Site-directed mutagenesis of human protein disulphide isomerase: effect on the assembly, activity and endoplasmic reticulum retention of human prolyl 4-hydroxylase in Spodoptera frugiperda insect cells

The exoskeleton collagens in Caenorhabditis elegans are modified by prolyl 4-hydroxylases with unique combinations of subunits

The collagen prolyl 4-hydroxylases (P4Hs, EC ) play a critical role in the synthesis of the extracellular matrix. The enzymes characterized from vertebrates and Drosophila are alpha(2)beta(2) tetramers, in which protein disulfide isomerase (PDI) serves as the beta subunit. Two conserved alpha subunit isoforms, PHY-1 and PHY-2, have been identified in Caenorhabditis elegans. We report here that three unique P4H forms are assembled from these polypeptides and the single beta subunit PDI-2, both in a recombinant expression system and in vivo, namely a PHY-1/PHY-2/(PDI-2)(2) mixed tetramer and PHY-1/PDI-2 and PHY-2/PDI-2 dimers. The mixed tetramer is the main P4H form in wild-type C. elegans but phy-2-/- and phy-1-/- (dpy-18) mutant nematodes can compensate for its absence by increasing the assembly of the PHY-1/PDI-2 and PHY-2/PDI-2 dimers, respectively. All three of the mixed tetramer-forming polypeptides PHY-1, PHY-2, and PDI-2 are coexpressed in the cuticle collagen-synthesizing hypodermal cells. The catalytic properties of the mixed tetramer are similar to those of other P4Hs, and analogues of 2-oxoglutarate were found to produce severe temperature-dependent effects on P4H mutant strains. Formation of the novel mixed tetramer was species-specific, and studies with hybrid recombinant PHY polypeptides showed that residues Gln(121)-Ala(271) and Asp(1)-Leu(122) in PHY-1 and PHY-2, respectively, are critical for its assembly.

Redox reactions of regulatory proteins: do kinetics promote specificity?

Signaling by redox state regulates the transcriptional and post-transcriptional events that control gene expression. To elucidate redox signaling in vivo, the effects of the reductive intracellular redox environment on regulatory redox events must be taken into account. This article focuses on proteins that contain regulatory disulfides, considering whether regulatory proteins can be oxidized and how the redox state of regulatory proteins can be uniquely controlled to allow redox signaling via specific pathways. It is possible that the favored kinetics of the redox reactions of regulatory proteins are important for attaining specificity in redox signaling.

Protein disulfide isomerases exploit synergy between catalytic and specific binding domains

Protein disulfide isomerases (PDIs) catalyse the formation of native disulfide bonds in protein folding pathways. The key steps involve disulfide formation and isomerization in compact folding intermediates. The high-resolution structures of the a and b domains of PDI are now known, and the overall domain architecture of PDI and its homologues can be inferred. The isolated a and a' domains of PDI are good catalysts of simple thiol-disulfide interchange reactions but require additional domains to be effective as catalysts of the rate-limiting disulfide isomerizations in protein folding pathways. The b' domain of PDI has a specific binding site for peptides and its binding properties differ in specificity between members of the PDI family. A model of PDI function can be deduced in which the domains function synergically: the b' domain binds unstructured regions of polypeptide, while the a and a' domains catalyse the chemical isomerization steps.

Endogenous prolyl 4-hydroxylation in Hansenula polymorpha and its use for the production of hydroxylated recombinant gelatin

Several yeast systems have recently been developed for the recombinant production of gelatin and collagen. Amino acid sequence-specific prolyl 4-hydroxylation is essential for the gel-forming capacity of gelatin and for the proper folding of (pro)collagen. This post-translational modification is generally considered to be absent in microbial eukaryotic systems and therefore co-expression of heterologous (human or animal) prolyl 4-hydroxylase would be required. However, we found that the well-known protein expression host Hansenula polymorpha unexpectedly does have the endogenous capacity for prolyl 4-hydroxylation. Without co-expression of a heterologous prolyl 4-hydroxylase, both an endogenous collagen-like protein and a heterologously expressed collagen fragment were found to be sequence-specifically hydroxylated.

Quality control in the endoplasmic reticulum: PDI mediates the ER retention of unassembled procollagen C-propeptides

Quality control within the endoplasmic reticulum (ER) is thought to be mediated by the interaction of a folding protein with one or several resident ER proteins [1]. Protein disulphide isomerase (PDI) is one such ER resident protein that has been previously shown to interact with proteins during their folding and assembly pathways [2, 3]. It has been assumed that, as a consequence of this interaction, unassembled proteins are retained within the ER. Here, we experimentally show that this is indeed the case. We have taken advantage of our previous finding that PDI interacts with procollagen chains early on in their assembly pathway [2] to address the role of this protein in directly retaining unassembled chains within the ER. Our experimental approach involved expressing individual C-propeptide domains from different procollagen chains in mammalian cells and determining the ability of these domains to interact with PDI and to be secreted. The C-propeptide from the proalpha2(I) chain was retained within the cell, where it formed a complex with PDI. Conversely, the C-propeptide from the proalpha1(III) chain did not form a complex with PDI and was secreted. Both domains were secreted, however, from a stable cell line expressing a secreted form of PDI lacking its ER retrieval signal. Hence, we have demonstrated directly that the intracellular retention of one substrate for ER quality control is due to an interaction with PDI.

Characterization of the EYE2 gene required for eyespot assembly in Chlamydomonas reinhardtii

The unicellular biflagellate green alga Chlamydomonas reinhardtii can perceive light and respond by altering its swimming behavior. The eyespot is a specialized structure for sensing light, which is assembled de novo at every cell division from components located in two different cellular compartments. Photoreceptors and associated signal transduction components are localized in a discrete patch of the plasma membrane. This patch is tightly packed against an underlying sandwich of chloroplast membranes and carotenoid-filled lipid granules, which aids the cell in distinguishing light direction. In a prior screen for mutant strains with eyespot defects, the EYE2 locus was defined by the single eye2-1 allele. The mutant strain has no eyespot by light microscopy and has no organized carotenoid granule layers as judged by electron microscopy. Here we demonstrate that the eye2-1 mutant is capable of responding to light, although the strain is far less sensitive than wild type to low light intensities and orients imprecisely. Therefore, pigment granule layer assembly in the chloroplast is not required for photoreceptor localization in the plasma membrane. A plasmid-insertion mutagenesis screen yielded the eye2-2 allele, which allowed the isolation and characterization of the EYE2 gene. The EYE2 protein is a member of the thioredoxin superfamily. Site-directed mutagenesis of the active site cysteines demonstrated that EYE2 function in eyespot assembly is redox independent, similar to the auxiliary functions of other thioredoxin family members in protein folding and complex assembly.

