five domains: a, b, b', a' and c, all of which except c have a thioredoxin fold. A single catalytic domain (a or a') is effective in catalyzing oxidation of a reduced protein but not isomerization of disulfides (Darby, N. J., and Creighton, T. E. (1995) Biochemistry 34, 11725-11735). To examine the structural basis for this oxidase and isomerase activity of PDI, shuffled domain mutants were generated using a method that should be generally applicable to multidomain proteins. Domains a and a' along with constructs ab, aa', aba', ab'a' display low disulfide isomerase activity, but all show significant reactivity with mammalian thioredoxin reductase, suggesting that the structure is not seriously compromised. The only domain order that retains significant isomerase activity has the b' domain coupled to the N terminus of the a' domain. This b'a'c has 38% of the isomerase activity of wild-type PDI, equivalent to the activity of full-length PDI with one of the active sites inactivated by mutation (Walker, K. W., Lyles, M. M., and Gilbert, H. F. (1996) Biochemistry 35, 1972-1980). Individual a and a' domains, despite their very low isomerase activities in vitro, support wild-type growth of a pdi1Delta Saccharomyces cerevisiae strain yeast. Thus, most of the PDI structure is dispensable for its essential function in yeast, and high-level isomerase activity appears not required for viability or rapid growth.     

Construction and characterization of a single polypeptide chain containing two enzymatically active dihydrofolate reductase domains.

A single polypeptide chain containing two dihydrofolate reductase (DHFR) sequences from Escherichia coli was constructed to determine if a repeat sequence fusion protein could be expressed in an active form. The possibility that intersequence interactions could play a significant role for this enzyme is suggested by the results of Hall and Frieden (1989, Proc. Natl Acad. Sci. USA, 86, 3060-3064) who observed a substantial decrease in the yield of active enzyme when folded in the presence of a large C-terminal fragment. The fusion protein [DHFR(Cys152Glu)--Ile--DHFR (Met1Gln)] was efficiently expressed in E. coli cells and has an activity which is twice that of the wild-type enzyme in the standard assay. The Michaelis constants of the fusion protein for the substrate, dihydrofolate and the cofactor, NADPH, are essentially unchanged from those of the wild-type protein. The urea-induced in vitro unfolding reaction of the fusion protein at low concentrations was found to be fully reversible and follow a three state model, suggesting that the two domains unfold independently. At higher protein concentrations the unfolding transition broadened and shifted to a higher urea concentration. Size-exclusion chromatography results are consistent with the formation of aggregates at the higher protein concentration, even in the absence of denaturant.     

Effect of doxycycline-regulated calnexin and calreticulin expression on specific thrombopoietin productivity of recombinant Chinese hamster ovary cells

In an attempt to increase the specific thrombopoietin (TPO) productivity (q(TPO)) of recombinant Chinese hamster ovary (rCHO) cells (CHO-TPO), the effect of expression level of calnexin (CNX) and calreticulin (CRT) on q(TPO) was investigated. To control both CNX and CRT expression levels simultaneously, the Tet-Off system was first introduced in CHO-TPO cells, and stable Tet-Off cells (TPO-Tet-Off) were screened by luciferase assay. The doxycycline-regulated CNX and CRT expression system in rCHO cells (TPO-CNX/CRT) was established by cotransfection of CNX and CRT expression vector and pTK-Hyg vector into TPO-Tet-Off cells and subsequent screening by Western blot analysis of CNX and CRT. The expression levels of CNX and CRT in TPO-CNX/CRT cells could be tightly controlled by adding different concentrations of doxycycline to a culture medium. Compared with the basal level (2 microg/mL doxycyline), a 2.9-fold increase in CNX expression and a 2.8-fold increase in CRT expression were obtained in the absence of doxycycline. This, in turn, resulted in a 1.9-fold increase in q(TPO), not inhibiting cell growth or changing in vivo biological activity of TPO. Taken together, these results demonstrate that a simultaneous overexpression of CNX and CRT can increase the q(TPO) of rCHO cells.     

Consequences of cAMP-binding site mutations on the structural stability of the type I regulatory subunit of cAMP-dependent protein kinase

The regulatory (R) subunit of cAMP-dependent protein kinase (cAPK) is a multidomain protein with two tandem cAMP-binding domains, A and B. The importance of cAMP binding on the stability of the R subunit was probed by intrinsic fluorescence and circular dichroism (CD) in the presence and absence of urea. Several mutants were characterized. The site-specific mutants R(R209K) and R(R333K) had defects in cAMP-binding sites A and B, respectively. R(M329W) had an additional tryptophan in domain B. Delta(260-379)R lacked Trp260 and domain B. The most destabilizing mutation was R209K. Both CD and fluorescence experiments carried out in the presence of urea showed a decrease in cooperativity of the unfolding, which also occurred at lower urea concentrations. Unlike native R, R(R209K) was not stabilized by excess cAMP. Additionally, CD revealed significant alterations in the secondary structure of the R209K mutant. Therefore, Arg209 is important not only as a contact site for cAMP binding but also for the intrinsic structural stability of the full-length protein. Introducing the comparable mutation into domain B, R333K, had a smaller effect on the integrity and stability of domain A. Unfolding was still cooperative; the protein was stabilized by excess cAMP, but the unfolding curve was biphasic. The R(M329W) mutant behaved functionally like the native protein. The Delta(260-379)R deletion mutant was not significantly different from wild-type RIalpha in its stability. Consequently, domain B and the interaction between Trp260 and cAMP bound to site A are not critical requirements for the structural stability of the cAPK regulatory subunit.     

