Human SOD1 before harboring the catalytic metal: solution structure of copper-depleted, disulfide-reduced form

SOD1 has to undergo several post-translational modifications before reaching its mature form. The protein requires insertion of zinc and copper atoms, followed by the formation of a conserved S-S bond between Cys-57 and Cys-146 (human numbering), which makes the protein fully active. In this report an NMR structural investigation of the reduced SH-SH form of thermostable E,Zn-as-SOD1 (E is empty; as is C6A, C111S) is reported, characterizing the protein just before the last step leading to the mature form. The structure is compared with that of the oxidized S-S form as well as with that of the yeast SOD1 complexed with its copper chaperone, CCS. Local conformational rearrangements upon disulfide bridge reduction are localized in the region near Cys-57 that is completely exposed to the solvent in the present structure, at variance with the oxidized forms. There is a local disorder around Cys-57 that may serve for protein-protein recognition and may possibly be involved in intermolecular S-S bonds in familial amyotrophic lateral sclerosis-related SOD1 mutants. The structure allows us to further discuss the copper loading mechanism in SOD1.     

Location of intrachain disulfide bonds in the VP5* and VP8* trypsin cleavage fragments of the rhesus rotavirus spike protein VP4.

Because the rotavirus spike protein VP4 contains conserved Cys residues at positions 216, 318, 380, and 774 and, for many animal rotaviruses, also at position 203, we sought to determine whether disulfide bonds were structural elements of VP4. Electrophoretic analysis of untreated and trypsin-treated rhesus rotavirus (RRV) and simain rotavirus SA11 in the presence and absence of the reducing agent dithioerythritol revealed that VP4 and its cleavage fragments VP5* and VP8* possessed intrachain disulfide bonds. Given that the VP8* fragments of RRV and SA11 contain only two Cys residues, those at positions 203 and 216, these data indicated that these two residues were covalently linked. Electrophoretic examination of truncated species of VP4 and VP4 containing Cys-->Ser mutations synthesized in reticulocyte lysates provided additional evidence that Cys-203 and Cys-216 in VP8* of RRV were linked by a disulfide bridge. VP5* expressed in vitro was able to form a disulfide bond analogous to that in the VP5* fragment of trypsin-treated RRV. Analysis of a Cys-774-->Ser mutant of VP5* showed that, while it was able to form a disulfide bond, a Cys-318-->Ser mutant of VP5* was not. These results indicated that the VP4 component of all rotaviruses, except B223, contains a disulfide bond that links Cys-318 and Cys-380 in the VP5* region of the protein. This bond is located between the trypsin cleavage site and the putative fusion domain of VP4. Because human rotaviruses lack Cys-203 and, hence, unlike many animal rotaviruses cannot possess a disulfide bond in VP8*, it is apparent that VP4 is structurally variable in nature, with human rotaviruses generally containing one disulfide linkage and animal rotaviruses generally containing two such linkages. Considered with the results of anti-VP4 antibody mapping studies, the data suggest that the disulfide bond in VP5* exists within the 2G4 epitope and may be located at the distal end of the VP4 spike on rotavirus particles.     

Disulfide scrambling of interleukin-2: HPLC resolution of the three possible isomers

Native interleukin-2 (IL-2) contains three cysteines; two exist in a disulfide bridge (Cys-58 and Cys-105) and the third Cys-125 is a free sulfhydryl. In the presence of 6 M guanidine hydrochloride at alkaline pH, IL-2 is converted into three isomers. Each isomer represents one of the three possible disulfide-linked forms that can be generated from three cysteines. These three isomers were resolved on a C4 reverse-phase HPLC system. The identity of each of the three forms was determined by carboxymethylation of the free cysteines in each isomer with [3H]iodoacetic acid followed by determination of the labelled cysteines by tryptic peptide mapping. Tryptic peptide mapping of the more predominant of the two scrambled peaks showed it to be the Cys-105-S-S-Cys-125 linked form of IL-2. A Ser-125 construction of IL-2, which lacks a free cysteine, did not scramble under these conditions. These experiments demonstrate the utility of reverse-phase HPLC in studies of protein folding and disulfide bond structure.     

