Phosphatidate, phosphatidic acid biosynthesis

Which of the following are NOT intermediates of phosphatidic acid biosynthesis ... 

Lysophosphatidic acids, the structure of which is given in the next figure, have not yet been isolated from mammalian tissue. However, they are assumed to be intermediates in phosphatidic acid biosynthesis. 

Phosphatidic acids not only are intennediates in the biosynthesis of triacylglycerols but also are biosynthetic precursors of other members of a group of compounds called phosphoglycerides or glycerol phosphatides. Phosphorus-containing derivatives of lipids are known as phospholipids, and phosphoglycerides are one type of phospholipid. 

Phosphatidic acid, the parent compound for the glycerol-based phospholipids (Figure 8.4), consists of 5w-glycerol-3-phosphate, with fatty acids esterified at the T and 2-positions. Phosphatidic acid is found in small amounts in most natural systems and is an important intermediate in the biosynthesis of the more common glycerophospholipids (Figure 8.6). In these compounds, a... 

Phosphatidic acid is glycerol esterified at the sn-1 and sn-2 positions to two fatty acids and at the sn-3 position to phosphoric acid. It is a product of phospholipase D action that is also an intermediate in the biosynthesis of phosphatidylseiine and phosphatidylinositol. 

The first step of triglyceride biosynthesis is the formation of phosphatidic acid with the involvement of glycerophosphate acyltrans-ferase ... 

Two routes to phospholipid biosynthesis are known in either, the participation of CTP is necessary. The first route involves phosphatidic acid in phosphoglyceride biosynthesis. Phosphatidic acid reacts with CTP to yield CDP-diglyceride which, as a coenzyme, can participate in the transfer of diglyceride onto serine (or inositol) to produce phosphatidylserine (or phosphatidylinositol). Serine phosphatides are liable to decarboxylation (pyridoxal phosphate acting... 

Phospholipid turnover also takes place in an asymmetric manner. The enzymes responsible for phospholipid turnover in response to receptor-mediated phospholipase c activation are active from the cytoplasmic surface of the membrane. Likewise, diacylglycerol kinases converting the product of phospholipase c back into the key intermediate of phospholipid biosynthesis, phosphatidic acid, are also located on the cytoplasmic smface of the membrane (Sanjuan et al., 2001). 

A recent report suggests that inhibition of PC synthesis constitutes one of the primary events by which C2-ceramide triggers apoptosis (Ramos et al, 2000). Treatment of cerebral granule neurons with C2-ceramide resulted in a rapid (within 1 hour) reduction in PC biosynthesis, whereas only 6 h after exposure to the agonists the first significant drop in cell viability was observed. The authors further showed that addition of exogenous PC resulted in a dose-dependent full prevention of neuronal death. This was specific for PC, because addition of other glycerohpids Uke, PE, PS, phosphatidylinositol and phosphatidic acid had no effect on C2-ceramide-induced apoptosis. 

Phosphatidates (anions of the phosphatidic acids), the simplest phospholipids, are phosphate esters of diacylglycerol. They are important intermediates in the biosynthesis of fats and phospholipids (see p. 170). Phosphatidates can also be released from phospholipids by phospholipases. 

A second esterification of this type leads to a phosphatidate (enzyme l-acylglycerol-3-phosphate acyltransferase 2.3.1.51). Unsaturated acyl residues, particularly oleic acid, are usually incorporated at C-2 of the glycerol. Phosphatidates (anions of phosphatidic acids) are the key molecules in the biosynthesis of fats, phospholipids, and glycolipids. 

FIGURE 21-18 Phosphatidic acid in lipid biosynthesis. Phosphatidic acid is the precursor of both triacylglycerols and glycerophospholipids. The mechanisms for head-group attachment in phospholipid synthesis are described later in this section. 

