Biogenesis of functional antigenic peptide transporter TAP requires assembly of pre-existing TAP1 with newly synthesized TAP2

The transporter associated with antigen processing (TAP) is essential for the delivery of antigenic peptides from the cytosol into the endoplasmic reticulum (ER), where they are loaded onto major histocompatibility complex class I molecules. TAP is a heterodimeric transmembrane protein that comprises the homologous subunits TAP1 and TAP2. As for many other oligomeric protein complexes, which are synthesized in the ER, the process of subunit assembly is essential for TAP to attain a native functional state. Here, we have analyzed the individual requirements of TAP1 and TAP2 for the formation of a functional TAP complex. Unlike TAP1, TAP2 is very unstable when expressed in isolation. We show that heterodimerization of TAP subunits is required for maintaining a stable level of TAP2. By using an in vitro expression system we demonstrate that the biogenesis of functional TAP depends on the assembly of preexisting TAP1 with newly synthesized TAP2, but not vice versa. The pore forming core transmembrane domain (core TMD) of in vitro expressed TAP2 is necessary and sufficient to allow functional complex formation with pre-existing TAP1. We propose that the observed assembly mechanism of TAP protects newly synthesized TAP2 from rapid degradation and controls the number of transport active transporter molecules. Our findings open up new possibilities to investigate functional and structural properties of TAP and provide a powerful model system to address the biosynthetic assembly of oligomeric transmembrane proteins in the ER.     

The relationship between molecular weight and quaternary structure of globular proteins

The relationship between the molecular weight and the number of subunits in oligomeric globular proteins consisting of identical subunits has been analyzed. It has been shown that the molecular weights of the subunits are distributed about a mean value of 48,000 and consequently that the molecular weights of the native oligomeric proteins are distributed in clearly distinguishable molecular weight regions. This observation allows the probability of a particular oligomeric structure to be predicted from a measurement of the oligomer molecular weight alone, which is useful in a number of types of study of protein structure, particularly comparative studies. Calculations have been performed which suggest that there is no thermodynamic limitation, in terms of the subunit interactions themselves, to the size of an oligomeric protein with a given number of subunits. Rather, an individual polypeptide chain itself has inherent size limitations, which consequently limits the molecular weight of the corresponding oligomer.     

Radiation-target molecular weights of urease and of l-glutamate dehydrogenase and their relevance to the size of the functional subunits

Activities of the oligomeric enzymes urease and l-glutamate dehydrogenase were measured after exposure as dry preparations to various doses of electron radiation. Inactivation curves were exponential. `Target sizes' deduced from these were small compared with the molecular weights of the whole enzyme molecules, but accorded well with independent estimates of the sizes of functional subunits. It was concluded that, when these were in associated from, there could be no transfer of absorbed energy between subunits.     

Fucoxanthin-chlorophyll proteins in diatoms: 18 and 19 kDa subunits assemble into different oligomeric states

Fucoxanthin-chlorophyll proteins were purified from the centric diatom Cyclotella meneghiniana. Two major fractions were observed that differed in their polypeptide composition and oligomeric state. Trimers consist of mainly 18 kDa polypeptides. Higher oligomers are tightly assembled from different trimers, which contain mostly 19 kDa subunits. In both oligomeric states, the excitation energy coupling between fucoxanthin and chlorophyll a was preserved, and chlorophyll c was shown to transfer energy efficiently to chlorophyll a. Circular dichroism spectra showed close interaction between fucoxanthin and chlorophyll a, and different chlorophyll a molecules were demonstrated to interact excitonically. The assembly of trimers of antenna proteins with a distinct subunit composition into higher oligomeric states was not reported so far and differs from the situation found in higher plants. The differences in the supramolecular structure of the fucoxanthin-chlorophyll proteins reflect the dissimilar arrangement of the thylakoid membranes in diatoms, which lack the grana-stroma distinction.     

