Sulfoquinovose Metabolism in Marine Algae

Sulfoquinovose Metabolism in Marine Algae

Botanica Marina 2021; 64(4): 301–312 Research article Sabine Scholz (nee´ Lehmann), Manuel Serif, David Schleheck, Martin D.J. Sayer, Alasdair M. Cook and Frithjof Christian Küpper* Sulfoquinovose metabolism in marine algae https://doi.org/10.1515/bot-2020-0023 Keywords: Ectocarpus; Flustra foliacea; isethionate; sul- Received April 17, 2020; accepted April 28, 2021; foquinovose; taurine. published online July 19, 2021 Abstract: This study aimed to survey algal model organ- isms, covering phylogenetically representative and ecolog- 1 Introduction ically relevant taxa. Reports about the occurrence of sulfonates (particularly sulfoquinovose, taurine, and ise- Sulfonates are widespread both as xenobiotic compounds thionate) in marine algae are scarce, and their likely rele- and natural products, yet knowledge about the biosyn- vance in global biogeochemical cycles and ecosystem thesis of the latter remains limited. Biotechnological in- functioning is poorly known. Using both field-collected terest in sulfonates relates to their property as surfactants seaweeds from NW Scotland and cultured strains, a com- (Singh et al. 2007; Van Hamme et al. 2006) and the need for bination of enzyme assays, high-performance liquid chro- their biodegradability due to their widespread application matography and matrix-assisted laser-desorption ionization and entry into the environment (Kertesz and Wietek 2001). time-of-flight mass spectrometry was used to detect key Benson and colleagues isolated a sulfolipid from higher sulfonates in algal extracts. This was complemented by plants and photosynthetic microorganisms, including the bioinformatics, mining the publicly available genome unicellular green algae Chlorella and Scenedesmus and the sequences of algal models. The results confirm the wide- purple nonsulfur bacterium Rhodospirillum (Benson et al. spread presence of sulfonates and their biosynthetic path- 1959). The polar head group was identified as sulfoquino- ways in macro- and microalgae. However, it is also clear that vose (SQ, Figure 1) and the structure of the sulfolipid was catabolic pathways, if present, must be different from those elucidated as sulfoquinovosyldiacylglycerol (SQDG; Ben- documented from the bacterial systems since no complete son 1963; Daniel et al. 1961). SQ is produced in quantities cluster of gene homologues of key genes could be detected estimated at some 10 billion tonnes annually (Goddard- in algal genomes. Borger and Williams 2017). Its biosynthesis in photosyn- thetic organisms has recently been reviewed. The available evidence is consistent with the biosynthesis of SQDG from uridine diphosphate (UDP)-glucose and sulfite in a two- step process via UDP-SQ (Goddard-Borger and Williams 2017). It turned out that SQDG plays a significant role in the Sabine Scholz (nee´ Lehmann) and Manuel Serif contributed equally to biological sulfur cycle, where it can represent up to 50% of this work. sulfur in plants and green algae. Especially in photosyn- *Corresponding author: Frithjof Christian Küpper, Scottish thetic plant tissues, SQDG concentrations of 1–6 mM are Association for Marine Science, Oban, Argyll, PA37 1QA, Scotland, UK; observed (Benson 1963). In general, the estimated value for and Present address: School of Biological Sciences, Cruickshank global biosynthesis of SQDG is about 3.6 × 1010 tons per Bldg, University of Aberdeen, St. Machar Drive, Aberdeen AB24 3UU, year (Harwood and Nicholls 1979). It has long been thought Scotland, UK, E-mail: [email protected] that SQDG plays a role in photosynthesis because of its Sabine Scholz (nee´ Lehmann) and Manuel Serif, Department of Biology, University of Konstanz, D-78457 Konstanz, Germany; and general occurrence in plants but also in photosynthetic Scottish Association for Marine Science, Oban, Argyll, PA37 1QA, bacteria and some flagellates (Harwood and Nicholls 1979). Scotland, UK However, many photosynthetic bacteria almost or entirely David Schleheck and Alasdair M. Cook, Department of Biology, lack the compound, whereas SQDG is found in several non- University of Konstanz, D-78457 Konstanz, Germany photosynthetic organisms. For example, it has been found Martin D.J. Sayer, NERC National Facility for Scientific Diving, Scottish Association for Marine Science, Oban, Argyll, PA37 1QA, Scotland, UK; in the symbiotic soil bacterium Sinorhizobium meliloti and Tritonia Scientific Ltd., Dunstaffnage Marine Laboratories, (Cedergren and Hollingsworth 1994) and in eggs and sperm Dunbeg, Oban, Argyll, PA37 1QA, Scotland, UK cells of the sea urchin Pseudocentrotus depressus (Isono 302 S. Scholz (nee´ Lehmann) et al.: Algal sulfonate metabolism et al. 1967). Analysis of mutants lacking SQDG biosynthesis (Roy et al. 2003), and Denger and colleagues