Interaction of α2-macroglobulin with L-asparaginase

Summary Obvious protection of the catalytic activity of Esch. coli L-asparaginase by ₂-macroglobulin (₂M) was observed under conditions otherwise propitious to the dissociation of the tetrameric molecule into inactive subunits, i.e. very diluted enzyme solutions or the presence of either SDS or urea. The degree of protection depended on enzyme and ₂M concentrations respectively, and on the preincubation time of the ₂M-enzyme mixture prior to substrate addition. The formation of a catalytically active complex between ₂M and L-asparaginase was confirmed by gel filtration on a Sephadex-G column and by polyacrylamide gel electrophoresis. The fact that the migration distance of the active complex corresponded to the migration of ₂M and the absence in that case of a migration band corresponding to the intact molecule suggest that complexing of the enzyme with ₂M prevented its dissociation into subunits and thus its inactivation. Addition of ₂M to the already dissociated enzyme molecule did not restore its catalytic activity.Alpha₂-macroglobulin was shown to have an inhibiting effect on the proteolytic activity of almost all proteases and no effect on their esterolytic activity. Furthermore, it prevents the inhibition of esterolytic activity by some natural compounds^1–5. The effect of ₂M on other types of catalytic activity has not been investigated enough to afford a generalization of the possible role of this macroglobulin in the control of enzyme activity in the body.This paper reports the results of an in vitro study of the effect of ₂M on the catalytic activity of an important amidase, i.e. L-asparaginase (L-asparagine amidohydrolase 3.5.1.1), which in recent years has been used in the treatment of acute lymphocytic leukemia in children^6,7.Abbreviations ₂M ₂-macroglobulin - E enzyme - SDS sodium dodecylsulfate Part of the results were reported at the 10th International Congress of Biochemistry, Hamburg 1976, Abst. p. 377.     

Interaction of transmembrane-spanning segments of the α2-adrenergic receptor with model membranes

Adrenergic receptors are integral membrane proteins involved in cellular signalling that belong to the G protein-coupled receptors. Synthetic peptides resembling the putative transmembrane (TM) segments TM4, TM6 and TM7, of the human α2-adrenergic receptor subtype C10 (P08913) and defined lipid vesicles were used to assess protein-lipid interactions that might be relevant to receptor structure/function. P6 peptide contains the hydrophobic core of TM6 plus the N-terminal hydrophilic motif REKR, while peptides P4 and P7 contained just the hydrophobic stretches of TM4 and TM7, respectively. All the peptides increase their helical tendency at moderate concentrations of TFE (30–50%) and in presence of 1,2-dielaidoyl-sn-glycero-3-phosphatidylethanolamine (DEPE) lipids. However, only P6 displays up to 19% of α-helix in the presence of just the DEPE lipids, evidences a transmembrane orientation and stabilizes the Lα lipid phase. Conversely, P4 and P7 peptides form only stable β-sheet structures in DEPE and favour the non-lamellar, inverted hexagonal (H_II) phase of DEPE by lowering its phase transition temperature. This study highlights the potential of using synthetic peptides derived from the amino acid sequence in the native proteins as templates to understand the behaviour of the transmembrane segments and underline the importance of interfacial anchoring interactions to meet hydrophobic matching requirements and define membrane organization.     

Interaction of the α2A domain of integrin with small collagen fragments

We here present a detailed study of the ligand-receptor interactions between single and triple-helical strands of collagen and the α2A domain of integrin (α2A), providing valuable new insights into the mechanisms and dynamics of collagen-integrin binding at a sub-molecular level. The occurrence of single and triple-helical strands of the collagen fragments was scrutinized with atom force microscopy (AFM) techniques. Strong interactions of the triple-stranded fragments comparable to those of collagen can only be detected for the 42mer triple-helical collagen-like peptide under study (which contains 42 amino acid residues per strand) by solid phase assays as well as by surface plasmon resonance (SPR) measurements. However, changes in NMR signals during titration and characteristic saturation transfer difference (STD) NMR signals are also detectable when α2A is added to a solution of the 21mer single-stranded collagen fragment. Molecular dynamics (MD) simulations employing different sets of force field parameters were applied to study the interaction between triple-helical or single-stranded collagen fragments with α2A. It is remarkable that even single-stranded collagen fragments can form various complexes with α2A showing significant differences in the complex stability with identical ligands. The results of MD simulations are in agreement with the signal alterations in our NMR experiments, which are indicative of the formation of weak complexes between single-stranded collagen and α2A in solution. These results provide useful information concerning possible interactions of α2A with small collagen fragments that are of relevance to the design of novel therapeutic A-domain inhibitors.     

