利用TAT多肽增强腺病毒对细胞感染效率的研究

蛋白转导多肽本身或携带生物大分子能以一种不明机制的方式高效地穿过真核细胞质膜并且几乎没有组织选择性。这为生物药物研究、基因治疗等领域带来了新的希望。最近有研究表明:来源于HIV-1的TAT蛋白的蛋白转导结构域多肽可以显著地提高重组腺病毒感染细胞和实验动物的效率。在对。HeLa且和Vero-E62种具有不同病毒易感性的细胞进行重组腺病毒感染实验时发现TAT多肽可以明显地提高重组腺病毒对HeLa细胞的感染及在细胞中外源报道基因的表达,但是对Vero-E6细胞却没有效果,表明TAT多肽增强重组腺病毒的感染与靶细胞类型有关,而并不像转导现象那样没有组织差异。这为蛋白转导技术在病毒载体中的应用提供了参考,但其中涉及的蛋白转导的机制有待进一步实验研究。     

TAT蛋白转导域：蛋白质治疗的新曙光

TAT蛋白转导域是源自人类免疫缺陷病毒Tat蛋白的一段碱性氨基酸多肽,能够将与之共价连接的多肽、蛋白、核酸等生物大分子快速而高效地转导入细胞内部,在药物转运和疾病治疗等领域有着巨大的应用潜力.TAT蛋白转导域首先通过电荷相互作用吸附于细胞膜,然后通过脂筏介导的巨胞饮作用进入细胞.随着体外研究的不断成熟,应用TAT蛋白转导域治疗人类肿瘤、卒中、炎症等疾病的动物模型也获得了成功,TAT蛋白转导域进入临床指日可待.     

Delivery of Bcl-XL or its BH4 domain by protein transduction inhibits apoptosis in human islets

Viability of isolated islets is one of the main obstacles limiting islet transplantation success. It has been reported that overexpression of Bcl-2/Bcl-XL proteins enhances islet viability. To avoid potential complications associated with long-term expression of anti-apoptotic proteins, we investigated the possibility of delivering Bcl-XL or its anti-apoptotic domain BH4 to islets by protein transduction. Bcl-XL and BH4 molecules were fused to TAT/PTD, the 11-aa cell penetrating peptide from HIV-1 transactivating protein, generating TAT-Bcl-XL and TAT-BH4, respectively. Transduction efficiency was assessed by laser scanning confocal microscopy of live islets. Biological activity was tested as the ability to protect NIT-1 insulinoma cell line from death induced by staurosporine or serum deprivation. Spontaneous caspase activation in human islets and cytotoxicity caused by IL-1beta were significantly reduced in the presence of TAT-Bcl-XL and TAT-BH4. We conclude that both TAT proteins are biologically active after transduction and could be an asset in the improvement of islet viability.     

Efficiency of protein transduction is cell type-dependent and is enhanced by dextran sulfate

Protein transduction domains (PTDs), both naturally occurring and synthetic, have been increasingly utilized to deliver biologically active agents to a variety of cell types in vitro and in vivo. We report that in addition to previously characterized arginine-rich PTDs, including TAT, lysine homopolymers were able to mediate transduction of a wide variety of cell types, as measured by flow cytometric and enzymatic assays. The efficiency of PTD-mediated transduction was influenced by the cell type tested, although polylysine homopolymers demonstrate levels of internalization that consistently exceeded those of TAT and arginine homopolymers. Transduction of arginine/lysine-rich PTDs occurred at 4 degrees C and following depletion of cellular ATP pools, albeit generally at reduced levels. Although transduction was reduced in Chinese hamster ovary mutant lines deficient in either heparan sulfate or glycosaminoglycan synthesis, uptake was restored to wild-type levels by incubating target cells with dextran sulfate. The enhancement of transduction by dextran sulfate suggests that electrostatic interactions play an important first step in the process by which PTDs and their cargo traverse the plasma membrane.     

Revised Role of Glycosaminoglycans in TAT Protein Transduction Domain-mediated Cellular Transduction

Cellular uptake of the human immunodeficiency virus TAT protein transduction domain (PTD), or cell-penetrating peptide, has previously been surmised to occur in a manner dependent on the presence of heparan sulfate proteoglycans that are expressed ubiquitously on the cell surface. These acidic polysaccharides form a large pool of negative charge on the cell surface that TAT PTD binds avidly. Additionally, sulfated glycans have been proposed to aid in the interaction of TAT PTD and other arginine-rich PTDs with the cell membrane, perhaps aiding their translocation across the membrane. Surprisingly, however, TAT PTD-mediated induction of macropinocytosis and cellular transduction occurs in the absence of heparan sulfate and sialic acid. Using labeled TAT PTD peptides and fusion proteins, in addition to TAT PTD-Cre recombination-based phenotypic assays, we show that transduction occurs efficiently in mutant Chinese hamster ovary cell lines deficient in glycosaminoglycans and sialic acids. Similar results were obtained in cells where glycans were enzymatically removed. In contrast, enzymatic removal of proteins from the cell surface completely ablated TAT PTD-mediated transduction. Our findings support the hypothesis that acidic glycans form a pool of charge that TAT PTD binds on the cell surface, but this binding is independent of the PTD-mediated transduction mechanism and the induction of macropinocytotic uptake by TAT PTD.     

