Identification of a Novel Protein Binding Motif within the T-synthase for the Molecular Chaperone Cosmc

Prior studies suggested that the core 1 β3-galactosyltransferase (T-synthase) is a specific client of the endoplasmic reticulum chaperone Cosmc, whose function is required for T-synthase folding, activity, and consequent synthesis of normal O-glycans in all vertebrate cells. To explore whether the T-synthase encodes a specific recognition motif for Cosmc, we used deletion mutagenesis to identify a cryptic linear and relatively hydrophobic peptide in the N-terminal stem region of the T-synthase that is essential for binding to Cosmc (Cosmc binding region within T-synthase, or CBRT). Using this sequence information, we synthesized a peptide containing CBRT and found that it directly interacts with Cosmc and also inhibits Cosmc-assisted in vitro refolding of denatured T-synthase. Moreover, engineered T-synthase carrying mutations within CBRT exhibited diminished binding to Cosmc that resulted in the formation of inactive T-synthase. To confirm the general recognition of CBRT by Cosmc, we performed a domain swap experiment in which we inserted the stem region of the T-synthase into the human β4GalT1 and found that the CBRT element can confer Cosmc binding onto the β4GalT1 chimera. Thus, CBRT is a unique recognition motif for Cosmc to promote its regulation and formation of active T-synthase and represents the first sequence-specific chaperone recognition system in the ER/Golgi required for normal protein O-glycosylation.     

The Endoplasmic Reticulum Chaperone Cosmc Directly Promotes in Vitro Folding of T-synthase

The T-synthase is the key β3-galactosyltransferase essential for biosynthesis of core 1 O-glycans (Galβ1–3GalNAcα1-Ser/Thr) in animal cell glycoproteins. Here we describe the novel ability of an endoplasmic reticulum-localized molecular chaperone termed Cosmc to specifically interact with partly denatured T-synthase in vitro to cause partial restoration of activity. By contrast, a mutated form of Cosmc observed in patients with Tn syndrome has reduced chaperone function. The chaperone activity of Cosmc is specific, does not require ATP in vitro, and is effective toward T-synthase but not another β-galactosyltransferase. Cosmc represents the first ER chaperone identified to be required for folding of a glycosyltransferase.     

Cosmc和T-合酶在黏蛋白型O-聚糖合成中的重要作用及其与人类疾病的相关性

从核心1结构（Galβ1,3GalNAcα1-O-Ser/Thr, core 1 structure, T antigen）中衍生出来的黏蛋白型O-聚糖在很多生理过程中发挥重要的生物学功能。T-合酶 （core 1 β3-galactosyltransferase, T-synthase） 是合成核心1结构的唯一糖基转移酶,它主要的功能是将半乳糖（Galactose） 添加到GalNAcα1-Ser/Thr （Tn抗原） 糖链上。但是在人体和其他脊椎动物中有活性的T-合酶的形成需要一个重要的伴侣分子Cosmc;Cosmc功能丧失将直接导致T-合酶失活,其结果是机体细胞只能合成Tn抗原以及唾液酰化Tn （sialylTn, STn, Neu5Acα2,6GalNAcα1-O-Ser/Thr）。综述目前对T-合酶和Cosmc的研究以及他们在人类疾病（如异常O-聚糖表达相关的Tn综合征、IgA肾病和肿瘤）发生发展中的作用。     

Regulation of protein O-glycosylation by the endoplasmic reticulum-localized molecular chaperone Cosmc

Regulatory pathways for protein glycosylation are poorly understood, but expression of branchpoint enzymes is critical. A key branchpoint enzyme is the T-synthase, which directs synthesis of the common core 1 O-glycan structure (T-antigen), the precursor structure for most mucin-type O-glycans in a wide variety of glycoproteins. Formation of active T-synthase, which resides in the Golgi apparatus, requires a unique molecular chaperone, Cosmc, encoded on Xq24. Cosmc is the only molecular chaperone known to be lost through somatic acquired mutations in cells. We show that Cosmc is an endoplasmic reticulum (ER)-localized adenosine triphosphate binding chaperone that binds directly to human T-synthase. Cosmc prevents the aggregation and ubiquitin-mediated degradation of the T-synthase. These results demonstrate that Cosmc is a molecular chaperone in the ER required for this branchpoint glycosyltransferase function and show that expression of the disease-related Tn antigen can result from deregulation or loss of Cosmc function.     

