Ethanolamine synthesis

In prokaryotes, phosphatidylserine is made from CDP-diacylglycerol (see fig. 19.3). The enzyme for this reaction is absent in animal cells, which rely on a base exchange reaction in which serine and ethanolamine are interchanged (fig. 19.8). Although the reaction is reversible, it usually proceeds in the direction of phosphatidylserine synthesis. Phosphatidylserine can be converted back to phos-phatidylethanolamine by a decarboxylation reaction in the mitochondria. This may be the preferred route for phosphatidylethanolamine biosynthesis in some animal cells. Furthermore these two reactions (see fig. 19.8) establish a cycle that has the net effect of converting serine into ethanolamine. This is the main route for ethanolamine synthesis... 

Cuprous chloride ethanolamine Synthesis of polyhalides from ethylene derivs. 

Phosphatidylethanolamine synthesis begins with phosphorylation of ethanol-amine to form phosphoethanolamine (Figure 25.19). The next reaction involves transfer of a cytidylyl group from CTP to form CDP-ethanolamine and pyrophosphate. As always, PP, hydrolysis drives this reaction forward. A specific phosphoethanolamine transferase then links phosphoethanolamine to the diacylglycerol backbone. Biosynthesis of phosphatidylcholine is entirely analogous because animals synthesize it directly. All of the choline utilized in this pathway must be acquired from the diet. Yeast, certain bacteria, and animal livers, however, can convert phosphatidylethanolamine to phosphatidylcholine by methylation reactions involving S-adenosylmethionine (see Chapter 26). 

Write a balanced, stoichiometric reaction for the synthesis of phosphatidylethanolamine from glycerol, fatty acyl-CoA, and ethanolamine. Make an estimate of the AG° for the overall process. 

Also the impact of various reaction parameters on enzymatic synthesis of amide surfactants from ethanolamine and diethanolamine has been studied, although the possibilities of acyl migration are not investigated. However, it was found that the selectivity of the reaction depended on the solubility of the product in the solvent used, and that the choice of solvent was critical to obtain an efficient process [17]. 

Selective synthesis of ethylenediamine from ethanolamine over modified H-mordenite catalyst... 

The synthesis of ethylenediamine (EDA) from ethanolamine (EA) with ammonia over acidic t3pes of zeolite catalyst was investigated. Among the zeolites tested in this study, the protonic form of mordenite catalyst that was treated with EDTA (H-EDTA-MOR) showed the highest activity and selectivity for the formation of EA at 603 K, W/F=200 g h mol, and NH3/ =50. The reaction proved to be highly selective for EA over H-EDTA-MOR, with small amounts of ethyleneimine (El) and piperazine (PA) derivatives as the side products. IR spectroscopic data provide evidence that the protonated El is the chemical intermediate for the reaction. The reaction for Uie formation of EDA from EA and ammonia required stronger acidic sites in the mordenite channels for hi er yield and selectivity. 

An important feature of the antibiotic chloramphenicol (9) is the presence of the dichloroacetamide function. Inclusion of this amide in a simpler molecule, teclozan (15), leads to a compound with antiamebic activity. Whether this is cause and effect or fortuitous is unclear. The synthesis begins with alkylation of the alkoxide derived from ethanolamine (10) with ethyl iodide to give the aminoether (11). Reaction of a,a -dibromo-p-xylene (12) with 2-nitropropane in the presence of base leads to dialdehyde (13). The reaction probably proceeds by O-alkylation on the nitropropyl anion... 

Zandbergen, P., van den Nieuwendijk, A.M.C.H., Brussee, J. et al. (1992) A one-pot reduction-transimition-reduction synthesis of JV-substituted /8-ethanolamines from cyanohydrins. Tetrahedron, 48, 3977-3982. 

Synthesis of 1-boraadamantane adducts with ethanolamine, L-phenylalanine, L-cysteine and and L-leucine methyl esters was reported (Table 3). The structures of three of them were supported by X-ray analysis (Table 1) <2003JME2823>. 

The method can be used for the synthesis of functionalized isocyanide complexes, e.g., reaction with ethanolamine produces a 2-hydroxy-ethylisocyanide complex,... 

Several recent articles describe the ring-opening of chiral epoxides under microwave irradiation conditions (see also Scheme 6.103). In the context of the preparation of novel /32-adrenoceptor agonists related to formoterol and salmeterol, Fairhurst and a team from Novartis have described the synthesis of chiral ethanolamines by solvent-free microwave-assisted ring-opening of a suitable chiral epoxide precursor with secondary benzylated amines (Scheme 6.129) [262]. At 110 °C, the reaction occurred... 

Anandamide is believed to be synthesized from a phospholipid precursor, /V-arachidonoyl-phosphatidylethanolamine, catalysed by phospholipase D (Di Marzo et al. 1998). The other proposed route of synthesis is from condensation of arachidonic acid and ethanolamine, although this has yet to be demonstrated in living cells. 2-AG is formed in a calcium-dependent manner, and mediated by the enzymes phospholipase C and diacylglycerol lipase (Kondo et al. 1998 Stella et al. 1997). 

Figure 1. Synthetic pathway for PS and PE in mammalian cells. The major steps occuring in the synthesis and interconversion of PS and PE are shown. The PS synthases condense serine with a phosphatidyl moiety derived from PC and PE. The nascent PS can be converted to PE by decarboxylation. PE can also be formed by transfer of a phosphoethanolamine moiety from CDP-ethanolamine to diacylglycerol via the Kennedy pathway. The abbreviations used are PC, phosphatidylcholine PS, phosphatidylserine PE, phosphatidylethanolamine DG, diacylglycerol PSD, phosphatidylserine decarboxylase PSS, PS synthase.

