Sustaining S-adenosyl-l-methionine-dependent methyltransferase activity in plant cells

Many biochemical reactions in plants involve the transfer of a methyl group from S -adenosyl- l -methionine (SAM). The transfer of the methyl group from SAM generates S -adenosyl- l -homocysteine (SAH), a potent inhibitor of SAM-dependent methyltransferases (MTs). To mitigate the toxic effects of SAH on MT activity, SAH is removed by SAH hydrolase (SAHH, EC 3.3.1.1) in a reaction generating homocysteine and adenosine (Ado). However, SAHH catalyzes a reversible reaction that is favored to move in the direction of SAH hydrolysis only by removal of these products. Removal of Ado is reported to exert a greater influence on promoting SAH hydrolysis. Whereas animals appear to rely upon Ado deaminase (EC 3.5.4.4) to catabolize Ado, plants appear to use adenosine kinase (EC 2.7.1.20) for this important role. Compounds undergoing methylation represent a broad spectrum of chemically diverse substrates ranging from nucleic acids, lipids and cell wall components to comparatively simpler amines, alcohols and metal halides. Given the diverse nature of methyl acceptor compounds, it is very likely that the demand for SAM synthesis and SAH removal changes both temporally and spatially during the course of plant growth and development. Plants also use SAM as a precursor for the synthesis of ethylene, polyamines, biotin and nicotianamine. These uses are also expected to undergo changes reflective of the metabolic activities of different plants, plant organs, or cells. This review examines the various uses of SAM in plants and addresses how they allocate this resource to satisfy potentially competing needs.     

Variations in S-adenosylmethionine, S-adenosylhomocysteine and adenosine concentrations in rat liver.

The hepatic concentrations of S-adenosylmethionine (SAM), S-adenosylhomocysteine (SAH) and adenosine (Ado) in the rat were examined diurnally and as a function of fasting. Ado concentrations increased continuously throughout the fasting period; concentrations after 2 days of fasting were 7.5-fold higher than control values. Diurnally, the concentration of Ado was highest during the light hours. SAM and the ratio of SAM/SAH were reduced greater than 50% due to fasting and exhibited a significant daily rhythm which appeared to be related to dietary methionine availability. Hepatic SAM concentrations decreased continuously during the light hours and increased during the dark period to levels 7.3-fold greater than the lowest light values. The concentration of SAH was altered in a similar fashion yet to a much lesser degree such that the ratio of SAM/SAH paralleled the changes in the concentration of SAM. The SAM/SAH ratio exhibited a 4.5-fold difference between the peak and nadir values.     

PRODUCT INHIBITION OF RAT BRAIN HISTAMINE-N-METHYLTRANSFERASE

Abstract— The inhibition of S -adenosylmenthionine: histamine- N -methyltransferase (EC 2.1.1.8; HMT) by its products, 3-methylhistamine (3-MetHm) and S -adenosyl- l -homocysteine (SAH), was examined using a preparation of the enzyme which was partially purified from rat brains. SAH was found in in vitro experiments, to be a competative inhibitor of HMT in relation to S -adenosyl- l -methionine (SAM), with a K _i= 5.6 μM. SAH was shown to be a non-competitive inhibitor with respect to histamine (Hm) ( K _i= 5.0 μM). The K _m's for SAM and Hm were 10.2 and 3.0 μM respectively. On the other hand, 3-MetHm was determined to be a non-competitive inhibitor of HMT with respect to Hm ( K _i= 8.7 μM) and an uncompetitive inhibitor with respect to SAM ( K _i= 9.6 μM). These results suggest that the addition of the substrate to, and the release of products by, HMT occurs sequentially. In the nomenclature Of C leland (1963) the reaction is seemingly of the 'ordered Bi-Bi' type.     

