Delivery of Nucleic Acids, Proteins, and Nanoparticles by Arginine-Rich Cell-Penetrating Peptides in Rotifers

Cell-penetrating peptides (CPPs) are a group of short, membrane-permeable cationic peptides that represent a nonviral technology for delivering nanomaterials and macromolecules into live cells. In this study, two arginine-rich CPPs, HR9 and IR9, were found to be capable of entering rotifers. CPPs were able to efficiently deliver noncovalently associated with cargoes, including plasmid DNAs, red fluorescent proteins (RFPs), and semiconductor quantum dots, into rotifers. The functional reporter gene assay demonstrated that HR9-delivered plasmid DNAs containing the enhanced green fluorescent protein and RFP coding sequences could be actively expressed in rotifers. The 1-(4,5-dimethylthiazol-2-yl)-3,5-diphenylformazan assay further confirmed that CPP-mediated cargo delivery was not toxic to rotifers. Thus, these two CPPs hold a great potential for the delivery of exogenous genes, proteins, and nanoparticles in rotifers.     

Formation of Disulfide Bridges Drives Oligomerization,Membrane Pore Formation,and Translocation of Fibroblast Growth Factor 2 to Cell Surfaces

Fibroblast growth factor 2 (FGF2) is a key signaling molecule in tumor-induced angiogenesis. FGF2 is secreted by an unconventional secretory mechanism that involves phosphatidylinositol 4,5-bisphosphate-dependent insertion of FGF2 oligomers into the plasma membrane. This process is regulated by Tec kinase-mediated tyrosine phosphorylation of FGF2. Molecular interactions driving FGF2 monomers into membrane-inserted FGF2 oligomers are unknown. Here we identify two surface cysteines that are critical for efficient unconventional secretion of FGF2. They represent unique features of FGF2 as they are absent from all signal-peptide-containing members of the FGF protein family. We show that phosphatidylinositol 4,5-bisphosphate-dependent FGF2 oligomerization concomitant with the generation of membrane pores depends on FGF2 surface cysteines as either chemical alkylation or substitution with alanines impairs these processes. We further demonstrate that the FGF2 variant forms lacking the two surface cysteines are not secreted from cells. These findings were corroborated by experiments redirecting a signal-peptide-containing FGF family member from the endoplasmic reticulum/Golgi-dependent secretory pathway into the unconventional secretory pathway of FGF2. Cis elements known to be required for unconventional secretion of FGF2, including the two surface cysteines, were transplanted into a variant form of FGF4 without signal peptide. The resulting FGF4/2 hybrid protein was secreted by unconventional means. We propose that the formation of disulfide bridges drives membrane insertion of FGF2 oligomers as intermediates in unconventional secretion of FGF2.     

Medin Oligomer Membrane Pore Formation: A Potential Mechanism of Vascular Dysfunction

Medin, a 50-amino-acid cleavage product of the milk fat globule-EGF factor 8 protein, is one of the most common forms of localized amyloid found in the vasculature of individuals older than 50 years. Medin induces endothelial dysfunction and vascular inflammation, yet despite its prevalence in the human aorta and multiple arterial beds, little is known about the nature of its pathology. Medin oligomers have been implicated in the pathology of aortic aneurysm, aortic dissection, and more recently, vascular dementia. Recent in vitro biomechanical measurements found increased oligomer levels in aneurysm patients with altered aortic wall integrity. Our results suggest an oligomer-mediated toxicity mechanism for medin pathology. Using lipid bilayer electrophysiology, we show that medin oligomers induce ionic membrane permeability by pore formation. Pore activity was primarily observed for preaggregated medin species from the growth-phase and rarely for lag-phase species. Atomic force microscopy (AFM) imaging of medin aggregates at different stages of aggregation revealed the gradual formation of flat domains resembling the morphology of supported lipid bilayers. Transmission electron microscopy images showed the coexistence of compact oligomers, largely consistent with the AFM data, and larger protofibrillar structures. Circular dichroism spectroscopy revealed the presence of largely disordered species and suggested the presence of β-sheets. This observation and the significantly lower thioflavin T fluorescence emitted by medin aggregates compared to amyloid-β fibrils, along with the absence of amyloid fibers in the AFM and transmission electron microscopy images, suggest that medin aggregation into pores follows a nonamyloidogenic pathway. In silico modeling by molecular dynamics simulations provides atomic-level structural detail of medin pores with the CNpNC barrel topology and diameters comparable to values estimated from experimental pore conductances.     