Molecular dynamics simulation of Escherichia coli dihydrofolate reductase and its protein fragments: relative stabilities in experiment and simulations

We have carried out molecular dynamics simulations of the native dihydrofolate reductase from Escherichia coli and several of its folded protein fragments at standard temperature. The simulations have shown fragments 1--36, 37--88, and 89--159 to be unstable, with a C(alpha)RMSD (C(alpha) root mean squared deviation) >5 A after 3.0 nsec of simulation. The unfolding of fragment 1--36 was immediate, whereas fragments 37--88 and 89--159 gradually unfolded because of the presence of the beta-sheet core structure. In the absence of residues 1--36, the two distinct domains comprising fragment 39--159 associated with each other, resulting in a stable conformation. This conformation retained most of its native structural elements. We have further simulated fragments derived from computational protein cutting. These were also found to be unstable, with the exception of fragment 104--159. In the absence of alpha(4), the loose loop region of residues 120--127 exhibited a beta-strand-like behavior, associating itself with the beta-sheet core of the protein fragment. The current study suggests that the folding of dihydrofolate reductase involves cooperative folding of distinct domains which otherwise would have been unstable as independent folded units in solution. Finally, the critical role of residues 1--36 in allowing the two distinct domains of fragment 104--159 to fold into the final native conformation is discussed.     

Structural basis of urea-induced unfolding of Fasciola gigantica glutathione S-transferase

Glutathione S-transferases (GSTs) are enzymes that are involved in the detoxification of harmful electrophilic endogenous and exogenous compounds by conjugating with glutathione (GSH). The liver fluke GSTs have multifunctional roles in the host–parasite interaction, such as general detoxification and bile acid sequestration to synthase activity. The GSTs have been highlighted as vaccine candidates towards parasitic flukes. In this study, we have thoroughly examined the urea-induced unfolding of a mu-class Fasciola gigantica GST1 ( FgGST1) using spectroscopic techniques and molecular dynamic simulations. FgGST1 is a highly cooperative molecule, because during urea-induced equilibrium unfolding, a concurrent unfolding of the protein without stabilization of any folded intermediate was observed. The protein was stabilized with conformational free energy of about ~12.36 kcal/mol. The protein loses its activity with increasing urea concentration, as the GSH molecule is not able to bind to the protein. We also studied the fluorescence quenching of Trp residues and the obtained K _SV data that provided additional information on the unfolding of FgGST1. Molecular dynamic trajectories simulated in different urea concentrations and temperatures indicated that urea destabilizes FgGST1 structure by weakening hydrophobic interactions and the hydrogen bond network. We observed a precise correlation between the in vitro and in silico studies.     

Hepatic lipase maturation: a partial proteome of interacting factors

Tandem affinity purification (TAP) has been used to isolate proteins that interact with human hepatic lipase (HL) during its maturation in Chinese hamster ovary cells. Using mass spectrometry and Western blotting, we identified 28 proteins in HL-TAP isolated complexes, 16 of which localized to the endoplasmic reticulum (ER), the site of HL folding and assembly. Of the 12 remaining proteins located outside the ER, five function in protein translation or ER-associated degradation (ERAD). Components of the two major ER chaperone systems were identified, the BiP/Grp94 and the calnexin (CNX)/calreticulin (CRT) systems. All factors involved in CNX/CRT chaperone cycling were identified, including UDP-glucose:glycoprotein glucosyltransferase 1 (UGGT), glucosidase II, and the 57 kDa oxidoreductase (ERp57). We also show that CNX, and not CRT, is the lectin chaperone of choice during HL maturation. Along with the 78 kDa glucose-regulated protein (Grp78; BiP) and the 94 kDa glucose-regulated protein (Grp94), an associated peptidyl-prolyl cis-trans isomerase and protein disulfide isomerase were also detected. Finally, several factors in ERAD were identified, and we provide evidence that terminally misfolded HL is degraded by the ubiquitin-mediated proteasomal pathway. We propose that newly synthesized HL emerging from the translocon first associates with CNX, ERp57, and glucosidase II, followed by repeated posttranslational cycles of CNX binding that is mediated by UGGT. BiP/Grp94 may stabilize misfolded HL during its transition between cycles of CNX binding and may help direct its eventual degradation.