Altered Thiol Chemistry in Human Amyotrophic Lateral Sclerosis-linked Mutants of Superoxide Dismutase 1

Neurodegenerative diseases share a common characteristic, the presence of intracellular or extracellular deposits of protein aggregates in nervous tissues. Amyotrophic Lateral Sclerosis (ALS) is a severe and fatal neurodegenerative disorder, which affects preferentially motoneurons. Changes in the redox state of superoxide dismutase 1 (SOD1) are associated with the onset and development of familial forms of ALS. In human SOD1 (hSOD1), a conserved disulfide bond and two free cysteine residues can engage in anomalous thiol/disulfide exchange resulting in non-native disulfides, a hallmark of ALS that is related to protein misfolding and aggregation. Because of the many competing reaction pathways, traditional bulk techniques fall short at quantifying individual thiol/disulfide exchange reactions. Here, we adapt recently developed single-bond chemistry techniques to study individual disulfide isomerization reactions in hSOD1. Mechanical unfolding of hSOD1 leads to the formation of a polypeptide loop held by the disulfide. This loop behaves as a molecular jump rope that brings reactive Cys-111 close to the disulfide. Using force-clamp spectroscopy, we monitor nucleophilic attack of Cys-111 at either sulfur of the disulfide and determine the selectivity of the reaction. Disease-causing mutations G93A and A4V show greatly altered reactivity patterns, which may contribute to the progression of familial ALS.     

Single amino acid substitutions in procollagen VII affect early stages of assembly of anchoring fibrils

Procollagen VII is a homotrimer of 350-kDa pro-alpha1(VII) chains, each consisting of a central collagenous domain flanked by the noncollagenous N-terminal NC1 domain and the C-terminal NC2 domain. After secretion from cells, procollagen VII molecules form anti-parallel dimers with a C-terminal 60-nm overlap. Characteristic alignment of procollagen VII monomers forming a dimer depends on site-specific binding between the NC2 domain and the triple-helical region adjacent to Cys-2634 of the interacting procollagen VII molecules. Formation of the intermolecular disulfide bonds between Cys-2634 and either Cys-2802 or Cys-2804 is promoted by the cleavage of the NC2 domain by procollagen C-proteinase. By employing recombinant procollagen VII variants harboring G2575R, R2622Q, or G2623C substitutions previously disclosed in patients with dystrophic epidermolysis bullosa, we studied how these amino acid substitutions affect intermolecular interactions. Binding assays utilizing an optical biosensor demonstrated that the G2575R substitution increased affinity between mutant molecules. In contrast, homotypic binding between the R2622Q or G2623C molecules was not detected. In addition, kinetics of heterotypic binding of all analyzed mutants to wild type collagen VII were different from those for binding between wild type molecules. Moreover, solid-state binding assays demonstrated that R2622Q and G2623C substitutions prevent formation of stable assemblies of procollagen C-proteinase-processed mutants. These results indicate that single amino acid substitutions in procollagen VII alter its self-assembly and provide a basis for understanding the pathomechanisms leading from mutations in the COL7A1 gene to fragility of the dermal-epidermal junction seen in patients with dystrophic forms of epidermolysis bullosa.     

Identification of intra- and intermolecular disulfide bridges in the multidrug resistance transporter ABCG2

