The role of individual amino acids in the dimerization of CR4 and ACR4 transmembrane domains

CRINKLY4 is a growth factor-like plant receptor kinase designated as CR4 in Zea mays and ACR4 in Arabidopsis. Using the TOXCAT system, a genetic assay that measures helix interactions in a natural membrane environment, we have previously demonstrated that the dimerization potential of the ACR4 transmembrane (TM) domain is significantly weaker than that of CR4 TM domain, even though 13 of the 24 residues are identical. Neither of the TM domains contain the GxxxG motif that has been shown to be important for the dimerization of the TM segments of several receptors. To further investigate the relationship between protein sequence and dimerization potential, we (a) mutated each of the 11 differing residues in the CR4 TM domain to the corresponding residue of ACR4 (b) made reciprocal mutations in ACR4 and (c) made hybrids consisting of half CR4 and half ACR4 TM domains. Our results suggest that most mutations in ACR4 or CR4 TM domains have low to moderate effects on the dimerization potential and that residues in the N-terminal half of the CR4 TM domain are important for dimerization.     

Structural requirements for catalysis and dimerization of human methionine adenosyltransferase I/III

We have used site-directed mutagenesis to probe the structural requirements for catalysis and dimerization of human hepatic methionine adenosyltransferase (hMAT). We built a homology model of the dimeric hMAT III inferred by the crystal structure of the highly homologous Escherichia coli MAT dimer. The active sites of both enzymes comprise the same amino acids and are located in the inter-subunit interface. All of the amino acids predicted to be in the hMAT III active site were mutated, as well as residues in a conserved ATP binding region. All of the mutations except one severely affected catalytic activity. On the other hand, dimerization was affected only by single mutations of three different residues, all on one monomer. The homology model suggested that the side chains of these residues stabilized the monomer and participated in a bridge between subunits consisting of a network of metal and phosphate ions. In agreement with this observation, we demonstrated that dimerization cannot occur in the absence of phosphate.     

Characterization and colocalization of steroid binding and dimerization activities in the mouse estrogen receptor

We have identified a region within the steroid binding domain of the mouse estrogen receptor that is required for both receptor dimerization and high affinity DNA binding. Analysis of sequences in this region revealed that a heptad repeat of hydrophobic residues was conserved in all members of the nuclear receptor superfamily. Single amino acid substitutions of residues in the N-terminal half, but not the C-terminal half, of the repeat prevented receptor dimerization. Steroid binding was abolished by point mutations in the center of the conserved region, implying that the steroid binding and dimerization domains overlap. The role of this region in steroid receptor function is discussed in relation to other models of protein dimerization and DNA binding.     

The catalysis of the SARS 3C-like protease is under extensive regulation by its extra domain

The 3C-like protease of the severe acute respiratory syndrome (SARS) coronavirus has a C-terminal extra domain in addition to the chymotrypsin-fold adopted by picornavirus 3C proteases hosting the complete catalytic machinery. Previously we identified the extra domain to be involved in enzyme dimerization which has been considered essential for the catalytic activity. In an initial attempt to map out the extra-domain residues critical for dimerization, we have systematically generated 15 point mutations, five deletions and one triple mutation and subsequently characterized them by enzymatic assay, dynamic light scattering, CD and NMR spectroscopy. The results led to identification of four regions critical for enzyme dimerization. Interestingly, Asn214Ala mutant with a significant tendency to form a monomer still retained approximately 30% activity, indicating that the relationship between the activity and dimerization might be very complex. Very surprisingly, two regions (one over Ser284-Thr285-Ile286 and another around Phe291) were discovered on which Ala-mutations significantly increased the enzymatic activities. Based on this, a super-active triple-mutant STI/A with a 3.7-fold activity enhancement was thus engineered by mutating residues Ser284, Thr285 and Ile286 to Ala. The dynamic light scattering, CD and NMR characterizations indicate that the wild-type (WT) and STI/A mutant share similar structural and dimerization properties, thus implying that in addition to dimerization, the extra domain might have other mechanisms to regulate the catalytic machinery. We rationalized these results based on the enzyme structure and consequently observed an interesting picture: the majority of the dimerization-critical residues plus Ser284-Thr285-Ile286 and Phe291 are clustered together to form a nano-scale channel passing through the central region of the enzyme. We therefore speculate that this channel might play a role in relaying regulatory effects from the extra domain to the catalytic machinery.     