ET), which catalyzes the formation of CDP-ethanolamine, and (iii) an ethanolaminephosphotransferase (EPT), which finally synthesizes PE from DAG and CDP-ethanolamine. As discussed rmder PC synthesis, four enzymes have been cloned that can phosphorylate ethanolamine, two of which preferentially use ethanolamine as a substrate, and two which are more specific for choline. Only one isoform of ET has been cloned, which contains two active sites, but seems to be not as strictly regulated compared to its counterpart CT (Bladergroen et al, 1999a). 

Figure 2. Effect of Ca-ceramide on phosphatidylcholine and phosphatidylethanolamine synthesis in rat-2 fibroblasts. Cells were treated for 2 h in the absence (open bars) or presence (hatched bars) of 25pM C6-ceramide and the following parameters were determined i) the incorporation of [ H]choline and [ H]ethanolamine into phosphatidylcholine (PC) and phosphatidylethanolamine (PE), respectively (panel A) and in CDP-choline and CDP-ethanolamine, respectively (panel B) and ii) the in vitro activity of choline- and ethanolaminephosphotransferase (CPT and EPT) (panel C).

Treatment of Rat-2 fibroblasts with various cell-permeable ceramides resulted, as discussed above, in a rapid inhibition of phospholipid synthesis. An intriguing observation was that C2-ceramides inhibited PC biosynthesis without affecting the synthesis of PE via the CDP-ethanolamine route. C2-ceramide are well known inducers of apoptosis and inhibit DNA- and protein synthesis (Obeid et al, 1993 Jayadev et al, 1995). C2-ceramide induced apoptosis in the rat-2 fibroblasts (Houweling et al, unpublished data), suggesting that inhibition of PE biosynthesis is not a prerequisite for apoptosis. 

Using N-terminus modified polylysine, we developed a synthesis for an amphiphilic polychelator, A,a-(DTPA-polylysyl)glutaryl phosphatidyl ethanolamine (DTPA-PL-NGPE). This polychelator was incorporated into the liposomal membrane and micelle core during liposome or micelle preparation. This system sharply increased the number of chelated Gd atoms attached to a single lipid anchor. This increased the number of bound reporter metal atoms per vesicle and decreased the dosage of an administered... 

Figure 2 (continued) (b) Synthesis of amphiphilic DTPA-PL-NGPE consisting of hydrophilic DTPA-polylysyl moiety and hydrophobic A-glutaryl phosphatidyl ethanolamine moiety [1]. 

The anaemia in B deficiency is caused by an inability to produce sufficient of the methylating agent S-adenosyhnethionine. This is required by proliferating cells for methyl group transfer, needed for synthesis of the deoxythymidine nucleotide for DNA synthesis (see below and Chapter 20). This leads to failure of the development of the nucleus in the precursor cells for erythrocytes. The neuropathy, which affects peripheral nerves as well as those in the brain, is probably due to lack of methionine for methyl transfer to form choline from ethanolamine, which is required for synthesis of phosphoglycerides and sphingomyelin which are required for formation of myelin and cell membranes. Hence, the neuropathy results from a... 

Methionine, which is involved in methyl group donation for nucleotide synthesis, methylation of bases in DNA (Chapter 20) and conversion of choline to ethanolamine for membrane synthesis (Chapter 11). 

One simple example of chloride-catalyzed nitration is the synthesis of the energetic plasticizer Bu-NENA (34) from the nitration of n-butyl ethanolamine (33) with a mixture of acetic anhydride-nitric acid to which catalytic zinc chloride has been added. ... 

Piperazine Piperazine (38.1.12) is a bulk product in organic synthesis. It is made from ethanolamine by heating it in ammonia at a temperature of 150-220°C and a pressure of 100-250atm. It is used as a drug in the form of a salt, and as a rule, in the form of adipinate [12,13],... 

Corticosteroids also affect adrenomeduUary function by increasing epinephrine production the mechanism is exertion of a stimulatory action on two of the enzymes that regulate catecholamine synthesis, tyrosine hydroxylase, the rate-Umiting enzyme, and phenyl-ethanolamine Af-methyltransferase, which catalyzes the conversion of norepinephrine to epinephrine. Steroids also influence the metabolism of circulating catecholamines by inhibiting their uptake from the circulation by noimeuronal tissues (i.e., extraneuronal uptake see Chapter 9). This effect of corticoids may explain their permissive action in potentiating the hemodynamic effects of circulating catecholamines. 

Induction of DNA single-strand breakage in rat liver after in-vivo exposure to N-nitrosodiethanolamine was demonstrated in three studies and dose-dependent effects were shown. In one of these studies, the DNA strand-breaking potential of 7V-nitroso-diethanolamine was found to be abolished by inhibition of sulfotransferase by 2,6-dichloro-4-nitrophenol. Unscheduled DNA synthesis was not detected in rats or mice in an in-vivo/in-vitro hepatocyte DNA repair assay after treatment with 7V-nitrosodi-ethanolamine. A single study in mice exposed in vivo to 7V-nitrosodiethanolamine did not find any significant induction of structural or numerical chromosomal aberrations or micronuclei in bone-marrow cells. 

Fig. 5. The reaction of ethanolamine-phosphate cytidylytransferase with substrates and analogues. Reaction 1 shows the normal reaction of the enzyme with ethanolamine phosphate (2-aminoethyl phosphate), which is part of the route of phospholipid synthesis. The alternative reaction with 2-aminoethylphosphonate, in parentheses, is used by some marine organisms to insert a C—P bond into their phospholipids. Reaction 2 shows the futile cycle obtained with 2-aminoethylarsonate (59). The symbol -P signifies -P03H2 and its ionized forms, and -P- signifies -P(0)(0H)- and its ionized form (61).

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