GPIomics: global analysis of glycosylphosphatidylinositol‐anchored molecules of Trypanosoma cruzi

Glycosylphosphatidylinositol (GPI) anchoring is a common, relevant posttranslational modification of eukaryotic surface proteins. Here, we developed a fast, simple, and highly sensitive (high attomole‐low femtomole range) method that uses liquid chromatography‐tandem mass spectrometry (LC‐MSⁿ) for the first large‐scale analysis of GPI‐anchored molecules (i.e., the GPIome) of a eukaryote, Trypanosoma cruzi, the etiologic agent of Chagas disease. Our genome‐wise prediction analysis revealed that approximately 12% of T. cruzi genes possibly encode GPI‐anchored proteins. By analyzing the GPIome of T. cruzi insect‐dwelling epimastigote stage using LC‐MSⁿ, we identified 90 GPI species, of which 79 were novel. Moreover, we determined that mucins coded by the T. cruzi small mucin‐like gene (TcSMUG S) family are the major GPI‐anchored proteins expressed on the epimastigote cell surface. TcSMUG S mucin mature sequences are short (56–85 amino acids) and highly O‐glycosylated, and contain few proteolytic sites, therefore, less likely susceptible to proteases of the midgut of the insect vector. We propose that our approach could be used for the high throughput GPIomic analysis of other lower and higher eukaryotes.     

Diagnosis of paroxysmal nocturnal hemoglobinuria by fluorescent clostridium septicum alpha toxin

Paroxysmal nocturnal hemoglobinuria (PNH), a hematopoietic stem cell disorder, is caused by the loss of glycosylphosphatidylinositol (GPI)-anchored proteins on the cell membrane. PNH can be simply diagnosed by flow cytometry using monoclonal antibodies against GPI-anchored proteins or fluorescent-tagged aerolysin, a bacterial toxin that binds GPI anchored proteins. Clostridium septicum alpha toxin is homologous to aerolysin and specifically binds GPI-anchored proteins. Previously, we found that an alpha toxin m45 mutant with two amino acid changes, S189C/S238C, lost cytotoxicity but still possessed binding activity for GPI-anchored proteins. To use this mutant toxin as a diagnostic probe in flow cytometry, we constructed the EGFP-AT(m45) expression vector, comprising a S189C/S238C alpha toxin mutant with EGFP and His tags at the N and C termini, respectively. The recombinant EGFP-AT(m45) was easily purified using single-step affinity chromatography against His tag from Escherichia coli. EGFP-AT(m45) bound to CHO and HeLa cells in a similar manner to monoclonal antibodies against GPI-anchored proteins or aerolysin. In whole blood from a PNH patient, GPI-deficient granulocytes could be differentiated by EGFP-AT(m45) using the same procedure as that employed with commercially available monoclonal antibodies. Therefore, nontoxic EGFP-conjugated C. septicum alpha toxin could be used clinically for PNH diagnosis.     

Altered KCNQ3 Potassium Channel Function Caused by the W309R Pore-Helix Mutation Found in Human Epilepsy

The second tryptophan (W) residue of the conserved WW motif in the pore helix of many K⁺ channel subunit is thought to interact with the tyrosine (Y) residues of the selectivity filter. A missense mutation causing the replacement of the corresponding residues with an arginine (W309R) occurs in KCNQ3 subunits forming part of M-channels. In this study, we examined the functional consequences of the W309R mutation in heterogously expressed KCNQ channels. Homomeric KCNQ3^W309R channels lacked KCNQ currents. Heteromeric KCNQ2/KCNQ3^W309R channels displayed a dominant-negative suppression of current and a significant modification in gating properties when compared with heteromeric KCNQ3/KCNQ2 channels mimicking the M-channels. A three-dimensional homology model in the W309R mutant indicated that the R side chain of pore helices is too far from the Y side chain of the selectivity filter to interact via hydrogen bonds with each other and stabilize the pore structure. Collectively, the present results suggest that the second W residues of pore helices and their chemical interaction with the Y residues of the selectivity filter are essential for normal K⁺ channel function. This pore-helix mutation, if occurs in the brain M channels, could thus lead to a channel dysfunction sufficient to trigger epileptic hyperexcitability.     

