Control and function of terminal gap gene activity in the posterior pole region of the Drosophila embryo.

We have studied the genetic requirement for the normal expression of the terminal gap genes huckebein (hkb) and tailless (tll) and their possible function in the posterior pole region of the Drosophila embryo. At the early blastoderm stage, both genes are expressed in largely coextensive expression domains. Our results show that in the posterior region of the embryo both the activation and the control of the spatial limits of tll and hkb expression are critically dependent on torso (tor) activity, which is thought to be a crucial component of a cellular signal transduction pathway provided by the terminal maternal system. Furthermore, the spatial control of hkb and tll expression does not require mutual interactions among each other, nor does it require regulatory input from other gap genes which are essential for the establishment of segmentation in the trunk region of the embryo ("central gap genes"). Therefore, the terminal gap genes have unique regulatory features which are distinct from the central gap genes. In the absence of terminal gap gene activities, as in hkb and tll mutant embryos, the expression domains of the central gap genes expand posteriorly, indicating that the terminal gap gene activities prevent central gap gene expression in the posterior pole region of the wildtype embryo. This, in turn, suggests that the terminal gap gene activities prevent metamerization by repression of central gap genes, thereby distinguishing the segmented trunk from the nonsegmented tail region of the embryo.     

Expression of SV40-lacZ gene in mouse preimplantation embryos after pronuclear microinjection.

In order to study the expression of an exogenous gene in developing mouse embryos during the preimplantation period, DNA carrying the SV40 early promoter fused with the Escherichia coli beta-galactosidase gene (lacZ) was microinjected into the pronucleus of fertilized mouse eggs. Expression of lacZ gene was detected by staining embryos with 5-bromo-4-chloro-3-indolyl-beta-D-galactopyranoside (X-gal) as a substrate at pH 7.2. The embryos expressing the lacZ gene showed various intensities of blue staining, all showing a mosaic pattern. The exogenous gene was expressed from the 4-cell stage until the blastocyst stage. The proportion of embryos expressing the lacZ gene was maximal (38%) at the morula stage, and the expression was dependent on the presence of the SV40 promoter.     

Interactions of Drosophila Ultrabithorax Regulatory Regions with Native and Foreign Promoters

The Ultrabithorax (Ubx) gene of the Drosophila bithorax complex is required to specify parasegments 5 and 6. Two P-element ``enhancer traps' have been recovered within the locus that contain the bacterial lacZ gene under the control of the P-element promoter. The P insertion that is closer to the Ubx promoter expresses lacZ in a pattern similar to that of the normal Ubx gene, but also in parasegment 4 during embryonic development. Two deletions have been recovered that remove the normal Ubx promoter plus several kilobases on either side, but retain the lacZ reporter gene. The lacZ patterns from the deletion derivatives closely match the normal pattern of Ubx expression in late embryos and imaginal discs. The lacZ genes in the deletion derivatives are also negatively regulated by Ubx and activated in trans by Contrabithorax mutations, again like the normal Ubx gene. Thus, the deleted regions, including several kilobases around the Ubx promoter, are not required for long range interactions with Ubx regulatory regions. The deletion derivatives also stimulate transvection, a pairing-dependent interaction with the Ubx promoter on the homologous chromosome.     

The Drosophila gene tailless is expressed at the embryonic termini and is a member of the steroid receptor superfamily

The zygotically active tailless (tll) gene plays a key role in the establishment of nonmetameric domains at the anterior and posterior poles of the Drosophila embryo. We have cloned the tll gene and show that it encodes a protein with striking similarity to steroid hormone receptors in both the DNA binding "finger" and ligand binding domains. tll RNA is initially expressed in embryos in two mirror-image symmetrical domains; this pattern then quickly resolves into a pattern consistent with the mutant phenotype: a posterior cap and an anterior dorsal stripe. That the tll gene may also play a role in the nervous system is suggested by its strong expression in the forming brain and transient expression in the peripheral nervous system.     

Expression of a mouse metallothionein-Escherichia coli beta-galactosidase fusion gene (MT-beta gal) in early mouse embryos

We have microinjected DNA containing the inducible mouse metallothionein-I (MT-I) promoter, coupled to the structural gene for Escherichia coli beta-galactosidase (lacZ), into the pronuclei of one-cell mouse embryos. A qualitative histochemical assay, with 5-bromo-4-chloro-3-indolyl beta-D-galactopyranoside (X-Gal) as a substrate, was used to detect expression of lacZ at several preimplantation stages. We observed staining indicative of exogenous beta-galactosidase activity in 5-17% of DNA-injected embryos assayed at preimplantation stages after 16-24 h treatment with ZnSO4. Thus, lacZ can be used as an indicator gene for promoter function during early mouse embryogenesis, and the incorporation of the MT-I promoter into fusion genes can be a useful means of controlling the expression of exogenous genes in preimplantation mouse embryos.     

