MicroRNAs Are Associated with Blood-pressure Effects of Exposure to Particulate Matter: Results from a Mediated Moderation Analysis

Overview

Journal Environ Res

Publisher Elsevier

Specialty Environmental Health

Date 2016 Jan 18

PMID 26775008

Citations 17

Authors

Valeria Motta

Chiara Favero

Laura Dioni

Simona Iodice

Cristina Battaglia

Laura Angelici

Luisella Vigna

Angela Cecilia Pesatori

Valentina Bollati

Affiliations

Soon will be listed here.

Abstract

Aims: Exposure to particulate air pollution is associated with increased blood pressure (BP), a well-established risk factor for cardiovascular disease. To elucidate the mechanisms underlying this relationship, we investigated whether the effects of particulate matter of less than 10μm in aerodynamic diameter (PM10) on BP are mediated by microRNAs.

Methods And Results: We recruited 90 obese individuals and we assessed their PM10 exposure 24 and 48h before the recruitment day. We performed multivariate linear regression models to investigate the effects of PM10 on BP. Using the TaqMan® Low-Density Array, we experimentally evaluated and technically validated the expression levels of 377 human miRNAs in peripheral blood. We developed a mediated moderation analysis to estimate the proportion of PM10 effects on BP that was mediated by miRNA expression. PM10 exposure 24 and 48h before the recruitment day was associated with increased systolic BP (β=1.22mmHg, P=0.019; β=1.24mmHg, P=0.019, respectively) and diastolic BP (β=0.67mmHg, P=0.044; β=0.91mmHg, P=0.007, respectively). We identified nine miRNAs associated with PM10 levels 48h after exposure. A conditional indirect effect (CIE=-0.1431) of PM10 on diastolic BP, which was mediated by microRNA-101, was found in individuals with lower values of mean body mass index.

Conclusions: Our data provide evidence that miRNAs are a molecular mechanism underlying the BP-related effects of air pollution exposure, and indicate miR-101 as epigenetic mechanism to be further investigated.

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