The C5 domain of the collagen VI alpha3(VI) chain is critical for extracellular microfibril formation and is present in the extracellular matrix of cultured cells

Collagen VI, a microfibrillar protein found in virtually all connective tissues, is composed of three distinct subunits, alpha1(VI), alpha2(VI), and alpha3(VI), which associate intracellularly to form triple helical heterotrimeric monomers then dimers and tetramers. The secreted tetramers associate end-to-end to form beaded microfibrils. Although the basic steps in assembly and the structure of the tetramers and microfibrils are well defined, details of the interacting protein domains involved in assembly are still poorly understood. To explore the role of the C-terminal globular regions in assembly, alpha3(VI) cDNA expression constructs with C-terminal truncations were stably transfected into SaOS-2 cells. Control alpha3(VI) N6-C5 chains with an intact C-terminal globular region (subdomains C1-C5), and truncated alpha3(VI) N6-C1, N6-C2, N6-C3, and N6-C4 chains, all associated with endogenous alpha1(VI) and alpha2(VI) to form collagen VI monomers, dimers and tetramers, which were secreted. These data demonstrate that subdomains C2-C5 are not required for monomer, dimer or tetramer assembly, and suggest that the important chain selection interactions involve the C1 subdomains. In contrast to tetramers containing control alpha3(VI) N6-C5 chains, tetramers containing truncated alpha3(VI) chains were unable to associate efficiently end-to-end in the medium and did not form a significant extracellular matrix, demonstrating that the alpha3(VI) C5 domain plays a crucial role in collagen VI microfibril assembly. The alpha3(VI) C5 domain is present in the extracellular matrix of SaOS-2 N6-C5 expressing cells and fibroblasts demonstrating that processing of the C-terminal region of the alpha3(VI) chain is not essential for microfibril formation.     

The N-terminal N5 subdomain of the alpha 3(VI) chain is important for collagen VI microfibril formation

Collagen VI assembly is unique within the collagen superfamily in that the alpha 1(VI), alpha 2(VI), and alpha 3(VI) chains associate intracellularly to form triple helical monomers, and then dimers and tetramers, which are secreted from the cell. Secreted tetramers associate end-to-end to form the distinctive extracellular microfibrils that are found in virtually all connective tissues. Although the precise protein interactions involved in this process are unknown, the N-terminal globular regions, which are composed of multiple copies of von Willebrand factor type A-like domains, are likely to play a critical role in microfibril formation, because they are exposed at both ends of the tetramers. To explore the role of these subdomains in collagen VI intracellular and extracellular assembly, alpha 3(VI) cDNA expression constructs with sequential N-terminal deletions were stably transfected into SaOS-2 cells, producing cell lines that express alpha 3(VI) chains with N-terminal globular domains containing modules N9-N1, N6-N1, N5-N1, N4-N1, N3-N1, or N1, as well as the complete triple helix and C-terminal globular domain (C1-C5). All of these transfected alpha 3(VI) chains were able to associate with endogenous alpha 1(VI) and alpha 2(VI) to form collagen VI monomers, dimers, and tetramers, which were secreted. Importantly, cells that expressed alpha 3(VI) chains containing the N5 subdomain, alpha 3(VI) N9-C5, N6-C5, and N5-C5, formed microfibrils and deposited a collagen VI matrix. In contrast, cells that expressed the shorter alpha 3(VI) chains, N4-C5, N3-C5, and N1-C5, were severely compromised in their ability to form end-to-end tetramer assemblies and failed to deposit a collagen VI matrix. These data demonstrate that the alpha 3(VI) N5 module is critical for microfibril formation, thus identifying a functional role for a specific type A subdomain in collagen VI assembly.     

Bethlem myopathy and engineered collagen VI triple helical deletions prevent intracellular multimer assembly and protein secretion.

