This subproject is one of many research subprojects utilizing the resources provided by a Center grant funded by NIH/NCRR. The subproject and investigator (PI) may have received primary funding from another NIH source, and thus could be represented in other CRISP entries. The institution listed is for the Center, which is not necessarily the institution for the investigator. Molecular motor proteins function in a multitude of intracellular transport processes that include the organization of organelles and their transport, chromosome segregation, axonal transport, and signaling pathways. Motor dependent processes are critical for the growth, proliferation, and differentiation of cells and tissues. How motor function is regulated in a developmental context, and the relationship of motor dysfunction to numerous medical problems including neurodegenerative disease, congenital chromosomal syndromes, and birth defects is a current focus of research activity. Our work is focused on the microtubule motor cytoplasmic dynein, and the important and unanswered question regarding how this single motor isoform accomplishes multiple tasks. How is dynein targeted to specific cargoes and/or cellular locations and structures? Our aims will address three non-exclusive mechanisms that potentially contribute to dynein targeting. (1) First, cytoplasmic dynein contains multiple subunits. The individual subunits or subunit domains could specify where, and to what, dynein is attached. To test this hypothesis we will ask whether domains within the light intermediate and the intermediate chain polypeptides confer specific functions. Mutagenesis and molecular genetic approaches will be used to disrupt domain function and the mutant phenotypes will be characterized. (2) Second, the posttranslational modification of dynein subunits might control whether subunits are competent to bind a cargo with high affinity. Collaboration with Dr. John Yates (Scripps Research Institute) will define the sites of phosphorylation on subunits within the dynein complex using a mass spectrometry approach. Subsequently, the phosphorylation sites identified will be mutated to mimic the phosphorylated or unphosphorylated state of the respective subunit. The phenotypes produced by transgenes that express the mutant subunits will be analyzed to reveal the functional significance of dynein phosphoregulation. (3) In a third mechanism, specific binding partners or """"""""effector"""""""" proteins might mediate the targeting of the dynien motor to specific cargoes or locations. We will pursue the functional analysis of candidate interacting proteins identified in the previous period and will continue with secondary tests on other interacting loci.

Agency
National Institute of Health (NIH)
Institute
National Center for Research Resources (NCRR)
Type
Biotechnology Resource Grants (P41)
Project #
5P41RR011823-14
Application #
7957812
Study Section
Special Emphasis Panel (ZRG1-CB-H (40))
Project Start
2009-09-01
Project End
2010-08-31
Budget Start
2009-09-01
Budget End
2010-08-31
Support Year
14
Fiscal Year
2009
Total Cost
$3,309
Indirect Cost
Name
University of Washington
Department
Biochemistry
Type
Schools of Medicine
DUNS #
605799469
City
Seattle
State
WA
Country
United States
Zip Code
98195
Xavier, Marina Amaral; Tirloni, Lucas; Pinto, Antônio F M et al. (2018) A proteomic insight into vitellogenesis during tick ovary maturation. Sci Rep 8:4698
Hollmann, Taylor; Kim, Tae Kwon; Tirloni, Lucas et al. (2018) Identification and characterization of proteins in the Amblyomma americanum tick cement cone. Int J Parasitol 48:211-224
Stieg, David C; Willis, Stephen D; Ganesan, Vidyaramanan et al. (2018) A complex molecular switch directs stress-induced cyclin C nuclear release through SCFGrr1-mediated degradation of Med13. Mol Biol Cell 29:363-375
Seixas, Adriana; Alzugaray, María Fernanda; Tirloni, Lucas et al. (2018) Expression profile of Rhipicephalus microplus vitellogenin receptor during oogenesis. Ticks Tick Borne Dis 9:72-81
Wang, Zheng; Wu, Catherine; Aslanian, Aaron et al. (2018) Defective RNA polymerase III is negatively regulated by the SUMO-Ubiquitin-Cdc48 pathway. Elife 7:
Ju Lee, Hyun; Bartsch, Deniz; Xiao, Cally et al. (2017) A post-transcriptional program coordinated by CSDE1 prevents intrinsic neural differentiation of human embryonic stem cells. Nat Commun 8:1456
Luhtala, Natalie; Aslanian, Aaron; Yates 3rd, John R et al. (2017) Secreted Glioblastoma Nanovesicles Contain Intracellular Signaling Proteins and Active Ras Incorporated in a Farnesylation-dependent Manner. J Biol Chem 292:611-628
Thakar, Sonal; Wang, Liqing; Yu, Ting et al. (2017) Evidence for opposing roles of Celsr3 and Vangl2 in glutamatergic synapse formation. Proc Natl Acad Sci U S A 114:E610-E618
Jin, Meiyan; Fuller, Gregory G; Han, Ting et al. (2017) Glycolytic Enzymes Coalesce in G Bodies under Hypoxic Stress. Cell Rep 20:895-908
Ogami, Koichi; Richard, Patricia; Chen, Yaqiong et al. (2017) An Mtr4/ZFC3H1 complex facilitates turnover of unstable nuclear RNAs to prevent their cytoplasmic transport and global translational repression. Genes Dev 31:1257-1271

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