Amauroderma schomburgkii (Mont. & Berk.) Torrend, Brotéria, 1920

Amauroderma schomburgkii (Mont. & Berk.) Torrend, Brotéria View in CoL , sér. bot. 18: 140 (1920). Figs. 7 h View FIGURE 7 , 8 f View FIGURE 8

≡ Polyporus schomburgkii Mont. & Berk., London View in CoL Journal of Botany 3: 331 (1844)

Description:— Furtado (1981) and Ryvarden (2004).

Substrate:—Growing out of soil but associated with roots.

Distribution:—The species seems to be the most common Amauroderma in the neotropics, occurring from South Brazil to Central America. In Brazil, it has been recorded from the Amazon, Atlantic Forest and Cerrado ( Furtado 1981, Ryvarden 2004, Campacci & Gugliotta 2009, Gugliotta et al. 2015).

Specimens examined:— BRAZIL. Mato Grosso: Chapada dos Guimarães, Parque Nacional da Chapada dos Guimarães, Sítio Véu da Noiva , 10 March 2013, Alves-Silva GAS393 About GAS ( FLOR 52176 About FLOR ) ; 10 March 2013, Alves-Silva GAS401 About GAS ( FLOR 52175 About FLOR )

Comments:—This species is recognized by its brown context with dark bands, pileipellis as a cortex, small pores (5–7/mm) and globose to sub-globose (rarely broadly ellipsoid) basidiospores [(8) 9–12 × (7) 9–11 μm]. Amauroderma exile and A. sprucei also have small pores and similarly shaped basidiospores. However, A. exile has a shiny, reddish brown and flexible pileus, distinct from A. schomburgkii , which usually presents a dull and hard basidiomata. Amauroderma sprucei is easily distinguished by its whitish context, vivid orange pore surface in some specimens, dextrinoid skeletal hyphae and a pileipellis as a crust.

Corner (1983) studied some specimens that he called A. schomburgkii A and A. schomburgkii B, with a distinct distribution in Brazil (the A in Amazonia, the B in Atlantic rain forest), but both had subglobose basidiospores (9–11.5 x 8–10.5 μm), different to the information given by Furtado (1981), Ryvarden (2004) and Gomes-Silva et al. (2015), in which the shape is described as globose with a variation in the diameter (between 7–11 μm, in general). As we have obtained the Q = 1.00–1.12 (1.20), ave-Q = 1.09, we describe the shape as globose to subglobose (rarely broadly ellipsoid).