Purification and characterization of a novel 7-kDa non-specific lipid transfer protein-2 from rice (Oryza sativa)

A novel 7-kDa non-specific lipid transfer protein-2 (nsLTP2) has been isolated from rice (Oryza sativa) seeds. In contrast to nsLTP1s, few nsLTP2s have been purified and characterized. Complete amino acid sequence of rice nsLTP2 was determined by N-terminal Edman degradation of the intact protein as well as the peptide fragments resulted from trypsin digestions. Rice nsLTP2 consists of 69 amino acid residues with eight conserved cysteines forming four disulfide bonds. The secondary structure of rice nsLTP2 is predominantly alpha-helical as determined by circular dichroism spectroscopy. Cysteine pairings of nsLTP2 have one miss match at Cys(35)-X-Cys(37) motif compared to nsLTP1. Primary structure analysis of various plant nsLTP2s revealed an interesting conservation of sequence features among nsLTP2 family.     

Determination of the disulfide structure of sillucin, a highly knotted, cysteine-rich peptide, by cyanylation/cleavage mass mapping

The disulfide structure of sillucin, a highly knotted, cysteine-rich, antimicrobial peptide, isolated from Rhizomucor pusillus, has been determined to be Cys2--Cys7, Cys12--Cys24, Cys13--Cys30, and Cys14--Cys21 by disulfide mass mapping based on partial reduction and CN-induced cleavage enabled by cyanylation. The denatured 30-residue peptide was subjected to partial reduction by tris(2-carboxyethyl)phosphine hydrochloride at pH 3 to produce a mixture of partially reduced sillucin species; the nascent sulfhydryl groups were immediately cyanylated by 1-cyano-4-(dimethylamino)pyridinium tetrafluoroborate. The cyanylated species, separated and collected during reversed phase high-performance liquid chromatography, were treated with aqueous ammonia, which cleaved the peptide chain on the N-terminal side of cyanylated cysteine residues. The CN-induced cleavage mixture was analyzed by matrix-assisted laser desorption ionization time-of-flight mass spectrometry before and after complete reduction of residual disulfide bonds in partially reduced and cyanylated species to mass map the truncated peptides to the sequence. Because the masses of the CN-induced cleavage fragments of both singly and doubly reduced and cyanylated sillucin are related to the linkages of the disulfide bonds in the original molecule, the presence of certain truncated peptide(s) can be used to positively identify the linkage of a specific disulfide bond or exclude the presence of other possible linkages.     

Determination of disulfide bonds in gamma-46 gliadin

The disulfide bonds in gamma-46 gliadin were identified: Cys173--Cys192, Cys212--Cys291, Cys165--Cys199 (or Cys200), Cys283--Cys200 (or Cys199). The disulfide-containing peptides were obtained by limited hydrolysis of the intact protein with chymotrypsin at an enzyme/substrate ratio of 1:1000 at 20 degrees C for 22 h with subsequent digestion of disulfide-containing fragments with trypsin and chymotrypsin. The locations of disulfide bonds were determined by sequencing disulfide-containing fractions and constituent peptides and comparison of the obtained sequences with the partial amino acid sequence of gamma-46 gliadin determined earlier.     

Structural characterization of recombinant soluble rat neuroligin 1: mapping of secondary structure and glycosylation by mass spectrometry

Neuroligins (NLs) are a family of transmembrane proteins that function in synapse formation and/or remodeling by interacting with beta-neurexins (beta-NXs) to form heterophilic cell adhesions. The large N-terminal extracellular domain of NLs, required for beta-NX interactions, has sequence homology to the alpha/beta hydrolase fold superfamily of proteins. By peptide mapping and mass spectrometric analysis of a soluble recombinant form of NL1, several structural features of the extracellular domain have been established. Of the nine cysteine residues in NL1, eight are shown to form intramolecular disulfide bonds. Disulfide pairings of Cys 117 to Cys 153 and Cys 342 to Cys 353 are consistent with disulfide linkages that are conserved among the family of alpha/beta hydrolase proteins. The disulfide bond between Cys 172 and Cys 181 occurs within a region of the protein encoded by an alternatively spliced exon. The disulfide pairing of Cys 512 and Cys 546 in NL1 yields a structural motif unique to the NLs, since these residues are highly conserved. The potential N-glycosylation sequons in NL1 at Asn 109, Asn 303, Asn 343, and Asn 547 are shown occupied by carbohydrate. An additional consensus sequence for N-glycosylation at Asn 662 is likely occupied. Analysis of N-linked oligosaccharide content by mass matching paradigms reveals significant microheterogeneous populations of complex glycosyl moieties. In addition, O-linked glycosylation is observed in the predicted stalk region of NL1, prior to the transmembrane spanning domain. From predictions based on sequence homology of NL1 to acetylcholinesterase and the molecular features of NL1 established from mass spectrometric analysis, a novel topology model for NL three-dimensional structure has been constructed.     

