Functional studies of {\it twist\/} during mouse embryogenesis

A fundamental task in developmental biology is to understand the molecular mechanisms governing early embryogenesis. The aim of this study was to understand the developmental role of a putative basic helix-loop-helix (b-HLH) transcription factor, twist, during mouse embryogenesis.^ twist was originally identified in Drosophila as one of the zygotic genes, including snail, that were required for dorsal-ventral patterning. In Drosophila embryogenesis, twist is expressed in the cells of the ventral midline destined to form mesoderm. In embryos lacking twist expression, their ventral cells fail to form a ventral furrow and subsequently no mesoderm is formed.^ During mouse embryogenesis, twist is expressed after initial mesoderm formation in both mesoderm and cranial neural crest cell derivatives. To study the role of twist in vivo, twist-null embryos were generated by gene targeting. Embryos homozygous for the twist mutation die at midgestation. The most prominent phenotype in the present study was a failure of the cranial neural tube to close (exencephaly). twist-null embryos also showed defects in head mesenchyme, branchial arches, somites, and limb buds.^ To understand whether twist functions cell-autonomously and to investigate how twist-null cells interact with wild-type cells in vivo, twist chimeras composed of both twist-null and wild-type cells marked by the expression of the lacZgene were generated. Chimeric analysis revealed a correlation between the incidence of exencephaly and the contribution of the underlying twist-null head mesenchyme, thus strongly suggesting that twist-expressing head mesenchyme is required for the closure of the cranial neural tube. These studies have identified twist as a critical regulator for the mesenchymal fate determination within the cranial neural crest lineage. Most strikingly, twist-null head mesenchyme cells were always segregated from wild-type cells, indicating that the twist mutation altered the adhesive specificity of these cells. Furthermore, these results also indicated that twist functions cell-autonomously in the head, arch, and limb mesenchyme but non-cell-autonomously in the somites. Taken together, these studies have established the essential role of twist during mouse embryogenesis. ^

Signal transduction of {\it HER-2\/}/{\it neu\/} receptor tyrosine kinase

Overexpression and/or amplification of HER2/neu is frequently detected in many human cancers. Activation of p185 tyrosine kinase can be achieved by point mutation, overexpression, deletion, and heterodimerization with other class I receptors. In this study I investigated the signal transduction pathways mediating the oncogenic signal of the point mutation-activated rat p185. I demonstrated that tyrosine phosphorylation of Shc and formation of Shc/Grb2 complex correlated to the transformation of NIH3T3 cells caused by the point mutation-activated rat HER2/neu. Furthermore, I observed that association with Shc was severely impaired by deletion of most of the major autophosphorylation sites of the point-mutated p185. The truncated p185 product, however, fully retained its ability to transform NIH3T3 cells, induce Shc tyrosine phosphorylation and Shc/Grb2 complex formation. These results suggest that tyrosine phosphorylation of Shc which allows formation of Shc/Grb2 complex may play an important role in cell transformation induced by the point mutation-activated p185, and that stable binding to mutant p185 may not be necessary for Shc to mediate this signaling pathway.^ Recent studies have suggested that formation of the complex containing Sos, Grb2 and Shc is important in coupling receptor tyrosine kinases to the Ras signaling pathway. To clarify the role of this trimer in the oncogenic signaling of the activated p185, I set out to interfere with the protein-protein interactions in Shc/Grb2/Sos complex by introducing Grb2 mutants with deletions in either amino- ($\Delta$N-Grb2) or carboxyl- ($\Delta$C-Grb2) terminal SH3 domains into B104-1-1 cells derived from NIH3T3 cells that express the point mutation-activated HER-2/neu. I found that the transformed phenotypes of the B104-1-1 cells were largely reversed by expression of the $\Delta$N-Grb2. The effect of the $\Delta$C-Grb2 on phenotypic reversion was much weaker. Biochemical analysis showed that the $\Delta$N-Grb2 was able to associate Shc but not the activated p185 nor Sos, while the $\Delta$C-Grb2 bound to Shc, the activated p185, and Sos. The p185-mediated Ras activation was severely inhibited by the $\Delta$N-Grb2 but not the $\Delta$C-Grb2. Taken together, these data demonstrate that interruption of the interaction between Shc and the endogenous Grb2 by the $\Delta$N-Grb2 is able to impair the oncogenic signaling of the mutation-activated p185, indicating that (i) the $\Delta$N-Grb2 functions as a strong dominant-negative mutant, (ii) Shc/Grb2/Sos pathway plays a major role in mediating the oncogenic signal of the mutation-activated p185. Unlike the $\Delta$N-Grb2, the $\Delta$C-Grb2 appears to be a relatively weak dominant-negative mutant, probably due to its ability to largely fulfill the biological functions of the wild-type Grb2. ^

Involvement of {\it p53\/} in PUVA-induced skin cancers

A combination of psoralen and ultraviolet-A radiation, commonly referred to as "PUVA," is widely used in the treatment of psoriasis. However, PUVA treatment increases the risk of developing skin cancer in psoriasis patients and induces skin cancer in mice. It is, however unknown whether the increased incidence of skin cancer in PUVA treated psoriasis patients is due to the carcinogenic effects of PUVA therapy or due to an indirect effect such as immunosuppression, which can permit the growth of tumors induced by UVB radiation. In this study, we used the p53 tumor suppressor gene as a molecular marker to determine whether PUVA-induced mouse skin cancers contain unique mutations in p53 that are different from UV-induced mutations, and if so, determine whether skin cancers from PUVA treated patients have PUVA-type or UV-type p53 mutations. Since the DNA lesions induced by PUVA are quite different from those induced by UV, we hypothesize that p53 mutations induced by PUVA may also be different from those induced by UV.^ Analysis of PUVA-induced murine skin cancers for p53 mutations revealed that 14 of 15 (93%) missense mutations detected in these cancers were localized at 5$\sp\prime$-TA/5$\sp\prime$-TAT sites, potential sites of psoralen photoadditions. Mutations at these sequences are exceedingly rare in UV-induced murine skin cancers. In addition, PUVA-induced murine skin cancers did not contain UV signature (C $\to$ T or CC $\to$ TT transitions) mutations in p53. These results suggest that PUVA induces unique mutations in p53 that can be distinguished from those induced by UV.^ Next we determined whether SCCs arising in PUVA treated psoriasis patients have PUVA-type or UV-type p53 mutations. The results indicated that 16 of 25 (64%) missense p53 mutations detected in SCCs from PUVA treated patients were located at 5$\sp\prime$-TG, 5$\sp\prime$-TA and 5$\sp\prime$-TT sites, putative sites of psoralen photobinding. Interestingly, about 32% of p53 mutations detected in SCCs from PUVA treated patients had the UV signature. Taken together these results suggest that both PUVA and UVB play a role in the development of SCCs in psoriasis patients undergoing PUVA therapy. ^