Interactions Crucial for Three-Dimensional Domain Swapping in the HP-RNase Variant PM8

The structural determinants that are responsible for the formation of higher order associations of folded proteins remain unknown. We have investigated the role on the dimerization process of different residues of a domain-swapped dimer human pancreatic ribonuclease variant. This variant is a good model to study the dimerization and swapping processes because dimer and monomer forms interconvert, are easily isolated, and only one dimeric species is produced. Thus, simple models for the swapping process can be proposed. The dimerization (dissociation constant) and swapping propensity have been studied using different variants with changes in residues that belong to different putative molecular determinants of dimerization. Using NMR spectroscopy, we show that these mutations do not substantially alter the overall conformation and flexibility, but affect the residue level stability. Overall, the most critical residues for the swapping process are those of one subunit that interact with the hinge loop of another one-subunit residue, stabilizing it in a conformation that favors the interchange. Tyr²⁵, Gln¹⁰¹, and Pro¹⁹, with Asn¹⁷, Ser²¹, and Ser²³, are found to be the most significant; notably, Glu¹⁰³ and Arg¹⁰⁴, which were postulated to form salt bridges that would stabilize the dimer, are not critical for dimerization.     

The composition rather than position of polar residues (QxxS) drives aspartate receptor transmembrane domain dimerization in vivo

Transmembrane (TM) helix association is an important process affecting the function of many integral membrane proteins. Consequently, aberrations in this process are associated with diseases. Unfortunately, our knowledge of the factors that control this oligomerization process in the membrane milieu is limited at best. Previous studies have shown a role for polar residues in the assembly of synthetic peptides in vitro and the association of de novo-designed TM helices in vivo. Here we examined, for the first time, the involvement of polar residues in the dimerization of a biological TM domain in its natural environment. We analyzed both the involvement of polar residues in the dimerization process and whether their influence is position-dependent. For this purpose, we used the TM domain of the Escherichia coli aspartate receptor (Tar) and 10 single and double mutants. Polar to nonpolar mutations in the sequence demonstrated the role of the QxxS motif in the dimerization of the Tar TM domain. Moreover, creating a GxxxG motif, instead of the polar motif, almost completely abolished dimerization. Swapping positions between two wild-type polar residues did not affect dimerization, implying a similar contribution from both positions. Interestingly, mutants that contain two identical strong polar residues, EE and QQ, demonstrated a substantially higher level of dimerization than a QE mutant, although all three TM domains contain two strong polar residues. This result suggests that, in addition to the polarity of the residues, the formation of symmetric bonds also plays a role in dimer stability. The results of this study may facilitate a rational modulation of membrane protein function for therapeutic purposes.     

GxxxG motifs within the amyloid precursor protein transmembrane sequence are critical for the etiology of Abeta42

Processing of the amyloid precursor protein (APP) by beta- and gamma-secretases leads to the generation of amyloid-beta (Abeta) peptides with varying lengths. Particularly Abeta42 contributes to cytotoxicity and amyloid accumulation in Alzheimer's disease (AD). However, the precise molecular mechanism of Abeta42 generation has remained unclear. Here, we show that an amino-acid motif GxxxG within the APP transmembrane sequence (TMS) has regulatory impact on the Abeta species produced. In a neuronal cell system, mutations of glycine residues G29 and G33 of the GxxxG motif gradually attenuate the TMS dimerization strength, specifically reduce the formation of Abeta42, leave the level of Abeta40 unaffected, but increase Abeta38 and shorter Abeta species. We show that glycine residues G29 and G33 are part of a dimerization site within the TMS, but do not impair oligomerization of the APP ectodomain. We conclude that gamma-secretase cleavages of APP are intimately linked to the dimerization strength of the substrate TMS. The results demonstrate that dimerization of APP TMS is a risk factor for AD due to facilitating Abeta42 production.     

