UMLS:C0019693 - FACTA Search

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Query: UMLS:C0019693 (HIV)
170,526 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Apoptin has been described to induce apoptosis in various human cancer cell lines, but not in normal cells, thus making it an interesting candidate for the development of novel therapeutic strategies. Apoptin was generated and cloned into several mammalian expression vectors. Transfection or microinjection of apoptin cDNA resulted in its expression, initially in the cytoplasm with a filamentous pattern. Subsequently, apoptin entered the nucleus and efficiently induced apoptosis in several cancer cell lines. Nuclear localization was shown to be required for induction of apoptosis. Apoptin expression level was found to be an important determinant of the efficiency of induction of apoptosis. Surprisingly, expression of apoptin or GFP-apoptin cDNA induced apoptosis in some normal cells. When fused to the HIV-TAT protein transduction domain and delivered as a protein, TAT-apoptin was transduced efficiently (>90%) into normal and tumour cells. However, TAT-apoptin remained in the cytoplasm and did not kill normal 6689 and 1BR3 fibroblasts. In contrast TAT-apoptin migrated from the cytoplasm to the nucleus of Saos-2 and HSC-3 cancer cells resulting in apoptosis after 24 h. This study shows that apoptin is a powerful apoptosis-inducing protein with a potential for cancer therapy.
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PMID:TAT-apoptin is efficiently delivered and induces apoptosis in cancer cells. 1469 60

The positively charged protein transduction domain of the HIV-1 TAT protein (TAT-PTD; residues 47-57 of TAT) rapidly translocates across the plasma membrane of living cells. This property is exploited for the delivery of proteins, drugs, and genes into cells. The mechanism of this translocation is, however, not yet understood. Recent theories for translocation suggest binding of the protein transduction domain (PTD) to extracellular glycosaminoglycans as a possible mechanism. We have studied the binding equilibrium between TAT-PTD and three different glycosaminoglycans with high sensitivity isothermal titration calorimetry and provide the first quantitative thermodynamic description. The polysulfonated macromolecules were found to exhibit multiple identical binding sites for TAT-PTD with only small differences between the three species as far as the thermodynamic parameters are concerned. Heparan sulfate (HS, molecular weight, 14.2 +/- 2 kDa) has 6.3 +/- 1.0 independent binding sites for TAT-PTD which are characterized by a binding constant K0 = (6.0 +/- 0.6) x 10(5) M(-1) and a reaction enthalpy deltaHpep0 = -4.6 +/- 1.0 kcal/mol at 28 degrees C. The binding affinity, deltaGpep0, is determined to equal extent by enthalpic and entropic contributions. The HS-TAT-PTD complex formation entails a positive heat capacity change of deltaCp0 = +135 cal/mol peptide, which is characteristic of a charge neutralization reaction. This is in contrast to hydrophobic binding reactions which display a large negative heat capacity change. The stoichiometry of 6-7 TAT-PTD molecules per HS corresponds to an electric charge neutralization. Light scattering data demonstrate a maximum scattering intensity at this stoichiometric ratio, the intensity of which depends on the order of mixing of the two components. The data suggest cross-linking and/or aggregation of HS-TAT-PTD complexes. Two other glycosaminoglycans, namely heparin and chondroitin sulfate B, were also studied with isothermal titration calorimetry. The thermodynamic parameters are K0 = (6.0 +/- 0.8) x 10(5) M(-1) and kcal/mol for heparin and K0 = (2.5 +/- 0.5) x 10(5) M(-1) and kcal/mol for chondroitin sulfate B at 28 degrees C. The close thermodynamic similarity of the three binding molecules also implies a close structural relationship. The ubiquitous occurrence of glycosaminoglycans on the cell surface together with their tight and rapid interaction with the TAT protein transduction domain makes complex formation a strong candidate as the primary step of protein translocation.
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PMID:Interaction of the protein transduction domain of HIV-1 TAT with heparan sulfate: binding mechanism and thermodynamic parameters. 1469 67

