Atopic dermatitis (AD) is a common inflammatory skin disease characterized by an epidermal barrier impairment, as well as a Th2/Th22-skewed immune response, both favoring skin colonization with Staphylococcus aureus. Colonization is strongly related to severity of the disease, and a reduction of S. aureus has been found to alleviate symptoms. Lactic acid bacteria (LAB) produce antimicrobial compounds such as organic acids and bacteriocins and are widely used as probiotics. The aim of this study was to isolate LAB and screen for antibacterial effect specifically toward S. aureus clonal complex type 1. A total of 680 LAB were isolated from fermented vegetables and swab samples from healthy volunteers (vaginal, stool and skin). Screening for antibacterial activity toward S. aureus, narrowed the field of isolates down to four LAB strains with high antibacterial activity. The activity varied according to the specific LAB strain and the origin of the strain. The results suggested different modes of action, including co-aggregation, expression of bacteriocins and production of specific organic acids. However, the ability to acidify the surroundings appeared as the main effect behind inhibition of S. aureus. Broth microdilution assays showed a significant reduction of S. aureus growth when using down to 10% cell free supernatant (CFS). Our results underline the use of specific living LAB or their CFS as potential future treatment strategies to reduce S. aureus colonization of AD skin.
BackgroundAdjuvant chemo‐ and radiotherapy cause cellular damage to tumorous and healthy dividing cells. Chemotherapy has been shown to cause mitochondrial respiratory dysfunction in non‐tumorous tissues, but the effects on human peripheral blood mononuclear cells (PBMCs) remain unknown.AimWe aimed to investigate mitochondrial respiration of PBMCs before and after adjuvant chemo‐ and radiotherapy in postmenopausal patients with early breast cancer (EBC) and relate these to metabolic parameters of the patients.MethodsTwenty‐three postmenopausal women diagnosed with EBC were examined before and shortly after chemotherapy with (n = 18) or without (n = 5) radiotherapy. Respiration (O2 flux per million PBMCs) was assessed by high‐resolution respirometry of intact and permeabilized PBMCs. Clinical metabolic characteristics and mitochondrial DNA (mtDNA) content of PBMCs (mtDN relative to nuclear DNA) were furthermore assessed.ResultsRespiration of intact and permeabilized PBMCs from EBC patients significantly increased with adjuvant chemo‐ and radiotherapy (p = 6 × 10−5 and p = 1 × 10−7, respectively). The oxygen flux attributed to specific mitochondrial complexes and respiratory states increased by 17–43% compared to before therapy initiation. Similarly, PBMC mtDNA content increased by 40% (p = 0.002). Leukocytes (p = 0.0001), hemoglobin (p = 0.0003), and HDL cholesterol (p = 0.003) concentrations decreased whereas triglyceride (p = 0.01) and LDL (p = 0.02) concentrations increased after treatment suggesting a worsened metabolic state. None of the metabolic parameters or the mtDNA content of PBMCs correlated significantly with PBMC respiration.ConclusionThis study shows that mitochondrial respiration and mtDNA content in circulating PBMCs increase after adjuvant chemo‐ and radiotherapy in postmenopausal patients with EBC. Besides the increased mtDNA content, a shift in PBMC subpopulation proportions towards cells relying on oxidative phosphorylation, who may be less sensitive to chemotherapy, might influence the increased mitochondrial respiration observed iafter chemotherapy.
Background: Adjuvant chemo- and radiotherapy cause cellular damage not only to cancerous but also to healthy dividing cells. Antineoplastic treatments have been shown to cause mitochondrial respiratory dysfunction in non-tumorous tissues, but the effects on circulating human peripheral blood mononuclear cells (PBMCs) remain unknown. Aim: We aimed to identify changes in mitochondrial respiration of PBMCs after adjuvant chemo- and radiotherapy in postmenopausal early breast cancer (EBC) patients and relate these to metabolic parameters of the patients. Methods: Twenty-three postmenopausal women diagnosed with EBC were examined before and shortly after chemotherapy treatment often administered in combination with radiotherapy (n=18). Respiration (O2 flux per million PBMCs) was assessed by high-resolution respirometry of intact and permeabilized PBMCs. Clinical metabolic characteristics were furthermore assessed. Results: Respiration of intact and permeabilized PBMCs from EBC patients was significantly increased after adjuvant chemo- and radiotherapy (p=6x10-5 and p=1x10-7, respectively). The oxygen flux attributed to specific mitochondrial complexes and respiratory states increased by 17-43% compared to before therapy commencement. Leukocyte counts (p=1x10-4), hemoglobin levels (p=0.0003), and HDL cholesterol (p=0.003) decreased while triglyceride (p=0.01) and LDL levels (p=0.02) increased after treatment suggesting a worsened metabolic state. None of the metabolic parameters correlated significantly with PBMC respiration. Conclusion: This study shows that mitochondrial respiration in circulating PBMCs is significantly increased after adjuvant chemo- and radiotherapy in postmenopausal EBC patients. The increase might be explained by a shift in PBMC subpopulation proportions towards cells relying on oxidative phosphorylation rather than glycolysis or a generally increased mitochondrial content in PBMCs. Both parameters might be influenced by therapy-induced changes to the bone marrow or vascular microenvironment wherein PBMCs differentiate and reside.
High-resolution respirometry (HRR) can assess PBMC bioenergetics, but no standardized medium for PBMC preparation and HRR analysis exist. Here, we study the effect of four different media (MiR05, PBS, RPMI, Plasmax) on quantification, size, and HRR analysis (Oxygraph-O2k) of intact PBMCs. Remarkably, PBMC quantification was 21% higher in MiR05 than PBS and Plasmax, and 28% higher than in RPMI, causing O2 flux underestimation during HRR due to inherent adjustments. Moreover, smaller cell size of PBMCs and aggregation was observed in MiR05. We suggest optimization of HRR with a standardized, plasma-like medium for future HRR analysis of intact PBMCs.
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