Characterization of the subunit structure of the catalytically active type I iodothyronine deiodinase

Type I iodothyronine deiodinase is a approximately 50-kDa, integral membrane protein that catalyzes the outer ring deiodination of thyroxine. Despite the identification and cloning of a 27-kDa selenoprotein with the catalytic properties of the type I enzyme, the composition and the physical nature of the active deiodinase are unknown. In this report, we use a molecular approach to determine holoenzyme composition, the role of the membrane anchor on enzyme assembly, and the contribution of individual 27-kDa subunits to catalysis. Overexpression of an immunologically unique rat 27-kDa protein in LLC-PK1 cells that contain abundant catalytically active 27-kDa selenoprotein decreased deiodination by approximately 50%, and > 95% of the LLC-PK1 derived 27-kDa selenoprotein was specifically immune precipitated by the anti-rat enzyme antibody. The hybrid enzyme had a molecular mass of 54 kDa and an s(20,w) of approximately 3.5 S indicating that every native 27-kDa selenoprotein partnered with an inert rat 27-kDa subunit in a homodimer. Enzyme assembly did not depend on the presence of the N-terminal membrane anchor of the 27-kDa subunit. Direct visualization of the deiodinase dimer showed that the holoenzyme was sorted to the basolateral plasma membrane of the renal epithelial cell.     

Electron transfer from menaquinol to fumarate. Fumarate reductase anchor polypeptide mutants of Escherichia coli

Fumarate reductase (FRD) of Escherichia coli is a four-subunit membrane-bound complex that is synthesized during anaerobic growth when fumarate is available as a terminal oxidant. The two subunits that comprise the catalytic domain, FrdA and FrdB, are anchored to the cytoplasmic membrane surface by two small hydrophobic polypeptides, FrdC and FrdD, which are also required for the enzyme to interact with quinone. To better define the individual roles of the FrdC and FrdD polypeptides in FRD complex formation and quinone binding, we selectively mutagenized the frdCD genes. Frd- strains were identified by their inability to grow on restrictive media, and the resulting mutant FRD complexes were isolated and biochemically characterized. The majority of the frdC and frdD mutations were identified as single base deletions that caused premature termination in either FrdC or FrdD and resulted in the loss of one or more of the predicted transmembrane helices. Two additional frdC mutants were characterized that contained single base changes resulting in single amino acid substitutions. All mutant enzyme complexes were incapable of oxidizing the physiological electron donor, menaquinol-6, in the presence of fumarate. Additionally, the ability of the mutant complexes to oxidize reduced benzyl viologen or reduce the ubiquinone analogue 2,3-dimethoxy-5-methyl-6-pentyl-1,4-benzoquinone and phenazine methosulfate with succinate as electron donor were also affected but to varying degrees. The separation of oxidative and reductive activities with quinones suggests there are two quinone binding sites in the fumarate reductase complex and that electron transfer occurs in two le- steps carried out at these separate sites.     

CRIF1 Is Essential for the Synthesis and Insertion of Oxidative Phosphorylation Polypeptides in the Mammalian Mitochondrial Membrane

Although substantial progress has been made in understanding the mechanisms underlying the expression of mtDNA-encoded polypeptides, the regulatory factors involved in mitoribosome-mediated synthesis and simultaneous insertion of mitochondrial oxidative phosphorylation (OXPHOS) polypeptides into the inner membrane of mitochondria are still unclear. In the present study, disruption of the mouse Crif1 gene, which encodes a mitochondrial protein, resulted in a profound deficiency in OXPHOS caused by the disappearance of OXPHOS subunits and complexes in?vivo. CRIF1 was associated with large mitoribosomal subunits that were located close to the polypeptide exit tunnel, and the elimination of CRIF1 led to both aberrant synthesis and defective insertion of mtDNA-encoded nascent OXPHOS polypeptides into the inner membrane. CRIF1 interacted with nascent OXPHOS polypeptides and molecular chaperones, e.g., Tid1. Taken together, these results suggest that CRIF1 plays a critical role in the integration of OXPHOS polypeptides into the mitochondrial membrane in mammals.     

