Litcius/Paper detail

Climate-driven transition in microbial deterioration and protection of stone surfaces at cultural heritage sites

Haiqing Yang, Xingyue Li, Liyuan Chai, Le Yi Wang, Chongchong Qi

2025Communications Earth & Environment5 citationsDOIOpen Access PDF

Abstract

Understanding the response of biofilms to climatic conditions and their effects on cultural heritage sites is crucial for developing effective conservation strategies. Previous studies have primarily focused on microbial community responses to environmental factors, and little is known about how climatic conditions influence biofilm-induced deterioration and protection. Here we analyzed genomic data from stone heritage sites in East and South Asia and found that biofilm roles shifted from causing deterioration to offering protection along the transition from temperate to tropical climates. This shift was likely regulated by climate-driven variations in functional genes associated with dissimilatory nitrate reduction (napAB, narGHI, nrfAH, and nirBD) and assimilatory sulfate reduction (cysJI and sir). The expression of genes related to these pathways inhibits the accumulation of soluble salts and biogenic acids, leading to protective effects. This study elucidates the dynamic role of microbes in cultural heritage conservation and lays the foundation for sustainable preservation strategies. Microbial biofilm effects in cultural heritage sites shift from deterioration to protection regulated by climate-driven variations in functional genes, according to the temperate-to-tropical climate transition, according to genomic data from 10 stone cultural heritage sites in East and South Asia.

Topics & Concepts

Cultural heritageTemperate climateEcologyBiofilmGeographyClimate changeMicrobial population biologyBiodiversityFlora (microbiology)BiologyEnvironmental protectionSulfate-reducing bacteriaSulfateCultural heritage managementTropicsEnvironmental ethicsBuilding materials and conservationMicrobial Community Ecology and PhysiologyBacterial biofilms and quorum sensing