TLR9 stimulation of B-cells induces transcription of p53 and prevents spontaneous and irradiation-induced cell death independent of DNA damage responses. Implications for Common variable immunodeficiency.

Kristine Lillebø Holm,Sergey Shaposhnikov,Hilde Nilsen,Randi Gussgard Syljuåsen,Grete Hasvold,Philippe Collas,Randi Larsen Indrevær,Lene Alsøe,Andrew Collins,Heidi Kiil Blomhoff,Kristina Ivanauskiene,Børre Fevang,Pål Aukrust,Roberto Amendola

doi:10.1371/journal.pone.0185708

Kristine Lillebø Holm, Sergey Shaposhnikov + Show 12 more

Open Access

https://doi.org/10.1371/journal.pone.0185708

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Abstract

In the present study, we address the important issue of whether B-cells protected from irradiation-induced cell death, may survive with elevated levels of DNA damage. If so, such cells would be at higher risk of gaining mutations and undergoing malignant transformation. We show that stimulation of B-cells with the TLR9 ligands CpG-oligodeoxynucleotides (CpG-ODN) prevents spontaneous and irradiation-induced death of normal peripheral blood B-cells, and of B-cells from patients diagnosed with Common variable immunodeficiency (CVID). The TLR9-mediated survival is enhanced by the vitamin A metabolite retinoic acid (RA). Importantly, neither stimulation of B-cells via TLR9 alone or with RA increases irradiation-induced DNA strand breaks and DNA damage responses such as activation of ATM and DNA-PKcs. We prove that elevated levels of γH2AX imposed by irradiation of stimulated B-cells is not due to induction of DNA double strand breaks, but merely reflects increased levels of total H2AX upon stimulation. Interestingly however, we unexpectedly find that TLR9 stimulation of B-cells induces low amounts of inactive p53, explained by transcriptional induction of TP53. Taken together, we show that enhanced survival of irradiated B-cells is not accompanied by elevated levels of DNA damage. Our results imply that TLR9-mediated activation of B-cells not only promotes cell survival, but may via p53 provide cells with a barrier against harmful consequences of enhanced activation and proliferation. As CVID-derived B-cells are more radiosensitive and prone to undergo apoptosis than normal B-cells, our data support treatment of CVID patients with CpG-ODN and RA.

Highlights

The integrity of the human genome is constantly threatened by exposure to genotoxic stress from both endogenous and exogenous sources [1;2]
We aimed to explore the protective role of retinoic acid (RA) in combination with CpG-ODN on spontaneous and irradiation-induced cell death in B-cells from Common variable immunodeficiency (CVID) patients
The present study addresses the concern that B-cells stimulated via TLR9 and RA may survive with enhanced levels of DNA damage

Summary

Introduction

The integrity of the human genome is constantly threatened by exposure to genotoxic stress from both endogenous and exogenous sources [1;2]. Endogenous sources alone, such as those from metabolic processes, account for more than 10,000 lesions per cell per day [3]. DNA damage, if not repaired, play major roles in carcinogenesis, aging and related diseases such as metabolic and cardiovascular disorders [4]. Lymphocytes, and B-cells, are regarded as highly sensitive to irradiation, as they respond by undergoing apoptosis [7]. We have previously shown that stimulating B-cells with the vitamin A metabolite retinoic acid (RA) in combination with ligands crosslinking TLR9 protects B-cells against both spontaneous and irradiation-induced apoptosis [8]

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