The photosynthetic F1-α3β3 and α1β1 catalytic core complexes

Minimal photosynthetic catalytic F₁() core complexes, containing equimolar ratios of the and subunits, were isolated from membrane-bound spinach chloroplast CF₁ and Rhodospirillum rubrum chromatophore RrF₁. A CF₁-₃₃ hexamer and RrF₁-₁₁ dimer, which were purified from the respective F₁() complexes, exhibit lower rates and different properties from their parent F₁-ATPases. Most interesting is their complete resistance to inhibition by the general F₁ inhibitor azide and the specific CF₁ inhibitor tentoxin. These inhibitors were earlier reported to inhibit multisite, but not unisite, catalysis in all sensitive F₁-ATPases and were therefore suggested to block catalytic site cooperativity. The absence of this typical property of all F₁-ATPases in the ₁₁ dimer is consistant with the view that the dimer contains only a single catalytic site. The ₃₃ hexamer contains however all F₁ catalytic sites. Therefore the observation that CF₁-₃₃ can bind tentoxin and is stimulated by it suggests that the F₁ subunit, which is required for obtaining inhibition by tentoxin as well as azide, plays an important role in the cooperative interactions between the F₁-catalytic sites.Abbreviations CF₀F₁ chloroplast F₀F₁ - CF₁ chloroplast F₁ - CF₁ chloroplast F₁ subunit - CF₁ chloroplast F₁ subunit - CF₁() a complex containing equal amounts of the CF₁ and subunits - MF₁ mitochondrial F₁ - RrF₀F₁ Rhodospirillum rubrum F₀F₁ - RrF₁ R. rubrum F₁ - RrF₁ R. rubrum F₁ subunit - RrF₁ R. rubrum F₁ subunit - RrF₁() a complex containing equal amounts of the RrF₁ and subunits - Rubisco Ribulose-1,5-bisphosphate carboxylase - TF₁ thermophilic bacterium PS3 F₁     

Structural and Functional Features of the Escherichia coli F 1 -ATPase

The structural organization and overall dimensions of the Escherichia coli F₁-ATPase in solutionhas been analyzed by synchroton X-ray scattering. Using an independent ab initio approach,the low-resolution shape of the hydrated enzyme was determined at 3.2 nm resolution. Theshape permitted unequivocal identification of the volume occupied by the _{3 3} complex ofthe atomic model of the ECF₁-ATPase. The position of the ^ and subunits were found byinteractive fitting of the solution scattering data and by cross-linking studies. Laser-inducedcovalent incorporation of 2-azido-ATP established a direct relationship between nucleotidebinding affinity and the different interactions between the stalk subunits and with the threecatalytic subunits () of the F₁-ATPase. Mutants of the ECF₁-ATPase with the introductionof Trp-for-Tyr replacement in the catalytic site of the complex made it possible to monitorthe activated state for ATP synthesis (ATP conformation) in which the and subunits arein close proximity to the subunits and the ADP conformation, with the stalk subunits arelinked to the subunit.     

Chemical modification of active sites in relation to the catalytic mechanism of F1

Recent studies of chemically modified F₁-ATPases have provided new information that requires a revision of our thinking on their catalytic mechanism. One of the subunits in F₁-ATPase is distinguishable from the other two both structurally and functionally. The catalytic site and regulatory site of the same subunit are probably sufficiently close to each other, and the interaction between the various catalytic and regulatory sites are probably sufficiently strong to raise the uni-site rate of ATP hydrolysis by several orders of magnitude to that of promoted (multi-site) ATP hydrolysis. Although all three subunits in F₁ possess weak uni-site ATPase activity, only one of them () catalyzes promoted ATP hydrolysis. But all three subunits catalyze ATP synthesis driven by the proton flux. Internal rotation of the ₃₃ or ₃ moiety relative to the remainder of the F₀F₁ complex did not occur during oxidative phosphorylation by reconstituted submitochondrial particles.     

Identification of subunits required for the catalytic activity of the F1-ATPase

F₁() complexes containing equimolar ratios of the and subunits have been shown to function as active ATPases, whereas individually isolated and subunits show no real ATPase activity. These results indicate that the single-copy subunits are not required for F₁-ATPase activity. The minimal F₁()-core complexes exhibit, however, lower rates and some different properties from those of their parent whole F₁ or ₃₃ complexes. It is therefore concluded that for obtaining a full spectrum of the characteristic functional properties of an F₁-ATPase the presence of the F₁- subunit is also required. The implications of these findings on the subunit location of both catalytic and noncatalytic nucleotide binding sites is discussed.     

