Global ETD Search

1	Design, Syntheses and Biological Applications of Through-bond Energy Transfer Cassettes and Novel Non-covalently Cell Penetrating Peptides Han, Junyan 2009 August 1900 (has links) A xanthene-BODIPY cassette is used as a ratiometric intracellular pH reporter for imaging protein-dye conjugates in living cells. A model was hypothesized to explain the pH-dependent energy transfer efficiencies from the donor to the acceptor based on the electronic chemistry data. Sulfonation conditions were developed for BODIPY dyes to give water-soluble functionalized monosulfonation and disulfonation donors. A water-soluble TBET cassette, which has good photophysical properties, was synthesized using a bissulfonated BODIPY dye as the donor, and their applications for in vitro protein labeling is achieved. Chemoselective cross-coupling reactions were demonstrated for C-S bonds in the BODIPY dye, and similar reactions were applied to make the acceptor of the watersoluble cassette. Chemiluminescent energy transfer cassettes based on fluorescein and Nile Red were synthesized and their spectral properties were studied. Pep-1 (also known as Chariot), R8 (which is not often used as a non-covalent protein carrier), and a new synthesized compound, Azo-R8, was used for the study of non-covalent delivery of four different proteins into mammalian cells. Data from confocal spectroscopy revealed that all three carriers are effective for translocating protein cargos into live cells. At 37 dgrees C, import into endocytic compartments dominates, but at 4 degrees C weak, diffuse fluorescence is observed in the cytosol indicative of a favorable mode of action. energy transfer cell penetrating peptide pH probes
2	Conception et évaluation de nouveaux peptides internalisants / Design and evaluation of news cell-penetrating peptides Lecigne, David 04 January 2011 (has links) Le peptide Tat est un des "cell penetrating peptides" (CPP) les plus utilisés pour l'internalisation cellulaire de diverses molécules cargos. La molécule chimérique (Tat-cargo) induit une réponse biologique plus efficace comparée au cargo seul. Cependant, en marquant le peptide Tat à l'iode 125, il a été déterminé que seulement moins de 1 % de la quantité initiale de peptide est internalisé. Il y a donc une opportunité d'augmenter l'efficacité de cette internalisation. L'étape cruciale du processus d'internalisation est le passage transmembranaire. Cette thèse présente l'évaluation de l'impact d'un groupement hydrophobe intégré en différentes positions au peptide Tat, afin de favoriser son interaction avec la membrane. Un acide aminé modifié chimiquement comportant un groupement cholestéryle a été développé dans ce sens. Cet aminoacide peut être intégré en toute position du peptide Tat. Différentes positions au sein du peptide Tat ont été cholestérylées et l'effet sur le taux d'internalisation a été étudié par cytométrie en flux et par comptage suite au radiomarquage des peptides à l'iode 125.L'ajout de cholestérol en position centrale du peptide Tat induit une efficacité d'internalisation supérieure d'un facteur 30 alors qu'une augmentation moindre est observée suite à l'ajout du groupement hydrophobe en positions latérales, N- ou C-terminale. / The Tat peptide is one of the most used cell penetrating peptides for internalizing various cargo molecules into cells. The chimaeric molecule thus triggers an efficient cellular biological response when compared with the cargo molecule alone. However, following labeling of the Tat peptide with radiolabeled iodine, less than 1% of the external peptide was internalized. Therefore, there is an opportunity to improve the level of CPP internalization. The ultimate step is the crossing through the plasma membrane. This thesis presents an evaluation of the impact of a hydrophobic group incorporated at different positions to Tat peptide, to promote its interaction with the membrane.A chemically modified amino acid comprising a cholesteryl group was developed in this direction. This amino acid can be inserted at any position within the Tat peptide. Different positions within the Tat peptide were cholesterylated and the effect on the internalization rate of Tat CPP was investigated by flow cytometry and by counting following the radiolabeling of peptides with iodine 125.The addition of cholesterol in the central position of the peptide Tat induces internalization efficiency than a factor of 30 while a smaller increase was observed after the addition of hydrophobic group in lateral positions, N-or C-terminus. Cell-Penetrating Peptide Tat Cholestérol Hydrophobisation Cell-Penetrating Peptide Tat Cholesterol Hydrophobization