Isoform identification, recombinant production and characterization of the allergen lipid transfer protein 1 from pear (Pyr c 3)

Non-specific lipid transfer proteins belonging to LTP1 family represent the most important allergens for non pollen-related allergies to Rosaceae fruits in the Mediterranean area. Peach LTP1 (Pru p 3) is a major allergen and is considered the prototypic allergenic LTP. On the contrary, pear allergy without pollinosis seems to be under-reported when compared to other Rosaceae fruits suggesting that the as-yet-uncharacterized pear LTP1 (Pyr c 3) has in vivo a low allergenicity. We report here on the identification of four cDNAs encoding for LTP1 in pear fruits. The two isoforms exhibiting amino acid sequences most similar to those of peach and apple homologues were obtained as recombinant proteins. Such isoforms exhibited CD spectra and lipid binding ability typical of LTP1 family. Moreover, pear LTP1 mRNA was mainly found in the peel, as previously shown for other Rosaceae fruits. By means of IgE ELISA assays a considerable immunoreactivity of these proteins to LTP-sensitive patient sera was detected, even though allergic reactions after ingestion of pear were not reported in the clinical history of the patients. Finally, the abundance of LTP1 in protein extracts from pear peel, in which LTP1 from Rosaceae fruits is mainly confined, was estimated to be much lower as compared to peach peel. Our data suggest that the two isoforms of pear LTP1 characterized in this study possess biochemical features and IgE-binding ability similar to allergenic LTPs. Their low concentrations in pear might be the cause of the low frequency of LTP-mediated pear allergy.     

Effects of acylation on the structure,lipid binding,and transfer activity of wheat lipid transfer protein

Study of the effect of protein chemical acylation on their functional properties or activity often brings valuable information regarding structure-function relationships. We performed such work on wheat lipid transfer protein, LTP1, to investigate the role of grafted acyl chains on the lipid binding and transfer properties. LTP1 was acylated by using anhydride derivatives of various chain lengths from C2 to C6. Only the chemical modifications with hexanoic acid yielded a marked effect on the tertiary structure and a slight change in the secondary structure. The affinity of the modified proteins for myristoyl-lysophosphatidylcholine was similar to that of the native protein accompanied by a slight decrease in stoichiometry. Interestingly, the acylation of LTP1 enhanced the lipid transfer activity by at least a factor of 10 for hexanoic chain length. Finally, the grafting of acyl chains was investigated by means of molecular modelling, and an attempt is made to correlate with our experimental data.     

A novel lipid transfer protein from the dill Anethum graveolens L.: isolation,structure, heterologous expression,and functional characteristics

A novel lipid transfer protein, designated as Ag‐LTP, was isolated from aerial parts of the dill Anethum graveolens L. Structural, antimicrobial, and lipid binding properties of the protein were studied. Complete amino acid sequence of Ag‐LTP was determined. The protein has molecular mass of 9524.4 Da, consists of 93 amino acid residues including eight cysteines forming four disulfide bonds. The recombinant Ag‐LTP was overexpressed in Escherichia coli and purified. NMR investigation shows that the Ag‐LTP spatial structure contains four α ‐helices, forming the internal hydrophobic cavity, and a long C‐terminal tail. The measured volume of the Ag‐LTP hydrophobic cavity is equal to ~800 A³, which is much larger than those of other plant LTP1s. Ag‐LTP has weak antifungal activity and unpronounced lipid binding specificity but effectively binds plant hormone jasmonic acid. Our results afford further molecular insight into biological functions of LTP in plants. Copyright © 2015 European Peptide Society and John Wiley & Sons, Ltd.     

