The long range objective of this research is an understanding of the biochemical mechanisms that operate and regulate the expression of human genes during growth and differentiation. The human epidermis has been chosen as a model system, since we are able to serially cultivate these cells in vitro under conditions where many of the differentiative properties, including stratification are retained. The major differentiation-specific proteins in these cells are the keratins, a group of closely related proteins of MW 40-70 K daltons that form 80 Angstrom cytoskeletal filaments. Only a subset of these keratins are ever expressed by an epidermal cell at any one time. During the course of differentiation, this subset changes concomitantly with an increase in keratin synthesis, leaving the fully differentiated epidermal cell with 85% of its total protein as keratins. We already know that early changes in the differentiation involve changes in mRNAs whereas late changes involve proteolytic processing. Recently, we isolated near full-length cDNA clones to the different epidermal keratins mRNAs and we showed that there are two distinct classes of keratins. We would now like to determine the nucleic acid sequence of these cDNAs. Since no amino acid sequence data is available, the amino acid sequence predicted from the cDNA sequence will be essential in determining the structural and functional relationship between these two classes of keratins. We will also isolate and characterize genomic clones for the keratins. This will aid us in determining the complexity and chromosomal organization of the keratin genes. We will then prepare subclones of these sequences to probe posttranscriptional regulation of keratin gene expression. Finally, epidermal cells from patients with genetic skin diseases are currently being cultured and alterations in the regulation and expression of the keratins and other differentiation-specific proteins in these cells will be investigated.

Agency
National Institute of Health (NIH)
Institute
National Institute of Arthritis and Musculoskeletal and Skin Diseases (NIAMS)
Type
Research Project (R01)
Project #
5R01AR027883-07
Application #
3155576
Study Section
Physiological Chemistry Study Section (PC)
Project Start
1980-12-01
Project End
1988-11-30
Budget Start
1986-12-01
Budget End
1987-11-30
Support Year
7
Fiscal Year
1987
Total Cost
Indirect Cost
Name
University of Chicago
Department
Type
Schools of Medicine
DUNS #
225410919
City
Chicago
State
IL
Country
United States
Zip Code
60637
Ge, Yejing; Gomez, Nicholas C; Adam, Rene C et al. (2017) Stem Cell Lineage Infidelity Drives Wound Repair and Cancer. Cell 169:636-650.e14
Gonzales, Kevin Andrew Uy; Fuchs, Elaine (2017) Skin and Its Regenerative Powers: An Alliance between Stem Cells and Their Niche. Dev Cell 43:387-401
Yang, Hanseul; Adam, Rene C; Ge, Yejing et al. (2017) Epithelial-Mesenchymal Micro-niches Govern Stem Cell Lineage Choices. Cell 169:483-496.e13
Ouspenskaia, Tamara; Matos, Irina; Mertz, Aaron F et al. (2016) WNT-SHH Antagonism Specifies and Expands Stem Cells prior to Niche Formation. Cell 164:156-169
Heller, Evan; Fuchs, Elaine (2015) Tissue patterning and cellular mechanics. J Cell Biol 211:219-31
Kulukian, Anita; Holland, Andrew J; Vitre, Benjamin et al. (2015) Epidermal development, growth control, and homeostasis in the face of centrosome amplification. Proc Natl Acad Sci U S A 112:E6311-20
Luxenburg, Chen; Heller, Evan; Pasolli, H Amalia et al. (2015) Wdr1-mediated cell shape dynamics and cortical tension are essential for epidermal planar cell polarity. Nat Cell Biol 17:592-604
Heller, Evan; Kumar, K Vijay; Grill, Stephan W et al. (2014) Forces generated by cell intercalation tow epidermal sheets in mammalian tissue morphogenesis. Dev Cell 28:617-32
Williams, Scott E; Fuchs, Elaine (2013) Oriented divisions, fate decisions. Curr Opin Cell Biol 25:749-58
Beronja, Slobodan; Fuchs, Elaine (2013) RNAi-mediated gene function analysis in skin. Methods Mol Biol 961:351-61

Showing the most recent 10 out of 84 publications