The transmembrane domain of the molecular chaperone Cosmc directs its localization to the endoplasmic reticulum

The molecular basis for retention of integral membrane proteins in the endoplasmic reticulum (ER) is not well understood. We recently discovered a novel ER molecular chaperone termed Cosmc, which is essential for folding and normal activity of the Golgi enzyme T-synthase. Cosmc, a type II single-pass transmembrane protein, lacks any known ER retrieval/retention motifs. To explore specific ER localization determinants in Cosmc we generated a series of Cosmc mutants along with chimeras of Cosmc with a non-ER resident type II protein, the human transferrin receptor. Here we show that the 18 amino acid transmembrane domain (TMD) of Cosmc is essential for ER localization and confers ER retention to select chimeras. Moreover, mutations of a single Cys residue within the TMD of Cosmc prevent formation of disulfide-bonded dimers of Cosmc and eliminate ER retention. These studies reveal that Cosmc has a unique ER-retention motif within its TMD and provide new insights into the molecular mechanisms by which TMDs of resident ER proteins contribute to ER localization.     

A novel fluorescent assay for T-synthase activity

Loss of T-synthase (uridine diphosphate galactose:N-acetylgalactosaminyl-α1-Ser/Thr β3galactosyltransferase), a key enzyme required for the formation of mucin-type core 1 O-glycans, is observed in several human diseases, including cancer, Tn syndrome and IgA nephropathy, but current methods to assay the enzyme use radioactive substrates and complicated isolation of the product. Here we report the development of a novel fluorescent assay to measure its activity in a variety of tumor cell lines. Deficiencies in T-synthase activity correlate with mutations in the gene encoding the molecular chaperone Cosmc that is required for folding the T-synthase. This new high-throughput assay allows for facile screening of tumor specimens and other biological material for T-synthase activity and could be used diagnostically.     

Identification of core 1 O-glycan T-synthase from Caenorhabditis elegans

The common O-glycan core structure in animal glycoproteins is the core 1 disaccharide Galbeta1-3GalNAcalpha1-Ser/Thr, which is generated by the addition of Gal to GalNAcalpha1-Ser/Thr by core 1 UDP-alpha-galactose (UDP-Gal):GalNAcalpha1-Ser/Thr beta1,3-galactosyltransferase (core 1 beta3-Gal-T or T-synthase, EC2.4.1.122). Although O-glycans play important roles in vertebrates, much remains to be learned from model organisms such as the free-living nematode Caenorhabditis elegans, which offer many advantages in exploring O-glycan structure/function. Here, we report the cloning and enzymatic characterization of T-synthase from C. elegans (Ce-T-synthase). A putative C. elegans gene for T-synthase, C38H2.2, was identified in GenBank by a BlastP search using the human T-synthase protein sequence. The full-length cDNA for Ce-T-synthase, which was generated by polymerase chain reaction using a C. elegans cDNA library as the template, contains 1170 bp including the stop TAA. The cDNA encodes a protein of 389 amino acids with typical type II membrane topology and a remarkable 42.7% identity to the human T-synthase. Ce-T-synthase has seven Cys residues in the lumenal domain including six conserved Cys residues in all orthologs. The Ce-T-synthase has four potential N-glycosylation sequons, whereas the mammalian orthologs lack N-glycosylation sequons. Only one gene for Ce-T-synthase was identified in the genome-wide search, and it contains eight exons. Promoter analysis of the Ce-T-synthase using green fluorescent protein (GFP) constructs shows that the gene is expressed at all developmental stages and appears to be in all cells. Unexpectedly, only minimal activity was recovered in the recombinant, soluble Ce-T-synthase secreted from a wide variety of mammalian cell lines, whereas robust enzyme activity was recovered in the soluble Ce-T-synthase expressed in Hi-5 insect cells. Vertebrate T-synthase requires the molecular chaperone Cosmc, but our results show that Ce-T-synthase does not require Cosmc and might require invertebrate-specific factors for the formation of the optimally active enzyme. These results show that the Ce-T-synthase is a functional ortholog to the human T-synthase in generating core 1 O-glycans and open new avenues to explore O-glycan function in this model organism.     

