Molecular specification and patterning of progenitor cells in the lateral and medial ganglionic eminences.

We characterized intrinsic and extrinsic specification of progenitors in the lateral and medial ganglionic eminences (LGE and MGE). We identified seven genes whose expression is enriched or restricted in either the LGE [biregional cell adhesion molecule-related/downregulated by oncogenes binding protein (Boc), Frizzled homolog 8 (Fzd8), Ankrd43 (ankyrin repeat domain-containing protein 43), and Ikzf1 (Ikaros family zinc finger 1)] or MGE [Map3k12 binding inhibitory protein 1 (Mbip); zinc-finger, SWIM domain containing 5 (Zswim5); and Adamts5 [a disintegrin-like and metallopeptidase (reprolysin type) with thrombospondin type 1 motif, 5]]. Boc, Fzd8, Mbip, and Zswim5 are apparently expressed in LGE or MGE progenitors, whereas the remaining three are seen in the postmitotic mantle zone. Relative expression levels are altered and regional distinctions are lost for each gene in LGE or MGE cells propagated as neurospheres, indicating that these newly identified molecular characteristics of LGE or MGE progenitors depend on forebrain signals not available in the neurosphere assay. Analyses of Pax6(Sey/Sey), Shh(-/-), and Gli3(XtJ/XtJ) mutants suggests that LGE and MGE progenitor identity does not rely exclusively on previously established forebrain-intrinsic patterning mechanisms. Among a limited number of additional potential patterning mechanisms, we found that extrinsic signals from the frontonasal mesenchyme are essential for Shh- and Fgf8-dependent regulation of LGE and MGE genes. Thus, extrinsic and intrinsic forebrain patterning mechanisms cooperate to establish LGE and MGE progenitor identity, and presumably their capacities to generate distinct classes of neuronal progeny.

Identification of the mglA gene product in the beta-methylgalactoside transport system of Escherichia coli using plasmid DNA deletions generated in vitro.

Three genes (mglA, mglB, and mglC) required for active transport of substrate by the methylgalactoside permease were identified in a hybrid ColE1-DNA plasmid isolated from a clone (pLC3-14) of the Clarke-Carbon bank of Escherichia coli genes. A 4.6-kilobase DNA fragment obtained from pLC3-14 was cloned into the plasmid vector pBR322. The presence of the three mgl genes in the resultant plasmid, pMG3, was verified by genetic complementation and biochemical analysis of mgl mutants transformed with pMG3 DNA. Derivatives of pMG3 containing deletions in each mgl gene were constructed; restriction endonuclease mapping and functional analysis of these plasmids allowed us to physically locate the mgl genes within the inserted plasmid DNA and also to identify a heretofore unknown protein component of the transport system. Expression of these plasmids in vivo resulted in the specific synthesis of three major proteins of apparent molecular weight of 19,000, 36,000, and 52,000. The 36,000-dalton protein is the galactose-binding protein previously identified as the mglB product. The 19,000-dalton protein maybe the product of mglD, a regulatory gene mapping outside of the mgl gene cluster. The 52,000-dalton protein is a new permease component which we have identified here as the mglA product based on the observation that pMG6, a plasmid with a 0.6-kilobase mglA deletion, failed to encode for this protein but produced a truncated polypeptide showing a reduction in molecular weight comparable to the extent of the deletion. In bacteria bearing an mglA+, B-, C+ plasmid (Pmg4), the 52,000-dalton protein is located to a large extent (73%) in the membrane fraction.