Molecular mechanisms of constitutive activity: mutations at position 111 of the angiotensin AT1 receptor.

A possible molecular mechanism for the constitutive activity of mutants of the angiotensin type 1 receptor (AT1) at position 111 was suggested by molecular modeling. This involves a cascade of conformational changes in spatial positions of side chains along transmembrane helix (TM3) from L112 to Y113 to F117, which in turn, results in conformational changes in TM4 (residues I152 and M155) leading to the movement of TM4 as a whole. The mechanism is consistent with the available data of site-directed mutagenesis, as well as with correct predictions of constitutive activity of mutants L112F and L112C. It was also predicted that the double mutant N111G/L112A might possess basal constitutive activity comparable with that of the N111G mutant, whereas the double mutants N111G/Y113A, N111G/F117A, and N111G/I152A would have lower levels of basal activity. Experimental studies of the above double mutants showed significant constitutive activity of N111G/L112A and N111G/F117A. The basal activity of N111G/I152A was higher than expected, and that of N111G/Y113A was not determined due to poor expression of the mutant. The proposed mechanism of constitutive activity of the AT(1) receptor reveals a novel nonsimplistic view on the general problem of constitutive activity, and clearly demonstrates the inherent complexity of the process of G protein-coupled receptor (GPCR) activation.     

Identification of secretin,vasoactive intestinal peptide and glucagon binding sites: from chimaeric receptors to point mutations

We have identified two basic residues that are important for the recognition of secretin and vasoactive intestinal peptide (VIP) by their respective receptors. These two peptides containing an Asp residue at position 3 interacted with an arginine residue in transmembrane helix 2 (TM2) of the receptor, and the lysine residue in extracellular loop 1 (ECL1) stabilized the active receptor conformation induced by the ligand. The glucagon receptor possesses a Lys instead of an Arg in TM2, and an Ile instead of Lys in ECL1; it markedly prefers a Gln side chain in position 3 of the ligand. Our results suggested that, in the wild-type receptor, the Ile side chain prevented access to the TM2 Lys side chain, but oriented the glucagon Gln(3) side chain to its proper binding site. In the double mutant, the ECL1 Lys allowed an interaction between negatively charged residues in position 3 of glucagon and the TM2 Arg, resulting in efficient receptor activation by [Asp(3)]glucagon as well as by glucagon.     

Key NAD+-binding residues in human 15-hydroxyprostaglandin dehydrogenase

NAD(+)-dependent 15-hydroxyprostaglandin dehydrogenase (15-PGDH), a member of the short-chain dehydrogenase/reductase (SDR) family, catalyzes the first step in the catabolic pathways of prostaglandins and lipoxins, and is believed to be the key enzyme responsible for the biological inactivation of these biologically potent eicosanoids. The enzyme utilizes NAD(+) specifically as a coenzyme. Potential amino acid residues involved in binding NAD(+) and facilitating enzyme catalysis have been partially identified. In this report, we propose that three more residues in 15-PGDH, Ile-17, Asn-91, and Val-186, are also involved in the interaction with NAD(+). Site-directed mutagenesis was used to examine their roles in binding NAD(+). Several mutants (I17A, I17V, I17L, I17E, I17K, N91A, N91D, N91K, V186A, V186I, V186D, and V186K) were prepared, expressed as glutathione S-transferase (GST) fusion enzymes in Escherichia coli, and purified by GSH-agarose affinity chromatography. Mutants I17E, I17K, N91L, N91K, and V186D were found to be inactive. Mutants N91A, N91D, V186A, and V186K exhibited comparable activities to the wild type enzyme. However, mutants I17A, I17V, I17L, and V186I had higher activity than the wild type. Especially, the activities of I17L and V186I were increased nearly 4- and 5-fold, respectively. The k(cat)/K(m) ratios of all active mutants for PGE(2) were similar to that of the wild type enzyme. However, the k(cat)/K(m) ratios of mutants I17A and N91A for NAD(+) were decreased 5- and 10-fold, respectively, whereas the k(cat)/K(m) ratios of mutants I17V, N91D, V186I, and V186K for NAD(+) were comparable to that of the wild type enzyme. The k(cat)/K(m) ratios of mutants I17L and V186A for NAD(+) were increased over nearly 2-fold. These results suggest that Ile-17, Asn-91, and Val-186 are involved in the interaction with NAD(+) and contribute to the full catalytic activity of 15-PGDH.     

