Tat 蛋白的PTD区段促进GFP蛋白进入骨髓瘤细胞SP2/0

随着生物工程技术的迅速发展 ,多肽与蛋白质类药物的增长速度相当可观 ,可是这些药物常因受到各种因素的影响而疗效偏低 ,其中生物膜的屏障作用是主要因素之一。近年来发现一种来源于人类免疫缺陷病毒ＨＩＶ 1Ｔａｔ(Ｔｒａｎｓ ａｃｔｉｖａ ｔｏｒ)蛋白的蛋白功能区 ,称之为ＰＴＤ区段 (Ｐｒｏｔｅｉｎｔｒａｎｓｄｕｃｔｉｏｎｄｏｍａｉｎ ,ＹＧＲＫＫＲＲＱＲＲＲ)的〔1 ,2〕,能够有效引导肽段或者蛋白质进入细胞 ,具有蛋白传送的功能〔3〕。 1988年Ｍａｕｒｉｃｅ和Ｐａｕｌ发现Ｔａｔ蛋白能够穿过细胞膜〔4〕 ;1994年Ｓｔｅｐｈｅｎ…     

Co-lyophilization of bovine serum albumin (BSA) with poly(ethylene glycol) improves efficiency of BSA encapsulation and stability in polyester microspheres by a solid-in-oil-in-oil technique

The effect of the co-lyophilization of bovine serum albumin (BSA) with poly(ethylene glycol) (PEG) on the BSA encapsulation efficiency and formation of soluble BSA aggregates upon solid-in-oil-in-oil (s/o/o) encapsulation in poly(lactic-co-glycolic) acid (PLGA) microspheres was investigated. Suspension of the lyophilized BSA-PEG formulations in methylene chloride produced small protein powder particles of less than 1 m diam. and this afforded high encapsulation efficiencies of typically 90% ameliorating one of the problems in s/o/o encapsulation. Formation of soluble BSA aggregates upon s/o/o encapsulation followed by 24 h in vitro release was between 5% and 22%, much lower than values of 59% reported for BSA without stabilizing excipients. Therefore, PEG also afforded BSA stabilization during s/o/o encapsulation. Sustained release occurred over ca. 2 months and was complete.     

融合蛋白TAT-RIG-I-GFP的原核表达及其跨膜递送

本研究旨在探讨融合蛋白TAT-RIG-I-GFP原核表达载体的构建并验证TAT在跨膜递送中的作用。首先设计了4对特异性引物,克隆了绿头鸭AnasplatyrhynchosRIG-I基因,构建了pET-TAT-RIG-I-GFP和pET-RIG-I-GFP原核表达载体;转化至感受态DE3细胞,经IPTG诱导表达,利用His60镍亲和层析柱纯化,进行SDS-PAGE;然后,将纯化后的上述两种表达蛋白分别孵育DF-1细胞;最后利用荧光显微镜观察是否在DF-1细胞产生相应的荧光。结果证实,携带有TAT的pET-TAT-RIG-I-GFP融合蛋白在DF-1细胞中显示出明显的绿色荧光;而不具有TAT的pET-RIG-I-GFP蛋白却不能显示绿色荧光。这表明携带TAT的融合蛋白已成功进入DF-1细胞,并在跨膜递送过程中发挥了关键作用。上述为进一步研制家禽的抗病毒药物奠定了基础。     

Yersinia enterocolitica can deliver Yop proteins into a wide range of cell types: development of a delivery system for heterologous proteins