ATP synthases—Structure of the F1-moiety and its relationship to function and mechanism

A great deal of progress has been made in understanding both the structure and the mechanism of F₁-ATPase. The primary structure is now fully known for at least five species. Sequence comparison between chloroplast, photobacteria, aerobic bacteria, and mitochondrial representatives allow us to infer more general functional relationships and evolutionary trends. Although the F₁ moiety is the most studied segment of the H⁺-ATPase complex, there is not a full understanding of the mechanism and regulation of its hydrolytic activity. The subunit is now known to contain one and probably two nucleotide binding domains, one of which is believed to be a catalytic site. Recently, two similar models have been proposed to attempt to describe the active part of the subunits. These models are mainly an attempt to use the structure of adenylate kinase to represent a more general working model for nucleotide binding phosphotransferases. Labelling experiments seem to indicate that several critical residues outside the region described by the adenylate kinase part of this model are also actively involved in the ATPase activity. New models will have to be introduced to include these regions. Finally, it seems that a consensus has been reached with regard to a broad acceptance of the asymmetric structure of the F₁-moiety. In addition, recent experimental evidence points toward the presence of nonequivalent subunits to describe the functional activity of the F₁-ATPase. A summary diagram of the conformational and binding states of the enzyme including the nonequivalent subunit is presented. Additional research is essential to establish the role of the minor subunits—and of the asymmetry they introduce in F₁—on the physiological function of the enzyme.     

Significance of the β-Subunit in the Biogenesis of Na+/K+-ATPase

This review summarizes our experiments on the significance of the -subunit in the functional expression of Na⁺/K⁺-ATPase. The -subunit acts like a receptor for the -subunit in the biogenesis of Na⁺/K⁺-ATPase and facilitates the correct folding of the -subunit in the membrane. The -subunit synthesized in the absence of the -subunit is subjected to rapid degradation in the endoplasmic reticulum. Several assembly sites are assigned in the sequence of the -subunit from the cytoplasmic NH₂-terminal domain to the extracellular COOH-terminus: the NH₂-terminal region of the extracellular domain, the conservative proline in the third disulfide loop, the hydrophobic amino acid residues near the COOH-terminus and the cysteine residues forming the second and the third disulfide bridges. Upon assembly, the -subunit confers a resistance to trypsin on the -subunit. The conformations induced in the -subunit of Na⁺/K⁺-ATPase by Na⁺/K⁺- and H⁺/K⁺-ATPase -subunits are somehow different from each other and are named the NK-type and KH-type, respectively. The extracellular domain of the -subunit is involved in the folding of the -subunit leading to trypsin-resistant conformations. The sequences from Cys150 to the COOH-terminus of the Na⁺/K⁺-ATPase -subunit and from Ile89 to the COOH–terminus of the H⁺/K⁺-ATPase -subunit are necessary to form trypsin-resistant conformations of the NK- and HK-type. respectively. The first disulfide loop of the extracellular domain of the -subunits is critical in the expression of functional Na⁺/K⁺-ATPase.     

Malate regulation of Mg2+-ATPase of chloroplast coupling factor 1

The regulatory effects of malate on chloroplast Mg²⁺-ATPase were investigated and the mechanism was discussed. Malate stimulated methanol-activated membrane-bound and isolated CF₁ Mg²⁺-ATPase activity. The subunit of CF₁ may be involved in malate regulation of the enzyme function. Modification of subunit at one site of the peptide by NEM may affect malate stimulation of ATPase while at another site may have no effect. The effect of malate on the Mg²⁺-ATPase was also controlled by the Mg²⁺/ATP ratio in the reaction medium. The enhancing effect of malate on Mg²⁺-ATPase activity depended on the presence of high concentrations of Mg²⁺ in the reaction mixture. Kinetic study showed that malate raised the V_max of catalysis without affecting the K_m for Mg²⁺ ATP. The experiments imply that the stimulation of Mg²⁺-ATPase by malate is probably correlated with the P_i binding site on the enzyme. The regulation of ATPase activity by malate in chloroplasts may be relevant to its function in vivo.Abbreviations CF₁ chloroplast coupling factor 1 - CF₁ (-) and CF₁ (-) CF₁ deficient in the and subunit - MF₁ mitochondria coupling factor 1 - NEM N-ethylmaleimide - PMS phenazine methosulfate - OG n-octyl--d-glucopyranoside     

