Abstract
Copper tolerance of brown-rot basidiomycete decay fungi can lessen the efficacy of copper-containing wood preservatives for wood products in-service. The purpose of this study was to evaluate wood mass loss and differential expression of three genes that have putative annotations for copper-transporting ATPase pumps (FIBRA_00974, FIBRA_04716, and FIBRA_01430). Untreated southern pine (SP) and SP treated with three concentrations of ammoniacal copper citrate (CC, 0.6, 1.2, and 2.4%) were exposed to two copper-tolerant Fibroporia radiculosa isolates (FP-90848-T and L-9414-SP) and copper-sensitive Gloeophyllum trabeum isolate (MAD 617) in a 4-week-long standard decay test (AWPA E10-19). Decay of copper-treated wood was inhibited by G. trabeum (p = 0.001); however, there was no inhibition of decay with increasing copper concentrations by both F. radiculosa isolates. Initially, G. trabeum and one F. radiculosa isolate (L-9414-SP) highly upregulated FIBRA_00974 and FIBRA_04716 on copper-treated wood at week 1 (p = 0.005), but subsequent expression was either not detected or was similar to expression on untreated wood (p = 0.471). The other F. radiculosa isolate (FP-90848-T) downregulated FIBRA_00974 (p = 0.301) and FIBRA_04716 (p = 0.004) on copper-treated wood. FIBRA_01430 expression by G. trabeum was not detected, but was upregulated by both F. radiculosa FP-90848-T (p = 0.481) and L-9414-SP (p = 0.392). Results from this study suggest that all three test fungi utilized different mechanisms when decaying copper-treated wood. Additionally, results from this study do not provide support for the involvement of these putative gene annotations for copper-transporting ATPase pumps in the mechanism of copper-tolerance.
Highlights
Copper is an essential metal for eukaryotic life (Lattore et al, 2011; Smith et al, 2017; Raffa et al, 2019)
We examined the differential expression of three putative copper transporting ATPase genes (FIBRA_00974, FIBRA_04716, and FIBRA_01430) in two coppertolerant F. radiculosa isolates (FP-90848-T and L-9414-southern pine (SP)) and copper-sensitive Gloeophyllum trabeum
G. trabeum produced significantly lower mass loss for all copper levels, < 2.4% (p = 0.001)
Summary
Copper is an essential metal for eukaryotic life (Lattore et al, 2011; Smith et al, 2017; Raffa et al, 2019). These metal tolerance mechanisms of fungi appear to include: efflux and excretion of accumulated metals (Weissman et al, 2000; Ito et al, 2007); cell wall complexation facilitated by extracellular polymeric slime materials which aid in controlling metal uptake (Daniel and Nilsson, 1989; Yahaya et al, 2009); chelation and/ or precipitation by soluble metabolites (oxalic acid; Clausen, 2000; Clausen and Green, 2003; Green and Clausen, 2003; Jarosz-Wilkolazka and Graz, 2006; Tang et al, 2013); accumulated metal complexation and immobilization by metallothioneins (Schwartz et al, 2013); and metal sequestration to the periplasm or vacuoles (Pearce and Sherman, 1999) Each of these mechanisms can be employed singularly or in concert to prevent metal toxicity by reducing intracellular damage typically caused by oxidative species resulting from reactive metal ions
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