Y. enterocolitica translocates virulence proteins, called Yop effectors, into the cytosol of eukaryotic cells. Here we investigated whether Y. enterocolitica could translocate Yops into a range of eukaryotic cells including neurons and insect cells. Y. enterocolitica translocated the hybrid reporter protein YopE-Cya into each of the eukaryotic cell types tested. In addition, Y. enterocolitica was cytotoxic for each of the adherent cell types. Thus we detected no limit to the range of eukaryotic cells into which Y. enterocolitica can translocate Yops. The Yop effectors YopE, YopH and YopT were each cytotoxic for the adherent cell types tested, showing that not only is Y. enterocolitica not selective in its translocation of particular Yop effectors into each cell type, but also that the action of these Yop effectors is not cell type specific. Invasin and/or YadA, two powerful adhesins were required for translocation of Yop into non-phagocytic cells but not for translocation into macrophages. To use the Yersinia translocation system for broad applications, a Y. enterocolitica translocation strain and vector for the delivery of heterologous proteins into eukaryotic cells was constructed. This strain + vector combination lacks the translocated Yop effectors and allows delivery into eukaryotic cells of heterologous proteins fused to the minimal N-terminal secretion/translocation signal of YopE. Using this strategy translocation of a YopE-Diphtheria toxin subunit A hybrid protein into several cell types has been shown.     

Sucrose-induced Autolysis and Development of Protoplast-like Cells of Clostridium saccharoperbutylacetonicum

A growing culture of Clostridium saccharoperbutylacetonicum partially lost its turbidity in the presence of 0.3 to 0.6 m sucrose without any extraneous supplements for cell wall degradation. The maximum effect was shown at 0.35 m of sucrose and the culture lost 40 to 50% of initial turbidity. The rate of lysis depended on the age of culture. The most rapid lysis occurred in the organisms of early exponential growing cultures, but no lysis was observed on those of late exponential and stationary phase cultures. The optimal pH was 5.5 to 6.0, and the optimal temperature 30 to 35°C. The sucrose-induced lysis was inhibited by bivalent cations (such as Ca²⁺, Mg²⁺), heavy metal cations (such as Cu²⁺, Pb²⁺), enzymic inhibitors (such as PCMB) and fixative agents (such as formalin, glutaraldehyde), while organisms whose growth had been inhibited by antibiotics (such as chloramphenicol, tetracycline) were also resistant to sucrose-induced lysis. The sucrose-induced lysis was accompanied by striking morphological conversion from original rod cells (3.0~6.0}0.4~0.6 μ) to spherical cells (1.0~ 1.2 μ diameter). The sucrose-induced lysis was also observed on the relative strains of C. saccharoperbutylacetonicum and C. sporogenes, but not observed on many other species of Clostridium and aerobic bacteria tested. It was suggested that sucrose-induced lysis was a kind of bacterial autolysis which was induced by sucrose treatment. The bacterial spheres developed during the lysis may be the protoplasts.     

Design and evaluation of succinylated soy protein tablets as delayed drug delivery systems

The impact of succinylation on soy proteins as excipients for delayed delivery of drugs in the gastrointestinal tract was studied. Succinylation decreased protein solubility and protein charge density at pH 1.2 and increased solubility and zeta potential at pH above 4.5. Tablet erosion and swelling were decreased at pH 1.2 and increased at pH 7.5. FTIR analysis indicated polypeptide chain unfolding as a result of succinylation. Tablets of protein succinylated 50% or 100% released less than 10% of loaded riboflavin or rifampicin in 2 h at gastric pH in the presence of pepsin but released these compounds rapidly at intestinal pH. Succinylated soy protein tablets were thus gastroresistant, suggesting their use as excipients for controlled release of medicinal or nutraceutical agents.     

Effect of redox-responsive DTSSP crosslinking on poly(l-lysine)-grafted-poly(ethylene glycol) nanoparticles for delivery of proteins

