Partial purification of active delta and epsilon subunits of the membrane ATPase from escherichia coli

We have partially purified active delta and epsilon subunits of the E. coli membranebound Mg²⁺ -ATPase (ECF₁). Treating purified ECF₁ with 50% pyridine precipitates the major subunits (α, β, and γ) of the enzyme, but the two minor subunits (δ and ϵ), which are present in relatively small amounts, remain in solution. The delta and epsilon subunits were then resolved from one another by anion exchange chromatography. The partially purified epsilon strongly inhibits the hydrolytic activity of ECF₁. The epsilon fraction inhibits both the highly purified five-subunit ATPase and the enzyme deficient in the δ subunit. The latter result indicates that the delta subunit is not required for inhibition by epsilon. By contrast, two-subunit enzyme, consisting chiefly of the α and β subunits, was insensitive to the ATPase inhibitor, suggesting that the γ subunit may be required for inhibition by epsilon. The partially purified delta subunit restored the capacity of ATPase deficient in delta to recombine with ATPase-depleted membranes and to reconstitute ATP-dependent transhydrogenase. Previously we reported (Biochem. Biophys. Res. Commun. 62:764 [1975]) that a fraction containing both the delta and epsilon subunits of ECF₁ restored the capacity of ATPase missing delta to recombine with depleted membranes and to function as a coupling factor in oxidative phosphorylation and for the energized transhydrogenase. These reconstitution experiments using isolated subunits provide rather substantial evidence that the delta subunit is essential for attaching the ATPase to the membrane and that the epsilon subunit has a regulatory function as an inhibitor of the ATPase activity of ECF₁.     

The epsilon subunit of Escherichia coli coupling factor 1 is required for its binding to the cytoplasmic membrane.

The coupling factor, F1-ATPase of Escherichia coli (ECF1) contains five different subunits, alpha, beta, gamma, delta, and epsilon. Properties of delta-deficient ECF1 have previously been described. F1-ATPase containing only the alpha, beta, and gamma subunits was prepared from E. coli by passage of delta-deficient ECF1 through an affinity column containing immobilized antibodies to the epsilon subunit. The delta, epsilon-deficient enzyme has normal ATPase activity but cannot bind to ECF1-depleted membrane vesicles. Both the delta and epsilon subunits are required for the binding of delta, epsilon-deficient ECF1 to membranes and the restoration of oxidative phosphorylation. Either delta or epsilon will bind to the deficient enzyme to form a four-subunit complex. Neither four-subunit enzyme binds to depleted membranes. The epsilon subunit, does, however, slightly improve the binding affinity between delta and delta-deficient enzyme suggesting a possible interaction between the two subunits. Neither subunit binds to trypsin-treated ECF1, which contains only the alpha and beta subunits. A role for gamma in the binding of epsilon to F1 is suggested. epsilon does not bind to ECF1-depleted membranes. Therefore, the in vitro reconstitution of depleted membranes requires an initial complex formation between epsilon and the rest of ECF1 prior to membrane attachment. Reconstitution experiments indicate that only one epsilon is required per functional ECF1 molecule.     

Guanidine-induced dissociation of mitochondrial F1-ATPase

The effect of guanidine hydrochloride on ATPase activity, gel filtration, turbidity, and the fluorescence emission intensity of mitochondrial F1-ATPase was examined. Purified F1 from bovine heart mitochondria was slowly inactivated at low denaturant concentration, and inactivation was associated with delta and epsilon subunit dissociation. delta and epsilon subunits were bound together to form a stable and soluble heterodimer. In parallel, appearance of turbidity was observed. This was caused by the formation of alpha3beta3gamma non-covalent aggregates, as analyzed by SDS-PAGE. Short periods of exposition of the F1 complex to high concentrations of guanidine hydrochloride (0.8-3 M) again induced deltaepsilon dissociation as a heterodimer and the formation of an inactive alpha3beta3gamma subcomplex. This eventually dissociated progressively into single subunits caused by partial unfolding, as evidenced through changes of the protein intrinsic fluorescence emission. Our results suggest that the delta and epsilon subunits are loosely bound to alpha3beta3gamma , and play an important role in determining structural stability to isolated mitochondrial F1-ATPase.     

