Pax-3-DNA interaction: flexibility in the DNA binding and induction of DNA conformational changes by paired domains.

The mouse Pax-3 gene encodes a protein that is a member of the Pax family of DNA binding proteins. Pax-3 contains two DNA binding domains: a paired domain (PD) and a paired type homeodomain (HD). Both domains are separated by 53 amino acids and interact synergistically with a sequence harboring an ATTA motif (binding to the HD) and a GTTCC site (binding to the PD) separated by 5 base pairs. Here we show that the interaction of Pax-3 with these two binding sites is independent of their angular orientation. In addition, the protein spacer region between the HD and the PD can be shortened without changing the spatial flexibility of the two DNA binding domains which interact with DNA. Furthermore, by using circular permutation analysis we determined that binding of Pax-3 to a DNA fragment containing a specific binding site causes conformational changes in the DNA, as indicated by the different mobilities of the Pax-3-DNA complexes. The ability to change the conformation of the DNA was found to be an intrinsic property of the Pax-3 PD and of all Pax proteins that we tested so far. These in vitro studies suggest that interaction of Pax proteins with their specific sequences in vivo may result in an altered DNA conformation.     

Telomere end-binding proteins control the formation of G-quadruplex DNA structures in vivo

Telomere end-binding proteins (TEBPs) bind to the guanine-rich overhang (G-overhang) of telomeres. Although the DNA binding properties of TEBPs have been investigated in vitro, little is known about their functions in vivo. Here we use RNA interference to explore in vivo functions of two ciliate TEBPs, TEBPalpha and TEBPbeta. Silencing the expression of genes encoding both TEBPs shows that they cooperate to control the formation of an antiparallel guanine quadruplex (G-quadruplex) DNA structure at telomeres in vivo. This function seems to depend on the role of TEBPalpha in attaching telomeres in the nucleus and in recruiting TEBPbeta to these sites. In vitro DNA binding and footprinting studies confirm the in vivo observations and highlight the role of the C terminus of TEBPbeta in G-quadruplex formation. We have also found that G-quadruplex formation in vivo is regulated by the cell cycle-dependent phosphorylation of TEBPbeta.     

Highly conserved amino acids in Pax and Ets proteins are required for DNA binding and ternary complex assembly

Combinatorial association of DNA-binding proteins on composite binding sites enhances their nucleotide sequence specificity and functional synergy. As a paradigm for these interactions, Pax-5 (BSAP) assembles ternary complexes with Ets proteins on the B cell-specific mb-1 promoter through interactions between their respective DNA-binding domains. Pax-5 recruits Ets-1 to bind the promoter, but not the closely related Ets protein SAP1a. Here we show that, while several different mutations increase binding of SAP1a to an optimized Ets binding site, only conversion of Val68 to an acidic amino acid facilitates ternary complex assembly with Pax-5 on the mb-1 promoter. This suggests that enhanced DNA binding by SAP1a is not sufficient for recruitment by Pax-5, but instead involves protein–protein interactions mediated by the acidic side chain. Recruitment of Ets proteins by Pax-5 requires Gln22 within the N-terminal β-hairpin motif of its paired domain. The β-hairpin also participates in recognition of a subset of Pax-5-binding sites. Thus, Pax-5 incorporates protein–protein interaction and DNA recognition functions in a single motif. The Caenorhabditis elegans Pax protein EGL-38 also binds specifically to the mb-1 promoter and recruits murine Ets-1 or the C.elegans Ets protein T08H4.3, but not the related LIN-1 protein. Together, our results define specific amino acid requirements for Pax–Ets ternary complex assembly and show that the mechanism is conserved between evolutionarily related proteins of diverse animal species. Moreover, the data suggest that interactions between Pax and Ets proteins are an important mechanism that regulates fundamental biological processes in worms and humans.     

DNA binding by the KP repressor protein inhibits P-element transposase activity in vitro.