Decreased Transmethylation of Biogenic Amines After In Vivo Elevation of Brain S-Adenosyl-l-Homocysteine

Abstract: The ability of S -adenosyl- l -homocysteine (AdoHcy) to inhibit biologic transmethylation reactions in vitro has led us to explore the possibility of pharmacologically manipulating AdoHcy levels in vivo and examining the consequences of these alterations on the transmethylation of some biogenic amines. Swiss-Webster mice were injected intraperitoneally with different doses of adenosine (Ado) and d,l -homocysteine thiolactone (Hcy) and were killed at various times thereafter. S -Adenosyl- l -methionine (AdoMet) and AdoHcy concentrations were determined by using a modified isotope dilution-ion exchange chromatography-high pressure liquid chromatography technique sensitive to less than 10 pmol. Increasing doses of Ado + Hcy (50-1000 mg/kg of each) produced a dose-related increase in blood, liver, and brain AdoHcy levels. At a dose level of 200 mg/kg Ado + Hcy, AdoHcy levels were markedly elevated, with minimal concomitant perturbations of AdoMet. This elevation was maximal 40 min after giving Ado + Hcy, returning to control values within 6 h. Ado + Hcy treatment resulted in decreased activities of catechol- O -methyltransferase, histamine- N -methyltransferase, and AdoHcy hydrolase in vitro. The cerebral catabolism of intraventricularly administered [³H]histamine (HA) was decreased in a dose-related manner by Ado + Hcy treatment as evidenced by higher amounts of nonutilized [³H]HA in brain, concurrent decreases in [³H]methylhistamine formation, and decreases in the transmethylation conversion index. Steady state levels of HA also showed dose-related increases after Ado + Hcy treatment. It is concluded that injections of Ado + Hcy can markedly elevate AdoHcy levels in vivo , which can, in turn, decrease the rate of transmethylation reactions.     

METHYLATION OF E. COLI TRANSFER RIBONUCLEIC ACIDS BY A tRNA ADENINE-l-METHYLTRANSFERASE FROM RAT BRAIN CORTEX AND BULK-ISOLATED NEURONS

Abstract— Brain cortices or bulk-isolated neuronal cell bodies prepared from cortices of 8-day old male rats were used as the source of a l-methyl adenine-specific tRNA methyltransferase (tRNA-AMT). Ammonium sulfate fractionation and chromatography on spheroidal hydroxylapatite and Sephadex G-200 yielded an 80-fold purified enzyme, as determined by using E. coli bulk tRNA as substrate. The kinetic parameters of tRNA-AMT for the substrate S -adenosyl- l -methionine (SAM) ( K _m= 6 μM) and the inhibitor, S -adenosyl- l -homocysteine (SAH) ( K _i= 3.4 μ m ) were determined and several SAH analogs tested as inhibitors. S -Adenosyl- l -cysteine (SAC) ( 10 ^-4 m ) and S -adenosyl- d -homocysteine (SADH) (10^-4 m ) produced a 35 and a 21% reduction in enzyme activity, respectively. The effects of Mg²⁺, NH₄⁺ acetate and of the polyamines spermine, putrescine and spermidine on the brain tRNA-AMT mimicked the effects of these agents on hepatic tRNA-AMT (G lick et al , 1975).
Comparing the ability of cerebral tRNA-AMT to methylate E. coli tRNA^glu2, tRNA^val, tRNA^phe and bulk tRNA revealed tRNA^glu2 as the best and tRNA^phe as the least effective substrate.
tRNA-AMT prepared from neuronal cell bodies showed closely similar characteristics to the cortical enzyme. A comparison of the activities of tRNA-AMT in neurons and glial cells revealed higher values in the former.     

Structural basis for recognition of S-adenosylhomocysteine by riboswitches

S-adenosyl-(L)-homocysteine (SAH) riboswitches are regulatory elements found in bacterial mRNAs that up-regulate genes involved in the S-adenosyl-(L)-methionine (SAM) regeneration cycle. To understand the structural basis of SAH-dependent regulation by RNA, we have solved the structure of its metabolite-binding domain in complex with SAH. This structure reveals an unusual pseudoknot topology that creates a shallow groove on the surface of the RNA that binds SAH primarily through interactions with the adenine ring and methionine main chain atoms and discriminates against SAM through a steric mechanism. Chemical probing and calorimetric analysis indicate that the unliganded RNA can access bound-like conformations that are significantly stabilized by SAH to direct folding of the downstream regulatory switch. Strikingly, we find that metabolites bearing an adenine ring, including ATP, bind this aptamer with sufficiently high affinity such that normal intracellular concentrations of these compounds may influence regulation of the riboswitch.     

