Metabolism of γ-hydroxybutyrate in perfused rat livers

GHB (γ-hydroxybutyrate) is both a neurotransmitter and a drug of abuse (date-rape drug). We investigated the catabolism of this compound in perfused rat livers. Using a combination of metabolomics and mass isotopomer analysis, we showed that GHB is metabolized by multiple processes, in addition to its previously reported metabolism in the citric acid cycle via oxidation to succinate. A substrate cycle operates between GHB and γ-aminobutyrate via succinic semialdehyde. Also, GHB undergoes (i) β-oxidation to glycolyl-CoA+acetyl-CoA, (ii) two parallel processes which remove C-1 or C-4 of GHB and form 3-hydroxypropionate from C-2+C-3+C-4 or from C-1+C-2+C-3 of GHB, and (iii) degradation to acetyl-CoA via 4-phosphobutyryl-CoA. The present study illustrates the potential of the combination of metabolomics and mass isotopomer analysis for pathway discovery.     

Metabolism of ribosylzeatin-5′-monophosphate by soybean callus

Using cytokinin dependent soybean callus and HPLC analysis it was shown that soybean callus rapidly metabolises ribosylzeatin-5-monophosphate to biologically active compounds which co-chromatographed with trans-ribosylzeatin and trans-zeatin.Abbreviations Z zeatin - RZ ribosylzeatin - RZMP ribosylzeatin-5-monophosphate     

Metabolism of Aniline by Rhodococcus erythropolis AN–13

The metabolic pathway of aniline was examined in Rhodococcus erythropolis AN-13 that was isolated from soil when aniline was provided as a sole source of carbon and nitrogen. cis, cis-Muconic acid and β-ketoadipic acid were detected by thin-layer chromatography in an incubation mixture containing aniline and resting cells of this strain. These two carboxylic acids were also formed from catechol, when the substrate was incubated with cell-free extract of aniline-grown cells, and characterized spectrally as crystalline samples. Ammonia was released from aniline by resting cells. The cell-free extract of aniline-grown cells had a strong catechol 1,2-dioxygenase activity. Catechol, once formed from aniline, was apparently converted so rapidly to cis, cis-muconic acid that it could not be isolated. These results suggest that R. erythropolis AN-13 converted aniline to catechol with the release of ammonia and then mineralized catechol ultimately to inorganic end products, H₂O and CO₂, through the β ketoadipic acid pathway.     