Identification of the amino acid residues and domains in the cysteine‐rich protein of Chinese wheat mosaic virus that are important for RNA silencing suppression and subcellular localization

Cysteine‐rich proteins (CRPs) encoded by some plant viruses in diverse genera function as RNA silencing suppressors. Within the N‐terminal portion of CRPs encoded by furoviruses, there are six conserved cysteine residues and a Cys–Gly–X–X–His motif (Cys, cysteine; Gly, glycine; His, histidine; X, any amino acid residue) with unknown function. The central domains contain coiled‐coil heptad amino acid repeats that usually mediate protein dimerization. Here, we present evidence that the conserved cysteine residues and Cys–Gly–X–X–His motif in the CRP of Chinese wheat mosaic virus (CWMV) are critical for protein stability and silencing suppression activity. Mutation of a leucine residue in the third coiled‐coil heptad impaired CWMV CRP activity for suppression of local silencing, but not for the promotion of cell‐to‐cell movement of Potato virus X (PVX). In planta and in vitro analysis of wild‐type and mutant proteins indicated that the ability of the CRP to self‐interact was correlated with its suppression activity. Deletion of up to 40 amino acids at the C‐terminus did not abolish suppression activity, but disrupted the association of CRP with endoplasmic reticulum (ER), and reduced its activity in the enhancement of PVX symptom severity. Interestingly, a short region in the C‐terminal domain, predicted to form an amphipathic α‐helical structure, was responsible for the association of CWMV CRP with ER. Overall, our results demonstrate that the N‐terminal and central regions are the functional domains for suppression activity, whereas the C‐terminal region primarily functions to target CWMV CRP to the ER.     

Pan1 is an intrinsically disordered protein with homotypic interactions

The yeast scaffold protein Pan1 contains two EH domains at its N‐terminus, a predicted coiled‐coil central region, and a C‐terminal proline‐rich domain. Pan1 is also predicted to contain regions of intrinsic disorder, characteristic of proteins that have many binding partners. In vitro biochemical data suggest that Pan1 exists as a dimer, and we have identified amino acids 705 to 848 as critical for this homotypic interaction. Tryptophan fluorescence was used to further characterize Pan1 conformational states. Pan1 contains four endogenous tryptophans, each in a distinct region of the protein: Trp³¹² and Trp⁶⁴² are each in an EH domain, Trp⁹⁵⁷ is in the central region, and Trp¹²⁸⁰ is a critical residue in the Arp2/3 activation domain. To examine the local environment of each of these tryptophans, three of the four tryptophans were mutagenized to phenylalanine to create four proteins, each with only one tryptophan residue. When quenched with acrylamide, these single tryptophan mutants appeared to undergo collisional quenching exclusively and were moderately accessible to the acrylamide molecule. Quenching with iodide or cesium, however, revealed different Stern‐Volmer constants due to unique electrostatic environments of the tryptophan residues. Time‐resolved fluorescence anisotropy data confirmed structural and disorder predictions of Pan1. Further experimentation to fully develop a model of Pan1 conformational dynamics will assist in a deeper understanding of the mechanisms of endocytosis. Proteins 2013; 81:1944–1963. © 2013 Wiley Periodicals, Inc.     

Comparative efficiencies of C‐terminal signals of native glycophosphatidylinositol (GPI)‐anchored proproteins in conferring GPI‐anchoring