Mutations in the genes that code for collagen VI subunits, COL6A1, COL6A2, and COL6A3, are the cause of the autosomal dominant disorder, Bethlem myopathy. Although three different collagen VI structural mutations have previously been reported, the effect of these mutations on collagen VI assembly, structure, and function is currently unknown. We have characterized a new Bethlem myopathy mutation that results in skipping of COL6A1 exon 14 during pre-mRNA splicing and the deletion of 18 amino acids from the triple helical domain of the alpha1(VI) chain. Sequencing of genomic DNA identified a G to A transition in the +1 position of the splice donor site of intron 14 in one allele. The mutant alpha1(VI) chains associated intracellularly with alpha2(VI) and alpha3(VI) to form disulfide-bonded monomers, but further assembly into dimers and tetramers was prevented, and molecules containing the mutant chain were not secreted. This triple helical deletion thus resulted in production of half the normal amount of collagen VI. To further explore the biosynthetic consequences of collagen VI triple helical deletions, an alpha3(VI) cDNA expression construct containing a 202-amino acid deletion within the triple helix was produced and stably expressed in SaOS-2 cells. The transfected mutant alpha3(VI) chains associated with endogenous alpha1(VI) and alpha2(VI) to form collagen VI monomers, but dimers and tetramers did not form and the mutant-containing molecules were not secreted. Thus, deletions within the triple helical region of both the alpha1(VI) and alpha3(VI) chains can prevent intracellular dimer and tetramer assembly and secretion. These results provide the first evidence of the biosynthetic consequences of structural collagen VI mutations and suggest that functional protein haploinsufficiency may be a common pathogenic mechanism in Bethlem myopathy.     

Structural basis of type VI collagen dimer formation

We have determined the interactive sites required for dimer formation in type VI collagen. Despite the fact that type VI collagen is a heterotrimer composed of alpha1(VI), alpha2(VI), and alpha3(VI) chains, the formation of dimers is determined principally by interactions of the alpha2(VI) chain. Key components of this interaction are the metal ion-dependent adhesion site (MIDAS) motif of the alpha2C2 A-domain and the GER sequence in the helical domain of another alpha2(VI) chain. Replacement of the alpha2(VI) C2 domain with the alpha3(VI) domain abolished dimer formation, whereas alterations in the alpha2(VI) C1 domain did not disrupt dimer formation. When the helical sequences were investigated, replacement of the alpha2(VI) sequence GSPGERGDQ with the alpha3(VI) sequence GEKGERGDV abolished dimer formation. Mutating the Pro-108 to a Lys-108 in this alpha2(VI) sequence did not influence dimer formation and suggests that, unlike the integrin I-domain/triple-helix interaction, hydroxyproline is not required in collagen VI A-domain/helix interaction. These results demonstrate that the alpha2(VI) chain position in the assembled triple-helical molecule is critical for antiparallel dimer formation and identify the interacting collagenous and MIDAS sequences involved. These interactions underpin the subsequent assembly of type VI collagen.     

Collagen VI Microfibril Formation Is Abolished by an α2(VI) von Willebrand Factor Type A Domain Mutation in a Patient with Ullrich Congenital Muscular Dystrophy

Collagen VI is an extracellular protein that most often contains the three genetically distinct polypeptide chains, α1(VI), α2(VI), and α3(VI), although three recently identified chains, α4(VI), α5(VI), and α6(VI), may replace α3(VI) in some situations. Each chain has a triple helix flanked by N- and C-terminal globular domains that share homology with the von Willebrand factor type A (VWA) domains. During biosynthesis, the three chains come together to form triple helical monomers, which then assemble into dimers and tetramers. Tetramers are secreted from the cell and align end-to-end to form microfibrils. The precise molecular mechanisms responsible for assembly are unclear. Mutations in the three collagen VI genes can disrupt collagen VI biosynthesis and matrix organization and are the cause of the inherited disorders Bethlem myopathy and Ullrich congenital muscular dystrophy. We have identified a Ullrich congenital muscular dystrophy patient with compound heterozygous mutations in α2(VI). The first mutation causes skipping of exon 24, and the mRNA is degraded by nonsense-mediated decay. The second mutation is a two-amino acid deletion in the C1 VWA domain. Recombinant C1 domains containing the deletion are insoluble and retained intracellularly, indicating that the mutation has detrimental effects on domain folding and structure. Despite this, mutant α2(VI) chains retain the ability to associate into monomers, dimers, and tetramers. However, we show that secreted mutant tetramers containing structurally abnormal C1 VWA domains are unable to associate further into microfibrils, directly demonstrating the critical importance of a correctly folded α2(VI) C1 domain in microfibril formation.     

Analysis of human red cell spectrin tetramer (head-to-head) assembly using complementary univalent peptides.