ABCG2 is an ATP binding cassette (ABC) half-transporter that plays a key role in multidrug resistance to chemotherapy. ABCG2 is believed to be a functional homodimer that has been proposed to be linked by disulfide bridges. We have investigated the structural and functional role of the only three cysteines predicted to be on the extracellular face of ABCG2. Upon mutation of Cys-592 or Cys-608 to alanine (C592A and C608A), ABCG2 migrated as a dimer in SDS-PAGE under non-reducing conditions; however, mutation of Cys-603 to Ala (C603A) caused the transporter to migrate as a single monomeric band. Despite this change, C603A displayed efficient membrane targeting and preserved transport function. Because the transporter migrated as a dimer in SDS-PAGE, when only Cys-603 was present (C592A-C608A), the data suggest that Cys-603 forms a symmetrical intermolecular disulfide bridge in the ABCG2 homodimer that is not essential for protein expression and function. In contrast to C603A, both C592A and C608A displayed impaired membrane targeting and function. Moreover, when only Cys-592 or Cys-608 were present (C592A/C603A and C603A/C608A), the transporter displayed impaired plasma membrane expression and function. The combined mutation (C592A/C608A) partially restored plasma membrane expression; however, although transport of mitoxantrone was almost normal, we observed impairment of BODIPY-prazosin transport. This supports the conclusion that Cys-592 and Cys-608 form an intramolecular disulfide bridge in ABCG2 that is critical for substrate specificity. Finally, mutation of all three cysteines simultaneously resulted in low expression and no measurable function. Altogether, our data are consistent with a scenario in which an inter- and an intramolecular disulfide bridge together are of fundamental importance for the structural and functional integrity of ABCG2.     

Disulfide structure of the leucine-rich repeat C-terminal cap and C-terminal stalk region of Nogo-66 receptor

Nogo-66 receptor (NgR1) is a leucine-rich repeat (LRR) protein that forms part of a signaling complex modulating axon regeneration. Previous studies have shown that the entire LRR region of NgR1, including the C-terminal cap of the LRR, LRRCT, is needed for ligand binding, and that the adjacent C-terminal region (CT stalk) of the NgR1 contributes to interaction with its coreceptors. To provide structure-based information for these interactions, we analyzed the disulfide structure of full-length NgR1. Our analysis revealed a novel disulfide structure in the C-terminal region of the NgR1, wherein the two Cys residues, Cys-335 and Cys-336, in the CT stalk are disulfide-linked to Cys-266 and Cys-309 in the LRRCT region: Cys-266 is linked to Cys-335, and Cys-309 to Cys-336. The other two Cys residues, Cys-264 and Cys-287, in the LRRCT region are disulfide-linked to each other. The analysis also showed that Cys-419 and Cys-429, in the CT stalk region, are linked to each other by a disulfide bond. Although published crystal structures of a recombinant fragment of NgR1 had revealed a disulfide linkage between Cys-266 and Cys-309 in the LRRCT region and we verified its presence in the corresponding fragment, this is artificially caused by the truncation of the protein, since this linkage was not detected in intact NgR1 or a slightly larger fragment containing Cys-335 and Cys-336. A structural model of the LRRCT with extended residues 311-344 from the CT stalk region is proposed, and its function in coreceptor binding is discussed.     

A study of short utrophin isoforms in mice deficient for full-length utrophin

Utrophin can functionally replace dystrophin in dystrophin-deficient muscle and may have a role in a therapeutic strategy for Duchenne muscular dystrophy. This has resulted in many investigations of the full-length muscle form of utrophin; however, the short utrophins and non-muscle forms have been relatively neglected, partly because they are difficult to analyze in the presence of the full-length form. Our study circumvents this problem by using mice deficient for the full-length form (UKOex6 mice) to study the translation and distribution of short utrophins. Four tissues were examined—kidney, testis, fetal hands/feet, and brain—and three novel short isoforms were identified, including Up120, which appears to be specific to kidney glomeruli, and Up 109, expressed in the fetal dermis. A third form, Up103, was found in testis but at extremely low levels. A cDNA for Up109 has been isolated and shown to have a unique NH2-terminal sequence. In addition, the first exons of Up109 and another short form, G-utrophin, have both been located within intron 55, 56 kb apart. Our immunological studies show that G-utrophin protein accumulates only in neural tissue, in line with its similarly restricted RNA distribution. Our study of testis expression shows, for the first time, that full-length utrophin is expressed at high levels in Leydig cells, raising the possibility that this protein is involved in testosterone secretion. We note that translation of the short utrophins, especially Up140 and Up71, is relatively inefficient and discuss the significance of this observation.     