Repulsive separation of the cytoplasmic ends of transmembrane helices 3 and 6 is linked to receptor activation in a novel thyrotropin receptor mutant (M626I)

Ligand-dependent activation of G protein-coupled receptors (GPCRs) involves repositioning of the juxtacytoplasmic ends of transmembrane helices TM3 and TM6. This concept, inferred from site-directed spin labeling studies, is supported by chemical cross-linking of the cytoplasmic ends of TM3 and TM6 blocking GPCR activation. Here we report a novel constitutive active mutation (M626I) in TM6 of the TSH receptor (TSHR), identified in affected members of a family with nonautoimmune hyperthyroidism. The specific constitutive activity of M626I, measured by its basal cAMP generation corrected for cell surface expression, was 13-fold higher than that of wild-type TSHR. Homology modeling of the TSHR serpentine domain based on the rhodopsin crystal structure suggests that M626 faces the side chain of I515 of TM3 near the membrane-cytoplasmic junction. Steric hindrance of the introduced isoleucine by I515 is consistent with the fact that shorter or more flexible side chains at position 626 did not increase constitutivity. Furthermore, a reciprocal mutation at position 515 (I515M), when introduced into the M626I background, acts as revertant mutation by allowing accommodation of the isoleucine sidechain at position 626 and fully restoring the constitutive activity to the level of wild-type TSHR. Thus, repulsive separation of the juxtacytoplasmic TM6 and TM3 in the M626I model conclusively demonstrates a direct link between the opening of this cytoplasmic face of the receptor structure and G protein coupling.     

Engineered zinc-binding sites confirm proximity and orientation of transmembrane helices I and III in the human serotonin transporter

The human serotonin transporter (hSERT) regulates neurotransmission by removing released serotonin (5-HT) from the synapse. Previous studies identified residues in SERT transmembrane helices (TMHs) I and III as interaction sites for substrates and antagonists. Despite an abundance of data supporting a 12-TMH topology, the arrangement of the TMHs in SERT and other biogenic amine transporters remains undetermined. A high-resolution structure of a bacterial leucine transporter that demonstrates homology with SERT has been reported, thus providing the basis for the development of a SERT model. Zn2+-binding sites have been utilized in transporters and receptors to define experimentally TMH proximity. Focusing on residues near the extracellular ends of hSERT TMHs I and III, we engineered potential Zn2+-binding sites between V102 or W103 (TMH I) and I179-L184 (TMH III). Residues were mutated to either histidine or cysteine. TMH I/III double mutants were constructed from functional TMH I mutants, and Zn2+ sensitivity was assessed. Dose-response assays suggest an approximately twofold increase in sensitivity to Zn2+ inhibition at the hSERT V102C/M180C and approximately fourfold at the V102C/I179C mutant compared to the hSERT V102C single mutant. We propose that the increased sensitivity to Zn2+ confirms the proximity and the orientation of TMHs I and III in the membrane. Homology modeling of the proposed Zn2+-binding sites using the coordinates of the Aquifex aeolicus leucine transporter structure provided a structural basis for interpreting the results and developing conclusions.     

An Arg307 to Gln polymorphism within the ATP-binding site causes loss of function of the human P2X7 receptor

The P2X(7) receptor is a ligand-gated channel that is highly expressed on mononuclear cells of the immune system and that mediates ATP-induced apoptosis. Wide variations in the function of the P2X receptor have been observed, explained in part by (7)loss-of-function polymorphisms that change Glu(496) to Ala (E496A) and Ile(568) to Asn (I568N). In this study, a third polymorphism, which substitutes an uncharged glutamine for the highly positively charged Arg(307) (R307Q), has been found in heterozygous dosage in 12 of 420 subjects studied. P2X(7) function was measured by ATP-induced fluxes of Rb(+), Ba(2+), and ethidium(+) into peripheral blood monocytes or various lymphocyte subsets and was either absent or markedly decreased. Transfection experiments showed that P2X(7) carrying the R307Q mutation lacked either channel or pore function despite robust protein synthesis and surface expression of the receptor. The monoclonal antibody (clone L4) that binds to the extracellular domain of wild type P2X(7) and blocks P2X(7) function failed to bind to the R307Q mutant receptor. Differentiation of monocytes to macrophages up-regulated P2X(7) function in cells heterozygous for the R307Q to a value 10-40% of that for wild type macrophages. However, macrophages from a subject who was double heterozygous for R307Q/I568N remained totally non-functional for P2X(7), and lymphocytes from the same subject also lacked ATP-stimulated phospholipase D activity. These data identify a third loss-of-function polymorphism affecting the human P2X(7) receptor, and since the affected Arg(307) is homologous to those amino acids essential for ATP binding to P2X(1) and P2X(2), it is likely that this polymorphism abolishes the binding of ATP to the extracellular domain of P2X(7).     