Partial Purification and Characterization of the Vacuolar H+-ATPase of Mammalian Synaptic Vesicles

Several major proteins of synaptic vesicles from rat or cow brain sediment as a large complex on sucrose density gradients when solubilized in nonionic detergents. A vacuolar H(+)-ATPase identified by sensitivity to bafilomycin A1 appears to be associated with this oligomeric protein complex. Two subunits of this complex, synaptic vesicle proteins S and U, correspond to the 57-kDa (B) and 39-kDa accessory (Ac39) subunits, respectively, of bovine chromaffin granule vacuolar H(+)-ATPase as shown by Western immunoblot analysis. The five subunits of the oligomeric complex constitute approximately 20% of the total protein of rat brain synaptic vesicles. Taken together, these results strongly suggest that the abundant, multisubunit complex partially purified from brain synaptic vesicles by density gradient centrifugation is a vacuolar H(+)-ATPase. Bafilomycin A1 completely blocks proton pumping in rat brain synaptic vesicles as measured by [14C]methylamine uptake and also blocks catecholamine accumulation measured by [3H]dopamine uptake. Moreover, ATPase activity, [14C]methylamine uptake, and [3H]dopamine uptake are inhibited by bafilomycin A1 at similar I50 values of approximately 1.7 nmol/mg of protein. These findings indicate that the vacuolar H(+)-ATPase is essential for proton pumping as well as catecholamine uptake by mammalian synaptic vesicles.     

Large-scale analysis of the human ubiquitin-related proteome

Protein ubiquitylation contributes to the regulation of many cellular processes including protein degradation, receptor internalization, and repair of DNA damage. We now present a comprehensive characterization of ubiquitin-conjugated and ubiquitin-associated proteins in human cells. The proteins were purified by immunoaffinity chromatography under denaturing or native conditions. They were then digested with trypsin, and the resulting peptides were analyzed by 2-D LC and MS/MS. A total of 670 distinct proteins were identified; 345 proteins (51%) were classified as Urp-D (ubiquitin-related proteome under the denaturing condition) and comprised ubiquitin-conjugated molecules, whereas 325 proteins (49%) were classified as Urp-N (ubiquitin-related proteome only under the native condition) and included molecules that associated with ubiquitylated proteins. The proportions of proteins in various functional categories differed substantially between Urp-D and Urp-N. Many ribosomal subunits were detected in the Urp-D group of proteins and several of these subunits were directly shown to be ubiquitylated by mass spectrometric analysis, suggesting that ubiquitylation might play an important role in the regulation and/or quality control of ribosomal proteins. Our results demonstrate the potential of proteomics analysis of protein ubiquitylation to provide important insight into the regulation of protein stability and other ubiquitin-related cellular functions.     

Molecular organization of glutamate-sensitive chemoexcitatory membranes of nerve cells. Comparative analysis of glutamate-binding membrane proteins from the cerebral cortex of rats and humans

The kinetics of 3H-L-glutamate binding to human brain synaptic membranes revealed the existence of one type of binding sites with Kd and Vmax comparable with those for freshly isolated rat brain membranes. The fraction of glutamate-binding proteins (GBP) was shown to contain three components with Mr of 14, 60 and 280 kD whose stoichiometry is specific for human and rat brain. All fractions were found to bind the radiolabeled neurotransmitter and to dissociate into subunits with Mr of 14 kD after treatment with-potent detergents (with the exception of the 56-60 kD component). Study of association-dissociation of GBP protein subunits by high performance liquid chromatography confirmed the hypothesis on the oligomeric structure of glutamate receptors which are made up of low molecular weight glycoprotein-lipid subunits and which form ionic channels by way of repeated association. Despite the similarity of antigen determinants in the active center of glutamate receptors from human and rat brain, it was assumed that the stoichiometry of structural organization of receptor subunits isolated from different sources is different. The functional role of structural complexity of human brain glutamate receptors is discussed.     

Stereochemistry of oligomeric proteins

The subunits of many oligomeric proteins are organized into stable arrays with high symmetry. When these proteins interact with small molecules such as enzyme substrates or inhibitors, a variety of non-equivalent forms of the protein may be produced. Some of these forms have the same atomic composition, but differ in the spatial arrangement of the subunits. These species differ in all of their properties (conformation, affinity for substrate, etc.), and the relationships among them and among their subunits may be defined using stereochemical nomenclature which has been developed for small molecules. In many cases, the number of such forms is quite large. Rigorous, group-theoretical methods for enumerating all possible species are described and illustrated for the enzyme aspartate transcarbamoylase.     