The mass-driven assembly of spectrin dimers to form tetramers involves two equal head-to-head alpha-beta associations and requires at least 30 degrees C for interconversion to occur readily. In this paper, the properties of tetramer formation were investigated using two complementary univalent peptides (the alpha I domain and beta monomers). Since the alpha I domain lacks an essential nucleation site required for side-to-side (lateral) heterodimer assembly [Speicher et al. (1992) J. Biol. Chem. 267, 14775-14782], these two peptides can only assemble head-to-head at a single site. This head-to-head assembly readily occurs at lower temperatures, indicating the temperature barrier for dimer-tetramer interconversion is caused by a conformational constraint of the dimer. This constraint, a closed hairpin loop, is released when the laterally associated partner is removed. The univalent alpha I-beta binding affinity at 37 degrees C (Ka = 1.4 x 10(5) M-1) is similar to the dimer-tetramer association constant at the same temperature. As the temperature is decreased from 37 to 0 degrees C, the alpha I-beta binding affinity increases about 32-fold. In contrast with head-to-head associations involving dimers, the second-order rate constants of two complementary univalent peptides (i.e., alpha I and beta) are dramatically higher, and the estimated activation energy (about 50 kJ mol-1) is about 5-fold lower. An open dimer conformation is an obligatory high-energy intermediate required for dimer-tetramer interconversion, and opening the dimer hairpin loop contributes about 190 kJ mol-1 to the activation energy for tetramer association.(ABSTRACT TRUNCATED AT 250 WORDS)     

Aggregation of deoxyhemoglobin subunits.

The formation of deoxyhemoglobin was examined by measuring the heme spectral change that accompanies the aggregation of isolated alpha and beta chains. At low hemeconcentrations (less than 10(-5) M), tetramer formation can be described by two consecutive, second order reactions representing the aggregation of monomers followed by the association of alphabeta dimers. At neutral pH, the rates of monomer and dimer aggregation are roughly the same, approximately 5 X 10(5) M(-1) X(-1) at 20 degrees. Raising or lowering the pH results in a uniform decrease of both aggregation rates due presumably to repulsion of positively charged subunits at acid pH and repulsion of negatively charged subunits at alkaline pH. Addition of p-hydroxymercuribenzoate to alpha chains lowers the rate of monomer aggregation whereas addition of mercurials to the beta subunits appears to lower both the rate of monomer and the rate of dimer aggregation. At high heme concentrations (greater than 10(-5) M) or in the presence of organic phosphates, the rate of chain aggregation becomes limited, in part, by the slow dissociation of beta chain tetramers. In the case of inositol hexaphosphate, the rate of hemoglobin formation exhibits a bell-shaped dependence on phosphate concentration. When intermediate concentrations of inositol hexaphosphate (approximately 10(-4 M) are preincubated with beta subunits, a slow first order time course is observed and exhibits a half-time of about 8 min. As more inositol hexaphosphate is added, the chain aggregation reaction begins to occur more rapidly. Eventually at about 10(-2) M inositol hexaphospate, the time course becomes almost identical to that observed in the absence of phosphates. The increase in the velocity of the chain aggregation reaction at high phosphate concentrations suggests strongly that inositol hexaphosphate binds to beta monomers and, if added in sufficiently large amounts, promotes beta4 dissociation. A quantitative analysis of these results showed that the affinity of beta monomers for inositol hexaphosphate is the same as that of alphabeta dimers. Only when tetramers are formed, either alpha2beta2 or beta4, is a marked increase in affinity for inositol hexaphosphate observed.     

Kinked collagen VI tetramers and reduced microfibril formation as a result of Bethlem myopathy and introduced triple helical glycine mutations.