Comparison of lipid binding and transfer properties of two lipid transfer proteins from plants

Plant lipid transfer proteins (LTPs) are soluble proteins which are characterized by their in vitro ability to transfer phospholipids between two membranes. We have compared the functional properties of two LTPs purified from maize and wheat seeds knowing that, despite a high degree of sequence identity, the two proteins exhibit structural differences. It was found that wheat LTP had a lower transfer activity than the maize LTP, consistent with a lower kinetics of fatty acid binding. The lower affinity for the fatty acids of the wheat LTP could be explained by a narrowing occurring in the middle part of the binding site, as revealed by comparing the fluorescence spectra of various anthroyloxy-labeled fatty acids associated with the two LTPs. The affinity for some natural fatty acids was studied by competition with fluorescent fatty acids toward binding to the protein. Again, wheat LTP had a lower affinity for those molecules. All together, these observations reveal the complexity of the LTP family in plants, probably reflecting the multiple roles played by these proteins.     

The structure of the Cys-rich terminal domain of Hydra minicollagen, which is involved in disulfide networks of the nematocyst wall

The minicollagens found in the nematocysts of Hydra constitute a family of invertebrate collagens with unusual properties. They share a common modular architecture with a central collagen sequence ranging from 14 to 16 Gly-X-Y repeats flanked by polyproline/hydroxyproline stretches and short terminal domains that show a conserved cysteine pattern (CXXXCXXXCXXX-CXXXCC). The minicollagen cysteine-rich domains are believed to function in a switch of the disulfide connectivity from intra- to intermolecular bonds during maturation of the capsule wall. The solution structure of the C-terminal fragment including a minicollagen cysteine-rich domain of minicollagen-1 was determined in two independent groups by 1H NMR. The corresponding peptide comprising the last 24 residues of the molecule was produced synthetically and refolded by oxidation under low protein concentrations. Both presented structures are identical in their fold and disulfide connections (Cys2-Cys18, Cys6-Cys14, and Cys10-Cys19) revealing a robust structural motif that is supposed to serve as the polymerization module of the nematocyst capsule.     

The structure of "defective in induced resistance" protein of Arabidopsis thaliana, DIR1, reveals a new type of lipid transfer protein

Screening of transfer DNA (tDNA) tagged lines of Arabidopsis thaliana for mutants defective in systemic acquired resistance led to the characterization of dir1-1 (defective in induced resistance [systemic acquired resistance, SAR]) mutant. It has been suggested that the protein encoded by the dir1 gene, i.e., DIR1, is involved in the long distance signaling associated with SAR. DIR1 displays the cysteine signature of lipid transfer proteins, suggesting that the systemic signal could be lipid molecules. However, previous studies have shown that this signature is not sufficient to define a lipid transfer protein, i.e., a protein capable of binding lipids. In this context, the lipid binding properties and the structure of a DIR1-lipid complex were both determined by fluorescence and X-ray diffraction. DIR1 is able to bind with high affinity two monoacylated phospholipids (dissociation constant in the nanomolar range), mainly lysophosphatidyl cholines, side-by-side in a large internal tunnel. Although DIR1 shares some structural and lipid binding properties with plant LTP2, it displays some specific features that define DIR1 as a new type of plant lipid transfer protein. The signaling function associated with DIR1 may be related to a specific lipid transport that needs to be characterized and to an additional mechanism of recognition by a putative receptor, as the structure displays on the surface the characteristic PxxP structural motif reminiscent of SH3 domain signaling pathways.     

Solution structure of a lipid transfer protein extracted from rice seeds. Comparison with homologous proteins.

Nuclear magnetic resonance (NMR) spectroscopy was used to determine the three dimensional structure of rice nonspecific lipid transfer protein (ns-LTP), a 91 amino acid residue protein belonging to the broad family of plant ns-LTP. Sequence specific assignment was obtained for all but three HN backbone 1H resonances and for more than 95% of the 1H side-chain resonances using a combination of 1H 2D NOESY; TOCSY and COSY experiments at 293 K. The structure was calculated on the basis of four disulfide bridge restraints, 1259 distance constraints derived from 1H-1H Overhauser effects, 72 phi angle restraints and 32 hydrogen-bond restraints. The final solution structure involves four helices (H1: Cys3-Arg18, H2: Ala25-Ala37, H3: Thr41-Ala54 and H4: Ala66-Cys73) followed by a long C-terminal tail (T) with no observable regular structure. N-capping residues (Thr2, Ser24, Thr40), whose side-chain oxygen atoms are involved in hydrogen bonds with i + 3 amide proton additionally stabilize the N termini of the first three helices. The fourth helix involving Pro residues display a mixture of alpha and 3(10) conformation. The rms deviation of 14 final structures with respect to the average structure is 1.14 +/- 0.16 A for all heavy atoms (C, N, O and S) and 0.72 +/- 0.01 A for the backbone atoms. The global fold of rice ns-LTP is close to the previously published structures of wheat, barley and maize ns-LTPs exhibiting nearly identical pattern of the numerous sequence specific interactions. As reported previously for different four-helix topology proteins, hydrophobic, hydrogen bonding and electrostatic mechanisms of fold stabilization were found for the rice ns-LTP. The sequential alignment of 36 ns-LTP primary structures strongly suggests that there is a uniform pattern of specific long-range interactions (in terms of sequence), which stabilize the fold of all plant ns-LTPs.     

