Stereochemical studies of hydrogen incorporation from nucleotides with fatty acid synthetase from Brevibacterium ammoniagenes.

The biosynthesis of fatty acids from malonyl-CoA and acetyl-CoA was investigated with an enzyme preparation which was purified 100-fold from Brevibacterium ammoniagenes. Fatty acids synthesized in the presence of D2O and stereospecifically deuterated NADPH and NADH were isolated and analyzed by mass chromatography to examine the localization of deuterium in the molecule. The following results were obtained: 1) HB hydrogen of NADPH was used for beta-ketoacyl reductase. 2) HB hydrogen of NADH was used for enoyl reductase. 3) Hydrogen atoms from water were found on the even-numbered methylene carbon atoms (2-hydrogen atoms per carbon atom) and some were also found on the odd-numbered methylene carbon atoms. 4) Hydrogen atoms from NADPH was found on the odd-numbered methylene carbon atoms (1 hydrogen per carbon). 5) Hydrogen atoms from NADH was also found on the odd-numbered methylene carbon atoms, but the number of incorporated hydrogen atoms was less than expected. The exchange of HB hydrogen of NADH with water catalyzed by enoyl reductase was suspected. 6) The exchange of methylene hydrogen atoms of malonyl-CoA with protons of water was suggested by 13C NMR analysis.     

Stereospecificity of hydrogen transfer by pyridine nucleotide-dependent enoyl reductases in fatty acid synthesis: Studies with enzymes obtained from developing castor bean seeds and Chlorella vulgaris

The mechanism of hydrogen incorporation into fatty acids wasinvestigated with fatty acid synthetase systems from developingcastor bean seeds and Chlorella vulgaris. Fatty acids synthesizedin the presence of D₂O or stereospecifically deuterium-labeledNADPH or NADH were isolated and analyzed by mass spectrometryto examine the localization of deuterium atoms in the molecule.The stereospecificities of ß-ketoacyl-acyl carrierprotein (ACP) reductase and enoyl-ACP reductase for reducedpyridine nucleotide were determined with acetoacetyl-ACP andcrotonyl-ACP as substrates. The products were also analyzedby gas chromatography-mass spectrometry. The following resultswere obtained:

1. ß-Ketoacyl-ACP reductases from both castor bean seedsand C. vulgaris used the B-side hydrogen of NADPH.
2. Enoyl-ACPreductase from C. vulgaris required NADH for the activity.
3. Enoyl-ACPreductase from castor bean seeds used the A-side hydrogenofNADPH, whereas that from C. vulgaris used the B-side hydrogenof NADH.
4. When stearate was synthesized with the crude fattyacid synthetasefraction from castor bean seeds, hydrogen atomsfrom water werefound on the even-numbered methylene carbonatoms (two hydrogenatoms per carbon atom) and some were foundon the odd-numberedmethylene carbon atoms. Hydrogen atoms fromthe B-side of NADPHwere found on the odd-numbered methylenecarbon atoms (one hydrogenatom per carbon atom). Hydrogen atomsfrom the A-side of NADPHwere also found on the odd-numberedmethylene carbon atoms,but the number of incorporated hydrogenatoms was less thanexpected.

(Received October 17, 1979; )     

Studies on the metabolism of unsaturated fatty acids. XII. Reaction catalyzed by 2,4-dienoyl-CoA reductase of Escherichia coli

Incorporation of deuterium atoms from deuterium-labeled NADPH and 2H2O during the reaction catalyzed by 2,4-dienoyl-CoA reductase of Escherichia coli (E. coli) was investigated. When trans-2,cis-4-decadienoyl-CoA was incubated with 4R- or 4S-[4-2H1]NADPH in the presence of purified 2,4-dienoyl-CoA reductase, no deuterium was detected in the reaction product by gas chromatography-mass spectrometry after derivatization to its pyrrolidine amide. On the other hand, when the dienoyl-CoA was incubated in the presence of NADPH and the reductase in 2H2O, two deuterium atoms were incorporated: One deuterium atom was located at the C-4 position of trans-2-decenoate, and the other at the C-5 position. The UV and shorter wavelengths of the visible spectrum of the reductase solution revealed that the reductase contained flavin as a prosthetic group. Therefore it is considered that a hydrogen atom of NADPH was first transferred to the flavin moiety of the reductase, and then the hydrogen atom was rapidly exchanged for one in the medium before its direct transfer to the substrate.     

