Exonucleolytic degradation of RNA by p53 protein in cytoplasm

The Role of Tumor Suppressor p53 Protein in HIV-Host Cell Interactions

The virus-host relationship is indispensable for executing successful viral infection. The pathogenesis of HIV is determined by an intricate interaction between the host and the virus for the regulation of HIV infection, thereby influencing various aspects, including the regulation of signaling pathways. High mutation rates and population heterogeneity characterize HIV with consequences for viral pathogenesis and the potential to escape the immune system and anti-viral inhibitors used in therapy. The origin of the high mutation rates exhibited by HIV may be attributed to a limited template-copied fidelity that likely operates in the cytoplasm. HIV-1 infection induces upregulation and activation of tumor suppressor p53 protein in the early stages of HIV-1 infection. p53 plays a multifaceted role in the context of HIV infection, thereby affecting viral replication. p53 is involved in maintaining genetic integrity, actively participating in various DNA repair processes through its various biochemical activities and via its ability to interact with components of the repair machinery. This report focuses on the impact of the p53 protein on the HIV-1 reverse transcription process while incorporating various incorrect and non-canonical nucleotides. The presence of functional host-coded p53 protein with proofreading-repair activities in the cytoplasm may lead to various biological outcomes.

Exonucleases: Degrading DNA to Deal with Genome Damage, Cell Death, Inflammation and Cancer

Although DNA degradation might seem an unwanted event, it is essential in many cellular processes that are key to maintaining genomic stability and cell and organism homeostasis. The capacity to cut out nucleotides one at a time from the end of a DNA chain is present in enzymes called exonucleases. Exonuclease activity might come from enzymes with multiple other functions or specialized enzymes only dedicated to this function. Exonucleases are involved in central pathways of cell biology such as DNA replication, repair, and death, as well as tuning the immune response. Of note, malfunctioning of these enzymes is associated with immune disorders and cancer. In this review, we will dissect the impact of DNA degradation on the DNA damage response and its links with inflammation and cancer.

Mitochondrial matrix-localized p53 participates in degradation of mitochondrial RNAs

Mitochondrial RNA degradation plays an important role in maintenance of the mitochondria genetic integrity. Mitochondrial localization of p53 was observed in non-stressed and stressed cells. p53, as an RNA-binding protein, exerts 3'→5' exoribonuclease activity. The data suggest that in non-stressed cells, mitochondrial matrix-localized p53, with exoribonuclease activity, may play a housekeeping positive role. p53, through restriction the formation of new RNA/DNA hybrid and processing R-loop, might serve as mitochondrial R-loop suppressor. Conversely, stress-induced matrix-p53 decreases the amount of mitochondrial single-stranded RNA transcripts (including polyA- and non-polyA RNAs), thereby leading to the decline in the amount of mitochondria-encoded oxidative phosphorylation components.

p53 regulates its own expression by an intrinsic exoribonuclease activity through AU-rich elements

The onco-suppressor p53 protein plays also an important role in the control of various aspects of health and disease. p53 levels are low in normal cells and elevated under stress conditions. While low levels of p53 promote tumor formation, overactive p53 leads to premature aging and cell death. RNA degradation is a critical level of regulation contributing to the control of gene expression. p53, as an RNA-binding protein, exerts 3' → 5' exoribonuclease activity, mediating degradation of adenylate/uridylate-rich elements (ARE)-containing ssRNAs. The 3'-UTR of p53-mRNA, which is a target of p53 itself, harbors cis-acting AREs. Our results suggest that p53 controls its own expression through murine double-minute 2 (mdm2)-independent "RNA decay" function in cytoplasm. We demonstrate that p53 expresses an exoribonuclease activity through the binding to ARE sequences of p53-mRNA via translation-independent and translation-dependent polysome-associated pathways. Antagonistic interplay was detected between p53 levels and execution of its exoribonuclease function mirrored in low p53 levels in normal cells, due to the efficient exoribonuclease activity, and in the accumulation of p53 in cells exposed to p53-activating drugs in accordance with the reduced exoribonuclease activity. Apparently, p53, via control of its own mRNA stability and/or translation in cytoplasm, might act as a negative regulator of p53-mRNA levels. The observed connection between exoribonuclease activity and p53 abundance highlights the importance of this function affecting p53 expression, imperative for multiple functions, with implications for the steady-state levels of protein and for the p53 stress response. The modulation in expression of exoribonuclease activity would be translated into the alterations in p53 level. KEY MESSAGES: p53 controls its own expression through mdm2-independent "RNA decay" function in cytoplasm. p53 expresses an exoribonuclease activity through the binding to ARE sequences of p53-mRNA. Antagonistic interplay exists between stress-induced p53 and execution of its exoribonuclease function.