Isolated epsilon subunit of thermophilic F1-ATPase binds ATP

F1-ATPase, a soluble part of the F0F1-ATP synthase, has subunit structure alpha3beta3gammadeltaepsilon in which nucleotide-binding sites are located in the alpha and beta subunits and, as believed, in none of the other subunits. However, we report here that the isolated epsilon subunit of F1-ATPase from thermophilic Bacillus strain PS3 can bind ATP. The binding was directly demonstrated by isolating the epsilon subunit-ATP complex with gel filtration chromatography. The binding was not dependent on Mg2+ but was highly specific for ATP; however, ADP, GTP, UTP, and CTP failed to bind. The epsilon subunit lacking the C-terminal helical hairpin was unable to bind ATP. Although ATP binding to the isolated epsilon subunits from other organisms has not been detected under the same conditions, a possibility emerges that the epsilon subunit acts as a built in cellular ATP level sensor of F0F1-ATP synthase.     

Large-scale purification and characterization of the five subunits of F1-ATPase from pig heart mitochondria.

A large-scale purification procedure was developed to isolate the five subunits of F1-ATPase from pig heart mitochondria. The previously described procedure (Williams, N. and Pedersen, P.L. (1986) Methods Enzymol. 126, 484-489) to dissociate the rat liver F1-ATPase by cold treatment followed by warming at 37 degrees C has been adapted for the pig heart enzyme. Removal of endogenous nucleotides from that enzyme before dissociation led to the efficient separation of the alpha and gamma subunits from beta, delta and epsilon subunits. The beta subunit was purified in the hundred-milligram range by anion-exchange chromatography in the absence of any denaturing agent. This subunit was free from any bound nucleotide and almost no ATPase and adenylate kinase-like activities were detected. The delta and epsilon subunits were purified by reversed-phase chromatography (RP-HPLC) in the milligram range. As recently reported (Penin, F., Deléage, G., Gagliardi, D., Roux, B. and Gautheron, D.C. (1990) Biochemistry 29, 9358-9364), these purified subunits kept biophysical features of folded proteins and their ability to reconstitute the tight delta epsilon complex. The alpha and gamma subunits remained poorly soluble and required dissociation by 8 M guanidinium chloride prior to their purification by RP-HPLC. In addition, characterizations of the five subunits by IEF and SDS-polyacrylamide gel electrophoresis are reported, as well as ultraviolet spectra and solubility properties of the beta, delta and epsilon subunits.     

Coupling factor 1 from Escherichia coli lacking subunits delta and epsilon: preparation and specific binding to depleted membranes, mediated by subunits delta or epsilon

A procedure for the preparation of coupling factor 1 (F1) from Escherichia coli lacking subunits delta and epsilon is described. Using chloroform and dimethyl sulfoxide, we can isolate F1 containing only subunits alpha, beta, and gamma [F1(alpha beta gamma)] directly from membrane vesicles in 10-mg quantities. Pure and active subunits delta and epsilon were prepared from five-subunit F1 by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. After addition of these subunits, F1(alpha beta gamma) is as active in reconstituting ATP-dependent transhydrogenase as five-subunit F1. The ATPase activity of F1 (alpha beta gamma) is inhibited by subunit epsilon in a 1:1 stoichiometry to the same extent (approximately equal to 90%) and with the same affinity (Ki = 0.2-0.8 nM) as reported earlier [Dunn, S.D. (1982) J. Biol. Chem. 257, 7354-7359]. In the presence of either delta or epsilon, F1(alpha beta gamma) binds to F1-depleted membrane vesicles and to liposomes containing the membrane sector (F0) of the ATP synthase to an extent commensurate with the F0 content. The binding ratios epsilon/F1 (alpha beta gamma) and probably also delta/F1 (alpha beta gamma) are close to unity. The specific, delta- or epsilon-deficient F1.F0 complexes presumably formed show ATPase activities sensitive to subunit epsilon but not to dicyclohexylcarbodiimide, and no energy-transfer capabilities. Binding studies at different pH values suggest that F1-F0 interactions in the presence of both subunits delta and epsilon are similar to a combination of those mediated by delta or epsilon alone.(ABSTRACT TRUNCATED AT 250 WORDS)     

