Similar mechanisms of fatty acid transfer from human anal rodent fatty acid-binding proteins to membranes: Liver,intestine, heart muscle,and adipose tissue FABPs

The mammalian fatty acid-binding proteins (FABPs) are thought to be important for the transport and metabolism of fatty acids in numerous cell types. The transfer of FA from different members of the FABP family to membranes has been shown to occur by two distinct mechanisms, an aqueous diffusion-based mechanism and a collisional mechanism, wherein the FABP interacts directly with membrane acceptors. Much of the work that underlies this concept comes from efforts using rodent FABPs. Given the increasing awareness of links between FABPs and several chronic diseases in humans, it was important to establish the mechanisms of FA transfer for human FABPs. In the present studies, we examined the rate and mechanism of fatty acid transfer from four pairs of human and rodent (rat or mouse, as specified) FABPs: hLFABP and rLFABP, hIFABP and rIFABP, hHFABP and rHFABP, and hAFABP and mAFABP. In the case of human IFABP, both the Ala⁵⁴ and Thr⁵⁴ forms were examined. The results show clearly that for all FABPs examined, the mechanisms of ligand transfer observed for rodent proteins hold true for their human counterparts. Moreover, it appears that the Ala to Thr substitution at residue 54 of the human IFABP does not alter the fundamental mechanism of ligand transfer to membranes, but nevertheless causes a consistent decrease in the rate of transfer.     

Similar structures but different mechanisms: Prediction of FABPs–membrane interaction by electrostatic calculation

The role of fatty acid binding proteins as intracellular fatty acid transporters may require their direct interaction with membranes. In this way different mechanisms have been previously characterized through experimental studies suggesting different models for FABPs–membrane association, although the process in which the molecule adsorbs to the membrane remains to be elucidated. To estimate the importance of the electrostatic energy in the FABP–membrane interaction, we computationally modeled the interaction of different FABPs with both anionic and neutral membranes. Free Electrostatic Energy of Binding (dE), was computed using Finite Difference Poisson Boltzmann Equation (FDPB) method as implemented in APBS (Adaptive Poisson Boltzmann Solver). Based on the computational analysis, it is found that recruitment to membranes is facilitated by non-specific electrostatic interactions. Also energetic analysis can quantitatively differentiate among the mechanisms of membrane association proposed and determinate the most energetically favorable configuration for the membrane-associated states of different FABPs. This type of calculations could provide a starting point for further computational or experimental analysis.     

Cytosolic fatty acid binding proteins catalyze two distinct steps in intracellular transport of their ligands

Cytosolic long-chain fatty acid binding proteins (FABPs) are found in tissues that metabolize fatty acids. Like most lipid binding proteins, their specific functions remain unclear. Two classes have been described. Membrane-active FABPs interact directly with membranes during exchange of fatty acids between the protein binding site and the membrane, while membrane-inactive FABPs bind only to fatty acids that are already in aqueous solution. Despite these binding proteins, most fatty acids in cell cytoplasm appear to be bound to membranes. This paper reviews data suggesting that FABPs catalyze transfer of fatty acids between intracellular membranes, often across considerable intracellular distances. This process occurs in three distinct steps: dissociation of the fatty acid from a donor membrane, diffusion of the fatty acid across the intervening water layer, and binding to an acceptor membrane. Membrane-active FABPs catalyze dissociation of the fatty acid from the donor membrane and binding to the acceptor membrane, while membrane-inactive FABPs catalyze diffusion of fatty acids across the aqueous cytosol. Thus, FABPs catalyze all three steps in intracellular transport. A simple quantitative model has been developed that predicts the rate of intracellular transport as a function of the concentration, affinity and diffusional mobility of the binding protein. Different FABPs may have evolved to match the specific transport requirements of the cell type within which they are found.     

Polytopic membrane protein folding and assembly in vitro and in vivo (Review)

The insertion and folding of proteins in biological membranes during protein synthesis in vivo is fundamental to membrane biogenesis. At present, however, certain molecular aspects of this process can only be understood by complementary studies in vitro. We bring together in vitro and in vivo results, highlighting how the studies inform each other and increase our knowledge of the folding and assembly of polytopic membrane proteins. A notable recent advance is the high-resolution crystal structure of the protein machinery responsible for membrane protein insertion into the endoplasmic reticulum. This provides an opportunity to combine in vitro and in vivo studies at a more sophisticated level and address mechanistic aspects of polytopic protein insertion and folding. Quality control is another important aspect of membrane biogenesis, and we give an overview of the current understanding of this process, focusing on cystic fibrosis as a well-studied paradigm. Mutations in the associated membrane protein, the cystic fibrosis transmembrane conductance regulator (CFTR), can cause the quality control mechanisms to prevent the mutant protein reaching its normal site of action, the cell surface. In vitro studies of CFTR shed light on the possible origins of other clinically relevant folding mutants and highlight the potential synergy between in vitro and in vivo approaches.     

