Proprotein interaction with the GPI transamidase

For characterizing how the glycosylphosphatidylinositol (GPI) transamidase complex functions, we exploited a two-step miniPLAP (placental alkaline phosphatase) in vitro translation system. With this system, rough microsomal membranes (RM) containing either [(35)S]-labeled Gaa1p or epitope-tagged Gpi8p, alternative components of the enzymatic complex, were first prepared. In a second translation, unmodified or mutant miniPLAP mRNA was used such that [(35)S]-labeled native or variant miniPLAP nascent protein was introduced. Following this, the RM were solubilized and anti-PLAP or anti-epitope immunoprecipitates were analyzed. With transamidase competent HeLa cell RM, anti-PLAP or anti-epitope antibody coprecipitated both Gaa1p and Gpi8p consistent with the assembly of the proprotein into a Gaa1p:Gpi8p-containing complex. When RM from K562 mutant K cells which lack Gpi8p were used, anti-PLAP antibody coprecipitated Gaa1p. The proprotein coprecipitation of Gaa1p increased with a nonpermissive GPI anchor addition (omega) site. In contrast, if a miniPLAP mutant devoid of its C-terminal signal was used, no coprecipitation occurred. During the transamidation reaction, a transient high Mr band forms. To definitively characterize this product, RM from K cells transfected with FLAG-tagged GPI8 were employed. Western blots of anti-FLAG bead isolates of solubilized RM from the cells showed that the high Mr band corresponded to Gpi8p covalently bound to miniPLAP. Loss of the band following hydrazinolysis demonstrated that the two components were associated in a thioester linkage. The data indicate that recognition of the proprotein involves Gaa1p, that the interaction with the complex does not depend on a permissive omega site, and that Gpi8p forms a thioester intermediate with the proprotein. The method could be useful for rapid analysis of nascent protein interactions with transamidase components, and possibly for helping to prepare a functional in vitro transamidase system.     

Aberrant cytosolic acyl-CoA thioester hydrolase in hippocampus of patients with mesial temporal lobe epilepsy

Summary. A series of enzyme alterations has been shown to be associated with several forms of epilepsy, in mesial temporal lobe epilepsy (MTLE), however, information is limited. It was therefore the aim of the study to determine brain enzyme protein expression using a proteomic screening approach. Hippocampi of controls and patients with drug-resistant MTLE were used for evaluation of protein expression. We applied two-dimensional electrophoresis (2-DE) with mass spectrometrical identification and immunoblotting. 2-DE revealed a remarkably decreased spot identified as cytosolic acyl-CoA thioester hydrolase (BACH; EC 3.1.2.2) in patients with MTLE. Western blotting showed absence of bands at 37kDa in MTLEs using an antibody against mouse BACH and at 140kDa in MTLEs using anti-rat BACH. This study demonstrates that BACHs were deranged in hippocampus of MTLE patients. This finding may well contribute to the understanding of the still elusive pathomechanisms involved in MTLE.J. W. Yang and T. Czech have equally contributed to the paper.     

Preparation of phosphopeptide thioesters by Fmoc- and Fmoc(2-F)-solid phase synthesis

Efficient methods for the preparation of phosphopeptidethioesters were examined, using Fmoc-based solid-phase method.Phosphopeptide thioesters were obtained in good yields by theuse of 1-methylpyrrolidine, hexamethyleneimine and 1-hydroxybenzotriazole in a DMSO-DMF (1:1, v/v) solution fordeblocking the Fmoc groups. Epimerization, which is oftenobserved at the C-terminal amino acid, was effectivelysuppressed by shortening the time of deblocking process viathe use of highly base sensitive Fmoc(2-F) groups for -aminoprotection.     

Investigation of peptide thioester formation via N→Se acyl transfer

Native chemical ligation is widely used for the convergent synthesis of proteins. The peptide thioesters required for this process can be challenging to produce, particularly when using Fmoc‐based solid‐phase peptide synthesis. We have previously reported a route to peptide thioesters, following Fmoc solid‐phase peptide synthesis, via an N→S acyl shift that is initiated by the presence of a C‐terminal cysteine residue, under mildly acidic conditions. Under typical reaction conditions, we occasionally observed significant thioester hydrolysis as a consequence of long reaction times (~48 h) and sought to accelerate the reaction. Here, we present a faster route to peptide thioesters, by replacing the C‐terminal cysteine residue with selenocysteine and initiating thioester formation via an N→Se acyl shift. This modification allows thioester formation to take place at lower temperatures and on shorter time scales. We also demonstrate how application of this strategy also accelerates peptide cyclization, when a linear precursor is furnished with an N‐terminal cysteine and C‐terminal selenocysteine. Copyright © 2013 European Peptide Society and John Wiley & Sons, Ltd.     