Evidence for altered methionine methyl-group utilization in the diabetic rat's brain

The methionine (MET) derivative, S-adenosylmethionine (SAM), provides methyl-groups for methylation reactions in many neural processes. In rats made diabetic with streptozotocin (SZ), brain SAM levels were generally lower (10–20%) than in controls, with a constant decrease being observed five weeks after onset of diabetes. This decrease in SAM levels may be due to reduced precursor (MET) availability because greatly elevating plasma MET concentrations in SZ diabetic rats by dietary manipulation increased their neural SAM concentrations to be approximately or even greater than (5–20%) those of controls. In contrast, neural levels of SAM's demethylated product, S-adenosylhomocysteine (SAH), were reduced to a greater extent (17–44%) than SAM levels in all groups of SZ diabetic rats independent of their plasma MET concentrations or brain SAM levels. This indicates that the decrease in SAH levels is not simply due to substrate (SAM) restriction. These changes in MET metabolites appear to be a general effect of diabetes rather than a non-pancreatic side-effect of SZ, because genetically diabetic BB Wistar rats also exhibited reduced brain SAM (25%) and brain SAH (46%) levels. These results indicate that methyl-groups from MET are handled differently in the brain of the diabetic rat, which considering the variety and importance of neural methylation reactions, could have important consequences for the diabetic.Abbreviations MET methionine - SAM S-adenosylmethionine - SAH S-adenosylhomocysteine - SZ streptozotocin - BBW BB Wistar - LNAA large neutral amino acids - BCAA branchedchain amino acids - MET:BCAA methionine to branched-chain amino acid ratio - MET:LNAA methionine to large neutral amino acid ratio     

m-OCTOPAMINE, p-OCTOPAMINE AND PHENYLETHANOLAMINE IN RAT BRAIN: A SENSITIVE, SPECIFIC ASSAY AND THE EFFECTS OF SOME DRUGS

Abstract— An enzyme radiochemical assay for p -octopamine, m -octopamine (norphenylephrine) and phenylethanolamine based on the N -methylation of these amines by the enzyme phenylethanolamine N -methyl transferase ( S -adenosyl- l -methionine: phenylethanolamine N -methyl transferase (EC 2.1.1.28) has been developed. [³H]Methyl- S -adenosyl- l -methionine was used as methyl donor. The reaction products are converted to their dansyl derivatives and separated by TLC in three different solvent systems prior to liquid scintillation counting. The method exhibits a sensitivity of less than 10 pg for each amine and is suitable for the measurement of endogenous p -octopamine levels in mammalian brain. The highest levels of p -octopamine were found in the hypothalamus (3.4 ng/g) but despite the sensitivity of the assay, neither phenylethanolamine nor m -octopamine could be detected. After MAO inhibition, however, both of these amines were found to be present. p -Octopamine was increased substantially in all brain regions following the administration of an MAO inhibitor, whereas pretreatment with reserpine produced a significant decrease in the hypothalamus.     

EFFECT OF METHIONINE AND METHIONINE SULPHOXIMINE ON RAT BRAIN S-ADENOSYL METHIONINE LEVELS

Rat brain SAM levels were markedly increased after methionine administration, whereas the convulsant, L-methionine-dl-sulphoximine (MSO), produced a 35 per cent decrease in whole brain content of S-adenosyl-L-methionine (SAM). When methionine was given in combination with MSO, SAM levels were not decreased. Studies on the regional distribution of SAM revealed only a small variation between regions (from 24 nmol/g in midbrain to 49-5 nmol/g in striatum). SAM levels were reduced by about 50 per cent in the cerebellum, striatum, cortex and hippocampus 3 and 6 h after MSO. It is proposed that abberant cerebral methylation processes may be involved in the genesis of the MSO seizure.     

