Diversity and Composition of Culturable Microorganisms and Their Biodeterioration Potentials in the Sandstone of Beishiku Temple, China

Microbial colonization on stone monuments leads to subsequent biodeterioration; determining the microbe diversity, compositions, and metabolic capacities is essential for understanding biodeterioration mechanisms and undertaking heritage management. Here, samples of epilithic biofilm and naturally w...

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Bibliographic Details
Published in:Microorganisms (Basel) 2023-02, Vol.11 (2), p.429
Main Authors: Zhang, Yong, Su, Min, Wu, Fasi, Gu, Ji-Dong, Li, Jie, He, Dongpeng, Guo, Qinglin, Cui, Huiping, Zhang, Qi, Feng, Huyuan
Format: Article
Language:English
Subjects:
Bacteria
Biocides
Biodegradation
Biodeterioration
Biofilms
Biological diversity
Biotechnology
Calcite
Calcium carbonate
Calcium oxalate
Carbonates
Caves
Composition
Cultural heritage
Culture
Destruction
Dissolution
Environmental aspects
Environmental conditions
Fungi
Historic sites
Humidity
Identification and classification
Memorials & monuments
Microbial activity
Microbial colonies
Microbiological research
Microorganisms
Mineralization
Minerals
Monuments
organic acid
Organic acids
pigment
Pigmentation
Precipitation
Relative humidity
Sandstone
Stone
stone monuments
Strains (organisms)
Weathering
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Summary:Microbial colonization on stone monuments leads to subsequent biodeterioration; determining the microbe diversity, compositions, and metabolic capacities is essential for understanding biodeterioration mechanisms and undertaking heritage management. Here, samples of epilithic biofilm and naturally weathered and exfoliated sandstone particles from different locations at the Beishiku Temple were collected to investigate bacterial and fungal community diversity and structure using a culture-based method. The biodeterioration potential of isolated fungal strains was analyzed in terms of pigmentation, calcite dissolution, organic acids, biomineralization ability, and biocide susceptibility. The results showed that the diversities and communities of bacteria and fungi differed for the different sample types from different locations. The population of culturable microorganisms in biofilm samples was more abundant than that present in the samples exposed to natural weathering. The environmental temperature, relative humidity, and pH were closely related to the variation in and distribution of microbial communities. Fungal biodeterioration tests showed that isolated strains four and five were pigment producers and capable of dissolving carbonates, respectively. Their biomineralization through the precipitation of calcium oxalate and calcite carbonate could be potentially applied as a biotechnology for stone heritage consolidation and the mitigation of weathering for monuments. This study adds to our understanding of culturable microbial communities and the bioprotection potential of fungal biomineralization.
ISSN:2076-2607
2076-2607
DOI:10.3390/microorganisms11020429