Activation of Class I transcription factors by low level Sonic hedgehog signaling is mediated by Gli2-dependent and independent mechanisms.

The partitioning of the ventral neural tube into five distinct neuronal progenitor domains is dependent on the morphogenic action of the secreted protein Sonic hedgehog (Shh). The prevailing model stipulates that Class I genes are repressed and Class II genes are activated by high levels of Shh signaling and that sharp progenitor domain boundaries are established by the mutual repression of complementary pairs of Class I and Class II transcription factors. While core elements of this model are supported by experimental evidence, a number of issues remain unresolved. Foremost of these is a more thorough understanding of the mechanism by which Class I genes are regulated. In this study, we describe the consequences of Shh misexpression on Class I and Class II gene expression in the hindbrain of ShhP1 embryos. We observed that an ectopic source of Shh in the otic vesicle of ShhP1 embryos ventralized the adjacent hindbrain by inducing, rather than repressing, the expression of several Class I genes (Pax6, Dbx1, Dbx2). The Shh dependent activation of Class I genes was mediated, in part, by Gli2. These results bear significance on the model of ventral neural tube patterning as they suggest a dual role for Shh in the regulation of Class I genes, whereby low levels of Shh signaling initiate Class I gene transcription, while higher levels restrict the domains of Class I gene expression to intermediate positions of the neural tube through the activation of Class II transcriptional regulators.

Structure of Escherichia coli aminodeoxychorismate synthase: architectural conservation and diversity in chorismate-utilizing enzymes.

Aminodeoxychorismate synthase is part of a heterodimeric complex that catalyzes the two-step biosynthesis of 4-amino-4-deoxychorismate, a precursor of p-aminobenzoate and folate in microorganisms. In the first step, a glutamine amidotransferase encoded by the pabA gene generates ammonia as a substrate that, along with chorismate, is used in the second step, catalyzed by aminodeoxychorismate synthase, the product of the pabB gene. Here we report the X-ray crystal structure of Escherichia coli PabB determined in two different crystal forms, each at 2.0 A resolution. The 453-residue monomeric PabB has a complex alpha/beta fold which is similar to that seen in the structures of homologous, oligomeric TrpE subunits of several anthranilate synthases of microbial origin. A comparison of the structures of these two classes of chorismate-utilizing enzymes provides a rationale for the differences in quaternary structures seen for these enzymes, and indicates that the weak or transient association of PabB with PabA during catalysis stems at least partly from a limited interface for protein interactions. Additional analyses of the structures enabled the tentative identification of the active site of PabB, which contains a number of residues implicated from previous biochemical and genetic studies to be essential for activity. Differences in the structures determined from phosphate- and formate-grown crystals, and the location of an adventitious formate ion, suggest that conformational changes in loop regions adjacent to the active site may be needed for catalysis. A surprising finding in the structure of PabB was the presence of a tryptophan molecule deeply embedded in a binding pocket that is analogous to the regulatory site in the TrpE subunits of the anthranilate synthases. The strongly bound ligand, which cannot be dissociated without denaturation of PabB, may play a structural role in the enzyme since there is no effect of tryptophan on the enzymic synthesis of aminodeoxychorismate. Extensive sequence similarity in the tryptophan-binding pocket among several other chorismate-utilizing enzymes, including isochorismate synthase, suggests that they too may bind tryptophan for structural integrity, and corroborates early ideas on the evolution of this interesting enzyme family.