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.     

Lune/eye gone, a Pax-like protein, uses a partial paired domain and a homeodomain for DNA recognition

Pax proteins, characterized by the presence of a paired domain, play key regulatory roles during development. The paired domain is a bipartite DNA-binding domain that contains two helix-turn-helix domains joined by a linker region. Each of the subdomains, the PAI and RED domains, has been shown to be a distinct DNA-binding domain. The PAI domain is the most critical, but in specific circumstances, the RED domain is involved in DNA recognition. We describe a Pax protein, originally called Lune, that is the product of the Drosophila eye gone gene (eyg). It is unique among Pax proteins, because it contains only the RED domain. eyg seems to play a role both in the organogenesis of the salivary gland during embryogenesis and in the development of the eye. A high-affinity binding site for the Eyg RED domain was identified by using systematic evolution of ligands by exponential enrichment techniques. This binding site is related to a binding site previously identified for the RED domain of the Pax-6 5a isoform. Eyg also contains another DNA-binding domain, a Prd-class homeodomain (HD), whose palindromic binding site is similar to other Prd-class HDs. The ability of Pax proteins to use the PAI, RED, and HD, or combinations thereof, may be one mechanism that allows them to be used at different stages of development to regulate various developmental processes through the activation of specific target genes.     

Reciprocal effect of Waardenburg syndrome mutations on DNA binding by the Pax-3 paired domain and homeodomain

The Pax-3 protein contains two DNA-binding domains, a paired domain and a homeodomain. Mutations in Pax-3 cause Waardenburg syndrome (WS) in humans and the mouse Splotch (Sp) phenotype. In the Sp-delayed mouse, a mutation in the Pax-3 paired domain (G9R) abrogates the DNA-binding activity of both the paired domain and the homeodomain, suggesting that they may functionally interact. To investigate this possibility further, we have analyzed the DNA-binding properties of additional point mutants in the Pax-3 paired domain and homeodomain that occur in WS patients (F12L, N14H, G15S, P17L, R23L, G48A, S51F and G66D in the paired domain, V47F and R53G in the homeodomain), the Pax-1 un mutation (G15A) and a substitution associated with Peters' anomaly in the PAX-6 gene (R23G). Within the paired domain, seven of 10 mutations were found to abrogate DNA-binding by the paired domain. Remarkably, these seven mutations also affected DNA binding by the homeodomain, causing either a complete loss (P17L and G66D), a reduction (R23G, R23L, G15S and G15A) or an increase in DNA-binding activity (N14H). In addition, the effect of paired domain mutations occurred at the level of monomer formation by the homeodomain, while the dimerization potential of this domain seemed unaffected in mutants where it could be analyzed. Furthermore, while both homeodomain mutations were found to abolish DNA binding by this domain, the R53G mutation also abrogated DNA binding by the paired domain. The important observation that independent mutations in either domain can affect DNA binding by the other in the intact Pax-3 protein strongly suggests that the two domains are not functionally independent but bind DNA through cooperative interactions. Modeling the deleterlous mutations on the three-dimensional structure of the paired domain of Drosophila Prd shows that these mutations cluster at the DNA interface, thus suggesting that a series of DNA contacts are essential for DNA binding by both the paired domain and the homeodomain of Pax-3.     

The C-terminal subdomain makes an important contribution to the DNA binding activity of the Pax-3 paired domain

The recognition of DNA targets by Pax-3 is achieved through the coordinate use of two distinct helix-turn-helix-based DNA-binding modules: a paired domain, composed of two structurally independent subdomains joined by a short linker, and a paired-type homeodomain. In mouse, the activity of the Pax-3 paired domain is modulated by an alternative splicing event in the paired domain linker region that generates isoforms (Q+ and Q-) with distinct C-terminal subdomain-mediated DNA-binding properties. In this study, we have used derivatives of a classical high affinity paired domain binding site (CD19-2/A) to derive an improved consensus recognition sequence for the Pax-3 C-terminal subdomain. This new consensus differs at six out of eight positions from the C-terminal subdomain recognition motif present in the parent CD19-2/A sequence, and includes a 5'-TT-3' dinucleotide at base pairs 15 and 16 that promotes high affinity binding by both Pax-3 isoforms. However, with a less favorable guanine at position 15, only the Q- isoform retains high affinity binding to this sequence, suggesting that this alternative splicing event might serve to stabilize binding to suboptimal recognition sequences. Finally, mutagenic analysis of the linker demonstrates that both the sequence and the spacing in this region contribute to the enhanced DNA-binding properties of the Pax-3/Q- isoform. Altogether, our studies establish a clear role for the Pax-3 C-terminal subdomain in DNA recognition and, thus, provide insights into an important mechanism by which Pax proteins achieve distinct target specificities.     