We try to develop a method for delivering antibody from blood circulation through blood brain barrier to brain. In order to achieve this goal, antibody has to cross cellular membrane of brain capillary endothelial cells twice. As a first step of our study, we examined the ability for scFv antibody to cross cellular membrane of RBL-2H3 cells once and be delivered into the inside of the cultured cells with the help of TAT peptide. TAT peptide was originally found in Tat protein from the HIV-1 virus and known as one of protein transduction domains. First, oligonucleotide encoding TAT peptide was linked to 5' terminal of gene fragment of scFv antibody by PCR technology. TAT-linked scFv gene fragment was subcloned into pET-23b vector and successfully expressed in E. coli as inclusion body. After solubilization and purification, TAT-linked scFv recombinant protein was added to the culture of RBL-2H3 cells. TAT-linked scFv delivered into RBL-2H3 cells was detected by means of immunocytochemistry using fluorescence microscopy. TAT-linked scFv crossed cellular membrane more efficiently than scFv without TAT peptide.
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PMID:[Study on a method for delivering scFv recombinant antibody into cultured cells]. 1474 Apr 3

This review presents an overview of the highlights of major concepts involving the anatomical routes for the transport of macromolecules and the transmigration of cellular elements across the blood-brain barrier (BBB) during inflammation. The particular focus will include inflammatory leukocytes, neoplastic cells and pathogenic microorganisms including specific types of viruses, bacteria and yeasts. The experimental animal models presented here have been employed successfully by the authors in several independent experiments during the past twenty-five years for investigations of pathologic alterations of the BBB after a variety of experimentally induced injuries and inflammatory conditions in mammalian and non-mammalian animal species. The initial descriptions of endothelial cell (EC) vesicles or caveolae serving as mini-transporters of fluid substances essentially served as a springboard for many subsequent discoveries during the past half century related to mechanisms of uptake of materials into ECs and whether or not pinocytosis is related to the transport of these materials across EC barriers under normal physiologic conditions and after tissue injury. In the mid-1970's, the authors of this review independently applied morphologic techniques (transmission electron microscopy-TEM), in conjunction with the plant protein tracer horseradish peroxidase (HRP) to investigate macromolecular transport structures that increased after the brain and spinal cord had been subjected to a variety of injuries. Based on morphologic evidence from these studies of BBB injury, the authors elaborated a unique EC system of modified caveolae that purportedly fused together forming transendothelial cell channels, and later similar EC profiles defined as vesiculo-canalicular or vesiculo-tubular structures (VTS, Lossinsky, et al., 1999). These EC structures were observed in association with increased BBB permeability of tracers including exogenously injected HRP, normally excluded from the intercellular milieu of the CNS. Subsequent studies of non-BBB-type tumor ECs determined that the EC VTS and other vesicular structures were defined by others as vesiculo-vacuolar organelles (VVOs, Kohn et al., 1992; Dvorak et al., 1996). Collectively, these structures appear to represent a type of anatomical gateway to the CNS likely serving as conduits. However, these CNS conduits become patent only in damaged ECs for the passage of macromolecules, and purportedly for inflammatory and neoplastic cells as well (Lossinsky et al., 1999). In this review, we focus attention on the similarities and differences between caveolae, fused racemic vesicular bundles, endothelial tubules and channels (VTS and the VVOs) that are manifest in normal, non-BBB-type blood vessels, and in the BBB after injury. This review will present evidence that the previous studies by the authors and other researchers established a framework for subsequent transmission (TEM), scanning (SEM) and high-voltage electron microscopic (HVEM) investigations concerning ultrastructural, ultracytochemical and immunoultra-structural alterations of the cerebral ECs and the mechanisms of the BBB transport that occurs after CNS injury. This review is not intended to include all of the many observations that might be included in a general historical overview of the development of the EC channel hypothesis, but it will discuss several of the major contributions. We have attempted to present some of the structural evidence that supports our early contributions and those made by other investigators by highlighting major features of these EC structures that are manifest in the injured BBB. We have focused on currently established concepts and principles related to mechanisms for the transendothelial transport of macromolecules after CNS injury and also offer a critical appraisal of some of this literature. Finally, we describe more recent concepts of transBBB avenues for viruses, including HIV-1, bacterial and mycotic organisms, as well as inflammatory and neoplastic cell adhesion and migration across the injured mammalian BBB. Data from studies of EC-related adhesion molecules, both from the literature and from the author's experimental results and observations made in other laboratories, as well as from personal communications underscore the importance of the adhesion molecules in facilitating the movement of leukocytic, neoplastic cell and human pathogens across the BBB during inflammatory and neoplastic events. Exciting, ongoing clinical trials are addressing possible therapeutic intervention in neuroinflammatory diseases, including multiple sclerosis, by blocking certain glycoprotein adhesion molecules before cells have the ability to adhere to the ECs and migrate across the BBB. Approaches whereby inflammation may be reduced or arrested using anti-adhesion molecules, by restructuring EC cytoskeletal, filamentous proteins, as well as remodeling cholesterol components of the modified VTS are discussed in the context of developing future therapies for BBB injury and inflammation. Understanding new concepts about the mechanism(s) by which inflammatory cells and a variety of pathogenic microorganisms are transported across the BBB can be expected to advance our understanding of fundamental disease processes. Taken together, the literature and the author's experiences during the past quarter of a century, will hopefully provide new clues related to the mechanisms of transendothelial cell adhesion and emigration across the injured BBB, issues that have been receiving considerable attention in the clinical arena. Learning how to chemically modulate the opening and/or closure of EC VTS and VVO structural pathways, or junctional complexes prior to cellular or microorganism adhesion and breaching the BBB presents challenging new questions in modern medicine. Future studies will be critically important for the development of therapeutic intervention in several human afflictions including traumatic brain and spinal cord injuries, stroke, cancer, multiple sclerosis and conditions where the immune system may be compromised including HIV infection, infantile and adult meningitis.
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PMID:Structural pathways for macromolecular and cellular transport across the blood-brain barrier during inflammatory conditions. Review. 1502 15