Therapeutic proteins are utilized in a variety of clinical applications, but side effects and rapid in vivo clearance still present hurdles. An approach that addresses both drawbacks is protein encapsulation within in a polymeric nanoparticle, which is effective but introduces the additional challenge of destabilizing the nanoparticle shell in clinically relevant locations. This study examined the effects of crosslinking self-assembled poly(l -lysine)-grafted-poly(ethylene glycol) nanoparticles with redox-responsive 3,3′-dithiobis(sulfosuccinimidyl propionate) (DTSSP) to achieve nanoparticle destabilization in a reductive environment. The polymer-protein nanoparticles (DTSSP NPs) were formed through electrostatic self-assembly and crosslinked with DTSSP, which contains a glutathione-reducible disulfide. As glutathione is upregulated in various cancers, DTSSP NPs could display destabilization within cancer cells. A library of DTSSP NPs was formed with varying copolymer to protein (C:P) and crosslinker to protein (X:P) mass ratios and characterized by size and encapsulation efficiency. DTSSP NPs with a 7:1 C:P ratio and 2:1 X:P ratio were further characterized by stability in the presence proteases and reducing agents. DTSSP NPs fully encapsulated the model protein and displayed 81% protein release when incubated with 5 mM dithiothreitol for 12 hr. This study contributes to understanding stimulus-responsive crosslinking of polymeric nanoparticles and could be foundational to clinical administration of therapeutic proteins.     

Non-classical export of an adenovirus structural protein

The icosahedral capsids of Adenoviruses (Ads) consist of the hexon and stabilizing proteins building the facettes, and of the vertex protein penton base (Pb) anchoring the protruding fibers. The fibers bind to the Coxsackie virus B Ad cell surface receptor (CAR) and Pb to integrins. Here we describe a novel property of the Ad2 Pb. Pb was found to leave the infected cell and, upon exit, it attached to the surrounding noninfected cells forming a radial gradient with highest Pb levels on cells adjacent to the infected cell. The producer cells remained intact until at least 30 h post infection. At this point, Pb was not recovered from the extracellular medium, suggesting that its cell–cell spread might not involve free Pb. When viral particles were released at late stages of infection, soluble Pb was found in the extracellular medium and it randomly bound to noninfected cells. Nonlytic export of Pb occurred upon transient transfection with plasmid DNA, but plasmid-encoded fiber was not exported, indicating that cell–cell spread of Pb is autonomous of infection. Pb export was not affected by Brefeldin A-induced disruption of the Golgi apparatus, suggesting that it occurred via a nonclassical mechanism. Interestingly, the coexpression of Pb and fiber leads to both Pb and fiber export, termed 'protein abduction'. We suggest that fiber abduction might support viral dissemination in infected tissues by interfering with tissue integrity .     

Adsorption of poly(ethylene glycol)-modified ribonuclease A to a poly(lactide-co-glycolide) surface

Protein adsorption is a source of variability in the release profiles of therapeutic proteins from biodegradable microspheres. We employ optical reflectometry and total internal reflection fluorescence to explore the extent and kinetics of ribonuclease A (RNase A) adsorption to spin-cast films of poly(lactide-co-glycolide) (PLG) and, in particular, to determine how covalent grafting of polyethylene glycol (PEG) to RNase A affects adsorption. Adsorption kinetics on PLG surfaces are surface-limited for RNase A but transport-limited for unconjugated PEG homopolymers and for PEG-modified RNase A, indicating that PEG anchors the conjugates to the surface during the transport-limited regime. PEG modification of RNase A decreases the total number of adsorbed molecules per unit area but increases the areal surface coverage because the grafted PEG chains exclude additional surface area. Total internal reflection fluorescence-based exchange measurements show that there is no exchange between adsorbed and solution-phase protein molecules. This indicates an unusually tenacious adsorption. Streaming current measurements indicate that the zeta potential of the PLG surface becomes increasingly negative as the film is exposed to water for several weeks, as expected. Aging of the PLG surface results in increased adsorption of unmodified RNase A but decreased adsorption of unconjugated PEG homopolymers and of PEG-RNase A conjugates, relative to the extent of adsorption on freshly prepared PLG surfaces. Adsorption results correlate well with an increase in the rate, total extent and preservation of bioactivity of RNase A released from PLG microspheres for the PEG-modified version of RNase A.     