Improving the catalytic efficiency of a meta-cleavage product hydrolase (CumD) from Pseudomonas fluorescens IP01

The meta-cleavage product hydrolase from Pseudomonas fluorescens IP01 (CumD) hydrolyzes 2-hydroxy-6-oxo-7-methylocta-2,4-dienoate (6-isopropyl HODA) in the cumene (isopropylbenzene) degradation pathway. To modulate the substrate specificity and catalytic efficiency of CumD toward substrates derived from monocyclic aromatic compounds, we constructed the CumD mutants, A129V, I199V, and V227I, as well as four types of double and triple mutants. Toward substrates with smaller side chains (e.g. 2-hydroxy-6-oxohepta-2,4-dienoate; 6-ethyl-HODA), the k(cat)/K(m) values of the single mutants were 4.2-11 fold higher than that of the wild type enzyme and 1.8-4.7 fold higher than that of the meta-cleavage product hydrolase from Pseudomonas putida F1 (TodF). The A129V mutant showed the highest k(cat)/K(m) value for 2-hydroxy-6-oxohepta-2,4-dienoate (6-ethyl-HODA). The crystal structure of the A129V mutant was determined at 1.65 A resolution, enabling location of the Ogamma atom of the Ser103 side chain. A chloride ion was bound to the oxyanion hole of the active site, and mutant enzymes at the residues forming this site were also examined. The k(cat) values of Ser34 mutants were decreased 2.9-65 fold, suggesting that the side chain of Ser34 supports catalysis by stabilizing the anionic oxygen of the proposed intermediate state (gem-diolate). This is the first crystal structure determination of CumD in an active form, with the Ser103 residue, one of the catalytically essential "triad", being intact.     

An activation switch in the ligand binding pocket of the C5a receptor

Although agonists are thought to occupy binding pockets within the seven-helix core of serpentine receptors, the topography of these binding pockets and the conformational changes responsible for receptor activation are poorly understood. To identify the ligand binding pocket in the receptor for complement factor 5a (C5aR), we assessed binding affinities of hexapeptide ligands, each mutated at a single position, for seven mutant C5aRs, each mutated at a single position in the putative ligand binding site. In ChaW (an antagonist) and W5Cha (an agonist), the side chains at position 5 are tryptophan and cyclohexylalanine, respectively. Comparisons of binding affinities indicated that the hexapeptide residue at this position interacts with two C5aR residues, Ile-116 (helix III) and Val-286 (helix VII); in a C5aR model these two side chains point toward one another. Both the I116A and the V286A mutations markedly increased binding affinity of W5Cha but not that of ChaW. Moreover, ChaW, the antagonist hexapeptide, acted as a full agonist on the I116A mutant. These results argue that C5aR residues Ile-116 and Val-286 interact with the side chain at position 5 of the hexapeptide ligand to form an activation switch. Based on this and previous work, we present a docking model for the hexapeptide within the C5aR binding pocket. We propose that agonists induce a small change in the relative orientations of helices III and VII and that these helices work together to allow movement of helix VI away from the receptor core, thereby triggering G protein activation.     

An evolutionary bridge to a new protein fold

Arc repressor bearing the N11L substitution (Arc-N11L) is an evolutionary intermediate between the wild type protein, in which the region surrounding position 11 forms a beta-sheet, and a double mutant 'switch Arc', in which this region is helical. Here, Arc-N11L is shown to be able to adopt either the wild type or mutant conformations. Exchange between these structures occurs on the millisecond time scale in a dynamic equilibrium in which the relative populations of each fold depend on temperature, solvent conditions and ligand binding. The N11L mutation serves as an evolutionary bridge from the beta-sheet to the helical fold because in the mutant, Leu is an integral part of the hydrophobic core of the new structure but can also occupy a surface position in the wild type structure. Conversely, the polar Asn 11 side chain serves as a negative design element in wild type Arc because it cannot be incorporated into the core of the mutant fold.     