HIV-1 TAT蛋白转导肽的研究进展

TAT蛋白转导肽是人类免疫缺陷病毒1型(human immunodeficiency virus type 1, HIV-1)编码的一段富含碱性氨基酸、带正电荷的多肽,属于蛋白转导域家族的一员。长期研究发现其全长及11个碱性氨基酸富集区的核心肽段(YGRKKRRQRRR)不仅能够在包括蛋白质、多肽及核酸等多种外源生物大分子的跨膜转导过程中具有重要作用,而且能够携带这些外源生物大分子通过活体细胞的各种生物膜性结构(如细胞膜和血脑屏障等)并发挥生理功能,但其跨膜转导机制仍不明确。新近研究还发现TAT核心肽段在促进外源蛋白高效表达过程中也具有重要作用,能够显著增加外源蛋白高效、可溶性表达的水平,显示了TAT蛋白转导肽的新功能。以TAT蛋白转导肽跨膜转导作用的长期研究背景为基础,分别从TAT蛋白转导肽的结构特点、其跨膜转导作用的影响因素及其作用机制等方面进行了系统综述,进一步结合TAT蛋白转导肽的最新研究进展分别从药物研发、机制探索及新功能的开发等方面展望了后续研究方向与应用价值,不仅为深入阐述TAT蛋白转导肽的跨膜转导作用的功能意义提供了参考依据,而且为TAT蛋白转导肽在微生物工程及蛋白质工程等领域的潜在应用价值提供了重要参考信息。     

TAT-mediated PRDX6 protein transduction protects against eye lens epithelial cell death and delays lens opacity

A diminished level of endogenous antioxidant in cells/tissues is associated with reduced resistance to oxidative stress. Peroxiredoxin 6 (PRDX6), a protective molecule, regulates gene expression/function by controlling reactive oxygen species (ROS) levels. Using PRDX6 protein linked to TAT, the transduction domain from human immunodeficiency virus type 1 TAT protein, we demonstrated that PRDX6 was transduced into lens epithelial cells derived from rat or mouse lenses. The protein was biologically active, negatively regulating apoptosis and delaying progression of cataractogenesis by attenuating deleterious signaling. Lens epithelial cells from cataractous lenses bore elevated levels of ROS and were susceptible to oxidative stress. These cells harbored increased levels of active transforming growth factor (TGF)-beta 1 and of alpha-smooth muscle actin and beta ig-h3, markers for cataractogenesis. Importantly, cataractous lenses showed a 10-fold reduction in PRDX6 expression, whereas TGF-beta1 mRNA and protein levels were elevated. The changes were reversed, and cataractogenesis was delayed when PRDX6 was supplied. Results suggest that delivery of PRDX6 can postpone cataractogenesis, and this should be an effective approach to delaying cataracts and other degenerative diseases that are associated with increased ROS.     

Protein transduction as a strategy for evaluating important factors in mammalian sex determination and differentiation

Protein transduction is a powerful tool to deliver biologically active protein into mammalian cells and whole animals. Transduced proteins are folded properly and can mediate their respective functions in their hosts. To examine the feasibility of applying this strategy to study the molecular events of gonadogenesis, we have studied the kinetics of protein transduction and stability of transduced protein in in vitro mouse gonad culture systems using two reporter proteins, TAT-beta-gal and beta-gal fusion proteins with and without the TAT protein transduction domain (PTD) respectively. Our results indicate that the TAT-PTD was critical and essential for protein transduction to cultured fetal gonads. The TAT-beta-gal reporter entered the cells of the gonads and mesonephros efficiently for both sexes at E11.5 to E15.5 stages examined. The delivered protein persisted in the gonads for an extended period after an initial one-hour transduction. The distribution of the reporter was relatively even in gonads and mesonephros at E11.5 stage for both sexes and at later stages in female. The transduced protein was distributed heterogeneously in male gonads after seminiferous tubule differentiation in which the amount of reporter protein was higher outside than inside the tubules. Nevertheless, we surmise that such protein delivery technique should be useful in studies designed to evaluate the sex determining or differentiating functions of various new protein factors identified by advanced differential screening strategies.     