Domains b' and a' of protein disulfide isomerase fulfill the minimum requirement for function as a subunit of prolyl 4-hydroxylase. The N-terminal domains a and b enhances this function and can be substituted in part by those of ERp57

Protein disulfide isomerase (PDI) is a modular polypeptide consisting of four domains, a, b, b', and a', plus an acidic C-terminal extension, c. PDI carries out multiple functions, acting as the beta subunit in the animal prolyl 4-hydroxylases and in the microsomal triglyceride transfer protein and independently acting as a protein folding catalyst. We report here that the minimum sequence requirement for the assembly of an active prolyl 4-hydroxylase alpha(2)beta(2) tetramer in insect cell coexpression experiments is fulfilled by the PDI domain construct b'a' but that the sequential addition of the b and a domains greatly increases the level of enzyme activity obtained. In the assembly of active prolyl 4-hydroxylase tetramers, the a and b domains of PDI, but not b' and a', can in part be substituted by the corresponding domains of ERp57, a PDI isoform that functions naturally in association with the lectins calnexin and calreticulin. The a' domain of PDI could not be substituted by the PDI a domain, suggesting that both b' and a' domains contain regions critical for prolyl 4-hydroxylase assembly. All PDI domain constructs and PDI/ERp57 hybrids that contain the b' domain can bind the 14-amino acid peptide Delta-somatostatin, as measured by cross-linking; however, binding of the misfolded protein "scrambled" RNase required the addition of domains ab or a' of PDI. The human prolyl 4-hydroxylase alpha subunit has at least two isoforms, alpha(I) and alpha(II), which form with the PDI polypeptide the (alpha(I))(2)beta(2) and (alpha(II))(2)beta(2) tetramers. We report here that all the PDI domain constructs and PDI/ERp57 hybrid polypeptides tested were more effectively associated with the alpha(II) subunit than the alpha(I) subunit.

Subcellular localization of procollagen I and prolyl 4-hydroxylase in corneal endothelial cells

To investigate the molecular mechanism of intracellular degradation of type I collagen in normal corneal endothelial cells (CEC), we studied the role of prolyl 4-hydroxylase (P4-H) and protein disulfide-isomerase (PDI; the beta subunit of P4-H) during procollagen I biosynthesis. When the subcellular localization of P4-H and PDI was determined, P4-H demonstrated a characteristic diffuse endoplasmic reticulum (ER) pattern, whereas PDI showed a slightly more restricted distribution within the ER. When colocalization of procollagen I with the enzymes was examined, procollagen I and PDI showed a large degree of colocalization. P4-H and procollagen I were predominantly colocalized at the perinuclear site. When colocalization of type IV collagen with PDI and P4-H was examined, type IV collagen was largely colocalized with PDI, which showed a wider distribution than type IV collagen. Type IV collagen is similarly colocalized with P4-H, except in some perinuclear sites. The colocalization profiles of procollagen I with both PDI and P4-H were not altered in cells treated with alpha,alpha'-dipyridyl compared to those of the untreated cells. The underhydroxylated type IV collagen demonstrated a colocalization profile with PDI similar to that observed with procollagen I, while the underhydroxylated type IV collagen was predominantly colocalized with P4-H at the perinuclear sites. Immunoblot analysis showed no real differences in the amounts of the beta subunit/PDI and the catalytic alpha subunit of P4-H in CEC compared to those of corneal stromal fibroblasts (CSF). When protein-protein association was determined, procollagen I was associated with PDI much more in CEC than it was in CSF, whereas type IV collagen showed no differential association specificity to PDI in both cells. Limited proteolysis of the newly synthesized intracellular procollagen I with pepsin showed that procollagen I in CEC was degraded by pepsin, whereas CSF contained type I collagen composed of alpha1(I) and alpha2(I). These findings suggest that procollagen I synthesized in CEC is not in triple helical conformation and that the improperly folded procollagen I may be preferentially associated with PDI before targeting to the intracellular degradation.

Overexpression of auxin-binding protein enhances the sensitivity of guard cells to auxin

To explore the role of auxin-binding protein (ABP1) in planta, a number of transgenic tobacco (Nicotiana tabacum) lines were generated. The wild-type KDEL endoplasmic reticulum targeting signal was mutated to HDEL, another common retention sequence in plants, and to KEQL or KDELGL to compromise its activity. The auxin-binding kinetics of these forms of ABP1 were found to be similar to those of ABP1 purified from maize (Zea mays). To test for a physiological response mediated by auxin, intact guard cells of the transgenic plants were impaled with double-barreled microelectrodes, and auxin-dependent changes in K(+) currents were recorded under voltage clamp. Exogenous auxin affected inwardly and outwardly rectifying K(+) currents in a dose-dependent manner. Auxin sensitivity was markedly enhanced in all plants overexpressing ABP1, irrespective of the form present. Immunogold electron microscopy was used to investigate the localization of ABP1 in the transgenic plants. All forms were detected in the endoplasmic reticulum and the KEQL and KDELGL forms passed further across the Golgi stacks than KDEL and HDEL forms. However, neither electron microscopy nor silver-enhanced immunogold epipolarization microscopy revealed differences in cell surface ABP1 abundance for any of the plants, including control plants, which indicated that overexpression of ABP1 alone was sufficient to confer increased sensitivity to added auxin. Jones et al. ([1998] Science 282: 1114-1117) found increased cell expansion in transgenic plants overexpressing wild-type ABP1. Single cell recordings extend this observation, with the demonstration that the auxin sensitivity of guard cell K(+) currents is mediated, at least in part, by ABP1.

Identification of a novel saturable endoplasmic reticulum localization mechanism mediated by the C-terminus of a Dictyostelium protein disulfide isomerase

Localization of soluble endoplasmic reticulum (ER) resident proteins is likely achieved by the complementary action of retrieval and retention mechanisms. Whereas the machinery involving the H/KDEL and related retrieval signals in targeting escapees back to the ER is well characterized, other mechanisms including retention are still poorly understood. We have identified a protein disulfide isomerase (Dd-PDI) lacking the HDEL retrieval signal normally found at the C terminus of ER residents in Dictyostelium discoideum. Here we demonstrate that its 57 residue C-terminal domain is necessary for intracellular retention of Dd-PDI and sufficient to localize a green fluorescent protein (GFP) chimera to the ER, especially to the nuclear envelope. Dd-PDI and GFP-PDI57 are recovered in similar cation-dependent complexes. The overexpression of GFP-PDI57 leads to disruption of endogenous PDI complexes and induces the secretion of PDI, whereas overexpression of a GFP-HDEL chimera induces the secretion of endogenous calreticulin, revealing the presence of two independent and saturable mechanisms. Finally, low-level expression of Dd-PDI but not of PDI truncated of its 57 C-terminal residues complements the otherwise lethal yeast TRG1/PDI1 null mutation, demonstrating functional disulfide isomerase activity and ER localization. Altogether, these results indicate that the PDI57 peptide contains ER localization determinants recognized by a conserved machinery present in D. discoideum and Saccharomyces cerevisiae.