Intracellular interaction between syntaxin and Munc 18-1 revealed by fluorescence resonance energy transfer

Neurosecretion is catalyzed by assembly of a soluble N-ethylmaleimide-sensitive fusion protein attachment protein receptor (SNARE)-complex composed of SNAP-25, synaptobrevin and syntaxin. Munc 18-1 is known to bind to syntaxin in vitro. This interaction prevents assembly of the SNARE-complex, but might also affect intracellular targeting of the proteins. We have fused syntaxin and Munc 18 to the yellow- (YFP) or cyan-fluorescence-protein (CFP) and expressed the constructs in CHO- and MDCK-cells. We have studied their localization with confocal microscopy and a possible protein-protein interaction with fluorescence-resonance energy transfer (FRET). YFP-syntaxin localizes to intracellular membranes. CFP-Munc 18 is present in the cytoplasm as expected for a protein lacking membrane targeting domains. However, Munc 18 is redirected to internal membranes when syntaxin is coexpressed, but only limited transport of the proteins to the plasma membrane was observed. An interaction between Munc 18 and syntaxin could be demonstrated by FRET using two methods, sensitized acceptor fluorescence and acceptor photobleaching. A mutation in syntaxin (L165A, E166A), which is known to inhibit binding to Munc 18 in vitro, prevents colocalization of the proteins and also the FRET signal. Thus, a protein-protein interaction between Munc 18 and syntaxin occurs on intracellular membranes, which is required but not sufficient for quantitative transport of both proteins to the plasma membrane.     

Molecular dynamics study of the membrane interaction of a membranotropic dengue virus C protein-derived peptide

Dengue virus C protein, essential in the dengue virus life cycle, possesses a segment, peptide PepC, known to bind membranes composed of negatively charged phospholipids. To characterize its interaction with the membrane, we have used the molecular dynamics HMMM membrane model system. This approach is capable of achieving a stable system and sampling the peptide/lipid interactions which determine the orientation and insertion of the peptide upon membrane binding. We have been able to demonstrate spontaneous binding of PepC to the 1,2-divaleryl-sn-glycero-3-phosphate/1,2-divaleryl-sn-glycero-3-phosphocholine membrane model system, whereas no binding was observed at all for the 1,2-divaleryl-sn-glycero-3-phosphocholine one. PepC, adopting an α-helix profile, did not insert into the membrane but did bind to its surface through a charge anchor formed by its three positively charged residues. PepC, maintaining its three-dimensional structure along the whole simulation, presented a nearly parallel orientation with respect to the membrane when bound to it. The positively charged amino acid residues Arg-2, Lys-6, and Arg-16 are mainly responsible for the peptide binding to the membrane stabilizing the structure of the bound peptide. The segment of dengue virus C protein where PepC resides is a fundamental protein–membrane interface which might control protein/membrane interaction, and its positive amino acids are responsible for membrane binding defining its specific location in the bound state. These data should help in our understanding of the molecular mechanism of DENV life cycle as well as making possible the future development of potent inhibitor molecules, which target dengue virus C protein structures involved in membrane binding.     

Probing the Interaction of Brain Fatty Acid Binding Protein (B-FABP) with Model Membranes

Brain fatty acid-binding protein (B-FABP) interacts with biological membranes and delivers polyunsaturated fatty acids (FAs) via a collisional mechanism. The binding of FAs in the protein and the interaction with membranes involve a motif called “portal region”, formed by two small α-helices, A1 and A2, connected by a loop. We used a combination of site-directed mutagenesis and electron spin resonance to probe the changes in the protein and in the membrane model induced by their interaction. Spin labeled B-FABP mutants and lipidic spin probes incorporated into a membrane model confirmed that B-FABP interacts with micelles through the portal region and led to structural changes in the protein as well in the micelles. These changes were greater in the presence of LPG when compared to the LPC models. ESR spectra of B-FABP labeled mutants showed the presence of two groups of residues that responded to the presence of micelles in opposite ways. In the presence of lysophospholipids, group I of residues, whose side chains point outwards from the contact region between the helices, had their mobility decreased in an environment of lower polarity when compared to the same residues in solution. The second group, composed by residues with side chains situated at the interface between the α-helices, experienced an increase in mobility in the presence of the model membranes. These modifications in the ESR spectra of B-FABP mutants are compatible with a less ordered structure of the portal region inner residues (group II) that is likely to facilitate the delivery of FAs to target membranes. On the other hand, residues in group I and micelle components have their mobilities decreased probably as a result of the formation of a collisional complex. Our results bring new insights for the understanding of the gating and delivery mechanisms of FABPs.     