Cellular uptake of unconjugated TAT peptide involves clathrin-dependent endocytosis and heparan sulfate receptors

Delivery of macromolecules mediated by protein transduction domains (PTDs) attracts a lot of interest due to its therapeutic and biotechnological potential. A major reevaluation of the mechanism of PTD-mediated internalization and the role of endocytosis in this mechanism has been recently initiated. Here, we demonstrate that the entry of TAT peptide (one of the most widely used PTDs) into different primary cells is ATPand temperature-dependent, indicating the involvement of endocytosis. Specific inhibitors of clathrin-dependent endocytosis partially inhibit TAT peptide uptake, implicating this pathway in TAT peptide entry. In contrast, the caveolin-dependent pathway is not essential for the uptake of unconjugated TAT peptide as evidenced by the efficient internalization of TAT in the presence of the known inhibitors of raft/caveolin-dependent pathway and for cells lacking or deficient in caveolin-1 expression. Whereas a significant part of TAT peptide uptake involves heparan sulfate receptors, efficient internalization of peptide is observed even in their absence, indicating the involvement of other receptors. Our results suggest that unconjugated peptide might follow endocytic pathways different from those utilized by TAT peptide conjugated to different proteins.     

Excision of selectable genes from transgenic goat cells by a protein transducible TAT-Cre recombinase

The Cre/loxP site-specific recombination system is a widely used tool for genetic engineering of mammalian genomes. Recombination of loxP-modified alleles is often induced by introduction of foreign DNA vector expressing Cre into the cells. But the introduced DNA vector has the potential to integrate into the genome of the cells and continuous expression of Cre recombinase from the foreign vector has the potential to yield cytotoxicity and genotoxicity in various cells. In this study, we investigate the possibility of overcoming this limitation by using a cell-permeable TAT-Cre recombinase. We found that TAT-Cre treatment of transgenic goat fibroblast cells did not compromise the development competency of reconstructed embryos by using these TAT-Cre-treated cells as nuclear donor in nuclear transfer. Finally, we obtained two live cloned goats where a selectable gene cassette was removed. Our work not only provided an efficient protein transduction-based system for removing selectable genes from transgenic goats, but also presented strong evidence that no severe damage was made to the host cells during the process of protein transduction.     

TAT-凋亡素融合蛋白的表达及其抗肿瘤活性

凋亡素(apoptin)由鸡贫血病毒vp3基因编码,能特异地诱导肿瘤细胞凋亡而对正常细胞 没有毒性,为了获得可转导入细胞内部的凋亡素,将人工合成的编码TAT蛋白转导结构域的DNA片段与凋亡素编码基因克隆入质粒pET-28a内,构建出表达融合蛋白TAT-apoptin的原核表达载体pET-28a-TAT-apoptin.在大肠杆菌Rosetta（DE3）中表达融合蛋白,利用IDA -Ni2+ 亲和柱纯化,葡聚糖凝胶G 25除去尿素后得到可溶的变性蛋白.纯化后的TAT apoptin加入体外培养的人脐静脉内皮细胞(HUVECs)和人肺癌Anip973细胞,对照组加入TAT-麦芽糖结合蛋白（TAT-MBP）. 经免疫组化检测,转导1 h后TAT-MBP分布于以上两种细胞的胞浆和胞核,TAT-apoptin则主要分布于2种细胞的胞浆内,转导24 h后TAT-MBP的亚细胞定位没有变化,TAT-apoptin分别定位于HUVECs的胞浆和Anip973的胞核中.脱氧核糖核苷酸末端转移酶介导的缺口末端标记法（TUNEL）显示转导48 h后,TAT-MBP处理过的 HUVECs和Anip973细胞、TAT-apoptin处理过的HUVECs没有明显改变,而TAT-apoptin处理过的Anip973细胞大量凋亡.以上结果表明TAT apoptin融合蛋白在肿瘤治疗上有潜在的应用价值.     

TAT‐mediated intracellular protein delivery to primary brain cells is dependent on glycosaminoglycan expression