A single C-terminal peptide segment mediates both membrane association and localization of lysyl hydroxylase in the endoplasmic reticulum

Hydroxylation of lysyl residues is crucial for the unique glycosylation pattern found in collagens and for the mechanical strength of fully assembled extracellular collagen fibers. Hydroxylation is catalyzed in the lumen of the endoplasmic reticulum (ER) by a specific enzyme, lysyl hydroxylase (LH). The absence of the known ER-specific retrieval motifs in its primary structure and its association with the ER membranes in vivo have suggested that the enzyme is localized in the ER via a novel retention/retrieval mechanism. We have identified here a 40-amino acid C-terminal peptide segment of LH that is able to convert cathepsin D, normally a soluble lysosomal protease, into a membrane-associated protein. The same segment also markedly slows down the transport of the reporter protein from the ER into post-ER compartments, as assessed by our pulse-chase experiments. The retardation efficiency mediated by this C-terminal peptide segment is comparable with that of the intact LH but lower than that of the KDEL receptor-based retrieval mechanism. Within this 40-amino acid segment, the first 25 amino acids appear to be the most crucial ones in terms of membrane association and ER localization, because the last 15 C-terminal amino acids did not possess substantial retardation activity alone. Our findings thus define a short peptide segment very close to the extreme C terminus of LH as the only necessary determinant both for its membrane association and localization in the ER.

Prolyl 4-hydroxylase is an essential procollagen-modifying enzyme required for exoskeleton formation and the maintenance of body shape in the nematode Caenorhabditis elegans

The multienzyme complex prolyl 4-hydroxylase catalyzes the hydroxylation of proline residues and acts as a chaperone during collagen synthesis in multicellular organisms. The beta subunit of this complex is identical to protein disulfide isomerase (PDI). The free-living nematode Caenorhabditis elegans is encased in a collagenous exoskeleton and represents an excellent model for the study of collagen biosynthesis and extracellular matrix formation. In this study, we examined prolyl 4-hydroxylase alpha-subunit (PHY; EC 1.14.11.2)- and beta-subunit (PDI; EC 5.3.4.1)-encoding genes with respect to their role in collagen modification and formation of the C. elegans exoskeleton. We identified genes encoding two PHYs and a single associated PDI and showed that all three are expressed in collagen-synthesizing ectodermal cells at times of maximal collagen synthesis. Disruption of the pdi gene via RNA interference resulted in embryonic lethality. Similarly, the combined phy genes are required for embryonic development. Interference with phy-1 resulted in a morphologically dumpy phenotype, which we determined to be identical to the uncharacterized dpy-18 locus. Two dpy-18 mutant strains were shown to have null alleles for phy-1 and to have a reduced hydroxyproline content in their exoskeleton collagens. This study demonstrates in vivo that this enzyme complex plays a central role in extracellular matrix formation and is essential for normal metazoan development.

Mutations that destabilize the a' domain of human protein-disulfide isomerase indirectly affect peptide binding

Protein-disulfide isomerase (PDI) is a catalyst of folding of disulfide-bonded proteins and also a multifunctional polypeptide that acts as the beta-subunit in the prolyl 4-hydroxylase alpha(2)beta(2)-tetramer (P4H) and the microsomal triglyceride transfer protein alphabeta-dimer. The principal peptide-binding site of PDI is located in the b' domain, but all domains contribute to the binding of misfolded proteins. Mutations in the C-terminal part of the a' domain have significant effects on the assembly of the P4H tetramer and other functions of PDI. In this study we have addressed the question of whether these mutations in the C-terminal part of the a' domain, which affect P4H assembly, also affect peptide binding to PDI. We observed a strong correlation between P4H assembly competence and peptide binding; mutants of PDI that failed to form a functional P4H tetramer were also inactive in peptide binding. However, there was also a correlation between inactivity in these assays and indicators of conformational disruption, such as protease sensitivity. Peptide binding activity could be restored in inactive, protease-sensitive mutants by selective proteolytic removal of the mutated a' domain. Hence we propose that structural changes in the a' domain indirectly affect peptide binding to the b' domain.

Up-regulation of protein-disulfide isomerase in response to hypoxia/brain ischemia and its protective effect against apoptotic cell death

We isolated and identified a stress protein that is up-regulated in response to hypoxia in primary-cultured glial cells. Protein-disulfide isomerase (PDI) was up-regulated not only by hypoxia in glia in vitro, but also by transient forebrain ischemia in rats in vivo. To determine whether newly synthesized PDI is involved in tolerance to ischemic stress, we carried out two procedures to induce PDI gene expression in human neuroblastoma SK-N-MC cells, as well as intrahippocampal injection following electroporation of an expression vector capable of overexpressing PDI in rats. Overexpression of this gene resulted in attenuation of the loss of cell viability induced by hypoxia in neuroblastoma SK-N-MC cells and a reduction in the number of DNA-fragmented cells in the CA1 area of the hippocampus in brain ischemic rats, respectively. These findings suggest that up-regulated PDI may play a critical role in resistance to ischemic damage, and that the elevation of levels of this protein in the brain may have beneficial effects against brain stroke.

Procollagen folding and assembly: the role of endoplasmic reticulum enzymes and molecular chaperones

Procollagen assembly occurs within the endoplasmic reticulum, where the C-propeptide domains of three polypeptide alpha-chains fold individually, and then interact and trimerise to initiate folding of the triple helical region. This highly complex folding and assembly pathway requires the co-ordinated action of a large number of endoplasmic reticulum-resident enzymes and molecular chaperones. Disease-causing mutations in the procollagens disturb folding and assembly and lead to prolonged interactions with molecular chaperones, retention in the endoplasmic reticulum, and intracellular degradation. This review focuses predominantly on prolyl 1-hydroxylase, an essential collagen modifying enzyme, and HSP47, a collagen-specific binding protein, and their proposed roles as molecular chaperones involved in fibrillar procollagen folding and assembly, quality control, and secretion.

Functional differences of two forms of the inhibitor of caspase-activated DNase, ICAD-L, and ICAD-S

Caspase-activated DNase (CAD) is responsible for the DNA fragmentation that occurs during apoptosis. CAD is complexed with an inhibitor of CAD (ICAD) in non-apoptotic, growing cells. Here, we report that mouse WR19L and human Jurkat T lymphoma cells express two alternative forms of ICAD, ICAD-L and ICAD-S, at similar levels. CAD was predominantly associated with ICAD-L in these cell lines. When CAD was expressed alone in Sf9 cells, it was found in insoluble fractions. However, when CAD was co-expressed with ICAD-L and ICAD-S, it was recovered as a soluble protein complexed predominantly with ICAD-L. In vitro transcription and translation of CAD cDNA did not produce a functional protein. Addition of ICAD-L but not ICAD-S to the assay mixture resulted in the synthesis of functional CAD. These results indicated that ICAD-L but not ICAD-S works as a specific chaperone for CAD, facilitating its correct folding during synthesis. Recombinant CAD, as a complex with ICAD-L, was then produced in Sf9 cells. The complex was treated with caspase 3, and CAD was purified to homogeneity. The purified CAD had DNase activity with a high specific activity.