TAT蛋白转导结构域介导融合蛋白在小鼠活体的跨膜递送作用

目的探讨跨膜递送短肽——TAT蛋白转导结构域(简称TAT)介导的与其融合的活性蛋白在活体的跨膜递送作用。方法以融合蛋白GST-TAT-GFP,GST-GFP-TAT和GST-GFP为研究模型蛋白,不经过蛋白质的变性处理、直接通过向小鼠腹腔注射和皮肤涂抹这两种含TAT的融合蛋白及作为对照的融合蛋白GST-GFP,一定时间作用后取体内器官和皮肤做冷冻切片,荧光显微镜检测这些融合蛋白的跨膜递送情况;并对分别融合在C端或者N端的TAT介导GFP在活体动物体内和皮肤的跨膜递送作用进行对比。结果腹腔注射实验结果表明,TAT可以介导不经过蛋白质的变性处理的融合蛋白GST-TAT-GFP和GST-GFP-TAT跨膜递送进入到小鼠的心脏、肝、肾、脾和肺,甚至脑组织;其中GST-GFP-TAT跨膜递送效率比GST-TAT-GFP更高。结构模拟分析提示GST-GFP-TAT与GST-TAT-GFP中的TAT的暴露情况不同可能是造成两种蛋白跨膜递送活性差异的重要因素。皮肤实验的结果则表明TAT不仅介导融合蛋白GST-TAT-GFP和GST-GFP-TAT进入小鼠表皮,而且使其进入小鼠皮肤的真皮层。结论 TAT可以跨膜递送不经过变性处理的融合蛋白进入小鼠皮肤和体内,递送效率可能与TAT的暴露程度相关;这些结果为在蛋白质疗法方面应用TAT提供了进一步的理论依据。     

Molecular mechanism of transdermal co-delivery of interferon-alpha protein with gold nanoparticle – a molecular dynamics study

The transdermal route provides numerous advantages over conventional drug delivery routes. However, passive delivery of large molecules such as proteins through the skin is challenging due to its barrier function. Therefore, to design a successful formulation, molecular interaction of these proteins with constituent molecules present in the skin responsible for its barrier function, is necessary. In this study, we have shown through extensive computer simulations that the therapeutic protein, interferon alpha (INF), can be co-delivered through the skin using the gold nanoparticle. We carried out both steered (umbrella sampling) and unrestrained coarse-grained molecular dynamics simulation to show the molecular mechanism of absorption/permeation of protein on/through skin layer in the absence/presence of gold nanoparticle. According to the steered simulations, when INF was taken alone, the free energy minimum was observed at the head group of the skin layer, whereas, when co-delivered with AuNP, it was observed in the interior of the bilayer. Unrestrained simulations have also shown that INF was adsorbed on the skin lipid bilayer head group, while in presence of AuNP, it first complexed with the AuNP and then breached the barrier. The MD simulations thus established the transdermal delivery as a possible pathway for delivery of INF protein.     

Preparation and characterization of poly(D,L-lactide-co-glycolide) microspheres for controlled release of human growth hormone

The purpose of this research was to assess the physicochemical properties of a controlled release formulation of recombinant human growth hormone (rHGH) encapsulated in poly(D,L-lactide-co-glycolide) (PLGA) composite microspheres. rHGH was loaded in poly(acryloyl hydroxyethyl) starch (acHES) microparticles, and then the protein-containing microparticles were encapsulated in the PLGA matrix by a solvent extraction/evaporation method. rHGH-loaded PLGA microspheres were also prepared using mannitol without the starch hydrogel microparticle microspheres for comparison. The detection of secondary structure changes in protein was investigated by using a Fourier Transfer Infrared (FTIR) technique. The composite microspheres were spherical in shape (44.6±2.47 μm), and the PLGA-mannitol microspheres were 39.7±2.50 μm. Drug-loading efficiency varied from 93.2% to 104%. The composite microspheres showed higher overall drug release than the PLGA/mannitol microspheres. FTIR analyses indicated good stability and structural integrity of HGH localized in the microspheres. The PLGA-acHES composite microsphere system could be useful for the controlled delivery of protein drugs.     