Mutations in the genes that code for collagen VI subunits, COL6A1, COL6A2, and COL6A3, are the cause of the dominantly inherited disorder, Bethlem myopathy. Glycine mutations that interrupt the Gly-X-Y repetitive amino acid sequence that forms the characteristic collagen triple helix have been defined in four families; however, the effects of these mutations on collagen VI biosynthesis, assembly, and structure have not been determined. In this study, we examined the consequences of Bethlem myopathy triple helical glycine mutations in the alpha1(VI) and alpha2(VI) chains, as well as engineered alpha3(VI) triple helical glycine mutations. Although the Bethlem myopathy and introduced mutations that are toward the N terminus of the triple helix did not measurably affect collagen VI intracellular monomer, dimer, or tetramer assembly, or secretion, the introduced mutation toward the C terminus of the helix severely impaired association of the mutant alpha3(VI) chain with alpha1(VI) and alpha2(VI). Association of the three chains was not completely prevented, however; and some non-disulfide bonded tetramers were secreted. Examination of the secreted Bethlem myopathy and engineered mutant collagen VI by negative staining electron microscopy revealed the striking finding that in all the cell lines a significant proportion of the tetramers contained a kink in the supercoiled triple helical region. Collagen VI tetramers from all of the mutant cell lines also showed a reduced ability to form microfibrils. These results provide the first evidence of the biosynthetic consequences of collagen VI triple helical glycine mutations and indicate that Bethlem myopathy results not only from the synthesis of reduced amounts of structurally normal protein but also from the presence of mutant collagen VI in the extracellular matrix.     

Functional consequences of mutations at the allosteric interface in hetero- and homo-hemoglobin tetramers.

A seminal difference exists between the two types of chains that constitute the tetrameric hemoglobin in vertebrates. While alpha chains associate weakly into dimers, beta chains self-associate into tightly assembled tetramers. While heterotetramers bind ligands cooperatively with moderate affinity, homotetramers bind ligands with high affinity and without cooperativity. These characteristics lead to the conclusion that the beta 4 tetramer is frozen in a quaternary R-state resembling that of liganded HbA. X-ray diffraction studies of the liganded beta 4 tetramers and molecular modeling calculations revealed several differences relative to the native heterotetramer at the "allosteric" interface (alpha 1 beta 2 in HbA) and possibly at the origin of a large instability of the hypothetical deoxy T-state of the beta 4 tetramer. We have studied natural and artificial Hb mutants at different sites in the beta chains responsible for the T-state conformation in deoxy HbA with the view of restoring a low ligand affinity with heme-heme interaction in homotetramers. Functional studies have been performed for oxygen equilibrium binding and kinetics after flash photolysis of CO for both hetero- and homotetramers. Our conclusion is that the "allosteric" interface is so precisely tailored for maintaining the assembly between alpha beta dimers that any change in the side chains of beta 40 (C6), beta 99 (G1), and beta 101 (G3) involved in the interface results in increased R-state behavior. In the homotetramer, the mutations at these sites lead to the destabilization of the beta 4 hemoglobin and the formation of lower affinity noncooperative monomers.     

Formation and carbon monoxide‐dependent dissociation of Allochromatium vinosum cytochrome c′ oligomers using domain‐swapped dimers

The number of artificial protein supramolecules has been increasing; however, control of protein oligomer formation remains challenging. Cytochrome c′ from Allochromatium vinosum (AVCP) is a homodimeric protein in its native form, where its protomer exhibits a four‐helix bundle structure containing a covalently bound five‐coordinate heme as a gas binding site. AVCP exhibits a unique reversible dimer–monomer transition according to the absence and presence of CO. Herein, domain‐swapped dimeric AVCP was constructed and utilized to form a tetramer and high‐order oligomers. The X‐ray crystal structure of oxidized tetrameric AVCP consisted of two monomer subunits and one domain‐swapped dimer subunit, which exchanged the region containing helices αA and αB between protomers. The active site structures of the domain‐swapped dimer subunit and monomer subunits in the tetramer were similar to those of the monomer subunits in the native dimer. The subunit–subunit interactions at the interfaces of the domain‐swapped dimer and monomer subunits in the tetramer were also similar to the subunit–subunit interaction in the native dimer. Reduced tetrameric AVCP dissociated to a domain‐swapped dimer and two monomers upon CO binding. Without monomers, the domain‐swapped dimers formed tetramers, hexamers, and higher‐order oligomers in the absence of CO, whereas the oligomers dissociated to domain‐swapped dimers in the presence of CO, demonstrating that the domain‐swapped dimer maintains the CO‐induced subunit dissociation behavior of native ACVP. These results suggest that protein oligomer formation may be controlled by utilizing domain swapping for a dimer–monomer transition protein.     