Identification of a Disulfide Bridge Important for Transport Function of SNAT4 Neutral Amino Acid Transporter

SNAT4 is a member of system N/A amino acid transport family that primarily expresses in liver and muscles and mediates the transport of L-alanine. However, little is known about the structure and function of the SNAT family of transporters. In this study, we showed a dose-dependent inhibition in transporter activity of SNAT4 with the treatment of reducing agents, dithiothreitol (DTT) and Tris(2-carboxyethyl)phosphine (TCEP), indicating the possible involvement of disulfide bridge(s). Mutation of residue Cys-232, and the two highly conserved residues Cys-249 and Cys-321, compromised the transport function of SNAT4. However, this reduction was not caused by the decrease of SNAT4 on the cell surface since the cysteine-null mutant generated by replacing all five cysteines with alanine was equally capable of being expressed on the cell surface as wild-type SNAT4. Interestingly, by retaining two cysteine residues, 249 and 321, a significant level of L-alanine uptake was restored, indicating the possible formation of disulfide bond between these two conserved residues. Biotinylation crosslinking of free thiol groups with MTSEA-biotin provided direct evidence for the existence of a disulfide bridge between Cys-249 and Cys-321. Moreover, in the presence of DTT or TCEP, transport activity of the mutant retaining Cys-249 and Cys-321 was reduced in a dose-dependent manner and this reduction is gradually recovered with increased concentration of H₂O₂. Disruption of the disulfide bridge also decreased the transport of L-arginine, but to a lesser degree than that of L-alanine. Together, these results suggest that cysteine residues 249 and 321 form a disulfide bridge, which plays an important role in substrate transport but has no effect on trafficking of SNAT4 to the cell surface.     

A comparison of spectral and physicochemical properties of yeast iso-1 cytochrome c and Cys 102-modified derivatives of the protein

Derivatives of yeast iso-1 cytochrome c, chemically modified at Cys-102 (Cys-102 acetamide-derivatized monomer, Cys-102 thionitrobenzoate-derivatized monomer, Cys-102 S-methylated monomer, and the disulfide dimer), exhibit different spectral and physicochemical properties relative to the native, unmodified protein, depending on the nature of the modifying group. The results of proton NMR studies on the Cys-102 acetamidederivatized monomer of iso-1 ferricytochrome c indicate that the conformational characteristics of the heme environment in this protein derivative are intermediate between those of the unmodified monomer and disulfide dimer forms of the protein. Measurements of the pK_a of the alkaline transitions of the five forms of iso-1 ferricytochrome c provided values of 8.89, 8.82, 8.67, 8.47, and 8.50 for the unmodified monomer, S-methylated monomer, acetamide-derivatized monomer, thionitrobenzoate-derivatized monomer, and disulfide dimer, respectively. The results of proton NMR studies of the reduced form of these proteins suggest that the heme environments of the unmodified monomer and disulfide dimer derivatives of iso-1 ferrocytochrome c are similar and indicate that treatment of the thionitrobenzoate-derivatized and disulfide dimer forms of the protein with sodium dithionite results in cleavage of the disulfide bonds at position 102. Circular dichroism studies reveal that only the disulfide dimer form of iso-1 ferricytochrome c exhibits a Soret CD spectrum which differs from the native, unmodified monomer in that the intensity of the negative band at approximately 420 nm is diminished in the spectrum of the dimer relative to the spectrum of the monomer. Soret CD spectra of the ascorbate-reduced form of all protein derivatives are similar. The process of autoreduction of yeast iso-1 ferricytochrome c is shown to occur in the absence of a free sulfhydryl group at position 102 and is exacerbated under moderately high pH conditions. These results are suggestive of the presence of a redox-active amino acid, perhaps a tyrosine, in yeast iso-1 cytochrome c.     