Activation and inhibition of the Escherichia coli F1-ATPase by monoclonal antibodies which recognize the epsilon subunit

The properties of two monoclonal antibodies which recognize the epsilon subunit of Escherichia coli F1-ATPase were studied in detail. The epsilon subunit is a tightly bound but dissociable inhibitor of the ATPase activity of soluble F1-ATPase. Antibody epsilon-1 binds free epsilon with a dissociation constant of 2.4 nM but cannot bind epsilon when it is associated with F1-ATPase. Likewise epsilon cannot associate with F1-ATPase in the presence of high concentrations of epsilon-1. Thus epsilon-1 activates F1-ATPase which contains the epsilon subunit, and prevents added epsilon from inhibiting the enzyme. Epsilon-1 cannot bind to membrane-bound F1-ATPase. The epsilon-4 antibody binds free epsilon with a dissociation constant of 26 nM. Epsilon-4 can bind to the F1-ATPase complex, but, like epsilon-1, it reverses the inhibition of F1-ATPase by the epsilon subunit. The epsilon subunit remains crosslinkable to both the beta and gamma subunits in the presence of epsilon-4, indicating that it is not grossly displaced from its normal position by the antibody. Presumably the activation arises from more subtle conformational effects. Antibodies epsilon-4 and delta-2, which recognizes the delta subunit, both bind to F1F0 in E. coli membrane vesicles, indicating that these subunits are substantially exposed in the membrane-bound complex. Epsilon-4 inhibits the ATPase activity of the membrane-bound enzyme by about 50%, and Fab prepared from epsilon-4 inhibits by about 40%. This inhibition is not associated with any substantial change in the major apparent Km for ATP. These results suggest that inhibition of membrane-bound F1-ATPase arises from steric effects of the antibody.     

Identification of the subunits of F1F0-ATPase from bovine heart mitochondria.

An oligomycin-sensitive F1F0-ATPase isolated from bovine heart mitochondria has been reconstituted into phospholipid vesicles and pumps protons. this preparation of F1F0-ATPase contains 14 different polypeptides that are resolved by polyacrylamide gel electrophoresis under denaturing conditions, and so it is more complex than bacterial and chloroplast enzymes, which have eight or nine different subunits. The 14 bovine subunits have been characterized by protein sequence analysis. They have been fractionated on polyacrylamide gels and transferred to poly(vinylidene difluoride) membranes, and N-terminal sequences have been determined in nine of them. By comparison with known sequences, eight of these have been identified as subunits beta, gamma, delta, and epsilon, which together with the alpha subunit form the F1 domain, as the b and c (or DCCD-reactive) subunits, both components of the membrane sector of the enzyme, and as the oligomycin sensitivity conferral protein (OSCP) and factor 6 (F6), both of which are required for attachment of F1 to the membrane sector. The sequence of the ninth, named subunit e, has been determined and is not related to any reported protein sequence. The N-terminal sequence of a tenth subunit, the membrane component A6L, could be determined after a mild acid treatment to remove an alpha-N-formyl group. Similar experiments with another membrane component, the a or ATPase-6 subunit, caused the protein to degrade, but the protein has been isolated from the enzyme complex and its position on gels has been unambiguously assigned. No N-terminal sequence could be derived from three other proteins. The largest of these is the alpha subunit, which previously has been shown to have pyrrolidonecarboxylic acid at the N terminus of the majority of its chains. The other two have been isolated from the enzyme complex; one of them is the membrane-associated protein, subunit d, which has an alpha-N-acetyl group, and the second, surprisingly, is the ATPase inhibitor protein. When it is isolated directly from mitochondrial membranes, the inhibitor protein has a frayed N terminus, with chains starting at residues 1, 2, and 3, but when it is isolated from the purified enzyme complex, its chains are not frayed and the N terminus is modified. Previously, the sequences at the N terminals of the alpha, beta, and delta subunits isolated from F1-ATPase had been shown to be frayed also, but in the F1F0 complex they each have unique N-terminal sequences.(ABSTRACT TRUNCATED AT 400 WORDS)     

