Sp1-mediated transcription regulation of TAF-Ialpha gene encoding a histone chaperone

TAF-I, one of histone chaperones, consists of two subtypes, TAF-Iα and TAF-Iβ. The histone chaperone activity of TAF-I is regulated by dimer patterns of these subtypes. TAF-Iβ is expressed ubiquitously, while the expression level of TAF-Iα with less activity than TAF-Iβ differs among cell types. It is, therefore, assumed that the expression level of TAF-Iα in a cell is important for the TAF-I activity level. Here, we found that TAF-Iα and TAF-Iβ genes are under the control of distinct promoters. Reporter assays and gel shift assays demonstrated that Sp1 binds to three regions in the TAF-Iα promoter and two or all mutaions of the three Sp1 binding regions reduced the TAF-Iα promoter activity. ChIP assays demonstrated that Sp1 binds to the TAF-Iα promoter in vivo. Furthermore, the expression level of TAF-Iα mRNA was reduced by knockdown of Sp1 using siRNA method. These studies indicated that the TAF-Iα promoter is under the control of Sp1.     

Structural similarity between histone chaperone Cia1p/Asf1p and DNA-binding protein NF-kappaB

The structural relationships between histone-binding proteins and DNA-binding proteins are important, since nucleosome-interacting factors possess histone-binding and/or DNA-binding components. S. cerevisiae (Sc) Cia1p/Asf1p, a homologue of human CIA (CCG1-interacting factor A), is the most evolutionarily conserved histone chaperone, which facilitates nucleosome assembly by interacting with the nucleosome entry site of the core histones H3/H4. The crystal structure of the evolutionarily conserved domain (residues 1-169) of Cia1p (ScCia1p-DeltaC2) was determined at 2.95 A resolution. The refined model contains 166 residues in the asymmetric unit. The overall tertiary structure resembles a beta-sandwich fold, and belongs to the "switched" immunoglobulin class of proteins. The crystal structure suggests that ScCia1p-DeltaC2 is structurally related to the DNA-binding proteins, such as NF-kappaB and its family members. This is the first examination of the structural similarities between a histone chaperone and DNA-binding proteins. We discuss the possibilities that the strands beta3 and beta4, which possess highly electronegative surface potentials, are the important regions for the interaction with core histones, and that the histone chaperone ScCia1p/Asf1p and the DNA-binding protein NF-kappaB may have evolved from the same prototypal protein class.