Every protein fated to receive the glycophosphatidylinositol (GPI) anchor post‐translational modification has a C‐terminal GPI‐anchor attachment signal sequence. This signal peptide varies with respect to length, content, and hydrophobicity. With the exception of predictions based on an upstream amino acid triplet termed ω→ω + 2 which designates the site of GPI uptake, there is no information on how the efficiencies of different native signal sequences compare in the transamidation reaction that catalyzes the substitution of the GPI anchor for the C‐terminal peptide. In this study we utilized the placental alkaline phosphatase (PLAP) minigene, miniPLAP, and replaced its native 3′ end‐sequence encoding ω‐2 to the C‐terminus with the corresponding C‐terminal sequences of nine other human GPI‐anchored proteins. The resulting chimeras then were fed into an in vitro processing microsomal system where the cleavages leading to mature product from the nascent preproprotein could be followed by resolution on an SDS–PAGE system after immunoprecipitation. The results showed that the native signal of each protein differed markedly with respect to transamidation efficiency, with the signals of three proteins out‐performing the others in GPI‐anchor addition and those of two proteins being poorer substrates for the GPI transamidase. The data additionally indicated that the hierarchical order of efficiency of transamidation did not depend solely on the combination of permissible residues at ω→ω + 2. J. Cell. Biochem. 84: 68–83, 2002. © 2001 Wiley‐Liss, Inc.     

Subtle difference between benzene and toluene dioxygenases of Pseudomonas putida

Benzene dioxygenase and toluene dioxygenase from Pseudomonas putida have similar catalytic properties, structures, and gene organizations, but they differ in substrate specificity, with toluene dioxygenase having higher activity toward alkylbenzenes. The catalytic iron-sulfur proteins of these enzymes consist of two dissimilar subunits, alpha and beta; the alpha subunit contains a [2Fe-2S] cluster involved in electron transfer, the catalytic nonheme iron center, and is also responsible for substrate specificity. The amino acid sequences of the alpha subunits of benzene and toluene dioxygenases differ at only 33 of 450 amino acids. Chimeric proteins and mutants of the benzene dioxygenase alpha subunit were constructed to determine which of these residues were primarily responsible for the change in specificity. The protein containing toluene dioxygenase C-terminal region residues 281 to 363 showed greater substrate preference for alkyl benzenes. In addition, we identified four amino acid substitutions in this region, I301V, T305S, I307L, and L309V, that particularly enhanced the preference for ethylbenzene. The positions of these amino acids in the alpha subunit structure were modeled by comparison with the crystal structure of naphthalene dioxygenase. They were not in the substrate-binding pocket but were adjacent to residues that lined the channel through which substrates were predicted to enter the active site. However, the quadruple mutant also showed a high uncoupled rate of electron transfer without product formation. Finally, the modified proteins showed altered patterns of products formed from toluene and ethylbenzene, including monohydroxylated side chains. We propose that these properties can be explained by a more facile diffusion of the substrate in and out of the substrate cavity.     

Trp fluorescence reveals an activation‐dependent cation‐π interaction in the Switch II region of Gαi proteins

Crystal structures of Gα_i (and closely related family member Gα_t) reveal much of what we currently know about G protein structure, including changes which occur in Switch regions. Gα_t exhibits a low rate of basal (uncatalyzed) nucleotide exchange and an ordered Switch II region in the GDP‐bound state, unlike Gα_i, which exhibits higher basal exchange and a disordered Switch II region in Gα_iGDP structures. Using purified Gα_i and Gα_t, we examined the intrinsic tryptophan fluorescence of these proteins, which reports conformational changes associated with activation and deactivation of Gα proteins. In addition to the expected enhancement in tryptophan fluorescence intensity, activation of GαGDP proteins was accompanied by a modest but notable red shift in tryptophan emission maxima. We identified a cation‐π interaction between tryptophan and arginine residues in the Switch II of Gα_i family proteins that mediates the observed red shift in emission maxima. Furthermore, amino‐terminal myristoylation of Gα_i resulted in a less polar environment for tryptophan residues in the GTPase domain, consistent with an interaction between the myristoylated amino terminus and the GTPase domain of Gα proteins. These results reveal unique insights into conformational changes which occur upon activation and deactivation of G proteins in solution.     