Removal of ribonucleotides by p53 protein incorporated during DNA synthesis by HIV-1 reverse transcriptase

OBJECTIVE(S)

HIV-1 reverse transcriptase frequently incorporates ribonucleotides into the proviral DNA in macrophages, but not in lymphocytes. The enzyme exerts an efficient ribonucleotide-terminated primer extension capacity. Furthermore, ribonucleotide-editing repair is attenuated in macrophages. Tumor suppressor p53 protein, displaying an intrinsic 3'→5' exonuclease activity, was found to be involved in efficient proofreading of base-base mismatches produced during DNA synthesis. As the presence of proofreading activity is cardinal for the DNA synthesis accuracy, it was of interest to assess whether p53 can serve as a trans-acting proofreader for HIV-1 reverse transcriptase during ribonucleotide incorporation.

DESIGN

We investigated the potential involvement of cytoplasmic p53 in error correction during insertion of ribonucleotides into DNA by recombinant HIV-1 reverse transcriptase in a p53-proficient and deficient background.

METHODS

Primer extension reactions were carried out to elucidate the incorporation and removal of ribonucleotides.

RESULTS

The biochemical studies suggest that p53 is involved in a ribonucleotide damage-associated repair mechanism through its capacity to remove preformed 3'-terminal ribonucleotides, to decrease ribonucleotide incorporation and to prevent the 3'-ribo-terminated primer extension during ongoing DNA synthesis by HIV-1 reverse transcriptase. A positive correlation exists between the presence of endogenous p53 and decrease in stable incorporation of ribonucleotides into DNA with p53-harboring lysates of HCT116 cells. p53, by preferential removal of purine over pyrimidine ribonucleotides, may affect the ribonucleotide mutation spectra produced by HIV-1 reverse transcriptase.

CONCLUSION

The data implies that p53 can excise incorrect sugar in addition to base mispairs, thereby expanding the role of p53 in the repair of nucleic acids replication errors.

p53 in the mitochondria, as a trans-acting protein, provides error-correction activities during the incorporation of non-canonical dUTP into DNA

Mutations in mitochondrial DNA is an outcome of errors produced by DNA polymerase γ during replication and failure of the repair mechanism. Misincorporation of non-canonical dUTP leads to mutagenesis or apoptosis, and may contribute to the cytotoxic effects of 5'-fluorouracil chemotherapy. Tumor suppressor p53 protein in the mitochondria displays physical and functional interactions with mitochondrial DNA and polymerase γ, and by its intrinsic 3'→5' exonuclease activity can diminish the polymerization errors. Here we demonstrate the impact of p53 on incorporation of uracil into DNA examined with mitochondrial fractions, as the source of polymerase γ. p53 in mitochondria facilitates DNA damage repair functions resulting from uracil-DNA misincorporation. Our biochemical studies revealed that the procession of U:A and mismatched U:G lesions enhances in the presence of recombinant or endogenous cytoplasmic p53. p53 in mitochondria can function as an exonuclease/proofreader for polymerase γ by either decreasing the incorporation of non-canonical dUTP into DNA or by promoting the excision of incorporated nucleotide from nascent DNA, thus expanding the spectrum of DNA damage sites exploited for proofreading as a trans-acting protein. The data suggest that p53 may contribute to defense of the cells from consequences of dUTP misincorporation in both normal and tumor cells.

Ribonuclease activity of p53 in cytoplasm in response to various stress signals

The tumor suppressor p53 protein is expressed at low levels under normal conditions. The subcellular localization and functional activation of p53 are influenced by diverse stress signals. p53 in cytoplasm exerts intrinsic 3'→5' exonuclease activity with various RNA and DNA substrates. ssRNAs containing an adenosine and uridine-rich (ARE) element are permissive targets for p53-mediated degradation. The analysis of the exonuclease activity in cytoplasm with activated p53 induced by various drug treatments or following γ-irradiation revealed that the expression of p53 exonuclease activity in response to stress signals is heterogeneous. Various genotoxic and non-genotoxic agents upregulate p53 yet have different effects on expression of exonuclease activity with ARE RNA but not with DNA substrate. Ribonuclease activity is enhanced in cytoplasmic extracts of HCT116 (p53+/+) cells exposed to γ-irradiation or treated by the non-genotoxic drug AS101 but decreased following treatment by genotoxic (e.g., doxorubicin) or non-genotoxic (e.g., DFMO) agents, thus indicating that p53 exonuclease activity is dependent on the specific stress and nature of the substrate. Apparently, the disparity in expression of p53 ribonuclease activity after each treatment is attributable to the different post-treatment response and to two posttranscriptional events: the interaction of RNA-binding HuR protein with ARE RNA protects the substrate from degradation by p53 and/or decrease in p53 ARE RNA binding capacity due to phosphorylation at Ser392 leads to reduction in p5 ribonuclease activity. Our results provide new insights into p53 exonuclease function and into the mechanisms behind the regulation ARE-RNA degradation by p53 under different cellular conditions.