Intracellular retention of procollagen within the endoplasmic reticulum is mediated by prolyl 4-hydroxylase

The correct folding and assembly of proteins within the endoplasmic reticulum (ER) are prerequisites for subsequent transport from this organelle to the Golgi apparatus. The mechanisms underlying the ability of the cell to recognize and retain unassembled or malfolded proteins generally require binding to molecular chaperones within the ER. One classic example of this process occurs during the biosynthesis of procollagen. Here partially folded intermediates are retained and prevented from secretion, leading to a build up of unfolded chains within the cell. The accumulation of these partially folded intermediates occurs during vitamin C deficiency due to incomplete proline hydroxylation, as vitamin C is an essential co-factor of the enzyme prolyl 4-hydroxylase. In this report we show that this retention is tightly regulated with little or no secretion occurring under conditions preventing proline hydroxylation. We studied the molecular mechanism underlying retention by determining which proteins associate with partially folded procollagen intermediates within the ER. By using a combination of cross-linking and sucrose gradient analysis, we show that the major protein binding to procollagen during its biosynthesis is prolyl 4-hydroxylase, and no binding to other ER resident proteins including Hsp47 was detected. This binding is regulated by the folding status rather than the extent of hydroxylation of the chains demonstrating that this enzyme can recognize and retain unfolded procollagen chains and can release these chains for further transport once they have folded correctly.

Identifying and characterizing a second structural domain of protein disulfide isomerase

Recent protein engineering studies have confirmed the multidomain nature of protein disulfide isomerase previously suggested on the basis of analysis of its amino acid sequence. The boundaries of three domains, denoted a, a' and b, have been determined, and each domain has been expressed as an individual soluble folded protein. In this report, the boundaries of the final structural domain, b', are defined by a combination of restricted proteolysis and protein engineering approaches to complete our understanding of the domain organization of PDI. Using these data an optimized polypeptide construct has been prepared and characterized with a view to further structural and functional studies.

The protein disulphide-isomerase family: unravelling a string of folds

The mammalian protein disulphide-isomerase (PDI) family encompasses several highly divergent proteins that are involved in the processing and maturation of secretory proteins in the endoplasmic reticulum. These proteins are characterized by the presence of one or more domains of roughly 95-110 amino acids related to the cytoplasmic protein thioredoxin. All but the PDI-D subfamily are composed entirely of repeats of such domains, with at least one domain containing and one domain lacking a redox-active -Cys-Xaa-Xaa-Cys- tetrapeptide. In addition to their known roles as redox catalysts and isomerases, the last few years have revealed additional functions of the PDI proteins, including peptide binding, cell adhesion and perhaps chaperone activities. Attention is now turning to the non-redox-active domains of the PDIs, which may play an important role in all of the known activities of these proteins. Thus the presence of both redox-active and -inactive domains within these proteins portends a complexity of functions differentially accommodated by the various family members.

Alterations in the enzyme activity and protein contents of protein disulfide isomerase in rat tissues during fasting and refeeding

Protein disulfide isomerase (PDI) is an enzyme that participates in the formation of disulfide bonds. It is also known to be the subunits of some enzymes and the membrane-associated thyroid hormone-binding protein. In this study, we measured the quantitative distribution of PDI protein in rat tissues and examined the relationship between protein level and enzyme activity in PDI during fasting and refeeding. Western blotting with specific anti-PDI antiserum detected the PDI protein band of 55 kd. Among several tissues, liver contained the largest amount of PDI protein, followed by kidney and fat, in which one-third to one-fourth of the hepatic PDI protein existed. The PDI protein band was also detected in heart and muscle. Fasting for 3 days decreased PDI protein levels in rat liver by 40%; control levels were recovered after 3 days of refeeding. The same change was observed in kidney. PDI activity, measured by the scrambled ribonuclease method, did not show the parallel alteration to PDI protein level in liver and kidney. Isomerase activity decreased to 50% of control values during fasting, but did not recover by refeeding. Thyroidal status did not affect either PDI protein level or isomerase activity. These findings show that fasting and refeeding affect PDI protein and enzyme activity, and that PDI protein level does not always reflect PDI activity.

The nonactive site cysteine residues of yeast protein disulfide isomerase are not required for cell viability

Protein disulfide isomerase (PDI), the product of the essential PDI1 gene of Saccharomyces cerevisiae catalyzes oxidization of thiols, reduction of disulfide bonds, and isomerization of disulfides. It can also act as a chaperone to facilitate folding of denatured proteins. The protein has 6 cysteine (Cys) residues. Four of these Cys are part of the 2 thioredoxin-like catalytic sites (-CGHC-), one of which is located near the N- and the other near the C-terminus. In addition, it has 2 non-active site Cys near the N-terminus. The function of these non-active site Cys of yeast PDI is poorly understood. Whereas in yeast PDI, these Cys residues are in the vicinity of the N-terminal-most active site, in mammalian PDI their position is closer to the C-terminal-most active site. We have examined their role and that of the active site cysteines by constructing an extensive set of mutants in which the Cys were systematically replaced by Ser. As reported earlier, the N-terminal Cys of the two active sites sequences of yeast PDI were found to be required for cell viability, but mutation of the C-terminal Cys to Ser in the two active sites was not lethal. We found that replacement of the two non-active site Cys with Ser did not affect cell viability, but in the case of the double mutant in which both Cys were replaced by Ser the processing and secretion of CPY was impaired.

Collagen hydroxylases and the protein disulfide isomerase subunit of prolyl 4-hydroxylases

Prolyl 4-hydroxylases catalyze the formation of 4-hydroxyproline in collagens and other proteins with an appropriate collagen-like stretch of amino acid residues. The enzyme requires Fe(II), 2-oxoglutarate, molecular oxygen, and ascorbate. This review concentrates on recent progress toward understanding the detailed mechanism of 4-hydroxylase action, including: (a) occurrence and function of the enzyme in animals; (b) general molecular properties; (c) intracellular sites of hydroxylation; (d) peptide substrates and mechanistic roles of the cosubstrates; (e) insights into the development of antifibrotic drugs; (f) studies of the enzyme's subunits and their catalytic function; and (g) mutations that lead to Ehlers-Danlos Syndrome. An account of the regulation of collagen hydroxylase activities is also provided.

Protein disulfide isomerase acts as a molecular chaperone during the assembly of procollagen

Protein-disulfide isomerase (PDI) has been shown to be a multifunctional enzyme catalyzing the formation of disulfide bonds, as well as being a component of the enzymes prolyl 4-hydroxylase (P4-H) and microsomal triglyceride transfer protein. It has also been proposed to function as a molecular chaperone during the refolding of denatured proteins in vitro. To investigate the role of this multifunctional protein within a cellular context, we have established a semi-permeabilized cell system that reconstitutes the synthesis, folding, modification, and assembly of procollagen as they would occur in the cell. We demonstrate here that P4-H associates transiently with the triple helical domain during the assembly of procollagen. The release of P4-H from the triple helical domain coincides with assembly into a thermally stable triple helix. However, if triple helix formation is prevented, P4-H remains associated, suggesting a role for this enzyme in preventing aggregation of this domain. We also show that PDI associates independently with the C-propeptide of monomeric procollagen chains prior to trimer formation, indicating a role for this protein in coordinating the assembly of heterotrimeric molecules. This demonstrates that PDI has multiple functions in the folding of the same protein, that is, as a catalyst for disulfide bond formation, as a subunit of P4-H during proline hydroxylation, and independently as a molecular chaperone during chain assembly.