Biomarkers of the one-carbon pathway in association with congenital diaphragmatic hernia

Homocysteine is an intermediate of the one-carbon (1-C) pathway and increased concentrations have been related to neural crest-related congenital anomalies. The neural crest and the 1-C pathway might be involved also in the etiology of Congenital Diaphragmatic Hernia (CDH). In 22 CDH and 28 control newborns and their mothers, general characteristics were obtained by standardized questionnaires. The 1-C pathway intermediates total homocysteine (tHcy), S-adenosylmethionine (SAM), and S-adenosylhomocysteine (SAH) were determined in cord blood. Correlations between maternal and newborn factors and risk estimates were investigated by univariate and multivariable logistic regression analyses. Birth weight (2962 vs. 3418 gram; p < 0.001) was lower and gestational age (270 vs. 277 days; p = 0.006) was shorter in case children. Control mothers were slightly older (32 vs. 35 year; p = 0.05). Other characteristics were comparable between case and control children and mothers. The concentrations of homocysteine, SAM and SAH, and the SAM/SAH ratio were comparable (tHcy: 8.57 vs. 8.56 μmol/l, p = 0.99; SAM: 152.7 vs. 157.3 nmol/l, p = 0.76; SAH: 43.5 vs. 48.9, p = 0.26; ratio: 3.8 vs. 3.5, p = 0.50). Maternal and newborn characteristics were not correlated to the biomarker concentrations. In conclusion, the biomarkers of methylation determined in cord blood are not associated with CDH risk. Maternal and child characteristics could not predict newborn biomarker concentrations of the 1-C pathway.     

Adenosine kinase deficiency is associated with developmental abnormalities and reduced transmethylation

Adenosine (Ado) kinase (ADK; ATP:Ado 5' phosphotransferase, EC 2.7.1.20) catalyzes the salvage synthesis of adenine monophosphate from Ado and ATP. In Arabidopsis, ADK is encoded by two cDNAs that share 89% nucleotide identity and are constitutively, yet differentially, expressed in leaves, stems, roots, and flowers. To investigate the role of ADK in plant metabolism, lines deficient in this enzyme activity have been created by sense and antisense expression of the ADK1 cDNA. The levels of ADK activity in these lines range from 7% to 70% of the activity found in wild-type Arabidopsis. Transgenic plants with 50% or more of the wild-type activity have a normal morphology. In contrast, plants with less than 10% ADK activity are small with rounded, wavy leaves and a compact, bushy appearance. Because of the lack of elongation of the primary shoot, the siliques extend in a cluster from the rosette. Fertility is decreased because the stamen filaments do not elongate normally; hypocotyl and root elongation are reduced also. The hydrolysis of S-adenosyl-L-homo-cysteine (SAH) produced from S-adenosyl-L-methionine (SAM)-dependent methylation reactions is a key source of Ado in plants. The lack of Ado salvage in the ADK-deficient lines leads to an increase in the SAH level and results in the inhibition of SAM-dependent transmethylation. There is a direct correlation between ADK activity and the level of methylesterified pectin in seed mucilage, as monitored by staining with ruthenium red, immunofluorescence labeling, or direct assay. These results indicate that Ado must be steadily removed by ADK to prevent feedback inhibition of SAH hydrolase and maintain SAM utilization and recycling.     

Ethanol-induced increased endogenous homocysteine levels and decreased ratios of SAM/SAH are only partially attenuated by exogenous glycine in developing chick brains

The effects of exogenous ethanol (EtOH) and/or glycine on chick (Gallus gallus) embryo viability, brain apoptosis (caspase-3 activities), and the endogenous levels of brain homocysteine (HoCys), S-adenosylmethionine (SAM), S-adenosylhomocysteine (SAH), and SAM/SAH were studied. Embryonic EtOH exposure caused decreased embryo viability as measured by EtOH-induced reductions in % living embryos at theoretical stage 37, EtOH-induced reductions in embryo masses, and EtOH-induced reductions in brain caspase-3 (Casp-3) activities. Exogenous glycine failed to attenuate EtOH-induced decreased embryo viability and EtOH-induced increased brain Casp-3 activities. Embryonic EtOH exposure caused elevated levels of endogenous HoCys, decreased levels of SAM, increased levels of SAH, and decreased SAM/SAH ratios in embryonic chick brains. While exogenous glycine failed to attenuate EtOH-induced increased HoCys levels, exogenous glycine attenuated EtOH-induced decreased levels of SAM, increased levels of SAH, and decreased SAM/SAH levels in embryonic chick brains.     

