About Me: My name is Maura Newhouse. I am a second semester senior here at Miami University, and I am from Youngstown, Ohio. I have a major in Biology and co-major in Premedical Studies, along with three minors in neuroscience, medical humanities, and medical sociology. After my graduation in May of 2026, I will be Attedning Medical School. I became interested in genetics in my sophomore year of high school, and it was the reason I committed to being a biology major.
Transcription factors (TFs) are regulatory proteins that control gene expression by binding to specific DNA sequences and influencing transcription. One area of development TF become increasingly important is cranial placodes. During early development, cranial placodes arise from a shared region of multipotent surface ectoderm. For example, both the lens placode and olfactory placode originate from this common surface ectoderm tissue before differentiating into distinct cell types. In the lens, FOXE3 is a forkhead transcription factor that is specifically expressed in the lens, a non nerual tissue, where it regulates cell proliferation and differentiation. In contrast, the olfactory placode gives rise to both neural and non-neural tissues but does not naturally express FOXE3. To study gene function in this system, the RCAS method, an avian specific retrovirus-based approach, can be used to deliver genes into cells to be incorporated into the host genome and subsequently expressed.
This project explores the role of FOXE3 in eye development, focusing on its potential influence on cell fate decisions. Key questions include: What is the role of FOXE3 in determining cell fate during eye development? Does FOXE3 suppress neural differentiation pathways?
The rationale for this project is based on evidence from FOXE3 null mice, which showed increased expression of neural genes and decreased expression of epithelial markers compared to wild type. This may suggest that FOXE3 may normally function to maintain epithelial identity and suppress neural gene programs during development. However, FOXE3 is not endogenously expressed in all ectoderm-derived tissues, such as the olfactory placode, raising the question of whether it can actively suppress neural development in a tissue where it is normally absent.
To test this, we used the RCAS retroviral system to introduce FOXE3 into early embryonic tissue. Embryos were injected at stage 10, when the surface ectoderm has not yet fully differentiated into distinct structures such as the lens and olfactory placodes. This timing allows FOXE3 to be expressed prior to lineage commitment. Tissues were then harvested at embryonic day 4 (E4), a developmental stage when early neurogenesis is occurring.
Abbreviations:
LTR: Long Terminal Repeat
FLAG: Flag Epitope Tag
hFOXE3: Human FOXE3
T2A: Viral Self cleaving peptide
GFP: Green Fluorescent Protein
Whole Mount E3 Immunofluorescence for A. No primary antibody, B. PAX6, C. ASCL1, D. SOX10 and E. TUBB3. The location of the eye is indicated.
PAX6: Neuronal + Nonneural Nuclei
ASCL1: Neuronal Nuclei
SOX10: Neuronal Nuclei
TUBB3: Neuronal Cytoplasm
A.H&E staining of E4 control group chicken embryo B. H&E staining of E4 chicken embryo injected with RCAS-GFP virus C. H&E staining of E4 chicken embryo injected with RCAS-FOXE3-GFP
Successful FOXE3T2AGFP insertion into RCAS virus shown by restriction digest and DF1 transfection.
RCAS-FOXE3-GFP injections do not show gross morphological differences compared to RCAS- GFP injected embryos or control samples.
Future studies will further refine the temporal and cellular characterization of FOXE3 function during development. Analysis of embryos at embryonic day 6 (E6) will be important to determine whether the effects observed at earlier stages persist into later phases of neurogenesis or instead reflect transient developmental changes. In parallel, antibody staining approaches will be repeated and optimized to improve the identification of post-mitotic neuronal populations, allowing for a more precise assessment of neuronal differentiation. Quantitative analysis of neuronal and non-neuronal cell populations within the olfactory epithelium will also be performed to assess potential shifts in tissue composition that may not be evident through morphological evaluation alone. Additionally, refinement of viral delivery methods will be necessary to ensure more consistent and efficient RCAS-mediated expression, thereby improving experimental reproducibility across samples.
Career and self-development: by pushing me to set independent goals and reflect on setbacks
Communication skills: through presenting findings, discussing troubleshooting strategies with peers, and translating my work and literature findings into my Honors Thesis
Professionalism: by requiring consistent time management and accountability for experimental outcomes.
Thank you to KDRT Lab & Nour Sayed
Funding NIH R21 EY031092 Grant