Functional role of transmembrane helix 7 in the activation of the heptahelical lutropin receptor

A member of the G protein-coupled receptor superfamily, the LH receptor (LHR), and the two other glycoprotein hormone receptors are distinguished from the other members by the presence of a relatively large N-terminal extracellular domain that is responsible for high-affinity ligand binding. Transmembrane helix (TMH) 7 of LHR is amphipathic, with an extended face containing only hydrophobic side chains and another containing both hydrophobic and polar side chains with potential hydrogen bond donor and acceptor functions. Since several reports have shown the importance of this helix in ligand-mediated signaling, we have used Ala scanning mutagenesis to study eight amino acid residues of rat LHR that are invariant in the three glycoprotein hormone receptors, Leu586, Val587, Asn593, Ser594, Cys595, Asn597, Phe604, and Thr605. The wild type (WT) and mutant cDNAs were transiently transfected into COS-7 cells for characterization by human CG (hCG) binding and cAMP production. No differences were detected in dissociation constants (K(d)S) or basal cAMP production relative to WT LHR, but three categories of LHR mutants were distinguished from WT LHR based upon their expression levels and responsiveness to hCG: 1) comparable or higher expression but reduced ligand responsiveness (N593A and C595A), 2) reduced expression and ligand responsiveness (N597A and T605A), and 3) comparable expression and responsiveness (L586A, V587A, S594A, and F604A). Three other mutants, C595M, F604Y, and T605Y, were comparable to WT LHR in ligand responsiveness. To provide more information on Asn593 and Asn597, a total of 12 replacements were investigated. Of considerable interest and potential significance was the finding that many of the replacements in LHR resulted in either loss of function (N593A, Q, S; N597R) or gain of function (N593R and N597Q), this being the first evidence of a position in LHR that, depending upon the nature of the amino acid residue, can result in constitutive activation and/or diminished responsiveness to ligand. The results of molecular modeling and energy minimization of TMHs 6 and 7, based on a postulated interaction between Asp556 (TMH 6) and Asn593/Asn597 (TMH 7), indicated that, while there is not a correlation between function and predicted energies of WT LHR and the mutants, reorientation of one or both helices is responsible for the functional changes observed. Possible interactions of TMHs 3 and 4 and of 5 and 6 were suggested by molecular modeling. Ten mutants were prepared of two amino acid residues that are invariant in the glycoprotein hormone receptors and have side chain hydrogen bond donor and acceptor function, Glu429 in TMH 3 and Asn513 in TMH 5. Expression levels and hCG-mediated signaling were reduced in most of the LHR mutants, but none of these exhibited constitutive receptor activation. We conclude that Glu429 is not critical for receptor function, while Asn513 appears to be particularly important in receptor folding and/or trafficking. The results reported herein indicate an important role for TMH 7, and particularly Asn593 and Asn597, in the process of receptor activation. Moreover, these two asparagines, although in close proximity to each other in TMH 7, are quite distinct in function as evidenced by certain replacements that can lead to loss of function in one and gain of function in the other.     

From molecular details of the interplay between transmembrane helices of the thyrotropin receptor to general aspects of signal transduction in family a G-protein-coupled receptors (GPCRs)

Transmembrane helices (TMHs) 5 and 6 are known to be important for signal transduction by G-protein-coupled receptors (GPCRs). Our aim was to characterize the interface between TMH5 and TMH6 of the thyrotropin receptor (TSHR) to gain molecular insights into aspects of signal transduction and regulation. A proline at TMH5 position 5.50 is highly conserved in family A GPCRs and causes a twist in the helix structure. Mutation of the TSHR-specific alanine (Ala-593^5.50) at this position to proline resulted in a 20-fold reduction of cell surface expression. This indicates that TMH5 in the TSHR might have a conformation different from most other family A GPCRs by forming a regular α-helix. Furthermore, linking our own and previous data from directed mutagenesis with structural information led to suggestions of distinct pairs of interacting residues between TMH5 and TMH6 that are responsible for stabilizing either the basal or the active state. Our insights suggest that the inactive state conformation is constrained by a core set of polar interactions among TMHs 2, 3, 6, and 7 and in contrast that the active state conformation is stabilized mainly by non-polar interactions between TMHs 5 and 6. Our findings might be relevant for all family A GPCRs as supported by a statistical analysis of residue properties between the TMHs of a vast number of GPCR sequences.     