A fluorescence energy transfer method for analyzing protein oligomeric structure: application to phospholamban

We have developed a method using fluorescence energy transfer (FET) to analyze protein oligomeric structure. Two populations of a protein are labeled with fluorescent donor and acceptor, respectively, then mixed at a defined donor/acceptor ratio. A theoretical simulation, assuming random mixing and association among protein subunits in a ring-shaped homo-oligomer, was used to determine the dependence of FET on the number of subunits, the distance between labeled sites on different subunits, and the fraction of subunits remaining monomeric. By measuring FET as a function of the donor/acceptor ratio, the above parameters of the oligomeric structure can be resolved over a substantial range of their values. We used this approach to investigate the oligomeric structure of phospholamban (PLB), a 52-amino acid protein in cardiac sarcoplasmic reticulum (SR). Phosphorylation of PLB regulates the SR Ca-ATPase. Because PLB exists primarily as a homopentamer on sodium dodecyl sulfate polyacrylamide gel electrophoresis, it has been proposed that the pentameric structure of PLB is important for its regulatory function. However, this hypothesis must be tested by determining directly the oligomeric structure of PLB in the lipid membrane. To accomplish this goal, PLB was labeled at Lys-3 in the cytoplasmic domain, with two different amine-reactive donor/acceptor pairs, which gave very similar FET results. In detergent solutions, FET was not observed unless the sample was first boiled to facilitate subunit mixing. In lipid bilayers, FET was observed at 25 degrees C without boiling, indicating a dynamic equilibrium among PLB subunits in the membrane. Analysis of the FET data indicated that the dye-labeled PLB is predominantly in oligomers having at least 8 subunits, that 7-23% of the PLB subunits are monomeric, and that the distance between dyes on adjacent PLB subunits is about 10 A. A point mutation of PLB (L37A) that runs as monomer on SDS-PAGE showed no energy transfer, confirming its monomeric state in the membrane. We conclude that FET is a powerful approach for analyzing the oligomeric structure of PLB, and this method is applicable to other oligomeric proteins.     

Comparison of the chemical and thermal denaturation of proteins by a two-state transition model

The conformational stabilities of eight proteins in terms of the free energy differences between the native "folded" state of the protein and its "unfolded" state were determined at 298 K by two methods: chemical denaturation at 298 K and extrapolation to 298 K of the thermal denaturation results at high temperature. The proteins were expressed in Escherichia coli from the Haemophilus influenzae and E. coli genes at different levels of expression, covered a molecular mass range from 13 to 37 kg mol(-1) per monomeric unit (some exhibiting unique structural features), and were oligomeric up to four subunits. The free energy differences were determined by application of a two-state transition model to the chemical and thermal denaturation results, ranged from 9.4 to 148 kJ mol(-1) at 298 K, and were found to be within the experimental uncertainties of both methods for all of the proteins. Any contributions from intermediate states detectable from chemical and thermal denaturation differences in the unfolding free energy differences in these proteins are within the experimental uncertainties of both methods.     

Dynamic nature of the quaternary structure of the vesicular stomatitis virus envelope glycoprotein

The envelope glycoprotein (G protein) of vesicular stomatitis virus probably exists in the viral envelope as a trimer of identical subunits. Depending on the conditions of solubilization, G protein may dissociate into monomers. G protein solubilized with the detergent octyl glucoside was shown to exist as oligomeric forms by sedimentation velocity analysis and chemical cross-linking. G protein was modified with either fluorescein isothiocyanate or rhodamine isothiocyanate. Resonance energy transfer between fluorescein and rhodamine labels was observed upon mixing the two labeled G proteins in octyl glucoside. This result provided further evidence that G protein in octyl glucoside is oligomeric and indicated that the subunits are capable of exchange to form mixed oligomers. Resonance energy transfer was independent of G protein concentration in the range examined (10-80 nM) and was not observed when labeled G proteins were mixed with fluorescein or rhodamine that was not conjugated to protein. Resonance energy transfer decreased upon incorporation of G protein into Triton X-100, consistent with sedimentation velocity data that G protein in Triton X-100 is primarily monomeric. Kinetic analysis showed that the subunit exchange reaction had a half-time of about 3 min at 27 degrees C that was independent of G protein concentration. These data indicate that the exchange occurs through dissociation of G protein trimers into monomers and dimers followed by reassociation into timers. Thus, in octyl glucoside, G protein must exist as an equilibrium between monomers and oligomers. This implies that monomers are capable of self-assembly into trimers.     