Graded requirement for the zygotic terminal gene, tailless, in the brain and tail region of the Drosophila embryo

We have used hypomorphic and null tailless (tll) alleles to carry out a detailed analysis of the effects of the lack of tll gene activity on anterior and posterior regions of the embryo. The arrangement of tll alleles into a continuous series clarifies the relationship between the anterior and posterior functions of the tll gene and indicates that there is a graded sensitivity of anterior and posterior structures to a decrease in tll gene activity. With the deletion of both anterior and posterior pattern domains in tll null embryos, there is a poleward expansion of the remaining pattern. Using anti-horseradish peroxidase staining, we show that the formation of the embryonic brain requires tll. A phenotypic and genetic study of other pattern mutants places the tll gene within the hierarchy of maternal and zygotic genes required for the formation of the normal body pattern. Analysis of mutants doubly deficient in tll and maternal terminal genes is consistent with the idea that these genes act together in a common pathway to establish the domains at opposite ends of the embryo. We propose that tll establishes anterior and posterior subdomains (acron and tail regions, respectively) within the larger pattern regions affected by the maternal terminal genes.     

Shifting boundaries of retinoic acid activity control hindbrain segmental gene expression

Retinoic acid (RA) generated by Raldh2 in paraxial mesoderm is required for specification of the posterior hindbrain, including restriction of Hoxb1 expression to presumptive rhombomere 4 (r4). Hoxb1 expression requires 3' and 5' RA response elements for widespread induction up to r4 and for r3/r5 repression, but RA has previously been detected only from r5-r8, and vHnf1 is required for repression of Hoxb1 posterior to r4 in zebrafish. We demonstrate in mouse embryos that an RA signal initially travels from the paraxial mesoderm to r3, forming a boundary next to the r2 expression domain of Cyp26a1 (which encodes an RA-degrading enzyme). After Hoxb1 induction, the RA boundary quickly shifts to r4/r5, coincident with induction of Cyp26c1 in r4. A functional role for Cyp26c1 in RA degradation was established through examination of RA-treated embryos. Analysis of Raldh2-/- and vHnf1-/- embryos supports a direct role for RA in Hoxb1 induction up to r4 and repression in r3/r5, as well as an indirect role for RA in Hoxb1 repression posterior to r4 via RA induction of vHnf1 up to the r4/r5 boundary. Our findings suggest that Raldh2 and Cyp26 generate shifting boundaries of RA activity, such that r3-r4 receives a short pulse of RA and r5-r8 receives a long pulse of RA. These two pulses of RA activity function to establish expression of Hoxb1 and vHnf1 on opposite sides of the r4/r5 boundary.     

In vivo analysis of a new lacZ retrovirus vector suitable for cell lineage marking in avian and other species

To obtain a replication-defective retrovirus vector well suited for cell lineage marking in early avian embryos, we have constructed and tested a derivative of the avian spleen necrosis virus (SNV) carrying the marker gene lacZ. Consistently high titers of this virus, designated CXL, were produced from retroviral packaging cells with no evidence of contaminating helper virus even after 12 months of continuous culture. CXL expresses lacZ strongly and stably in avian cells and has a host range that extends to other avian and some mammalian species. We show that CXL has the potential to mark a wide variety of chick embryo cell types by infection in ovo. The high titers obtainable with this virus can provide a significant advantage over alternative lacZ vectors, especially in lineage marking of early stage embryos. As an example of this, we show that CXL can be used to mark cells of the precardiac mesoderm in stage 4-5 chick embryos.     

Expression of TTK, a novel human protein kinase, is associated with cell proliferation.

We have isolated the full-length sequence for a unique human kinase, designated TTK. TTK was initially identified by screening of a T cell expression library with anti-phosphotyrosine antibodies. The kinases most closely related to TTK are the SPK1 serine, threonine and tyrosine kinase, the Pim1, PBS2, and CDC2 serine/threonine kinases, and the TIK kinase which was also identified through screening of an expression library with anti-phosphotyrosine antibodies. However, the relationships are distant with less than 25% identity. Nevertheless, TTK is highly conserved throughout phylogeny with hybridizing sequences being detected in mammals, fish, and yeast. TTK mRNA is present at relatively high levels in testis and thymus, tissues which contain a large number of proliferating cells, but is not detected in most other benign tissues. Freshly isolated cells from most malignant tumors assessed expressed TTK mRNA. As well, all rapidly proliferating cell lines tested expressed TTK mRNA. Escherichia coli expressing the complete kinase domain of TTK contain markedly elevated levels of phosphoserine and phosphothreonine as well as slightly increased levels of phosphotyrosine. Taken together, these findings suggest that expression of TTK, a previously unidentified member of the family of kinases which can phosphorylate serine, threonine, and tyrosine hydroxyamino acids, is associated with cell proliferation.