Abstract

Sugar alcohols (polyols) are abundant carbohydrates in lichen-forming algae and transported to other lichen symbionts, fungi, and bacteria. Particularly, ribitol is an abundant polyol in the lichen Cetraria sp. Polyols have important physiological roles in lichen symbiosis, but polyol utilization in lichen-associated bacteria has been largely unreported. Herein, we purified and characterized a novel ribitol dehydrogenase (RDH) from a Cetraria sp.-associated bacterium Sphingomonas sp. PAMC 26621 grown on a minimal medium containing D-ribitol (the RDH hereafter referred to as SpRDH). SpRDH is present as a trimer in its native form, and the molecular weight of SpRDH was estimated to be 39 kDa by SDS-PAGE and 117 kDa by gel filtration chromatography. SpRDH converted D-ribitol to D-ribulose using NAD+ as a cofactor. As far as we know, SpRDH is the first RDH belonging to the medium-chain dehydrogenase/reductase family. Multiple sequence alignments indicated that the catalytic amino acid residues of SpRDH consist of Cys37, His65, Glu66, and Glu157, whereas those of short-chain RDHs consist of Ser, Tyr, and Lys. Furthermore, unlike other short-chain RDHs, SpRDH did not require divalent metal ions for its catalytic activity. Despite SpRDH originating from a psychrophilic Arctic bacterium, Sphingomonas sp., it had maximum activity at 60°C and exhibited high thermal stability within the 4–50°C range. Further studies on the structure/function relationship and catalytic mechanism of SpRDH will expand our understanding of its role in lichen symbiosis.

Highlights

  • Lichens have traditionally been considered a symbiotic association between fungi and either algae or cyanobacteria

  • PAMC 26621 thrived only on D-ribitol among the examined polyols with a four-day longer lag phase compared with that on D-glucose but reached a similar plateau to that observed with D-glucose (Fig 1)

  • The results indicate that SpRDH converts D-ribitol into D-ribulose with a relatively high catalytic efficiency (Table 3)

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Summary

Introduction

Lichens have traditionally been considered a symbiotic association between fungi (mycobionts) and either algae or cyanobacteria (photobionts). Recent studies demonstrated that non-photosynthetic bacteria are an integral part of lichens [1,2,3,4]. Photobionts synthesize and transport carbohydrates to mycobionts and bacteria; cyanobacteria release glucose while green algae liberate sugar alcohols (polyols) such as D-ribitol, Meso-erythritol, and D-sorbitol [5, 6]. Fungi and bacteria supply nutrients (nitrogen, phosphorus, iron, and sulfur) and vitamins to photobionts [7, 8].

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