Lysophospholipids have been found in butter serum by Cho et al. (1977). They characterized the sn-1 and -2 lysophosphatidylcholines and phosphatidylethanolamines. It is not known if these compounds are products of degradation or remnants of biosynthesis. Cho et al. (1977) searched for, but did not find, another possible product of enzymatic degradation of milk, phosphatidic acid. Phosphatidic acid can be formed by the action of phospholipase D on phosphatidylcholine, for example, but this enzymatic activity was not detected. The compound is also an important intermediate in the biosynthesis of lipids, but the concentration in tissue is always very low. The amount is also low in milk. Cho et al. (1977) found 1.2 and 0.9 (percent of total lipid P) of the lyso compounds above. The quantities of the other phospholipids were phosphatidylethanolamine, 27.3 -choline, 29.1 -serine, 13.4 -inositol, 2.5 and sphingomyelin, 25.6. 

In the first phase of phospholipid synthesis from glyc-erol-3-phosphate to phosphatidic acid, the pathways in E. coli and eukaryotes are very similar (see fig. 19.2). The major difference is that one additional pathway exists for generation of phosphatidic acid from dihydroxyacetone phosphate, an intermediate in glycolysis. Once phosphatidic acid is made, it is rapidly converted to diacylglycerol or CDP-diacylglycerol (see fig. 19.2) both of which are intermediates for the biosynthesis of eukaryotic phospholipids. 

These compounds are well established as important intermediates in the biosynthesis of phosphoglycerides, such as phosphatidylcholine. The fact that they are formed on agonist stimulation of a cell suggested a role in the cell signaling process (Exton, 1990). In addition, over a period of many years, there have been reports on the interrelation of phosphatidic acid formation and cellular responses (Ca2+ movements to agonists, for example). Thus, these compounds have emerged as important components of cellular metabolism and merit serious attention in any metabolic investigation. 

Phosphoglycerides may be synthesized either from phosphatidic add or by the so-called salvage pathway. Phosphatidic acid is also an intermediate in triglyceride biosynthesis (Figure 19.4). The phosphatidic acid pathway is relatively minor in eukaryotes phosphatidic acid reacts with CTP to form CDP diglyceride (see Figure 19.15), and the latter may then react with choline or inositol to form phosphatidylinositol or phosphatidylcholine, as in Equations (19.14) and (19.15). 

Glycerophosphatides. These lipids are mainly acyl derivatives of a-glycerophosphoric acid and often are called phospholipids. The simplest glycerophosphatides are the phosphatidic acids, which contain a-glycerophosphoric acid esterified with two fatty acids (Fig. III-37). Small quantities of phosphatidic acids have been isolated from a wide variety of plant and animal tissues. It is doubtful that these compounds exist in large amounts in tissues, because more complex glycerophosphatides are readily hydrolyzed by enzymes that are widely distributed in such tissues, yielding phosphatidic acids. Phosphatidic acid is a crucial intermediate in the biosynthesis of phospholipids. 

Burstein and Hunter (1995) observed that THC stimulated the biosynthesis of anandamide in neuroblastoma cells employing either ethanolamine or arachidonic acid as the label. Anandamide bios5mthesis has also been shown to occur in primary cultures of rat brain neurons labelled with [H]-ethanolamine when stimulated with ionomycin, a Ca ionophore (Di Marzo et al. 1994). These authors proposed an alternate model for the biosynthesis of anandamide in which N-arachidonoyl phosphatidyl ethanolamine is cleaved by a phospholipase D activity to yield phosphatidic acid and ararchidonoylethanolamide. This model is based upon extensive studies undertaken by Schmid and collaborators (1990), who have shown that fatty acid ethanolamide formation results from the N-acylation of phosphatidyl ethanolamine by a transacylase to form N-acyl phosphatidylethanolamine. Possibly resulting from postmortem changes, this compound is subsequently hydrolyzed to the fatty acid ethanolamide and the corresponding phosphatide by a phosphodiesterase, phospholipase D. 

Fig. 6.15 Formation and function of diacylglycerol. The figure schematically shows two main pathways for formation of diacylglycerol (DAG). DAG can be formed from PtdlnsP2 by the action of phospholipase C (PL-C). Another pathway starts from phosphatidyl choline. Phospholipase D (PL-D) converts phosphatidyl choline to phosphatidic acid (Ptd), and the action of phosphatases results in DAG. Arachidonic acid, the starting point of biosynthesis of prostaglandins and other intracellular and extracellular messenger substances, can be cleaved from DAG. PKC protein kinase C Ptdlns phosphatidyl inositol.

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