Primary structure and subunit stoichiometry of F1-ATPase from bovine mitochondria

The enzyme complex F1-ATPase has been isolated from bovine heart mitochondria by gel filtration of the enzyme released by chloroform from sub-mitochondrial particles. The five individual subunits alpha, beta, gamma, delta and epsilon that comprise the complex have been purified from it, and their amino acid sequences determined almost entirely by direct protein sequence analysis. A single overlap in the gamma-subunit was obtained by DNA sequence analysis of a complementary DNA clone isolated from a bovine cDNA library using a mixture of 32 oligonucleotides as the hybridization probe. The alpha, beta, gamma, delta and epsilon subunits contain 509, 480, 272, 146 and 50 amino acids, respectively. Two half cystine residues are present in the alpha-subunit and one in each of the gamma- and epsilon-chains; they are absent from the beta- and delta-subunits. The stoichiometry of subunits in the complex is estimated to be alpha 3 beta 3 gamma 1 delta 1 epsilon 1 and the molecular weight of the complex is 371,135. Mild trypsinolysis of the F1-ATPase complex, which has little effect on the hydrolytic activity of the enzyme, releases peptides from the N-terminal regions of the alpha- and beta-chains only; the C-terminal regions are unaffected. Sequence analysis of the released peptides demonstrates that the N terminals of the alpha- and beta-chains are ragged. In 65% of alpha-chains, the terminus is pyrrolidone carboxylic acid; in the remainder this residue is absent and the chains commence at residue 2, i.e. lysine. In the beta-subunit a minority of chains (16%) have N-terminal glutamine, or its deamidation product, glutamic acid (6%), or the cyclized derivative, pyrrolidone carboxylic acid (5%). A further 28% commence at residue 2, alanine, and 45% at residue 3, serine. The delta-chains also are heterogeneous; in 50% of chains the N-terminal alanine residue is absent. The sequences of the alpha- and beta-chains show that they are weakly homologous, as they are in bacterial F1-ATPases. The sequence of the bovine delta-subunit of F1-ATPase shows that it is the counterpart of the bacterial epsilon-subunit. The bovine epsilon-subunit is not related to any known bacterial or chloroplast H+-ATPase subunit, nor to any other known sequence. The counterpart of the bacterial delta-subunit is bovine oligomycin sensitivity conferral protein, which helps to bind F1 to the inner mitochondrial membrane.(ABSTRACT TRUNCATED AT 400 WORDS)     

Membrane ATPase of Vibrio alginolyticus. Ion transport activity and homology with F0F1-ATPase from E. coli]

F0F1-ATPase has been isolated from the marine alkali-resistant bacterium Vibrio alginolyticus. The enzyme subunits cross-reacted with antibodies against subunits alpha, beta, gamma, epsilon, and b of E. coli ATPase. The purified ATPase was reconstituted into liposomes effecting an ATP-dependent uptake of H+. Proton transport was inhibited by the ATPase blockers DCCD, triphenyltin, and venturicidin. Na+ ions had no effect on ATP-dependent proton transport. No ATP-dependent transport of Na+ was detected in proteoliposomes.     

Intrinsic tryptophan fluorescence of Schizosaccharomyces pombe mitochondrial F1-ATPase. A powerful probe for phosphate and nucleotide interactions

Mitochondrial F1 from the yeast Schizosaccharomyces pombe, in contrast to the mammalian enzyme, exhibits a characteristic intrinsic tryptophan fluorescence with a maximal excitation at 291 nm and a maximal emission at 332 nm. Low values of Stern-Volmer quenching constants, 4.0 M-1 or 1.8 M-1, respectively, in the presence of either acrylamide or iodide, indicate that tryptophans are mainly buried inside the native enzyme. Upon subunit dissociation and unfolding by 6 M guanidine hydrochloride (Gdn.HCl), the maximal emission is shifted to 354 nm, a value very similar to that obtained with N-acetyltryptophanamide, a solute-tryptophan model compound. The tryptophan content of each isolated subunit has been estimated by fluorescence titration in the presence of Gdn.HCl with free tryptophan as a standard. Two tryptophans and one tryptophan are found respectively in the alpha and epsilon subunits, whereas none is detected in the beta, gamma, and delta subunits. These subunit contents are consistent with the total of seven tryptophans estimated for native F1 with alpha 3 beta 3 gamma 1 delta 1 epsilon 1 stoichiometry. The maximal emission of the isolated epsilon subunit is markedly blue-shifted to 310-312 nm by interaction with the isolated delta subunit, which suggests that the epsilon subunit tryptophan might be a very minor contributor to the native F1 fluorescence measured at 332 nm. This fluorescence is very sensitive to phosphate, which produces a marked blue shift indicative of tryptophans in a more hydrophobic environment. On the other hand, ADP and ATP quench the maximal emission at 332 nm, lower tryptophan accessibility to acrylamide, and reveal tryptophan heterogeneity.     