The stereospecificity of the reduction of nitrate by reduced nicotinamide-adenine dinucleotides catalysed by Candida utilis preparations.

The reduction of nitrate by reduced nicotinamide-adenine dinucleotides, catalysed by extract of Candida utilis, exhibits an apparent high degree of stereospecificity for the 'B' methylene hydrogen atom of NADPH and mixed stereospecificity for the methylene hydrogen atoms of NADH. Purified nitrate reductase, on the other hand, exhibits 'A' stereospecificity for NADH and NADPH. The apparent switch of stereospecificity from the 'B' to the 'A' side of NADPH, which occurs after purification of the enzyme, is partly explained by the fact that in crude extracts nitrate is reduced completely to ammonia. Nitrite does not accumulate but is reduced to ammonia by nitrite dehydrogenase, which is 'B'-specific, so that up to 75% of hydrogen removed from NADPH during the reduction of nitrate could occur from the 'B' side. A further increase in the removal of hydrogen from the 'B' side of NADPH could be the kinetic isotope effect that is observed when ['A'-3H]NADPH is the reductant, the H--C bond being cleaved 2.3 times faster than the 3H--C bond. The mixed stereospecificity observed with NADH has been traced to an uncharacterized enzyme that catalyses a 'B'-specific exchange between NAD+ and NADH. This reaction is discussed in relation to the possibility that it may explain other cases of apparent mixed stereospecificity that have been reported.     

Intersubunit transfer of fatty acyl groups during fatty acid reduction

Fatty acid reduction in Photobacterium phosphoreum is catalyzed in a coupled reaction by two enzymes: acyl-protein synthetase, which activates fatty acids (+ATP), and a reductase, which reduces activated fatty acids (+NADPH) to aldehyde. Although the synthetase and reductase can be acylated with fatty acid (+ATP) and acyl-CoA, respectively, evidence for acyl transfer between these proteins has not yet been obtained. Experimental conditions have now been developed to increase significantly (5-30-fold) the level of protein acylation so that 0.4-0.8 mol of fatty acyl groups are incorporated per mole of the synthetase or reductase subunit. The acylated reductase polypeptide migrated faster on sodium dodecyl sulfate-polyacrylamide gel electrophoresis than the unlabeled polypeptide, with a direct 1 to 1 correspondence between the moles of acyl group incorporated and the moles of polypeptide migrating at this new position. The presence of 2-mercaptoethanol or NADPH, but not NADP, substantially decreased labeling of the reductase enzyme, and kinetic studies demonstrated that the rate of covalent incorporation of the acyl group was 3-5 times slower than its subsequent reduction with NADPH to aldehyde. When mixtures of the synthetase and reductase polypeptides were incubated with [3H] tetradecanoic acid (+ATP) or [3H]tetradecanoyl-CoA, both polypeptides were acylated to high levels, with the labeling again being decreased by 2-mercaptoethanol or NADPH. These results have demonstrated that acylation of the reductase represents an intermediate and rate-limiting step in fatty acid reduction. Moreover, the activated acyl groups are transferred in a reversible reaction between the synthetase and reductase proteins in the enzyme mechanism.     