Solution structure of a tobacco lipid transfer protein exhibiting new biophysical and biological features

Plant lipid transfer proteins are small soluble extracellular proteins that are able to bind and transfer a variety of lipids in vitro. Recently, it has been proposed that lipid transfer proteins may play a key role in plant defence mechanisms, especially during the induction of systemic acquired resistance. However, very little is known about the proteins expressed in developing plants and tissues, since almost all the biophysical and structural data available to date on lipid transfer proteins originate from proteins present in storage tissues of monocot cereal seeds. In this paper, we report the structural and functional characteristics of a lipid transfer protein (named LTP1_1) constitutively expressed in young aerial organs of Nicotiana tabacum (common tobacco). The unlabelled and uniformly labelled proteins were produced in the yeast Pichia pastoris, and we determined the three-dimensional (3D) structure of LTP1_1 using nuclear magnetic resonance (NMR) spectroscopy and molecular modeling techniques. The global fold of LTP1_1 is very close to the previously published structures of LTP1 extracted from cereal seeds, including an internal cavity. However, the chemical shift variations of several NMR signals upon lipid binding show that tobacco LTP1_1 is able to bind only one LysoMyristoylPhosphatidylCholine (LMPC), while wheat and maize LTPs can bind either one or two. Titration experiments using intrinsic tyrosine fluorescence confirm this result not only with LMPC but also with two fatty acids. These differences can be explained by the presence in tobacco LTP1_1 of a hydrophobic cluster closing the second possible access to the protein cavity. This result suggests that LTP1 lipid binding properties could be modulated by subtle changes in a conserved global structure. The biological significance of this finding is discussed in the light of the signalling properties of the tobacco LTP1_1-jasmonate complex described elsewhere.     

Insect lipid transfer particle can facilitate net vectorial lipid transfer via a carrier-mediated mechanism.

The mechanism of facilitated lipid transfer by insect or mammalian plasma lipid transfer proteins has not been elucidated. Transfer catalysts may act as carriers of lipid between donor and acceptor lipoproteins or, alternatively, transfer may require formation of a ternary complex. This study was designed to determine if Manduca sexta hemolymph lipid transfer particle (LTP) can facilitate net vectorial transfer of lipid without concomitant contact between donor and acceptor lipoproteins and LTP. M. sexta [3H]diacylglycerol-high density lipophorin-larval ([3H]DAG-HDLp-L) and human low density lipoprotein (LDL) were covalently bound to Sepharose matrices and packed into separate columns. In incubations lacking LTP, greater than 98% of the recovered DAG remained associated with HDLp-L. An unrelated hemolymph storage protein, arylphorin, was unable to catalyze the transfer of DAG between solid-phase lipoproteins. Facilitated transfer of DAG from HDLp-L to LDL was observed when LTP was circulated between the columns. Under these conditions, facilitated transfer occurred at a rate of 2.24 ng of DAG/h (versus 0.16 microgram of DAG/h in the control), and after 16 h greater than 26% of recovered labeled DAG was transferred to LDL. This corresponds to a 14-fold rate enhancement induced by LTP. The LTP-specific transfer of DAG between physically separated lipoproteins demonstrates the ability of LTP to facilitate net lipid transfer via a carrier-mediated mechanism in the absence of a ternary complex involving donor, acceptor, and catalyst. In experiments aimed at assessing the relative contribution of ternary complex formation to DAG transfer, acceptor LDL was circulated with HDLp-L remaining immobilized. Under these conditions, LTP induced a 13-fold rate enhancement from 1.3 to 16.3 micrograms of DAG/h. The similar rate enhancements observed with both lipoproteins bound and only donor bound suggest the overall contribution of ternary complex formation to facilitated lipid transfer is insignificant. The described system should prove useful in mechanistic studies of other transfer proteins as well as studies of transfer of other lipids.     

