Abstract

The long term goal of this project has been to understand the role of Sertoli cells in spermatogenesis. To achieve this goal, previous studies focused on gene expression and hormonal response of murine Sertoli cells and the interactions of the somatic cells with the germinal cells. The results of these studies have led to a central hypothesis that attempts to explain how Sertoli cells regulate the maturation of spermatogonia and the entry into spermatogenesis and meiosis. Elements of this testable hypothesis include: A) A major functional role of the Sertoli cells is to regulate the spatial and temporal delivery of retinoic acid to spermatogonia. B) Once delivered, the retinoic acid stimulates the undifferentiated spermatogonia to enter into a differentiation pathway and ultimately meiosis. Induction of the gene stra8 is a sensitive and reliable marker of this process. C) The delivery of retinoic acid via the Sertoli cells is a highly regulated process and is ultimately responsible for the establishment of the cycle of the seminiferous epithelium. The experiments to test this hypothesis are organized into three specific aims:
Specific aim 1 : Determine the kinetics of stra8 induction and the extent to which this induction in germ cells leads to differentiation in vivo and in vitro.
Specific aim 2 : Determine if, and how, the flow of retinoic acid through the Sertoli cells to the spermatogonia is regulated and resolve which components of the Sertoli cells are key for inducing stra8 in spermatogonia and initiating spermatogonial differentiation.
Specific aim 3 : Examine the onset of meiosis and establishment of the cycle of the seminiferous epithelium in models where the retinoid metabolism has been perturbed. The hypothesis requires that gonocytes and spermatogonia do not have access to circulating retinoic acid except that which is delivered by the Sertoli cells. Another requirement is that the delivery of retinoic acid to gonocytes or spermatogonia is sufficient to push these cells into the differentiation pathway. This hypothesis suggests a mechanism for entry into meiosis and thus predicts how the cycle of the seminiferous epithelium can be generated and regulated. This research project could potentially determine the molecular mechanisms that initiate spermatogenesis in the male germline and determine the role of the Sertoli cells in that process. Results from these studies could lead to new fundamental approaches to problems relating to male infertility and contraception. ? ? This research project could potentially determine the molecular mechanisms that initiate spermatogenesis in the male germline and determine the role of the Sertoli cells in that process. Results from these studies could lead to new fundamental approaches to problems relating to male infertility and contraception. ? ? ?

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
Eunice Kennedy Shriver National Institute of Child Health & Human Development (NICHD)
Type
Research Project (R01)
Project #
2R01HD010808-30A1
Application #
7370914
Study Section
Cellular, Molecular and Integrative Reproduction Study Section (CMIR)
Program Officer
Taymans, Susan
Project Start
1977-08-01
Project End
2013-02-28
Budget Start
2008-03-15
Budget End
2009-02-28
Support Year
30
Fiscal Year
2008
Total Cost
$299,000
Indirect Cost

  Institution

Name
Washington State University
Department
Biology
Type
Schools of Arts and Sciences
DUNS #
041485301
City
Pullman
State
WA
Country
United States
Zip Code
99164

  Publications

Jauregui, Estela J; Mitchell, Debra; Topping, Traci et al. (2018) Retinoic acid receptor signaling is necessary in steroidogenic cells for normal spermatogenesis and epididymal function. Development 145:
Griswold, Michael D; Hogarth, Cathryn (2018) Beyond stem cells: Commitment of progenitor cells to meiosis. Stem Cell Res 27:169-171
Agrimson, Kellie S; Oatley, Melissa J; Mitchell, Debra et al. (2017) Retinoic acid deficiency leads to an increase in spermatogonial stem number in the neonatal mouse testis, but excess retinoic acid results in no change. Dev Biol 432:229-236
Griswold, Michael D (2016) Spermatogenesis: The Commitment to Meiosis. Physiol Rev 96:1-17
Agrimson, Kellie S; Onken, Jennifer; Mitchell, Debra et al. (2016) Characterizing the Spermatogonial Response to Retinoic Acid During the Onset of Spermatogenesis and Following Synchronization in the Neonatal Mouse Testis. Biol Reprod 95:81
Chen, Yao; Ma, Li; Hogarth, Cathryn et al. (2016) Retinoid signaling controls spermatogonial differentiation by regulating expression of replication-dependent core histone genes. Development 143:1502-11
Kent, Travis; Arnold, Samuel L; Fasnacht, Rachael et al. (2016) ALDH Enzyme Expression Is Independent of the Spermatogenic Cycle, and Their Inhibition Causes Misregulation of Murine Spermatogenic Processes. Biol Reprod 94:12
Arnold, Samuel L M; Kent, Travis; Hogarth, Cathryn A et al. (2015) Pharmacological inhibition of ALDH1A in mice decreases all-trans retinoic acid concentrations in a tissue specific manner. Biochem Pharmacol 95:177-92
Hogarth, Cathryn A; Evans, Elizabeth; Onken, Jennifer et al. (2015) CYP26 Enzymes Are Necessary Within the Postnatal Seminiferous Epithelium for Normal Murine Spermatogenesis. Biol Reprod 93:19
Arnold, Samuel L; Kent, Travis; Hogarth, Cathryn A et al. (2015) Importance of ALDH1A enzymes in determining human testicular retinoic acid concentrations. J Lipid Res 56:342-57

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