From glycosylation disorders to dolichol biosynthesis defects: a new class of metabolic diseases

Polyisoprenoid alcohols are membrane lipids present in every cell, from archaea to higher eukaryotes. They all have in common a function as sugar carrier for protein glycosylation but display a surprising structural diversity between different species and also inside the same organism (Swiezewska and Danikiewicz 2005; Jones et al. 2009). The most common species, dolichol was originally identified by Pennock, Hemming and Morton in 1960 (Pennock et al. 1960). Dolichol phosphate requirement for glycoprotein biosynthesis was established 10 years later by Behrens and Leloir (Behrens and Leloir 1970). During dolichol biosynthesis, isoprenoids are used as a five-carbon building block to generate linear polymers. These polyisoprenoids are not present as species of a single chain length, but are found as a mixture (or family) of four or more different chain lengths, with one or two chain lengths predominating. The size of dolichols (i.e., the mixture of different chain lengths) is variable depending on the species. In the yeast S.cerevisiae, the size ranges from 14 repeating isoprene units to 18 (Dol-14 to Dol-18) and the major dolichols are Dol-16 and Dol-17. A preponderance of Dol-19 has been observed for several vertebrates including human (Chojnacki and Dallner 1988).

Whereas the length of these lipids is variable, the configuration of the double bonds of polyisoprenoids is fixed. All dolichol species characterized so far show a di-trans, poly-cis configuration. This is a consequence of the involvement of two types of enzyme, a short-chain trans-prenyl transferase and a long-chain cis-prenyl transferase (Skorupinska-Tudek et al. 2008). The α-terminal isoprene unit is unsaturated in polyprenol (formerly dehydrodolichol), whereas dolichol contains a saturated α-terminal unit (See Fig. 2). This saturation event is of great interest because it is absent in bacteria but required in many eukaryotic cells (Krag 1998). The terminal hydroxyl group of dolichol may exist either free, phosphorylated or esterified with fatty acids. Depending on the tissue or membrane, dolichyl esters represent 10 to 60% of the total dolichol content and Dol-P in general represents less than 10% (Tollbom and Dallner 1986).

Dolichol biosynthesis is known to occur mainly on the cytoplasmic face of the ER, where N-glycosylation occurs. Besides the presence of glycosylated dolichol species in the ER, dolichol is present in all subcellular membrane systems. The free alcohol, but also phosphorylated and esterified dolichol are detected in peroxisomes and are highly enriched in lysosomes, plasma membrane and Golgi vesicles (Rip et al. 1981). The ER microsomal fraction is low in dolichol compared to other organelles. The mitochondrial membranes and nuclei also contain a limited amount of dolichol, especially low in the mitochondrial inner membrane.

All tissues and almost all membranes in eukaryotic cells contain dolichol. In general, they are present in small absolute quantities, only a few percent compared to glycerol-based phospholipids (Chojnacki and Dallner 1988). However, the amount is highly variable depending on tissue and age (Rip et al. 1985). For example, in human endocrine tissues, this lipid is present in milligram quantities per gram of wet weight, as much as phospholipids. In different species, several organs are highly enriched in dolichol. In human, testes and especially pituitary are associated with high contents of dolichol. Surprisingly, human tissues seem to have levels 5 to 10-fold higher in comparison to the corresponding tissues from rat or mouse, ranging from ~ 0.1-2 mg/g fresh weight in human versus ~ 10-200 μg/g in mouse or rat (Rip and Carroll 1985). Dolichol is also detected in the serum at low concentration, associated with the HDL fraction (Elmberger et al. 1988).

The reason of the specific enrichment of some tissues versus others is unknown, but does not seem to be correlated with the level of glycosylation.

A significant age-related accumulation of dolichol has been reported. In the human brain, a 100-fold increase has been detected during the aging process (Pallottini et al. 2003), a similar increase has been observed in other tissues. These accumulations might also be involved in pathology as elevated dolichol levels have been detected in hepatocarcinogenesis and ceroid lipofuscinosis (Ericsson et al. 1993). However, this accumulation seems to be disrupted in Alzheimer’s disease as a significant reduction of dolichol levels has been detected in patient brains (Edlund et al. 1994).

