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High Levels of Oxidative Stress Create a Microenvironment That Significantly Decreases the Diversity of the Microbiota in Diabetic Chronic Wounds and Promotes Biofilm Formation

Jane Kim, Paul R. Ruegger, Elyson Gavin Lebig, Samantha VanSchalkwyk, Daniel R. Jeske, Ansel Hsiao, James Borneman, Manuela Martins‐Green

2020Frontiers in Cellular and Infection Microbiology66 citationsDOIOpen Access PDF

Abstract

Diabetic chronic wounds are characterized by high levels of oxidative stress (OS) and are often colonized by biofilm-forming bacteria which severely compromise healing and can result in amputation. Little is known about the role of skin microbiota in wound healing and chronic wound development. We hypothesize that high OS levels lead to chronic wound development by promoting the colonization of biofilm-forming bacteria over commensal/beneficial bacteria. To test this hypothesis, we used our db/db-/- mouse model for chronic wounds that develops pathogenic biofilms naturally after we induce high OS immediately after wounding. We analyzed wound microbiota by sequencing the bacterial rRNA internal transcribed spacer (ITS) gene of the wound microbiota from chronic wound initiation to fully developed chronic wounds. Indicator species analysis, which considers a species’ fidelity and specificity, was used to determine which bacterial species were strongly associated with healing wounds or chronic wounds. We found that healing wounds were colonized by a diverse and dynamic bacterial microbiome that never developed biofilms even though strong biofilm-forming bacteria were present. Several clinically relevant species such as Cutibacterium acnes, Achromobacter sp., Delftia sp., and Escherichia coli, were highly associated with healing wounds. These bacteria may serve as bioindicators of healing by actively participating in the processes of wound healing and preventing pathogenic bacteria from colonizing the wound. In contrast, chronic wounds, which had high levels of OS, had low bacterial diversity and were colonized by several clinically relevant, biofilm-forming bacteria such as Pseudomonas aeruginosa, Enterobacter cloacae, Corynebacterium frankenforstense, and Acinetobacter sp. We observed unique population trends: for example, Pseudomonas aeruginosa associated with aggressive biofilm development, whereas Staphylococcus xylosus was only present early after injury. These findings show that high levels of OS in the wound significantly altered the bacterial wound microbiome, decreasing diversity and promoting the colonization of bacteria from the skin microbiota to form biofilm. In conclusion, bacteria associated with non-chronic or chronic wounds could function as bioindicators of healing or non-healing (chronicity), respectively. Moreover, a better understanding of bacterial interactions between pathogenic and beneficial bacteria within an evolving chronic wound microbiota may lead to better solutions for chronic wound.

Topics & Concepts

BiofilmMicrobiologyChronic woundBiologyBacteriaPseudomonas aeruginosaWound healingMicrobiomeImmunologyBioinformaticsGeneticsWound Healing and TreatmentsBacterial biofilms and quorum sensingPressure Ulcer Prevention and Management
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