Mistic's membrane association and its assistance in overexpression of a human GPCR are independent processes

The interaction of the Bacillus subtilis protein Mistic with the bacterial membrane and its role in promoting the overexpression of other membrane proteins are still matters of debate. In this study, we aimed to determine whether individual helical fragments of Mistic are sufficient for its interaction with membranes in vivo and in vitro. To this end, fragments encompassing each of Mistic's helical segments and combinations of them were produced as GFP‐fusions, and their cellular localization was studied in Escherichia coli. Furthermore, peptides corresponding to the four helical fragments were synthesized by solid‐phase peptide synthesis, and their ability to acquire secondary structure in a variety of lipids and detergents was studied by circular dichroism spectroscopy. Both types of experiments demonstrate that the third helical fragment of Mistic interacts only with LDAO micelles but does not partition into lipid bilayers. Interestingly, the other three helices interact with membranes in vivo and in vitro. Nevertheless, all of these short sequences can replace full‐length Mistic as N‐terminal fusions to achieve overexpression of a human G‐protein‐coupled receptor in E. coli, although with different effects on quantity and quality of the protein produced. A bioinformatic analysis of the Mistic family expanded the number of homologs from 4 to 20, including proteins outside the genus Bacillus. This information allowed us to discover a highly conserved Shine‐Dalgarno sequence in the operon mstX‐yugO that is important for downstream translation of the potassium ion channel yugO.     

Improved understanding of pathogenesis from protein interactions in Mycobacterium tuberculosis

Comprehensive mapping and analysis of protein–protein interactions provide not only systematic approaches for dissecting the infection and survival mechanisms of pathogens but also clues for discovering new antibacterial drug targets. Protein interaction data on Mycobacterium tuberculosis have rapidly accumulated over the past several years. This review summarizes the current progress of protein interaction studies on M. tuberculosis, the causative agent of tuberculosis. These efforts improve our knowledge on the stress response, signaling regulation, protein secretion and drug resistance of the bacteria. M. tuberculosis–host protein interaction studies, although still limited, have recently opened a new door for investigating the pathogenesis of the bacteria. Finally, this review discusses the importance of protein interaction data on identifying and screening new anti-tuberculosis targets and drugs, respectively.     

Fatty acid transfer from intestinal fatty acid binding protein to membranes: electrostatic and hydrophobic interactions

Intestinal fatty acid binding protein (IFABP) is thought to participate in the intracellular transport of fatty acids (FAs). Fatty acid transfer from IFABP to phospholipid membranes is proposed to occur during protein-membrane collisional interactions. In this study, we analyzed the participation of electrostatic and hydrophobic interactions in the collisional mechanism of FA transfer from IFABP to membranes. Using a fluorescence resonance energy transfer assay, we examined the rate and mechanism of transfer of anthroyloxy-fatty acid analogs a) from IFABP to phospholipid membranes of different composition; b) from chemically modified IFABPs, in which the acetylation of surface lysine residues eliminated positive surface charges; and c) as a function of ionic strength. The results show clearly that negative charges on the membrane surface and positive charges on the protein surface are important for establishing the "collisional complex", during which fatty acid transfer occurs. In addition, changes in the hydrophobicity of the protein surface, as well as the hydrophobic volume of the acceptor vesicles, also influenced the rate of fatty acid transfer. Thus, ionic interactions between IFABP and membranes appear to play a primary role in the process of fatty acid transfer to membranes, and hydrophobic interactions can also modulate the rates of ligand transfer.     

Interaction of a peptide corresponding to the loop domain of the S2 SARS-CoV virus protein with model membranes

The severe acute respiratory syndrome coronavirus (SARS-CoV) envelope spike (S) glycoprotein is responsible for the fusion between the membranes of the virus and the target cell. In the case of the S2 domain of protein S, it has been found a highly hydrophobic and interfacial domain flanked by the heptad repeat 1 and 2 regions; significantly, different peptides pertaining to this domain have shown a significant leakage effect and an important plaque formation inhibition, which, similarly to HIV-1 gp41, support the role of this region in the fusion process. Therefore, we have carried out a study of the binding and interaction with model membranes of a peptide corresponding to segment 1073–1095 of the SARS-CoV S glycoprotein, peptide SARS_L in the presence of different membrane model systems, as well as the structural changes taking place in both the lipid and the peptide induced by the binding of the peptide to the membrane. Our results show that SARS_L strongly partitions into phospholipid membranes and organizes differently in lipid environments, displaying membrane activity modulated by the lipid composition of the membrane. These data would support its role in SARS-CoV mediated membrane fusion and suggest that the region where this peptide resides could be involved in the merging of the viral and target cell membranes.     

