Characterization of Karyopherin Alpha's Relationship with SubH2Bv as Acrosome-Associated Proteins in Spermiogenesis

Tran, MONG HOA

04 September 2008

Specialized in form and function, the sperm cell is a unique microsystem unto itself where in the cytoskeletal processes and structures of the somatic cell often find new purpose and characteristics within the sperm. Unlike other cells in the human body, this unique cell polarizes and transforms itself from a line of germ cells to evolve into a functional, hydrodynamic haploid spermatozoon. The success of fertilization is dependent on this haploid cell and its specially designed vesicular structure, the acrosome, which provides the leading edge of oocyte penetration. To date, there is little insight into the mechanics of how acrosomic vesicles are successfully targeted and transported to the nuclear envelope and tether to its surface. Our laboratory has identified a novel 15 kDa sperm specific histone variant, SubH2Bv, which possesses a distinct and functional nuclear localization signal (NLS) that associates with the acrosomic vesicle. This study provides evidence that SubH2Bv’s bipartite NLS (an NLS with two basic domains linked together by 10-12 amino acid residues) is responsible for directing acrosomic vesicles to the nuclear envelope using the somatic import receptor, karyopherin alpha (Kap α). Based on bipartite NLS-receptor conventions, where karyopherin alpha is known to specifically associate with this NLS-type, SubH2Bv would be the karyophilic cargo and karyopherin alpha would act as part of the underlying transport mechanism. Western blot analysis and immunohistochemistry characterized Kap α as a membrane-associated sperm protein that is co-localized with SubH2Bv around the proacrosomic granules and the acrosomic vesicle during spermiogenesis. Their co-expression and co-localization, as demonstrated by immunolabelling, suggested a potential binding relationship that was confirmed by a His-tag-recombinant SubH2Bv-pull-down assay. The co-developmental acrosomic expression of Kap α and SubH2Bv in haploid cells, combined with the pull-down evidence of their binding affinity, provides a compelling argument that these two proteins work in concert to traffic the acrosomic vesicles to the nucleus. The exclusion of these two otherwise nuclear proteins from the nucleus, and their co-localization to the subacrosomal region in elongating spermatids, also implies a contingent role for SubH2Bv and Kap α in acrosomal docking, that may involve the classical bipartite/Kap α nuclear import pathway. / Thesis (Master, Anatomy & Cell Biology) -- Queen's University, 2008-09-02 16:11:17.429

Acrosome

Nuclear Targeting

Spermiogenesis

SubH2Bv

Karyopoherin Alpha

Design, Synthesis and Evaluation of Cancer Targeting α-Peptides and Novel Peptidomimetic β-Peptides

Ahmed, Sahar

Unknown Date

No description available.

Bone Targeting Salmon Calcitonin Analogues as Drug Delivery Systems for Bone Disease

Bhandari, Krishna H

Unknown Date

No description available.

Bone Targeting

Salmon Calcitonin PEGylation,

Osteoporosis and Arthritis

Harnessing Mitochondria-penetrating Peptides for the Organellar Delivery of Small Molecule Drugs

Fonseca, Sonali

11 December 2012

Mitochondria play essential roles in numerous cellular processes, including oxidative phosphorylation and apoptotic initiation. As a result, organellar dysfunction has been implicated in several pathologies such as cancer, diabetes and neurodegenerative diseases. The opportunity to deliver compounds to probe or treat these conditions would be highly beneficial but accessing this organelle is challenging. Prior work investigated the physicochemical properties required for mitochondrial targeting and yielded mitochondria-penetrating peptides (MPPs). MPPs possess hydrophobic and cationic character and exhibit efficient cellular uptake and mitochondrial localization. In this proof-of-principle study, MPPs were harnessed to re-route an anti-leukemia agent, chlorambucil (Cbl), from the nucleus to mitochondria. This DNA alkylating agent was selected for its rapid kinetics and facile conjugation to an MPP. In addition, because mitochondria possess their own genome, the target of this drug would also be present in the organelle. Conjugation of an MPP to Cbl (mt-Cbl) confirmed that the drug was re-routed to the mitochondria and an increase in potency was observed in several cell lines and patient samples. This gain in activity was due to the increased accessibility of the mitochondrial genome, its lack of introns and its limited repair capacity. However, despite this enhanced toxicity, a therapeutic window continued to be maintained due to the elevated mitochondrial membrane potential in cancer cells. The re-routing of Cbl also resulted in evasion of several drug resistance mechanisms. Damage directly within the organelle was sufficient to initiate apoptosis even in cell lines with disabled apoptotic triggering. In addition, mitochondrial sequestration protected mt-Cbl from drug inactivation mechanisms. Lastly, mt-Cbl inhibited Pgp efflux by unexpectedly interacting with the pumps and inhibiting activity for a short period of time. The anti-cancer activity of mt-Cbl was also assessed in vivo in xenograft models of leukemia. The conjugate was stable in mouse plasma and displayed an improved pharmacokinetic profile. In addition, mt-Cbl successfully delayed tumor growth in two xenograft models and continued to alkylate mitochondrial DNA in vivo. These studies demonstrate that MPPs can be harnessed to re-route drugs to this organelle. Mitochondrial re-targeting could be a novel method of re-purposing FDA-approved drugs to enhance activity and evade resistance.