Added subunit beta of CF1 as well as gamma/delta/epsilon restore photophosphorylation in partially CF1-depleted thylakoids.

We investigated the ability of subunits beta, gamma, delta, and epsilon of CF1, the F1-ATPase of chloroplasts, to interact with exposed CF0 in EDTA-treated, partially CF1-depleted thylakoid membranes. We measured the ability of subunits beta, gamma, delta, and epsilon to stimulate the rate of photophosphorylation under continuous light and, for subunit beta, also the ability to diminish the proton leakage through exposed CF0 by deceleration of the decay of electrochromic absorption transients under flashing light. The greatest effect was caused by subunit beta, followed by gamma/delta/epsilon. Pairwise combinations of gamma, delta, and epsilon or each of these subunits alone were only marginally effective. Subunit gamma from the thermophilic bacterium PS 3 in combination with chloroplast delta and epsilon was as effective as chloroplast gamma. The finding that the small CF1 subunits in concert and the beta subunit by itself specifically interacted with the exposed proton channel CF0, qualifies the previous concept of subunit delta acting particularly as a plug to the open CF0 channel. The interactions between the channel and the catalytic portion of the enzyme seem to involve most of the small, and at least beta of the large subunits.     

Structural aspects of proton-pumping ATPases

ATP synthase is found in bacteria, chloroplasts and mitochondria. The simplest known example of such an enzyme is that in the eubacterium Escherichia coli; it is a membrane-bound assembly of eight different polypeptides assembled with a stoichiometry of alpha 3 beta 3 gamma 1 delta 1 epsilon 1 a1b2c10-12. The first five of these constitute a globular structure, F1-ATPase, which is bound to an intrinsic membrane domain, F0, an assembly of the three remaining subunits. ATP synthases driven by photosynthesis are slightly more complex. In chloroplasts, and probably in photosynthetic bacteria, they have nine subunits, all homologues of the components of the E. coli enzyme; the additional subunit is a duplicated and diverged relation of subunit b. The mammalian mitochondrial enzyme is more complex. It contains 14 different polypeptides, of which 13 have been characterized. Two membrane components, a (or ATPase-6) and A6L, are encoded in the mitochondrial genome in overlapping genes and the remaining subunits are nuclear gene products that are translated on cytoplasmic ribosomes and then imported into the organelle. The sequence of the proteins of ATP-synthase have provided information about amino acids that are important for its function. For example, amino acids contributing to nucleotide binding sites have been identified. Also, they provide the basis of models of secondary structure of membrane components that constitute the transmembrane proton channel. An understanding of the coupling of the transmembrane potential gradient for protons, delta mu H+, to ATP synthesis will probably require the determination of the structure of the entire membrane bound complex. Crystals have been obtained of the globular domain, F1-ATPase. They diffract to a resolution of 3-4 A and data collection is in progress. As a preliminary step towards crystallization of the entire complex, we have purified it from bovine mitochondria and reconstituted it into phospholipid vesicles.     

