Tid1 is a new regulator of p53 mitochondrial translocation and apoptosis in cancer.

The p53 tumor suppressor protein induces apoptosis in response to genotoxic and environmental stresses. Recent studies have revealed the existence of a transcription-independent mitochondrial p53 apoptotic pathway; however, the mechanism that regulates its translocation to the mitochondria has been unknown. In this study, we show that the tumor suppressor Tid1 forms a complex with p53 under hypoxic conditions that directs p53 translocation to the mitochondria and the subsequent initiation of the mitochondrial apoptosis pathway. Loss of Tid1 expression abrogated p53 translocation to the mitochondria and inhibited apoptosis, whereas the over-expression of Tid1 promoted p53 mitochondrial localization and apoptosis. Tid1's mitochondrial signal sequence and DnaJ domain were both required for the movement of the p53-Tid1 complex from the cytosol to the mitochondria. When Tid is over-expressed in cancer cell lines expressing mutant p53 isoforms defective in transcriptional activity, mitochondrial localization and pro-apoptotic activities of the mutant p53 proteins was restored. Our results establish Tid1 as a novel regulator of p53-mediated apoptosis, and suggest that therapies designed to enhance Tid1's function in promoting mitochondrial localization of p53 and apoptosis could be an effective therapy in many cancers.

Identification and evaluation of major histocompatibility complex antigens in chicken chimeras and their relationship to germline transmission.

Chimeric chickens were evaluated as an intermediate for development of transgenic chickens. The transfer of Barred Plymouth Rock (BR) blastodermal cells into White Leghorn (WL) embryos results in BR-->WL chimeras, and some breeder males generate over 30% germline transmission of the BR genotype to offspring based on a feather-color trait. The objectives of the current study were to 1) identify the MHC (B haplotypes) in resident BR and WL lines, 2) establish that B antigens could be detected and quantified in red blood cells (RBC) of chimeras, 3) establish if there is a correlation in chimeras between percentage of RBC with donor B antigens and percentage germline transmission, and 4) evaluate if the MHC genotype influences chimera development. The RBC agglutination data indicated three B haplotypes were present in each line. The B*2-like, and B*19-like genes were unique to the WL line, and B*13-like and B-15-like genes were unique to the BR line, whereas a B*21-like gene was present in both lines. In adult BR-->WL chimeras, as well as 10- to 14 d-old WL-->WL chimeras, donor-type B antigens were detectable and quantifiable on RBC using flow cytometry. In BR-->WL chimeras, the percentage germline transmission was significantly correlated with the percentage of RBC with donor B antigen, as well as percentage of black feathers in the plumage. In a retrospective study using previously developed BR-->WL chimeras, the level of chimerism and germline transmission was higher in B*21/*21 type recipients, but this was not statistically significant in two prospective studies. It was concluded that MHC antigens on RBC can be used for identifying, quantifying, and selecting chicken chimeras developed by the transfer of blastodermal cells.

Manipulation of blastodermal cells.

Blastodermal cells isolated from newly laid, unincubated eggs are virtually uncommitted cells that exhibit many of the properties of pluripotential stem cells. They can be transferred from donor to recipient embryos and contribute to both somatic tissues and the germline. Blastodermal cells that have been maintained in culture for 7 d express the epitopes ECMA-7 and SSEA-1, which are also expressed by mouse embryonic stem cells. After culture for up to at least 7 d, blastodermal cells retain the ability to differentiate into somatic tissues and the germline both in vivo and in vitro. Proliferation in the absence of differentiation of blastodermal cells is stimulated by the presence of Leukemia Inhibitory Factor (LIF) and other ligands that interact with the gp130 receptor, and differentiation is stimulated by exposure to retinoic acid. Blastodermal cells also possess high levels of telomerase activity, which is shared by immortalized cells and cells within the germline. Blastodermal cells can be transfected and will express foreign genes both in vivo and in vitro. Transfected cells can be isolated by fluorescence activated cell sorting and can be cryopreserved without losing their ability to contribute to either somatic tissues or the germline. These properties of blastodermal cells make them ideal vectors for introducing genetic modifications to the germline.