Inhibition of methylation of DNA and tRNA by adenosine in an adenosine-sensitive mutant of the baby hamster kidney cell line

An adenosine-sensitive (Ados) mutant of baby hamster kidney (BHK) cells, ara-S10d, when treated with a toxic concentration of adenosine (Ado), displayed a substantial elevation of S-adenosylhomocysteine (SAH), S-adenosylmethionine (SAM), and methylthioadenosine (MTA). Wild-type BHK cells treated with the same concentration of Ado (not toxic to these parental cells) produced an elevation of SAH 1.5 times higher than that of ara-S10d cells without a concurrent elevation of SAM or MTA. Inhibition of methylation of DNA and tRNA is greater in ara-S10d cells treated with Ado than that of similarly treated wild-type cells. This inhibition was correlated with the enhanced Ado toxicity, suggesting inhibition of methylation as a possible causal factor for the great increase in Ado sensitivity. Inhibition of methylation may be due to the elevated level of MTA and not solely to the elevation of SAH, a well-known potent inhibitor of numerous methyltransferases.     

Biomarkers of the one‐carbon pathway in association with congenital diaphragmatic hernia

Homocysteine is an intermediate of the one‐carbon (1‐C) pathway and increased concentrations have been related to neural crest‐related congenital anomalies. The neural crest and the 1‐C pathway might be involved also in the etiology of Congenital Diaphragmatic Hernia (CDH). In 22 CDH and 28 control newborns and their mothers, general characteristics were obtained by standardized questionnaires. The 1‐C pathway intermediates total homocysteine (tHcy), S‐adenosylmethionine (SAM), and S‐adenosylhomocysteine (SAH) were determined in cord blood. Correlations between maternal and newborn factors and risk estimates were investigated by univariate and multivariable logistic regression analyses. Birth weight (2962 vs. 3418 gram; p < 0.001) was lower and gestational age (270 vs. 277 days; p = 0.006) was shorter in case children. Control mothers were slightly older (32 vs. 35 year; p = 0.05). Other characteristics were comparable between case and control children and mothers. The concentrations of homocysteine, SAM and SAH, and the SAM/SAH ratio were comparable (tHcy: 8.57 vs. 8.56 μmol/l, p = 0.99; SAM: 152.7 vs. 157.3 nmol/l, p = 0.76; SAH: 43.5 vs. 48.9, p = 0.26; ratio: 3.8 vs. 3.5, p = 0.50). Maternal and newborn characteristics were not correlated to the biomarker concentrations. In conclusion, the biomarkers of methylation determined in cord blood are not associated with CDH risk. Maternal and child characteristics could not predict newborn biomarker concentrations of the 1‐C pathway. Birth Defects Research (Part A) 2012. © 2012 Wiley Periodicals, Inc.     

Reversed-phase high-performance liquid chromatography procedure for the simultaneous determination of S-adenosyl-l-methionine and S-adenosyl-l-homocysteine in mouse liver and the effect of methionine on their concentrations