3	Cell-penetrating peptides in protein mimicry and oligonucleotide delivery : Applications and mechanisms Johansson, Henrik January 2008 (has links) The plasma membrane functions as a barrier, restricting entry of hydrophilic pharmaceutical agents. Cell-penetrating peptides (CPPs) are capable of transporting bioactive cargos into the cell and have consequently been extensively investigated for their mechanism of entry and capability to deliver various cargos spanning from peptides to plasmids. The main aim of this thesis was to investigate the mechanism and capability of some of these CPPs to deliver mainly oligonucleotides and peptides into the cell. Oligonucleotides in the form of ds DNA decoy for sequestering of transcription factors or PNAs for redirection of splicing. In addition, peptides derived from the interaction interface of a tumor suppressor protein were investigated for their potential to combine a biological effect with internalization. Peptides with or without any cargo were predominantly dependent on some form of endocytic mechanism for internalization, substantiated by using a functional assay, where all tested CPPs were associated with endocytosis for delivery of splice correcting PNAs. A new CPP, M918 proved most efficient in promoting splice correction and internalized mainly via macropinocytosis. In addition, TP10 efficiently delivered dsDNA decoy oligonucleotides for sequestering of the transcription factor Myc with a concomitant biological response, i.e. reduced proliferation. Finally, for the first time, to our knowledge, a novel pro-apoptotic peptide with cell-penetrating properties was designed from the tumor suppressor p14ARF, which decreased proliferation and induced apoptosis in cancer cell-lines, potentially mimicking the full-length protein. Altogether, this thesis highlights the functionality of CPPs and the possibility to develop new CPPs with improved or new properties, having the potential to advance delivery of therapeutic compounds. peptide oligonucleotide cell-penetrating peptide PNA splicing Neurochemistry Neurokemi
4	Rational modifications of cell-penetrating peptides for drug delivery : Applications in tumor targeting and oligonucleotide delivery Mäe, Maarja January 2009 (has links) High molecular weight biomolecules are becoming important in the development of new therapeutics. However, their size and nature creates a major limitation for their application – poor penetration through biological membranes. A new class of peptides, cell-penetrating peptides (CPPs), has shown the capability to transport various macromolecules inside the cells. However, there are at least two limiting factors for successful application of CPPs: the lack of cell-type specificity and restricted bioavailability resulting from endocytic uptake of CPPs and entrapment in endosomal compartments. This thesis aims at designing delivery vehicles for therapeutic substances. In papers I-III, the CPPs have been rationally modified in order to achieve in vivo selectivity towards cancer cells. The first two papers employ tumor homing peptides as targeting moieties coupled to the N-termini of CPPs. In the third paper, a CPP is C-terminally prolonged with a matrix metalloproteinase 2 (MMP-2) specific cleavage site followed by an inactivating amino acid sequence. In tissues overexpressing MMP-2, i. e. in proximity to cancer, the CPP is activated after proteolytic removal of the inactivating sequence, thus the cargo can be transported inside the cells. In paper IV, several CPPs have been N-terminally modified with a stearyl moiety and applied for the delivery of splice-correcting oligonucleotides. We show that stearyl-TP10 is as effective in oligonucleotide delivery as Lipofectamine™ 2000. Moreover, stearyl-TP10 has preserved efficacy in serum and is not toxic to cells. In conclusion, the rational modifications of CPPs greatly potentiate their application in cargo delivery both in vitro and in vivo. Cell-penetrating peptide oligonucleotide drug delivery tumor targeting Neurochemistry Neurokemi
5	Development of multifunctional siRNA delivery systems and their applications in modulating gene expression in a cardiac ischemia-reperfusion model Liu, Jie 08 June 2015 (has links) RNA interference (RNAi) is a conservative post-transcriptional gene silencing mechanism that can be mediated by small interfering RNAs (siRNAs). Given the effectiveness and specificity of RNAi, the administration of siRNA molecules is a promising approach to cure diseases caused by abnormal gene expression. However, as siRNA is susceptible to degradation by nucleases and it can hardly penetrate cell membranes due to its polyanionic nature, a successful translation of the RNAi mechanism for therapeutic purposes is contingent on the development of safe and efficient delivery systems. This dissertation described the development of novel siRNA delivery systems on the basis of polymeric and dendrimeric materials and also demonstrated the application of one optimized delivery system to deliver therapeutic siRNAs in a cardiovascular disease model in vivo. We studied a linear peptide polymer made from cell penetrating peptide monomers and investigated the contribution of the polymeric