The Rubisco subunit binding protein

Chloroplasts contain an abundant soluble protein that binds non-covalently newly synthesized large and small subunits of the enzyme ribulose bisphosphate carboxylase-oxygenase. This binding protein has been purified from Pisum sativum and Hordeum vulgare in the form of a dodecamer consisting of equal amounts of two types of subunit. These subunits are synthesized as higher molecular mass precursors by cytoplasmic ribosomes before import into the chloroplast. Antibodies raised against the purified binding protein from Pisum sativum detect polypeptides not only in extracts of plastids from several plant species but also in cell extracts of several bacterial species. The oligomeric binding protein dissociates reversibly into monomeric subunits in the presence of 1–5 mmol/liter MgATP. For one type of subunit the cDNA sequence has been isolated and determined and reveals homology with certain bacterial proteins.These observations are discussed in relation to the idea that the binding protein is an example of a general class of proteins termed "molecular chaperones" which are required for the correct assembly of certain oligomeric proteins such as the carboxylase from their subunits.Abbreviations BP Binding protein - Rubisco Ribulose bisphosphate carboxylase-oxygenase     

From diversity of molecular forms to functional specialization of oligomeric proteins, nicotinic acetylcholine receptor, acetylcholinesterase and Na+, K+-ATPase

The review is devoted to the issue of diversity of molecular forms of oligomeric proteins using as examples members of the three protein classes: nicotinic acetylcholine receptor, acetylcholinesterase, and Na,K-ATPase. The data are presented on the molecular structure of proteins, subunit compositions, and isoforms of subunits, as well as on some features of gene expression. Particular emphasis has been made on the functional specialization of different molecular forms of one and the same oligomeric protein. The three above proteins, which serve seemingly quite different cellular processes, demonstrate many common principles of molecular mechanisms of physiological function.     

Surface recognition elements of membrane protein oligomerization

Although certain membrane proteins are functional as monomeric polypeptides, others must assemble into oligomers to carry out their biological roles. High-resolution membrane protein structures provide a valuable resource for examining the sequence features that facilitate-or preclude-assembly of membrane protein monomers into multimeric structures. Here we have utilized a data set of 28 high-resolution alpha-helical membrane protein structures comprising 32 nonredundant polypeptides to address this issue. The lipid-exposed surfaces of membrane proteins that have reached their fully assembled and functional biological units have been compared with those of the individual subunits that build quaternary structures. Though the overall amino acid composition of each set of surfaces is similar, a key distinction-the distribution of small-xxx-small motifs-delineates subunits from membrane proteins that have reached a functioning oligomeric state. Quaternary structure formation may therefore be dictated by small-xxx-small motifs that are not satisfied by intrachain contacts.     

A novel induced-fit reaction mechanism of asymmetric hot dog thioesterase PAAI

Hot dog fold proteins sharing the characteristic "hot dog" fold are known to involve certain coenzyme A binding enzymes with various oligomeric states. In order to elucidate the oligomerization-function relationship of the hot dog fold proteins, crystal structures of the phenylacetate degradation protein PaaI from Thermus thermophilus HB8 (TtPaaI), a tetrameric acyl-CoA thioesterase with the hot dog fold, have been determined and compared with those of other family members. In the liganded crystal forms with coenzyme A derivatives, only two of four intersubunit catalytic pockets of the TtPaaI tetramer are occupied by the ligands. A detailed structural comparison between several liganded and unliganded forms reveals that a subtle rigid-body rearrangement of subunits within 2 degrees upon binding of the first two ligand molecules can induce a strict negative cooperativity to prevent further binding at the remaining two pockets, indicating that the so-called "half-of-the-sites reactivity" of oligomeric enzymes is visualized for the first time. Considering kinetic and mutational analyses together, a possible reaction mechanism of TtPaaI is proposed; one tetramer binds only two acyl-CoA molecules with a novel asymmetric induced-fit mechanism and carries out the hydrolysis according to a base-catalyzed reaction through activation of a water molecule by Asp48. From a structural comparison with other family members, it is concluded that a subgroup of the hot dog fold protein family, referred to as "asymmetric hot dog thioesterases" including medium chain acyl-CoA thioesterase II from Escherichia coli and human thioesterase III, might share the same oligomerization mode and the asymmetric induced-fit mechanism as observed in TtPaaI.     

