Involvement of the Phospholipid Sterol Acyltransferase1 in Plant Sterol Homeostasis and Leaf Senescence

Genes encoding sterol ester-forming enzymes were recently identified in the Arabidopsis (Arabidopsis thaliana) genome. One belongs to a family of six members presenting homologies with the mammalian Lecithin Cholesterol Acyltransferases. The other one belongs to the superfamily of Membrane-Bound O-Acyltransferases. The physiological functions of these genes, Phospholipid Sterol Acyltransferase1 (PSAT1) and Acyl-CoA Sterol Acyltransferase1 (ASAT1), respectively, were investigated using Arabidopsis mutants. Sterol ester content decreased in leaves of all mutants and was strongly reduced in seeds from plants carrying a PSAT1-deficient mutation. The amount of sterol esters in flowers was very close to that of the wild type for all lines studied. This indicated further functional redundancy of sterol acylation in Arabidopsis. We performed feeding experiments in which we supplied sterol precursors to psat1-1, psat1-2, and asat1-1 mutants. This triggered the accumulation of sterol esters (stored in cytosolic lipid droplets) in the wild type and the asat1-1 lines but not in the psat1-1 and psat1-2 lines, indicating a major contribution of the PSAT1 in maintaining free sterol homeostasis in plant cell membranes. A clear biological effect associated with the lack of sterol ester formation in the psat1-1 and psat1-2 mutants was an early leaf senescence phenotype. Double mutants lacking PSAT1 and ASAT1 had identical phenotypes to psat1 mutants. The results presented here suggest that PSAT1 plays a role in lipid catabolism as part of the intracellular processes at play in the maintenance of leaf viability during developmental aging.Sterols are components of most eukaryotic membranes; as such, they are important regulators of membrane fluidity and thus influence membrane properties, functions, and structure (Demel and De Kruyff, 1976; Bloch, 1983; Schuler et al., 1991; Roche et al., 2008). Unlike animals, in which cholesterol is most often the unique end product of sterol biosynthesis, each plant species has its own distribution of sterols, with the three most common phytosterols being sitosterol, stigmasterol, and campesterol (Benveniste, 2004). In addition to their free sterol form, phytosterols are also found as conjugates, particularly fatty acyl sterol esters (SE). Since SE are hardly integrated into the bilayer of the membranes (Hamilton and Small, 1982), the biochemical process of sterol acylation is believed to play a crucial role in maintaining free sterol concentration in the cell membranes (Lewis et al., 1987; Dyas and Goad, 1993; Chang et al., 1997; Sturley, 1997; Schaller, 2004). In other words, SE are generally thought to constitute a storage pool of sterols when those are present in amounts greater than immediately required for the cells. For instance, in plants, accumulation of SE has been described during seed maturation and senescence or when plant cell cultures reach stationary phase (Dyas and Goad, 1993, and refs. therein) as well as in mutant lines overproducing sterols (Gondet et al., 1994; Schaller et al., 1995).In mammals and yeast, the genes involved in sterol esterification have been known for a long time. These genes encode two types of enzymes responsible for the formation of SE in animals, the Acyl-Coenzyme A:Cholesterol Acyltransferase (ACAT) and the Lecithin:Cholesterol Acyltransferase (LCAT). ACAT, which catalyzes an acyl-CoA-dependent acylation, is a membrane-bound enzyme acting inside the cells (Chang et al., 1997). LCAT, which is evolutionarily unrelated to ACAT, catalyzes transacylation of acyl groups from phospholipids to sterols. It is a soluble enzyme present in the blood stream, where it is an important regulator of circulating cholesterol (Jonas, 2000). The budding yeast Saccharomyces cerevisiae has two enzymes of the ACAT type for the synthesis of SE (Yang et al., 1996).In plants, genes encoding enzymes responsible for SE formation have long been unknown. Based on biochemical studies, it was suggested that phospholipids and/or neutral lipids could serve as acyl donors (Garcia and Mudd, 1978a, 1978b; Zimowski and Wojciechowski, 1981a, 1981b). The identification in the Arabidopsis (Arabidopsis thaliana) genome of two genes involved in sterol esterification was based on homology searches. First, the phospholipid:sterol acyltransferase gene AtPSAT1 (At1g04010) was found to display consistent identity with the mammalian LCAT and then was biochemically characterized by expression in Arabidopsis (Noiriel, 2004; Banas et al., 2005). The encoded protein was shown to be associated with microsomal membranes and to catalyze the transfer of unsaturated fatty acyl groups from position sn-2 of phosphatidylethanolamine (and phosphatidylcholine to a lesser extent) to sterols. The preferred acceptor molecules of PSAT1 were cholesterol, a minor biosynthetic end product in Arabidopsis, then campesterol and sitosterol, the two main end products. Sterol coincubation studies performed with this microsomal enzymatic assay showed that sterol precursors such as cycloartenol or obtusifoliol, which were poor substrates when incubated alone, were preferentially acylated in the presence of sitosterol, suggesting an activation of the enzyme by sitosterol (Banas et al., 2005). Another sterol acyltransferase gene, AtASAT1 (At3g51970), was identified in a survey of members of the Arabidopsis superfamily of membrane-bound O-acyltransferases with a yeast ACAT mutant functional complementation approach (Chen et al., 2007). AtASAT1 encodes a protein structurally related to the animal and yeast ACATs. This enzyme was shown to prefer saturated fatty acyl-CoAs as acyl donors and cycloartenol as the acyl acceptor. Overexpression of AtASAT1 in seeds of Arabidopsis resulted in a strong accumulation of cycloartenol fatty acyl esters accompanied by an increase of the whole SE content of these seeds and, in spite of a slight decrease of the free sterol pool, an increase of the total sterol content of the transgenic seeds by up to 60% compared with that of the wild type (Chen et al., 2007). We took advantage of the availability of Arabidopsis T-DNA insertion mutants of these two genes to investigate their respective physiological roles. Here, we report on the involvement of AtPSAT1 in leaf senescence, its major contribution to SE formation in leaves and seeds, and also its essential role in free sterol homeostasis in these organs.