SLC35A2 deficiency reduces protein levels of core 1 β-1,3-galactosyltransferase 1 (C1GalT1) and its chaperone Cosmc and affects their subcellular localization

Nucleotide sugar transporters (NSTs) are multitransmembrane proteins, localized in the Golgi apparatus and/or endoplasmic reticulum, which provide glycosylation enzymes with their substrates. It has been demonstrated that NSTs may form complexes with functionally related glycosyltransferases, especially in the N-glycosylation pathway. However, potential interactions of NSTs with enzymes mediating the biosynthesis of mucin-type O-glycans have not been addressed to date. Here we report that UDP-galactose transporter (UGT; SLC35A2) associates with core 1 β-1,3-galactosyltransferase 1 (C1GalT1; T-synthase). This provides the first example of an interaction between an enzyme that acts exclusively in the O-glycosylation pathway and an NST. We also found that SLC35A2 associated with the C1GalT1-specific chaperone Cosmc, and that the endogenous Cosmc was localized in both the endoplasmic reticulum and Golgi apparatus of wild-type HEK293T cells. Furthermore, in SLC35A2-deficient cells protein levels of C1GalT1 and Cosmc were decreased and their Golgi localization was less pronounced. Finally, we identified SLC35A2 as a novel molecular target for the antifungal agent itraconazole. Based on our findings we propose that NSTs may contribute to the stabilization of their interaction partners and help them to achieve target localization in the cell, most likely by facilitating their assembly into larger functional units.     

Antibodies to inactive conformations of glyceraldehyde-3-phosphate dehydrogenase inactivate the apo-and holoforms of the enzyme

Polyclonal antibodies produced after the immunization of a rabbit with glyceraldehyde-3-phosphate dehydrogenase (GAPDH) from Bacillus stearothermophilus were used to isolate two types of antibodies interacting with different non-native forms of the antigen. Type I antibodies were purified using Sepharose-bound apo-GAPDH that was treated with glutaraldehyde to stabilize the enzyme in the tetrameric form. Type II antibodies were isolated using immobilized denatured monomers of the enzyme. It was shown that the type I antibodies bound to the native holo- and apoforms of the enzyme with the ratio of one antibody molecule per GAPDH tetramer. While interacting with the native holoenzyme, the type I antibodies induce a time-dependent decrease in its activity by 80-90%. In the case of the apoenzyme, the decrease in the activity constitutes only 25%, this indicating that only one subunit of the tetramer is inactivated. Differential scanning calorimetry experiments showed that the formation of the complex between both forms of the enzyme and the type I antibodies resulted in a shift of the maximum of the thermal capacity curves (T(m) value) to lower temperatures. The extremely stable holoenzyme was affected to the greatest extent, the shift of the T(m) value constituting approximately 20 degrees C. We assume that the formation of the complex between the holo- or apo-GAPDH and the type I antibody results in time-dependent conformational changes in the enzyme molecule. Thus, the antibodies induce the structural rearrangements yielding the conformation that is identical to the structure of the antigen used for the selection of the antibodies (i.e., inactive). The interaction of the antibodies with the apo-GAPDH results in the inactivation of the subunit directly bound to the antibody. Virtually complete inactivation of the holoenzyme by the antibodies is likely due to the transmission of the conformational changes through the intersubunit contacts. The type II antibodies, which were selected using the immunosorbent with unfolded enzyme form, do not affect the activity of native holo- and apo-GAPDH, but prevent the reactivation of the denatured GAPDH, binding the denatured forms of the enzyme.     

Perturbations of the denatured state ensemble: modeling their effects on protein stability and folding kinetics.

