Established and potential impacts of eukaryotic mycelial decomposers in marine/terrestrial ecotones

Marine mycelial decomposers (eumycotes, members of Kingdom Fungi, and oomycotes, zoosporic members of the Kingdom Protoctista) are highly adapted for capture of solid substrate by pervasion and digestion from within. Thus they exert their influence in areas of large input of litter of vascular plants, especially at some types of terrestrial/marine ecosystemic interfaces (ecotones). Unavailability of methods easily used by general microbial ecologists has hampered progress in the study of marine mycelial decomposers, and there are still pockets of difficulty in this regard (especially for oomycotes). Recently published or refined methods for measuring fungal mass and productivity have begun to allow us to realize the impacts of fungi in marine ecotones. For example, it is now clear that the older paradigm reflecting negligible contribution of microbial mass to litter nitrogen content is false for the standing-decay system of saltmarsh grasses — in these decay systems, fungal mass can account for virtually all of the nitrogen present at some point(s) in the standing-decay period. Another generally held belief about marine fungi has also been reversed — ascomycetes (Fungi) of a saltmarsh grass (smooth cordgrass) clearly do digest lignocellulose under natural-decay circumstances. Much more work is needed to clarify the situation, but at present it appears that major types of marine ecotones (e.g., saltmarshes and mangroves) differ sharply in the balance among major groups of decomposers (eumycotes, oomycotes, and bacteria) with regard to their utilization of vascular-plant litter. In saltmarshes, microbial production in standing grass litter is strongly dominated by fungi, and oomycotes do not show evidence of a substantial role in decomposition. In mangroves, submerged fallen leaves appear to support minor fungal occupancy, but ubiquitous and rapid occupancy by oomycotes (especially Halophytophthora vesicula). Many exciting areas of research are now more open than ever before to marine microbial ecologists interested in working with mycelial decomposers.