Interaction of α-lactalbumin with dimyristoylphosphatidylcholine vesicles. III. Influence of the temperature and of the lipid-to-protein molar ratio on the complex formation

We investigated the interaction between α-lactalbumin and sonicated dimyristoylphosphatidylcholine at pH 4 and different temperatures. (1) At 23°C and lipid-to-protein molar ratios below 170, the interaction results in a disruption of the original vesicles to form smaller complex particles. By the sedimentation velocity method we determined for this particle a molar mass of (1.05 ± 0.16) · 10⁶ g·mol^?1. The lipid-to-protein molar ratio within the complex particle is 70/1, as earlier estimated. It follows that there are approximately 1200 lipid and 17 α-lactalbumin molecules per particle. At molar ratios above 170, α-lactalbumin strongly associates with the vesicles. In this case the vesicle entity remains. The ability of α-lactalbumin to break up the vesicles at this temperature is determined by the number of protein molecules which are required in the complex particle. (2) By means of fluorescence polarization of the lipophilic probe 1,6-diphenyl-1,3,5-hexatriene and energy transfer of the tryptophan groups of the protein to 1,3-(1,1′-dipyrenyl)propane located in the hydrocarbon region of the vesicles, it is shown that with increasing temperature above 25°C, complexes of decreasing internal lipid-to-protein molar ratio are formed. However, by electron microscopy we show that the overall size of these complexes remains approximately the same, i.e., bars with dimensions $\text{70 × 220}\text{A}\text{?}$. A temperature-reversible transformation occurs between these complexes, which cannot be isolated by gel chromatography. In contrast, the complex of molar ratio 70/1 remains stable at lower temperatures.     

Interaction of chaperone α-crystallin with unfolded state of α-amylase: Implications for reconstitution of the active enzyme

α-Crystallin is reported to act like molecular chaperone by suppressing the aggregation of damaged crystallins in eye lens. In this work, it is shown that α-crystallin increases the reactivation of guanidine hydrochloride (GdnHCl)-denatured α-amylase from porcine pancreas. 8-Anilinonaphthalene-sulphonate (ANS) binding studies reveal the involvement of hydrophobic interactions in the formation of the complex of α-crystallin and α-amylase. On the basis of our fluorescence spectroscopic and gel-filtration results, we propose that α-crystallin blocks the unfavorable pathways that lead to irreversible denaturation of α-amylase and keep it in folding-competent intermediate state.     

The Tre2 Oncoprotein, Implicated in Ewing’s Sarcoma, Interacts with Two Components of the Cytoskeleton

The product of the Tre2 oncogene, structurally related to the Ypt/RabGTPase-activating proteins (Ypt/RabGAP), is involved in various human cancers, including Ewing’s sarcoma. In order to identify proteins interacting with the GAP part of this protein, we performed yeast two-hybrid screening of two libraries. Two components of the cytoskeleton were thus identified, whose interaction with the GAP region was confirmed by GST-pulldown, co-immunoprecipitation, and colocalisation experiments. The proteins found to interact with the GAP region are the light regulatory chain of myosin II (Myl2) and LOC91256, a protein containing ankyrin repeats.     

Interaction of α-Chymotrypsin with Dimethyl Sulfoxide: A Change of Substrate Could “Change” the Interaction Mechanism

The kinetic behavior of -chymotrypsin was studied in water–DMSO mixtures at concentrations of the organic solvent that do not cause irreversible denaturation of the enzyme. Various substrates (N-substituted derivatives of L-tyrosine) were found to display substantially different kinetic patterns of interaction with -chymotrypsin, which can be described by totally different kinetic schemes. The differences were ascribed to competition between the N-acyl group of the substrate and the DMSO molecule at the S ₂ site of substrate binding to the active site of the enzyme.     

Interaction of α-cyano[14C]cinnamate with the mitochondrial pyruvate translocator

The binding of α-cyanocinnamate to rat-heart mitochondrial membrane was investigated using α-cyano[¹⁴C]cinnamate. The binding was correlated to the inhibition of pyruvate transport. The results obtained demonstrate that both these functions reach saturation at the same titre of the inhibitor. Quantitative parameters of α-cyano[¹⁴C]cinnamate binding have been determined. The binding can be prevented by pyruvate and other substrates of the carrier but not by acetate. Pyruvate decreases the affinity of α-cyanocinnamate binding, leaving the maximum number of binding unchanged. It is concluded that rat-heart mitochondria contain a specific site at which α-cyanocinnamate binds which is directly involved in the inhibition of pyruvate transport.     