Characterization of distinct early assembly units of different intermediate filament proteins

We have determined the mass-per-length (MPL) composition of distinct early assembly products of recombinant intermediate filament (IF) proteins from the four cytoplasmic sequence homology classes, and compared these values with those of the corresponding mature filaments. After two seconds under standard assembly conditions (i.e. 25 mM Tris-HCl (pH 7.5), 50 mM NaCl, 37 degrees C), vimentin, desmin and the neurofilament triplet protein NF-L aggregated into similar types of "unit-length filaments" (ULFs), whereas cytokeratins (CKs) 8/18 already yielded long IFs at this time point, so the ionic strength had to be reduced. The number of molecules per filament cross-section, as deduced from the MPL values, was lowest for CK8/18, i.e. 16 and 25 at two seconds compared to 16 and 21 at one hour. NF-L exhibited corresponding values of 26 and 30. Vimentin ULFs yielded a pronounced heterogeneity, with major peak values of 32 and 45 at two seconds and 30, 37 and 44 after one hour. Desmin formed filaments of distinctly higher mass with 47 molecules per cross-section, at two seconds and after one hour of assembly. This indicates that individual types of IF proteins generate filaments with distinctly different numbers of molecules per cross-section. Also, the observed significant reduction of apparent filament diameter of ULFs compared to the corresponding mature IFs is the result of a "conservative" radial compaction-type reorganization within the filament, as concluded from the fact that both the immature and mature filaments contain very similar numbers of subunits per cross-section. Moreover, the MPL composition of filaments is strikingly dependent on the assembly conditions employed. For example, vimentin fibers formed in 0.7 mM phosphate (pH 7.5), 2.5 mM MgCl2, yield a significantly increased number of molecules per cross-section (56 and 84) compared to assembly under standard conditions. Temperature also strongly influences assembly: above a certain threshold temperature "pathological" ULFs form that are arrested in this state, indicating that the system is forced into strong but unproductive interactions between subunits. Similar "dead-end" structures were obtained with vimentins mutated to introduce principal alterations in subdomains presumed to be of general structural importance, indicating that these sequence changes led to new modes of intermolecular interactions.     

Oligomerization state influences the degradation rate of 3-hydroxy-3-methylglutaryl-CoA reductase.

The steady-state level of the resident endoplasmic reticulum protein, 3-hydroxy-3-methylglutaryl-coenzyme A reductase (HMGR), is regulated, in part, by accelerated degradation in response to excess sterols or mevalonate. Previous studies of a chimeric protein (HM-Gal) composed of the membrane domain of HMGR fused to Escherichia coli beta-galactosidase, as a replacement of the normal HMGR cytosolic domain, have shown that the regulated degradation of this chimeric protein, HM-Gal, is identical to that of HMGR (Chun, K. T., Bar-Nun, S., and Simoni, R. D. (1990) J. Biol. Chem. 265, 22004-22010; Skalnik, D. G., Narita, H., Kent, C., and Simoni, R. D. (1988) J. Biol. Chem. 263, 6836-6841). Since the cytosolic domain can be replaced with beta-galactosidase without effect on regulated degradation, it has been assumed that the cytosolic domain was not important to this process and also that the membrane domain of HMGR was both necessary and sufficient for regulated degradation. In contrast to our previous results with HM-Gal, we observed in this study that replacement of the cytosolic domain of HMGR with various heterologous proteins can have an effect on the regulated degradation, and the effect correlates with the oligomeric state of the replacement cytosolic protein. Chimeric proteins that are oligomeric in structure are relatively stable, and those that are monomeric are unstable. To test the hypothesis that the oligomeric state of the cytosolic domain of HMGR influences degradation, we use an "inducible" system for altering the oligomeric state of a protein in vivo. Using a chimeric protein that contains the membrane domain of HMGR fused to three copies of FK506-binding protein 12, we were able to induce oligomerization by addition of a "double-headed" FK506-like "dimerizer" drug (AP1510) and to monitor the degradation rate of both the monomeric form and the drug-induced oligomeric form of the protein. We show that this chimeric protein, HM-3FKBP, is unstable in the monomeric state and is stabilized by AP1510-induced oligomerization. We also examined the degradation rate of HMGR as a function of concentrations within the cell. HMGR is a functional dimer; therefore, its oligomeric state and, we predict, its degradation rate should be concentration-dependent. We observed that it is degraded more rapidly at lower concentrations.     