Kinetic properties of mutant human thymidine kinase 2 suggest a mechanism for mitochondrial DNA depletion myopathy

Thymidine kinase 2 (TK2) is a mitochondrial (mt) pyrimidine deoxynucleoside salvage enzyme involved in mtDNA precursor synthesis. The full-length human TK2 cDNA was cloned and sequenced. A discrepancy at amino acid 37 within the mt leader sequence in the DNA compared with the determined peptide sequence was found. Two mutations in the human TK2 gene, His-121 to Asn and Ile-212 to Asn, were recently described in patients with severe mtDNA depletion myopathy (Saada, A., Shaag, A., Mandel, H., Nevo, Y., Eriksson, S., and Elpeleg, O. (2001) Nat. Genet. 29, 342-344). The same mutations in TK2 were introduced, and the mutant enzymes, prepared in recombinant form, were shown to have similar subunit structure to wild type TK2. The I212N mutant showed less than 1% activity as compared with wild type TK2 with all deoxynucleosides. The H121N mutant enzyme had normal K(m) values for thymidine (dThd) and deoxycytidine (dCyd), 6 and 11 microm, respectively, but 2- and 3-fold lower V(max) values as compared with wild type TK2 and markedly increased K(m) values for ATP, leading to decreased enzyme efficiency. Competition experiments revealed that dCyd and dThd interacted differently with the H121N mutant as compared with the wild type enzyme. The consequences of the two point mutations of TK2 and the role of TK2 in mt disorders are discussed.     

Phenylalanine 138 in the second intracellular loop of human thromboxane receptor is critical for receptor-G-protein coupling.

Eicosanoid receptors exhibit a highly conserved ERY(C)XXV(I)XXPL sequence in the second intracellular loop. The carboxyl end of this motif contains a bulky hydrophobic amino acid (L,I,V, or F). In human thromboxane A2 receptor (TXA(2)R), phenylalanine 138 is located at the carboxyl end of this highly conserved motif. This study examined the function of the F138 in G protein coupling. F138 was mutated to aspartic acid (D) and tyrosine (Y), respectively. Both mutants F138D and F138Y showed similar ligand binding activity to that of the wild type TXA(2)R. The Kd and Bmax values of either mutant were comparable to those of the wild type receptor. However, both mutants showed significant impairment of agonist induced Ca(2+) signaling and phospholipase C activation. These results suggest that the F138 plays a key role in G protein coupling.     

Role of cleavage and shedding in human thyrotropin receptor function and trafficking.

The thyrotropin receptor (TSHR) undergoes a cleavage at the cell membrane, leading to a heterodimer, comprising an alpha extracellular and a beta-transmembrane and intracellular subunits, held together by disulfide bonds. Moreover, part of the alpha-subunit of the receptor is shed from thyroid and transfected L cells. To understand the role of cleavage and shedding, we constructed deletion mutants starting, respectively, at the most N-terminal (S314), and C-terminal (L378) cleavage sites previously mapped, corresponding to free beta1 or beta2-subunits without further modification of receptor structure. Functional studies performed in COS-7 cells showed that both mutants display an increased basal activation of the cAMP pathway when compared with the wild-type receptor. By contrast, deletion of almost the entire extracellular domain of the receptor (TM409 mutant) totally impairs receptor function, thus confirming a role of the juxtamembrane extracellular region in receptor function. The beta1 mutant receptor exhibited an increased internalization when compared with the hormone-activated holoreceptor. Furthermore, no recycling was observed in the case of the beta1 mutant receptor. These observations strongly argue for a different conformation between the receptor activated by cleavage and shedding on the one hand, and the receptor activated by the ligand on the other hand. Cleavage and shedding of a receptor already activated by a transmembrane activating mutation M453T further increase its activity, showing that the extracellular domain still exerts a negative effect in the M453T holoreceptor. An increased internalization of the M453T receptor was observed when compared with the wild-type receptor, which was increased further in the corresponding truncated beta1-M453T receptor. Thus cleavage and shedding yield TSHR activation but also increase internalization of the free beta-subunits of the receptor, the latter mechanism limiting simultaneously excessive receptor signaling. The combined effects may be responsible for the limited basal constitutive activation of the cAMP pathway that is detected for the TSHR.     