Striking differences of LDL receptor-related protein 1B expression in mouse and human

The low density lipoprotein (LDL) receptor-related protein 1B (LRP1B) is a member of the expanding LDL receptor family, and is closely related to LRP. It was discovered as a putative tumor suppressor, and is frequently inactivated in human malignant tissues. However, the expression pattern of LRP1B in normal human tissues was unclear. In the present study, we analyzed LRP1B expression in normal mouse and human tissues. By using RT-PCR, we found that, while mouse LRP1B expression is mostly restricted to the brain, human LRP1B expression is more widespread with highest expression levels detected in the brain, adrenal gland, salivary gland, and testis. Although mouse LRP1B expresses in the forms of both full-length receptor tail and an alternatively spliced form lacking a 33-amino acid insert, human LRP1B is expressed exclusively in the form of full-length receptor tail. Finally, we found that, unlike mouse LRP1B, human LRP1B is cleaved by furin. Taken together, these data demonstrate that there are striking differences between LRP1B expression in mouse and human tissues. The broader expression pattern of LRP1B in human tissues suggests that this putative tumor suppressor may play roles in several types of human cancer.     

Depolarization induces intersubunit cross-linking in a S4 cysteine mutant of the Shaker potassium channel

Voltage-gated potassium (K(v)) channels are integral membrane proteins, composed of four subunits, each comprising six (S1-S6) transmembrane segments. S1-S4 comprise the voltage-sensing domain, and S5-S6 with the linker P-loop forms the ion conducting pore domain. During activation, S4 undergoes structural rearrangements that lead to the opening of the channel pore and ion conduction. To obtain details of these structural changes we have used the engineered disulfide bridge approach. For this we have introduced the L361C mutation at the extracellular end of S4 of the Shaker K channel and expressed the mutant channel in Xenopus oocytes. When exposed to mild oxidizing conditions (ambient oxygen or copper phenanthroline), Cys-361 formed an intersubunit disulfide bridge as revealed by the appearance of a dimeric band on Western blotting. As a consequence, the mutant channel suffered a significant loss in conductance (measured by two-electrode voltage clamp). Removal of native cysteines failed to prevent the disulfide formation, indicating that Cys-361 forms a disulfide with its counterpart in the neighboring subunit. The effect was voltage-dependent and occurred during channel activation after Cys-361 has been exposed to the extracellular phase. Although the disulfide bridge reduced the maximal conductance, it caused a hyperpolarizing shift in the conductance-voltage relationship and reduced the deactivation kinetics of the channel. The latter two effects suggest stabilization of the open state of the channel. In conclusion, we report that during activation the intersubunit distance between the N-terminal ends of the S4 segments of the L361C mutant Shaker K channel is reduced.     

Determination of disulfide array and subunit structure of taste-modifying protein, miraculin

The taste-modifying protein, miraculin (Theerasilp, S. et al. (1989) J. Biol. Chem. 264, 6655-6659) has seven cysteine residues in a molecule composed of 191 amino acid residues. The formation of three intrachain disulfide bridges at Cys-47-Cys-92, Cys-148-Cys-159 and Cys-152-Cys-155 and one interchain disulfide bridge at Cys-138 was determined by amino acid sequencing and composition analysis of cystine-containing peptides isolated by HPLC. The presence of an interchain disulfide bridge was also supported by the fact that the cystine peptide containing Cys-138 showed a negative color test for the free sulfhydryl group and a positive test after reduction with dithiothreitol. The molecular mass of non-reduced miraculin (43 kDa) in sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) was nearly twice the calculated molecular mass based on the amino acid sequence and the carbohydrate content of reduced miraculin (25 kDa). The molecular mass of native miraculin determined by low-angle laser light scattering was 90 kDa. Application of a crude extract of miraculin to a Sephadex G-75 column indicated that the taste-modifying activity appears at 52 kDa. It was concluded that native miraculin in pure form is a tetramer of the 25 kDa-peptide and native miraculin in crude state or denatured, non-reduced miraculin in pure form is a dimer of the peptide. Both tetramer miraculin and native dimer miraculin in crude state had the taste-modifying activity.     