Mimicry of Dopamine 1 Receptor Signaling with Cell-Penetrating Peptides

International Journal of Peptide Research and Therapeutics - In this study, through the use of protein mimicry, a peptide was developed to activate the dopamine 1 receptor signaling pathway from...     

细胞渗透肽的研究近况

细胞渗透肽是一类能携带大分子物质进入细胞的短肽,其跨膜能力不依赖经典的胞吞作用,被认为是一种理想的运载工具,在将蛋白质和其他分子导入活细胞的研究中有着广泛的应用前景.该文着重介绍细胞渗透肽的跨膜转运机制及其应用等.     

The Energetics of Membrane Fusion from Binding,through Hemifusion,Pore Formation,and Pore Enlargement

The main steps of viral membrane fusion are local membrane approach, hemifusion, pore formation, and pore enlargement. Experiments and theoretical analyses have helped determine the relative energies required for each step. Key protein structures and conformational changes of the fusion process have been identified. The physical deformations of monolayer bending and lipid tilt have been applied to the steps of membrane fusion. Experiment and theory converge to strongly indicate that, contrary to former conceptions, the fusion process is progressively more energetically difficult: hemifusion has a relatively low energy barrier, pore formation is more energy-consuming, and pore enlargement is the most difficult to achieve.This revised version was published online in August 2005 with a corrected cover date.     

Folding and Self-Assembly of the TatA Translocation Pore Based on a Charge Zipper Mechanism

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Highlights? Charge zippers as a new concept for folding and assembly of membrane proteins ? 3D structure of TatA pore explains translocation of folded proteins across membrane ? Ladders of salt bridges connect an amphiphilic palisade that can span the bilayer ? MD simulations and specific charge mutations support the charge zipper model     

Extreme Secretion: Protein Translocation Across the Archaeal Plasma Membrane

In all three domains of life, extracytoplasmic proteins must overcome the hurdle presented by hydrophobic, lipid-based membranes. While numerous aspects of the protein translocation process have been well studied in bacteria and eukarya, little is known about how proteins cross the membranes of archaea. Analysis to date suggests that archael protein translocation is a mosaic of bacterial, eukaryal, and archaeal features, as indeed is much of archaeal biology. Archaea encode homologues of selected elements of the bacterial and eukaryal translocation machines, yet lack other important components of these two systems. Other aspects of the archaeal translocation process appear specific to this domain, possibly related to the extreme environmental conditions in which archsea thrive. In the following, current understanding of archaeal protein translocation is reviewed, as is recent progress in reconstitution of the archaeal translocation process in vitro.     

穿膜肽介导的新型基因转运载体的功能研究

目的：借助穿膜肽TAT高效跨膜的特性和LacI前头肽突变体（LacI HPM）高亲和力结合DNA的特性,建立-种安全高效、无基因插入片段大小限制的基因转导系统。方法：在TAT-LacI HPM片段C端和N端分别添加GST标签,构建pET-28a（＋）-TAT-LacI HPM-GST和pGEX-GST-TAT-LacI HPM重组表达载体,可溶性表达TAT-LacI HPM-GST及GST-TAT-LacI HPM融合蛋白并纯化,获得TAT-LacI HPM二聚体,免疫荧光检测TAT-LacI HPM融合蛋白穿过HeLa细胞膜的情况,观察EGFP的表达,用免疫印迹检测TAT-LacI HPM融合蛋白介导质粒DNA进入细胞的能力。结果：表达、纯化并获得二聚体融合蛋白,体内实验表明其具有跨膜能力,能介导带有LacI结合序列的DNA质粒进入细胞,并在转染细胞里检测到了目的蛋白。结论：初步证实TAT-LacI HPM融合蛋白作为-种新型通用性非病毒DNA转运载体的可行性,为评价这种新型DNA疫苗载体在提高免疫效果方面的可行性奠定了前期实验基础。     