Assembly of mitochondrial cytochrome c-oxidase, a complicated and highly regulated cellular process

Cytochrome c-oxidase (COX), the terminal enzyme of the mitochondrial respiratory chain, plays a key role in the regulation of aerobic production of energy. Biogenesis of eukaryotic COX involves the coordinated action of two genomes. Three mitochondrial DNA-encoded subunits form the catalytic core of the enzyme, which contains metal prosthetic groups. Another 10 subunits encoded in the nuclear DNA act as a protective shield surrounding the core. COX biogenesis requires the assistance of >20 additional nuclear-encoded factors acting at all levels of the process. Expression of the mitochondrial-encoded subunits, expression and import of the nuclear-encoded subunits, insertion of the structural subunits into the mitochondrial inner membrane, addition of prosthetic groups, assembly of the holoenzyme, further maturation to form a dimer, and additional assembly into supercomplexes are all tightly regulated processes in a nuclear-mitochondrial-coordinated fashion. Such regulation ensures the building of a highly efficient machine able to catalyze the safe transfer of electrons from cytochrome c to molecular oxygen and ultimately facilitate the aerobic production of ATP. In this review, we will focus on describing and analyzing the present knowledge about the different regulatory checkpoints in COX assembly and the dynamic relationships between the different factors involved in the process. We have used information mostly obtained from the suitable yeast model, but also from bacterial and animal systems, by means of large-scale genetic, molecular biology, and physiological approaches and by integrating information concerning individual elements into a cellular system network.     

Both hydrophobic domains of M13 procoat are required to initiate membrane insertion.

M13 procoat protein has two hydrophobic domains, one in the leader peptide and one which anchors the mature coat protein in the membrane. Disruption of the membrane anchor region by insertion of arginyl residues does not yield periplasmic coat protein. Instead, the rate of membrane assembly is slowed greater than 100-fold (t1/2 less than 5 s for wild-type, t1/2 greater than 10 min for mutant). The hydrophobic region of mature coat protein not only functions as a membrane anchor, but has an important role in the membrane assembly process per se.     

Synthesis and assembly of large subunits into ribulose bisphosphate carboxylase/oxygenase in chloroplast extracts

We have developed a new system for the in vitro synthesis of large subunits and their assembly into ribulose bisphosphate carboxylase oxygenase (Rubisco) holoenzyme in extracts of higher plant chloroplasts. This differs from previously described Rubisco assembly systems because the translation of the large subunits occurs in chloroplast extracts as opposed to isolated intact chloroplasts, and the subsequent assembly of large subunits into holoenzyme is completely dependent upon added small subunits. Amino acid incorporation in this system displayed the characteristics previously reported for chloroplast-based translation systems. Incorporation was sensitive to chloramphenicol or RNase but resistant to cycloheximide, required magnesium, and was stimulated by nucleotides. The primary product of this system was the large subunit of Rubisco. However, several lower molecular weight polypeptides were formed. These were structurally related to the Rubisco large subunit. The initiation inhibitor aurintricarboxylic acid (ATA) decreased the amount of lower molecular weight products accumulated. The accumulation of completed large subunits was only marginally reduced in the presence of ATA. The incorporation of newly synthesized large subunits into Rubisco holoenzyme occurred under conditions previously identified as optimal for the assembly of in organello-synthesized large subunits and required the addition of purified small subunits.     