Relative activities and stabilities of mutant Escherichia coli tryptophan synthase alpha subunits

In vitro mutagenesis of the Escherichia coli trpA gene has yielded 66 mutant tryptophan synthase alpha subunits containing single amino acid substitutions at 49 different residue sites and 29 double and triple amino acid substitutions at 16 additional sites, all within the first 121 residues of the protein. The 66 singly altered mutant alpha subunits encoded from overexpression vectors have been examined for their ability to support growth in trpA mutant host strains and for their enzymatic and stability properties in crude extracts. With the exception of mutant alpha subunits altered at catalytic residue sites Glu-49 and Asp-60, all support growth; this includes those (48 of 66) that have no enzymatic defects and those (18 of 66) that do. The majority of the enzymatically defective mutant alpha subunits have decreased capacities for substrate (indole-3-glycerol phosphate) utilization, typical of the early trpA missense mutants isolated by in vivo selection methods. These defects vary in severity from complete loss of activity for mutant alpha subunits altered at residue positions 49 and 60 to those, altered elsewhere, that are partially (up to 40 to 50%) defective. The complete inactivation of the proteins altered at the two catalytic residue sites suggest that, as found via in vitro site-specific mutagenesis of the Salmonella typhimurium tryptophan synthetase alpha subunit, both residues probably also participate in a push-pull general acid-base catalysis of indole-3-glycerol phosphate breakdown for the E. coli enzyme as well. Other classes of mutant alpha subunits include some novel types that are defective in their functional interaction with the other tryptophan synthetase component, the beta 2 subunit. Also among the mutant alpha subunits, 19 were found altered at one or another of the 34 conserved residue sites in this portion of the alpha polypeptide sequence; surprisingly, 10 of these have wild-type enzymatic activity, and 16 of these can satisfy growth requirements of a trpA mutant host. Heat stability and potential folding-rate alterations are found in both enzymatically active and defective mutant alpha subunits. Tyr-4. Pro-28, Ser-33, Gly-44, Asp-46, Arg-89, Pro-96, and Cys-118 may be important for these properties, especially for folding. Two regions, one near Thr-24 and another near Met-101, have been also tentatively identified as important for increasing stability.     

An extracellular hydrophilic carboxy‐terminal domain regulates the activity of TaALMT1, the aluminum‐activated malate transport protein of wheat

Al³⁺‐resistant cultivars of wheat (Triticum aestivum L.) release malate through the Al³⁺‐activated anion transport protein Triticum aestivum aluminum‐activated malate transporter 1 (TaALMT1). Expression of TaALMT1 in Xenopus oocytes and tobacco suspension cells enhances the basal transport activity (inward and outward currents present in the absence of external Al³⁺), and generates the same Al³⁺‐activated currents (reflecting the Al³⁺‐dependent transport function) as observed in wheat cells. We investigated the amino acid residues involved in this Al³⁺‐dependent transport activity by generating a series of mutations to the TaALMT1 protein. We targeted the acidic residues on the hydrophilic C‐terminal domain of TaALMT1 and changed them to uncharged residues by site‐directed mutagenesis. These mutant proteins were expressed in Xenopus oocytes and their transport activity was measured before and after Al³⁺ addition. Three mutations (E274Q, D275N and E284Q) abolished the Al³⁺‐activated transport activity without affecting the basal transport activity. Truncation of the hydrophilic C‐terminal domain abolished both basal and Al³⁺‐activated transport activities. Al³⁺‐dependent transport activity was recovered by fusing the N‐terminal region of TaALMT1 with the C‐terminal region of AtALMT1, a homolog from Arabidopsis. These findings demonstrate that the extracellular C‐terminal domain is required for both basal and Al³⁺‐dependent TaALMT1 activity. Furthermore, we identified three acidic amino acids within this domain that are specifically required for the activation of transport function by external Al³⁺.     

Optimising the signal peptide for glycosyl phosphatidylinositol modification of human acetylcholinesterase using mutational analysis and peptide-quantitative structure-activity relationships.