Isolation of a Drosophila homolog of the vertebrate homeobox gene Rx and its possible role in brain and eye development

Vertebrate and invertebrate eye development require the activity of several evolutionarily conserved genes. Among these the Pax-6 genes play a major role in the genetic control of eye development. Mutations in Pax-6 genes affect eye development in humans, mice, and Drosophila, and misexpression of Pax-6 genes in Drosophila can induce ectopic eyes. Here we report the identification of a paired-like homeobox gene, DRx, which is also conserved from flies to vertebrates. Highly conserved domains in the Drosophila protein are the octapeptide, the identical homeodomain, the carboxyl-terminal OAR domain, and a newly identified Rx domain. DRx is expressed in the embryo in the procephalic region and in the clypeolabrum from stage 8 on and later in the brain and the central nervous system. Compared with eyeless, the DRx expression in the embryo starts earlier, similar to the pattern in vertebrates, where Rx expression precedes Pax-6 expression. Because the vertebrate Rx genes have a function during brain and eye development, it was proposed that DRx has a similar function. The DRx expression pattern argues for a conserved function at least during brain development, but we could not detect any expression in the embryonic eye primordia or in the larval eye imaginal discs. Therefore DRx could be considered as a homolog of vertebrate Rx genes. The Rx genes might be involved in brain patterning processes and specify eye fields in different phyla.     

A conserved TN8TCCT motif in the octapeptide-encoding region of Pax genes which has the potential to direct cytosine methylation

Our previous findings have shown that the developmental genes Pax7 and Pax3 are differentially methylated; the gene region that encodes the paired domain is hypomethylated, whereas the region that encodes the homeodomain is hypermethylated. For this reason, the known DNA sequence between the paired and homeoboxes was analysed for the presence of a conserved DNA motif to which a modifying protein could bind in order to direct the methylation or demethylation of surrounding gene sequences. The octapeptide-encoding region was found to contain several nucleotides that were highly conserved throughout the Pax gene family from phylogenetically distant species. The most conserved nucleotides are thought to comprise a motif TN8TCCT where N8=any combination of eight nucleotides. A conserved octapeptide-like-encoding sequence containing the TN8TCCT motif was also found in non-Pax genes of higher eukaryotes and in the non-coding strand of plants. Moreover, differential methylation seems to be associated with the presence of the TN8TCCT motif in p53 and the human oestrogen receptor genes. The presence of the TN8TCCT motif within an octapeptide-like-encoding sequence in human T-cell leukaemia virus type 1 might suggest that the putative recognition motif may have been introduced into various host genomes via some form of retroviral agent.     

The zebrafish Pax3 and Pax7 homologues are highly conserved, encode multiple isoforms and show dynamic segment-like expression in the developing brain

This study describes the isolation and characterization of zebrafish homologues of the mammalian Pax3 and Pax7 genes. The proteins encoded by both zebrafish genes are highly conserved (>83%) relative to the known mammalian sequences. Also the neural expression patterns during embryogenesis are very similar to the murine homologues. However, observed differences in neural crest and mesodermal expression relative to mammals could reflect some functional divergence in the development of these tissues. For the zebrafish Pax7 protein we report the first full-length amino acid sequences in vertebrates and show the existence of three additional isoforms which have truncations in the homeodomain and/or the C-terminal region. These novel variants provide evidence for additional isoform diversity of vertebrate Pax proteins.     

Helix 2 of the paired domain plays a key role in the regulation of DNA-binding by the Pax-3 homeodomain

Pax3 contains two structurally independent DNA-binding domains, a paired domain (PD) and a homeodomain (HD). Biochemical and mutagenesis studies have shown that both domains are functionally interdependent. In particular, it has been shown that the PD can regulate the DNA-binding specificity and dimerization potential of the HD. To delineate Pax3 protein segments that are involved in the regulation of HD DNA-binding, a series of chimeric proteins were created in which the HD and linker region were gradually replaced with corresponding sequences from a heterologous HD protein, Phox. Characterization of chimeric proteins by electrophoretic mobility shift analysis (EMSA) suggests that a portion of the linker region contributes to the functional interaction between the PD and HD. In addition, stepwise removal of sequences from the Pax3 PD was used to define regions within this domain that are involved in the regulation of HD DNA-binding. EMSA of these proteins in the context of the chimeric Pax3/Phox backbone provided two key findings: (i) the C-terminal subdomain of the PD does not play a major role in the regulation of HD DNA-binding and (ii) the N-terminal subdomain and, in particular, the second alpha-helix are essential for modulation of HD DNA-binding. Significantly, deletion of helix 2 was found to be sufficient to uncouple regulation of HD DNA-binding by the PD.