Cysteines 431 and 1074 are responsible for inhibitory disulfide cross-linking between the two nucleotide-binding sites in human P-glycoprotein

Human wild-type and Cys-less P-glycoproteins were expressed in Pichia pastoris and purified in high yield in detergent-soluble form. Both ran on SDS gels as a single 140-kDa band in the presence of reducing agent and showed strong verapamil-stimulated ATPase activity in the presence of added lipid. The wild type showed spontaneous formation of higher molecular mass species in the absence of reducing agent, and its ATPase was activated by dithiothreitol. Oxidation with Cu(2+) generated the same higher molecular mass species, primarily at 200 and approximately 300 kDa, in high yield. Cross-linking was reversed by dithiothreitol and prevented by pretreatment with N-ethylmaleimide. Using proteins containing different combinations of naturally occurring Cys residues, it was demonstrated that an inhibitory intramolecular disulfide bond forms between Cys-431 and Cys-1074 (located in the Walker A sequences of nucleotide-binding sites 1 and 2, respectively), giving rise to the 200-kDa species. In addition, dimeric P-glycoprotein species ( approximately 300 kDa) form by intermolecular disulfide bonding between Cys-431 and Cys-1074. The ready formation of the intramolecular disulfide between Cys-431 and Cys-1074 establishes that the two nucleotide-binding sites of P-glycoprotein are structurally very close and capable of intimate functional interaction, consistent with available information on the catalytic mechanism. Formation of such a disulfide in vivo could, in principle, underlie a regulatory mechanism and might provide a means of intervention to inhibit P-glycoprotein.     

Membrane immunoglobulins are stabilized by interchain disulfide bonds occurring within the extracellular membrane-proximal domain

Membrane-bound immunoglobulins have, in addition to the transmembrane and cytoplasmic portions, an extracellular membrane-proximal domain (EMPD), absent in the secretory forms. EMPDs of immunoglobulin isotypes alpha, gamma, and epsilon contain cysteines whose role has so far not been elucidated. Using a genetic strategy, we investigated the ability of these cysteines to form disulfide bridges. Shortened versions of human membrane immunoglobulins, depleted of cysteines known to form intermolecular disulfide bonds, were constructed and expressed on the surface of a B-cell line. The resulting membrane proteins contain a single chain fragment of variable regions (scFv) linked to the dimerizing domain from the immunoglobulin heavy chains (CH3 for alpha and gamma or CH4 for epsilon isotypes), followed by the corresponding EMPD and the transmembrane and cytoplasmic domains. The two functional membrane versions of the epsilon chain, containing the short and long EMPD, were analyzed. Our results show that the single cysteine within alpha1L and gamma1 EMPD and the short version of epsilon EMPD form an interchain disulfide bond. Conversely, the cysteine resident in the epsilon transmembrane domain remains unreacted. epsilon-long EMPD contains four cysteines; two are involved in interchain bonds while the remaining two are likely forming an intrachain bridge. Expression of a full-length membrane epsilon heavy chain mutant, in which Cys(121) and Cys(209) within domain CH2 (involved in interchain bridges) were mutated to alanines, confirmed that, within the complete IgE, EMPD cysteines form interchain disulfide bonds. In conclusion, we unveil evidence for additional covalent stabilization of membrane-bound immunoglobulins.     

毛细管电泳测定牛红细胞超氧化物歧化酶的巯基位点

本文介绍了毛细管电泳分析蛋白质酶解产物中含巯基多肽的方法。还原的及天然的牛红细胞超氧化物歧化酶(SOD)经4-乙烯吡啶修饰后,由TPCK-胰蛋白酶水解,在254nm检测到还原的SOD水解物中含3个巯基多肽,天然的SOD为1个疏基多肽且其毛细管电泳行为与上述3个多肽之一相一致。分析它们的氨基酸顺序,证实Cys-6为游离的巯基,Cys-55和Cys~(-144)形成二硫键。     

Relevance of cysteine residues for biosynthesis and antigenicity of human hepatitis B virus e protein.