Charged residues at the intracellular boundary of transmembrane helices 2 and 3 independently affect constitutive activity of Kaposi's sarcoma-associated herpesvirus G protein-coupled receptor

Because charged residues at the intracellular ends of transmembrane helix (TMH) 2 and TMH3 of G protein-coupled receptors (GPCRs) affect signaling, we performed mutational analysis of these residues in the constitutively signaling Kaposi's sarcoma-associated herpesvirus GPCR (KSHV-GPCR). KSHV-GPCR contains the amino acid sequence Val-Arg-Tyr rather than the Asp/Glu-Arg-Tyr ((D/E)RY) motif at the intracellular end of TMH3. Mutation of Arg-143 to Ala (R143A) or Gln (R143Q) abolished constitutive signaling whereas R143K exhibited 50% of the basal activity of KSHV-GPCR. R143A was not stimulated by agonist, whereas R143Q was stimulated by growth-related oncogene-alpha, and R143K, similar to KSHV-GPCR, was stimulated further. These findings show that Arg-143 is critical for signal generation in KSHV-GPCR. In other GPCRs, Arg in this position may act as a signaling switch by movement of its sidechain from a hydrophilic pocket in the TMH bundle to a position outside the bundle. In rhodopsin, the Arg of Glu-Arg-Tyr interacts with the adjacent Asp to constrain Arg outside the TMH bundle. V142D was 70% more active than KSHV-GPCR, suggesting that an Arg residue, which is constrained outside the bundle by interacting with Asp-142, leads to a receptor that signals more actively. Because the usually conserved Asp in the middle of TMH2 is not present in KSHV-GPCR, we tested whether Asp-83 at the intracellular end of TMH2 was involved in signaling. D83N and D83A were 110 and 190% more active than KSHV-GPCR, respectively. The double mutant D83A/V142D was 510% more active than KSHV-GPCR. That is, cosubstitutions of Asp-83 by Ala and Val-142 by Asp act synergistically to increase basal signaling. A model of KSHV-GPCR predicts that Arg-143 interacts with residues in the TMH bundle and that the sidechain of Asp-83 does not interact with Arg-143. These data are consistent with the hypothesis that Arg-143 and Asp-83 independently affect the signaling activity of KSHV-GPCR.     

Tryptophan scanning mutagenesis in the alphaM3 transmembrane domain of the Torpedo californica acetylcholine receptor: functional and structural implications

The functional role of the alphaM3 transmembrane domain of the Torpedo nicotinic acetylcholine receptor (AChR) was characterized by performing tryptophan-scanning mutagenesis at 13 positions within alphaM3, from residue M278 through I290. The expression of the mutants in Xenopus oocytes was measured by [(125)I]-alpha-bungarotoxin binding, and ACh receptor function was evaluated by using a two-electrode voltage clamp. Six mutants (L279W, F280W, I283W, V285W, S288W, and I289W) were expressed at lower levels than the wild type. Most of these residues have been proposed to face the interior of the protein. The I286W mutant was expressed at 2.4-fold higher levels than the wild type, and the two lipid-exposed mutations, F284W and S287W, were expressed at similar levels as wild type. Binding assays indicated that the alphaM3 domain can accommodate bulky groups in almost all positions. Three mutations, M282W, V285W, and I289W, caused a loss of receptor function, suggesting that the tryptophan side chains alter the conformational changes required for channel assembly or ion channel function. This loss of function suggests that these positions may be involved in helix-helix contacts that are critical for channel gating. The lipid-exposed mutation F284W enhances the receptor macroscopic response at low ACh concentrations and decreases the EC(50). Taken together, our results suggest that alphaM3 contributes to the gating machinery of the nicotinic ACh receptor and that alphaM3 is comprised of a mixture of two types of helical structures.     

The role of common and rare MC4R variants and FTO polymorphisms in extreme form of obesity

Melanocortin 4 receptor (MC4R) is an important regulator of food intake and number of studies report genetic variations influencing the risk of obesity. Here we explored the role of common genetic variation from MC4R locus comparing with SNPs from gene FTO locus, as well as the frequency and functionality of rare MC4R mutations in cohort of 380 severely obese individuals (BMI > 39 kg/m²) and 380 lean subjects from the Genome Database of Latvian Population (LGDB). We found correlation for two SNPs—rs11642015 and rs62048402 in the fat mass and obesity-associated protein (FTO) with obesity but no association was detected for rs17782313 located in the MC4R locus in these severely obese individuals. We sequenced the whole gene MC4R coding region in all study subjects and found five previously known heterozygous non-synonymous substitutions V103I, I121T, S127L, V166I and I251L. Expression in mammalian cells showed that the S127L, V166I and double V103I/S127L mutant receptors had significantly decreased quantity at the cell surface compared to the wild type MC4R. We carried out detailed functional analysis of V166I that demonstrated that, despite low abundance in plasma membrane, the V166I variant has lower EC₅₀ value upon αMSH activation than the wild type receptor, while the level of AGRP inhibition was decreased, implying that V166I cause hyperactive satiety signalling. Overall, this study suggest that S127L may be the most frequent functional MC4R mutation leading to the severe obesity in general population and provides new insight into the functionality of population based variants of the MC4R.     