Enzymes as chaperones and chaperones as enzymes

Chaperones and foldases are two groups of accessory proteins which assist maturation of nascent peptides into functional proteins in cells. Protein disulfide isomerase, a foldase, and ATP-dependent proteases, responsible for degradation of misfolded proteins in cells, both have intrinsic chaperone activities. Trigger factor and DnaJ, well known Escherichia coli chaperones, show peptidyl prolyl isomerase and protein disulfide isomerase activities respectively. It is suggested that the combination of chaperone and enzyme activities in one molecule is the result of evolution to increase molecular efficiency.

Prolyl 4-hydroxylases and their protein disulfide isomerase subunit

Prolyl 4-hydroxylases (EC 1.14,11.2) catalyze the formation of 4-hydroxyproline in collagens and other proteins with collagen-like sequences. The vertebrate type I and type II enzymes are [alpha (I)]2 beta 2 and [alpha (II)]2 beta 2 tetramers, respectively, whereas the enzyme from the nematode Caenorhabditis elegans is an alpha beta dimer. The type I enzyme is the major form in most but not all vertebrate tissues. The catalytic properties of the various enzyme forms are highly similar, but there are distinct, although small, differences in K(m) values for various peptide substrates between the enzyme forms and major differences in Ki values for the competitive inhibitor, poly(L-proline). Prolyl 4-hydroxylase requires Fe2+, 2-oxoglutarate, O2 and ascorbate. Kinetic studies and theoretical considerations have led to elucidation of the reaction mechanism, and recent extensive site-directed mutagenesis studies have identified five critical residues at the cosubstrate binding sites. A number of compounds have been characterized that inhibit it competitively with respect to some of the cosubstrates, and three groups of suicide inactivators have also been identified. The beta subunit in all forms of prolyl 4-hydroxylase is identical to protein disulfide isomerase (PDI), a multifunctional polypeptide that also serves as a subunit in the microsomal triglyceride transfer protein, as a chaperone-like polypeptide that probably assists folding of a number of newly synthesized proteins, and in several other functions. The main role of the PDI polypeptide as a protein subunit is probably related to its chaperone function. Recent expression studies of recombinant human prolyl 4-hydroxylase subunits in a yeast have indicated that the formation of a stable enzyme tetramer in vivo requires coexpression of collagen polypeptide chains.

A 21-kDa C-terminal fragment of protein-disulfide isomerase has isomerase, chaperone, and anti-chaperone activities

A catalyst of disulfide formation and isomerization during protein folding, protein-disulfide isomerase (PDI) has two catalytic sites housed in two domains homologous to thioredoxin, one near the N terminus and the other near the C terminus. The thioredoxin domains, by themselves, can catalyze disulfide formation, but they are unable to catalyze disulfide isomerizations (Darby, N. J. and Creighton, T. E. (1995) Biochemistry 34, 11725-11735). A 21-kDa, C-terminal fragment of PDI (amino acids 308-491), termed weePDI, comprises the C-terminal third of the molecule. The kcat for ribonuclease oxidative folding by weePDI is 0.26 +/- 0.02 min-1, 3-fold lower than the wild-type enzyme but indistinguishable from the activity of a full-length mutant of PDI in which both active site cysteines of the N-terminal thioredoxin domain have been mutated to serine. Eliminating the ability of weePDI to escape easily from covalent complexes with substrate by mutating the active site cysteine nearer the C terminus to serine has a large effect on the isomerase activity of weePDI compared with its effect on the full-length enzyme. weePDI also displays chaperone and anti-chaperone activity characteristic of the full-length molecule. As isolated, weePDI is a disulfide-linked dimer in which the single cysteine (Cys-326) outside active site cross-links two weePDI monomers. The presence of the intermolecular disulfide decreases the activity by more than 2-fold. The results imply that the functions of the core thioredoxin domains of PDI and other members of the thioredoxin superfamily might be modified quite easily by the addition of relatively small accessory domains.

Phosphoinositide 3-kinase activity is necessary for insulin-dependent inhibition of apolipoprotein B secretion by rat hepatocytes and localizes to the endoplasmic reticulum

Insulin inhibits apolipoprotein B (apoB) secretion by primary rat hepatocytes through activation of phosphoinositide 3-kinase (PI 3-K). Current studies demonstrate that the PI 3-K inhibitor wortmannin inhibits both basal and insulin-stimulated PI 3-K activities. Wortmannin and LY 294002, two structurally distinct PI 3-K inhibitors, prevent insulin-dependent inhibition of apoB secretion in a dose-dependent manner. To link PI 3-K activation to insulin action on apoB, we investigated whether insulin induced localization of activated PI 3-K to the endoplasmic reticulum (ER), where apoB biogenesis is initiated. Insulin action results in a significant redistribution of PI 3-K to a low density microsome (LDM) fraction containing apoB protein and apoB mRNA. Insulin stimulates a significant increase in PI 3-K activity associated with insulin receptor substrate-1 as well as an increase in insulin receptor substrate-1/PI 3-K mass in LDM. Subfractionation of LDM on sucrose density gradients shows that insulin significantly increases the amount of PI 3-K present in an ER fraction containing apoB. Insulin stimulates PI 3-K activity in smooth and rough microsomes isolated from rat hepatocytes, the latter of which contain rough ER as demonstrated by electron microscopy. Studies indicate that 1) PI 3-K activity is necessary for insulin-dependent inhibition of apoB secretion by rat hepatocytes; 2) insulin action leads to the activation and localization of PI 3-K in an ER fraction containing apoB; and 3) insulin stimulates PI 3-K activity in the rough ER.

The enzymatic and non-enzymatic roles of protein-disulfide isomerase in apolipoprotein B secretion

Secretion of apolipoprotein B (apoB) from mammalian cells requires the presence of functional microsomal triglyceride transfer protein (MTP). We previously reported that co-expressing the human intestinal form of apoB, B48, with both subunits of human MTP in oleate-treated Sf21 cells led to a dramatic induction of B48 secretion. Deletion mutagenesis studies showed that the cysteine-enriched amino terminus of apoB was necessary for the MTP responsiveness (Gretch, D. G., Sturley, S. L., Wang, L., Dunning, A., Grunwald, K. A. A., Wetterau, J. R., Yao, Z., Talmud, P., and Attie, A. D. (1996) J. Biol. Chem. 271, 8682-8691). We therefore hypothesized that the small subunit of MTP, protein-disulfide isomerase (PDI), plays a role in apoB secretion by facilitating correct disulfide bond formation. To determine whether the enzymatic activities of PDI are important for MTP-stimulated apoB secretion, the wild type PDI subunit was replaced with an active site mutant, mPDI (Cys36 --> Ser/Cys380 --> Ser), lacking both disulfide shuffling and redox activities. MTP containing mPDI was fully functional in promoting apoB and triglyceride secretion. Therefore, the shufflase and redox activities of PDI are not necessary for the function of MTP. Since PDI exists in large molar excess over the other subunit of MTP, the role of free PDI (independent of the MTP complex) was investigated. PDI or mPDI was co-expressed with B48 and B17, a fragment encompassing the amino-terminal 17% of apoB. Mutant PDI significantly and specifically reduced the accumulation of the B17 and B48 both intracellularly and in the culture medium. The reduction was partially eliminated by the protease inhibitor N-acetyl-leucyl-leucyl-norleucinal, consistent with rapid co- or post-translational degradation of apoB in the presence of mPDI. Treating the cells with oleate reversed the effect of mPDI on B48 secretion in a dose-dependent manner, but had no effect on B17.