beta-Oxidation of polyunsaturated fatty acids by rat liver peroxisomes. A role for 2,4-dienoyl-coenzyme A reductase in peroxisomal beta-oxidation

beta-Oxidation of unsaturated fatty acids was studied with isolated solubilized or nonsolubilized peroxisomes or with perfused liver isolated from rats treated with clofibrate. gamma-Linolenic acid gave the higher rate of beta-oxidation, while arachidonic acid gave the slower rate of beta-oxidation. Other polyunsaturated fatty acids (including docosahexaenoic acid) were oxidized at rates which were similar to, or higher than, that observed with oleic acid. Experiments with 1-14C-labeled polyunsaturated fatty acids demonstrated that these are chain-shortened when incubated with nonsolubilized peroxisomes. Spectrophotometric investigation of solubilized peroxisomal incubations showed that 2,4-dienoyl-CoA esters accumulated during peroxisomal beta-oxidation of fatty acids possessing double bond(s) at even-numbered carbon atoms. beta-Oxidation of [1-14C]docosahexaenoic acid by isolated peroxisomes was markedly stimulated by added NADPH or isocitrate. This fatty acid also failed to cause acyl-CoA-dependent NADH generation with conditions of assay which facilitate this using other acyl-CoA esters. These findings suggest that 2,4-dienoyl-CoA reductase participation is essential during peroxisomal beta-oxidation if chain shortening is to proceed beyond a delta 4 double bond. Evidence obtained using arachidionoyl-CoA, [1-14C]arachidonic acid, and [5,6,8,9,11,12,14,15-3H]arachidonic acid suggests that peroxisomal beta-oxidation also can proceed beyond a double bond positioned at an odd-numbered carbon atom. Experiments with isolated perfused livers showed that polyunsaturated fatty acids also in the intact liver are substrates for peroxisomal beta-oxidation, as judged by increased levels of the catalase-H2O2 complex on infusion of polyunsaturated fatty acids.     

What factors are responsible for the greater yield of ATP per carbon atom when fatty acids are completely oxidised to CO2 and water compared with glucose?

Some current textbooks of biochemistry present calculations which indicate that when palmitic or stearic acid is completely oxidised to CO₂ and water, more molecules of ATP are produced per carbon atom than when glucose is similarly oxidised. This greater yield of ATP is not due to ATP produced as a result of the β-oxidative process, but rather due to the increased yield of acetyl-CoA molecules produced from fatty acids (3 acetyl-CoA molecules per 6 carbon atoms) compared with that produced from glucose (2 acetyl-CoA molecules per 6 carbon atoms).     

Purification of the multienzyme complex for fatty acid oxidation from Pseudomonas fragi and reconstitution of the fatty acid oxidation system

The multienzyme complex for fatty acid oxidation was purified from Pseudomonas fragi, which was grown on oleic acid as the sole carbon source. This complex exhibited enoyl-CoA hydratase [EC 4.2.1.17], 3-hydroxyacyl-CoA dehydrogenase [EC 1.1.1.35], 3-oxoacyl-CoA thiolase [EC 2.3.1.16], cis-3,trans-2-enoyl-CoA isomerase [EC 5.3.3.3], and 3-hydroxyacyl-CoA epimerase [EC 5.1.2.3] activities. The molecular weight of the native complex was estimated to be 240,000. Two types of subunits, with molecular weights of 73,000 and 42,000, were identified. The complex was composed of two copies each of the 73,000- and 42,000-Da subunits. The beta-oxidation system was reconstituted in vitro using the multienzyme complex, acyl-CoA synthetase and acyl-CoA oxidase. This reconstituted system completely oxidized saturated fatty acids with acyl chains of from 4 to 18 carbon atoms as well as unsaturated fatty acids having cis double bonds extending from odd-numbered carbon atoms. However, unsaturated fatty acids having cis double bonds extending from even-numbered carbon atoms were not completely oxidized to acetyl-CoA: about 5 mol of acetyl-CoA was produced from 1 mol of linoleic or alpha-linolenic acid, and about 2 mol of acetyl-CoA from 1 mol of gamma-linolenic acid. These results suggested that the 3-hydroxyacyl-CoA epimerase in the complex was not operative. When the epimerase was by-passed by the addition of 2,4-dienoyl-CoA reductase to the reconstituted system, unsaturated fatty acids with cis double bonds extending from even-numbered carbon atoms were also completely degraded to acetyl-CoA.     