OCAM: a new tool for studying the oligomeric diversity of MscL channels

We have developed a new technique to study the oligomeric state of proteins in solution. OCAM or Oligomer Characterization by Addition of Mass counts protein subunits by selectively shaving a protein mass tag added to a protein subunit via a short peptide linker. Cleavage of each mass tag reduces the total mass of the protein complex by a fixed amount. By performing limited proteolysis and separating the reaction products by size on a blue native PAGE gel, a ladder of reaction products corresponding to the number of subunits can be resolved. The pattern of bands may be used to distinguish the presence of a single homo-oligomer from a mixture of oligomeric states. We have applied OCAM to study the mechanosensitive channel of large conductance (MscL) and find that these proteins can exist in multiple oligomeric states ranging from tetramers up to possible hexamers. Our results demonstrate the existence of oligomeric forms of MscL not yet observed by X-ray crystallography or other techniques and that in some cases a single type of MscL subunit can assemble as a mixture of oligomeric states.     

Bacterioferritin from Mycobacterium smegmatis contains zinc in its di-nuclear site

Bacterioferritins, also known as cytochrome b (1), are oligomeric iron-storage proteins consisting of 24 identical amino acid chains, which form spherical particles consisting of 24 subunits and exhibiting 432 point-group symmetry. They contain one haem b molecule at the interface between two subunits and a di-nuclear metal binding center. The X-ray structure of bacterioferritin from Mycobacterium smegmatis (Ms-Bfr) was determined to a resolution of 2.7 A in the monoclinic space group C2. The asymmetric unit of the crystals contains 12 protein molecules: five dimers and two half-dimers located along the crystallographic twofold axis. Unexpectedly, the di-nuclear metal binding center contains zinc ions instead of the typically observed iron ions in other bacterioferritins.     

Phosphate-starvation-induced outer membrane proteins of members of the families Enterobacteriaceae and Pseudomonodaceae: demonstration of immunological cross-reactivity with an antiserum specific for porin protein P of Pseudomonas aeruginosa

Bacteria from members of the families Enterobacteriaceae and Pseudomonadaceae were grown under phosphate-deficient (0.1 to 0.2 mM Pi) conditions and examined for the production of novel membrane proteins. Of the 17 strains examined, 12 expressed a phosphate-starvation-induced outer membrane protein which was heat modifiable in that after solubilization in sodium dodecyl sulfate at low temperature the protein ran on gels as a diffuse band of higher apparent molecular weight, presumably an oligomer form, which shifted to an apparent monomer form after solubilization at high temperature. These proteins fell into two classes based on their monomer molecular weights and the detergent conditions required to release the proteins from the peptidoglycan. The first class, expressed by species of the Pseudomonas fluorescens branch of the family Pseudomonadaceae, was similar to the phosphate-starvation-inducible, channel-forming protein P of Pseudomonas aeruginosa. The second class resembled the major enterobacterial porin proteins and the phosphate-regulated PhoE protein of Escherichia coli. Using a protein P-trimer-specific polyclonal antiserum, we were able to demonstrate cross-reactivity of the oligomeric forms of both classes of these proteins on Western blots. However, this antiserum did not react with the monomeric forms of any of these proteins, including protein P monomers. With a protein P-monomer-specific antiserum, no reactivity was seen with any of the phosphate-starvation-inducible membrane proteins (in either oligomeric or monomeric form), with the exception of protein P monomers. These results suggest the presence of conserved antigenic determinants only in the native, functional proteins.