Genetic transcription

There are approximately 20,000 genes in the human genome. Around 2% of these genes code for transcriptional repressors known as KRAB-ZFPs. It is already known that Zinc-Finger Proteins contain two main functional domains at either end of the polypeptide. In today's database, you will find a KRAB (Kruppell-associated Box) domain at one end and a tandem array of Zinc-finger repeats at the other end. The carboxyl terminal tandem Zinc-finger repeats function as sequence-specific DNA-binding domains. The amino terminal KRAB domain serves as a repressor domain, which will recruit a co-repressor termed KAP-1 (KRAB Associated Protein-1). Located in between these two domains is a region of uncharacterized DNA referred to as the "Linker Region". This thesis will explore the DNA-binding domains of 6 known KRAB-ZFPs, as well as utilize the linker regions to derive an evolutionary history for this superfamily.

Transcription factors are macromolecules that are involved in transcriptional regulation by interacting with specific DNA regions, and they can cause activation or silencing of their target genes. Gene regulation by transcriptional control explains different biological processes such as development, function, and disease. Even though transcriptional control has been of great interest for molecular biology, much still remains unknown. This study was designed to generate the most current list of human transcription factor genes. Unique entries of transcription factor genes were collected and entered into Microsoft Office 2007 Access Database along with information about each gene. Microsoft Office 2007 Access tools were used to analyze and group collected entries according to different properties such as activator or repressor record, or presence of certain protein domains. Furthermore, protein sequence alignments of members of different groups were performed, and phylogenetic trees were used to analyze relationship between different members of each group. This work contributes to the existing knowledge of transcriptional regulation in humans.

The zinc finger associated domain (ZAD) containing family of transcription factors is not well described in the literature, in part because it is very difficult to study by mutagenesis. We used in vitro-binding techniques to identify characteristics of the ZAD family, by constructing glutathione Stransferase (GST)-ZAD domain chimeric proteins for use in protein binding assays, and GST-Zinc finger array domain chimera for binding site selections. Protein binding assays indicated a possible shared cofactor, as seen in the analogous KRAB system in mammals. DNA binding assays have provided a consensus binding sequence for five of the ZAD proteins, consistent with previously reported work on ZAD and unpublished work on mammalian transcription factors. Research is ongoing with an additional ~50 ZAD proteins to more fully map the binding characters of ZAD proteins.

Transcriptional regulation is an important area of research due to the fact that it leads to gene expression. Transcription factors associated with the regulation can either be activators or repressors of target genes, acting directly or with the aid of other factors. A majority of transcriptional repressors are zinc finger proteins (ZFPs) which bind to specific DNA sequences. The Snail/Gfi (SNAG) domain family, with members such as Slug, Smuc, Snail, and Scratch, are transcriptional repressors shown to play a role in various diseases such as cancer. The SNAG transcription factors contain a conserved SNAG repression domain and DNA binding domain zinc fingers. The specific DNA sequences to which each SNAG-ZFP binds, as well as a general consensus -TGCACCTGTCCGA, have been determined. Also, putative protein-protein interactions in which the Slug domain participates has been identified via binding assays. All these results contribute to better understanding of SNAG-ZFP functions.