mitochondria

chlorambucil

targeting

0992

0572

0491

Harnessing Mitochondria-penetrating Peptides for the Organellar Delivery of Small Molecule Drugs

Fonseca, Sonali

11 December 2012

Mitochondria play essential roles in numerous cellular processes, including oxidative phosphorylation and apoptotic initiation. As a result, organellar dysfunction has been implicated in several pathologies such as cancer, diabetes and neurodegenerative diseases. The opportunity to deliver compounds to probe or treat these conditions would be highly beneficial but accessing this organelle is challenging. Prior work investigated the physicochemical properties required for mitochondrial targeting and yielded mitochondria-penetrating peptides (MPPs). MPPs possess hydrophobic and cationic character and exhibit efficient cellular uptake and mitochondrial localization. In this proof-of-principle study, MPPs were harnessed to re-route an anti-leukemia agent, chlorambucil (Cbl), from the nucleus to mitochondria. This DNA alkylating agent was selected for its rapid kinetics and facile conjugation to an MPP. In addition, because mitochondria possess their own genome, the target of this drug would also be present in the organelle. Conjugation of an MPP to Cbl (mt-Cbl) confirmed that the drug was re-routed to the mitochondria and an increase in potency was observed in several cell lines and patient samples. This gain in activity was due to the increased accessibility of the mitochondrial genome, its lack of introns and its limited repair capacity. However, despite this enhanced toxicity, a therapeutic window continued to be maintained due to the elevated mitochondrial membrane potential in cancer cells. The re-routing of Cbl also resulted in evasion of several drug resistance mechanisms. Damage directly within the organelle was sufficient to initiate apoptosis even in cell lines with disabled apoptotic triggering. In addition, mitochondrial sequestration protected mt-Cbl from drug inactivation mechanisms. Lastly, mt-Cbl inhibited Pgp efflux by unexpectedly interacting with the pumps and inhibiting activity for a short period of time. The anti-cancer activity of mt-Cbl was also assessed in vivo in xenograft models of leukemia. The conjugate was stable in mouse plasma and displayed an improved pharmacokinetic profile. In addition, mt-Cbl successfully delayed tumor growth in two xenograft models and continued to alkylate mitochondrial DNA in vivo. These studies demonstrate that MPPs can be harnessed to re-route drugs to this organelle. Mitochondrial re-targeting could be a novel method of re-purposing FDA-approved drugs to enhance activity and evade resistance.

mitochondria

chlorambucil

targeting

0992

0572

0491

Two-photon Excitation Photodynamic Therapy for Localized Blood Vessel Targeting

Khurana, Mamta

18 February 2011

The motivation of this study lies in the necessity for a microfocal therapy to specifically target diseased areas in vascular pathologies such as age-related macular degeneration (AMD). AMD is the most common cause of legal blindness among people over the age of 60 in developed countries. This degenerative condition affects the macula, the central region of the retina, severely impairing detailed vision and hindering everyday activities. Worldwide, 25-30 million people live with some form of AMD. Among them, ~10% suffer from the more advanced and damaging form, wet-AMD, which causes rapid and severe loss of central vision. To date, there is no cure or long-term alternative for this degenerative disease despite intensive research efforts. With recent developments in biophysical tools and experimental procedures, in this study, we demonstrate a highly-localized therapeutic option: two-photon (2-photon) photodynamic therapy (PDT) that could be advantageous for the cure of wet-AMD, either alone or in combination with recently discovered anti-angiogenic therapies. This new approach offers selective targeting of the diseased area, thus minimizing damage to the surrounding sensitive healthy eye tissues, which is a major concern with the clinically-used, standard wide-beam, one-photon (1-photon) PDT. The objective of the research was to test the feasibility of microfocal 1-photon and the inherently localized 2-photon PDT, their optimization and also to evaluate the efficacy of existing 1-photon and novel 2-photon photosensitizers. In this thesis, I illustrated the in vitro (endothelial cell monolayer) and in vivo (window chamber mouse (WCM)) models that can be used to quantitatively compare the 2-photon efficiency of photosensitizers. Using the in vitro model, I compared the 2-photon efficacy of clinically used 1-photon PDT drugs Photofrin and Visudyne, and showed that the Visudyne is an order of magnitude better 2-photon photosensitizer than Photofrin. With the WCM model, I demonstrated a novel designer 2-photon photosensitizer is 20 times more efficient than Visudyne for single vessel occlusion. I also generated the drug and light dose reciprocity curve for localized single-vessel microfocal PDT. This is a necessary step towards applying the method to the relevant ocular models of AMD, which is the next phase for this research.