Analysis of the role of glycosylation of the human fibronectin receptor

1-Deoxymannojirimycin (MNJ), an inhibitor of Golgi alpha-mannosidase IA and IB, was used to assess the possible roles of asparagine-linked oligosaccharides in the structure and function of the integrin fibronectin receptor from cultured human fibroblasts. These cells normally attach well to fibronectin substrates and have only mature forms of the fibronectin receptor on their surfaces. MNJ inhibits the intracellular trimming of high mannose oligosaccharides, and cells treated with 0.2 mg/ml MNJ synthesize only immature precursor forms of both the alpha and beta subunits of the fibronectin receptor. The immature receptor polypeptides were found to be nonfunctional by two criteria: 1) cells treated with MNJ attached poorly to fibronectin substrates; and 2) receptor from the treated cells was defective in binding to fibronectin affinity columns. The precursor forms of the fibronectin receptor subunits were found on the surfaces of cells treated with MNJ, demonstrating that processing of receptor carbohydrates to mature forms was not necessary for receptor insertion into the plasma membrane. A monoclonal antibody that specifically bound the alpha subunit of the fibronectin receptor immunoprecipitated both alpha and beta subunit polypeptides from both control cells and cells treated with MNJ. Similarly, a monoclonal antibody that specifically bound only the beta subunit also immunoprecipitated both alpha and beta subunit polypeptides of the receptor from extracts of both control and MNJ-treated cells. These results indicate that receptor assembly can occur in the absence of complete oligosaccharide processing. Thus, oligosaccharide processing to the mature form of the fibronectin receptor is important for its binding function but not for receptor assembly or insertion into the plasma membrane.     

Developmentally regulated rearrangement and expression of genes encoding the T cell receptor-T3 complex

Human leukemic cells corresponding to the earliest identifiable stages of intrathymic T cell differentiation lack cell surface expression of the T cell receptor(TCR alpha/beta)-T3 complex but transcribe TCR beta mRNA from either germ-line configuration (1/13) or partially (DJ) or fully (VDJ) rearranged (12/13) genes. These cells do not produce TCR alpha mRNA, but do contain T3 delta and T3 epsilon mRNA and accumulate T3 polypeptides, primarily in the perinuclear envelope. Equivalent normal T cells isolated from thymus have a predominantly germ-line configuration of TCR beta but contain intracellular T3 proteins. T3 gene expression is therefore a very early event in T cell differentiation. TCR alpha chain production appears to be the limiting maturation-linked event in the transport, assembly, and cell surface membrane insertion of the TCR alpha/beta-T3 complex.     

Multiple roles for the twin arginine leader sequence of dimethyl sulfoxide reductase of Escherichia coli

Dimethyl sulfoxide (Me(2)SO) reductase of Escherichia coli is a terminal electron transport chain enzyme that is expressed under anaerobic growth conditions and is required for anaerobic growth with Me(2)SO as the terminal electron acceptor. The trimeric enzyme is composed of a membrane extrinsic catalytic dimer (DmsAB) and a membrane intrinsic anchor (DmsC). The amino terminus of DmsA has a leader sequence with a twin arginine motif that targets DmsAB to the membrane via a novel Sec-independent mechanism termed MTT for membrane targeting and translocation. We demonstrate that the Met-1 present upstream of the twin arginine motif serves as the correct translational start site. The leader is essential for the expression of DmsA, stability of the DmsAB dimer, and membrane targeting of the reductase holoenzyme. Mutation of arginine 17 to aspartate abolished membrane targeting. The reductase was labile in the leader sequence mutants. These mutants failed to support growth on glycerol-Me(2)SO minimal medium. Replacing the DmsA leader with the TorA leader of trimethylamine N-oxide reductase produced a membrane-bound DmsABC with greatly reduced enzyme activity and inefficient anaerobic respiration indicating that the twin arginine leaders may play specific roles in the assembly of redox enzymes.     

Multiple functions of tail-anchor domains of mitochondrial outer membrane proteins

Tail-anchored proteins form a distinct class of membrane proteins that have a single membrane anchor sequence at their C-terminus, the tail-anchor. Their N-terminal portion is exposed to the cytosol. We have studied the roles of tail-anchor domains of proteins residing in the mitochondrial outer membrane. Four distinct functions of the tail-anchor domain were identified. First, the domain mediates the targeting to mitochondria in a process that probably requires a net positive charge at the C-terminally flanking segment. Second, tail-anchor domains facilitate the insertion into the mitochondrial outer membrane. Third, the tail-anchor is responsible for the assembly of the respective protein into functional multi-subunit complexes; and fourth, tail-anchor domains can stabilize such complexes.     