Modulation of interprotomer relationships is important for activation of dimeric calcium-sensing receptor

The extracellular calcium-sensing receptor (CaR) forms a disulfide-linked dimer through cysteine residues within its N-terminal extracellular domain (ECD). However, these disulfide linkages are dispensable for the formation of the dimeric CaR and for the functional reconstitution of two inactive CaRs. In this study, using molecular modeling, mutagenesis, and biochemical and biophysical analyses, we examined the importance of two leucine residues, Leu-112 and Leu-156, in the ECD of the CaR for the non-covalent dimerization and functional reconstitution. We found that the mutant receptor carrying L112S and L156S still exists mostly as a covalently linked dimer and has a significantly higher apparent affinity for calcium than the wild-type receptor. However, a combination of four mutations, L112S, L156S, C129S, and C131S, significantly reduces receptor dimerization and markedly inactivates the CaR. We also found that L112S and L156S mediate the non-covalent intermolecular interactions important for functional reconstitution. Because mutating either the two cysteines or the two leucines enhances the apparent ligand affinity of the CaR, it is likely that the changes in intermolecular relationships between two receptor protomers linked by these leucines and cysteines are essential for receptor activation. Moreover, these mutations are unlikely to have negative effects on the secondary structure of each protomer of the dimeric receptor. Thus, the detrimental effects of the combined mutations on the function of the CaR further suggest that CaR dimerization through its ECD is essential for the formation of a functional tertiary structure of the CaR.     

Dominant role of the 5' TAR bulge in dimerization of HIV-1 genomic RNA, but no evidence of TAR-TAR kissing during in vivo virus assembly

The 5' untranslated region of HIV-1 genomic RNA (gRNA) contains two stem-loop structures that appear to be equally important for gRNA dimerization: the 57-nucleotide 5' TAR, at the very 5' end, and the 35-nucleotide SL1 (nucleotides 243-277). SL1 is well-known for containing the dimerization initiation site (DIS) in its apical loop. The DIS is a six-nucleotide palindrome. Here, we investigated the mechanism of TAR-directed gRNA dimerization. We found that the trinucleotide bulge (UCU24) of the 5' TAR has dominant impacts on both formation of HIV-1 RNA dimers and maturation of the formed dimers. The ΔUCU trinucleotide deletion strongly inhibited the first process and blocked the other, thus impairing gRNA dimerization as severely as deletion of the entire 5' TAR, and more severely than deletion of the DIS, inactivation of the viral protease, or most severe mutations in the nucleocapsid protein. The apical loop of TAR contains a 10-nucleotide palindrome that has been postulated to stimulate gRNA dimerization by a TAR-TAR kissing mechanism analogous to the one used by SL1 to stimulate dimerization. Using mutations that strongly destabilize formation of the TAR palindrome duplex, as well as compensatory mutations that restore duplex formation to a wild-type-like level, we found no evidence of TAR-TAR kissing, even though mutations nullifying the kissing potential of the TAR palindrome could impair dimerization by a mechanism other than hindering of SL1. However, nullifying the kissing potential of TAR had much less severe effects than ΔUCU. By not uncovering a dimerization mechanism intrinsic to TAR, our data suggest that TAR mutations exert their effect 3' of TAR, yet not on SL1, because TAR and SL1 mutations have synergistic effects on gRNA dimerization.     

Sequence dependence of BNIP3 transmembrane domain dimerization implicates side-chain hydrogen bonding and a tandem GxxxG motif in specific helix-helix interactions

The transmembrane domain of the pro-apoptotic protein BNIP3 self-associates strongly in membranes and in detergents. We have used site-directed mutagenesis to analyze the sequence dependence of BNIP3 transmembrane domain dimerization, from which we infer the physical basis for strong and specific helix-helix interactions in this system. Hydrophobic substitutions identify six residues as critical to dimerization, and the pattern of sensitive residues suggests that the BNIP3 helices interact at a right-handed crossing angle. Based on the dimerization propensities of single point mutants, we propose that: polar residues His173 and Ser172 make inter-monomer hydrogen bonds to one another through their side-chains; Ala176, Gly180, and Gly184 form a tandem GxxxG motif that allows close approach of the helices; and Ile183 makes inter-monomer van der Waals contacts. Since neither the tandem GxxxG motif nor the hydrogen bonding pair is sufficient to drive dimerization, our results demonstrate the importance of sequence context for either hydrogen bonding or GxxxG motif involvement in BNIP3 transmembrane helix-helix interactions. In this study, hydrophobic substitutions away from the six interfacial positions have almost no effect on dimerization, confirming the expectation that hydrophobic replacements affect helix-helix interactions only if they interfere with packing or hydrogen bonding by interfacial residues. However, changes to slightly polar residues are somewhat disruptive even when located away from the interface, and the degree of disruption correlates with the decrease in hydrophobicity. Changing the hydrophobicity of the BNIP3 transmembrane domain alters its helicity and protection of its backbone amides. We suggest that polar substitutions decrease the fraction of dimer by stabilizing an unfolded monomeric state of the transmembrane span, rather than by affecting helix-helix interactions. This result has broad implications for interpreting the sequence dependence of membrane protein stability in detergents.     