Interaction of Insulin-Like Growth Factor-Binding Protein 2 with α2-Macroglobulin in the Circulation

Insulin-like growth factors (IGFs) play active role in mitogenic and metabolic processes. In the peripheral circulation, they are mostly bound to specific IGF-binding proteins (IGFBPs). Proteolysis of IGFBPs releases free, active IGFs. IGFBP-2 is the second most abundant of the six binding proteins and its concentration increases in catabolic states. The possible interaction between IGFBP-2 and other proteins in the circulation was investigated in this study. Our results showed that IGFBP-2 associates with α2-macroglobulin (α2M), a protease inhibitor. Formation of IGFBP-2/α2M complexes most likely contributes to the regulation of IGFBP-2 proteolysis and, thus, the activity of IGFs.     

Interaction of α-synuclein with vesicles that mimic mitochondrial membranes

α-Synuclein, an intrinsically-disordered protein associated with Parkinson's disease, interacts with mitochondria, but the details of this interaction are unknown. We probed the interaction of α-synuclein and its A30P variant with lipid vesicles by using fluorescence anisotropy and (19)F nuclear magnetic resonance. Both proteins interact strongly with large unilamellar vesicles whose composition is similar to that of the inner mitochondrial membrane, which contains cardiolipin. However, the proteins have no affinity for vesicles mimicking the outer mitochondrial membrane, which lacks cardiolipin. The (19)F data show that the interaction involves α-synuclein's N-terminal region. These data indicate that the middle of the N-terminal region, which contains the KAKEGVVAAAE repeats, is involved in binding, probably via electrostatic interactions between the lysines and cardiolipin. We also found that the strength of α-synuclein binding depends on the nature of the cardiolipin acyl side chains. Eliminating one double bond increases affinity, while complete saturation dramatically decreases affinity. Increasing the temperature increases the binding of wild-type, but not the A30P variant. The data are interpreted in terms of the properties of the protein, cardiolipin demixing within the vesicles upon binding of α-synuclein, and packing density. The results advance our understanding of α-synuclein's interaction with mitochondrial membranes.     

Interaction of C-Terminal Truncated Human αA-Crystallins with Target Proteins

Background

Significant portion of αA-crystallin in human lenses exists as C-terminal residues cleaved at residues 172, 168, and 162. Chaperone activity, determined with alcohol dehydrogenase (ADH) and βL-crystallin as target proteins, was increased in αA_1–172 and decreased in αA_1–168 and αA_1–162. The purpose of this study was to show whether the absence of the C-terminal residues influences protein-protein interactions with target proteins.

Methodology/Principal Findings

Our hypothesis is that the chaperone-target protein binding kinetics, otherwise termed subunit exchange rates, are expected to reflect the changes in chaperone activity. To study this, we have relied on fluorescence resonance energy transfer (FRET) utilizing amine specific and cysteine specific fluorescent probes. The subunit exchange rate (k) for ADH and αA_1–172 was nearly the same as that of ADH and αA-wt, αA_1–168 had lower and αA_1–162 had the lowest k values. When βL-crystallin was used as the target protein, αA_1–172 had slightly higher k value than αA-wt and αA_1–168 and αA_1–162 had lower k values. As expected from earlier studies, the chaperone activity of αA_1–172 was slightly better than that of αA-wt, the chaperone activity of αA_1–168 was similar to that of αA-wt and αA_1–162 had substantially decreased chaperone activity.

Conclusions/Significance

Cleavage of eleven C-terminal residues including Arg-163 and the C-terminal flexible arm significantly affects the interaction with target proteins. The predominantly hydrophilic flexible arm appears to be needed to keep the chaperone-target protein complex soluble.     