Purification of NADPH-dependent enoyl-CoA reductase involved in the malonyl-CoA dependent fatty acid elongation system of Mycobacterium smegmatis

NADPH-Dependent enoyl-CoA reductase [EC 1.3.1.8] was purified to homogeneity, for the first time, from the crude extract of Mycobacterium smegmatis. The molecular weight of this enzyme was estimated to be around 32,000 using sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The purified enzyme reduced 2-trans-hexadecenoyl-CoA (Km value, 100 microM) and -eicosenoyl-CoA (Km value, 83 microM) almost equally well in the presence of NADPH as a sole electron donor. The Km value for NADPH was 34.5 microM. When NADP3H was incubated with 2-eicosenoyl-CoA and the purified enzyme, the sole tritiated product was arachidate. This enzyme was almost inert to enoyl-CoAs with chains less than 12 carbon atoms long. The purified enzyme still retained FMN, which was detectable by acid ammonium sulfate and was essential for full activity of the enzyme. The enzyme was sensitive to SH-reagents such as N-ethylmaleimide and monoiodoacetamide but was not sensitive to isonicotinamide hydrazide. Anti-NADPH-dependent-enoyl-CoA-reductase rabbit serum was found to inhibit the activities of both the reductase and the malonyl-CoA dependent fatty acid elongation system, supporting the involvement of the reductase in this elongation system.     

Deuterium transfer from [1,1-2-H] ethanol during metabolism of bile acids and cyclohexanone in the isolated perfused rat liver.

Deuterium transfer from [1,1-2-H]ethanol (95 atoms % excess) to reducible substrates was studied in the isolated perfused rat liver. The dueterium excess in cyclohexanol formed from cyclohexanone was somewhat lower (49 atoms%) than found under conditions in vivo, and this was also true of the deuterium excess in lithocholic acid formed from 3-oxo-5beta-cholanoic acid. These results may reflect a slower rate of ethanol oxidation in the isolated organ than in vivo. Cycloserine decreased the dueterium transfer to both substrates, whereas addition of lactate and malate resulted in an increased deuterium excess in cyclohexanol and a decreased deuterium excess in lithocholic acid. Addition of heavy water to the perfusion fluid resulted in labelling at C-3 of lithocholic acid formed from 3-oxo-5beta-cholanoic acid, and at C-3, C-4 and C-5 of 3alpha-hydroxy-5alpha-cholanoic acid formed from 3-oxo-4-cholenoic acid. The deuterium excess of hydrogens derived from NADPH (at C-3 and C-5) was approximately the same as that of hydrogen derived directly from water (at C-4). Thus, the hydrogen of NADPH is extensively exchanged with protons of water, which explains the dilution of deuterium with protium during the transfer from [1,1-2-H]ethanol via NADPH to the bile acids. The labelling at C-5 in the reduction of the 4,5-double bond indicates that different pools of NADPH are used for reduction of this double bond and the 3-oxo group, since in a previous study it was shown that deuterium is transferred from [1,1-2-H]ethanol only in the latter reaction.     

The biological conversion of 7-dehydrocholesterol into cholesterol and comments on the reduction of double bonds

It is shown that the 7-dehydrocholesterol reductase-catalysed conversion of 7-dehydrocholesterol into cholesterol (II), with a 105000g microsomal pellet of rat liver in the presence of [4-(3)H(2)]NADPH, results in the transfer of radioactivity to the 7alpha-position of cholesterol. When the conversion is carried out in the presence of tritiated water the label is introduced exclusively at the 8beta-position. However, when the conversion of 7-dehydrocholesterol into cholesterol is performed with a 500g supernatant of rat liver homogenate the radioactivity is incorporated at both the 7alpha- and the 8beta-position. Evidence is provided for the presence of an enzyme system in the 500g supernatant that catalyses an equilibration of hydrogen atoms between those at the 4-position of NADPH and those of water. The work with stereospecifically labelled cofactors shows that both the equilibrating system and the 7-dehydrocholesterol reductase utilize the 4B-hydrogen atom of NADPH. In the light of these results a mechanism for the reduction of carbon-carbon double bonds is discussed.     

