This project focuses on the ability of small molecules to alter the cell's cytoskeleton and, in particular, microtubules (MT). MT are the most rigid of the cytoskeletal polymers, and are central to establishing and maintaining non-spherical cell morphology. In addition, MT have intrinsic polarity, and the cytoplasmic array of MT provides the substrate for directional intracellular movement. Thus, small molecules that alter MT integrity and/or dynamics can scramble intracellular trafficking and alter the physical properties of the cytoplasm. This project has two parts. One is to understand in detail the interaction of MT-active small molecules with MT or the MT subunit protein, tubulin, focusing on anti-mitotic peptide natural products from marine sources. The second part aims to use the knowledge of MT-small molecule interactions to identify drug therapies for parasite diseases.? In part one we have focused on antimitotic peptides because these are among the most potent anti-MT agents known, they have been synthesized and analogs are available, and because they induce the MT subunits to assume unusual and characteristic ring shapes. We are studying the structural and dynamic properties of these ring polymers by analytical ultracentrifugation, cryoelectron microscopy, fluorescence correlation spectroscopy, and protease mapping. The high stability and uniformity of these rings that our studies revealed have led us to attempt crystallization of these polymers to achieve atomic resolution of their structure.? In part two, we are seeking to identify small molecules that do not bind well with mammalian tubulin but do bind to parasite tubulin. The tubulin molecule is quite conserved evolutionarily, but differences do exist, and several molecules are known that can target, for example, yeast rather than mammalian tubulin or vice-versa. We are looking for molecules that will target Leishmania, the infectious cause of an important group of human diseases. We have identified several small molecules that show promise as selective agents, binding to Leishmania tubulin preferentially over mammalian tubulin, and preventing parasite multiplication inside human macrophage cells.

Project Start
Project End
Budget Start
Budget End
Support Year
3
Fiscal Year
2005
Total Cost
Indirect Cost
Name
U.S. National Inst/Child Hlth/Human Dev
Department
Type
DUNS #
City
State
Country
United States
Zip Code
Huzil, J Torin; Chik, John K; Slysz, Gordon W et al. (2008) A unique mode of microtubule stabilization induced by peloruside A. J Mol Biol 378:1016-30
Balasubramanian, Ranganathan; Raghavan, Bhooma; Steele, Jaeson C et al. (2008) Tubulysin analogs incorporating desmethyl and dimethyl tubuphenylalanine derivatives. Bioorg Med Chem Lett 18:2996-9
Sackett, Dan L; Ozbun, Laurent; Zudaire, Enrique et al. (2008) Intracellular proadrenomedullin-derived peptides decorate the microtubules and contribute to cytoskeleton function. Endocrinology 149:2888-98
Poruchynsky, Marianne S; Sackett, Dan L; Robey, Robert W et al. (2008) Proteasome inhibitors increase tubulin polymerization and stabilization in tissue culture cells: a possible mechanism contributing to peripheral neuropathy and cellular toxicity following proteasome inhibition. Cell Cycle 7:940-9
Raghavan, Bhooma; Balasubramanian, Ranganathan; Steele, Jaeson C et al. (2008) Cytotoxic simplified tubulysin analogues. J Med Chem 51:1530-3
Piekarz, Richard L; Sackett, Dan L; Bates, Susan E (2007) Histone deacetylase inhibitors and demethylating agents: clinical development of histone deacetylase inhibitors for cancer therapy. Cancer J 13:30-9
Zhuang, Sen H; Hung, Y Elizabeth; Hung, Laura et al. (2007) Evidence for microtubule target engagement in tumors of patients receiving ixabepilone. Clin Cancer Res 13:7480-6
Boukari, Hacene; Sackett, Dan L; Schuck, Peter et al. (2007) Single-walled tubulin ring polymers. Biopolymers 86:424-36
Kim, Yeoun Jin; Sackett, Dan L; Schapira, Matthieu et al. (2006) Identification of 12Cysbeta on tubulin as the binding site of tubulyzine. Bioorg Med Chem 14:1169-75
Trostel, Shana Y; Sackett, Dan L; Fojo, Tito (2006) Oligomerization of p53 precedes its association with dynein and nuclear accumulation. Cell Cycle 5:2253-9

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