The development and application of protein-liposome conjugation techniques

Numerous techniques have been developed over the past 10 years for the conjugation of proteins to liposomes. Early procedures involved coupling with reagents such as glutaraldehyde or EDCI. Subsequently, more sophisticated approaches involving selective bifunctional coupling agents have been developed. These later procedures are also much more efficient for coupling in aqueous media. The techniques of coupling have become more rigorous because investigators have recognized the inherent problems of producing, purifying and characterizing protein conjugated liposomes.

Protein-liposome coupling techniques were developed mainly for targeted drug delivery. The attachment of specific antibodies to the surface of the liposomes makes them able to bind to cells and to subsequently be internalised by the cells. Protein conjugated liposomes have also been used for various immunochemical and diagnostic purposes. These include the binding of labelled liposomes to cells and the agglutination of cells or latex particles by protein conjugated liposomes.     

Water-based nanoparticulate polymeric system for protein delivery: permeability control and vaccine application

The idea of using polymeric nanoparticles as drug carriers is receiving an increasing amount of attention both in academia and industry, Nanoparticles have a number of potential applications in protein, drug and vaccine delivery, as well as gene therapy applications. In this article, we focus on this unique drug delivery technology as a method to control the release rate of substances, not only for protein delivery but also for delivering an experimental vaccine immunogen. Nanoparticles were assembled on the basis of ionic interaction between water-soluble polymers so that the resulting particles were stable in physiologic media. Among the typical polymers used to assemble nanoparticles, different polysaccharides, natural amines, and poly-amines were investigated. The entrapped substances tested included a protein and antigens. Polydextran aldehyde was incorporated into the particle core, to enable physiologic cross-linking as a method to control permeability. This resulted in long-term retention of substances that would otherwise rapidly leak out of the nanoparticles. Results of cross-linking experiments clearly demonstrated that the release rate could be substantially reduced, depending on the degree of cross-linking. For vaccine antigen delivery tests, we measured an antibody production after subcutaneous and oral administration. The data indicated that only the cross-linked antigen was immunogenic when the oral route of administration was used. The data presented in this article address primarily the utility of nanoparticulates for oral delivery of vaccine antigen.     

Production of a fusion protein consisting of the enterotoxigenic<Emphasis Type="Italic"> Escherichia coli</Emphasis> heat-labile toxin B subunit and a tuberculosis antigen in<Emphasis Type="Italic"> Arabidopsis thaliana</Emphasis>

Transgenic plants are potentially safe and inexpensive vehicles to produce and mucosally deliver protective antigens. However, the application of this technology is limited by the poor response of the immune system to non-particulate, subunit vaccines. Co-delivery of therapeutic proteins with carrier proteins could increase the effectiveness of the antigen. This paper reports the ability of transgenic Arabidopsis thaliana plants to produce a fusion protein consisting of the B subunit of the Escherichia coli heat-labile enterotoxin and a 6 kDa tuberculosis antigen, the early secretory antigenic target ESAT-6. Both components of the fusion protein were detected using GM1-ganglioside-dependent enzyme-linked immunosorbant assay. This suggested the fusion protein retained both its native antigenicity and the ability to form pentamers.Abbreviations ELISA Enzyme linked immunosorbant assay - ESAT-6 Early secretory antigenic target (6 kDa) - ETEC Enterotoxigenic Escherichia coli - LTB B subunit of E. coli heat-labile enterotoxin Communicated by W.A. Parrott     

Identification and characterization of a novel cell-penetrating peptide of 30Kc19 protein derived from Bombyx mori