Modifications of cysteine residues in the solution and membrane-associated conformations of phosphatidylinositol transfer protein have differential effects on lipid transfer activity

The alpha isoforms of mammalian phosphatidylinositol transfer protein (PITP) contain four conserved Cys residues. In this investigation, a series of thiol-modifying reagents, both alkylating and mixed disulfide-forming, was employed to define the accessibility of these residues and to evaluate their role in protein-mediated intermembrane phospholipid transport. Isolation and analysis of chemically modified peptides and site-directed mutagenesis of each Cys residue to Ala were also performed. Soluble, membrane-associated, and denatured preparations of wild-type and mutant rat PITPs were studied. Under denaturing conditions, all four Cys residues could be detected spectrophotometrically by chemical reaction with 4,4'-dipyridyl disulfide or 5,5'-dithiobis(2-nitrobenzoate). In the native protein, two of the four Cys residues were sensitive to some but not all thiol-modifying reagents, with discrimination based on the charge and hydrophobicity of the reagent and the conformation of the protein. With the soluble conformation of PITP, achieved in the absence of phospholipid vesicles, the surface-exposed Cys(188) was chemically modified without consequence to lipid transfer activity. Cys(188) exhibited an apparent pK(a) of 7.6. The buried Cys(95), which constitutes part of the phospholipid substrate binding site, was covalently modified upon transient association of PITP with a membrane surface. The Cys-to-Ala mutations showed that neither Cys(95) nor Cys(188) was essential for lipid transfer activity. However, chemical modification of Cys(95) resulted in the loss of lipid transfer activity. These results demonstrate that the Cys residues of PITP can be assigned to several different classes of chemical reactivity. Of particular interest is Cys(95), whose sulfhydryl group becomes exposed to modification in the membrane-associated conformation of PITP. Furthermore, the inhibition of PITP activity by thiol-modifying reagents is a result of steric hindrance of phospholipid substrate binding.     

Distinct Unfolding and Refolding Pathways of Lipid Transfer Proteins LTP1 and LTP2

Plant non-specific lipid transfer proteins (ns-LTPs) comprise two families, LTP1s and LTP2s, all structurally stabilized by four native disulfide bonds. Solution and crystal structures of both LTP1s and LTP2s from various plants have been determined. Despite the similarities of their biological function and backbone folds, the biophysical properties of LTP1s and LTP2s differ significantly. In this report, the mechanisms of unfolding and refolding of rice LTP1 and LTP2 have been investigated using the technique of disulfide bonds scrambling. LTP1 is shown to unfold and refold via predominant species of partially structured intermediates. Four isomers of partly unfolded and extensively unfolded LTP1 were identified, isolated and their disulfide structures were determined. By contrast, unfolding and refolding of LTP2 adopt a (close to) two-state mechanism, and undergo a reversible conversion between the native and a single extensively unfolded isomer without accumulation of any significant intermediate.     

Kiwi protein inhibitor of pectin methylesterase amino-acid sequence and structural importance of two disulfide bridges.

A protein acting as a powerful inhibitor of plant pectin methylesterase was isolated from kiwi (Actinidia chinensis) fruit. The complete amino-acid sequence of the pectin methylesterase inhibitor (PMEI) was determined by direct protein analysis. The sequence comprises 152 amino-acid residues, accounting for a molecular mass of 16 277 Da. The far-UV CD spectrum indicated a predominant alpha-helix conformation in the secondary structure. The protein has five cysteine residues but neither tryptophan nor methionine. Analysis of fragments obtained after digestion of the protein alkylated without previous reduction identified two disulfide bridges connecting Cys9 with Cys18, and Cys74 with Cys114; Cys140 bears a free thiol group. A database search pointed out a similarity between PMEI and plant invertase inhibitors. In particular, the four Cys residues, which in PMEI are involved in the disulfide bridges, are conserved. This allows us to infer that also in the homologous proteins, whose primary structure was deduced only by cDNA sequencing, those cysteine residues are engaged in two disulfide bridges, and constitute a common structural motif. The comparison of the sequence of these inhibitors confirms the existence of a novel class of proteins with moderate but significant sequence conservation, comprising plant proteins acting as inhibitors of sugar metabolism enzymes, and probably involved in various steps of plant development.     