A highly conserved domain of the maize activator transposase is involved in dimerization

Previous studies have presented indirect evidence that the transposase of the maize transposable element Activator (TPase) is active as an oligomer and forms inactive macromolecular complexes expressed in large amounts. Here, we have identified and characterized a dimerization domain at the C terminus of the protein. This domain is the most highly conserved region in the transposases of elements belonging to the Activator superfamily (hAT element superfamily) and contains a characteristic signature motif. The isolated dimerization domain forms extremely stable dimers in vitro. Interestingly, mutations in five of the six conserved residues of the signature motif do not affect in vitro dimerization, whereas mutations in other, less strictly conserved residues of the signature motif do. Loss of dimerization in vitro correlates with loss of TPase activity in vivo. As revealed by in situ immunofluorescence staining of mutant TPase proteins, the dimerization domain also is involved in forming inactive macromolecular aggregates when overexpressed, and the TPase contains one or more additional interaction functions.     

Dimerization of the quorum-sensing transcription factor TraR enhances resistance to cytoplasmic proteolysis

TraR is a LuxR-type quorum-sensing protein encoded by the tumour-inducing plasmid of Agrobacterium tumefaciens . TraR requires the pheromone N-3-oxooctanoyl- l -homoserine lactone (OOHL) for biological activity, and is dimeric both in solution and when bound to DNA. Dimerization is mediated primarily by two α-helices, one in the N-terminal OOHL binding domain, and the other in the C-terminal DNA binding domain. Each of these helices forms a parallel coiled coil with the identical helix of the opposite subunit. We have previously shown that OOHL is essential for resistance to proteolysis, and here we asked whether dimerization is also required for protease resistance. We constructed a series of site-directed mutations at the dimer interface, and tested these mutants for activity in vivo . Alteration of residues A149, A150, A153, A222 and I229 completely abolished activity, while alteration of three other residues also caused significant defects. All mutants were tested for dimerization as well as for specific DNA binding. The cellular abundance of these proteins in A. tumefaciens was measured using Western immunoblots and OOHL sequestration, while the half-life was measured by pulse-chase radiolabelling. We found a correlation between defects in in vivo activity, in vitro dimerization, DNA binding and protein half-life. We conclude that dimerization of TraR enhances resistance to cellular proteases.     

Lethal mutations in the major homology region and their suppressors act by modulating the dimerization of the rous sarcoma virus capsid protein C‐terminal domain

An infective retrovirus requires a mature capsid shell around the viral replication complex. This shell is formed by about 1500 capsid protein monomers, organized into hexamer and pentamer rings that are linked to each other by the dimerization of the C‐terminal domain (CTD). The major homology region (MHR), the most highly conserved protein sequence across retroviral genomes, is part of the CTD. Several mutations in the MHR appear to block infectivity by preventing capsid formation. Suppressor mutations have been identified that are distant in sequence and structure from the MHR and restore capsid formation. The effects of two lethal and two suppressor mutations on the stability and function of the CTD were examined. No correlation with infectivity was found for the stability of the lethal mutations (D155Y‐CTD, F167Y‐CTD) and suppressor mutations (R185W‐CTD, I190V‐CTD). The stabilities of three double mutant proteins (D155Y/R185W‐CTD, F167Y/R185W‐CTD, and F167Y/I190V‐CTD) were additive. However, the dimerization affinity of the mutant proteins correlated strongly with biological function. The CTD proteins with lethal mutations did not dimerize, while those with suppressor mutations had greater dimerization affinity than WT‐CTD. The suppressor mutations were able to partially correct the dimerization defect caused by the lethal MHR mutations in double mutant proteins. Despite their dramatic effects on dimerization, none of these residues participate directly in the proposed dimerization interface in a mature capsid. These findings suggest that the conserved sequence of the MHR has critical roles in the conformation(s) of the CTD that are required for dimerization and correct capsid maturation. Proteins 2013. © 2012 Wiley Periodicals, Inc.     