By considering the denatured state of a protein as an ensemble of conformations with varying numbers of sequence-specific interactions, the effects on stability, folding kinetics, and aggregation of perturbing these interactions can be predicted from changes in the molecular partition function. From general considerations, the following conclusions are drawn: (1) A perturbation that enhances a native interaction in denatured state conformations always increases the stability of the native state. (2) A perturbation that promotes a non-native interaction in the denatured state always decreases the stability of the native state. (3) A change in the denatured state ensemble can alter the kinetics of aggregation and folding. (4) The loss (or increase) in stability accompanying two mutations, each of which lowers (or raises) the free energy of the denatured state, will be less than the sum of the effects of the single mutations, except in cases where both mutations affect the same set of partially folded conformations. By modeling the denatured state as the ensemble of all non-native conformations of hydrophobic-polar (HP) chains configured on a square lattice, it can be shown that the stabilization obtained from enhancement of native interactions derives in large measure from the avoidance of non-native interactions in the D state. In addition, the kinetic effects of fixing single native contacts in the denatured state or imposing linear gradients in the HH contact probabilities are found, for some sequences, to significantly enhance the efficiency of folding by a simple hydrophobic zippering algorithm. Again, the dominant mechanism appears to be avoidance of non-native interactions. These results suggest stabilization of native interactions and imposition of gradients in the stability of local structure are two plausible mechanisms involving the denatured state that could play a role in the evolution of protein folding and stability.     

Physical Interaction between Bacterial Heat Shock Protein (Hsp) 90 and Hsp70 Chaperones Mediates Their Cooperative Action to Refold Denatured Proteins

In eukaryotes, heat shock protein 90 (Hsp90) is an essential ATP-dependent molecular chaperone that associates with numerous client proteins. HtpG, a prokaryotic homolog of Hsp90, is essential for thermotolerance in cyanobacteria, and in vitro it suppresses the aggregation of denatured proteins efficiently. Understanding how the non-native client proteins bound to HtpG refold is of central importance to comprehend the essential role of HtpG under stress. Here, we demonstrate by yeast two-hybrid method, immunoprecipitation assays, and surface plasmon resonance techniques that HtpG physically interacts with DnaJ2 and DnaK2. DnaJ2, which belongs to the type II J-protein family, bound DnaK2 or HtpG with submicromolar affinity, and HtpG bound DnaK2 with micromolar affinity. Not only DnaJ2 but also HtpG enhanced the ATP hydrolysis by DnaK2. Although assisted by the DnaK2 chaperone system, HtpG enhanced native refolding of urea-denatured lactate dehydrogenase and heat-denatured glucose-6-phosphate dehydrogenase. HtpG did not substitute for DnaJ2 or GrpE in the DnaK2-assisted refolding of the denatured substrates. The heat-denatured malate dehydrogenase that did not refold by the assistance of the DnaK2 chaperone system alone was trapped by HtpG first and then transferred to DnaK2 where it refolded. Dissociation of substrates from HtpG was either ATP-dependent or -independent depending on the substrate, indicating the presence of two mechanisms of cooperative action between the HtpG and the DnaK2 chaperone system.     

Double modification of cytidine residues in DNA]

The reaction of O-beta-diethylaminoethylhydroxylamine (O-beta-HA) with cytidine was studied and its mechanism was shown to be analogous to that of the reaction of hydroxylamine of O-methylhydroxylamine with cytidine. In experiments involving reaction of denatured DNA with O-beta-HA., Sephadex G-15 columns were used for the quantitative separation of normal and modified nucleosides after enzymatic hydrolysis of modified DNA by exonuclease A5 followed by alkaline phosphatase treatment. DNA cytidine residues of free cytidine with O-beta-HA. Modified cytidines can form complex with phosphotungstic acid (PTA). It was shown that one mole of PTA was bound per one mole of modified cytidine either in DNA or in free state. Electron microscopic examination of denatured DNA molecules modified by O-beta-HA and reacted with PTA revealed linear arrays of electron-scattering spots which presumably correspond to PTA molecules complexed with modified cytidine in DNA chains.     

Oxidation of glyceraldehyde-3-phosphate dehydrogenase enhances its binding to nucleic acids

Glyceraldehyde-3-phosphate dehydrogenase (GAPDH) is a protein with various activities far from its enzymatic function. Here, we showed that the oxidation of SH-groups of the active site of GAPDH enhanced its binding with total transfer RNA or with total DNA. Both NAD and NADH-the cofactors of GAPDH-inhibited the GAPDH-RNA (DNA) interaction, though NAD was much less effective than NADH in the case of oxidized GAPDH. Oxidation of GAPDH strongly decreased its affinity to NAD but not to NADH. Immobilized tetramers of GAPDH dissociated into dimers during the incubation with total RNA but not DNA. The staining of HeLa cells with monoclonal antibodies specific to dimers, monomers or the denatured form of GAPDH revealed the condensation of non-native forms of GAPDH in the nucleus. The role of oxidation of GAPDH in the regulation of the quaternary structure of the enzyme and in its interaction with nucleic acids is discussed.     