An improved reversed-phase high-performance liquid chromatography (HPLC) procedure with ultraviolet detection is described for the simultaneous determination of S-adenosyl-l-methionine (SAM) and S-adenosyl-l-homocysteine (SAH) in mouse tissue. The method provides rapid resolution of both compounds in a 25-μl perchloric acid extract of the tissue. The limits of detection in 25-μl injection volumes were 22 and 20 pmol for SAM and SAH, respectively. The limits of quantitation in 25-μl injection volumes were 55 and 50 pmol for SAM and SAH, respectively, with recovery consistently >98%. The assay was validated over linear ranges of 55–11 000 pmol for SAM and 50–10 000 pmol for SAH. The intra-day precision and accuracy were ≤6.4% relative standard deviation (RSD) and 99.9–100.0% for SAH and ≤6.7% RSD and 100.0–100.1% for SAM. The inter-day precision and accuracy were ≤5.9% RSD and 99.9–100.6% for SAH and ≤7.0% RSD and 99.5–100.1% for SAM. Compared to earlier procedures, the HPLC method demonstrated significantly better separation, detection limit and linear range for SAM and SAH determination. The assay demonstrated applicability to monitoring in mice the time-course of the effect of methionine on SAM and SAH levels in the liver. Administering methionine to mice increased by 10-fold the liver concentration of SAM and SAH within 2 h, which then rapidly decreased to the control levels by 8 h. This indicated that methionine was promptly converted to SAM and then rapidly catabolized into SAH. Thus, the metabolism of methionine to SAM should be considered in the supplementation of methionine to maintain SAM levels in the body.     

Effects of L-dopa treatment on methylation in mouse brain: implications for the side effects of L-dopa

The effects of L-dopa on methylation process in the mouse brain were investigated. The study is based on recent findings that methylation may play an important role in Parkinson's disease (PD) and in the actions of L-dopa. The methyl donor, S-adenosylmethionine (SAM) and a product of SAM, methyl beta-carboline, were shown to cause PD-like symptoms, when injected into the brain of animals. Furthermore, large amounts of 3-O-methyl dopa, the methyl product of L-dopa, are produced in PD patients receiving L-dopa treatment, and L-dopa induces methionine adenosyl transferase, the enzyme that produces SAM. The results show that, at 0.5 hr, L-dopa (100 mg/kg) decreased the methyl donor, S-adenosylmethionine (SAM) by 36%, increased its metabolite S-adenosylhomocysteine (SAH) by 89% and increased methylation (SAH/SAM) by about 200%. All parameters returned to control values within 4 hr. But 2, 3 and 4 consecutive injections of L-dopa, given at 45 min intervals, depleted SAM by 60, 64 and 76% and increased SAM/SAH to 818, 896, and 1524%. L-dopa (50, 100 and 200 mg/kg) dose-dependently depleted SAM from 24.9 +/- 1.7 nmol/g to 13.0 +/- 0.8, 14.7 +/- 0.8 and 7.7 +/- 0.7 nmol/g, and increased SAH from 1.88 +/- 0.14 to 3.43 +/- 0.26, 4.22 +/- 0.32 and 6.21 +/- 0.40 nmol/g. Brain L-dopa was increased to 326, 335 and 779%, dopamine to 138, 116 and 217% and SAH/SAM to 354, 392 and 1101%. The data show that L-dopa depletes SAM, and increases methylation 4-5 times more than dopamine, therefore, methylation may play a role in the actions of L-dopa. This and other studies suggest that the high level of utilization of methyl group by L-dopa leads to the induction of enzymes to replenish SAM and to increase the methylation of L-dopa as well as DA. These changes may be involved in the side effects of L-dopa.     

Somatic embryo development in carrot is associated with an increase in levels of S-adenosylmethionine,S-adenosylhomocysteine and DNA methylation

Almost homogeneous populations representing different developmental stages of somatic embryos (globular, torpedo-shaped, plantlets) and vacuolated cells were obtained from a cell suspension culture of carrot. The concentrations of S-adenosylmethionine (SAM), S-adenosylhomocysteine (SAH) and methylated DNA were determined in embryos at different developmental stages and were found to increase during somatic embryogenesis. The highest increase during embryogenesis was a 5-fold increase in the level of SAM. A considerable increase in the methylation index (SAM/SAH ratio) was also found. We propose that the levels of SAM and SAH may be involved in the control of somatic embryogenesis by affecting the level of DNA methylation, which in turn might cause differential changes in gene activation. An increase in the level of SAM may be a prerequisite for progression of embryogenesis and the development of complete embryos.     