Isolation, purification and characterization of a nonspecific lipid transfer protein from Cuminum cyminum

Cuminum cyminum, an aromatic plant from the family Umbelliferae, is used as a flavoring and seasoning agent in foods. This communication reports the characterization of a nonspecific lipid transfer protein nsLTP1 from its seeds. Plant nsLTPs are small basic proteins involved in transport of lipids between membranes. These proteins are known to participate in plant defense; however, the exact mechanism of their antimicrobial action against fungi or bacteria is still unclear.The cumin nsLTP1 has been purified using a combination of chromatographic procedures and further characterized using mass spectrometry, circular dichroism spectroscopy and Edman degradation. Amino acid sequence has been used to predict homology model of cumin nsLTP1 in complex with myristic acid, and lyso-myristoyl phosphatidyl choline (LMPC). Cumin nsLTP1 is a monomeric protein with a molecular weight of 9.7 kDa as estimated by SDS-PAGE and ESIMS. The protein shows an isoelectric point of 7.8 on 6% PAGE. The primary structure consists of 92 amino acids with eight conserved cysteine residues. The global fold of cumin nsLTP1 includes four α-helices stabilized by four disulfide bonds and a C-terminal tail. The role of internal hydrophobic cavity of the protein in lipid transfer is discussed.     

Protein disulfide isomerase is a component of the microsomal triglyceride transfer protein complex

A bovine liver protein which catalyzes the transfer of triglyceride between membranes has previously been isolated from the lumen of the microsomal fraction. When further purified about 100-fold, two polypeptides of molecular mass 58,000 and 88,000 were identified (Wetterau, J. R., and Zilversmit, D. B. (1985) Chem. Phys. Lipids 38, 205-222). We demonstrate here that the two polypeptides (referred to as 58-kDa and 88-kDa, respectively) are associated in a protein-protein complex, and that the triglyceride transfer activity is associated with this complex. Antibodies specific for either polypeptide immunoprecipitated both the 58-kDa and 88-kDa polypeptides as well as the lipid transfer activity. The 58-kDa subunit of the microsomal transfer protein complex was identified as protein disulfide-isomerase (PDI) (EC 5.3.4.1) by 1) a comparison of the amino-terminal sequence of PDI and the 58-kDa subunit of the transfer protein, 2) a comparison of the reverse phase high performance liquid chromatography peptide maps of CNBr digests of PDI and the lipid transfer protein, 3) immunoprecipitation competition experiments in which PDI was found to compete with the lipid transfer protein for immunoprecipitation by the anti-58-kDa polyclonal antibodies, 4) immunological cross-reactivity of the microsomal triglyceride transfer protein complex with polyclonal antibodies raised against PDI, and 5) the appearance of protein disulfide isomerase activity following the dissociation of purified microsomal transfer protein complex with guanidine HCl. In conclusion, the microsomal triglyceride transfer protein has a multi-subunit structure which is unique compared to other intracellular lipid transfer proteins which have been described to be single polypeptides. The unexpected finding that PDI is a component of the microsomal triglyceride transfer protein complex suggests a new previously undescribed role for protein disulfide isomerase.     

Mutating the four extracellular cysteines in the chemokine receptor CCR6 reveals their differing roles in receptor trafficking,ligand binding,and signaling

CCR6 is the receptor for the chemokine MIP-3 alpha/CCL20. Almost all chemokine receptors contain cysteine residues in the N-terminal domain and in the first, second, and third extracellular loops. In this report, we have studied the importance of all cysteine residues in the CCR6 sequence using site-directed mutagenesis and biochemical techniques. Like all G protein-coupled receptors, mutating disulfide bond-forming cysteines in the first (Cys118) and second (Cys197) extracellular loops in CCR6 led to complete elimination of receptor activity, which for CCR6 was also associated with the accumulation of the receptor intracellularly. Although two additional cysteines in the N-terminal region and the third extracellular loop, which are present in almost all chemokine receptors, are presumed to form a disulfide bond, this has not been demonstrated experimentally for any of these receptors. We found that mutating the cysteines in the N-terminal domain (Cys36) and the third extracellular loop (Cys288) neither significantly affected receptor surface expression nor completely abolished receptor function. Importantly, contrary to several previous reports, we demonstrated directly that instead of forming a disulfide bond, the N-terminal cysteine (Cys36) and the third extracellular loop cysteine (Cys288) contain free SH groups. The cysteine residues (Cys36 and Cys288), rather than forming a disulfide bond, may be important per se. We propose that CCR6 forms only a disulfide bond between the first (Cys118) and second (Cys197) extracellular loops, which confines a helical bundle together with the N-terminus adjacent to the third extracellular loop, creating the structural organization critical for ligand binding and therefore for receptor signaling.