Thioredoxin-independent Regulation of Metabolism by the ��-Arrestin Proteins

Thioredoxin-interacting protein (Txnip), originally characterized as an inhibitor of thioredoxin, is now known to be a critical regulator of glucose metabolism in vivo. Txnip is a member of the α-arrestin protein family; the α-arrestins are related to the classical β-arrestins and visual arrestins. Txnip is the only α-arrestin known to bind thioredoxin, and it is not known whether the metabolic effects of Txnip are related to its ability to bind thioredoxin or related to conserved α-arrestin function. Here we show that wild type Txnip and Txnip C247S, a Txnip mutant that does not bind thioredoxin in vitro, both inhibit glucose uptake in mature adipocytes and in primary skin fibroblasts. Furthermore, we show that Txnip C247S does not bind thioredoxin in cells, using thiol alkylation to trap the Txnip-thioredoxin complex. Because Txnip function was independent of thioredoxin binding, we tested whether inhibition of glucose uptake was conserved in the related α-arrestins Arrdc4 and Arrdc3. Both Txnip and Arrdc4 inhibited glucose uptake and lactate output, while Arrdc3 had no effect. Structure-function analysis indicated that Txnip and Arrdc4 inhibit glucose uptake independent of the C-terminal WW-domain binding motifs, recently identified as important in yeast α-arrestins. Instead, regulation of glucose uptake was intrinsic to the arrestin domains themselves. These data demonstrate that Txnip regulates cellular metabolism independent of its binding to thioredoxin and reveal the arrestin domains as crucial structural elements in metabolic functions of α-arrestin proteins.Thioredoxin-interacting protein (Txnip),³ an inhibitor of thioredoxin disulfide reductase activity in vitro (1–3), is robustly induced by glucose (4–6) and a critical regulator of metabolism in vivo (7–10). In humans, Txnip expression is suppressed by insulin and strongly up-regulated in diabetes (7). Txnip-deficient mice have fasting hypoglycemia and ketosis (8, 9, 11, 12) with a striking enhancement of glucose uptake by peripheral tissues (8, 9). We have proposed that Txnip inhibits thioredoxin by forming a mixed disulfide with thioredoxin at its catalytic active site cysteines in a disulfide exchange reaction (13). However, it is not known how Txnip metabolic functions relate to its ability to bind thioredoxin.Structurally, Txnip belongs to the arrestin superfamily of proteins (14). The prototypical arrestins (the visual arrestins and the β-arrestins) are key regulators of receptor signaling. The β-arrestins, named for their interaction with the β-adrenergic receptor, are now known to control signaling through the multiple families of receptors (15). These arrestin proteins have two wing-like arrestin domains arranged around a central core that detects and binds selectively to the charged phosphates of activated receptors (16). The arrestin domains then act as multifunctional scaffolds that cannot only quench receptor signals by recruiting endocytotic machinery and ubiquitin ligases, but also start new signal cascades (15). Recently, arrestin-β2 has also been shown to play a key role in metabolism as a controller of insulin receptor signaling that is deficient in diabetes (17).In addition to the classical visual/β-arrestins, a large number of arrestins more closely related to Txnip are present throughout multicellular evolution. These proteins have been termed the “α-arrestins,” as they are of more ancient origin than the visual/β family (14). Although no structures are known of the α-arrestins to date, they appear highly likely to share the overall fold: two β-sheet sandwich arrestin domains connected by a short linker sequence (14, 18). Confidence in this prediction has been enhanced by the surprising finding that the vps26 family of proteins, even more distantly related to the classical arrestins than Txnip, also share the arrestin fold (19). The vps26 proteins are a component of the retromer complex that controls retrograde transport of recycling endosomes to the trans-Golgi network. This functional overlap with visual/β-arrestin regulation of endocytosis suggests that control of endosome formation and transport may be a conserved function of the arrestin superfamily fold.The functions of the mammalian α-arrestins remain unclear. Humans have six α-arrestins: Txnip and five other proteins, which have been assigned the names Arrdc1–5 (arrestin domain-containing 1–5) (13). Very little is known about these other α-arrestins; thioredoxin binding is not conserved beyond Txnip (13, 20). More is known in yeast: recent reports suggest that α-arrestins function in regulation of endocytosis and protein ubiquitination through PXXY motifs in their C-terminal tails (21–25). However, as all the vertebrate α-arrestins have diverged from the ancestral α-arrestins (14), their structure-function relationships may differ from yeast α-arrestins.Given that other α-arrestins are not thioredoxin-binding proteins, we hypothesized that Txnip metabolic functions may be conserved in mammalian α-arrestins and independent of its interaction with thioredoxin. Overexpression of Txnip in vitro can decrease levels of available thioredoxin and increase levels of reactive oxygen species (1, 3, 26). However, in vivo studies of two different Txnip-deficient mouse models found no change in available thioredoxin levels (8, 27). Txnip reportedly binds to other proteins including Jab1 (28) and Dnajb5 (29), but it is not clear to what extent these interactions are themselves independent of a Txnip-thioredoxin complex (30).Using overexpression of a mutant Txnip that does not bind thioredoxin, we show here that a major metabolic function of Txnip, its inhibition of glucose uptake, does not require interaction with thioredoxin. Instead, we show that inhibition of glucose uptake is a conserved function of another human α-arrestin, Arrdc4. Studies of Txnip mutants and chimeric α-arrestins suggest that the metabolic functions of Txnip and Arrdc4 are intrinsic to the arrestin domains.     