IN CONCLUSION

1) the role of PDI in the MTP complex involves functions other than its known enzymatic activities; 2) one or both of the enzymatic activities of free PDI is/are important for the MTP-independent steps of apoB secretion; 3) oleate can affect apoB secretion at high physiological concentrations and compensate for the insufficiency of PDI activities.

A mutant truncated protein disulfide isomerase with no chaperone activity

A mutant human protein disulfide isomerase with the COOH-terminal 51 amino acid residues deleted (abb'a') has been expressed in Escherichia coli. Its secondary structures are very similar to those of the native bovine enzyme. The mutant enzyme shows neither peptide binding ability nor chaperone activity in assisting the refolding of denatured D-glyceraldehyde-3-phosphate dehydrogenase but keeps most of the catalytic activities for reduction of insulin and isomerization of scrambled ribonuclease. It assists the reactivation of denatured and reduced proteins containing disulfide bonds, acid phospholipase A2, and lysozyme to different levels, which are significantly lower than those by the native bovine enzyme.

Thioredoxin domain non-equivalence and anti-chaperone activity of protein disulfide isomerase mutants in vivo

Coexpression of the enzyme, protein disulfide isomerase (PDI), has been shown to increase soluble and secreted IgG levels from baculovirus-infected insect cells (Hsu, T.-A., Watson, S., Eiden, J. J., and Betenbaugh, M. J. (1996) Protein Expression Purif. 7, 281-288). PDI is known to include catalytic active sites in two separate thioredoxin-like domains, one near the amino terminus and another near the carboxyl terminus. To examine the role of these catalytic active sites in enhancing immunoglobulin solubility, baculovirus constructs were utilized with cysteine to serine mutations at the first cysteine of one or both of the CGHC active site sequences. Trichoplusia ni insect cells were coinfected with a baculovirus vector coding for IgG in concert with either the wild-type human PDI virus, amino-terminal mutant (PDI-N), carboxyl-terminal mutant (PDI-C), or mutant with both active sites altered (PDI-NC). Western blot analysis revealed that both immunoglobulins and PDI protein were expressed in the coinfected cells. To evaluate the effect of the PDI variants on immunoglobulin solubility and secretion, the infected cells were labeled with 35S-amino-acids for different periods, and the soluble immunoglobulins were immunoprecipitated from clarified cell lysates and culture medium using anti-IgG antibodies. Only coinfections with the wild-type PDI and PDI-N mutant led to increased immunoglobulin solubility and higher IgG secretion. In contrast, infection with the PDI-C and PDI-NC variants actually lowered immunoglobulin solubility levels below those achieved with a negative control virus. Immunoprecipitation with anti-PDI antibody revealed that heterologous PDI-C and PDI-NC were insoluble, even though PDI-N and wild-type PDI protein were detected in soluble form. The capacity for PDI-N to increase immunoglobulin solubility whereas the PDI-C mutant lowered solubility indicates that the amino- and carboxyl-terminal thioredoxin domains of PDI are functionally distinct in vivo following mutations to the active site. Furthermore, mutations at the active site of the carboxyl-terminal thioredoxin domain result in PDI variants that can act as anti-chaperones of immunoglobulin solubility in vivo as has been observed in vitro for lysozyme aggregation by wild-type PDI and PDI mutants (Puig, A., and Gilbert, H. F. (1994) J. Biol. Chem. 269, 7764-7771).

Expression of wild-type and modified proalpha chains of human type I procollagen in insect cells leads to the formation of stable [alpha1(I)]2alpha2(I) collagen heterotrimers and [alpha1(I)]3 homotrimers but not [alpha2(I)]3 homotrimers

Insect cells coinfected with a baculovirus coding for the proalpha1(I) chain of human type I procollagen and a double promoter virus coding for the alpha and beta subunits of human prolyl 4-hydroxylase produced homotrimeric [proalpha1(I)]3 procollagen molecules. The use of an additional virus coding for the proalpha2(I) chain led to the formation of a heterotrimeric molecule with the correct 2:1 ratio of proalpha1 to proalpha2 chains of type I procollagen (proalpha1(I) and proalpha2(I) chains, respectively), unless the proalpha1(I) chain was expressed in a relatively large excess. Replacement of the sequences coding for the signal peptide and the N propeptide of the proalpha1(I) chain with those of the proalpha1(III) chain increased level of expression of the proalpha1(I) chain, whereas no similar effect was found when the corresponding modification was made to the virus coding for the proalpha2(I) chain. Molecules containing such modified N propeptides were found to be processed at their N terminus more rapidly than those containing the wild-type propeptides. The Tm of the type I collagen homotrimer was similar to that of the heterotrimer, both values being about 42-43 degrees C when determined by circular dichroism. The wild-type proalpha2(I) chain formed no homotrimers. Replacement of the C propeptide of the proalpha2(I) chain with that of the proalpha1(I) chain or proalpha1 chain of type III procollagen (proalpha1(III) chain) led to the formation of homotrimers, but the alpha2(I) chains in such molecules were completely digested by pepsin in 1 h at 22 degrees C. The data thus suggest that, in addition to control at the level of the C propeptide, other restrictions may exist at the level of the collagen domain that prevent the formation of stable homotrimeric [proalpha2(I)]3 molecules in insect cells.

Structures of the human gene for the protein disulfide isomerase-related polypeptide ERp60 and a processed gene and assignment of these genes to 15q15 and 1q21

ERp60 (also known as ERp61 or GRP58) is an isoform of protein disulfide isomerase (PDI) that has two thioredoxin-like domains a and a' in positions corresponding to those of domains a and a' in the PDI polypeptide and shows a significant amino acid sequence similarity to PDI in almost all parts. We report here that the human ERp60 gene is about 18 kb in size and consists of 13 exons. No distinct correlation was found between its exon-intron organization and the modular structure of the ERp60 polypeptide, nor were any similarities in exon-intron organization found between the human ERp60, PDI, and thioredoxin genes. The 5' flanking region of the ERp60 gene has no TATAA box or CCAAT motif but contains several potential binding sites for transcription factors. The highest levels of expression of the ERp60 mRNA were found by Northern blotting in the liver, placenta, lung, pancreas, and kidney, and the lowest in the heart, skeletal muscle, and brain. We also isolated an intronless ERp60 gene that probably represents a pseudogene. The ERp60 gene was mapped by fluorescence in situ hybridization to 15q15 and the processed gene to 1q21, so that neither was located on the same chromosome as the human PDI and thioredoxin genes.