The strong dimerization of the transmembrane domain of the fibroblast growth factor receptor (FGFR) is modulated by C‐terminal juxtamembrane residues

The fibroblast growth factor receptor 3 (FGFR3) is a member of the FGFR subfamily of the receptor tyrosine kinases (RTKs) involved in signaling across the plasma membrane. Generally, ligand binding leads to receptor dimerization and activation. Dimerization involves the transmembrane (TM) domain, where mutations can lead to constitutive activation in certain cancer types and also in skeletal malformations. Thus, it has been postulated that FGFR homodimerization must be inherently weak to allow regulation, a feature reminiscent of α and β integrin TM interactions. However, we show herein that in FGFR3‐TM, four C‐terminal residues, CRLR, have a profound destabilizing effect in an otherwise strongly dimerizing TM peptide. In the absence of these four residues, the dimerizing propensity of FGFR3‐TM is comparable to glycophorin, as shown using various detergents. In addition, the expected enhanced dimerization induced by the mutation associated to the Crouzon syndrome A391E, was observed only when these four C‐terminal residues were present. In the absence of these four residues, A391E was dimer‐destabilizing. Finally, using site specific infrared dichroism and convergence with evolutionary conservation data, we have determined the backbone model of the FGFR3‐TM homodimer in model lipid bilayers. This model is consistent with, and correlates with the effects of, most known pathological mutations found in FGFR‐TM.     

Influence of the C-terminus of the glycophorin A transmembrane fragment on the dimerization process

The monomer-dimer equilibrium of the glycophorin A (GpA) transmembrane (TM) fragment has been used as a model system to investigate the amino acid sequence requirements that permit an appropriate helix-helix packing in a membrane-mimetic environment. In particular, we have focused on a region of the helix where no crucial residues for packing have been yet reported. Various deletion and replacement mutants in the C-terminal region of the TM fragment showed that the distance between the dimerization motif and the flanking charged residues from the cytoplasmic side of the protein is important for helix packing. Furthermore, selected GpA mutants have been used to illustrate the rearrangement of TM fragments that takes place when leucine repeats are introduced in such protein segments. We also show that secondary structure of GpA derivatives was independent from dimerization, in agreement with the two-stage model for membrane protein folding and oligomerization.     

Requirement of PKR Dimerization Mediated by Specific Hydrophobic Residues for Its Activation by Double-Stranded RNA and Its Antigrowth Effects in Yeast

The roles of protein dimerization and double-stranded RNA (dsRNA) binding in the biochemical and cellular activities of PKR, the dsRNA-dependent protein kinase, were investigated. We have previously shown that both properties of the protein are mediated by the same domain. Here we show that dimerization is mediated by hydrophobic residues present on one side of an amphipathic α-helical structure within this domain. Appropriate substitution mutations of residues on that side produced mutants with increased or decreased dimerization activities. Using these mutants, we demonstrated that dimerization is not essential for dsRNA binding. However, enhancing dimerization artificially, by providing an extraneous dimerization domain, increased dsRNA binding of both wild-type and mutant proteins. In vitro, the dimerization-defective mutants could not be activated by dsRNA but were activated normally by heparin. In Saccharomyces cerevisiae, unlike wild-type PKR, these mutants could not inhibit cell growth and the dsRNA-binding domain of the dimerization-defective mutants could not prevent the antigrowth effect of wild-type PKR. These results demonstrate the biological importance of the dimerization properties of PKR.     