The active centres in penicillin-sensitive enzymes

The interaction between beta-lactam antibiotics and the penicillin-sensitive enzymes is a multiple-step process. Binding of the beta-lactam ring of the penam (or 3-cepham) nucleus occurs at binding site no. 1. Interaction between the N-14 substituent of the bound molecule and binding site no. 2 induces changes in binding site no. 1. In turn, the catalytic site thus created increases the chemical reactivity of the beta-lactam amide bond. As the beta-lactam ring opens and acylates an enzyme serine residue, the interaction between the thiazolidine (or dihydrothiazine) ring and binding site no. 3 stabilizes the acyl-enzyme complex. Enzyme regeneration slowly proceeds either by direct elimination of the penicilloyl moiety or via C-5-C-6 splitting of the bound metabolite. The fragment arising from thiazolidine yields free N-formyl-D-penicillamine while the enzyme-linked N-acylglycyl fragment is immediately attacked by an exogenous nucleophile correctly positioned on the acceptor site. Similarly, the enzyme action on L-X-D-Ala-D-Ala terminated peptides is mediated via a binding site no. 1 that combines with D-Ala-D-Ala, a binding site no. 2 that interacts with the side chain of the preceding L-residue, an inducible catalytic site and an acceptor site. Enzymes are known that form a transitory L-X-D-Ala-enzyme complex where the acyl group is ester-linked to the same serine residue as that involved in the formation of the penicilloyl-enzyme complex (Waxman et al., this symposium). Other enzymes, however, may function as catalyst templates. Depending on the enzymes, the independence of the beta-lactam and L-X-D-Ala-D-Ala active centres is more or less pronounced.     

Mechanism of inhibition of the beta-lactamase of Enterobacter cloacae P99 by 1:1 complexes of vanadate with hydroxamic acids

The class C beta-lactamase of Enterobacter cloacae P99 is competitively inhibited by low concentrations of 1:1 complexes of vanadate and hydroxamic acids. Structure-activity studies indicated that the hydroxamic acid functional group was essential to this inhibition. Both aryl and alkyl hydroxamic acids form inhibitory ternary complexes with vanadate and the enzyme, although, in certain cases of the latter, the inhibition may not be seen because of the low formation constants of the vanadate-hydroxamic acid complex. After all of the vanadate species present in solution had been taken into account, "real" K(i) values for the vanadate complexes could be determined. The K(i) value of the best of the inhibitors that were investigated, the 1:1 complex of vanadate with 4-nitrobenzohydroxamic acid, was 0.48 microM. Kinetics studies showed that the association and dissociation rate constants of this complex with the enzyme were 1.48 x 10(6) s(-1) M(-1) and 0.73 s(-1), respectively; the magnitude of the latter indicates covalent interaction of the complex with the enzyme. (51)V NMR and UV-vis spectra suggest that the structure of the vanadate complex bound to the enzyme may be very similar to that in solution. A (13)C NMR spectrum of the enzyme complex with 4-nitrobenzo[(13)C]hydroxamic acid and vanadate yields a coordination-induced shift (CIS) of 7.74 ppm. This is significantly larger than that of the vanadate complex in free solution (3.62 ppm), suggesting either, somewhat contrary to the (51)V and UV-vis spectra, greater interaction between vanadium and the hydroxamate carbonyl oxygen in the enzyme complex than in free solution or, more likely, polarization of the hydroxamate by interaction, e.g., hydrogen bonding, with the enzyme. Molecular modeling indicates that a pentacoordinated vanadate complex may well be able to snugly occupy the enzyme active site; Asn 152 is suitably placed to hydrogen bond to the hydroxamic acid oxygen atom. The experimental results are in accord with a model whereby the vanadate-hydroxamate-enzyme complex is a moderately good analogue of the transition state of the reaction of the beta-lactamase with phosphonate inhibitors.     