A technology has recently been developed that allows for the rapid transduction of full-length functionally active proteins into intact tissue through intravenous injection and into cultured cells. This technology involves the fusion of an 11 amino acid sequence of the HIV TAT protein to the protein of interest. In the current investigation, we determined whether functionally active TAT fusion proteins could be transduced into intact corneas by topical application. TAT-beta-galactosidase was purified from bacterial cells and applied in serial dilutions (12.5-250 nm) to cultured epithelial cells for 5 or 15 min. In addition, enucleated globes and excised corneas with or without a central 3-mm epithelial debridement were incubated with TAT-beta-galactosidase for 1 or 2 hr. Excised corneas were allowed to heal in organ culture. Transduction of active beta-galactosidase was detected by incubating the cells or corneas with X-gal. TAT-beta-galactosidase was transduced into nearly all cultured cells in a concentration-dependent manner. When TAT-beta-galactosidase was topically applied to intact corneas, only the most superficial layer of epithelium was highly transduced. When the superficial layer was removed with nitrocellulose, two to four layers of cells were transduced. In corneas with a central debridement, epithelial cells at the edge of the debridement were transduced as well as the stromal cells subjacent to the debridement. Active beta-galactosidase was maintained at least 1 day in organ culture. No X-gal reaction was seen in either cells or corneas not incubated with TAT-beta-galactosidase. Functionally active proteins can be efficiently transduced into corneal epithelial and stromal cells using TAT fusion protein technology. The intact epithelium provides a barrier to penetration of TAT proteins. This barrier can be overcome by disrupting the epithelium. TAT-mediated protein transduction may be extremely useful in studies of corneal wound healing and homeostasis.
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PMID:Transduction of functionally active TAT fusion proteins into cornea. 1505 80

Protein transduction domains (PTDs) have been used increasingly to deliver biologically active agents to a variety of cell types in vitro and in vivo. To define the most effective PTDs for transducing hematopoietic cells, we have screened a panel of PTD peptides in human CD34(+) cells for delivery of a 60-kd marker protein and assessed its impact on phenotypic maintenence in vitro. Compared to the HIV-TAT peptide, most peptide complexes displayed high efficiency in transducing the CD34(+) cells, except for those based on shorter peptides (4R, 4K, and 5RQ). In particular, the arginine homopolymers including 8R, 10R, and 12R, were internalized by the cells to a greater extent than the other PTDs. Transduction was significantly potentiated by preincubation of cells with dextran sulfate. Importantly, colony forming ability and CD34(+) CD38(-) primitive phenotype were not significantly altered in the presence of these peptides during a short-term liquid culture. Together, these data suggest the potential usefulness of arginine homopolymers in hematopoietic stem and progenitor cell manipulations.
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PMID:Evaluation of peptide-mediated transduction in human CD34+ cells. 1505 66

A novel carrier system that originates from membrane shuttling proteins such as the Drosophila homeobox protein Antennapedia, the HIV-1 transcriptional factor TAT and VP22 from HSV-1 has advantages for targeted delivery compared with standard translocation techniques. This transport system is mediated by so-called cell-penetrating peptides, which consist of short peptide sequences that rapidly translocate large molecules into the cell interior in a seemingly energy- and receptor-independent manner. Cell-penetrating peptides have low toxicity and a high yield of delivery and in the future might become a widely used tool in the field of gene regulation.
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PMID:The use of cell-penetrating peptides as a tool for gene regulation. 1547 18