Quinone induced stimulation of hexose monophosphate shunt activity in the guinea pig lens: role of zeta-crystallin.

The response of the hexose monophosphate shunt (HMS) in organ-cultured guinea pig lens to 1,2-naphthoquinone and 5-hydroxy-1,4-naphthoquinone (juglone) has been investigated. Both these compounds, which are substrates of guinea pig lens zeta-crystallin (NADPH:quinone oxidoreductase), were found to cause increases in the rate of 14CO2 production from 1-14C-labelled glucose. Exposure of lenses to 15 microM 1,2-naphthoquinone or 20 microM juglone yielded 5.9- and 7-fold stimulation of HMS activity, respectively. Unlike hydrogen peroxide-induced stimulation of HMS activity, these effects were not abolished by preincubation with the glutathione reductase inhibitor, 1,3-bis(2-chloroethyl)-1 nitrosourea (BCNU). While hydrogen peroxide produced substantial decrements in lens glutathione (GSH) levels, incubation with quinones was not associated with a similar reduction in GSH concentration. Protein-bound NADPH content in quinone-exposed guinea pig lenses was decreased, with a concomitant increase in the amounts of free NADP+. This finding supported the involvement of zeta-crystallin bound NADPH in the in vivo enzymic reduction of quinones. Hydrogen peroxide, on the other hand, caused decreases in the level of free NADPH alone, serving to confirm our earlier inference that quinone stimulated increases in the guinea pig lens HMS could be mediated through zeta-crystallin NADPH:quinone oxidoreductase activity.     

Biosynthesis of acaterin: mechanism of the reaction catalyzed by dehydroacaterin reductase

Dehydroacaterin reductase is an enzyme which catalyzes the final step of acaterin biosynthesis, that is, the reduction of the C-4/C-5 double bond of dehydroacaterin. The mechanism of the reduction was investigated with a cell-free preparation obtained from the acaterin-producing microorganism, Pseudomonas sp. A 92. Incubation of dehydroacaterin in the presence of [4,4- 2H2]NADPH or D2O followed by 2H NMR analysis of the resulting acaterin revealed that the deuterium atom from NADPH was incorporated into the C-5 position of acaterin, while the deuterium atom from D2O was introduced into the C-4 position. It was further demonstrated that the pro-R hydrogen at C-4 of NADPH was stereospecifically utilized in this reduction.     

Evidence for a second microsomal trans-2-enoyl coenzyme A reductase in rat liver. NADPH-specific short chain reductase

Evidence for the existence of a previously unknown rat hepatic microsomal reductase, short chain trans-2-enoyl-CoA reductase (SC reductase) is presented. This reductase has a specific requirement for NADPH, is unable to utilize NADH, and catalyzes the conversion of crotonyl-CoA and trans-2-hexenoyl-CoA to butyric acid and hexenoic acid at a rate of 5 and 65 nmol per min per mg of microsomal protein, respectively. Highly purified NADPH cytochrome P-450 reductase incorporated into liposomes prepared from dilauroyl phosphatidylcholine in the presence or absence of cytochrome P-450 possesses no SC reductase activity. These liposomal preparations did, however, catalyze mixed function oxidations of benzphetamine and testosterone. Rabbit antibody to rat liver NADPH cytochrome P-450 reductase had little to no effect on the conversion of crotonyl-CoA and trans-2-hexenoyl-CoA, suggesting that the SC reductase accepts reducing equivalents directly from NADPH. When acetoacetyl-CoA was incubated with hepatic microsomes and either NADH or NADPH, no formation of butyrate was detected; however, when both cofactors were present, a rate of formation of 3 nmol of butyrate was determined per min per mg of microsomal protein. These results suggest the presence of a previously unknown short chain beta-ketoreductase which catalyzes the reduction of short chain beta-keto acids, only in the presence of NADH. Our results also indicate that the electrons from NADH to the beta-ketoreductase bypass cytochrome b5. The physiological significance is discussed in terms of lipogenesis and ketone body utilization by the liver.     