Glycosyl phosphatidylinositol (GPI)-modified proteins have a C-terminal signal peptide (GPIsp) that mediates the addition of a GPI-anchor to an amino acid residue at the cleavage and modification site (omega-site). Within the GPIsp, a stretch of hydrophilic amino acid residues are found which constitutes the spacer region that separates the omega-site residue from a hydrophobic C-terminus. Deletions and insertions into the spacer region of human acetylcholinesterase (AChE) show that the length of this spacer region is very important for efficient GPI-modification. Surprisingly, the natural length of the spacer region in human AChE was not optimal for the highest degree of GPI modification. The importance of the two adjacent residues downstream of the omega-site, the omega+1 and omega+2 residues, was investigated by peptide-quantitative structure-activity relationships (Peptide-QSAR). A model was made that predicts the efficiency of the GPI modification when these residues are substituted with others, and suggests important features for these residues. The most preferred omega+1 and omega+2 residues, predicted by the model, in combination with an ideal spacer length resulted in an optimised GPIsp. This mutant protein is more efficiently GPI-modified than any mutant AChE tested thus far.     

Determination and physiological roles of the glycosylphosphatidylinositol lipid remodelling pathway in yeast

In the yeast Saccharomyces cerevisiae, glycosylphosphatidylinositol (GPI)‐anchored proteins play important roles in cell wall biogenesis/assembly and the formation of lipid microdomains. The lipid moieties of mature GPI‐anchored proteins in yeast typically contain either ceramide moieties or diacylglycerol. Recent studies have identified that the GPI phospholipase A₂ Per1p and O‐acyltransferase Gup1p play essential roles in diacylglycerol‐type lipid remodelling of GPI‐anchored proteins, while Cwh43p is involved in the remodelling of lipid moieties to ceramide. It has been generally proposed that phosphatidylinositol with diacylglycerol containing a C26 saturated fatty acid, which is generated by the sequential activity of Per1p and Gup1p, is converted to inositolphosphorylceramide by Cwh43p. In this report, we constructed double‐mutant strains defective in lipid remodelling and investigated their growth phenotypes and the lipid moieties of GPI‐anchored proteins. Based on our analyses of single‐ and double‐mutants of proteins involved in lipid remodelling, we demonstrate that an alternative pathway, in which lyso‐phosphatidylinositol generated by Per1p is used as a substrate for Cwh43p, is involved in the remodelling of GPI lipid moieties to ceramide when the normal sequential pathway is inhibited. In addition, mass spectrometric analysis of lipid species of Flag‐tagged Gas1p revealed that Gas1p contains ceramide moieties in its GPI anchor.     

Arabidopsis COBRA‐LIKE 10, a GPI‐anchored protein,mediates directional growth of pollen tubes

Successful reproduction of flowering plants requires constant communication between female tissues and growing pollen tubes. Female cells secrete molecules and peptides as nutrients or guidance cues for fast and directional tube growth, which is executed by dynamic changes of intracellular activities within pollen tubes. Compared with the extensive interest in female cues and intracellular activities of pollen tubes, how female cues are sensed and interpreted intracellularly in pollen is poorly understood. We show here that COBL10, a glycosylphosphatidylinositol (GPI)‐anchored protein, is one component of this pollen tube internal machinery. Mutations in COBL10 caused gametophytic male sterility due to reduced pollen tube growth and compromised directional sensing in the female transmitting tract. Deposition of the apical pectin cap and cellulose microfibrils was disrupted in cobl10 pollen tubes. Pollen tube localization of COBL10 at the apical plasma membrane is critical for its function and relies on proper GPI processing and its C‐terminal hydrophobic residues. GPI‐anchored proteins are widespread cell sensors in mammals, especially during egg‐sperm communication. Our results that COBL10 is critical for directional growth of pollen tubes suggest that they play critical roles in cell‐cell communications in plants.     