Steroid Polyols from the Far Eastern Starfish Henricia sanguinolenta and H. leviuscula leviuscula

Two new asterosaponins, (20R)-3-O--D-(2-O-methylxylopyranosyl)-24-propylcholest-4-ene-3,6,8,15,16,29-hexaol (sanguinoside A) and (20R,24S)-3-O--D-(2,3,4-tri-O-methylxylopyranosyl)-5-cholestane-3,4,6,8,15,24-hexaol (sanguinoside B), were isolated from two species of Pacific Far Eastern Starfish Henricia sanguinolenta and H. leviuscula leviuscula, collected in the Sea of Okhotsk. Both glycosides contain aglycones with pentahydroxysteroid nuclei of similar structures, which are substituted at the 3-hydroxy group with differently methylated -D-xylosyl residues. Sanguinoside A has an unusual structure of its aglycone side chain, whereas sanguinoside B has a unique permethylated carbohydrate chain. In addition, laevisculoside G, a known glycoside, was identified in the H. leviuscula starfish. The structures of the isolated glycosides were established by interpreting their spectral data and by comparing their spectral characteristics with those of known compounds.     

Molecular switch of F0F1-ATP synthase,G-protein,and other ATP-driven enzymes

Exchange-out of amide tritium from labeled -subunit of ₃₃ complex of F₀F₁-ATP synthase was not accelerated by ATP, suggesting that hemagglutinin-type transition of coiled-coil structure did not occur in -subunit. Local topology of nucleotide binding site and switch II region of G-protein resemble those of F₁- subunit and other proteins which catalyze ATP-triggered reactions. Probably, binding of nucleotide to F₀F₁-ATP synthase induces conformational change of the switch II-like region with transforming subunit structure from open to closed form and this transformation results in loss of hydrogen bonds with the subunit, thus enabling the subunit to move.     

A quantitative method for separating reaction components of CMP-sialic acid: Lactosylceramide sialyltransferase using Sep Pak C18 cartridges

A rapid procedure is described for the separation of CMP-sialic acid:lactosylceramide sialyltransferase reaction components using Sep Pak C₁₈ cartridges. The quantitative separation of the more polar nucleotide sugar, CMP-sialic acid, and its free acid from the less polar G_M3-ganglioside is simple and rapid relative to previously described methods. Recovery of G_M3 is optimized by the addition of phosphatidylcholine to the reaction mixture prior to the chromatographic step. Using rat liver Golgi membranes as a source of CMP-sialic acid: lactosylceramide sialyltransferase activity (G_M3 synthase; ST-1), the transfer of [¹⁴C] sialic acid from CMP-[¹⁴C] sialic acid to lactosylceramide can be quantified by this assay. The procedure is reliable and may be applicable to the isolation of ganglioside products in otherin vitro glycosyltransferase assays.Abbreviations G_M3 G_M3-ganglioside - II³NeuAc-LacCer NeuAc2-3Gal1-4Glc1-1Cer - G_D1a G_D1a-ganglioside, IV³NeuAc, II³NeuAc-GgOse₄Cer, NeuAc2-3Gal1-3GalNac1-4(NeuAc2-3)Gal1-4Glc1-1Cer - G_D3 G_D3-ganglioside, II³(NeuAc)₂LacCer, NeuAc2-8NeuAc2-3Gal1-4Glc1-1Cer - GgOse₄Cer asialo-G_M1 Gal1-3GalNAc1-4Gal1-4Glc1-1Cer - FucG_MI fucosyl-G_MI-ganglioside, Fuc1-2Gal1-3GalNAc1-4Gal1-4 Glc1-1Cer - ST-1 G_M3 synthase, CMP-sialic acid:lactosylceramide sialyltransferase - LacCer lactosylceramide, Gal1-4Glc1-1Cer - CMP-NeuAc cytidine 5-monophospho-N-acetylneuraminic acid - PC phosphatidylcholine - PMSF phenylmethylsulfonyl fluoride     

Variability in the 11S globulin fraction of seed storage proteins ofHelianthus (Asteraceae)