Significance of beta116 His (G18) at alpha1beta1 contact sites for alphabeta assembly and autoxidation of hemoglobin

The role of heterotetramer interaction sites in assembly and autoxidation of hemoglobin is not clear. The importance of beta(116His) (G-18) and gamma(116Ile) at one of the alpha1beta1 or alpha1gamma1 interaction sites for homo-dimer formation and assembly in vitro of beta and gamma chains, respectively, with alpha chains to form human Hb A and Hb F was assessed using recombinant beta(116His)(-->)(Asp), beta(116His)(-->)(Ile), and beta(112Cys)(-->)(Thr,116His)(-->)(Ile) chains. Even though beta chains (e.g., 116 His) are in monomer/tetramer equilibrium, beta(116Asp) chains showed only monomer formation. In contrast, beta(116Ile) and beta(112Thr,116Ile) chains showed homodimer and homotetramer formation like gamma-globin chains which contain 116 Ile. Assembly rates in vitro of beta(116Ile) or beta(112Thr,116Ile) chains with alpha chains were 340-fold slower, while beta(116Asp) chains promoted assembly compared to normal beta-globin chains. These results indicate that amino acid hydrophobicity at the G-18 position in non-alpha chains plays a key role in homotetramer, dimer, and monomer formation, which in turn plays a critical role in assembly with alpha chains to form Hb A and Hb F. These results also suggest that stable dimer formation of gamma-globin chains must not occur in vivo, since this would inhibit association with alpha chains to form Hb F. The role of beta(116His) (G-18) in heterotetramer-induced stabilization of the bond with oxygen in hemoglobin was also assessed by evaluating autoxidation rates using recombinant Hb tetramers containing these variant globin chains. Autoxidation rates of alpha(2)beta(2)(116Asp) and alpha(2)beta(2)(116Ile) tetramers showed biphasic kinetics with the faster rate due to alpha chain oxidation and the slower to the beta chain variants whose rates were 1.5-fold faster than that of normal beta-globin chains. In addition, NMR spectra of the heme area of these two hemoglobin variant tetramers showed similar resonance peaks, which are different from those of Hb A. Oxygen-binding properties of alpha(2)beta(2)(116His)(-->)(Asp) and alpha(2)beta(2)(116His)(-->)(Ile), however, showed slight alteration compared to Hb A. These results suggest that the beta116 amino acid (G18) plays a critical role in not only stabilizing alpha1beta1 interactions but also in inhibiting hemoglobin oxidation. However, stabilization of the bonds between oxygen and heme may not be dependent on stabilization of alpha1beta1 interactions. Tertiary structural changes may lead to changes in the heme region in beta chains after assembly with alpha chains, which could influence stability of dioxygen binding of beta chains.     

Protein conformational heterogeneity as a binding catalyst: ESI-MS study of hemoglobin H formation

Our previous studies of hemoglobin tetramer assembly in vitro suggested that the initial step in the oligomerization process, which ultimately dictates the high fidelity of the heterotetramer (alpha*beta*)2 assembly, is the binding of a flexible heme-free beta-globin chain to a highly ordered heme-bound alpha*-globin. In this work, we extend these studies to investigate formation of the homotetrameric hemoglobin H, whose formation in vivo is a well-documented clinical consequence of significant overexpression of beta-globin in alpha-thalassemic disorders. Upon reconstitution of the isolated beta-globin with excess heme, the predominant species in the ESI mass spectrum corresponds to the homotetramer beta*4, alongside homodimeric species and monomeric beta-globin chains in both apo and holo forms. The assembly process of the hemoglobin H homotetramer apparently follows a scenario similar to that of a normal heterodimeric hemoglobin (alpha*beta*)2 species, with the asymmetric binding event between compact and flexible polypeptide chains being the initial step. The extreme importance of large-scale chain dynamics and conformational heterogeneity for the protein assembly process is highlighted by the inability of highly structured alpha-globins to undergo ordered oligomerization to form dimers and tetramers as opposed to indiscriminate aggregation.     

Quaternary structure of pig liver phosphofructokinase

The quaternary structure of phosphofructokinase from pig liver has been studied by electron microscopy. Particles ranging in size from tetramers to long flexible chains of tetramers were commonly observed. Phosphofructokinase tetramers are square planar and approximately 110 A on a side; individual subunits are roughly spherical, with a mean radius of 28 A. Chains are formed by end-to-end association of tetramers rather than by tetramer stacking. The geometry of association implies that phosphofructokinase tetramers possess D2 symmetry, with distinct isologous bonding domains for dimer, tetramer, and chain formation.     