Resolution and reconstitution of H+ -ATPase complex from beef heart mitochondria

Mitochondrial H+ -ATPase complex, purified by the lysolecithin extraction procedure, has been resolved into a "membrane" (NaBr-F0) and a "soluble" fraction by treatment with 3.5 M sodium bromide. The NaBr-F0 fraction is completely devoid of beta, delta, and epsilon subunits of the F, ATPase and largely devoid of alpha and gamma subunits of F1, where F0 is used to denote the membrane fraction and F1, coupling factor 1. This is confirmed by complete loss of ATPase and Pi-ATP exchange activities. The addition of F1 (400 micrograms X mg-1 F0) results in complete restoration of oligomycin sensitivity without any reduction in the F1-ATPase activity. Presumably, this is due to release of ATPase inhibitor protein from the F1-F0 complex consequent to sodium bromide extraction. Restoration of Pi-ATP exchange and H+ -pumping activities require coupling factor B in addition to F1-ATPase. The oligomycin-sensitive ATPase and 32Pi-ATP exchange activities in reconstituted F1-F0 have the same sensitivity to uncouplers and energy transfer inhibitors as in starting submitochondrial particles from the heavy layer of mitochondria and F1-F0 complex. The data suggest that the altered properties of NaBr-F0 observed in other laboratories are probably inherent to their F1-F0 preparations rather than to sodium bromide treatment itself. The H+ -ATPase (F1-F0) complex of all known prokaryotic (3, 8, 9, 10, 21, 32, 34) and eukaryotic (11, 26, 30, 33, 35-37) phosphorylating membranes contain two functionally and structurally distinct entities. The hydrophilic component F1, composed of five unlike subunits, shows ATPase activity that is cold labile as well as uncoupler- and oligomycin-insensitive. The membrane-bound hydrophobic component F0, having no energy-linked catalytic activity of its own, is indirectly assayed by its ability to regain oligomycin sensitive ATPase and Pi-ATP exchange activities on binding to F1-ATPase (33). The purest preparations of bovine heart mitochondrial F0 show seven or eight major components in polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate or SDS-PAGE (1, 2, 12, 14), ranging from 6 to 54 ku in molecular weight (12). The precise structure and polypeptide composition of mitochondrial F0 is not known. The F0 preparations from bovine heart reported so far have been derived from H+ -ATPase preparations isolated in the presence of cholate and deoxycholate (11, 33, 36, 37).(ABSTRACT TRUNCATED AT 400 WORDS)     

The F1-ATPase from Streptococcus cremoris: isolation, purification and partial characterization

1. The F1-ATPase from the plasma membrane of Streptococcus cremoris HA was released by low ionic shock wash and purified by gel filtration and ion exchange chromatography. 2. The specific activity of the purified F1-ATPase was 25.8 mumol Pi/mg protein/min. 3. Km for ATP was 0.80 mM, and Ki for ADP as a competetive inhibitor 0.40 mM. 4. The purified F1-ATPase consisted of five subunits, alpha, beta, gamma, delta and epsilon, with molecular masses of 47.0, 45.0, 29.5, 22.0 and 13.0 kDa, respectively. 5. The isoelectric point of the enzyme complex was found to be 4.4.     

High performance liquid chromatography purification and amino terminal sequence analysis of the subunits of bovine heart mitochondrial F1-ATPase

All five subunits of bovine heart mitochondrial F1-ATPase have been isolated by reverse-phase HPLC and NH2-terminal sequences determined by gas phase Edman degradations. Bovine gamma exhibits 16 identities in the first 30 residues compared with the NH2-terminus of gamma from E.coli F1. Bovine delta exhibit about 27% identity with residues 28-59 of precursor delta from N.crassa and in the first six residues is identical with delta from S.cerevisiae. Approximately half of bovine epsilon has been sequenced. Possibly significant sequence similarities exist between bovine gamma and epsilon and kinase-related gene and oncogene products. The bovine alpha subunit has a blocked NH2-terminus.     