Evidence for the essential function of 2,4-dienoyl-coenzyme A reductase in the beta-oxidation of unsaturated fatty acids in vivo. Isolation and characterization of an Escherichia coli mutant with a defective 2,4-dienoyl-coenzyme A reductase

For the purpose of assessing in vivo the importance of 2,4-dienoyl-CoA reductase (EC 1.3.1.34) in the beta-oxidation of unsaturated fatty acids, reductase mutants of Escherichia coli were isolated by selecting cells that were able to grow on oleate but not on petroselinic acid (6-cis-octadecenoic acid). One mutant (fadH) exhibited 12% of the 2,4-dienoyl-CoA reductase activity present in the parental strain with other beta-oxidation enzymes being essentially unaffected. Antireductase antibodies were used to show that the mutant contains a fadH gene product at a level similar to that observed in the parental strain. Thus, the mutation seems to have resulted in the synthesis of a fadH gene product with lower specific activity. The mutation was mapped in the 71-75-min region of the E. coli chromosome where no other gene for beta-oxidation enzymes has so far been located. Complementation of the mutation by F'141, which carries the 67-75.5-min region of the E. coli genome, resulted in an increase in the 2,4-dienoyl-CoA reductase activity to 80% of the level found in the parental strain. Measurements of respiration with petroselinic acid as the substrate showed rates to be linearly dependent on the 2,4-dienoyl-CoA reductase activity up to levels found in wild-type E. coli. 2,4-Dienoyl-CoA reductase, like other enzymes of beta-oxidation, was induced when E. coli was grown on a long chain fatty acid as the sole carbon source. It is concluded that 2,4-dienoyl-CoA reductase is required in vivo for the beta-oxidation of unsaturated fatty acids with double bonds extending from even-numbered carbon atoms.     

A role for hormone-sensitive lipase in the selective mobilization of adipose tissue fatty acids.

The mobilization of fatty acids from rat and human fat cells is selective according to molecular structure, and notably carbon atom chain length. This study aimed at examining whether the release of individual fatty acids from triacylglycerols (TAG) by hormone-sensitive lipase (HSL) plays a role in the selectivity of fatty acid mobilization. Recombinant rat and human HSL were incubated with a lipid emulsion. The hydrolysis of 18 individual fatty acids, ranging in chain length from 12 to 24 carbon atoms and in unsaturation degree from 0 to 3 double bond(s), was measured by comparing the composition of non-esterified fatty acids (NEFA) to that of the original TAG. The relative hydrolysis (% in NEFA/% in TAG) differed between fatty acids, being about 5-fold and 3-fold higher for the most (18:1n-7) than for the least (24:0) readily released fatty acid by recombinant rat and human HSL, respectively. Relationships were found between the chain length of fatty acids and their relative hydrolysis. Among 12-24 carbon atom saturated fatty acids, the relative hydrolysis markedly decreased (by about 5- and 3-times for recombinant rat and human HSL, respectively) with increasing chain length. We conclude that fatty acids are selectively released from TAG by HSL according to carbon atom chain length. These data provide insight on the mechanism by which fatty acids are selectively mobilized from fat cells.     

Hydrogen transfer from 4-R and 4-S (4-3H) NADH in the reduction of d,l-cis-6,7-dimethyl-6,7 (8H) dihydropterin with dihydropteridine reductase from human liver and sheep liver.

Transfer of the 4-hydrogen atom from NADH onto a nitrogen atom of d,l-cis-6,7-dimethyl-6,7(8H)-dihydropterin was shown to take place stereospecifically from the B-face of NADH (transfer of the pro-S hydrogen atom) by using 4-R and 4-S (4-³H)NADH, and dihydropteridine reductase from human liver and sheep liver.     