identified the suggested that SQDG has no essential role in photosyn- genes, enzymes and intermediates of the core pathway of thesis but rather acts as a surrogate for anionic phospho- bacterial degradation of SQ in Escherichia coli K-12 MG1655 to lipids during phosphate limitation and is required for quantitative amounts of 2,3-dihydroxypropane-1-sulfonate proper protein import into chloroplasts (Benning 1998; (DHPS), which is completely degraded by other bacteria un- Güler et al. 1996). The conclusion was that SQDG is required der aerobic as well as anaerobic conditions (Burrichter et al. for chloroplast stabilization and function (Yu and Benning 2018; Denger et al. 2014; Figures 2, 3). Another bacterial 2003). As already mentioned, SQDG concentrations are high pathway involves SQ-dehydrogenase which has been found in plant cells, thus it does not seem surprising that it also in Pseudomonas putida SQ1 (Felux et al. 2015) and quantita- serves as an internal sulfur source for protein biosynthesis tively excretes 3-sulfolactate. The latter is also degraded by during sulfur starvation in Chlamydomonas reinhardtii otherbacterialcommunities(Dengeretal.2012;Reinetal. (Sugimoto et al. 2007). Analytical methods in use for the 2005). A third pathway has been described recently, detection and analysis of SQDG include thin-layer chroma- involving a 6-deoxy-6-sulfofructose trans-aldolase step in tography (TLC), nuclear magnetic resonance (NMR) spec- Bacillus spp. and other Firmicutes bacteria (Frommeyer et al. troscopy, gas chromatography (GC)–mass spectrometry 2020; Liu et al. 2020). (MS) following saponification and derivatization, and tan- As little free SQ was observed in plant extracts, the dem mass spectrometric methods (reviewed by Goddard- compound appeared to be readily metabolized in the plant Borger and Williams 2017). cell (Benson 1963). Furthermore, sulfolactate, DHPS, sulfo- At this point, considering its abundance in nature, the lactaldehyde and presumably cysteate from SQDG were question arises as to how the sulfolipid, or at least SQ, is detected in the green alga Chlorella (Shibuya et al. 1963). degraded? Two major sulfoglycolytic pathways have been SQDG has furthermore been observed in red algae of the discovered in recent years for SQ degradation, the sulfo- genus Gracilaria (Araki et al. 1990) and in several brown Embden–Meyerhof–Parnas (sulfo-EMP) and sulfo-Entner– algae including Ishige okamurai, Colpomenia sinuosa, Doudoroff (sulfo-ED) pathways,whichmirrorthemajorsteps Endarachne binghamiae, Scytosiphon lomentaria, Undaria in the glycolytic EMP and ED pathways. Sulfoglycolysis pro- pinnatifida, Eisenia bicyclis, Dictyota dichotoma, Pachy- duces C3-sulfonates, which undergo biomineralization to dictyon coriaceum, Padina arborescens, Hizikia fusiformis, inorganic sulfur species, completing the sulfur cycle (God- Sargassum horneri, S. ringgoldianum and S. thunbergii (Araki dard-Borger and Williams 2017). The catabolism of SQDG to et al. 1991). Isethionate (Ise) is found at high concentrations SQ involves a rapid hydrolysis by plant acyl hydrolases to (<0.001–1.70% dry weight) in red algae (Barrow et al. 1993; form the deacylated product sulfoquinovosylglycerol (SQG, Holst et al. 1994). In the red alga Grateloupia turuturu,ise- Figure 1, reaction 1; Benson 1963; Shibuya et al. 1963), which thionate has been reported to inhibit the settlement of is further attacked by β-galactosidase yielding SQ (Figure 1, Balanus amphitrite cyprid larvae (Hellio et al. 2004). While reaction 2; Shibuya and Benson 1961). Roy and colleagues taurine occurs only in traces in the plant kingdom, sea proposed an SQ degradation pathway based on the consid- weeds have relatively high concentrations (0.01% of wet eration that SQ is an analogue of glucose 6-phosphate weight; Huxtable 1992). Although taurine and presumably Figure 1: Catabolism of the plant sulfur lipid sulfoquinovosyldiacylglycerol to sulfoquinovose in Escherichia coli K-12 MG1655, based upon Denger (2014). S. Scholz (nee´ Lehmann) et al.: Algal sulfonate metabolism 303 biomass, CO2 pyruvate O OH OH dihydroxy-acetone- OH phosphate OH 2- homo- OH OPO3 taurine - O SO3 6-deoxy- (APS) 6-deoxy- 6-sulfofructose + 6-sulfofructose NH3 YihR -1-phosphate sulfoquinovose OH OPO 2- (= 6-deoxy-6-sulfoglucose) O 3 - 2,3-dihydroxy- SO - SO3 3 OH O O propane- O YihS OH YihV OH sulfonate OH OH OH YihT (DHPS) OH OH ADP OH O O OH ATP OH OH OH OH OH YihU OH OH NAD(P)H + - - - - NAD(P) - - SO3 SO3 SO3 SO3 SO3 SO3 3-sulfo- 3-sulfo- lactaldehyde propanal NAD+ NADH cysteate 3-sulfopyruvate 3-sulfolactate - - O O O- O O + O NH2 O OH - SO glutamate - NADH + 3 2-oxo- SO3 NAD SO - glutarate 3 CO2 + O NADH NAD NADH NAD+ O- O OH isethionate - - - SO3 SO3 SO3 sulfoacetate sulfoacetaldehyde alanine pyruvate + NH2

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