structure, degradability, and ligand conjugation to the siRNA loading capacity, biocompatibility, and transfection efficiency of polymeric materials. With the obtained knowledge and experience, we invented a neutral crosslinked delivery system aiming to solve the inherent drawbacks of traditional cationic delivery systems that are based on electrostatic interactions. The new concept utilized buffering amines to temporarily bind siRNA and a crosslinking reaction to immobilize the formed particles, and targeting ligands modified on the neutral dendrimer surface further enhanced the interactions between the delivery vehicles and target cells. The obtained delivery system allowed stability, safety, controllability, and targeting ability for siRNA delivery, and the method developed here could be transformed to other polymeric or dendrimeric cationic materials to make them safer and more efficient. To exploit the therapeutic potential of siRNA delivery, we developed a tadpole-shaped dendrimeric material to deliver siRNA against an Angiotensin II receptor in a rat ischemia-reperfusion model. Our results showed that the nonaarginine-conjugated tadpole dendrimer was capable of delivering siRNA effectively to cardiac cells both in vitro and in vivo, and the successful down-regulation of the Angiotensin II receptor preserved the cardiac functions and reduced the infarct size post-myocardial infarction. This dissertation paves a way for transforming multifunctional non-viral siRNA delivery systems into potent therapeutic strategies for the management of cardiovascular diseases. Delivery system siRNA Cell penetrating peptide Dendrimer Myocardial infarction
6	Specificity of antisense oligonucleotide derivatives and cellular delivery by cell-penetrating peptides Guterstam, Peter January 2009 (has links) Atypical gene expression has a major influence on the disease profile of several severe human disorders. Oligonucleotide (ON) based therapeutics has opened an avenue for compensating deviant protein expression by acting on biologically important nucleic acids, mainly RNAs. Antisense ONs (asONs) can be designed to target complementary specific RNA sequences and thereby to influence the corresponding protein synthesis. However, cellular uptake of ONs is poor and is, together with the target specificity of the asONs, the major limiting factor for the development of ON based therapeutics. In this thesis, the mechanisms of well-characterized cell-penetrating peptides (CPPs) are evaluated and CPPs are adapted for cellular ON-delivery. The functionality of ON derivatives in cells is investigated and by optimization of asONs, targeting pre-messenger RNA, high efficiency and specificity is achieved. The optimization of the asONs is based on sequence design and through the choice of nucleic acid analogue composition. It is concluded that asONs, partly composed of locked nucleic acids are attractive for splice-switching applications but these mixmers must be designed with limited number of locked nucleic acid monomers to avoid risk for off-target activity. A protocol allowing for convenient characterization of internalization routes for CPPs is established and utilized. A mechanistic study on cellular CPP uptake and translocation of associated ON cargo reveals the importance of the optimal combination of for example charge and hydrophobicity of CPPs for efficient cellular uptake. Formation of non-covalent CPP:ON complexes and successful cellular delivery is achieved with a stearylated version of the well-recognized CPP, transportan 10. The results illustrate that CPPs and ON derivatives have the potential to become winning allies in the competition to develop therapeutics regulating specific protein expression patterns involved in the disease profile of severe human disorders. / At the time of doctoral defense, the following papers were unpublished and had s status as follows: Paper 4: Accepted.Peper 5: In press. / VINNOVA-SAMBIO Multidisciplinary BIO cell-penetrating peptide splice-switching oligonucleotide oligonucleotide derivative Neurochemistry Neurokemi
7	Structures, toxicity and internalization of cell-penetrating peptides Eiríksdóttir, Emelía January 2010 (has links) Cellular internalization is a highly regulated process controlled by proteins in the plasma membrane. Large and hydrophilic compounds, in particular, face difficulties conquering the plasma membrane barrier in order to gain access to intracellular environment. This puts serious constrains on the drug industry since many drugs are hydrophilic. Several methods aiming at aiding the cellular internalization of otherwise impermeable compounds have therefore been developed. One such class, so-called cell-penetrating peptides (CPPs), emerged around twenty years ago. This group constitutes hundreds of peptides that have shown a remarkable ability in translocating diverse molecules, ranging from small molecules to large proteins, over the cell membrane. The