Repetitive Protein Unfolding by the trans Ring of the GroEL-GroES Chaperonin Complex Stimulates Folding

A key constraint on the growth of most organisms is the slow and inefficient folding of many essential proteins. To deal with this problem, several diverse families of protein folding machines, known collectively as molecular chaperones, developed early in evolutionary history. The functional role and operational steps of these remarkably complex nanomachines remain subjects of active debate. Here we present evidence that, for the GroEL-GroES chaperonin system, the non-native substrate protein enters the folding cycle on the trans ring of the double-ring GroEL-ATP-GroES complex rather than the ADP-bound complex. The properties of this ATP complex are designed to ensure that non-native substrate protein binds first, followed by ATP and finally GroES. This binding order ensures efficient occupancy of the open GroEL ring and allows for disruption of misfolded structures through two phases of multiaxis unfolding. In this model, repeated cycles of partial unfolding, followed by confinement within the GroEL-GroES chamber, provide the most effective overall mechanism for facilitating the folding of the most stringently dependent GroEL substrate proteins.     

Mitochondrial malate dehydrogenase and its precursor have different conformations

Antiserum prepared against the denatured form of mammalian malate dehydrogenase was found to immunoprecipitate the denatured but not the native form of the mature enzyme. In contrast, the antiserum immunoprecipitated the enzyme's precursor, synthesized in a rabbit reticulocyte lysate, either before or after denaturation. The mature form of the enzyme but not the precursor bound to an affinity column of 5'-AMP-Sepharose. These results indicate that the mature and precursor forms of malate dehydrogenase have different conformations.     

Covalent fixation of NAD+ to dehydrogenases and properties of the modified enzymes

Starting from 6-chloropurine riboside and NAD+, different reactive analogues of NAD+ have been obtained by introducing diazoniumaryl or aromatic imidoester groups via flexible spacers into the nonfunctional adenine moiety of the coenzyme. The analogues react with different amino-acid residues of dehydrogenases and form stable amidine or azobridges, respectively. After the formation of a ternary complex by the coenzyme, the enzyme and a pseudosubstrate, the reactive spacer is anchored in the vicinity of the active site. Thus, the coenzyme remains covalently attached to the protein even after decomposition of the complex. On addition of substrates the covalently bound coenzyme is converted to the dihydro-form. In enzymatic tests the modified dehydrogenases show 80-90% of the specific activity of the native enzymes, but they need remarkably higher concentrations of free NAD+ to achieve these values. The dihydro-coenzymes can be reoxidized by oxidizing agents like phenazine methosulfate or by a second enzyme system. Various systems for coenzyme regeneration were investigated; the modified enzymes were lactate dehydrogenase from pig heart and alcohol dehydrogenase from horse liver; the auxiliary enzymes were alcohol dehydrogenase from yeast and liver, lactate dehydrogenase from pig heart, glutamate dehydrogenase and alanine dehydrogenase. Lactate dehydrogenase from heart muscle is inhibited by pyruvate. With alanine dehydrogenase as the auxiliary enzyme, the coenzyme is regenerated and the reaction product, pyruvate, is removed. This system succeeds to convert lactate quantitatively to L-alanine. The thermostability of the binary enzyme systems indicates an interaction of covalently bound coenzymes with both dehydrogenases; both binding sites seem to compete for the coenzyme. The comparison of dehydrogenases with different degrees of modifications shows that product formation mainly depends on the amount of incorporated coenzyme.     

Comparison of the enzymatic behavior of high molecular weight and free lysyl-tRNA synthetase from rat liver: kinetic analysis of lysylation of tRNA

Lysyl-tRNA synthetase occurs in the high molecular weight form in rat liver. The high molecular weight lysyl-tRNA synthetase has been previously demonstrated to exist as multienzyme complexes of aminoacyl-tRNA synthetases. The multienzyme complexes can be dissociated by hydrophobic interaction chromatography and yield fully active, free lysyl-tRNA synthetase. The free form is found to be twice as active as the complexed form in lysylation. Bisubstrate and product inhibition kinetics of lysylation are systematically carried out for highly purified free lysyl-tRNA synthetase and the 18 S synthetase complex. Surprisingly, the two enzyme forms exhibit distinctly different kinetic patterns in bisubstrate and product inhibition kinetics under identical conditions. The 18 S synthetase complex shows kinetic patterns consistent with an ordered bi uni uni bi ping pong mechanism, while the results of free lysyl-tRNA synthetase do not. We conclude that structural organization of lysyl-tRNA synthetase beyond quaternary structure of proteins may alter the enzyme behavior.