The seed storage globulins from sixHelianthus and four hybrids were studied using mono and bidimensional gel SDS electrophoresis (+ 2 mercaptoethanol). The polypeptide composition of each subunit was determined. Different pairs are specifically expressed according to the species studied. Three typical patterns were discriminated. All the studied species exhibit five subunits: two of them are expressed in all the species (₁₁ and ₂₂). The subunit corresponding to the ₁₁ pair is present inH. petiolaris and in the three populations ofH. annuus studied. The _2b2 pair is common toH. annuus andH. argophyllus. H. petiolaris presents two specific _2a2 and ₄₄ pairs andH. annuus a specific ₃₃ pair. InH. argophyllus _{11 33} or ₄₄ are never observed but are replaced by ₁₃ and ₃₁ pairs. Some globulins, poorly represented, are of forms but present chains of higher molecular weights (in the range 54–56 kDa). Expressing variations in the banding patterns between these species by the use of a similarity index reveals complete identity between the three populations ofH. annuus. Identity between the twoH. petiolaris studied is also observed.H. annuus andH. argophyllus appear to be closer to each other thanH. petiolaris concerning the seed storage globulins.     

The α/β Interfaces of α1β1, α3β3, and F1: Domain Motions and Elastic Energy Stored during γ Rotation

ATP synthase (F_oF₁) consists of F₁ (ATP-driven motor) and F_o (H⁺-driven motor). F₁ is a complex of ₃₃ subunits, and is the rotating cam in ₃₃. Thermophilic F₁ (TF₁) is exceptional in that it can be crystallized as a monomer and an ₃₃ oligomer, and it is sufficiently stable to allow refolding and reassembly of hybrid complexes containing 1, 2, and 3 modified or . The nucleotide-dependent open–close conversion of conformation is an inherent property of an isolated and energy and signals are transferred through / interfaces. The catalytic and noncatalytic interfaces of both mitochondrial F₁ (MF₁) and TF₁ were analyzed by an atom search within the limits of 0.40 nm across the interfaces. Seven (plus thermophilic loop in TF₁) contact areas are located at both the catalytic and noncatalytic interfaces on the open form. The number of contact areas on closed increased to 11 and 9, respectively, in the catalytic and noncatalytic interfaces. The interfaces in the barrel domain are immobile. The torsional elastic strain applied through the mobile areas is concentrated in hinge residues and the P-loop in . The notion of elastic energy in F_oF₁ has been revised. X-ray crystallography of F₁ is a static snap shot of one state and the elastic hypotheses are still inconsistent with the structure, dyamics, and kinetics of F_oF₁. The domain motion and elastic energy in F_oF₁ will be elucidated by time-resolved crystallography.     

ATP Synthases in the Year 2000: Evolving Views about the Structures of These Remarkable Enzyme Complexes

This introductory article briefly summarizes how our views about the structural features ofATP synthases (F₀F₁) have evolved over the past 30 years and also reviews some of our currentviews in the year 2000 about the structures of these remarkably unique enzyme complexes.Suffice it to say that as we approach the end of the first year of this new millinium, we canbe conservatively confident that we have a reasonably good grasp of the overall low-resolutionstructural features of ATP synthases. Electron microscopy techniques, combined with the toolsof biochemistry, molecular biology, and immunology, have played the leading role here byidentifying the headpiece, basepiece, central stalk, side stalk, cap, and in the mitochondrialenzyme, the collar around the central stalk. We can be reasonably confident also that we havea fairly good grasp of much of the high-resolution structural features of both the F₁ moietycomprised of fives subunit types (, , , , and ) and parts of the F₀ moiety comprised ofeither three (E. coli) or at least ten (mitochondria) subunit types. This information acquiredin several different laboratories, either by X-ray crystallography or NMR spectroscopy, includesdetails about the active site and subunit relationships. Moreover, it is consistent with recentlyreported data that the F₁ moiety may be an ATP driven motor, which, during ATP synthesis,is driven in reverse by the electrochemical proton gradient generated by the electron transportchain. The real structural challenges of the future are to acquire at high resolution completeATP synthase complexes representative of different stages of the catalytic cycle during ATPsynthesis and representative also of key regulatory states.     