The thiol-dependent reductase ERp57 interacts specifically with N-glycosylated integral membrane proteins

The lumen of the endoplasmic reticulum contains a number of distinct molecular chaperones and folding factors, which modulate the folding and assembly of newly synthesized proteins and protein complexes. A subset of these luminal components are specific for glycoproteins, and, like calnexin and calreticulin, the thiol-dependent reductase ERp57 has been shown to interact specifically with soluble secretory proteins bearing N-linked carbohydrate. Calnexin and calreticulin also interact with glycosylated integral membrane proteins, and in this study we have examined the interaction of ERp57 with these substrates. As with soluble proteins, the binding of ERp57 to an integral membrane protein is dependent upon the protein bearing an N-glycan that has undergone glucose trimming. Furthermore, ERp57 binds to newly synthesized glycoproteins in combination with either calnexin or calreticulin. We propose that ERp57 acts in concert with calnexin and calreticulin to modulate glycoprotein folding and enforce the glycoprotein specific quality control mechanism operating in the endoplasmic reticulum.

Mutant human protein disulfide isomerase assists protein folding in a chaperone-like fashion

Human protein disulfide isomerase with an extra 10 amino acid residues of AEITRIDPAM at the N-terminal was expressed in E. coli as a soluble protein comprising 20% of total cell proteins, and was purified to near homogeneity through one step of DEAE-Sephacel chromatography. The mutant enzyme, which had the same CD spectrum and comparable disulfide isomerase and thiol-protein oxidoreductase activities with that of the wild type human and bovine protein disulfide isomerases, also showed chaperone-like activity in stimulating the refolding of proteins containing no disulfide bond. The overall yield of the active product is about 20 mg 1-1 culture.

Involvement of prolyl 4-hydroxylase in the assembly of trimeric minicollagen XII. Study in a baculovirus expression system

We have shown previously that hydroxylation played a critical role in the trimer assembly and disulfide bonding of the three constituent alpha chains of a minicollagen composed of the extreme C-terminal collagenous (COL1) and noncollagenous (NC1) domains of type XII collagen in HeLa cells (Mazzorana, M., Gruffat, H., Sergeant, A., and van der Rest, M. (1993) J. Biol. Chem. 268, 3029-3032). We have further characterized the involvement of prolyl 4-hydroxylase in the assembly of the three alpha chains to form trimeric disulfide-bonded type XII minicollagen in an insect cell expression system. For this purpose, type XII minicollagen was produced in insect cells from baculovirus vectors, alone or together with wild-type human prolyl 4-hydroxylase or with the human enzyme mutated in the catalytic site of its alpha or beta subunits or with the individual alpha or beta subunits. When type XII minicollagen was produced alone, negligible amounts of disulfide-bonded trimers were found to be produced by the cells. However, coproduction of the collagen with the two subunits of the wild-type human enzyme dramatically increased the amount of disulfide-bonded trimeric type XII minicollagen molecules. In contrast, coproduction of the collagen with alpha subunits that had a mutation completely inactivating the human enzyme failed to enhance the trimer assembly. These results directly show that an active prolyl 4-hydroxylase is required for the assembly of disulfide-bonded trimers of type XII minicollagen.

Characterization of human type III collagen expressed in a baculovirus system. Production of a protein with a stable triple helix requires coexpression with the two types of recombinant prolyl 4-hydroxylase subunit

An efficient expression system for recombinant collagens would have numerous scientific and practical applications. Nevertheless, most recombinant systems are not suitable for this purpose, as they do not have sufficient amounts of prolyl 4-hydroxylase activity. Pro-alpha 1 chains of human type III collagen expressed in insect cells by a baculovirus vector are reported here to contain significant amounts of 4-hydroxyproline and to form triple-helical molecules, although the Tm of the triple helices was only about 32-34 degrees C. Coexpression of the pro-alpha1(III) chains with the alpha and beta subunits of human prolyl 4-hydroxylase increased the Tm to about 40 degrees C, provided that ascorbate was added to the culture medium. The level of expression of type III procollagen was also increased in the presence of the recombinant prolyl 4-hydroxylase, and the pro-alpha 1(III) chains and alpha1(III) chains were found to be present in disulfide-bonded molecules. Most of the triple-helical collagen produced was retained within the insect cells and could be extracted from the cell pellet. The highest expression levels were obtained in High Five cells, which produced up to about 80 microg of cellular type III collagen (120 microg of procollagen) per 5 X 10(6) cells in monolayer culture and up to 40 mg/liter of cellular type III collagen (60 mg/liter procollagen) in suspension. The 4-hydroxyproline content and Tm of the purified recombinant type III collagen were very similar to those of the nonrecombinant protein, but the hydroxylysine content was slightly lower, being about 3 residues/1000 in the former and 5/1000 in the latter.

Protein disulfide isomerase: a multifunctional protein of the endoplasmic reticulum

Protein disulfide isomerase (PDI) is a resident enzyme of the endoplasmic reticulum (ER) that was discovered over three decades ago. Contemporary biochemical and molecular biology techniques have revealed that it is present in all eukaryotic cells studied and retained in the ER via a -KDEL or -HDEL sequence at its C-terminus. However, evidence is accumulating that in certain cell types, PDI can be found in other subcellular compartments, despite possessing an intact retention sequence. A wide range of studies has established that in presence of a redox pair, PDI acts catalytically to both form and reduce disulfide bonds, therefore acting as a disulfide isomerase. Recent studies have focused on the mechanism of the isomerization process and the precise role of the two active site sequences (-CGHC-) in the process. In addition, prokaryotes have been shown to possess a set of proteins that function in a similar fashion, being able to generate disulfide bonds on polypeptides translocated into the periplasmic space. Following the recent discovery that PDI binds peptides, coupled with earlier findings that PDI is a subunit of at least two enzymatic complexes (prolyl 4-hydroxylase and microsomal triglyceride transfer protein), it seems that it may serve functions other than merely that of a disulfide isomerase. In fact, it is now clear that PDI can facilitate protein folding independently of its disulfide isomerase activity. A major challenge for the future is to define mechanistically how it accomplishes isomerization and the relationship between this process and the protein folding steps that culminate in the final, fully mature protein.