The Role of Hydrogen for Sulfurimonas denitrificans’ Metabolism

Sulfurimonas denitrificans was originally isolated from coastal marine sediments. It can grow with thiosulfate and nitrate or sulfide and oxygen. Recently sequencing of its genome revealed that it encodes periplasmic and cytoplasmic [NiFe]-hydrogenases but the role of hydrogen for its metabolism has remained unknown. We show the first experimental evidence that S. denitrificans can indeed express a functional hydrogen uptake active hydrogenase and can grow on hydrogen. In fact, under the provided conditions it grew faster and denser on hydrogen than on thiosulfate alone and even grew with hydrogen in the absence of reduced sulfur compounds. In our experiments, at the time points tested, the hydrogen uptake activity appeared to be related to the periplasmic hydrogenase and not to the cytoplasmic hydrogenase. Our data suggest that under the provided conditions S. denitrificans can grow more efficiently with hydrogen than with thiosulfate.     

Altered Brain Metabolism of Iron as a Cause of Neurodegenerative Diseases?

Abstract: Iron is the most abundant metal in the human body (Pollitt and Leibel, 1982; Youdim, 1988), and the brain, like the liver, contains a substantially higher concentration of iron than of any other metal (Yehuda and Youdim, 1988). Within the brain, iron shows an uneven distribution, with high levels in the basal ganglia (substantia nigra, putamen, caudate nucleus, and globus pallidus), red nucleus, and dentate nucleus (Spatz, 1922; Hallgren and Sourander, 1958; Hill and Switzer, 1984; Riederer et al., 1989). Iron deposition in the brain is mainly in organic storage forms such as ferritin but not hemosiderin (Hallgren and Sourander, 1958; Octave et al., 1983), with relatively little in a free and reactive form. Although the function of a regionally high brain iron content is unknown, the homeostasis of brain iron is thought to be necessary for normal brain function, especially in learning and memory (Youdim et al., 1989; Yehuda and Youdim, 1989; Pollit and Metallinos-Katsaras, 1990; Youdim, 1990). Thus, a high content of brain iron may be essential, particularly during development, but its presence means that injury to brain cells may release iron ions that can lead to oxidative stress via formation of oxygen free radicals. Such radicals are thought to be involved in lipid peroxidation of the cell membrane, leading to increased membrane fluidity, disturbance of calcium homeostasis, and finally cell death (Youdim et al., 1989; Halliwell, 1992). Iron is an essential participant in many metabolic processes, including (a) DNA, RNA, and protein synthesis, (b) as a cofactor of many heme and nonheme enzymes, (c) the formation of myelin, and (d) the development of the neuronal dendritric tree (Ben-Shachar et al., 1986; Youdim et al., 1991b). A deficiency of iron metabolism would therefore be expected to alter some or all of these processes (Jacobs and Worwood, 1980; Youdim, 1985, 1988). Studies of iron distribution in the human brain have demonstrated that the degree of iron deposition, primarily in the basal ganglia (a predominantly dopamine structure), increases with age (Hallgren and Sourander, 1958) and in certain disorders, most notably the basal ganglia disorders (Seitelberger, 1964). This review will present some of the experimental evidence indicating a role of disturbed iron metabolism as a cause of the neurodegenerative disorder Parkinson's disease and possibly other neurodegenerative disorders such as Alzheimer's disease. In addition, some of the neurochemical and histochemical findings obtained at autopsy from analyses of the brain from patients with neurodegenerative diseases such as Parkinson's disease, Alzheimer's disease, Huntington's disease, and progressive supranuclear palsy (Steele-Richardson-Olszewski's disease) will be discussed. Special attention will be paid to clarifying the possible implication of the observed changes in the etiology of neurodegenerative disorders.     