Regional Distribution of Methionine Adenosyltransferase in Rat Brain as Measured by a Rapid Radiochemical Method

Abstract: The distribution of methionine adenosyltransferase (MAT) in the CNS of the rat was studied by use of a rapid, sensitive and specific radiochemical method. The S -adenosyl-[methyl-¹⁴C] l -methionine ([¹⁴C]SAM) generated by adenosyl transfer from ATP to [methyl-¹⁴C] l -methionine is quantitated by use of a SAM-consuming transmethylation reaction. Catechol O -methyltransferase (COMT), prepared from rat liver, transfers the methyl-¹⁴C group of SAM to 3,4-dihydroxybenzoic acid. The ¹⁴C-labelled methylation products, vanillic acid and isovanillic acid, are separated from unreacted methionine by solvent extraction and quantitated by liquid scintillation counting. Compared to other methods of MAT determination, which include separation of generated SAM from methionine by ion-exchange chromatography, the assay described exhibited the same high degree of specificity and sensitivity but proved to be less time consuming. MAT activity was found to be uniformly distributed between various brain regions and the pituitary gland of adult male rats. In the pineal gland the enzyme activity is about tenfold higher.     

Cigarette smoke extract increases S-adenosylmethionine and cystathionine in human lung epithelial-like (A549) cells

The effect of cigarette smoke extract (CSE) on S-adenosylmethionine (SAM), S-adenosylhomocysteine (SAH), and sulfur amino acid metabolism was examined in human lung epithelial-like (A549) cells exposed to various CSE concentrations (2.5-100%) for 24 or 48 h. Intracellular SAM and SAM/SAH ratio were elevated after exposure to CSE for 48 h. Cell SAH content decreased, but the effect was not consistent. Cellular cystathionine, cysteine, and methionine levels were increased after CSE exposure for 48h. Sub-acute exposure to CSE induced increases in cellular SAM and SAM/SAH ratio. The transsulfuration pathway was likely activated by CSE since cystathionine increased, potentially contributing to the increased total intracellular GSH content.     

Role of adenosine kinase in the control of Streptomyces differentiations: Loss of adenosine kinase suppresses sporulation and actinorhodin biosynthesis while inducing hyperproduction of undecylprodigiosin in Streptomyces lividans

Adenosine kinase (ADK) catalyses phosphorylation of adenosine (Ado) and generates adenosine monophosphate (AMP). ADK gene (adk(Sli), an ortholog of SCO2158) was disrupted in Streptomyces lividans by single crossover-mediated vector integration. The adk(Sli) disruption mutant (Deltaadk(Sli)) was devoid of sporulation and a plasmid copy of adk(Sli) restored sporulation ability in Deltaadk(Sli), thus indicating that loss of adk(Sli) abolishes sporulation in S. lividans. Ado supplementation strongly suppressed sporulation ability in S. lividans wild-type (wt), supporting that disruption of adk(Sli) resulted in Ado accumulation, which in turn suppressed sporulation. Cell-free experiments demonstrated that Deltaadk(Sli) lacked ADK activity and in vitro characterization confirms that adk(Sli) encodes ADK. The intracellular level of Ado was highly elevated while the AMP level was significantly reduced after loss of adk(Sli) while Deltaadk(Sli) displayed no significant derivation from wt in the levels of S-adenosylhomocysteine (SAH) and S-adenosylmethionine (SAM). Notably, Ado supplementation to wt lowered AMP content, albeit not to the level of Deltaadk(Sli), implying that the reduction of AMP level is partially forced by Ado accumulation in Deltaadk(Sli). In Deltaadk(Sli), actinorhodin (ACT) production was suppressed and undecylprodigiosin (RED) production was dramatically enhanced; however, Ado supplementation failed to exert this differential control. A promoter-probe assay verified repression of actII-orf4 and induction of redD in Deltaadk(Sli), substantiating that unknown metabolic shift(s) of ADK-deficiency evokes differential genetic control on secondary metabolism in S. lividans. The present study is the first report revealing the suppressive role of Ado in Streptomyces development and the differential regulatory function of ADK activity in Streptomyces secondary metabolism, although the underlying mechanism has yet to be elucidated.