ATP Synthases in the Year 2000: Defining the Different Levels of Mechanism and Getting a Grip on Each

ATP synthases are unusually complex molecules, which fractionate most readily into two major units, one a water soluble unit called F₁ and the other a detergent soluble unit called F₀. In almost all known species the F₁ unit consists of 5 subunit types in the stoichiometric ratio ₃₃ while the F₀ unit contains 3 subunit types (a, b, and c) in E. coli, and at least 10 subunit types (a, b, c, and others) in higher animals. It is now believed by many investigators that during the synthesis of ATP, protons derived from an electrochemical gradient generated by an electron transport chain are directed through the F₀ unit in such a way as to drive the rotation of the single subunit, which extends from an oligomeric ring of at least 10 c subunits in F₀ through the center of F₁. It is further believed by many that the rotating subunit, by interacting sequentially with the 3 pairs of F₁ (360° cycle) in the presence of ADP, P_i, and Mg⁺⁺, brings about via power strokes conformational/binding changes in these subunits that promote the synthesis of ATP and its release on each pair. In support of these views, studies in several laboratories either suggest or demonstrate that F₀ consists in part of a proton gradient driven motor while F₁ consists of an ATP hydrolysis driven motor, and that the subunit does rotate during F₁ function. Therefore, current implications are that during ATP synthesis the former motor drives the latter in reverse via the subunit. This would suggest that the process of understanding the mechanism of ATP synthases can be subdivided into three major levels, which include elucidating those chemical and/or biophysical events involved in (1) inducing rotation of the subunit, (2) coupling rotation of this subunit to conformational/binding changes in each of the 3 pairs, and (3) forming ATP and water (from ADP, P_i, and Mg⁺⁺) and then releasing these products from each of the 3 catalytic sites. Significantly, it is at the final level of mechanism where the bond breaking/making events of ATP synthesis occur in the transition state, with the former two levels of mechanism setting the stage for this critical payoff event. Nevertheless, in order to get a better grip in this new century on how ATP synthases make ATP and then release it, we must take on the difficult challenge of elucidating each of the three levels of mechanism.     

Notes on the Mechanism of ATP Synthesis

The most commonly quoted mechanism of the coupling between the electrochemical proton gradient and the formation of ATP from ADP and P_i assumes that all states of the F₁ portion of the ATP synthase have subunits in tight, loose, and open conformations. Models based on this assumption are inconsistent with some of the available experimental evidence. A mechanism that includes an additional subunit conformation, closed, observed in the rat liver structure overcomes these difficulties.     

Evolutionary relationship between Enterobacteriaceae: comparison of the ATP synthases (F1F0) of Escherichia coli and Klebsiella pneumoniae

The ATP synthase complex of Klebsiella pneumoniae (KF₁F₀) has been purified and characterized. SDS-gel electrophoresis of the purified F₁F₀ complexes revealed an identical subunit pattern for E. coli (EF₁F₀) and K. pneumoniae. Antibodies raised against EF₁ complex and purified EF₀ subunits recognized the corresponding polypeptides of EF₁F₀ and KF₁F₀ in immunoblot analysis. Protease digestion of the individual subunits generated an identical cleavage pattern for subunits , , , , a, and c of both enzymes. Only for subunit different cleavage products were obtained. The isolated subunit c of both organisms showed only a slight deviation in the amino acid composition. These data suggest that extensive homologies exist in primary and secondary structure of both ATP synthase complexes reflecting a close phylogenetic relationship between the two enterobacteric tribes.Abbreviations ACMA 9-amino-6-chloro-2-methoxyacridine - DCCD N,N-dicyclohexylcarbodiimide - FITC fluorescein isothiocyanate - SDS sodium dodecyl sulfate - TTFB 4,5,6,7-tetrachloro-2-trifluoromethylbenzimidazole     

Interaction between Tubulin and Na2+,K2+-ATPase in Brain Stem Neurons

Functionally active Na²⁺,K²⁺-ATPase isozymes containing three types of the catalytic subunits (1, 2, and 3) were obtained from calf brain by two methods: selective removal of contaminating proteins according to Jorgensen (1974) and selective solubilization of the enzyme with subsequent reformation of the membrane structure according to Esmann (1988). All preparations were characterized with respect to ouabain-inhibition constants. The presence of the cytoskeleton protein tubulin (3 isoform) in the high-molecular-weight complex of Na²⁺,K²⁺-ATPase 31 isozyme from brain stem axolemma and the junction between Na²⁺,K²⁺-ATPase 3 subunit and tubulin 3 subunit are shown for the first time.     