Metabolism of dynorphin A1–13 in human CSF

In-vitro incubation of human cerebrospinal fluid (CSF) obtained from patients ranging from 22–78 years with 10 μM of dynorphin A1–13 (Dyn A1–13) resulted in several cleavage products. Dyn A1–12 and A2–13 were identified as the major CSF metabolites by matrix-assisted laser desorption mass spectrometry (LD-MS). Further metabolites were Dyn A1–6, A2–12 and A4–12. LD-MS further suggested the formation of Dyn A1–8, A1–7, A1–10, A7–10, A3–12, A7–12, A3–13, A7–13 and A8–13. The metabolic half-life of Dyn A1–13 at 37°C was approximately 2.5 h (range 1.75–8.5 h), compared to less than one minute in plasma. The half-life of Dyn A1–13 decreased markedly with age or age-associated processes (n=20, r²=0.498). Noncompartmental kinetic analysis in the absence or presence of enzyme inhibitors (leucinethiol 10 μM, captopril 100 μM and GEMSA 20 μM) suggested that Dyn A1–13 is mainly metabolized by carboxypeptidase to A1–12 (51%) and by aminopeptidases to A2–13 (35%). The generation of A1–6 (13%) was only detected under enzyme inhibition. The extent of conversion into the main metabolites did not follow an age-associated trend, thus over-all enzyme levels but no specific enzymatic systems are elevated with age.     

A Lipidomic Study of the Effects of N-methyl-N′-nitro-N-nitrosoguanidine on Sphingomyelin Metabolism

Systems biology is a new and rapidly developing research area in which,by quantitativelydescribing the interaction among all the individual components of a cell,a systems-level understanding of abiological response can be achieved.Therefore,it requires high-throughput measurement technologies forbiological molecules,such as genomic and proteomic approaches for DNA/RNA and protein,respectively.Recently,a new concept,lipidomics,which utilizes the mass spectrometry(MS)method for lipid analysis,has been proposed.Using this lipidomic approach,the effects of N-methyl-N'-nitro-N-nitrosoguanidine(MNNG)on sphingomyelin metabolism,a major class of sphingolipids,were evaluated.Sphingomyelin moleculeswere extracted from cells and analyzed by matrix-assisted laser desorption ionization-time of flight MS.Itwas found that MNNG induced profound changes in sphingomyelin metabolism,including the appearance ofsome new sphingomyelin species and the disappearance of some others,and the concentrations of severalsphmgomyelin species also changed.This was accompanied by the redistribution of acid sphingomyelinase(ASM),a key player in sphingomyelin metabolism.On the other hand,imipramine,an inhibitor of ASM,caused the accumulation of sphingomyelin.It also prevented some of the effects of MNNG,as well as theredistribution of ASM.Taken together,these data suggested that the lipidomic approach is highly effectivefor the systematic analysis of cellular lipids metabolism.     

α-Amylase Formation and Nucleic Acid Metabolism of Bacillus subtilis

The nucleic acid metabolism in washed cells of Bacillus subtilis was investigated with special reference to amylase formation of the bacterium. On incubation of the suspension of the washed cells, purines, pyrimidines and their related compounds were observed in the medium. However, in the medium of the cells incubated with a calcium chelater, where no amylase formation occurred, were detected adenosine- and guanosine-monophosphate in addition to those described above. The addition of a calcium chelater was also found to decrease the quantity of the nucleic acids being involved in the lysozyme-sensitive fraction of the bacterial cells, suggesting the possibility that the metabolism of nucleic acids in this fraction is closely related to amylase formation of the cells.     

A Lipidomic Study of the Effects of N-methyl-N＇-nitro-N-nitrosoguanidine on Sphingomyelin Metabolism

Systems biology is a new and rapidly developing research area in which, by quantitatively describing the interaction among all the individual components of a cell, a systems-level understanding of a biological response can be achieved. Therefore, it requires high-throughput measurement technologies for biological molecules, such as genomic and proteomic approaches for DNA/RNA and protein, respectively.Recently, a new concept, lipidomics, which utilizes the mass spectrometry （MS） method for lipid analysis,has been proposed. Using this lipidomic approach, the effects of N-methyl-N＇-nitro-N-nitrosoguanidine （MNNG） on sphingomyelin metabolism, a major class of sphingolipids, were evaluated. Sphingomyelin molecules were extracted from cells and analyzed by matrix-assisted laser desorption ionization-time of flight MS. It was found that MNNG induced profound changes in sphingomyelin metabolism, including the appearance of some new sphingomyelin species and the disappearance of some others, and the concentrations of several sphingomyelin species also changed. This was accompanied by the redistribution of acid sphingomyelinase （ASM）, a key player in sphingomyelin metabolism. On the other hand, imipramine, an inhibitor of ASM,caused the accumulation of sphingomyelin. It also prevented some of the effects of MNNG, as well as the redistribution of ASM. Taken together, these data suggested that the lipidomic approach is highly effective for the systematic analysis of cellular lipids metabolism.     