Dimethyl sulfoxide reductase of Escherichia coli: an investigation of function and assembly by use of in vivo complementation.

Dimethyl sulfoxide (DMSO) reductase of Escherichia coli is a membrane-bound, terminal anaerobic electron transfer enzyme composed of three nonidentical subunits. The DmsAB subunits are hydrophilic and are localized on the cytoplasmic side of the plasma membrane. DmsC is the membrane-intrinsic polypeptide, proposed to anchor the extrinsic subunits. We have constructed a number of strains lacking portions of the chromosomal dmsABC operon. These mutant strains failed to grow anaerobically on glycerol minimal medium with DMSO as the sole terminal oxidant but exhibited normal growth with nitrate, fumarate, and trimethylamine N-oxide, indicating that DMSO reductase is solely responsible for growth on DMSO. In vivo complementation of the mutant with plasmids carrying various dms genes, singly or in combination, revealed that the expression of all three subunits is essential to restore anaerobic growth. Expression of the DmsAB subunits without DmsC results in accumulation of the catalytically active dimer in the cytoplasm. The dimer is thermolabile and catalyzes the reduction of various substrates in the presence of artificial electron donors. Dimethylnaphthoquinol (an analog of the physiological electron donor menaquinone) was oxidized only by the holoenzyme. These results suggest that the membrane-intrinsic subunit is necessary for anchoring, stability, and electron transport. The C-terminal region of DmsB appears to interact with the anchor peptide and facilitates the membrane assembly of the catalytic dimer.     

Functional analysis of the adsorption protein of two filamentous phages with different host specificities

The gene 3 coding for one minor coat protein (adsorption protein) of phage IKe was cloned into an expression plasmid and overproduced. The presence of a promoter for this gene could be demonstrated as well as the incorporation of the IKe gene 3 protein (g3p) into the cytoplasmic membrane of host cells. When 110 carboxy-terminal amino acids were deleted, the truncated protein was translocated across the cytoplasmic membrane into the periplasm. Thus the deleted amino acids bear a membrane anchor domain. In contrast to the partly homologous g3p of the Ff phages, IKe g3p did not alter the membrane properties of its host. IKe g3p was not incorporated into Ff phage particles in amounts detectable by our assays although the presence of IKe g3p may affect the efficiency of Ff phage production. The existence of a structural feature necessary for the specific recognition of the respective g3p during phage assembly is deduced.     

Solution NMR studies of antiamoebin,a membrane channel-forming polypeptide

Antiamoebin I is a membrane-active peptaibol produced by fungi of the species Emericellopsis which is capable of forming ion channels in membranes. Previous structure determinations by x-ray crystallography have shown the molecule is mostly helical, with a deep bend in the center of the polypeptide, and that the backbone structure is independent of the solvent used for crystallization. In this study, the solution structure of antiamoebin was determined by NMR spectroscopy in methanol, a solvent from which one of the crystal structures was determined. The ensemble of structures produced exhibit a right-handed helical C terminus and a left-handed helical conformation toward the N-terminus, in contrast to the completely right-handed helices found in the crystal structures. The NMR results also suggest that a "hinge" region exists, which gives flexibility to the polypeptide in the central region, and which could have functional implications for the membrane insertion process. A model for the membrane insertion and assembly process is proposed based on the antiamoebin solution and crystal structures, and is contrasted with the assembly and insertion mechanism proposed for other ion channel-forming polypeptides.     

The roles of toc34 and toc75 in targeting the toc159 preprotein receptor to chloroplasts

The Toc complex at the outer envelope of chloroplasts initiates the import of nuclear-encoded preproteins from the cytosol into the organelle. The core of the Toc complex is composed of two receptor GTPases, Toc159 and Toc34, as well as Toc75, a beta-barrel membrane channel. Toc159 is equally distributed between a soluble cytoplasmic form and a membrane-inserted form, suggesting that assembly of the Toc complex is dynamic. In the present study, we used the Arabidopsis thaliana orthologs of Toc159 and Toc34, atToc159 and atToc33, respectively, to investigate the requirements for assembly of the trimeric Toc complex. In addition to its intrinsic GTPase activity, we demonstrate that integration of atToc159 into the Toc complex requires atToc33 GTPase activity. Additionally, we show that the interaction of the two GTPase domains stimulates association of the membrane anchor of atToc159 with the translocon. Finally, we employ reconstituted proteoliposomes to demonstrate that proper insertion of the receptor requires both Toc75 and Toc34. Collectively these data suggest that Toc34 and Toc75 act sequentially to mediate docking and insertion of Toc159 resulting in assembly of the functional translocon.     