The mature form of the secretory core protein (HBe protein) of human hepatitis B virus contains four cysteines which are located at amino acid positions -7, 48, 61, and 107 relative to the HBc start methionine. In addition, there is a cysteine, Cys-183, located in the C-terminal domain of the HBe precursor, which is cleaved during HBe maturation. Here, the significance of these cysteines for biosynthesis and antigenicity of the HBe protein was examined. The cysteines at positions -7 and 61 were found to be crucial for HBe biosynthesis. As has already been described, if the Cys at position -7 is mutated, disulfide-linked HBe homodimers which have both HBe antigenicity and HBc antigenicity are expressed. Here we show that these dimers are due to Cys-61-Cys-61 disulfide bridges which are formed only if the Cys at position -7 is not present. In the wild-type protein, this dimerization appears to be inhibited by formation of intramolecular disulfide bridges between the Cys at -7 and one of the internal cysteines. Moreover, Cys-61 is important for HBe biosynthesis in general since mutation of this amino acid results in production of HBe proteins which are either only poorly secreted or possess a different antigenicity.     

Deletion of carboxy-terminal residues of murine granulocyte-macrophage colony-stimulating factor results in a loss of biologic activity and altered glycosylation

A deletion mutant of murine granulocyte-macrophage colony-stimulating factor (GM-CSF) which differs in primary structure from native GM-CSF in the carboxy-terminal 11 amino acids was prepared. Four amino acid residues are mutated and the seven terminal residues including Cys-118 are deleted. Supernatants from COS-1 cells transfected with this deletion mutant (GM-CSF(del] showed a 3000-fold decrease in the ability to stimulate bone marrow stem cells to proliferate and differentiate into granulocytes and macrophages in vitro. Northern blot analysis using poly(A)+ RNA extracted from the transfected cells showed equal accumulations of GM-CSF and GM-CSF(del). Transfection with full-length GM-CSF followed by immunoprecipitation of metabolically labeled supernatant proteins with rabbit anti-rGM-CSF antiserum yielded predominantly the 23-kDa, fully glycosylated form and small amounts of both a 29-kDa form and the 18-kDa non-N-glycosylated form. Transfection of the GM-CSF(del) mutant and immunoprecipitation revealed a large, diffuse band on sodium dodecyl sulfate--polyacrylamide gel electrophoresis with a molecular weight of about 29 kDa. Digestion of the immunoprecipitated 29-kDa species with N-glycanase converted the 29-kDa form into two forms of about 23 and 18 kDa, suggesting that the increase in molecular weight of the deletion mutant protein resulted from hyperglycosylation. Adding tunicamycin to the culture medium of cells transfected with GM-CSF(del) also yielded a single non-N-glycosylated species of about 18 kDa, but secretion was at a significantly lower level than either the 29-kDa hyperglycosylated GM-CSF(del) protein from non-tunicamycin-treated cells or the 18-kDa non-N-glycosylated full-length GM-CSF from tunicamycin-treated cells. Since very recent scanning-deletion analysis indicates that there is a critical region for activity near Cys-118 and that Cys-118 is necessary for maximal activity, we conclude that the Cys-118 residue is necessary for proper glycosylation and maximal biologic activity of GM-CSF.     

Vascular proteomics and subtractive antibody expression cloning

The cloning of genes expressing proteins that are differentially expressed in the organ microvasculature has the potential to address a variety of problems ranging from the analysis of disease pathogenesis to drug targeting for particular tissues. This study describes a methodology designed to analyze differential protein expression in the brain microvasculature. The method can be applied to other organs and is particularly suited to the cloning of cDNAs encoding membrane proteins. The technology merges a tissue-specific polyclonal antiserum with a cDNA library expression cloning system. The tissue-specific antiserum is subtracted with protein extracts from control tissues to remove those antibodies that recognize common antigenic proteins. Then, the depleted antiserum is used to expression clone tissue-specific proteins from a cDNA library expressed in mammalian cells. The methodology was evaluated with a rabbit polyclonal antiserum prepared against purified bovine brain capillaries. The antiserum was absorbed with acetone powders of liver and kidney and then used to screen a bovine brain capillary cDNA library in COS cells. The initial clone detected with this expression methodology was the Lutheran membrane glycoprotein, which is specifically expressed at the brain microvasculature compared with liver and kidney tissues. This subtractive expression cloning methodology provides a new approach to "vascular proteomics" and to the detection of proteins specifically expressed at the microvasculature, including membrane proteins.