Although some studies have shown that the cell penetrating peptide (CPP) TAT can enter a variety of cell lines with high efficiency, others have observed little or no transduction in vivo or in vitro under conditions mimicking the in vivo environment. The mechanisms underlying TAT‐mediated transduction have been investigated in cell lines, but not in primary brain cells. In this study we demonstrate that transduction of a green fluorescent protein (GFP)‐TAT fusion protein is dependent on glycosaminoglycan (GAG) expression in both the PC12 cell line and primary astrocytes. GFP‐TAT transduced PC12 cells and did so with even higher efficiency following NGF differentiation. In cultures of primary brain cells, TAT significantly enhanced GFP delivery into astrocytes grown under different conditions: (1) monocultures grown in serum‐containing medium; (2) monocultures grown in serum‐free medium; (3) cocultures with neurons in serum‐free medium. The efficiency of GFP‐TAT transduction was significantly higher in the monocultures than in the cocultures. The GFP‐TAT construct did not significantly enter neurons. Experimental modulation of GAG content correlated with alterations in TAT transduction in PC12 cells and astrocyte monocultures grown in the presence of serum. In addition, this correlation was predictive of TAT‐mediated transduction in astrocyte monocultures grown in serum free medium and in coculture. We conclude that culture conditions affect cellular GAG expression, which in turn dictates TAT‐mediated transduction efficiency, extending previous results from cell lines to primary cells. These results highlight the cell‐type and phenotype‐dependence of TAT‐mediated transduction, and underscore the necessity of controlling the phenotype of the target cell in future protein engineering efforts aimed at creating more efficacious CPPs. Biotechnol. Bioeng. 2009; 104: 10–19 © 2009 Wiley Periodicals, Inc.     

Exploring refined conditions for reprogramming cells by recombinant Oct4 protein

The generation of human induced pluripotent stem (iPS) cells would represent an appealing option for the derivation of pluripotent patient-specific cells, as no embryos or oocytes are required. However, crucial safety issues have to be addressed in order to create human iPS cells that are clinically useful, as the classical iPS technique involves permanent genetic manipulation that may result in tumor formation. Various experimental strategies have been suggested to accomplish transgene-free derivation of iPS cells, including the use of non-integrating viruses, site specific recombinases to excise transgenes after reprogramming, or RNA transfection. Protein transduction, i.e. the direct delivery of biologically active proteins into cells, has been employed to generate iPS cells but has been found to have very low efficiency. In fact, success of protein transduction is limited by poor stability and solubility of recombinant factors, as well as their poor endosomal release. We recently reported the generation of cell-permeant versions of Oct4 and Sox2 and showed that both can be delivered intracellularly as biologically active proteins. Here we explore conditions for enhanced protein stabilization and delivery into somatic cells. Employing optimized conditions, we demonstrate that Oct4 protein delivery can substitute for Oct4 virus, yielding iPS derivation efficacy comparable to a four virus transduction protocol. The number of colonies is strictly dependent on the dose and duration of cell-permeant Oct4 exposure. We expect our transduction system to reach a thus far unattained level of control over reprogramming activity, turning it into a valuable tool for both the analysis of the reprogramming mechanism and the derivation of transgene-free iPS cells.     

Heme oxygenase-1 fused to a TAT peptide transduces and protects pancreatic beta-cells

Transplantation of islets is becoming an established method for treating type 1 diabetes. However, viability of islets is greatly affected by necrosis/apoptosis induced by oxidative stress and other insults during isolation and subsequent in vitro culture. Expression of cytoprotective proteins, such as heme oxygenase-1 (HO-1), reduces the deleterious effects of oxidative stress in transplantable islets. We have generated a fusion protein composed of HO-1 and TAT protein transduction domain (TAT/PTD), an 11-aa cell penetrating peptide from the human immunodeficiency virus TAT protein. Transduction of TAT/PTD-HO-1 to insulin-producing cells protects against TNF-alpha-mediated cytotoxicity. TAT/PTD-HO-1 transduction to islets does not impair islet physiology, as assessed by reversion of chemically induced diabetes in immunodeficient mice. Finally, we report that transduction of HO-1 fusion protein into islets improves islet viability in culture. This approach might have a positive impact on the availability of islets for transplantation.     

Short-hairpin RNAs delivered by lentiviral vector transduction trigger RIG-I-mediated IFN activation

Activation of the type I interferon (IFN) pathway by small interfering RNA (siRNA) is a major contributor to the off-target effects of RNA interference in mammalian cells. While IFN induction complicates gene function studies, immunostimulation by siRNAs may be beneficial in certain therapeutic settings. Various forms of siRNA, meeting different compositional and structural requirements, have been reported to trigger IFN activation. The consensus is that intracellularly expressed short-hairpin RNAs (shRNAs) are less prone to IFN activation because they are not detected by the cell-surface receptors. In particular, lentiviral vector-mediated transduction of shRNAs has been reported to avoid IFN response. Here we identify a shRNA that potently activates the IFN pathway in human cells in a sequence- and 5′-triphosphate-dependent manner. In addition to suppressing its intended mRNA target, expression of the shRNA results in dimerization of interferon regulatory factor-3, activation of IFN promoters and secretion of biologically active IFNs into the extracellular medium. Delivery by lentiviral vector transduction did not avoid IFN activation by this and another, unrelated shRNA. We also demonstrated that retinoic-acid-inducible gene I, and not melanoma differentiation associated gene 5 or toll-like receptor 3, is the cytoplasmic sensor for intracellularly expressed shRNAs that trigger IFN activation.