A fraction of CD3 epsilon subunits exists as disulfide-linked dimers in both human and murine T lymphocytes

In a T cell antigen receptor complex (TCR), the clonotypic disulfide-linked Ti heterodimer is noncovalently associated with the invariant CD3 polypeptides. The latter are composed of three monomeric subunits (gamma, delta, epsilon) and either a disulfide-linked homodimer (zeta zeta) or a disulfide-linked heterodimer (zeta eta). The exact stoichiometry of the Ti-CD3 subunits in a given complex is still largely unknown. Here, we report the presence of a CD3 epsilon dimer in a fraction of the TCR. When TCRs from both human and murine T lymphocytes were immunoprecipitated with monoclonal antibodies against either CD3 epsilon or Ti, a 40-kDa disulfide-linked dimer was coprecipitated with the other TCR subunits from digitonin lysates. Amino acid sequence analysis of peptides obtained by in situ CNBr cleavage of the 20-kDa product blotted to polyvinyl difluoride membranes from reducing/nonreducing two-dimensional gels identified human CD3 epsilon. Assuming this CD3 epsilon to derive from a homodimer, then either some TCRs contain more than one CD3 epsilon chain or several TCRs are covalently associated with one another via their CD3 epsilon subunits. Although it has been suggested that a putative TCR association with CD2 exists under similar conditions to those utilized to detect CD3 epsilon dimers, the CD2 molecule was not coimmunoprecipitated with the TCR by any of a series of anti-CD3 epsilon monoclonal antibodies. In conjunction with the fact that CD2 and the TCR do not colocalize during conjugate formation between T cells and antigen-presenting cells (Koyasu, S., Lawton, T., Novick, D., Recny, M. A., Siliciano, R. F., Wallner, B. P., and Reinherz, E. L. (1990) Proc. Natl. Acad. Sci. U. S. A. 87, 2603-2607), we conclude that CD2 and the TCR are not physically associated on the T cell surface.     

Modification of the T cell antigen receptor (TCR) complex by UDP-glucose:glycoprotein glucosyltransferase. TCR folding is finalized convergent with formation of alpha beta delta epsilon gamma epsilon complexes.

Most T lymphocytes express on their surfaces a multisubunit receptor complex, the T cell antigen receptor (TCR) containing alpha, beta, gamma, delta, epsilon, and zeta molecules, that has been widely studied as a model system for protein quality control. Although the parameters of TCR assembly are relatively well established, little information exists regarding the stage(s) of TCR oligomerization where folding of TCR proteins is completed. Here we evaluated the modification of TCR glycoproteins by the endoplasmic reticulum folding sensor enzyme UDP-glucose:glycoprotein glucosyltransferase (GT) as a unique and sensitive indicator of how TCR subunits assembled into multisubunit complexes are perceived by the endoplasmic reticulum quality control system. These results demonstrate that all TCR subunits containing N-glycans were modified by GT and that TCR proteins were differentially reglucosylated during their assembly with partner TCR chains. Importantly, these data show that GT modification of most TCR subunits persisted until assembly of CD3alpha beta chains and formation of CD3-associated, disulfide-linked alpha beta heterodimers. These studies provide a novel evaluation of the folding status of TCR glycoproteins during their assembly into multisubunit complexes and are consistent with the concept that TCR folding is finalized convergent with formation of alpha beta delta epsilon gamma epsilon complexes.     

The quaternary structure of DNA polymerase epsilon from Saccharomyces cerevisiae

DNA polymerase epsilon (Pol epsilon) from Saccharomyces cerevisiae consists of four subunits (Pol2, Dpb2, Dpb3, and Dpb4) and is essential for chromosomal DNA replication. Biochemical characterizations of Pol epsilon have been cumbersome due to protease sensitivity and the limited amounts of Pol epsilon in cells. We have developed a protocol for overexpression and purification of Pol epsilon from S. cerevisiae. The native four-subunit complex was purified to homogeneity by conventional chromatography. Pol epsilon was characterized biochemically by sedimentation velocity experiments and gel filtration experiments. The stoichiometry of the four subunits was estimated to be 1:1:1:1 from colloidal Coomassie-stained gels. Based on the sedimentation coefficient (11.9 S) and the Stokes radius (74.5 A), a molecular mass for Pol epsilon of 371 kDa was calculated, in good agreement with the calculated molecular mass of 379 kDa for a heterotetramer. Furthermore, analytical equilibrium ultracentrifugation experiments support the proposed heterotetrameric structure of Pol epsilon. Thus, both DNA polymerase delta and Pol epsilon are purified as monomeric complexes, in agreement with accumulating evidence that Pol delta and Pol epsilon are located on opposite strands of the eukaryotic replication fork.