Metabolism of Yarrowia lipolytica Grown on Ethanol under Conditions Promoting the Production of α-Ketoglutaric and Citric Acids: A Comparative Study of the Central Metabolism Enzymes

A comparative study of the enzymes of tricarboxylic acid (TCA) and glyoxylate cycles in the mutant Yarrowia lipolytica strain N1 capable of producing -ketoglutaric acid (KGA) and citric acid showed that almost all enzymes of the TCA cycle are more active under conditions promoting the production of KGA. The only exception was citrate synthase, whose activity was higher in yeast cells producing citric acid. The production of both acids was accompanied by suppression of the glyoxylate cycle enzymes. The activities of malate dehydrogenase, aconitase, NADP-dependent isocitrate dehydrogenase, and fumarase were higher in cells producing KGA than in cells producing citric acid.     

Metabolism of 17α-methyl-5α-dihydrotestosterone in the rabbit

17α-Methyl-5α-dihydrotestosterone and the reduced metabolites, 17α-methyl-5α-androstane-3α, 17β-diol and -3β, 17β-diol together with two hydroxylated metabolites, 17α-methyl-5α-androstane-3β, 15α, 17β-triol and 17α-methyl-5α-androstane-3α, 6α, 17β-triol were isolated and identified in the urine of rabbits orally dosed with 17α-methyl-5α-dihydrotestosterone. Formation of the C-6 hydroxylated derivative demonstrates that the 4,6-enolization of a 4-en-3-one is not a necessary requirement for hydroxylation at C-6 of the androstane nucleus in the rabbit. No evidence was obtained for the presence of 17α-methyl/17β-hydroxyl epimerization.     

Effect of Seawater–Sewage Cross-Transplants on Bacterial Metabolism and Diversity

Bioassays experiments were conducted to determine the metabolic and community composition response of bacteria to transplants between relatively pristine coastal seawater and sewage-impacted seawater. There were four treatments: (1) pristine seawater bacteria?+?pristine seawater (Pb?+?Pw), (2) sewage-impacted bacteria?+?sewage-impacted water (Sb?+?Sw), (3) pristine seawater bacteria?+?sewage-impacted water (Pb?+?Sw), and (4) sewage-impacted bacteria?+?pristine seawater (Sb?+?Pw). Sewage-derived DOC was more labile and readily utilized by bacteria, which favored the growth of high nucleic acid (HNA) bacteria, resulting in high bacterial production (BP, 113?±?4.92 to 130?±?15.8 μg C l^?1?day^?1) and low respiration rate (BR, <67?±?11.3 μg C l^?1?day^?1), as well as high bacterial growth efficiency (BGE, 0.68?±?0.09 to 0.71?±?0.05). In contrast, at the relatively pristine site, bacteria utilized natural marine-derived dissolved organic matter (DOM) at the expense of lowering their growth efficiency (BGE, <0.32?±?0.02) with low BP (<62?±?6.3 μg C l^?1?day^?1) and high BR 133?±?14.2 μg C l^?1?day^?1). Sewage DOM input appeared to alter the partitioning of carbon between respiration and production of bacteria, resulting in a shift toward higher BGE, which would not enhance oxygen consumption. Taxonomic classification based on 454 pyrosequencing reads of the 16S rRNA gene amplicons revealed that changes in bacterial community structure occurred when seawater bacteria were transferred to the eutrophic sewage-impacted water. Sewage DOM fueled the growth of Gammma-proteobacteria and Epsilson-proteobacteria and reduced the bacterial richness, but the changes in the community were not apparent when sewage-impacted bacteria were transferred to pristine seawater.     

