Many aspects of development require the migration of individual cells through diverse and complex environments. In vertebrate embryos, for example, neural crest cells leave the developing central nervous system and migrate over long distances to give rise to such cell types as sensory neurons, facial cartilage and pigment cells of the skin. In adults, migratory cell types include the cells of the immune system, fibroblasts during wound healing, and cancer cells during metastasis. During directed cell migration, motile cells are guided along a particular path, they recognize guidance cues and translate them into directed movement. Finally, cells must be able to recognize their target tissue and stop migrating and cells that fail to reach their target have to be eliminated. Primordial germ cells provide an excellent model system for the analysis of directed cell migration. Many aspects of germ cell biology, such as their overall morphology and their curious migratory path toward the somatic components of the gonad are conserved throughout the animal kingdom. We have used Drosophila to identify signals produced by the soma that guide migrating germ cells. We find that lipid signaling plays a critical role for migrating primordial germ cells. This proposal aims to understand how lipid signaling and membrane composition affect germ cell migration and survival.
The aim i s to characterize the signaling processes within the germ cells and to determine the nature and distribution of the extracellular signals that guide germ cells. In the first aim we will use a genetic approach targeted at germline expressed genes to identify new and additional components of the migratory machinery in germ cells. In the second aim, we will characterize the lipid targets of the Drosophila lipidphosphate phosphatases, Wunen and Wunen2 that guide germ cells and analyze the nature of the migratory response in germ cells and its role in germ cell survival. In the third aim, we propose to isolate a germ cell attractant produced by the somatic gonad, which we have shown is lipid modified and exported by the somatic gonad cells by an conserved, unconventional ABC transporter. Mis-migration of germ cells in humans is thought to be the cause of germinomas, tumors of the germ line that develop outside of the testis and ovaries. It remains unclear what causes germ cell mis-migration and why these apparently 'lost' germ cells survive outside of the gonad environment. The mechanisms underlying germ cell migration and survival have been studied in genetically tractable organisms such as Drosophila, mouse and zebrafish. These studies have revealed striking parallels in the behavior of germ cells and in the genes that control this behavior. Findings resulting from this application are likely to contribute to a better understanding of the cues and cellular processes that guide germ cell migration and that physically distinguish germ cells from other cells in the body.

Public Health Relevance

Germinomas, tumors of the germ line that develop outside of the testis and ovaries are thought to arise from defective embryonic germ cell migration. Here we use Drosophila germ cell migration to determine some of the fundamental mechanisms of cell migration in the context of a developing organism. We use genetic and biochemical approaches, live imaging and in vitro germ cell cultures to address how lipids and lipid modification provide migratory cues and how these signals are interpretated by the migrating germ cells.

Agency
National Institute of Health (NIH)
Institute
Eunice Kennedy Shriver National Institute of Child Health & Human Development (NICHD)
Type
Method to Extend Research in Time (MERIT) Award (R37)
Project #
5R37HD041900-14
Application #
8925697
Study Section
Cellular, Molecular and Integrative Reproduction Study Section (CMIR)
Program Officer
Taymans, Susan
Project Start
2001-09-01
Project End
2017-08-31
Budget Start
2015-09-01
Budget End
2016-08-31
Support Year
14
Fiscal Year
2015
Total Cost
$270,231
Indirect Cost
$110,331
Name
New York University
Department
Anatomy/Cell Biology
Type
Schools of Medicine
DUNS #
121911077
City
New York
State
NY
Country
United States
Zip Code
10016
Coux, RĂ©mi-Xavier; Teixeira, Felipe Karam; Lehmann, Ruth (2018) L(3)mbt and the LINT complex safeguard cellular identity in the Drosophila ovary. Development 145:
LeBlanc, Michelle G; Lehmann, Ruth (2017) Domain-specific control of germ cell polarity and migration by multifunction Tre1 GPCR. J Cell Biol 216:2945-2958
Pae, Juhee; Cinalli, Ryan M; Marzio, Antonio et al. (2017) GCL and CUL3 Control the Switch between Cell Lineages by Mediating Localized Degradation of an RTK. Dev Cell 42:130-142.e7
Teixeira, Felipe Karam; Okuniewska, Martyna; Malone, Colin D et al. (2017) piRNA-mediated regulation of transposon alternative splicing in the soma and germ line. Nature 552:268-272
Slaidina, Maija; Lehmann, Ruth (2017) Quantitative Differences in a Single Maternal Factor Determine Survival Probabilities among Drosophila Germ Cells. Curr Biol 27:291-297
Barton, Lacy J; LeBlanc, Michelle G; Lehmann, Ruth (2016) Finding their way: themes in germ cell migration. Curr Opin Cell Biol 42:128-137
Lehmann, Ruth (2016) Germ Plasm Biogenesis--An Oskar-Centric Perspective. Curr Top Dev Biol 116:679-707
Sanchez, Carlos G; Teixeira, Felipe Karam; Czech, Benjamin et al. (2016) Regulation of Ribosome Biogenesis and Protein Synthesis Controls Germline Stem Cell Differentiation. Cell Stem Cell 18:276-90
Hurd, Thomas Ryan; Herrmann, Beate; Sauerwald, Julia et al. (2016) Long Oskar Controls Mitochondrial Inheritance in Drosophila melanogaster. Dev Cell 39:560-571
Hurd, Thomas R; Sanchez, Carlos G; Teixeira, Felipe K et al. (2015) Ultrastructural Analysis of Drosophila Ovaries by Electron Microscopy. Methods Mol Biol 1328:151-62

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