A novel post‐ligation thioesterification device enables peptide ligation in the N to C direction: synthetic study of human glycodelin

Human glycodelin consists of 162 amino acid residues and two N‐linked glycans at Asn²⁸ and Asn⁶³. In this study, we synthesized it by a fully convergent strategy using native chemical ligation (NCL) in N to C direction. The four peptide segments corresponding to 1–31, 32–65, 66–105 and 106–162 sequences were synthesized by 9‐fluorenylmethoxycarbonyl based solid‐phase peptide synthesis. At the C‐terminus of the second segment, N‐ethyl‐S‐acetamidomethyl‐cysteine was attached as a post‐ligation thioesterification device. The N‐terminal two segments were condensed by the homocysteine‐mediated NCL at Leu‐Met site, and the product was methylated to convert homocysteine to methionine. After deprotection of acetamidomethyl group on the N‐ethylcysteine residue, the peptide was thioesterified by N‐alkylcysteine‐assisted method. The product was then ligated with the C‐terminal half, which was obtained by the NCL of third and fourth segments, to give the full‐length glycodelin. Copyright © 2013 European Peptide Society and John Wiley & Sons, Ltd.     

Uniform binding and negative catalysis at the origin of enzymes

Enzymes are well known for their catalytic abilities, some even reaching “catalytic perfection” in the sense that the reaction they catalyze has reached the physical bound of the diffusion rate. However, our growing understanding of enzyme superfamilies has revealed that only some share a catalytic chemistry while others share a substrate‐handle binding motif, for example, for a particular phosphate group. This suggests that some families emerged through a “substrate‐handle‐binding‐first” mechanism (“binding‐first” for brevity) instead of “chemistry‐first” and we are, therefore, left to wonder what the role of non‐catalytic binders might have been during enzyme evolution. In the last of their eight seminal, back‐to‐back articles from 1976, John Albery and Jeremy Knowles addressed the question of enzyme evolution by arguing that the simplest mode of enzyme evolution is what they defined as “uniform binding” (parallel stabilization of all enzyme‐bound states to the same degree). Indeed, we show that a uniform‐binding proto‐catalyst can accelerate a reaction, but only when catalysis is already present, that is, when the transition state is already stabilized to some degree. Thus, we sought an alternative explanation for the cases where substrate‐handle‐binding preceded any involvement of a catalyst. We find that evolutionary starting points that exhibit negative catalysis can redirect the reaction''s course to a preferred product without need for rate acceleration or product release; that is, if they do not stabilize, or even destabilize, the transition state corresponding to an undesired product. Such a mechanism might explain the emergence of “binding‐first” enzyme families like the aldolase superfamily.     

油质体在5种蚁播植物种子散布中的作用

蚁播植物种子上常附着有蚂蚁喜食的油质体,该物体可吸引蚂蚁取食或为蚂蚁提供钳着位点从而影响种子散布。为进一步揭示油质体在种子散布中的作用,在野外研究了4属5种典型蚁播植物包括小花宽瓣黄堇(Corydalis giraldii Fedde)、假刻叶紫堇(C.pseudoincisa C.Y.Wu)、白屈菜(Chelidonium majus L.)、紫花堇菜(Viola grypoceras A.Gray)和柔毛淫羊藿(Epimedium pubescens Maxim.)其相应的搬运蚂蚁即玉米毛蚁(Lasius alienus(Foerster))和尼特纳大头蚁(Pheidole nietneri Emery)对植物完整种子(SE)、去除油质体的种子(S)和粘有人工模拟油质体的种子(S+H)的搬运行为和搬运效率。结果显示,蚂蚁对相同植物3类种子的触碰和检查次数均无显著差异。蚂蚁对种子的尝试搬运次数除玉米毛蚁对小花宽瓣黄堇、假刻叶紫堇和白屈菜去除油质体的种子(S)显著高于完整种子(SE)和粘有人工模拟油质体的种子(S+H)外,其它的均无显著差异。玉米毛蚁对小花宽瓣黄堇、假刻叶紫堇、白屈菜和紫花堇菜以及尼特纳大头蚁对小花宽瓣黄堇、假刻叶紫堇和紫花堇菜完整种子(SE)的搬运效率显著高于粘有人工模拟油质体的种子(S+H)和去除油质体的种子(S),此外,玉米毛蚁对小花宽瓣黄堇粘有人工模拟油质体的种子(S+H)的搬运效率显著高于去除油质体的种子(S)。这说明玉米毛蚁在搬运小花宽瓣黄堇种子过程中油质体不仅起到吸引作用,而且起到钳着位点作用;玉米毛蚁在搬运假刻叶紫堇、白屈菜和紫花堇菜以及尼特纳大头蚁搬运小花宽瓣黄堇、假刻叶紫堇和紫花堇菜种子过程中油质体仅起到吸引作用。研究表明油质体可通过对蚂蚁起吸引作用,或同时起吸引和钳着位点的双重作用等影响种子散布,油质体的影响作用不但取决于植物种类,也与搬运蚂蚁的种类有关。     