Use of Clostridium septicum alpha toxins for isolation of various glycosylphosphatidylinositol-deficient cells

In eukaryotic cells, various proteins are anchored to the plasma membrane through glycosylphosphatidylinositol (GPI). To study the biosynthetic pathways and modifications of GPI, various mutant cells have been isolated from the cells of Chinese hamster ovaries (CHO) supplemented with several exogenous genes involved in GPI biosynthesis using aerolysin, a toxin secreted from gram-negative bacterium Aeromonas hydrophila. Alpha toxin from Gram-positive bacterium Clostridium septicum is homologous to large lobes (LL) of aerolysin, binds GPI-anchored proteins and possesses a cell-destroying mechanism similar to aerolysin. Here, to determine whether alpha toxins can be used as an isolation tool of GPI-mutants, like aerolysin, CHO cells stably transfected with several exogenous genes involved in GPI biosynthesis were chemically mutagenized and cultured in a medium containing alpha toxins. We isolated six mutants highly resistant to alpha toxins and deficient in GPI biosynthesis. By genetic complementation, we determined that one mutant cell was defective of the second subunit of dolichol phosphate mannose synthase (DPM2) and other five cells were of a putative catalytic subunit of inositol acyltransferase (PIG-W). Therefore, C. septicum alpha toxins are a useful screening probe for the isolation of various GPI-mutant cells.     

Characterization of the SRP68/72 interface of human signal recognition particle by systematic site‐directed mutagenesis

The signal recognition particle (SRP) is a ribonucleoprotein complex which is crucial for the delivery of proteins to cellular membranes. Among the six proteins of the eukaryotic SRP, the two largest, SRP68 and SRP72, form a stable SRP68/72 heterodimer of unknown structure which is required for SRP function. Fragments 68e′ (residues 530 to 620) and 72b′ (residues 1 to 166) participate in the SRP68/72 interface. Both polypeptides were expressed in Escherichia coli and assembled into a complex which was stable at high ionic strength. Disruption of 68e′/72b′ and SRP68/72 was achieved by denaturation using moderate concentrations of urea. The four predicted tetratricopeptide repeats (TPR1 to TPR4) of 72b′ were required for stable binding of 68e′. Site‐directed mutagenesis suggested that they provide the structural framework for the binding of SRP68. Deleting the region between TPR3 and TPR4 (h120) also prevented the formation of a heterodimer, but this predicted alpha‐helical region appeared to engage several of its amino acid residues directly at the interface with 68e′. A 39‐residue polypeptide (68h, residues 570–605), rich in prolines and containing an invariant aspartic residue at position 585, was found to be active. Mutagenesis scanning of the central region of 68h demonstrated that D585 was solely responsible for the formation of the heterodimer. Coexpression experiments suggested that 72b′ protects 68h from proteolytic digestion consistent with the assertion that 68h is accommodated inside a groove formed by the superhelically arranged four TPRs of the N‐terminal region of SRP72.     

Mycoplasma pneumoniae Mpn133 is a cytotoxic nuclease with a glutamic acid‐, lysine‐ and serine‐rich region essential for binding and internalization but not enzymatic activity

We identified Mpn133 as a Ca²⁺‐dependent cytotoxic nuclease of Mycoplasma pneumoniae. Flow cytometry analysis and immunofluorescence studies revealed the binding and internalization of recombinant Mpn133 (rMpn133) in human airway A549 cells. Amino acid sequence comparisons of Mpn133 with other mycoplasma nucleases demonstrated the presence of a unique glutamic acid‐, lysine‐ and serine‐rich region (EKS region; amino acids 72–110). Deletion of this EKS peptide (rMpn133^Δ72–110) abrogated its binding and internalization but not its nuclease activity. The function of the EKS region in host cell trafficking and nuclear localization was reinforced by the successful delivery of EKS‐conjugated mCherry protein into A549 cells. rMpn133, but not rMpn133^Δ72–110, induced apoptosis‐like death in A549 cells. This observation suggested a unique role of Mpn133 as an important contributor to M. pneumoniae‐associated life cycle events and as a virulence factor in host‐associated cytopathologies. In addition, the distinct property of the EKS peptide in delivery of proteins, like mCherry, into target cells opens new avenues to the establishment of novel concepts of drug delivery and therapy.     