Interaction between cucumber green mottle mosaic virus MP and CP promotes virus systemic infection

The movement protein (MP) and coat protein (CP) of tobamoviruses play critical roles in viral cell-to-cell and long-distance movement, respectively. Cucumber green mottle mosaic virus (CGMMV) is a member of the genus Tobamovirus. The functions of CGMMV MP and CP during viral infection remain largely unclear. Here, we show that CGMMV MP can interact with CP in vivo, and the amino acids at positions 79–128 in MP are vital for the MP–CP interaction. To confirm this finding, we mutated five conserved residues within the residue 79–128 region and six other conserved residues flanking this region, followed by in vivo interaction assays. The results showed that the conserved threonine residue at the position 107 in MP (MP^T107) is important for the MP–CP interaction. Substitution of T107 with alanine (MP^T107A) delayed CGMMV systemic infection in Nicotiana benthamiana plants, but increased CGMMV local accumulation. Substitutions of another 10 conserved residues, not responsible for the MP–CP interaction, with alanine inhibited or abolished CGMMV systemic infection, suggesting that these 10 conserved residues are possibly required for the MP movement function through a CP-independent manner. Moreover, two movement function-associated point mutants (MP^F17A and MP^D97A) failed to cause systemic infection in plants without impacting on the MP–CP interaction. Furthermore, we have found that co-expression of CGMMV MP and CP increased CP accumulation independent of the interaction. MP and CP interaction inhibits the salicylic acid-associated defence response at an early infection stage. Taken together, we propose that the suppression of host antiviral defence through the MP–CP interaction facilitates virus systemic infection.     

Lift and cut: Anti-host autophagy mechanism of Legionella pneumophila

RavZ, an effector protein of pathogenic Legionella pneumophila, inhibits host macroautophagy/autophagy by deconjugation of lipidated LC3 proteins from phosphatidylethanolamine (PE) on the autophagosome membrane. The mechanism for how RavZ specifically recognizes and deconjugates the lipidated LC3s is not clear. To understand the structure-function relationship of LC3-deconjugation by RavZ, we prepared semisynthetic LC3 proteins modified with different fragments of PE or 1-hexadecanol (C16). We find that RavZ activity is strictly dependent on the conjugated PE structure and RavZ extracts LC3–PE from the membrane before deconjugation. Structural and biophysical analysis of RavZ-LC3 interactions suggest that RavZ initially recognizes LC3–PE on the membrane via its N-terminal LC3-interacting region (LIR) motif. RavZ specifically targets to autophagosome membranes by interaction with phosphatidylinositol 3-phosphate (PtdIns3P) via its C-terminal domain and association with membranes via the hydrophobic α3 helix. The α3 helix is involved in extraction of the PE moiety and docking of the fatty acid chains into the lipid-binding site of RavZ, which is related in structure to that of the phospholipid transfer protein Sec14. The LIR interaction and lipid binding facilitate subsequent proteolytic cleavage of LC3–PE. The findings reveal a novel mode of host-pathogen interaction.     

Protein microarrays as a discovery tool for studying protein–protein interactions

Exploring the function of the genome and the encoded proteins has emerged as a new and exciting challenge in the postgenomic era. Novel technologies come into view that promise to be valuable for the investigation not only of single proteins, but of entire protein networks. Protein microarrays are the innovative assay platform for highly parallel in vitro studies of protein–protein interactions. Due to their flexibility and multiplexing capacity, protein microarrays benefit basic research, diagnosis and biomedicine. This review provides an overview on the basic principles of protein microarrays and their potential to multiplex protein–protein interaction studies.     