Photodynamic therapy

vessel targeting

0760

0752

Design, Synthesis and Evaluation of Cancer Targeting -Peptides and Novel Peptidomimetic -Peptides

Ahmed, Sahar

11 1900

Current cancer therapies have low specificity for tumor cells and have serious toxic side effects. Targeting drugs to the cancer cells can help improve the outcome of existing cancer therapies. In recent years, a number of peptides have been identified by peptide phage display for targeting different tumor types. Peptides identified from the phage display for targeting cancer cells can be further improved for specific binding and metabolic stability by chemical manipulation of their structures. The aims of this work were: (i) to develop a peptide array-whole cell binding assay for screening peptides with specific binding affinity for cancer cells (ii) design of novel peptidomimetics to improve their properties as drug candidates. First, peptide arrays based on the lead peptide sequences NGR and p160 were designed and synthesized. A direct peptide-cell binding assay using CyQUANT dye allowed identification of several new peptides with higher affinity for MDA-MB-435 and MCF-7 cancer cells compared to the wild type p160. These peptides did not recognize the normal endothelial HUVEC cells. Three p160 peptide analogues, namely, 11 (RGDPAYQGRFL), 18 (WXEAAYQRFL), and 40 (WXEPAYQRKL), that displayed highest affinity for the cancer cells were manually synthesized and labelled with FITC. The binding ability of these peptides was confirmed using fluorescence imaging and flow cytometry. The results confirmed the high and specific affinity of peptides 11 and 18 for the cancer cells. The peptide array-cell binding assay established in this study is not only useful for the identification of cancer targeting peptides. It can also be used for the generation of diagnostic tools for cancer. Secondly, two new classes of -peptides, 3- and 2-peptides derived from L-Asp and L-Dap monomers, respectively, were synthesized. The methodology allowed independent buildup of the -peptide backbone and the introduction of sequential side chain substitutions. It is shown that / mixed peptide increases target recognition and retains the proteolytic stability. Moreover, -peptides impart no cytotoxicity, which will expand their potential application in the design of biologically active peptides. As a result, these compounds represent good candidates for new drugs and as tools to gain further insight into protein folding and molecular recognition processes. / Pharmaceutical Sciences

Homologous Recombination of Mouse ZAKI-4 Gene to Disrupt its Expression

KANOU, Yasuhiko, ABE, Naoki, ISHIDA, Junji, FUKAMIZU, Akiyoshi, SEO, Hisao, MURATA, Yoshiharu

12 1900

国立情報学研究所で電子化したコンテンツを使用している。

ZAKI-4

homologous recombination

gene targeting

calcineurin

Two-Step Targeting for Effective Radionuclide Therapy : Preclinical Evaluation of 125I-labelled Anthracycline Delivered by Tumour Targeting Liposomes

Fondell, Amelie

January 2011

For the treatment of cancer, Auger-electron emitting radionuclides are strongly dependent on their close proximity to DNA to utilize the local therapeutic potential of the Auger electrons. This thesis investigates a two-step targeting approach that uses targeting liposomes for the delivery of an Auger-electron emitter, 125I, coupled to a DNA-binding compound, Comp1, to the tumour-cell DNA. In the first step the liposome targets overexpressed cell-surface receptors. Receptors belonging to epidermal growth factor receptor (EGFR) family are overexpressed in a number of different cancers and are therefore suitable targets. The second step is transportation of the radionuclide to the cell nucleus utilizing a DNA-binding compound. The DNA-binder used in this thesis is a daunorubicin derivative called Comp1. Papers I and II are in vitro characterizations of the targeting liposomes. Both EGFR- and HER2-targeting liposomes delivered 125I-Comp1 receptor specifically to tumour cells, and were efficient in decreasing growth of cultured tumour cells. Paper II also included a biodistribution of 125I-Comp1 delivered by HER2-targeting liposomes in tumour-bearing mice. The results gave a time-dependent uptake in tumours differed from when non-targeting liposomes encapsulating 125I-Comp1 were given. Paper III investigates the therapeutic effect of 125I-Comp1 delivered by HER2-targeting liposomes, in an animal model that mimics a situation of disseminated tumour cells in the abdomen. 125I-Comp1 delivered by HER2-targeting liposomes effectively prolonged survival of the mice in a dose-dependent relation. Several mice in the groups receiving the highest doses were tumour-free at the end of the study. Paper IV compares different lipid compositions of the liposomes with respect to leakage, cellular uptake and therapeutic efficacy of delivered 125I-Comp1on cultured cells. Liposomes containing sphingomyelin or dihydrosphingomyelin retained drug more efficiently and exhibited more receptor specific delivery properties than distearoylglycerophosphatidylcholine (DSPC) containing liposomes. However, it was the DSPC-containing liposomes that displayed best growth inhibition on cultured tumour cells. The thesis concludes that 125I-Comp1 delivered by targeting liposomes is a promising candidate for effective radionuclide therapy.

radionuclide

Auger electrons

liposomes

targeting

tumour therapy

Genetic re-targeting and de-targeting of adenovirus type 5 in order to create vectors for gene therapy /

Myhre, Susanna,

January 2007

Diss. (sammanfattning) Göteborg : Göteborgs universitet, 2007. / Härtill 5 uppsatser.