Systems genetics analyses predict a transcription role for P2P-R: Molecular confirmation that P2P-R is a transcriptional co-repressor

Background  

The 250 kDa P2P-R protein (also known as PACT and Rbbp6) was cloned over a decade ago and was found to bind both the p53 and Rb1 tumor suppressor proteins. In addition, P2P-R has been associated with multiple biological functions, such as mitosis, mRNA processing, translation and ubiquitination. In the current studies, the online GeneNetwork system was employed to further probe P2P-R biological functions. Molecular studies were then performed to confirm the GeneNetwork evaluations.     

Post-translational processing of Schizosaccharomyces pombe YPT proteins.

ras proteins are post-translationally processed at their carboxyl-terminal CAAX motif by a triplet of modifications: prenylation of C with farnesyl, proteolytic trimming of AAX, and carboxyl-methylation. These modifications co-operate with palmitoylation of nearby sites or a polybasic region to target plasma membrane localization. The related YPT/rab proteins in contrast are localized to compartments of the endo-membrane system and may be involved in directing membrane traffic. These proteins end in XCC or CXC motifs. We have analyzed the processing of members of this subfamily form the fission yeast Schizosaccharomyces pombe. We find using in vitro translation in reticulocyte lysates that YPT1, -3, and -5 are prenylated with geranylgeranyl and that they incorporate label from [3H]mevalonic acid when expressed in transfected COS cells in vivo. Furthermore, prenylation was necessary for membrane binding in vivo. The CXC protein YPT5, but neither of the two XCC proteins YPT1 and YPT3, was carboxyl-methylated in S. pombe and in COS cells in vivo. However, YPT5 was not carboxyl-methylated in vitro in lysates which were able to methylate ras protein. YPT3 was detectably palmitoylated when expressed in COS cells, though at a much lower level than ras.     

SAFB1 interacts with and suppresses the transcriptional activity of p53

A significant amount of nuclear p53 is found associated with the nuclear matrix in cells that were exposed to genotoxic stress. In this study we identified Scaffold attachment factor B1 (SAFB1), a nuclear matrix-associated protein that binds the scaffold or matrix attachment regions (S/MARs) of genomic DNA, as a novel p53-interacting protein. SAFB1 was able to associate with p53 through its C-terminal domain, while significant co-localization of the two proteins was observed in cells treated with 5-fluorouracil or mithramycin. Binding of p53 to SAFB1 had a significant functional outcome, since SAFB1 was shown to suppress p53-mediated reporter gene expression. These data suggest that nuclear matrix-associated proteins may play a critical role in regulating p53 localization and activity.

Structured summary

p53physically interacts with SRPK1a: shown by two hybrid (view interaction)p53physically interacts with SRPK1a: shown by pull down (view interaction)p53physically interacts with SRPK1a: shown by anti bait coimmunoprecipitation (view interaction)p53physically interacts with SRPK1a: shown by anti tag coimmunoprecipitation (view interaction)SAFB1physically interacts with p53: shown by pull down (view interactions 1, 2)SAFB1physically interacts with p53: shown by anti bait coimmunoprecipitation (view interactions 1, 2)SAFB1 and p53colocalize: shown by fluorescence microscopy (view interaction)SAFB2physically interacts with p53: shown by pull down (view interaction)     

Expression of β-galactosidase multiple forms during barley (Hordeum vulgare) seed germination. Separation and characterization of enzyme isoforms

β-Galactosidase (EC 3.2.1.23) activity in barley ( Hordeum vulgare ) seedlings increases moderately during the first stages of germination. The level of activity in the whole seedling is the result of increasing activity of β-galactosidase in the roots and shoots and of declining enzyme activity in the grain. β-Galactosidase was purified during different developmental stages and from various parts of the barley seedling using affinity chromatography and was resolved into multiple forms by isoelectric focusing on polyacrylamide gels. The expression of the isoforms was shown to be under temporal and tissue-specific control. Four sets of isozymes were separated by DEAE-cellulose chromatography and were shown to be functionally similar. β-Galactosidase isoforms also exhibit size microheterogeneity, the more acidic entities having higher molecular masses. The differences in molecular weight are mainly restricted to the size of the small subunit. Multiplicity can not be attributed to glycosylation, since treatment of the enzyme preparation with N- or O-glycanase did not alter the isoelectric points or the molecular weights of the isoforms.