Effects of Peroxidation Products of Linoleic Acid on Tryptophan–nicotinamide Metabolism in Rats

The flavin and pyridine nucleotide coenzymes are involved in the detoxication of autoxidation products of lipids. In tryptophan-nicotinamide metabolism, kynurenine 3-hydroxylase and N¹-methylnicotinamide (MNA) oxidase contain FAD as a coenzyme. So, the effects of dietary autoxidation products of linoleic acid on the metabolism of tryptophan-nicotinamide were investigated using rats. The administration of linoleic acid hydroperoxides or secondary products reduced the urinary excretion of xanthurenic acid, nicotinamide and its metabolites such as MNA, N¹-methyl-2-pyridone-5-carboxamide (2-Py), and N¹-methyl-4-pyridone-3-carboxamide (4-Py) as compared with the group administered saline or linoleic acid. Among the enzyme activities involved in the tryptophan-nicotinamide metabolism, the activity of NAD⁺ synthetase was decreased by the administration of linoleic acid hydroperoxides or secondary products. The activities of tryptophan oxygenase and 4-Py-forming MNA oxidase were also decreased by the administration of secondary products. These results indicate that the conversion of tryptophan to nicotinamide would be lower in the groups administered the hydroperoxides and secondary products than in saline and linoleic acid groups.     

Metabolism of 17α-methyl-5β-dihydrotestosterone in the rabbit

17α-Methy1-5β-androstane-3α, 17β-diol together with the hydroxylated metabolites 17α-methyl-5β-androstane-1β, 3α, 17β-triol, 17α-methyl-5β-androstane-3α, 12β, 17β-triol, 17α-methyl-5β-androstane-3α, 16α, 17β-triol and 17α-methyl-5β-androstane-3α, 16β, 17β-triol were isolated and identified in the urine of rabbits orally dosed with 17α-methyl-5β-dihydrotestosterone. Biotransformations differ from the 5α-series where hydroxylation occurred at C-6 and C-15. In both series, the C-3 equatorial epimer was the major urinary excretion product among the non-hydroxylated metabolites. The 5β-compound was more resistant to metabolic hydroxylation than the 5α-compound. No evidence for epimerization at the C-17 position was observed.     

Metabolism of 2,4,4′-Trichlorobiphenyl by Acinetobacter sp. P6

Metabolism of 2,4,4′-trichlorobiphenyl by Acinetobacter sp. strain P6 has been studied. When the incubation was carried out without shaking at 15°C, two isomeric monohydroxy compounds, a dihydrodiol compound, a dihydroxy compound, a meta-cleaved yellow compound and a dichlorobenzoic acid were detected by combined gas liquid chromatograph-mass spectrometry. As an additional metabolite, dichlorodihydroxy biphenyl, a dechlorinationhydroxylation product, was also detected. When the incubation mixture was shaken at 30°C, a meta-cleaved yellow compound was readily produced and predominantly accumulated in the reaction mixture upon further incubation. The major pathway of 2,4,4′-trichlorobiphenyl by Acinetobacter sp. P6 was considered to proceed oxidatively via 2.′3′-dihydro-2′,3′-diol compound, concomitant dehydrogenated 2′,3′-dihydroxy compound and then the 1′,2′-meta-cleaved yellow compound, i.e., 3-chloro-2-hydroxy-6-oxo-6(2,4-dichlorophenyl)hexa-2,4-dienoic acid.     