Activation of carbonyl reductase from pig lung by fatty acids.

The NADPH-linked reductase activity of pig lung carbonyl reductase was activated two- to fivefold by fatty acids with a carbon chain length greater than nine at pH 7.0. cis-Unsaturated fatty acids of C:18 and C:20 were potent activators, showing Ka values of 2-14 microM which were lower than the values of 21-125 microM for saturated fatty acids (C:9 to C:16). Of the fatty acids arachidonic acid (C20:4) gave the highest activation. No significant stimulatory effect was observed with acyl CoAs, fatty alcohols, phospholipids, and nonionic detergents. Anionic detergents (sodium dodecyl sulfate and sarkosyl) stimulated the enzyme activity more than ninefold, but the Ka values for them were much higher than those for the cis-unsaturated fatty acids. Although no change in molecular weight or in subunit composition was observed in the enzyme activated by C20:4, the activation led to a decrease in thermal stability of the enzyme. The binding of C20:4 to the enzyme was instantaneous and reversible, shifted the pH optimum of the activity from 5.8 to 6.5, and changed the inhibitor sensitivity. In addition, C20:4 acted as an allosteric effector abolishing the negative interaction of the enzyme with carbonyl substrates which was seen without the fatty acid, but the activation increased both Vmax and [S]0.5 values for the substrates. Kinetic analysis with respect to NADPH concentration, in which no cooperativity was detected with or without C20:4, indicated that C20:4 was a nonessential activator of mixed type showing a binding constant of 10 microM. These results suggest that cis-unsaturated fatty acids may be potential modulators of pulmonary carbonyl reductase.     

In vitro metabolic engineering of hydrogen production at theoretical yield from sucrose

Hydrogen is one of the most important industrial chemicals and will be arguably the best fuel in the future. Hydrogen production from less costly renewable sugars can provide affordable hydrogen, decrease reliance on fossil fuels, and achieve nearly zero net greenhouse gas emissions, but current chemical and biological means suffer from low hydrogen yields and/or severe reaction conditions. An in vitro synthetic enzymatic pathway comprised of 15 enzymes was designed to split water powered by sucrose to hydrogen. Hydrogen and carbon dioxide were spontaneously generated from sucrose or glucose and water mediated by enzyme cocktails containing up to15 enzymes under mild reaction conditions (i.e. 37 °C and atm). In a batch reaction, the hydrogen yield was 23.2 mol of dihydrogen per mole of sucrose, i.e., 96.7% of the theoretical yield (i.e., 12 dihydrogen per hexose). In a fed-batch reaction, increasing substrate concentration led to 3.3-fold enhancement in reaction rate to 9.74 mmol of H₂/L/h. These proof-of-concept results suggest that catabolic water splitting powered by sugars catalyzed by enzyme cocktails could be an appealing green hydrogen production approach.     

Biosynthesis and n.m.r. studies of deuterated poly(3-hydroxybutyrate) produced by Alcaligenes eutrophus H16.

Alcaligenes eutrophus H16 was grown on mixtures of 1H- and 2H-acetate as carbon sources. The accumulation of deuterated poly(3-hydroxybutyrate) (P(3HB)) was observed. The deuterium distributions in the isolated P(3HB)s were determined from 1H and 2H-n.m.r. spectra and confirmed by 13C-n.m.r. spectra. Although one would expect to synthesize P([2,2,4,4,4-2H5]3HB) when the cells were grown on 2H-acetate as the sole carbon source, the methyl, methylene and methine groups of the P(3HB) contained both deuterium and proton. This observation indicates some substitution from 2H to 1H during the P(3HB) synthesis. The 2H content in the methyl groups was larger than that in the methylene groups, which suggests a kinetic isotope effect in the P(3HB) synthesizing process. The deuterium distributions in the two magnetically non-equivalent methylene protons were determined to be different, which indicates stereoselectivity at the C2 site.