Dynamin-related Protein 1 Oligomerization in Solution Impairs Functional Interactions with Membrane-anchored Mitochondrial Fission Factor

Mitochondrial fission is a crucial cellular process mediated by the mechanoenzymatic GTPase, dynamin-related protein 1 (Drp1). During mitochondrial division, Drp1 is recruited from the cytosol to the outer mitochondrial membrane by one, or several, integral membrane proteins. One such Drp1 partner protein, mitochondrial fission factor (Mff), is essential for mitochondrial division, but its mechanism of action remains unexplored. Previous studies have been limited by a weak interaction between Drp1 and Mff in vitro. Through refined in vitro reconstitution approaches and multiple independent assays, we show that removal of the regulatory variable domain (VD) in Drp1 enhances formation of a functional Drp1-Mff copolymer. This protein assembly exhibits greatly stimulated cooperative GTPase activity in solution. Moreover, when Mff was anchored to a lipid template, to mimic a more physiologic environment, significant stimulation of GTPase activity was observed with both WT and ΔVD Drp1. Contrary to recent findings, we show that premature Drp1 self-assembly in solution impairs functional interactions with membrane-anchored Mff. Instead, dimeric Drp1 species are selectively recruited by Mff to initiate assembly of a functional fission complex. Correspondingly, we also found that the coiled-coil motif in Mff is not essential for Drp1 interactions, but rather serves to augment cooperative self-assembly of Drp1 proximal to the membrane. Taken together, our findings provide a mechanism wherein the multimeric states of both Mff and Drp1 regulate their collaborative interaction.     

Total synthesis of the natural,medium-length,peptaibol pentadecaibin and study of the chemical features responsible for its membrane activity

Peptaibols are naturally occurring, antimicrobial peptides endowed with well-defined helical conformations and resistance to proteolysis. Both features stem from the presence in their sequence of several, C^α-tetrasubstituted, α-aminoisobutyric acid (Aib) residues. Peptaibols interact with biological membranes, usually causing their leakage. All of the peptaibol–membrane interaction mechanisms proposed so far begin with peptide aggregation or accumulation. The long-length alamethicin, the most studied peptaibol, acts by forming pores in the membranes. Conversely, the carpet mechanism has been claimed for short-length peptaibols, such as trichogin. The mechanism of medium-length peptaibols is far less studied, and this is partly due to the difficulties of their synthesis. They are believed to perturb membrane permeability in different ways, depending on the membrane properties. The present work focuses on pentadecaibin, a recently discovered, medium-length peptaibol. In contrast to the majority of its family members, its sequence does not comprise hydroxyprolines or prolines, and its helix is not kinked. A reliable and effective synthesis procedure is described that allowed us to produce also two shorter analogs. By a combination of techniques, we were able to establish a 3D-structure–activity relationship. In particular, the membrane activity of pentadecaibin heavily depends on the presence of three consecutive Aib residues that are responsible for the clear, albeit modest, amphiphilic character of its helix. The shortest analog, devoid of two of these three Aib residues, preserves a well-defined helical conformation, but not its amphipathicity, and loses almost completely the ability to cause membrane leakage. We conclude that pentadecaibin amphiphilicity is probably needed for the peptide ability to perturb model membranes.     

IEX-1相互作用蛋白的筛选与鉴定

骨肉瘤即原发于骨的恶性肿瘤,易发生早期肺转移且预后差,恶性程度高.本研究小组前期研究发现,IEX-1在骨肉瘤中具有重要作用.为了阐明其作用机制,本研究运用酵母双杂交技术筛选其相互作用蛋白,共鉴定出12个IEX-1相互作用蛋白,包括生物氧化相关酶类、分子伴侣、信号转导相关蛋白等.并首次证实clusterin(CLU,又名载脂蛋白J)与IEX-1存在相互作用,两者在细胞中具有很好的共定位.采用RNAi干扰减低骨肉瘤细胞中内源性CLU表达水平,显著抑制了细胞增殖与细胞侵袭能力.为阐明IEX-1在骨肉瘤发生发展中的作用机制提供了重要的线索,为骨肉瘤的早期诊治及预后监测提供了新的靶点.     

Biolayer interferometry of lipid nanodisc‐reconstituted yeast vacuolar H+‐ATPase

Vacuolar H⁺‐ATPase (V‐ATPase) is a large, multisubunit membrane protein complex responsible for the acidification of subcellular compartments and the extracellular space. V‐ATPase activity is regulated by reversible disassembly, resulting in cytosolic V₁‐ATPase and membrane‐integral V₀ proton channel sectors. Reversible disassembly is accompanied by transient interaction with cellular factors and assembly chaperones. Quantifying protein‐protein interactions involving membrane proteins, however, is challenging. Here we present a novel method to determine kinetic constants of membrane protein–protein interactions using biolayer interferometry (BLI). Yeast vacuoles are solubilized, vacuolar proteins are reconstituted into lipid nanodiscs with native vacuolar lipids and biotinylated membrane scaffold protein (MSP) followed by affinity purification of nanodisc‐reconstituted V‐ATPase (V₁V₀ND). We show that V₁V₀ND can be immobilized on streptavidin‐coated BLI sensors to quantitate binding of a pathogen derived inhibitor and to measure the kinetics of nucleotide dependent enzyme dissociation.