Identification of membrane anchor polypeptides of Escherichia coli fumarate reductase

Fumarate reductase of Escherichia coli has been shown to be a membrane-bound enzyme composed of a 69,000-dalton catalytic-flavin-containing subunit and a 27,000-dalton nonheme-iron-containing subunit. Using gene cloning and amplification techniques, we have observed two additional polypeptides encoded by the frd operon, with apparent molecular weights of 15,000 and 14,000, which are expressed when E. coli is grown anaerobically on glycerol plus fumarate. Expression of these two small polypeptides is necessary for the two large subunits to associate with the membrane. The four subunits remain associated in Triton X-100 extracts of the membrane, and a holoenzyme form of fumarate reductase containing one copy of each of the four polypeptides has been isolated. Unlike the well-characterized two-subunit form, the holoenzyme is not dependent on anions for activity and is not labile at alkaline pH. In these respects, it more closely resembles the membrane-bound activity.     

Cell-free expression and assembly of ATP synthase

Cell-free (CF) expression technologies have emerged as promising methods for the production of individual membrane proteins of different types and origin. However, many membrane proteins need to be integrated in complex assemblies by interaction with soluble and membrane-integrated subunits in order to adopt stable and functionally folded structures. The production of complete molecular machines by CF expression as advancement of the production of only individual subunits would open a variety of new possibilities to study their assembly mechanisms, function, or composition. We demonstrate the successful CF formation of large molecular complexes consisting of both membrane-integrated and soluble subunits by expression of the atp operon from Caldalkalibacillus thermarum strain TA2.A1 using Escherichia coli extracts. The operon comprises nine open reading frames, and the 542-kDa F₁F_o-ATP synthase complex is composed of 9 soluble and 16 membrane-embedded proteins in the stoichiometry α₃β₃γδ?ab₂c₁₃. Complete assembly into the functional complex was accomplished in all three typically used CF expression modes by (i) solubilizing initial precipitates, (ii) cotranslational insertion into detergent micelles or (iii) cotranslational insertion into preformed liposomes. The presence of all eight subunits, as well as specific enzyme activity and inhibition of the complex, was confirmed by biochemical analyses, freeze-fracture electron microscopy, and immunogold labeling. Further, single-particle analysis demonstrates that the structure and subunit organization of the CF and the reference in vivo expressed ATP synthase complexes are identical. This work establishes the production of highly complex molecular machines in defined environments either as proteomicelles or as proteoliposomes as a new application of CF expression systems.     

The ER membrane complex (EMC) can functionally replace the Oxa1 insertase in mitochondria

Two multisubunit protein complexes for membrane protein insertion were recently identified in the endoplasmic reticulum (ER): the guided entry of tail anchor proteins (GET) complex and ER membrane complex (EMC). The structures of both of their hydrophobic core subunits, which are required for the insertion reaction, revealed an overall similarity to the YidC/Oxa1/Alb3 family members found in bacteria, mitochondria, and chloroplasts. This suggests that these membrane insertion machineries all share a common ancestry. To test whether these ER proteins can functionally replace Oxa1 in yeast mitochondria, we generated strains that express mitochondria-targeted Get2–Get1 and Emc6–Emc3 fusion proteins in Oxa1 deletion mutants. Interestingly, the Emc6–Emc3 fusion was able to complement an Δoxa1 mutant and restored its respiratory competence. The Emc6–Emc3 fusion promoted the insertion of the mitochondrially encoded protein Cox2, as well as of nuclear encoded inner membrane proteins, although was not able to facilitate the assembly of the Atp9 ring. Our observations indicate that protein insertion into the ER is functionally conserved to the insertion mechanism in bacteria and mitochondria and adheres to similar topological principles.