Intracellular proton-mediated activation of TRPV3 channels accounts for the exfoliation effect of α-hydroxyl acids on keratinocytes

α-Hydroxyl acids (AHAs) from natural sources act as proton donors and topical compounds that penetrate skin and are well known in the cosmetic industry for their use in chemical peels and improvement of the skin. However, little is known about how AHAs cause exfoliation to expose fresh skin cells. Here we report that the transient receptor potential vanilloid 3 (TRPV3) channel in keratinocytes is potently activated by intracellular acidification induced by glycolic acid. Patch clamp recordings and cell death assay of both human keratinocyte HaCaT cells and TRPV3-expressing HEK-293 cells confirmed that intracellular acidification led to direct activation of TRPV3 and promoted cell death. Site-directed mutagenesis revealed that an N-terminal histidine residue, His-426, known to be involved in 2-aminoethyl diphenylborinate-mediated TRPV3 activation, is critical for sensing intracellular proton levels. Taken together, our findings suggest that intracellular protons can strongly activate TRPV3, and TRPV3-mediated proton sensing and cell death in keratinocytes may serve as a molecular basis for the cosmetic use of AHAs and their therapeutic potential in acidic pH-related skin disorders.     

Studies on the Chemical Components of the Tacca chanteraeri André

A steroidal saponin has been isolated from the roots of Taccachanteraeri Andre', a folk medicine in Yunnan, which identified as diosgenin 3β-O-α-L-rhamnopyranosyl-(1→2)- O-α-L-rhamnopyranosyl-( 1 → 3 )-O-β-D-glucopyranoside ( 1 ) with stigmasterol (2) and daucosterin (3). Our studies support I. H. Burkill and A. Takhtajan's idea according to which Taccaceae would be the closest to Dioscoreaceae and be included in Liliales.     

Study on the Interaction between the Inclusion Complex of Hematoxylin with β-Cyclodextrin and DNA

Ultraviolet-visible (UV-vis) spectra, fluorescence spectra, electrochemistry, and the thermodynamic method were used to discuss the interaction mode between the inclusion complex of hematoxylin with β-cyclodextrin and herring sperm DNA. On the condition of physiological pH, the result showed that hematoxylin and β-cyclodextrin formed an inclusion complex with binding ratio n_hematoxylin:n_{β-cyclodextrin} = 1:1. The interaction mode between β-cyclodextrin-hematoxylin and DNA was a mixed binding, which contained intercalation and electrostatic mode. The binding ratio between β-cyclodextrin-hematoxylin and DNA was n_{β-cyclodextrin -hematoxylin}:n_DNA = 2:1, binding constant was K^? _298.15K = 5.29 × 10⁴ L·mol^?1, and entropy worked as driven force in this action.     

Interaction of α-Lipoic Acid with the Human Na+/Multivitamin Transporter (hSMVT)

The human Na⁺/multivitamin transporter (hSMVT) has been suggested to transport α-lipoic acid (LA), a potent antioxidant and anti-inflammatory agent used in therapeutic applications, e.g. in the treatment of diabetic neuropathy and Alzheimer disease. However, the molecular basis of the cellular delivery of LA and in particular the stereospecificity of the transport process are not well understood. Here, we expressed recombinant hSMVT in Pichia pastoris and used affinity chromatography to purify the detergent-solubilized protein followed by reconstitution of hSMVT in lipid bilayers. Using a combined approach encompassing radiolabeled LA transport and equilibrium binding studies in conjunction with the stabilized R-(+)- and S-(−)-enantiomers and the R,S-(+/−) racemic mixture of LA or lipoamide, we identified the biologically active form of LA, R-LA, to be the physiological substrate of hSMVT. Interaction of R-LA with hSMVT is strictly dependent on Na⁺. Under equilibrium conditions, hSMVT can simultaneously bind ∼2 molecules of R-LA in a biphasic binding isotherm with dissociation constants (K_d) of 0.9 and 7.4 μm. Transport of R-LA in the oocyte and reconstituted system is exclusively dependent on Na⁺ and exhibits an affinity of ∼3 μm. Measuring transport with known amounts of protein in proteoliposomes containing hSMVT in outside-out orientation yielded a catalytic turnover number (k_cat) of about 1 s⁻¹, a value that is well in agreement with other Na⁺-coupled transporters. Our data suggest that hSMVT-mediated transport is highly specific for R-LA at our tested concentration range, a finding with wide ramifications for the use of LA in therapeutic applications.     

Interaction of the β-Transglycosylase of Trichoderma longibrachiatum with Cellulose

The effects of cellulose on the production and stimulation of β-transglycosylase were studied. The β-transglycosylase of Trichoderma longibrachiatum was produced specifically in the presence of cellulose in Czapeck-Dox medium containing sucrose as a sole carbon source. The enzyme activity was stimulated by the addition of cellulose in the reaction mixture, where the transfer reaction product (a water-insoluble glucan) was apparently synthesized on the surface of the added cellulose fibers.