Three binding sites in protein-disulfide isomerase cooperate in collagen prolyl 4-hydroxylase tetramer assembly

Protein-disulfide isomerase (PDI) is a modular polypeptide consisting of four domains, a, b, b', and a'. It is a ubiquitous protein folding catalyst that in addition functions as the beta-subunit in vertebrate collagen prolyl 4-hydroxylase (C-P4H) alpha(2)beta(2) tetramers. We report here that point mutations in the primary peptide substrate binding site in the b' domain of PDI did not inhibit C-P4H assembly. Based on sequence conservation, additional putative binding sites were identified in the a and a' domains. Mutations in these sites significantly reduced C-P4H tetramer assembly, with the a domain mutations generally having the greater effect. When the a or a' domain mutations were combined with the b' domain mutation I272W tetramer assembly was further reduced, and more than 95% of the assembly was abolished when mutations in the three domains were combined. The data indicate that binding sites in three PDI domains, a, b', and a', contribute to efficient C-P4H tetramer assembly. The relative contributions of these sites were found to differ between Caenorhabditis elegans C-P4H alphabeta dimer and human alpha(2)beta(2) tetramer formation.     

Determination of the hemoglobin surface domains that react with cytochrome b5

We have compared the photoinitiated electron-transfer (ET) reaction between cytochrome b(5) (b(5)) and zinc mesoporphyrin-substituted hemoglobin [(ZnM)Hb] and Hb variants in order to determine whether b(5) binds to the subunit surface of either or both Hb chains, or to sites which span the dimer--dimer interface. Because the dimer--dimer interface would be disrupted for monomers or alpha beta dimers, we studied the reaction of b(5) with alpha ZnM chains and (ZnM)Hb beta W37E, which exists as alpha beta dimers in solution. Triplet quenching titrations of the ZnHb proteins with Fe(3+)b(5) show that the binding affinity and ET rate constants for the alpha-chains are the same when they are incorporated into a Hb tetramer or dimer, or exist as monomers. Likewise, the parameters for beta-chains in tetramers and dimers differ minimally. In parallel, we have modified the surface of the Hb chains by neutralizing the heme propionates through the preparation of zinc deuterioporphyrin dimethyl ester hemoglobin, (ZnD-DME)Hb. The charge neutralization increases the ET rate constants 100-fold for the alpha-chains and 40-fold for the beta-chains (but has has little effect on the affinity of either chain type for b(5), similar to earlier results for myoglobin). Together, these results indicate that b(5) binds to sites at the subunit surface of each chain rather than to sites which span the dimer-dimer interface. The charge-neutralization results further suggest that b(5) binds over a broad area of the subunit face, but reacts only in a minority population of binding geometries.     

Detection and binding properties of GABA(A) receptor assembly intermediates

Density gradient centrifugation of native and recombinant gamma-aminobutyric acid, type A (GABA(A)) receptors was used to detect assembly intermediates. No such intermediates could be identified in extracts from adult rat brain or from human embryonic kidney (HEK) 293 cells transfected with alpha(1), beta(3), and gamma(2) subunits and cultured at 37 degrees C. However, subunit dimers, trimers, tetramers, and pentamers were found in extracts from the brain of 8-10-day-old rats and from alpha(1)beta(3)gamma(2) transfected HEK cells cultured at 25 degrees C. In both systems, alpha(1), beta(3), and gamma(2) subunits could be identified in subunit dimers, indicating that different subunit dimers are formed during GABA(A) receptor assembly. Co-transfection of HEK cells with various combinations of full-length and C-terminally truncated alpha(1) and beta(3) or alpha(1) and gamma(2) subunits and co-immunoprecipitation with subunit-specific antibodies indicated that even subunits containing no transmembrane domain can assemble with each other. Whereas alpha(1)gamma(2), alpha(1)Ngamma(2), alpha(1)gamma(2)N, and alpha(1)Ngamma(2)N, combinations exhibited specific [(3)H]Ro 15-1788 binding, specific [(3)H]muscimol binding could only be found in alpha(1)beta(3) and alpha(1)beta(3)N, but not in alpha(1)Nbeta(3) or alpha(1)Nbeta(3)N combinations. This seems to indicate that a full-length alpha(1) subunit is necessary for the formation of the muscimol-binding site and for the transduction of agonist binding into channel gating.     