β-Sheet Augmentation Is a Conserved Mechanism of Priming HECT E3 Ligases for Ubiquitin Ligation

Ubiquitin (Ub) ligases (E3s) catalyze the attachment of Ub chains to target proteins and thereby regulate a wide array of signal transduction pathways in eukaryotes. In HECT-type E3s, Ub first forms a thioester intermediate with a strictly conserved Cys in the C-lobe of the HECT domain and is then ligated via an isopeptide bond to a Lys residue in the substrate or a preceding Ub in a poly-Ub chain. To date, many key aspects of HECT-mediated Ub transfer have remained elusive. Here, we provide structural and functional insights into the catalytic mechanism of the HECT-type ligase Huwe1 and compare it to the unrelated, K63-specific Smurf2 E3, a member of the Nedd4 family. We found that the Huwe1 HECT domain, in contrast to Nedd4-family E3s, prioritizes K6- and K48-poly-Ub chains and does not interact with Ub in a non-covalent manner. Despite these mechanistic differences, we demonstrate that the architecture of the C-lobe ~ Ub intermediate is conserved between Huwe1 and Smurf2 and involves a reorientation of the very C-terminal residues. Moreover, in Nedd4 E3s and Huwe1, the individual sequence composition of the Huwe1 C-terminal tail modulates ubiquitination activity, without affecting thioester formation. In sum, our data suggest that catalysis of HECT ligases hold common features, such as the β-sheet augmentation that primes the enzymes for ligation, and variable elements, such as the sequence of the HECT C-terminal tail, that fine-tune ubiquitination activity and may aid in determining Ub chain specificity by positioning the substrate or acceptor Ub.     

Dominance of mixed ether/ester,intact polar membrane lipids in five species of the order Rubrobacterales: Another group of bacteria not obeying the “lipid divide”

The composition of the core lipids and intact polar lipids (IPLs) of five Rubrobacter species was examined. Methylated (ω-4) fatty acids (FAs) characterized the core lipids of Rubrobacter radiotolerans, R. xylanophilus and R. bracarensis. In contrast, R. calidifluminis and R. naiadicus lacked ω-4 methyl FAs but instead contained abundant (i.e., 34–41 % of the core lipids) ω-cyclohexyl FAs not reported before in the order Rubrobacterales. Their genomes contained an almost complete operon encoding proteins enabling production of cyclohexane carboxylic acid CoA thioester, which acts as a building block for ω-cyclohexyl FAs in other bacteria. Hence, the most plausible explanation for the biosynthesis of these cyclic FAs in R. calidifluminis and R. naiadicus is a recent acquisition of this operon. All strains contained 1-O-alkyl glycerol ether lipids in abundance (up to 46 % of the core lipids), in line with the dominance (>90 %) of mixed ether/ester IPLs with a variety of polar headgroups. The IPL head group distribution of R. calidifluminis and R. naiadicus differed, e.g. they lacked a novel IPL tentatively assigned as phosphothreoninol. The genomes of all five Rubrobacter species contained a putative operon encoding the synthesis of the 1-O-alkyl glycerol phosphate, the presumed building block of mixed ether/ester IPLs, which shows some resemblance with an operon enabling ether lipid production in various other aerobic bacteria but requires more study. The uncommon dominance of mixed ether/ester IPLs in Rubrobacter species exemplifies our recent growing awareness that the lipid divide between archaea and bacteria/eukaryotes is not as clear cut as previously thought.     

Oligoglyceric acid synthesis by autocondensation of glyceroyl thioester

Summary The autocondensation of the glyceroyl thioesterS-glyceroyl-ethanethiol yielded oligoglyceric acid. The rates of autocondensation and hydrolysis of the thioester increased from pH 6.5 to pH 7.5 in 2,6-lutidine and imidazole buffers. Autocondensation and hydrolysis were much more rapid in imidazole buffers than in 2,6-lutidine buffers of the same pH. The efficiency of ester bond synthesis was about 20% for 40 mMS-glyceroylethanethiol in 2,6-lutidine and imidazole buffers near neutral pH. The size and yield of the oligoglyceric acid products increased when the concentration of the thioester was increased. The relationship of these results to prebiotic polymer synthesis is discussed.