The hyphal wall fraction of the fungus had the same stimulatory effect on β-transglycosylase as the cellulose fibers. A cellulose-like material in this fraction was found by partial acid hydrolysis and gas chromatography. Cellotriose was the smallest substrate effective for the synthesis of a water-insoluble glucan in the presence of cellulose by the β-transglycosylase, though a significant amount of glucan could not be synthesized without the addition of cellulose.     

Expression of α-taxilin in the murine gastrointestinal tract: potential implication in cell proliferation

α-Taxilin, a binding partner of the syntaxin family, is a candidate tumor marker. To gain insight into the physiological role of α-taxilin in normal tissues, we examined α-taxilin expression by Western blot and performed immunochemical analysis in the murine gastrointestinal tract where cell renewal vigorously occurs. α-Taxilin was expressed in the majority of the gastrointestinal tract and was prominently expressed in epithelial cells positive for Ki-67, a marker of actively proliferating cells. In the small intestine, α-taxilin was expressed in transient-amplifying cells and crypt base columnar cells intercalated among Paneth cells. In the corpus and antrum of the stomach, α-taxilin was expressed in cells localized in the lower pit and at the gland, respectively, but not in parietal or zymogenic cells. During development of the small intestine, α-taxilin was expressed in Ki-67-positive regions. Inhibition of cell proliferation by suppression of the Notch cascade using a γ-secretase inhibitor led to a decrease in α-taxilin- and Ki-67-positive cells in the stomach. These results suggest that expression of α-taxilin is regulated in parallel with cell proliferation in the murine gastrointestinal tract.     

Interaction of newly synthesized α-crystallin with isolated lens plasma membranes

Translation of lens polyribosomes in a reticulocyte cell-free system results mainly in the synthesis of the water-soluble crystallins. After incubation of the translation products with isolated lens fiber plasma membranes, the newly synthesized α-crystallin interacts with this fraction and becomes water-insoluble. Urea extraction of the reisolated plasma membranes shows that part of the polymeric α-crystallin, in particular the αA chains, becomes urea-insoluble. When the membranes were isolated under conditions that stabilize complex formation with the cytoskeleton, only αA₂ seems to interact with this complex. In contrast, interaction with β- and γ-crystallin could not be observed.     

Interaction of α-tocopherol quinone, α-tocopherol and other prenyllipids with photosystem II

We have found that plastoquinone-A (PQ-A) and α-tocopherol (α-Toc) increased the reduction level of the high-potential form of cytochrome b-559 (cyt. b-559 HP) and α-tocopherol quinone (α-TQ) decreased the level of this cytochrome form in Scenedesmus obliquus wild-type, while the investigated prenyllipids were not active in the restoration of the cyt. b-559 HP form in Scenedesmus PS28 mutant and Synechococcus 6301 (Anacystis nidulans) where the cyt. b-559 HP form is naturally not present. Among the tested prenyllipids, α-TQ quenched fluorescence in thylakoids of S. obliquus wild-type, the PS28 mutant and tobacco to the highest extent, while PQ-A was less effective in this respect. α-Tocopherol showed the opposite effect to α-TQ and it was rather small. The fluorescence quenching measurements of thylakoids in the presence of DCMU (3-(3,4-dichlorophenyl)-1,1-dimethylurea) showed that the α-Toc and FCCP (carbonylcyanide-p-trifluoromethoxy-phenyl-hydrazone) did not quench non-photochemically chlorophyll fluorescence while PQ-9 and α-TQ were effective fluorescence quenchers at higher concentrations (> 15 μM). However, at the lower α-TQ concentrations where its effective fluorescence quenching was found in DCMU-free samples, there was nearly no quenching effect by α-TQ observed in DCMU-treated thylakoids. This suggested a specific, not non-photochemical, DCMU sensitive, fluorescence quenching of photosystem II (PSII) at low α-TQ concentrations which is probably connected with the cyclic electron transport around PSII and might have a function of excess light energy dissipation. The effects of α-TQ on PSII resembled those of FCCP under many respects which might suggest similar mechanism of action of these compounds on PSII, i.e. the catalytic deprotonation and/or redox changes of some components of PSII such as the water splitting system, tyrosine D, Chl_z or cytochrome b-559.