Loss of function of the tuberous sclerosis 2 tumor suppressor gene results in embryonic lethality characterized by disrupted neuroepithelial growth and development.

Germline defects in the tuberous sclerosis 2 (TSC2) tumor suppressor gene predispose humans and rats to benign and malignant lesions in a variety of tissues. The brain is among the most profoundly affected organs in tuberous sclerosis (TSC) patients and is the site of development of the cortical tubers for which the hereditary syndrome is named. A spontaneous germline inactivation of the Tsc2 locus has been described in an animal model, the Eker rat. We report that the homozygous state of this mutation (Tsc2(Ek/Ek)) was lethal in mid-gestation (the equivalent of mouse E9.5-E13.5), when Tsc2 mRNA was highly expressed in embryonic neuroepithelium. During this period homozygous mutant Eker embryos lacking functional Tsc2 gene product, tuberin, displayed dysraphia and papillary overgrowth of the neuroepithelium, indicating that loss of tuberin disrupted the normal development of this tissue. Interestingly, there was significant intraspecies variability in the penetrance of cranial abnormalities in mutant embryos: the Long-Evans strain Tsc2(Ek/Ek) embryos displayed these defects whereas the Fisher 344 homozygous mutant embryos had normal-appearing neuroepithelium. Taken together, our data indicate that the Tsc2 gene participates in normal brain development and suggest the inactivation of this gene may have similar functional consequences in both mature and embryonic brain.

Mouse Brachyury the Second (T2) is a gene next to classical T and a candidate gene for tct.

The mouse Brachyury the Second (T2) gene is 15 kb away from classical Brachyury (T). A mutation in T2 disrupts notochord development, pointing to the existence of a second T/t complex gene involved in axis development. T2 encodes a novel protein that is disrupted by an insertion in T2(Bob) mice. Sequence analysis of T2 from several t haplotypes shows that they all share the same changed stop codon, and, thus, T2 is a candidate gene for the t complex tail interaction factor. T1, T2, and the unlinked t-int are distinct and unrelated loci, and mutations in these genes do not complement one another genetically. Either their products interact in the same pathway during the genesis of the embryonic axis, or the T/t region itself is truly complex.

Zebrafish organizer development and germ-layer formation require nodal-related signals.

The vertebrate body plan is established during gastrulation, when cells move inwards to form the mesodermal and endodermal germ layers. Signals from a region of dorsal mesoderm, which is termed the organizer, pattern the body axis by specifying the fates of neighbouring cells. The organizer is itself induced by earlier signals. Although members of the transforming growth factor-beta (TGF-beta) and Wnt families have been implicated in the formation of the organizer, no endogenous signalling molecule is known to be required for this process. Here we report that the zebrafish squint (sqt) and cyclops (cyc) genes have essential, although partly redundant, functions in organizer development and also in the formation of mesoderm and endoderm. We show that the sqt gene encodes a member of the TGF-beta superfamily that is related to mouse nodal. cyc encodes another nodal-related proteins, which is consistent with our genetic evidence that sqt and cyc have overlapping functions. The sqt gene is expressed in a dorsal region of the blastula that includes the extraembryonic yolk syncytial layer (YSL). The YSL has been implicated as a source of signals that induce organizer development and mesendoderm formation. Misexpression of sqt RNA within the embryo or specifically in the YSL induces expanded or ectopic dorsal mesoderm. These results establish an essential role for nodal-related signals in organizer development and mesendoderm formation.

Is there a Brachyury the Second? Analysis of a transgenic mutation involved in notochord maintenance in mice.

A new phenotype mapping to the t-complex, which is designated Brachyury the Second (T2), is characterized by a slightly shortened tail in heterozygotes and homozygous failure to form an organized notochord with subsequent abnormal development of posterior somites and neural tube. The phenotype of T2 superficially resembles that of Brachyury; however, there are several important differences. Brachyury homozygotes fail to make posterior somites, notochord, floor plate, and a placental connection, resulting in death by 10.5 days of development. In contrast, T2 homozygotes make posterior somites, scattered notochord cells, and floorplate and achieve an allantoic connection. However, despite making a maternal connection, T2 homozygotes cease development at E11.5 and die soon after. We have cloned and analyzed the transgene insertion site, which maps within 100 kb of the Brachyury gene, but does not seem to physically interrupt nor affect transcription from that locus. The existence of a second gene mapping near Brachyury and affecting the same developmental processes was alluded to over 50 years ago and has been debated ever since. An embryological description of T2 is presented, as is a discussion of the implications of a single, larger Brachyury locus versus two closely linked genes coordinately regulating axial development.