Gene silencing mediated by RNA interference (RNAi) was first discovered in Caenorhabditis elegans, and was subsequently recognized in various other organisms. In mammalian cells, RNAi can be induced by small interfering RNAs (siRNAs). In earlier studies, our group developed a vector-based system for expression of siRNA under control of a polymerase III promoter, the U6 promoter, which can induce RNAi in living cells. We here describe a system for controlling the U6 promoter-driven expression of siRNA using the Cre-loxP recombination system. We constructed a 'Cre-On' siRNA expression vector which could be switched on upon excision catalyzed by Cre recombinase, which was delivered to cells directly from the medium as a fusion protein. An examination of the effectiveness of RNAi against a reporter gene revealed that addition of TAT-NLS-Cre (where NLS is a nuclear localization signal and TAT is a peptide of 11 amino acids derived from HIV) to the medium resulted in plasmid recombination, generation of siRNA and suppression of reporter activity. This system should allow us to induce RNAi in a spatially, temporally, cell type-specifically or tissue-specifically controlled manner and potentiate the improved application of RNAi in both an experimental and a therapeutic context.
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PMID:Control of siRNA expression using the Cre-loxP recombination system. 1510 81

Apactin is an 80-kDa type I membrane glycoprotein derived from pro-Muclin, a precursor that also gives rise to the zymogen granule protein Muclin. Previous work showed that apactin is efficiently removed from the regulated secretory pathway and targeted to the actin-rich apical plasma membrane of the pancreatic acinar cell. The cytosolic tail (C-Tail) of apactin consists of 16 amino acids, has Thr casein kinase II and Ser protein kinase C phosphorylation sites, and a C-terminal PDZ-binding domain. Secretory stimulation of acinar cells causes a decrease in Thr phosphorylation and an increase in Ser phosphorylation of apactin. Fusion peptides of the C-Tail domain pulldown actin, ezrin, and EBP50/NHERF in a phosphorylation-dependent manner. HIV TAT-C-Tail fusion peptides were used as dominant negative constructs on living pancreatic cells to study effects on the actin cytoskeleton. During secretory stimulation, TAT-C-Tail-Thr/Asp phosphomimetic peptide caused an increase in actin-coated zymogen granules at the apical surface, while TAT-C-Tail-S/D phosphomimetic peptide caused a broadening of the actin cytoskeleton. These data indicate that stimulation-mediated Thr dephosphorylation allows decreased association of apactin with EBP50/NHERF and fosters actin remodeling to coat zymogen granules. Stimulation-mediated Ser phosphorylation increases apactin association with the actin cytoskeleton, maintaining tight bundling of actin microfilaments at the apical surface. Thus, apactin is involved in remodeling the apical cytoskeleton during regulated exocytosis in a manner controlled by phosphorylation of the apactin C-Tail.
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PMID:Apactin is involved in remodeling of the actin cytoskeleton during regulated exocytosis. 1514 79

To elucidate the role of enhanced phosphoinositide-3-kinase (PI3-kinase) activity in memory, a synthetic phosphopeptide (TAT-YPMDM) containing the p85 regulatory subunit receptor-binding motif (YXXM) coupled to the cell transduction domain of HIV-TAT protein was employed. This phosphopeptide bound the p85 subunit of PI3-kinase, and was internalized by both granule and pyramidal neurons when injected into the hippocampus. Increased lipid kinase activity and enhanced phosphorylation of the PI3-kinase substrates Akt (protein kinase B) and ribosomal S6 kinase were associated with TAT-YPMDM administration. Bilateral infusion of the phosphopeptide into the dorsal hippocampus after training improved performance in three hippocampus-dependent memory tasks: contextual fear conditioning, trace fear conditioning, and the Morris water maze. Both the biochemical and behavioral effects of the TAT-YPMDM phosphopeptide could be blocked by wortmannin. No effect was observed when a nonphosphorylated peptide (TAT-YMDM), or a second, unrelated phosphopeptide (TAT-YPLDL) was utilized. In addition, infusion of the TAT-YPMDM phosphopeptide did not interfere with memory acquisition or 4 hr memory. In addition, pretesting administration did not affect the ability to recall a previously established long-term memory. These findings suggest that stimulation of PI3-kinase activity by phosphorylated receptor fragments containing the YMDM motif augments long-term memory.
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PMID:Performance in long-term memory tasks is augmented by a phosphorylated growth factor receptor fragment. 1521 87

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