Molecular characterization of peripherin-2 and rom-1 mutants responsible for digenic retinitis pigmentosa

Peripherin-2 and Rom-1 are homologous tetraspanning membrane proteins that assemble into noncovalent tetramers and higher order disulfide-linked oligomers implicated in photoreceptor disc morphogenesis. Individuals who coinherit a L185P peripherin-2 mutation and a null or G113E rom-1 mutation are afflicted with retinitis pigmentosa, whereas individuals who inherit only one defective gene are normal. We examined the expression, subunit assembly, and disulfide-mediated oligomerization of L185P and L185A peripherin-2 and L188P Rom-1 by velocity sedimentation, co-immunoprecipitation, and cross-linking. These mutants formed noncovalent dimers under disulfide-reducing conditions but failed to assemble into core tetramers. Under nonreducing conditions, L185P dimers formed disulfide-linked tetramers but not higher order oligomers. L185P coassembled with wild-type peripherin-2 and Rom-1 to form tetramers and higher order disulfide-linked oligomers characteristic of the wild-type proteins. The G113E Rom-1 mutant expressed 20-fold lower than wild-type Rom-1, indicating that it behaves mechanistically as a null allele. We conclude that Leu(185) of peripherin-2 (Leu(188) of Rom-1) is critical for tetramer but not dimer formation and that the core tetramer has 2-fold symmetry. Peripherin-2-containing tetramers are required for higher order disulfide-linked oligomer formation. The level of these oligomers is critical for stable photoreceptor disc formation and the digenic retinitis pigmentosa disease phenotype.     

Orientation of type VI collagen monomers in molecular aggregates

Type VI collagen, prepared from guanidine extracts of human amnion, contains very little monomeric material, the major forms being dimers and tetramers. In order to study the orientation of the molecules in these aggregates, they were digested with pepsin followed by bacterial collagenase. Two fragments were isolated, one containing part of the inner globular domain still attached to part of the triple helix and the other containing large fragments of the outer globular domain. Each fraction was further analyzed; peptides were isolated and their amino-terminal amino acid sequences determined. By comparing the determined sequences with published data, it was found that the outer globular domain contained sequences derived from the amino-terminal domain of all three chains of type VI collagen whereas the inner globular domain contained sequences from the carboxy-terminal domain. This provided direct chemical evidence that dimers and tetramers of type VI collagen are formed by overlapping carboxy-terminal regions of the monomers.     

Differences in collagen prolyl 4-hydroxylase assembly between two Caenorhabditis nematode species despite high amino acid sequence identity of the enzyme subunits.

The collagen prolyl 4-hydroxylases (P4Hs) are essential for proper extracellular matrix formation in multicellular organisms. The vertebrate enzymes are alpha(2)beta(2) tetramers, in which the beta subunits are identical to protein disulfide isomerase (PDI). Unique P4H forms have been shown to assemble from the Caenorhabditis elegans catalytic alpha subunit isoforms PHY-1 and PHY-2 and the beta subunit PDI-2. A mixed PHY-1/PHY-2/(PDI-2)(2) tetramer is the major form, while PHY-1/PDI-2 and PHY-2/PDI-2 dimers are also assembled but less efficiently. Cloning and characterization of the orthologous subunits from the closely related nematode Caenorhabditis briggsae revealed distinct differences in the assembly of active P4H forms in spite of the extremely high amino acid sequence identity (92-97%) between the C. briggsae and C. elegans subunits. In addition to a PHY-1/PHY-2(PDI-2)(2) tetramer and a PHY-1/PDI-2 dimer, an active (PHY-2)(2)(PDI-2)(2) tetramer was formed in C. briggsae instead of a PHY-2/PDI-2 dimer. Site-directed mutagenesis studies and generation of inter-species hybrid polypeptides showed that the N-terminal halves of the Caenorhabditis PHY-2 polypeptides determine their assembly properties. Genetic disruption of C. briggsae phy-1 (Cb-dpy-18) via a Mos1 insertion resulted in a small (short) phenotype that is less severe than the dumpy (short and fat) phenotype of the corresponding C. elegans mutants (Ce-dpy-18). C. briggsae phy-2 RNA interference produced no visible phenotype in the wild type nematodes but produced a severe dumpy phenotype and larval arrest in phy-1 mutants. Genetic complementation of the C. briggsae and C. elegans phy-1 mutants was achieved by injection of a wild type phy-1 gene from either species.