Directed cell migration toward chemoattractants, termed chemotaxis, is central to many physiologic events such as axon guidance, wound healing, and tissue morphogenesis. Inappropriate chemotaxis is a key feature of many human diseases, including tumor metastasis, asthma, arthritis, and atherosclerosis. Understanding the mechanisms of chemotaxis is therefore vital for understanding these chemotaxis-related diseases. The long- term goal of our research is to reveal how cells sense their chemical environment and control their migratory behaviors. Using Dictyostelium amoebae as our discovery tool and human cells as our translational tool, we focus on the potent intracellular signal phosphatidylinositol-3,4,5-triphosphate (PIP3), which is produced at the leading edge of cells and reorganizes the actin cytoskeleton. An important, but unanswered, question in the field of chemotaxis is how cells stably maintain the signaling network and remodel the actin cytoskeleton in chemoattractant gradients. To address this fundamental problem, our current studies identified: i) a signaling step that stabilizes directional sensing by persistently orientig Ras activation and PIP3 production, ii) a molecular link that directly binds to both PIP3 and the actin cytoskeleton, and iii) a conserved process in Dictyostelium and humans that turns off PIP3 signaling through translocation of the PIP3 phosphatase PTEN to the plasma membrane. In the next funding period, we propose to study each of these regulatory events and the mechanisms by which chemotactic signaling controls cell migration with high precision.
In Aim 1, we will determine how directional sensing is spatially directed toward chemoattractants. We hypothesize that the activation of Ras GTPases and PIP3 production that occurs at the leading portion of cells is regulated by active Rho GTPases located at the rear end through chemical gradients. We will examine how Rho GTPases transmit signal to Ras GTPases.
In Aim 2, we will determine how PIP3-binding monomeric myosin I converts the PIP3 signal to the actin cytoskeleton. We will test three models for the function of myosin I in cytoskeletal remodeling: connecting actin filaments to the plasma membrane, directly polymerizing actin, and recruiting actin nucleation factors.
In Aim 3, we will delineate how human PTEN is recruited to the plasma membrane. We hypothesize that previously unidentified PTEN receptors in the plasma membrane mediate this process in human cells. We will examine the function of newly identified human PTEN-binding proteins in the localization of PTEN. Moreover, we will further determine the functional importance of the receptors in PIP3 signaling. The outcomes of our research are expected to provide a conceptual breakthrough into two central events in chemotaxis, directional sensing and cytoskeletal rearrangements, and may lead to development of chemotaxis-based treatments for cancer and inflammation.

Public Health Relevance

Chemotaxis has been linked to many human diseases such as cancer, asthma, arthritis and atherosclerosis. The proposed research projects will deepen our understanding of the molecular mechanism of chemotaxis and the pathogenesis of the chemotaxis-related diseases using genetics, biochemistry and cell biology.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
2R01GM084015-06A1
Application #
8887423
Study Section
Nuclear and Cytoplasmic Structure/Function and Dynamics Study Section (NCSD)
Program Officer
Nie, Zhongzhen
Project Start
2009-09-30
Project End
2019-03-31
Budget Start
2015-07-01
Budget End
2016-03-31
Support Year
6
Fiscal Year
2015
Total Cost
Indirect Cost
Name
Johns Hopkins University
Department
Anatomy/Cell Biology
Type
Schools of Medicine
DUNS #
001910777
City
Baltimore
State
MD
Country
United States
Zip Code
21205
Kriebel, Paul W; Majumdar, Ritankar; Jenkins, Lisa M et al. (2018) Extracellular vesicles direct migration by synthesizing and releasing chemotactic signals. J Cell Biol 217:2891-2910
Yamada, Tatsuya; Murata, Daisuke; Adachi, Yoshihiro et al. (2018) Mitochondrial Stasis Reveals p62-Mediated Ubiquitination in Parkin-Independent Mitophagy and Mitigates Nonalcoholic Fatty Liver Disease. Cell Metab 28:588-604.e5
Igarashi, Atsushi; Itoh, Kie; Yamada, Tatsuya et al. (2018) Nuclear PTEN deficiency causes microcephaly with decreased neuronal soma size and increased seizure susceptibility. J Biol Chem 293:9292-9300
Adachi, Yoshihiro; Iijima, Miho; Sesaki, Hiromi (2018) An unstructured loop that is critical for interactions of the stalk domain of Drp1 with saturated phosphatidic acid. Small GTPases 9:472-479
Yamada, Tatsuya; Adachi, Yoshihiro; Yanagawa, Toru et al. (2018) p62/sequestosome-1 knockout delays neurodegeneration induced by Drp1 loss. Neurochem Int 117:77-81
Kameoka, Shoichiro; Adachi, Yoshihiro; Okamoto, Koji et al. (2018) Phosphatidic Acid and Cardiolipin Coordinate Mitochondrial Dynamics. Trends Cell Biol 28:67-76
Itoh, Kie; Adachi, Yoshihiro; Yamada, Tatsuya et al. (2018) A brain-enriched Drp1 isoform associates with lysosomes, late endosomes, and the plasma membrane. J Biol Chem 293:11809-11822
Tellios, Nikoleta; Belrose, Jillian C; Tokarewicz, Alexander C et al. (2017) TGF-? induces phosphorylation of phosphatase and tensin homolog: implications for fibrosis of the trabecular meshwork tissue in glaucoma. Sci Rep 7:812
Yang, Jr-M; Schiapparelli, P; Nguyen, H-N et al. (2017) Characterization of PTEN mutations in brain cancer reveals that pten mono-ubiquitination promotes protein stability and nuclear localization. Oncogene 36:3673-3685
Adachi, Yoshihiro; Itoh, Kie; Iijima, Miho et al. (2017) Assay to Measure Interactions between Purified Drp1 and Synthetic Liposomes. Bio Protoc 7:

Showing the most recent 10 out of 41 publications