internalization mechanism of CPPs has been questioned ever since the first peptides were discovered. Initially, the consensus in the field was direct translocation but endocytosis has gradually gained ground. The confusion and the disunity within this research field through the years proceeds from divergent results between research groups that hamper comparison of the peptides. This thesis aims at characterizing several well-established CPPs with comprehensive studies on cellular toxicity, secondary structure and cellular internalization kinetics. The results demonstrate that CPPs act in general in a low or non-toxic way, but the apparent toxicity is both peptide- and cell line-dependent. Structural studies show that the CPPs have a diverse polymorphic behavior ranging from random coil to structured β-sheet or α-helix, depending on the environment. The ability to change secondary structure could be the key to the internalization property of the CPPs. Internalization kinetic studies of CPP conjugates reveal two sorts of internalization profiles, either fast curves that cease in few minutes or slow curves that peak in tens of minutes. Furthermore, improved synthesis of CPP conjugates is demonstrated. In conclusion, the studies in this thesis provide useful information about cytotoxicity and structural diversity of CPPs, and emphasize the importance of kinetic measurements over end-point studies in order to give better insights into the internalization mechanisms of CPPs. / <p>At the time of the doctoral defense, the following paper was unpublished and had a status as follows: Paper 4: Submitted.</p> CPP cell-penetrating peptide internalization toxicity structures Neurochemistry Neurokemi
8	Multi-component peptide-based carriers for gene delivery Shu Yang Unknown Date (has links) The feasibility of most gene therapy strategies depends on the efficient delivery of DNA to target cells and tissues. Current gene delivery carriers can be divided into two classes: viral and non-viral delivery systems. Although the viral carriers are highly efficient due to their invasive nature, safety concerns may restrict their application in clinical settings. Synthetic non-viral carriers attract increasing attention because they are less toxic and allow readily modification. Non-viral carrier mediated gene delivery involves several processes. They must condense DNA into small particles, allow membrane penetration and protect DNA from extracellular and intracellular degradative enzymes. In the present study, a small library of carriers containing various combinations of cell penetrating peptide TAT, SV40 large T protein nuclear localisation signal (NLS) and cationic dendrimer of 7 lysine residues (DEN) was synthesised and tested for their ability to deliver DNA to mammalian cells. We evaluated the contribution of each component as well as the combination of the components on DNA condensation, uptake and gene expression. It was found that all carriers condensed DNA and protected DNA from DNase degradation. We showed that the TAT peptide was essential, but not sufficient, for uptake of exogenous DNA. The addition of either NLS or DEN significantly enhanced uptake. The most efficient carrier contained all three components (DEN-NLS-TAT). The carriers were able to deliver DNA in the presence of serum and were non-toxic to cells at up to 30 μM. However, for those peptides that facilitated DNA uptake, the complexes were targeted to intracellular compartments that required a fusogenic agent, such as chloroquine, before gene expression was observed. Modifications were introduced to the initial carrier library in order to circumvent the chloroquine dependence. The addition of cell penetrating peptide penetratin, virus derived fusogenic peptide or lipoamino acid C12 enhanced either DNA uptake or endosomal release. However, none of the modified carriers were able to produce high level transgene expression in the absence of chloroquine. We also found that the carriers containing lipid components were able to deliver DNA to T-lymphocytes derived cells, which are usually resistant to transfection. However, the toxicity of the lipid-based carriers needs to be reduced before further application. We also evaluated the function of chloroquine as a gene expression enhancer. We demonstrated that chloroquine did not enhance expression solely by promoting endosomal release. This was supported by the fact that fusogenic peptide and endosomal disruptive reagents (bafilomycin A1 and monensin) did not improve gene expression. Other properties of chloroquine, such as DNA protection and transcription enhancement, may also contribute to gene expression. We characterised the uptake mechanism of DEN-NLS-TAT in HeLa cell lines. We found that the uptake of DEN-NLS-TAT/DNA complex in HeLa cell line was mainly via receptor-mediated endocytosis and caveolae endocytosis. Moreover, various intracellular processes, such as intact cytoskeleton and