A recombinant carboxy‐terminal domain of alpha‐toxin protects mice against Clostridium perfringens

Clostridium perfringens alpha‐toxin (CP, 370 residues) is one of the main agents involved in the development of gas gangrene. In this study, the immunogenicity and protective efficacy of the C‐terminal domain (CP251‐370) of the toxin and phospholipase C (PLC; CB, 372 residues) of Clostridum bifermentans isolated from cases of clostridium necrosis were examined. The recombinant proteins were expressed as glutathione S‐transferase (GST) fusion proteins. Antibodies that cross‐reacted with alpha‐toxin were produced after immunization with recombinant proteins including GST‐CP251‐370, GST‐CP281‐370, GST‐CP311‐370, CB1‐372 and GST‐CB251‐372. Anti‐GST‐CP251‐370, anti‐GST‐CP281‐370 and anti‐GST‐CP311‐370 sera neutralized both the PLC and hemolytic activities of alpha‐toxin, whereas anti‐CB1‐372 and anti‐GST‐CB251‐372 weakly neutralized these activities. Immunization with GST‐CP251‐370 and GST‐CP281‐370 provided protection against the lethal effects of the toxin and C. perfringens type A NCTC8237. Partial protection from the toxin and C. perfringens was elicited by immunization with GST‐CP311‐370 and CB1‐372. GST‐CP251‐370 and GST‐CP281‐370 are promising candidates for vaccines for clostridial‐induced gas gangrene.     

Assignment of the contribution of the tryptophan residues to the spectroscopic and functional properties of the ribotoxin alpha-sarcin

alpha-Sarcin, a potent cytotoxic protein from Aspergillus giganteus, contains two tryptophan residues at positions 4 and 51. Two single, W4F and W51F, and the double mutant, W4/51F, have been produced and purified to homogeneity. These two residues are neither required for the highly specific ribonucleolytic activity of the protein on the ribosomes (production of the so called alpha-fragment) nor for its interaction with lipid membranes (aggregation and fusion of vesicles), although the mutant forms involving Trp-51 show a decreased ribonuclease activity. Proton NMR data reveal that no significant changes in the global structure of the enzyme occur upon replacement of Trp-51 by Phe. Substitution of each Trp residue results in a 4 degrees C drop in the thermal denaturation midpoint, and the double mutant's midpoint is 9 degrees C lower. Trp-51 is responsible for most of the near-UV circular dichroism of the protein and also contributes to the overall ellipticity of the protein in the peptide bond region. Trp-51 does not show fluorescence emission. The membrane-bound proteins undergo a thermal denaturation at a lower temperature than the corresponding free forms. The interaction of the protein with phospholipid bilayers promotes a large increase of the quantum yield of Trp-51 and its fluorescence emission is quenched by anthracene incorporated into the hydrophobic region of such bilayers. This indicates that the region around this residue is located in the hydrophobic core of the bilayer following protein-vesicle interaction.     

Arabidopsis thaliana FLA4 functions as a glycan‐stabilized soluble factor via its carboxy‐proximal Fasciclin 1 domain

Fasciclin‐like arabinogalactan proteins (FLAs) are involved in numerous important functions in plants but the relevance of their complex structure to physiological function and cellular fate is unresolved. Using a fully functional fluorescent version of Arabidopsis thaliana FLA4 we show that this protein is localized at the plasma membrane as well as in endosomes and soluble in the apoplast. FLA4 is likely to be GPI‐anchored, is highly N‐glycosylated and carries two O‐glycan epitopes previously associated with arabinogalactan proteins. The activity of FLA4 was resistant against deletion of the amino‐proximal fasciclin 1 domain and was unaffected by removal of the GPI‐modification signal, a highly conserved N‐glycan or the deletion of predicted O‐glycosylation sites. Nonetheless these structural changes dramatically decreased endoplasmic reticulum (ER)‐exit and plasma membrane localization of FLA4, with N‐glycosylation acting at the level of ER‐exit and O‐glycosylation influencing post‐secretory fate. We show that FLA4 acts predominantly by molecular interactions involving its carboxy‐proximal fasciclin 1 domain and that its amino‐proximal fasciclin 1 domain is required for stabilization of plasma membrane localization. FLA4 functions as a soluble glycoprotein via its carboxy‐proximal Fas1 domain and its normal cellular trafficking depends on N‐ and O‐glycosylation.