Thermosensitive Nanoparticles with pH-Triggered Degradation and Release of Anti-inflammatory Cell-Penetrating Peptides

Poly(N-isopropylacrylamide-2-acrylamido-2-methyl-1-propanesulfonate) [poly(NIPAm-AMPS)] nanoparticles can be cross-linked with hydrolytically degradable N,O-dimethacryloyl hydroxylamine (DMHA) in order to yield a pH-sensitive drug delivery system that slowly erodes above pH 5.0. Varying the composition of degradable DMHA and nondegradable MBA cross-linking allows for engineered variation of particle size and degradation kinetics. Utilizing sulfated comonomer AMPS provides for increased passive loading of anti-inflammatory mitogen-activated protein kinase-activated protein kinase 2 (MK2)-inhibiting cell-penetrating peptide KAFAKLAARLYRKALARQLGVAA (KAFAK) between 24.3% and 29.2% (w/w) for nanoparticles with 5 mol % cross-linker. Nanoparticles were shown to be nontoxic in vitro and were effective at delivering a therapeutically active dose of KAFAK to THP1 human monocytes to suppress tumor necrosis factor α (TNF-α) expression during lipopolysaccharide (LPS)-induced inflammation. This thermosensitive nanoparticle system is an excellent platform for passive diffusive loading in deionized water and release in physiologically relevant ionic strength media of environmentally sensitive peptide therapeutics.     

Apically Sorted P2X7 Receptors Mediate Purinergic-Induced Pore Formation Preferentially in Apical Domains of the Plasma Membrane

Treatment of human epithelial cervical cells CaSki attached on filters with the P2X7-receptor (P2X7-R) agonist BzATP induced acute transient influx of calcium, most likely the result of P2X7-R channel activation, followed by slower sustained calcium influx. In cultures incubated in the presence of ethidium bromide (EB), BzATP induced slow and sustained influx of the dye with a time-course similar to the late slow calcium influx, suggesting P2X7-R pore formation. The acute and late calcium effects of BzATP were greater if the agonist was added to the luminal solution, facing the apical membrane of the cells. The EB effect of BzATP initially occurred in the apical membrane, while effects in the basolateral membrane were delayed and smaller. These results suggest that in polarized epithelial cells under steady-state conditions the P2X7-R is located in the apical membrane, and activation of the receptor induces formation of P2X7-R pores preferentially in the apical membrane.     

ATP11C Facilitates Phospholipid Translocation across the Plasma Membrane of All Leukocytes

Organization of the plasma membrane into specialized substructures in different blood lineages facilitates important biological functions including proper localization of receptors at the plasma membrane as well as the initiation of crucial intracellular signaling cascades. The eukaryotic plasma membrane is a lipid bilayer that consists of asymmetrically distributed phospholipids. This asymmetry is actively maintained by membrane-embedded lipid transporters, but there is only limited data available about the molecular identity of the predominantly active transporters and their substrate specificity in different leukocyte subsets. We demonstrate here that the P4-type ATPase ATP11C mediates significant flippase activity in all murine leukocyte subsets. Loss of ATP11C resulted in a defective internalization of phosphatidylserine (PS) and phosphatidylethanolamine (PE) in comparison to control cells. The diminished flippase activity caused increased PS exposure on 7-aminoactinomycin D⁻ (7-AAD⁻) viable pro-B cells freshly isolated from the bone marrow of ATP11C-deficient mice, which was corrected upon a 2-hour resting period in vitro. Despite the impaired flippase activity in all immune cell subsets, the only other blood cell type with an accumulation of PS on the surface were viable 7-AAD⁻ developing T cells but this did not result in any discernable effect on their development in the thymus. These findings show that all leukocyte lineages exhibit flippase activity, and identify ATP11C as an aminophospholipid translocase in immune cells.     