microtubule network, tyrosine and PI 3 kinase activity, and membrane cholesterol were also required for the uptake of the carrier/DNA complex. In conclusion, the results from the present study demonstrated that multi-component peptide-based carriers are versatile carriers for the delivery of plasmid DNA in human cells. The results have improved our understanding of the role of chloroquine as a widely used gene expression enhancer which may be useful in the future improvement of non-viral gene delivery carriers. A strategy to overcome the dependence on chloroquine for gene expression or reduce the toxicity of chloroquine will be necessary for further in vivo applications. The current carrier library may also be used to delivery other cargos such as siRNA or protein to human cells. non-viral gene delivery carrier cell penetrating peptide dendrimer chloroquine endocytosis
9	Study of cellular delivery of siRNA and shRNA targeting bcr-abl in chronic myeloid leukemia using Tat derived peptide Arthanari, Yamini January 2011 (has links) Chronic Myeloid Leukemia is characterised by the formation of a fusion gene bcr-abl. The gene product BCR-ABL has deregulated tyrosine kinase activity that plays a direct role in the pathogenesis of the disease. Recently, use of siRNA in leukaemic cells has led to effective gene silencing of bcr-abl. Gene delivery systems like viral vectors, electroporation and lipid based vectors have showed varying efficiencies but are limited by their level of toxicity and immunogenicity. Developments in the field of Cell Penetrating Peptides have shown effective cellular uptake of nucleic acids and proteins by the CPPs in vitro and in vivo. Report from our lab has shown the use of CPP Tat along with membrane active peptide LK15 to improve the transfection efficiency of both Tat and LK15 peptides individually. Hence, this study will focus on the use of Tat-LK15 peptide to study the delivery of siRNA and shRNA plasmid in K562 cells and observe the BCR-ABL protein expression. Cellular uptake studies using Tat-LK15 based complexes of Cy5-labelled DNA and siRNA showed a concentration dependent uptake leading to increase in percentage transfected cells. Tat-LK15 based DNA complexes achieved 80% transfected cells (charge ratio of 2:1) while siRNA complexes resulted in a maximum of 60% (charge ratio of 3:1). However, Lipofectamine based DNA complexes did not show a concentration dependent increase in percentage transfected cells. Interestingly, Tat-LK15 based siRNA complexes showed a similar level of uptake and percentage transfected cells as that of Lipofectamine based siRNA complexes. Cellular uptake studies using confocal microscopy 4 hours post transfection, showed that when 1μg of DNA was transfected, the labelled DNA was primarily localised on the cell membrane. Interestingly, using 5μg of DNA led to increased intracellular localisation of the labelled DNA, but this observation was not made with Lipofectamine based complexes. The observation at 24 hours post transfection of Tat-LK15/labelled DNA complexes was of higher intensity when compared to that of Lipofectamine based DNA complexes. The reason for this is however not known. Interestingly, the cellular uptake profile using siRNA based complexes was different. At 4 hours post transfection, there was intracellular localisation of labelled siRNA. 24 hours post transfection, there was diffuse cytoplasmic localisation using lower concentration of siRNA whereas using higher concentration led to more high intensity punctate localisations within the cell. Similar observations were made for both Tat-LK15 and Lipofectamine based siRNA complexes.Gene silencing studies of Tat-LK15/shRNA plasmid complex resulted in 80% reduction in protein levels 96 hours post transfection for higher concentrations of shRNA plasmid treated. Similar level of reduction in BCR-ABL was observed with Lipofectamine based complex. Supporting evidence of reduction in mRNA levels was observed using qRT-PCR 48 hours post transfection. However, Tat-LK15/shRNA plasmid complexes led to around 80% of protein reduction 192 hours post transfection while Lipofectamine based complexes resulted in only 40% of protein reduction. Transfection using increasing concentrations of siRNA complexed to Tat-LK15 and Lipofectamine led to greater than 70% reduction in protein levels for most concentration ranges tested. This reduction in protein levels lasted only 48 hours post transfection. In conclusion, Tat-LK15 peptide could be used for shRNA plasmid and siRNA based delivery and could offer an efficient gene delivery model for studying RNAi. 572.8
10	Developments and Applications of Cyclic Cell Penetrating Peptides Qian, Ziqing 10 October 2014 (has links) No description available. Chemistry Cell Penetrating Peptide Drug delivery cyclic peptide cyclic cell penetrating peptide protein delivery endosomal escape calcineurin VIVIT

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