The αβ complexes of ATP synthase: the α3β3 oligomer and α1β1 protomer

The basic structures of the catalytic portion (F₁, ₃₃) of ATP synthase are the ₃₃ hexamer (oligomer with cooperativity) and ₁₁ heterodimer (protomer). These were reconstituted from the and subunits of thermophilic F₁ (TF₁), and the ₃₃ hexamer was crystallized. On electrophoresis, both the dimer and hexamer showed bands with ATPase activity. Using the dimer and hexamer, we studied the nucleotide-dependent rapid molecular dynamics. The formation of the hexamer required neither nucleotide nor Mg. The hexamer was dissociated into the dimer in the presence of MgADP, while the dimer was associated into the hexamer in the presence of MgATP. The hexamer, like mitochondrial F₁ and TF₁, showed two kinds of ATPase activity: one was cooperative and was inhibited by only one BzADP per hexamer, and the other was inhibited by three BzADP per hexamer.     

Preparation of a series of sulfated tetrasaccharides from shark cartilage chondroitin sulfate D using testicular hyaluronidase and structure determination by 500 MHz1H NMR spectroscopy

Six tetrasaccharide fractions were isolated from shark cartilage chondroitin sulfate D by gel filtration chromatography followed by HPLC on an amine-bound silica column after exhaustive digestion with testicular hyaluronidase. Their structures were determined unambiguously by one- and two-dimensional 500 MHz¹H NMR spectroscopy in conjunction with HPLC analysis of chondroitinase AC-II digests of the tetrasaccharides. One fraction was found to contain two tetrasaccharide components. All the seven tetrasaccharides shared the common core structure GlcA1-3GalNAc1-4GlcA1-3GalNAc with various sulfation profiles. Four were disulfated comprising of two monosulfated disaccharide units GlcA1-3GalNAc(4-sulfate) and/or GlcA1-3GalNAc(6-sulfate), whereas the other three were hitherto unreported trisulfated tetrasaccharides containing a disulfated disaccharide unit GlcA(2-sulfate)1-3GalNAc(6-sulfate) and a monosulfated disaccharide unit GlcA1-3GalNAc(4-or 6-sulfate). These sulfated tetrasaccharides were demonstrated to serve as appropriate acceptor substrates for serum -N-acetylgalactosaminyltransferase, indicating their usefulness as authentic oligosaccharide substrates or probes for the glycobiology of sulfated glycosaminoglycans.Abbreviations NFU National formulary unit - COSY correlation spectroscopy - HOHAHA homonuclear Hartmann-Hahn - 1D or 2D one- or two-dimensional - IdoA l-iduronic acid - GlcA d-gluco-4-enepyranosyluronic acid - Di-0S GlcA1-3GalNAc - Di-4S GlcA1-3GalNAc(4-sulfate) - Di-4S GlcA1-3GalNAc(4-sulfate) - Di-6S GlcA1-3GalNAc(6-sulfate) - Di-6S GlcA1-3GalNAc(6-sulfate) - Di-diS _d GlcA(2-sulfate)1-3GalNAc(6-sulfate) - Di-diS_E GlcA1-3GalNAc(4, 6-disulfate) - U G, U, 2S, 4S, and 6S represent GlcA, GalNAc, GlcA, 2-O-sulfate, 4-O-sulfate, and 6-O-sulfate, respectively     

The Role of the Amino-Terminal β-Barrel Domain of the α and β Subunits in the Yeast F1-ATPase

The crystal structure of mitochondrial F₁-ATPase indicatesthat the and subunits fold into a structure defined by threedomains: the top -barrel domain, the middle nucleotide-binding domain,and the C-terminal -helix bundle domain (Abraham et al.1994); Bianchet et al., 1998). The -barrel domains of the and subunits form a crown structure at the top ofF₁, which was suggested to stabilize it (Abraham et al.1994). In this study. the role of the -barrel domain in the and subunits of the yeast Saccharomyces cerevisiae F₁,with regard to its folding and assembly, was investigated. The -barreldomains of yeast F₁ and subunits were expressedindividually and together in Escherichia coli. When expressedseperately, the -barrel domain of the subunit formed a largeaggregate structure, while the domain of the subunit waspredominately a monomer or dimer. However, coexpression of the -barreldomain of subunit domain. Furthermore, the two domains copurified incomplexes with the major portion of the complex found in a small molecularweight form. These results indicate that the -barrel domain of the and subunits interact specifically with each other and thatthese interactions prevent the aggregation of the -barrel domain of the subunit. These results mimic in vivo results and suggest thatthe interactions of the -barrel domains may be critical during thefolding and assembly of F₁.