P elements are a family of mobile DNA elements found in Drosophila. P-element transposition is tightly regulated, and P-element-encoded repressor proteins are responsible for inhibiting transposition in vivo. To investigate the molecular mechanisms by which one of these repressors, the KP protein, inhibits transposition, a variety of mutant KP proteins were prepared and tested for their biochemical activities. The repressor activities of the wild-type and mutant KP proteins were tested in vitro using several different assays for P-element transposase activity. These studies indicate that the site-specific DNA-binding activity of the KP protein is essential for repressing transposase activity. The DNA-binding domain of the KP repressor protein is also shared with the transposase protein and resides in the N-terminal 88 amino acids. Within this region, there is a C2HC putative metal-binding motif that is required for site-specific DNA binding. In vitro the KP protein inhibits transposition by competing with the transposase enzyme for DNA-binding sites near the P-element termini.     

Evolution of regulatory elements producing a conserved gene expression pattern in Caenorhabditis

Natural selection acts at the level of function, not at the logistical level of how organisms achieve a particular function. Consequently, significant DNA sequence and regulatory differences can achieve the same function, such as a particular gene expression pattern. To investigate how regulatory features underlying a conserved function can evolve, we compared the regulation of a conserved gene expression pattern in the related species Caenorhabditis elegans and C. briggsae. We find that both C. elegans and C. briggsae express the ovo-related zinc finger gene lin-48 in the same pattern in hindgut cells. However, the regulation of this gene by the Pax-2/5/8 protein EGL-38 differs in two important ways. First, specific differences in the regulatory sequences of lin-48 result in the presence of two redundant EGL-38 response elements in C. elegans, whereas the redundancy is absent in C. briggsae. Second, there is a single egl-38 gene in C. briggsae. In contrast, the gene is duplicated in C. elegans, with only one copy retaining the ability to regulate lin-48 in vivo. These results illustrate molecular changes that can occur despite maintenance of conserved gene function in different species.     

Protein/DNA interactions involving ATF/AP1-, CCAAT-, and HiNF-D-related factors in the human H3-ST519 histone promoter: cross-competition with transcription regulatory sites in cell cycle controlled H4 and H1 histone genes.

Protein/DNA interactions of the H3-ST519 histone gene promoter were analyzed in vitro. Using several assays for sequence specificity, we established binding sites for ATF/AP1-, CCAAT-, and HiNF-D related DNA binding proteins. These binding sites correlate with two genomic protein/DNA interaction domains previously established for this gene. We show that each of these protein/DNA interactions has a counterpart in other histone genes: H3-ST519 and H4-F0108 histone genes interact with ATF- and HiNF-D related binding activities, whereas H3-ST519 and H1-FNC16 histone genes interact with the same CCAAT-box binding activity. These factors may function in regulatory coupling of the expression of different histone gene classes. We discuss these results within the context of established and putative protein/DNA interaction sites in mammalian histone genes. This model suggests that heterogeneous permutations of protein/DNA interaction elements, which involve both general and cell cycle regulated DNA binding proteins, may govern the cellular competency to express and coordinately control multiple distinct histone genes.     

Identification of amino acids involved in the functional interaction between DnaA protein and acidic phospholipids

DnaA protein, the initiator of chromosomal DNA replication in Escherichia coli, seems to be regulated through its binding to acidic phospholipids, such as cardiolipin. In our previous paper (Hase, M., Yoshimi, T., Ishikawa, Y., Ohba, A., Guo, L., Mima, S., Makise, M., Yamaguchi, Y., Tsuchiya, T., and Mizushima, T. (1998) J. Biol. Chem. 273, 28651-28656), we found that mutant DnaA protein (DnaA431), in which three basic amino acids (Arg(360), Arg(364), and Lys(372)) were mutated to acidic amino acids showed a decreased ability to interact with cardiolipin in vitro, suggesting that DnaA protein binds to cardiolipin through an ionic interaction. In this study, we construct three mutant dnaA genes each with a single mutation and examined the function of the mutant proteins in vitro and in vivo. All mutant proteins maintained activities for DNA replication and ATP binding. A mutant protein in which Lys(372) was mutated to Glu showed the weakest interaction with cardiolipin among these three mutant proteins. Thus, Lys(372) seems to play an important role in the interaction between DnaA protein and acidic phospholipids. Plasmid complementation analyses revealed that all these mutant proteins, including DnaA431 could function as an initiator for chromosomal DNA replication in vivo.