In vivo and in vitro characterization of TEV protease mutants

Tobacco etch virus protease (TEVp) is frequently applied in the cleavage of fusion protein. However, production of TEV protease in Escherichia coli is hampered by low yield and poor solubility, and auto-cleavage of wild type TEVp gives rise to the loss-of-function. Previously it was reported that TEVp S219V displayed more stability, and TEVp variant containing T17S/N68D/I77V and double mutant L56V/S135G resulted in the enhanced production and solubility, respectively. Here, we introduced T17S/N68D/I77V in TEVp S219V to generate TEVpM1 and combined five amino acid mutations (T17S/L56V/N68D/I77V/S135G) in TEVp S219V to create TEVpM2. Among TEVp S219V, and two constructed variants, TEVpM2 displayed highest solubility and catalytic activity in vivo, using EmGFP as the solubility reporter, and the designed fusion protein as in vivo substrate containing an N-terminal hexahistidine tagged GST, a peptide sequence for thrombin and TEV cut and E. coli diaminopropionate ammonia-lyase. The purified TEVp mutants fused with double hexahistidine-tag at N and C terminus showed highest yield, solubility and cleavage efficiency. Mutations of five amino acid residues in TEVpM2 slightly altered protein secondary structure conformed by circular dichroism assay.     

Functional significance of the thyrotropin receptor germline polymorphism D727E

In a toxic thyroid adenoma we identified a novel somatic mutation that constitutively activates the thyrotropin receptor (TSHR). Two heterozygous point mutations at adjacent nucleotides led to a substitution of alanine with asparagine at codon 593 (A593N) in the fifth transmembrane helix of TSHR. This somatic mutation resided on the same TSHR allele with the germline polymorphism D727E. The functional characteristics of the single TSHR mutants A593N and D727E and of the double mutant A593N/D727E were studied in transiently transfected COS-7 cells. The TSHR mutants A593N and A593N/D727E constitutively activated the cAMP cascade, whereas the D727E mutant did not differ from the wild-type TSHR. Surprisingly, the double mutant's specific constitutive activity was 2.3-fold lower than the A593N mutant. Thus, the polymorphism significantly ameliorates G(alphas) protein activation in the presence of the gain-of-function mutation A593N, although it is functionally inert in the context of the wild-type TSHR.     

Dominant Negative Effect of Mutated Thyroid Stimulating Hormone Receptor (P556L) Causes Hypothyroidism in C.RF-Tshr(hyt/wild) Mice

C.RF-Tshr(hyt/hyt) mice have a mutated thyroid stimulating hormone receptor (P556L-TSHR) and these mice develop severe hypothyroidism. We found that C.RF-Tshr(hyt/wild) heterozygous mice are also in a hypothyroid state. Thyroid glands from C.RF-Tshr(hyt/wild) mice are smaller than those from wild-type mice, and (125)I uptake activities of the former are significantly lower than those in the latter. When TSHR (TSHR(W)) and P556L-TSHR (TSHR(M)) cDNAs were cloned and co-transfected into HEK 293 cells, the cells retained (125)I-TSH binding activity, but cAMP response to TSH was decreased to about 20% of HEK 293 cells transfected with TSHR(W) cDNA. When TSHR(W) and TSHR(M) were tagged with eCFP or eYFP, we observed fluorescence resonance energy transfer (FRET) in HEK 293 cells expressing TSHR(W)-eCFP and TSHR(W)-eYFP in the absence of TSH, but not in the presence of TSH. In contrast, we obtained FRET in HEK 293 cells expressing TSHR(W)-eCFP and TSHR (M)-eYFP, regardless of the presence or absence of TSH. These results suggest that P556L TSHR has a dominant negative effect on TSHR(W) by impairing polymer to monomer dissociation, which decreases TSH responsiveness and induces hypothyroidism in C.RF-Tshr(hyt/wild) mice.