Nucleolar Accumulation of RNA Binding Proteins Induced by ActinomycinD Is Functional in Trypanosoma cruzi and Leishmania mexicana but Not in T. brucei

We have recently shown in T. cruzi that a group of RNA Binding Proteins (RBPs), involved in mRNA metabolism, are accumulated into the nucleolus in response to Actinomycin D (ActD) treatment. In this work, we have extended our analysis to other members of the trypanosomatid lineage. In agreement with our previous study, the mechanism seems to be conserved in L. mexicana, since both endogenous RBPs and a transgenic RBP were relocalized to the nucleolus in parasites exposed to ActD. In contrast, in T. brucei, neither endogenous RBPs (TbRRM1 and TbPABP2) nor a transgenic RBP from T. cruzi were accumulated into the nucleolus under such treatment. Interestingly, when a transgenic TbRRM1was expressed in T. cruzi and the parasites exposed to ActD, TbRRM1 relocated to the nucleolus, suggesting that it contains the necessary sequence elements to be targeted to the nucleolus. Together, both experiments demonstrate that the mechanism behind nucleolar localization of RBPs, which is present in T. cruzi and L. mexicana, is not functional in T. brucei, suggesting that it has been lost or retained differentially during the evolution of the trypanosomatid lineage

The novel mouse Polo-like kinase 5 responds to DNA damage and localizes in the nucleolus

Polo-like kinases (Plk1-4) are emerging as an important class of proteins involved in many aspects of cell cycle regulation and response to DNA damage. Here, we report the cloning of a fifth member of the polo-like kinase family named Plk5. DNA and protein sequence analyses show that Plk5 shares more similarities with Plk2 and Plk3 than with Plk1 and Plk4. Consistent with this observation, we show that mouse Plk5 is a DNA damage inducible gene. Mouse Plk5 protein localizes predominantly to the nucleolus, and deletion of a putative nucleolus localization signal (NoLS) within its N-terminal moiety disrupts its nucleolar localization. Ectopic expression of Plk5 leads to cell cycle arrest in G1, decreased DNA synthesis, and to apoptosis, a characteristic it shares with Plk3. Interestingly, in contrast to mouse Plk5 gene, the sequence of human Plk5 contains a stop codon that produces a truncated protein lacking part of the kinase domain

Aprataxin Forms a Discrete Branch in the HIT (Histidine Triad) Superfamily of Proteins with Both DNA/RNA Binding and Nucleotide Hydrolase Activities

Ataxia with oculomotor apraxia type 1 (AOA1) is an early onset autosomal recessive spinocerebellar ataxia with a defect in the protein Aprataxin, implicated in the response of cells to DNA damage. We describe here the expression of a recombinant form of Aprataxin and show that it has dual DNA binding and nucleotide hydrolase activities. This protein binds to double-stranded DNA with high affinity but is also capable of binding double-stranded RNA and single-strand DNA, with increased affinity for hairpin structures. No increased binding was observed with a variety of DNA structures mimicking intermediates in DNA repair. The DNA binding observed here was not dependent on zinc, and the addition of exogenous zinc abolished DNA binding. We also demonstrate that Aprataxin hydrolyzes with similar efficiency the model histidine triad nucleotide-binding protein substrate, AMPNH2, and the Fragile histidine triad protein substrate, Ap4A. These activities were significantly reduced in the presence of duplex DNA and to a lesser extent in the presence of single-strand DNA, and removal of the N-terminal Forkhead associated domain did not alter activity. Finally, comparison of sequence relationships between the histidine triad superfamily members shows that Aprataxin forms a distinct branch in this superfamily. In addition to its capacity for nucleotide binding and hydrolysis, the observation that it also binds DNA and RNA adds a new dimension to this superfamily of proteins and provides further support for a role for Aprataxin in the cellular response to DNA damage

p53-Dependent subcellular proteome localization following DNA damage

The nucleolus is involved in regulating several aspects of stress responses and cell cycle arrest through the tumor suppressor p53. Under normal conditions, p53 is a short-lived protein that is present in cells at a barely detectable level. Upon exposure of cells to various forms of exogenous stress, such as DNA damage, there is a stabilization of p53 which is then responsible for an ensuing cascade of events. To further investigate the effect of p53 activation, we used a MS-based proteomics method to provide an unbiased, quantitative and high-throughput approach for measuring the subcellular distribution of the proteome that is dependent on p53. The spatial proteomics method analyses a whole cell extract created by recombining differentially labeled subcellular fractions derived from cells in which proteins have been mass labeled with heavy isotopes [Boisvert, F.-M., Lam, Y. W., Lamont, D., Lamond, A. I., Mol. Cell. Proteomics 2010, 9, 457–470]. This was used here to measure the relative distribution between cytoplasm, nucleus and nucleolus of around 2000 proteins in HCT116 cells that are either expressing wild-type p53 or null for p53. Spatial proteomics also facilitates a proteome-wide comparison of changes in protein localization in response to a wide range of physiological and experimental perturbations. We used this method to study differences in protein localization in HCT116 cells either with or without p53, and studied the differences in cellular response to DNA damage following treatment of HCT116 cells with etoposide in both p53 wild-type and null genetic backgrounds

Polo-like kinase 3 is required for entry into S phase

The polo-like kinase, Plk1, which is expressed and active in mitosis, is involved in regulation of mitotic entry, spindle pole assembly, mitotic exit, and cytokinesis [Donaldson MM, Tavares AA, Hagan IM, Nigg EA, Glover DM (2001) J Cell Sci 114:2357–2358]. In mammals, there are two other members of the polo-like kinase family that are less well understood, Plk2 and Plk3. Plk3 first was identified and cloned as an immediate early gene. Here, we report Plk3 localizes to the nucleolus and is involved in regulation of the G(1)/S phase transition. We demonstrate that the level of Plk3 protein is cell cycle regulated, peaking in G(1). We have delivered Plk3-interfering RNA with lentivirus to serum-starved cells and found that, upon serum stimulation, Plk3 is required for cyclin E expression and entry into S phase. Plk3-interfering RNA-induced Plk3 depletion resulted in a large fraction of asynchronously proliferating cells to become quiescent. We propose the Plk3 requirement in the cell cycle is fulfilled in G(1), and that once cells pass this point, they are able to complete cell division, whereas in the absence of Plk3, they fail to reenter the cell cycle. Additional data suggest that Plk3 may regulate entry into S phase in part through interaction with the phosphatase Cdc25A, because its depletion also resulted in attenuation of cyclin E expression