Intermonomer Hydrogen Bonds Enhance GxxxG-Driven Dimerization of the BNIP3 Transmembrane Domain: Roles for Sequence Context in Helix-Helix Association in Membranes

We determined the sequence dependence of human BNIP3 transmembrane domain dimerization using the biological assay TOXCAT. Mutants in which intermonomer hydrogen bonds between Ser172 and His173 are abolished show moderate interaction, indicating that side-chain hydrogen bonds contribute to dimer stability but are not essential to dimerization. Mutants in which a GxxxG motif composed of Gly180 and Gly184 has been abolished show little or no interaction, demonstrating the critical nature of the GxxxG motif to BNIP3 dimerization. These findings show that side-chain hydrogen bonds can enhance the intrinsic dimerization of a GxxxG motif and that sequence context can control how hydrogen bonds influence helix-helix interactions in membranes. The dimer interface mapped by TOXCAT mutagenesis agrees closely with the interfaces observed in the NMR structure and inferred from mutational analysis of dimerization on SDS-PAGE, showing that the native dimer structure is retained in detergents. We show that TOXCAT and SDS-PAGE give complementary and consistent information about BNIP3 transmembrane domain dimerization: TOXCAT is insensitive to mutations that have modest effects on self-association in detergents but readily discriminates among mutations that completely disrupt detergent-resistant dimerization. The close agreement between conclusions reached from TOXCAT and SDS-PAGE data for BNIP3 suggests that accurate estimates of the relative effects of mutations on native-state protein-protein interactions can be obtained even when the detergent environment is strongly disruptive.     

PAS-mediated dimerization of soluble guanylyl cyclase revealed by signal transduction histidine kinase domain crystal structure

Signal transduction histidine kinases (STHK) are key for sensing environmental stresses, crucial for cell survival, and attain their sensing ability using small molecule binding domains. The N-terminal domain in an STHK from Nostoc punctiforme is of unknown function yet is homologous to the central region in soluble guanylyl cyclase (sGC), the main receptor for nitric oxide (NO). This domain is termed H-NOXA (or H-NOBA) because it is often associated with the heme-nitric oxide/oxygen binding (H-NOX) domain. A structure-function approach was taken to investigate the role of H-NOXA in STHK and sGC. We report the 2.1 A resolution crystal structure of the dimerized H-NOXA domain of STHK, which reveals a Per-Arnt-Sim (PAS) fold. The H-NOXA monomers dimerize in a parallel arrangement juxtaposing their N-terminal helices and preceding residues. Such PAS dimerization is similar to that previously observed for EcDOS, AvNifL, and RmFixL. Deletion of 7 N-terminal residues affected dimer organization. Alanine scanning mutagenesis in sGC indicates that the H-NOXA domains of sGC could adopt a similar dimer organization. Although most putative interface mutations did decrease sGCbeta1 H-NOXA homodimerization, heterodimerization of full-length heterodimeric sGC was mostly unaffected, likely due to the additional dimerization contacts of sGC in the coiled-coil and catalytic domains. Exceptions are mutations sGCalpha1 F285A and sGCbeta1 F217A, which each caused a drastic drop in NO stimulated activity, and mutations sGCalpha1 Q368A and sGCbeta1 Q309A, which resulted in both a complete lack of activity and heterodimerization. Our structural and mutational results provide new insights into sGC and STHK dimerization and overall architecture.     

Mechanistic link between PKR dimerization, autophosphorylation, and eIF2alpha substrate recognition

The antiviral protein kinase PKR inhibits protein synthesis by phosphorylating the translation initiation factor eIF2alpha on Ser51. Binding of double-stranded RNA to the regulatory domains of PKR promotes dimerization, autophosphorylation, and the functional activation of the kinase. Herein, we identify mutations that activate PKR in the absence of its regulatory domains and map the mutations to a recently identified dimerization surface on the kinase catalytic domain. Mutations of other residues on this surface block PKR autophosphorylation and eIF2alpha phosphorylation, while mutating Thr446, an autophosphorylation site within the catalytic-domain activation segment, impairs eIF2alpha phosphorylation and viral pseudosubstrate binding. Mutational analysis of catalytic-domain residues preferentially conserved in the eIF2alpha kinase family identifies helix alphaG as critical for the specific recognition of eIF2alpha. We propose an ordered mechanism of PKR activation in which catalytic-domain dimerization triggers Thr446 autophosphorylation and specific eIF2alpha substrate recognition.