Systemic PPARγ Deletion Impairs Circadian Rhythms of Behavior and Metabolism

Compelling evidence from both human and animal studies suggests a physiological link between the circadian rhythm and metabolism but the underlying mechanism is still incompletely understood. We examined the role of PPARγ, a key regulator of energy metabolism, in the control of physiological and behavioral rhythms by analyzing two strains of whole-body PPARγ null mouse models. Systemic inactivation of PPARγ was generated constitutively by using Mox2-Cre mice (MoxCre/flox) or inducibly by using the tamoxifen system (EsrCre/flox/TM). Circadian variations in oxygen consumption, CO(2) production, food and water intake, locomotor activity, and cardiovascular parameters were all remarkably suppressed in MoxCre/flox mice. A similar phenotype was observed in EsrCre/flox/TM mice, accompanied by impaired rhythmicity of the canonical clock genes in adipose tissues and liver but not skeletal muscles or the kidney. PPARγ inactivation in isolated preadipocytes following exposure to tamoxifen led to a similar blockade of the rhythmicity of the clock gene expression. Together, these results support an essential role of PPARγ in the coordinated control of circadian clocks and metabolic pathways.     

Water-relation Parameters of Individual Mesophyll Cells of the Crassulacean Acid Metabolism Plant Kalanchoë daigremontiana

Water-relation parameters of leaf mesophyll cells of the CAM plant Kalanchoë daigremontiana have been determined directly in cells of tissue slices using the pressure-probe technique. Turgor pressures measured in cells of the second to fourth layer from the cut surface showed an average of 1.82 ± 0.62 bar (mean ± sd; n = 157 cells). This was lower than expected from measurements of the osmotic pressure of the cell sap. The half-time (T_1/2) for water-flux equilibration of individual cells was 2.5 to 8.8 seconds. This is the fastest T_1/2 found so far for higher-plant cells. The calculated values of the hydraulic conductivity were in the range of 0.20 to 1.6 × 10⁻⁵ centimeters second⁻¹ bar⁻¹, with an average of (0.69 ± 0.46) × 10⁻⁵ centimeters second⁻¹ bar⁻¹ (mean ± sd; n = 8 cells). The T_1/2 values of water exchange of individual cells are consistent with the overall rates of water-flux equilibration measured for tissue slices.The volumetric elastic moduli (∈) of individual cells were in the range 13 to 128 bar for turgor pressures between 0.0 and 3.4 bar; the average ∈ value was 42.4 ± 27.7 bar (mean ± sd; n = 21 cells). This ∈ value is similar to that observed for other higher-plant cells.The water-storage capacity of individual cells, calculated as C_c = V/(∈ + πⁱ) (where V = cell volume and πⁱ = internal osmotic pressure) was 9.1 × 10⁻⁹ cubic centimeters bar⁻¹ per cell, and the capacity for the tissue was 2.2 × 10⁻² cubic centimeters bar⁻¹ gram⁻¹ fresh weight. The significance of the water-relation parameters determined at the cellular level is discussed in terms of the water relations of whole leaves and the high water-use efficiency characteristic of CAM plants.     

Metabolism of a glutathione conjugate of 2-hydroxyoestradiol-17β in the adult male rat

Adult male rats with cannulated or ligated bile ducts were given S-(2-hydroxyoestradiol-1-yl)[(35)S]glutathione, S-(2-hydroxy[6,7-(3)H(2)]oestradiol-1-yl)glutathione or S-(2-hydroxyoestradiol-1-yl)[glycine-(3)H]glutathione by intraperitoneal injection. The recovery of radioactivity in the bile of bile duct-cannulated rats was 33-86% and in the urine of bile duct-ligated rats was 54-105%. Oestrogen thioether derivatives of glutathione, cysteinylglycine, cysteine and N-acetylcysteine were isolated from bile; only the N-acetylcysteine derivatives could be identified in the urine. The steroid moiety was characterized by microchemical tests before and after treatment with Raney nickel: 2-hydroxyoestradiol-17beta was released from the glutathione conjugate, and 2-hydroxyoestrone and 2-hydroxyoestrone 3-methyl ether from the other conjugates. From intact rats the recovery of administered radioactivity was about 15% in the urine and 5% in the faeces over a period of several days and the radioactivity appeared to be largely protein-bound. The results demonstrate that injected oestrogen-glutathione conjugate undergoes conversion into N-acetylcysteine derivatives in vivo. Oestrogen-glutathione conjugates formed in the intact rat may be excreted in an apparently non-steroidal, possibly protein-bound form, which would not be detected by current analytical techniques.