A 30-amino acid truncation of the microsomal triglyceride transfer protein large subunit disrupts its interaction with protein disulfide-isomerase and causes abetalipoproteinemia

The microsomal triglyceride transfer protein (MTP) is a heterodimer composed of the multifunctional enzyme, protein disulfide-isomerase, and a unique large, 97 kDa, subunit. It is found as a soluble protein within the lumen of the endoplasmic reticulum of liver and intestine and is required for the assembly of very low density lipoproteins and chylomicrons. Mutations in MTP which result in an absence of MTP function have been shown to cause abetalipoproteinemia. Here, the gene encoding the MTP 97-kDa subunit of an abetalipoproteinemic subject, which we have previously demonstrated lacks MTP activity and protein (Wetterau, J. R., Aggerbeck, L. P., Bouma, M.-E., Eisenberg, C., Munck, A., Hermier, M., Schmitz, J., Gay, G., Rader, D. J., and Gregg, R. E. (1992) Science 258, 999-1001), was isolated and sequenced. A nonsense mutation, which predicts the truncation of the protein by 30 amino acids, was identified. To investigate if this apparently subtle change in MTP could explain the observed absence of MTP, protein disulfide-isomerase was co-expressed with either the normal or mutant MTP 97-kDa subunit in Sf9 insect cells using a baculovirus expression system. Although there were high levels of expression of both the normal and mutant forms of the MTP 97-kDa subunit, only the normal subunit was able to form a stable, soluble complex with protein disulfide-isomerase. These results indicate that the carboxyl-terminal 30 amino acids of the MTP 97-kDa subunit plays an important role in its interaction with protein disulfide-isomerase.

Site-directed mutagenesis of the alpha subunit of human prolyl 4-hydroxylase. Identification of three histidine residues critical for catalytic activity

Prolyl 4-hydroxylase (EC 1.14.11.2) catalyzes the formation of 4-hydroxyproline in collagens. The vertebrate enzyme is an alpha 2 beta 2 tetramer in which the alpha subunits contribute to most parts of the two catalytic sites. To study the roles of histidine and cysteine residues in this catalytic activity we converted all 5 histidines that are conserved between species, 4 nonconserved histidines, and 3 conserved cysteines of the human alpha subunit individually to serine and expressed the mutant alpha subunits together with the wild-type beta subunit in insect cells by means of baculovirus vectors. Mutation of any of the 3 conserved histidines, residues 412, 483, and 501, inactivated the enzyme completely or essentially completely, with no effect on tetramer assembly or binding of the tetramer to poly(L-proline). These histidines are likely to provide the three ligands needed for the binding of Fe2+ to a catalytic site. Mutation of either of the other 2 conserved histidines reduced the amount of enzyme tetramer by 20-25% and the activity of the tetramer by 30-60%. Mutation of the nonconserved histidine 324 totally prevented tetramer assembly, whereas mutation of the 3 other nonconserved histidines had no effects. Two of the 3 cysteine to serine mutations, those involving residues 486 and 511, totally prevented tetramer assembly under the present conditions, whereas the third, involving residue 150, had only a minor effect in reducing tetramer assembly and activity. The data do not support previous suggestions that cysteine residues are involved in Fe2+ binding sites. Additional mutagenesis experiments demonstrated that the two glycosylated asparagines have no role in tetramer assembly or catalytic activity.

Prolyl 4-hydroxylase: defective assembly of alpha-subunit mutants indicates that assembled alpha-subunits are intramolecularly disulfide bonded

The vital hydroxylation of peptidyl proline residues in collagens and protein with collagen-like amino acid sequences is catalyzed by the tetrameric enzyme prolyl 4-hydroxylase (P4-H). We have previously detailed [John et al. (1993) EMBO J. 12, 1587-1595] the redox-dependent assembly of the catalytically important alpha-subunit (64 kDa) in a cell-free system containing endogenous beta-subunits (PDI, 60 kDa). To identify the origin of this redox-dependent assembly, we have now shown directly by an electrophoretic mobility shift assay that the assembled wild-type protein possesses at least one intramolecular disulfide bond. We also analyzed five alpha-subunit mutants that have single Cys to Ser mutations in one of the five Cys residues present in the wild-type protein and found that (i) subunits mutated at Cys150 or Cys511 formed intramolecular disulfide bonds, whereas subunits mutated at Cys276, Cys293, or Cys486 did not, (ii) mutation of Cys276, Cys293, or Cys486 led to a large reduction in alpha-beta complex formation, (iii) subunits mutated at Cys276, Cys293, Cys486, or Cys511 were recognized by an antiserum raised against an alpha-subunit C-terminal peptide which failed to recognize the assembled wild-type subunit or the assembled subunit mutated at Cys150, and (iv) the assembled complexes fractionated in a similar position to the purified protein on sucrose gradients whereas the assembly-defective mutants formed higher molecular weight aggregates or complexes with other proteins. On the basis of these results, we propose that P4-H alpha-subunits possess an intramolecular disulfide bond between Cys276 and Cys293 that is essential for alpha-beta complex formation.

Protein disulphide isomerase: building bridges in protein folding

Protein disulphide isomerase (PDI) has been known for many years to assist in the folding of proteins containing disulphide bonds, but the exact mechanism by which it achieves this is only now becoming clear. The active site of PDI closely resembles that of the redox protein thioredoxin, and cDNA cloning has revealed a superfamily of proteins with related active-site sequences, in organisms ranging from bacteria to higher animals and plants. Recent mutagenesis studies are now helping to unravel the catalytic mechanism of PDI, and work in yeast and other systems is clarifying the physiological roles of the multiple PDI-related proteins.

The same 15 kDa proteolipid subunit is a constituent of two different proteins in Torpedo, the acetylcholine releasing protein mediatophore and the vacuolar H+ ATPase

Using the monoclonal antibody 15K1, we have studied, at the cellular and subcellular levels, the distribution of a 15 kDa proteolipid, identified as the subunit of mediatophore, a presynaptic membrane protein able to release acetylcholine when activated by calcium. Aside from the electric lobe, the antigen distribution in the brain of Torpedo paralleled that of the synaptic vesicle antigen SV2 and did not appear to be related to that of acetylcholine and choline acetyltransferase. The 15 kDa proteolipid antigen was therefore present in all nerve endings and not restricted to cholinergic ones. At the ultrastructural level, on cholinergic nerve endings, the antigen was detected associated to synaptic vesicles and, to a lesser extent, to the presynaptic plasma membrane. Indeed, considering the high sequence homology between the mediatophore subunit (Birman et al., 1990) and the proteolipid subunit of the vacuolar type H+ ATPase, a major enzyme constituent of synaptic vesicles, this distribution was not surprising. To determine whether antibody 15K1 recognizes the vacuolar type H+ ATPase, we chose a non neuronal cell type which possesses a high content of this enzyme, the kidney proton secreting epithelial cells. Indeed, antibody 15K1 intensely labelled the apical plasma membrane of mitochondria rich epithelial cells in kidney tubules. A high density of the antigen was also found associated to intracellular membrane structures such as lysosomal multivesicular bodies, both in kidney epithelial cells and in electromotoneurons. The 15 kDa proteolipid antigen was associated with other vacuolar H+ ATPase subunits in kidney membranes which was not the case in presynaptic plasma membranes. This illustrates that the 15 kDa proteolipid antigen is a constituent of two different protein complexes, which exhibit very different functional properties.