Antimicrobial and anti‐inflammatory activity of five Taxandria fragrans oils in vitro

The antimicrobial activity of five samples of Taxandria fragrans essential oil was evaluated against a range of Gram‐positive (n= 26) and Gram‐negative bacteria (n= 39) and yeasts (n= 10). The majority of organisms were inhibited and/or killed at concentrations ranging from 0.06–4.0% v/v. Geometric means of MIC were lowest for oil Z (0.77% v/v), followed by oils X (0.86%), C (1.12%), A (1.23%) and B (1.24%). Despite differences in susceptibility data between oils, oils A and X did not differ when tested at 2% v/v in a time kill assay against Staphylococcus aureus. Cytotoxicity assays using peripheral blood mononuclear cells demonstrated that T. fragrans oil was cytotoxic at 0.004% v/v but not at 0.002%. Exposure to one or more of the oils at concentrations of ≤0.002% v/v resulted in a dose responsive reduction in the production of proinflammatory cytokines IL‐6 and TNF‐α, regulatory cytokine IL‐10, Th1 cytokine IFN‐γ and Th2 cytokines IL‐5 and IL‐13 by PHA stimulated mononuclear cells. Oil B inhibited the production of all cytokines except IL‐10, oil X inhibited TNF‐α, IL‐6 and IL‐10, oil A inhibited TNF‐α and IL‐6, oil C inhibited IL‐5 and IL‐6 and oil Z inhibited IL‐13 only. IL‐6 production was significantly inhibited by the most oils (A, B, C and X), followed by TNF‐α (oils A, B and X). In conclusion, T. fragrans oil showed both antimicrobial and anti‐inflammatory activity in vitro, however, the clinical relevance of this remains to be determined.     

Understorey thinning and burning trials are needed in conservation reserves: The case of Tuart (Eucalyptus gomphocephala D.C.)

Summary Management interventions are needed to reverse the decline of Tuart (Eucalyptus gomphocephala) woodland in the Yalgorup area of south‐west Western Australia where the largest intact remaining example of this ecosystem is located. Although the cause of the decline is uncertain and several factors may be involved, management action should not be withheld because the decline process is not fully understood. We contend that the reduction in fire frequency over the last 50 years has led to an increase in understorey density, particularly of Western Australian Peppermint (Agonis flexuosa), resulting in greater competition for resources, which may in turn have increased the susceptibility of healthy woodland to decline. In contrast to Tuart regeneration, which is usually tied to fire, Western Australian Peppermint can establish readily in unburnt woodland. Further, once Western Australian Peppermint seedlings develop to the lignotuberous stage, they can resprout vigorously after fire. Therefore, a combination of fire and the physical removal of understorey in sites where this species has formed extensive thickets is required to: (i) provide an opportunity for regeneration of Tuart in both healthy and declining stands; (ii) improve the chances of sustained recovery of Tuart trees in declining stands; and (iii) ensure heterogeneity in the vegetation at multiple scales, a recognized strategy for conserving biodiversity and increasing ecosystem resilience. We propose that this approach may also be relevant to other tree decline syndromes in southern Australia. However, fostering community support for active intervention using thinning and fire in conservation reserves and staging the operations within an experimental framework will be important for such action to gain both the social and scientific acceptance necessary for it to be applied widely.