Quantitative Measurement of GLUT4 Translocation to the Plasma Membrane by Flow Cytometry

Glucose is the main source of energy for the body, requiring constant regulation of its blood concentration. Insulin release by the pancreas induces glucose uptake by insulin-sensitive tissues, most notably the brain, skeletal muscle, and adipocytes. Patients suffering from type-2 diabetes and/or obesity often develop insulin resistance and are unable to control their glucose homeostasis. New insights into the mechanisms of insulin resistance may provide new treatment strategies for type-2 diabetes.The GLUT family of glucose transporters consists of thirteen members distributed on different tissues throughout the body¹. Glucose transporter type 4 (GLUT4) is the major transporter that mediates glucose uptake by insulin sensitive tissues, such as the skeletal muscle. Upon binding of insulin to its receptor, vesicles containing GLUT4 translocate from the cytoplasm to the plasma membrane, inducing glucose uptake. Reduced GLUT4 translocation is one of the causes of insulin resistance in type-2 diabetes^2,3.The translocation of GLUT4 from the cytoplasm to the plasma membrane can be visualized by immunocytochemistry, using fluorophore-conjugated GLUT4-specific antibodies.Here, we describe a technique to quantify total amounts of GLUT4 translocation to the plasma membrane of cells during a chosen duration, using flow cytometry. This protocol is rapid (less than 4 hours, including incubation with insulin) and allows the analysis of as few as 3,000 cells or as many as 1 million cells per condition in a single experiment. It relies on anti-GLUT4 antibodies directed to an external epitope of the transporter that bind to it as soon as it is exposed to the extracellular medium after translocation to the plasma membrane.     

Critical Role of Lipid Scramblase TMEM16F in Phosphatidylserine Exposure and Repair of Plasma Membrane after Pore Formation

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Mechanism of Membrane Permeation Induced by Synthetic β-Hairpin Peptides

We have investigated the membrane destabilizing properties of synthetic amphiphilic cationic peptides, MAX1 and MAX35, which have the propensity to form β-hairpin structures under certain conditions, and a control non-β-hairpin-forming peptide MAX8V16E. All three peptides bind to liposomes containing a mixture of zwitterionic POPC and negatively charged POPS lipids as determined by Zeta potential measurements. Circular dichroism measurements indicated folding of MAX1 and MAX35 in the presence of the POPC/POPS liposomes, whereas no such folding was observed with MAX8V16E. There was no binding or folding of these peptides to liposomes containing only POPC. MAX1 and MAX35 induced release of contents from negatively charged liposomes, whereas MAX8V16E failed to promote solute release under identical conditions. Thus, MAX1 and MAX35 bind to, and fold at the surface of negatively charged liposomes adopting a lytic conformation. We ruled out leaky fusion as a mechanism of release by including 2 mol % PEG-PE in the liposomes, which inhibits aggregation/fusion but not folding of MAX or MAX-induced leakage. Using a concentration-dependent quenching probe (calcein), we determined that MAX-induced leakage of liposome contents was an all-or-none process. At MAX1 concentrations, which cause release of ∼50% of the liposomes that contain small (R_h <1.5 nm) markers, only ∼15% of those liposomes release a fluorescent dextran of 40 kDa. A multimeric model of the pore is presented based on these results. Atomistic molecular dynamics simulations show that barrels consisting of 10 β-hairpin MAX1 and MAX35 peptides are relatively more stable than MAX8V16E barrels in the bilayer, suggesting that barrels of this size are responsible for the peptides lytic action.     