Excision of nucleoside analogs in mitochondria by p53 protein

OBJECTIVE

Nucleoside analogs, used against HIV, can be incorporated into a mitochondrial DNA by DNA polymerase gamma. Both the decrease in mitochondrial DNA and increased mutations of mitochondrial DNA may lead to mitochondrial diseases. The tumor suppressor protein p53 exhibits 3' --> 5' exonuclease activity and can provide a proofreading function for DNA polymerases. In the present study, we investigated the ability of p53 to excise incorporated nucleoside analogs from DNA in mitochondria.

DESIGN

The functional interaction of p53 and DNA polymerase gamma during the incorporation of nucleoside analog was examined in mitochondrial fractions of p53-null H1299 cells, as the source of DNA polymerase gamma.

METHODS

Primer extension reactions were carried out to elucidate the incorporation and removal of nucleoside analogs.

RESULTS

The results demonstrate that the excision of incorporated nucleoside analogs in mitochondrial fractions of H1299 cells increased in the presence of purified recombinant p53, or cytoplasmic extracts of large cell carcinoma 2 cells expressing endogenous wild-type p53 (but not specifically predepleted extracts) or cytoplasmic extracts of H1299 cells overexpressing wild-type p53, but not exonuclease-deficient mutant p53-R175H. The amount of nucleoside analogs incorporated into the elongated DNA with mitochondrial fractions of human colon carcinoma 116 (HCT116)(p53+/+) cells was lower than that of HCT116(p53-/-) cells. Furthermore, mitochondrion-localized elevation of p53 in HCT116(p53+/+) cells, following the irradiation-stress stimuli, correlates with the reduction in incorporation of nucleoside analogs and wrong nucleotides.

CONCLUSION

p53 in mitochondria may functionally interact with DNA polymerase gamma, thus providing a proofreading function during mitochondrial DNA replication for excision of nucleoside analogs and polymerization errors.

Physical and functional interactions between human mitochondrial single-stranded DNA-binding protein and tumour suppressor p53

Single-stranded DNA-binding proteins (SSB) form a class of proteins that bind preferentially single-stranded DNA with high affinity. They are involved in DNA metabolism in all organisms and serve a vital role in replication, recombination and repair of DNA. In this report, we identify human mitochondrial SSB (HmtSSB) as a novel protein-binding partner of tumour suppressor p53, in mitochondria. It binds to the transactivation domain (residues 1-61) of p53 via an extended binding interface, with dissociation constant of 12.7 (+/- 0.7) microM. Unlike most binding partners reported to date, HmtSSB interacts with both TAD1 (residues 1-40) and TAD2 (residues 41-61) subdomains of p53. HmtSSB enhances intrinsic 3'-5' exonuclease activity of p53, particularly in hydrolysing 8-oxo-7,8-dihydro-2'-deoxyguanosine (8-oxodG) present at 3'-end of DNA. Taken together, our data suggest that p53 is involved in DNA repair within mitochondria during oxidative stress. In addition, we characterize HmtSSB binding to ssDNA and p53 N-terminal domain using various biophysical measurements and we propose binding models for both.

p53 in mitochondria enhances the accuracy of DNA synthesis

Mitochondrial localization of p53 was observed in stressed and unstressed cells. p53 is involved in DNA repair and apoptosis. It exerts physical and functional interactions with mitochondrial DNA and DNA polymerase gamma (pol gamma). The functional cooperation of p53 and pol gamma during DNA synthesis was examined in the mitochondrial fraction of p53-null H1299 cells, as the source of pol gamma. The results show that p53 may affect the accuracy of DNA synthesis in mitochondria: (1) the excision of a misincorporated nucleotide increases in the presence of (a) recombinant wild-type p53 (wtp53); (b) cytoplasmic fraction of LCC2 cells expressing endogenous wtp53 (but not specifically pre-depleted fraction); (c) cytoplasmic extract of H1299 cells overexpressing wtp53, but not exonuclease-deficient mutant p53-R175H. (2) Mitochondrial extracts of HCT116(p53+/+) cells display higher exonuclease activity compared with that of HCT116(p53-/-) cells. Addition of exogenous p53 complements the HCT116(p53-/-) mitochondrial extract mispair excision. Furthermore, the misincorporation was lower in the mitochondrial fraction of HCT116(p53+/+) cells as compared with that of HCT116(p53-/-) cells. (3) Irradiation-induced mitochondrial translocation of endogenous p53 in HCT116(p53+/+) cells correlates with the enhancement of error-correction activities. Taken together, the data suggest that p53 in mitochondria may be a component of an error-repair pathway and serve as guardian of the mitochondrial genome. The function of p53 in DNA repair and apoptosis is discussed.