Redirecting the core subunits of the protein membrane insertion complex EMC into mitochondria rescues cells deficient for the mitochondrial Oxa1 system; this supports the hypothesis that the machinery for protein insertion into the ER membrane is functionally analogous to the YidC/Oxa1/Alb3 family of bacteria, mitochondria and chloroplasts.     

Characterization of tonoplast polypeptides isolated from corn seedling roots

Tonoplast vesicles were isolated by discontinuous sucrose gradient centrifugation in the presence of Mg²⁺ from 5 day old corn (Zea mays L., Golden Cross Bantam) seedling roots. Marker enzyme assays indicated only a low degree of cross-contamination of tonoplast vesicles at the 10/23% (weight/weight) interface by other membrane components. Severalfold enrichment of tonoplast ATPase and pyrophosphatase was indicated in tonoplast fractions by dot blot studies with antibodies against an oat tonoplast ATPase and a mung bean tonoplast pyrophosphatase. Comparison of two-dimensional electrophoretic gels of tonoplast and microsomal membrane polypeptides revealed approximately 68 polypeptides to be specific to tonoplast by silver staining. Immunoblot analysis with antibodies against a tonoplast holoenzyme ATPase from oat roots revealed the presence of the 72, 60, and 41 kilodalton polypeptides in isolated tonoplast vesicles from corn roots. Affinity blotting with concanavalin A and secondary antibodies indicated the degree of glycosylation of tonoplast polypeptides, where 21 of 68 tonoplast-specific polypeptides contained detectable carbohydrate moieties. Salt and NaOH washes removed 38 of the tonoplast-specific polypeptides, indicating a peripheral association with the membrane. Thirteen of the peripheral polypeptides and eight of the integral polypeptides were identified as glycoproteins. This information on the polypeptide composition of the tonoplast of root cells will aid in gaining insight into the role of this membrane in controlling vacuolar functions.     

DNA Polymerase III holoenzyme of Escherichia coli. IV. The holoenzyme is an asymmetric dimer with twin active sites

Pol III, a subassembly of Escherichia coli DNA polymerase III holoenzyme lacking only the auxiliary beta subunit, was purified to homogeneity by an improved procedure. This assembly consists of nine different polypeptides, likely in a 1:1 stoichiometry: a catalytic core (pol III) of alpha (132 kDa), epsilon (27 kDa), and theta (10 kDa), and six auxiliary subunits: tau (71 kDa), gamma (52 kDa), delta (35 kDa), delta' (33 kDa), chi (15 kDa), and psi (12 kDa). The assembly behaves on gel filtration as a particle of about 800 kDa, indicating a content of two each of the subunits. A new procedure for purifying the core yielded a novel dimeric form which may provide the foundation for the dimeric nature of the more complex pol III and holoenzyme forms. Pol III readily dissociates into several subassemblies including pol III', likely a dimeric core with two tau subunits. The holoenzyme, purified by a similar procedure with ATP and Mg2+ present throughout, retained the beta subunit (37 kDa) as well as all the subunits present in pol III; the mass of the holoenzyme was estimated to be 900 kDa. The isolated initiation complex of holoenzyme with a primed template DNA and the elongation complex (formed in the presence of three deoxynucleoside triphosphates) had the same composition and stoichiometry as observed for pol III with two beta dimers in addition. An initiation complex assembled from a mixture of monomeric pol III core, gamma 2 delta delta' chi psi complex (gamma complex), beta, and tau retained the core, one beta dimer, and two tau subunits but was deficient in the gamma complex. When tau was omitted from the assembly mixture, the initiation complex contained one or two gamma complexes instead of the tau subunit. Based on these data, pol III holoenzyme is judged to be an asymmetric dimeric particle with twin pol III core active sites and two different sets of auxiliary units designed to achieve essentially concurrent replication of both leading and lagging strand templates.