Phosphorylated dolichol has a well defined role as a lipid carrier for the glycan precursor in the early stages of N-linked protein glycosylation. This precursor is assembled in the endoplasmic reticulum of all eukaryotic cells (Fig. 1). During N-linked protein glycosylation, a first dolichol phosphate is used by the GlcNAc-1-phosphotransferase to start the assembly of the lipid-linked oligosaccharide (LLO) on the cytoplasmic face of the ER. The product of this reaction is elongated to Man₅GlcNAc₂-P-P-Dol and then flipped to the inside of the ER. Then four other dolichol phosphates, previously linked to a mannose (Man-P-Dol) and flipped inside the ER lumen, are used as sugar donor for LLO synthesis. Finally, three dolichol phosphates in the form of dolichol phosphate glucose (Dol-P-Glc) as sugar donor are used for completion of the LLO before transfer of the glycan onto nascent proteins (Fig. 1). In addition to its role during LLO biosynthesis, Man-P-Dol is a necessary substrate for C- and O-mannosylation as well as GPI anchor biosynthesis (Rosenwald et al. 1990).

In comparison to dolichol phosphate, the role of the free alcohol and its carboxylic ester is less established. An important question is the effect of these lipids on the physical properties of biological membranes. Biophysical studies have shown that dolichol and dolichol phosphates destabilize the bilayer structure of model membranes, and also increase their fluidity (Valtersson et al. 1985). Isolated membrane phospholipids may adopt different phases including the lamellar bilayer phase and a phase where phospholipids are arranged as cylinders with the lipid head group facing the inner core of the cylinder, also called hexagonal phase II (Turned and Gruner 1992). Dolichol promotes this hexagonal phase II organization, which may facilitate movements between the two layers of the membrane and may elicit the transmembrane movement of LLOs. This property would add another function for this lipid in the glycosylation process. Another interesting property is the fact that dolichol enhances vesicle fusion and that dolichol phosphate stimulates the fusion of rat liver microsomes (van Duijn et al. 1986). In this way, dolichol might play a more general role in membrane trafficking. In vivo, consequences of dolichol synthesis defects have been investigated in a yeast mutant for the cis-isoprenyltransferase (cis-IPTases) RER2 responsible for the elongation of the polyisoprenoid chain (Sato et al. 1999) (Belgareh-Touze et al. 2003). These studies suggest that free dolichol is involved in vesicle trafficking, a function in agreement with an enrichment of the Golgi apparatus for this lipid.

A specific role for the dolichol-ester has not been clearly established. Besides an effect on membrane properties, the esterified form was suggested to be necessary for intracellular dolichol transport (Tollbom and Dallner 1986; Turunen and Schedin-Weiss 2007). An oxidized derivative of dolichol, dolichoic acid has also been identified in human brain (Ward et al. 2007). It is speculated to result from dolichol catabolism (Van Houte et al. 1997), but its exact function is unknown.

The first steps in the biosynthesis of dolichol are common with those for cholesterol and belong to the mevalonate pathway (Fig. 2). This pathway starts with the condensation of acetyl-CoA, followed by the production of mevalonate through the action of HMG-CoA reductase (Swiezewska and Danikiewicz 2005). After several modifications, isopentenyl pyrophosphate (IPP) is produced. IPP condensation gives rise to farnesyl pyrophosphate (FPP), used as the substrate of many reactions including the synthesis of cholesterol, dolichol, solanesyl pyrophosphate (i.e., the side chain of ubiquinone) and for isoprenylation of proteins.

The in vitro rescue experiment of the LLO synthesis defect in cell extracts from SRD5A3 patients indicates that the adjustment of dolichol phosphate levels in patient cells could theoretically correct the N-glycosylation defect. Polyisoprenoid lipids are present in the diet, polyprenols are abundant in mature plants in contrast with animal tissues that possess dolichols. The contribution of dietary dolichol to the cellular pool of dolichol has been investigated in rat liver. An important part of the cholesterol utilized in metabolic processes is supplied by the diet but for polyisoprenoids, this contribution appeared to be quite limited. It was found that polyisoprenoids supplied orally were taken up through the rat gastrointestinal system; from 0.05% to a few percent of the total (Keller et al. 1982; Jakobsson et al. 1989). The uptake efficiency depends on the form of administration of dolichol and its incorporation into liposomes was found to be the most efficient. The study of the subcellular incorporation revealed that microsomes contain only a few percent of the labeled dietary dolichols. Making a significant part of this exogenous dolichol bioavailable will be an important step to consider some therapeutic options. Some previous studies detected that a fraction of dietary dolichol taken up by the liver was able to be phosphorylated (i.e., about 10% ) and potentially plays a role in protein glycosylation (Jakobsson et al. 1989) (Chojnacki and Dallner 1983).