Differential effects of plant sterols on water permeability and on acyl chain ordering of soybean phosphatidylcholine bilayers.

Schuler, Isabelle; Milon, Alain; Nakatani, Yôichi; Ourisson, Guy; Albrecht, Anne-Marie; Benveniste, Pierre; Hartman, Marie-Andree

doi:10.1073/pnas.88.16.6926

Cited by 212 publications

(162 citation statements)

References 36 publications

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“…For example, Grandmougin-Ferjani et al (1997) revealed that cholesterol and stigmasterol were able to stimulate the Hþ pump of the ATPase in higher plant plasma membranes. Furthermore, stigmasterol was less efficient in regulating membrane permeability than sitosterol and 24-methylcholesterol (Schuler et al, 1991). Both examples suggest that not all of the functions of the various phytosterols have yet been explored.…”

Section: Introductionmentioning

confidence: 99%

Phytoplankton sterol contents vary with temperature, phosphorus and silicate supply: a study on three freshwater species

Piepho

Martin‐Creuzburg

Wacker

2012

European Journal of Phycology

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The understanding of environmentally induced changes in the biochemical composition of phytoplankton species is of great importance in both physiological studies and ecological food web research. In extensive laboratory experiments we tested the influence of two different temperatures (10 C and 25 C) and a phosphorus supply gradient on the sterol concentrations of the three freshwater phytoplankton species Scenedesmus quadricauda, Cryptomonas ovata and Cyclotella meneghiniana. The diatom C. meneghiniana was additionally exposed to a silicate gradient. In two separate experiments we analysed (1) possible interactive effects of temperature and phosphorus supply and (2) the effect of four phosphorus levels and three silicate levels on algal sterol concentrations. We observed that sterol concentrations were higher at 25 C than at 10 C in S. quadricauda and C. meneghiniana, but were not affected by temperature in C. ovata. Interactive effects of temperature and phosphorus supply on sterol concentrations were found in C. meneghiniana. This presumably was due to the bioconversion of one sterol (24-methylenecholesterol) into another (22-dihydrobrassicasterol). Increasing phosphorus supply resulted in species-specific effects on sterol concentrations, viz. an optimum curve response in S. quadricauda, a saturation curve response in C. meneghiniana and no change in sterol concentration in C. ovata. Effects of silicate supply on the sterols of C. meneghiniana equalled the effects of phosphorus supply. Albeit we did not observe a general trend in the three phytoplankton species tested, we conclude that sterol concentrations of phytoplankton are strongly affected by temperature and nutrient supply. Interactive effects point out the importance of taking into account more than just one environmental factor when assessing the effects of environmentally induced changes on phytoplankton sterol concentrations.

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Section: Introductionmentioning

confidence: 99%

Phytoplankton sterol contents vary with temperature, phosphorus and silicate supply: a study on three freshwater species

Piepho

Martin‐Creuzburg

Wacker

2012

European Journal of Phycology

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“…hyd1-1 and hyd1-2 mutants showed no significant differences. Sitosterol and campesterol are the most abundant sterols in Arabidopsis, each being essential in ordering acyl chains in the membrane lipid bilayer and in regulating membrane permeability; stigmasterol cannot functionally replace either sterol (Schuler et al, 1991;Hartmann, 1998). These results demonstrate the requirement for a functional ⌬8-⌬7 sterol isomerase activity for sterol composition in Arabidopsis and indicate that mutations in sterol isomerase (in hyd1) and in C14 reductase (in hyd2/fk), respectively, result in similar gross changes in sterol profiles.…”

Section: Hyd1 and Hyd2 Are Sterol Biosynthetic Mutantsmentioning

confidence: 99%

hydra Mutants of Arabidopsis Are Defective in Sterol Profiles and Auxin and Ethylene Signaling

et al. 2002

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The hydra mutants of Arabidopsis are characterized by a pleiotropic phenotype that shows defective embryonic and seedling cell patterning, morphogenesis, and root growth. We demonstrate that the HYDRA1 gene encodes a ⌬ 8-⌬ 7 sterol isomerase, whereas HYDRA2 encodes a sterol C14 reductase, previously identified as the FACKEL gene product. Seedlings mutant for each gene are similarly defective in the concentrations of the three major Arabidopsis sterols. Promoter::reporter gene analysis showed misexpression of the auxin-regulated DR5 and ACS1 promoters and of the epidermal cell file-specific GL2 promoter in the mutants. The mutants exhibit enhanced responses to auxin. The phenotypes can be rescued partially by inhibition of auxin and ethylene signaling but not by exogenous sterols or brassinosteroids. We propose a model in which correct sterol profiles are required for regulated auxin and ethylene signaling through effects on membrane function. INTRODUCTIONSterols are essential components of fungal, plant, and animal membranes. They regulate fluidity and interact with lipids and proteins within the membrane, and they are the precursors for the brassinosteroid (BR) hormones in plants (Hartmann, 1998). The sterol biosynthetic pathway in plants, therefore, can be viewed as comprising two parts: one branch produces the bulk membrane sterols (the principal sterols in Arabidopsis being stigmasterol, campesterol, and sitosterol), and the second part represents the BR synthesis branch. Sterol biosynthesis has been well characterized in yeast, supported by a powerful system of genetic analysis. In animals, and more recently in plants, sterol biosynthetic enzyme function has been confirmed via the functional complementation of yeast mutants (Gachotte et al., 1996). Functional analysis of sterol function in plants has involved a range of approaches, but recently, genetic studies have provided useful information on the requirement for particular enzymes in sterol and BR biosynthesis and, for BRs, perception and signal transduction (Clouse, 2000;Diener et al., 2000;Schaeffer et al., 2001).In animals, sterols appear to be important to maintain correct cell-signaling activities. For example, drugs such as the ligand SR31747A, which inhibits the activity of the receptor (emopamil binding protein [EBP], which has ⌬ 8-⌬ 7 sterol isomerase activity), cause defects in a diversity of cellular processes, including the inhibition of mammalian lymphocyte proliferation in response to mitogens (Derocq et al., 1995) and the inhibition of graft rejection in mouse via the modulation of gene expression (Carayon et al., 1995), and they may influence lipoprotein functions leading to immunosuppressive effects (Dussossoy et al., 1999). In plants, a lack of detailed pharmacological studies has precluded analogous investigations of the role of sterols in plant cell biology.However, mutational and transgenic studies have given new insight into the roles of sterols in plant development. sterol methyltransferase1 ( smt1 ) mutants accumulate cholesterol...

