Micromorphological Features of Brown Rotted Wood Revealed by Broad Argon Ion Beam Milling

Overview

Journal Sci Rep

Specialty Science

Date 2024 Dec 31

PMID 39738786

Authors

Rikako Tsukida

Tomohiro Hatano

Yuka Kojima

Satoshi Nakaba

Yoshiki Horikawa

Ryo Funada

Barry Goodell

Makoto Yoshida

Affiliations

Soon will be listed here.

Abstract

Brown rot fungi, the major decomposers in the boreal coniferous forests, cause a unique wood decay pattern but many aspects of brown rot decay mechanisms remain unclear. In this study, decayed wood samples were prepared by cultivation of the brown rot fungi Gloeophyllum trabeum and Coniophora puteana on Japanese coniferous wood of Cryptomeria japonica, and the cutting planes were prepared using broad ion beam (BIB) milling, which enables observation of intact wood, in addition to traditional microtome sections. Samples were observed using field-emission SEM revealing that areas inside the end walls of ray parenchyma cells were the first to be degraded. Osmium reaction precipitates were observed in the degraded regions, as well as in plasmodesmata. In the cell wall where ray parenchyma cells contacted with the tracheids, specific degradation of cross-field pits and hyphal elongation into this area was observed in degradation by both fungi. Other pit types were also degraded as noted in previous studies. Delamination between the S and S layers of tracheids, and cracks in the tracheid cell walls were observed. These findings provide new insights into the cell wall degradation mechanisms during the incipient stages of brown rot decay.

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