膜穿透肽的应用与穿膜机制研究

膜穿透肽(membrane penetrating peptide,MPP)能引导大分子物质穿透细胞膜.应用MPP为载体,引导神经营养分子通透血脑屏障进入神经元,能有效治疗中枢神经系统疾病;在基因治疗方面, MPP引导干扰小RNA进行基因治疗,避免了使用病毒载体等一些传统基因治疗方法的毒副作用.穿膜机制研究证实 MPP通透细胞膜的过程分为三个阶段:与细胞表面结合;细胞巨胞饮摄取 MPP;MPP从胞饮体中逃逸入胞质,其中最后阶段是限速步骤.随着对多肽片段的深入研究和穿膜机制的逐渐明晰,MPP的应用将会更为深入和广泛.     

Mathematical Modeling of K-Ras Nanocluster Formation on the Plasma Membrane

K-Ras functions as a critical node in the mitogen-activated protein kinase (MAPK) pathway that regulates key cellular functions including proliferation, differentiation, and apoptosis. Following growth factor receptor activation K-Ras.GTP forms nanoclusters on the plasma membrane through interaction with the scaffold protein galectin-3. The generation of nanoclusters is essential for high fidelity signal transduction via the MAPK pathway. To explore the mechanisms underlying K-Ras.GTP nanocluster formation, we developed a mathematical model of K-Ras-galectin-3 interactions. We designed a computational method to calculate protein collision rates based on experimentally determined protein diffusion rates and diffusion mechanisms and used a genetic algorithm to search the values of key model parameters. The optimal estimated model parameters were validated using experimental data. The resulting model accurately replicates critical features of K-Ras nanoclustering, including a fixed ratio of clustered K-Ras.GTP to monomeric K-Ras.GTP that is independent of the concentration of K-Ras.GTP. The model reproduces experimental results showing that the cytosolic level of galectin-3 determines the magnitude of the K-Ras.GTP clustered fraction and illustrates that nanoclustering is regulated by key nonequilibrium processes. Our kinetic model identifies a potential biophysical mechanism for K-Ras nanoclustering and suggests general principles that may be relevant for other plasma-membrane-localized proteins.     

Alternative Mechanisms for the Interaction of the Cell-Penetrating Peptides Penetratin and the TAT Peptide with Lipid Bilayers

Cell-penetrating peptides (CPPs) have recently attracted much interest due to their apparent ability to penetrate cell membranes in an energy-independent manner. Here molecular-dynamics simulation techniques were used to study the interaction of two CPPs: penetratin and the TAT peptide with 1,2-Dipalmitoyl-sn-glycero-3-phosphocholine (DPPC) and 1,2-dioleoyl-sn-glycero-3-phosphocholine (DOPC) phospolipid bilayers shed light on alternative mechanisms by which these peptides might cross biological membranes. In contrast to previous simulation studies of charged peptides interacting with lipid bilayers, no spontaneous formation of transmembrane pores was observed. Instead, the simulations suggest that the peptides may enter the cell by micropinocytosis, whereby the peptides induce curvature in the membrane, ultimately leading to the formation of small vesicles within the cell that encapsulate the peptides. Specifically, multiple peptides were observed to induce large deformations in the lipid bilayer that persisted throughout the timescale of the simulations (hundreds of nanoseconds). Pore formation could be induced in simulations in which an external potential was used to pull a single penetratin or TAT peptide into the membrane. With the use of umbrella-sampling techniques, the free energy of inserting a single penetratin peptide into a DPPC bilayer was estimated to be ∼75 kJmol⁻¹, which suggests that the spontaneous penetration of single peptides would require a timescale of at least seconds to minutes. This work also illustrates the extent to which the results of such simulations can depend on the initial conditions, the extent of equilibration, the size of the system, and the conditions under which the simulations are performed. The implications of this with respect to the current systems and to simulations of membrane-peptide interactions in general are discussed.