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“…1) is the substrate of the first methylation reaction, resulting in 24-methylene cycloartanol (11) [4-71, whereas 24-methylene lophenol (IV) is the preferred substrate for the second methylation, yielding 24-ethylidene lophenol (V) [8,91 (Fig. 1).…”

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confidence: 99%

Identification of Cdnas Encoding Sterol Methyl‐Transferases involved in the Second Methylation Step of Plant Sterol Biosynthesis

Bouvier-Navé

Husselstein

Desprez

et al. 1997

European Journal of Biochemistry

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Two methyl transfers are involved in the course of plant sterol biosynthesis and responsible for the formation of 24-alkyl sterols (mainly 24-ethyl sterols) which play major roles in plant growth and development. The first methyl transfer applies to cycloartenol, the second one to 24-methylene lophenol. Five cDNA clones encoding two Arabidopsis thalianu, two Nicotiana tabacum and one Ricinus communis S-adenosyl-L-methionine (AdoMet) sterol methyltransferases (SMT) were isolated. The deduced amino acid sequences of A. thaliana and N. tabacum SMT are about 80% identical in all possible combinations. In contrast they are about 40% identical with the deduced amino acid sequence of R. communis SMT and the published Glycine max sequence. Both A. thaliana and one N. tabacum SMT cDNAs were expressed in a yeast null mutant erg6, deficient in AdoMet zymosterol C24-methyltransferase and containing C24-non-alkylated sterols. In all cases, several 24-ethylidene sterols were synthesized. A thorough study of the sterolic composition of erg6 expressing the A. thaliana cDNA 411 (erg6-4118-pYeDP60) showed 24-methylene and 24-ethylidene derivatives of 4-desmethy1, 4a-methyl and 4,4-dimethyl sterols as well as 24-methyl and 24-ethyl derivatives of 4-desmethyl sterols. The structure of 5a-stigmasta-8, Z-24(24')-dien-3P-o1, the major sterol of transformed yeasts, was demonstrated by 400 MHz 'H NMR.Microsomes from erg-6-42 18-pYeDP60 were shown to possess AdoMet-dependent sterol-C-methyltransferase activity. Delipidated preparations of these microsomes converted cycloartenol into 24-methylene cycloartanol and 24-methylene lophenol into 24-ethylidene lophenol, thus allowing the first identification of a plant sterol-C-methyltransferase cDNA. The catalytic efficiency of the expressed SMT was 17-times higher with 24-methylene lophenol than with cycloartenol. This result provides evidence that the A. thuliana cDNA 41 1 (and most probably the 3 plant SMT cDNAs presenting 80% identity with it) encodes a 24-methylene lophenol-C-24l methyltransferase catalyzing the second methylation step of plant sterol biosynthesis.Keywords: plant sterol methyltransferase; yeast transformation; complementation analysis; 24-methylene lophenol ; cycloartenol.Sterols from fungi and higher plants differ from vertebrate sterols by the presence of an extra alkyl group at C24 [l, 21. Whereas most fungi sterols possess a methyl group at C24, higher plants contain both 24-methyl and 24-ethyl sterols. This alkylation of the side chain is catalyzed by S-adenosyl-L-methionine (AdoMet) sterol C-methyltransferases (SMT). In Saccharomyces cerevihiue, the SMT converts zymosterol (IX) into fecosterol (XVI) [3] (Fig. 3). In higher plants, the presence of 24-ethyl sterols results from two distinct methyl transfers from AdoMet [l, 21. According to the chemical structures of intermediCorrespondence to P.

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Differential effects of plant sterols on water permeability and on acyl chain ordering of soybean phosphatidylcholine bilayers.

Cited by 212 publications

References 36 publications

Phytoplankton sterol contents vary with temperature, phosphorus and silicate supply: a study on three freshwater species

Phytoplankton sterol contents vary with temperature, phosphorus and silicate supply: a study on three freshwater species

hydra Mutants of Arabidopsis Are Defective in Sterol Profiles and Auxin and Ethylene Signaling

Identification of Cdnas Encoding Sterol Methyl‐Transferases involved in the Second Methylation Step of Plant Sterol Biosynthesis

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