Cell-penetrating peptides (CPPs) or protein transduction domains (PTDs) have attracted increasing attention due to their high potential to deliver various, otherwise impermeable, bioactive agents, such as drugs and proteins across cell membranes. A number of CPPs have been discovered since then. Recently, 30Kc19 protein has attracted attention because it was the first cell-penetrating protein that has been found in insect hemolymph. Here, we report a cell-penetrating peptide derived from 30Kc19 protein, VVNKLIRNNKMNC, which efficiently penetrates cells when supplemented to medium for mammalian cell culture. Moreover, like other CPPs, this “Pep-c19” also efficiently delivered cell-impermeable cargo proteins, such as green fluorescent protein (GFP) into cells. In addition to the in vitro system, Pep-c19 exhibited the cell-penetrating property in vivo. When Pep-c19 was intraperitoneally injected into mice, Pep-c19 successfully delivered cargo proteins into various organ tissues with higher efficiency than the 30Kc19 protein itself, and without toxicity. Our data demonstrates that Pep-c19 has a great potential as a cell-penetrating peptide that can be used as a therapeutic tool to efficiently deliver different cell-impermeable cargo molecules into the tissues of various organs.     

Targeted delivery of insulin-modified immunoliposomes in vivo

The purpose of this study was to investigate the effect of liposomes conjugated with insulin to the surface on circulation time, biodistribution, and antitumor activity after intravenous injection in tumor-bearing mice. Immunoliposomes were constructed with insulin, which was covalently linked to liposomes containing anticancer drugs. In order to investigate the targeting performance of insulin-modified immunoliposomes (SILs) in vivo, plasma pharmacokinetics, biodistribution, and antitumor activity were tested. In comparison with nontargeted liposomes (SLs), SILs were cleared faster from circulation as a result of greater liver and tumor uptake. In addition, SILs retarded the growth of the tumor effectively, compared with the ZTO injection or SL. This is the first time for selective in vivo targeting of tumor vessels using insulin-modified immunoliposomes. SILs are candidate drug-delivery systems for therapeutic anticancer approaches.     

Microencapsulation methods for delivery of protein drugs

Recent advances in recombinant DNA technology have resulted in development of many new protein drugs. Due to the unique properties of protein drugs, they have to be delivered by parenteral injection. Although delivery of protein drugs by other routes, such as pulmonary and nasal routes, has shown some promises, to date most protein drugs are administered by parenteral routs. For long-term delivery of protein drugs by parenteral administration, they have been developed, and the currently used microencapsulation methods are reviewed here. The microencapsulation methods have been divided based on the method used. They are: solvent evaporation/extraction; phase separation (coacervation); spray drying; ionotropic gelation/polyelectrolyte complexation; interfacial polymerization; and supercritical fluid precipitation. Each method is described for its applications, advantages, and limitations.     

Intracellular small interfering RNA delivery using genetically engineered double‐stranded RNA binding protein domain

Background

A variety of synthetic carriers, such as cationic polymers and lipids, have been used as nonviral carriers for small interfering RNA (siRNA) delivery. Although siRNA polyplexes and lipoplexes exhibited good gene silencing efficiencies, they often showed serious cytotoxicities, which are not useful for clinical applications. A double‐stranded RNA binding cellular protein with highly specific siRNA binding property and noncytotoxicity was used for siRNA delivery.

Methods

A double‐stranded RNA binding domain (dsRBD) of human double‐stranded RNA activated protein kinase R was genetically produced and utilized to complex siRNA for intracellular delivery. For characterization of the siRNA/dsRBD complexes, decomplexation assay and RNase protection assay were performed. Cytotoxicity and target gene inhibition ability were also examined using human carcinoma cell lines.

Results

The recombinantly produced polypeptide dsRBD exhibited its inherent binding activity for siRNA without sequence specificity, and the siRNA/dsRBD complexes protected siRNA from degradation by ribonucleases. Green fluorescent protein (GFP) siRNA/dsRBD complexes showed prominent down‐regulation of a target GFP gene, when an endosomal escape function was supplemented by addition of a fusogenic peptide, KALA, in the formulation.

Conclusions

The results suggest that dsRBD‐based protein carriers could be successfully applied for a wide range of therapeutic siRNAs for intracellular gene inhibition without showing any cytotoxicity. Copyright © 2009 John Wiley & Sons, Ltd.