S-adenosylmethionine Synthetase Gene Research Articles

Engineered Pichia pastoris for enhanced production of S-adenosylmethionine

A genetically engineered strain of Pichia pastoris expressing S-adenosylmethionine synthetase gene from Saccharomyces cerevisiae under the control of AOX 1 promoter was developed. Induction of recombinant strain with 1% methanol resulted in the expression of SAM2 protein of ~ 42 kDa, whereas control GS115 showed no such band. Further, the recombinant strain showed 17-fold higher enzyme activity over control. Shake flask cultivation of engineered P. pastoris in BMGY medium supplemented with 1% L-methionine yielded 28 g/L wet cell weight and 0.6 g/L S-adenosylmethionine, whereas control (transformants with vector alone) with similar wet cell weight under identical conditions accumulated 0.018 g/L. The clone cultured in the bioreactor containing enriched methionine medium showed increased WCW (117 g/L) as compared to shake flask cultures and yielded 2.4 g/L S-adenosylmethionine. In spite of expression of SAM 2 gene up to 90 h, S-adenosylmethionine accumulation tended to plateau after 72 h, presumably because of the limited ATP available in the cells at stationery phase. The recombinant P pastoris seems promising as potential source for industrial production of S-adenosylmethionine.

Morphology, Genome Plasticity, and Phylogeny in the Genus Ostreococcus Reveal a Cryptic Species, O. mediterraneus sp. nov. (Mamiellales, Mamiellophyceae)

Coastal marine waters in many regions worldwide support abundant populations of extremely small (1-3μm diameter) unicellular eukaryotic green algae, dominant taxa including several species in the class Mamiellophyceae. Their diminutive size conceals surprising levels of genetic diversity and defies classical species' descriptions. We present a detailed analysis within the genus Ostreococcus and show that morphological characteristics cannot be used to describe diversity within this group. Karyotypic analyses of the best-characterized species O. tauri show it to carry two chromosomes that vary in size between individual clonal lines, probably an evolutionarily ancient feature that emerged before species' divergences within the Mamiellales. By using a culturing technique specifically adapted to members of the genus Ostreococcus, we purified >30 clonal lines of a new species, Ostreococcus mediterraneus sp. nov., previously known as Ostreococcus clade D, that has been overlooked in several studies based on PCR-amplification of genetic markers from environment-extracted DNA. Phylogenetic analyses of the S-adenosylmethionine synthetase gene, and of the complete small subunit ribosomal RNA gene, including detailed comparisons of predicted ITS2 (internal transcribed spacer 2) secondary structures, clearly support that this is a separate species. In addition, karyotypic analyses reveal that the chromosomal location of its ribosomal RNA gene cluster differs from other Ostreococcus clades.

Overexpression of metK shows different effects on avermectin production in various Streptomyces avermitilis strains

The S-adenosylmethionine synthetase gene (metK) from Streptomyces avermitilis was cloned into multi-copy vector pIJ653 and integrative vector pSET152 yielding two metK expression plasmids pYJ02 and pYJ03, respectively. When wild-type strain ATCC31267 was transformed with these two plasmids, avermectin production was increased about 2.0-fold and 5.5-fold, respectively. The introduction of integrative expression plasmid pYJ03 into the engineered strain GB-165, which produces only avermectin B, promoted the production of avermectin approximately 2.0-fold. However, introduction of pYJ02 did not influence avermectin accumulation in GB-165. Moreover, transformation of the avermectin-overproducing industry strain 76-05 with these two plasmids did not stimulate avermectin production. These results showed that there were different effects of metK expression levels on avermectin production in various S. avermitilis strains. Additionally, the transcript levels of metK, aveR (the avermectin pathway-specific regulatory gene) and aveA1 (one avermectin biosynthesis gene) meet the expectation of fermentation levels of avermectin in wild-type strain and its recombinant strains. The gene expression levels of metK, aveR and aveA1 in GB-165 and 76-05 were much higher then those in wild-type strain, which probably limited the increasement of avermectin by overexpression of metK.

高盐下条斑紫菜光合特性和S-腺苷甲硫氨酸合成酶基因表达的变化

为了研究条斑紫菜耐盐机理,对条斑紫菜叶状体进行了高盐胁迫处理,继而采用氧电极法测量了光合放氧速率和呼吸耗氧速率的变化,采用实时荧光定量PCR技术测量了S-腺苷甲硫氨酸合成酶(命名为PySAMS)基因的表达变化。结果显示藻体的光合与呼吸作用均受到高盐度海水的显著影响,随着盐度的增加,光合放氧率逐渐降低,呼吸耗氧率也逐渐降低。高盐度海水对PySAMS基因表达量也产生了显著影响,40和50盐度的海水诱导了PySAMS表达,但60至80盐度的海水却不同程度地抑制了PySAMS表达。据此推测,在面对较高盐度胁迫时条斑紫菜叶状体将逐步降低体内新陈代谢以度过不良环境。;The intertidal red alga <em>Porphyra yezoensis</em> is an important marine crop which has a high stress tolerance. The salinity of the remaining water on the surface of the <em>P. yezoensis</em> thalli increases significantly during emersion, however, thalli can survive this severe osmotic dehydration. In order to investigate the mechanism of high salinity tolerance in <em>P.yezoensis</em>, the effects of high salinity on S-Adenosylmethionine synthetase (designated as PySAMS) gene expression and photosynthetic characteristics in <em>P. yezoensis</em> were determined. At first the thalli of <em>P. yezoensis</em> were subjected to seawater with high salinities (40, 50, 60, 70 or 80 salinity) for 1h. Then the oxygen evolution and consumption in cellular processes of photosynthesis and respiration were measured using the Oxygraph oxygen electrode system. And the relative mRNA expression levels of PySAMS gene were investigated using the real-time PCR. The results show that both photosynthesis and respiration were significantly influenced by seawater with 50, 60, 70 or 80 salinity in <em>P. yezoensis</em> thalli. The higher was the salinity of seawater, the lower was the oxygen evolution rate, and the lower was the oxygen consumption rate. The PySAMS gene expression was also influenced by seawater with high salinities significantly in <em>P. yezoensis</em> thalli. Seawater with 40 and 50 salinity induced the expression of PySAMS gene. However sawater with 60, 70 and 80 salinity repressed the expression of PySAMS gene. Based upon these we speculated that<em> P. yezoensis</em> thalli reduce the metabolism rate gradually to survive the unsuitable environmental condition when thalli suffer high salinity stress.

RNA Interference 및 T-DNA Integration 방법에 의한 배추 기능유전자 Silencing 효과 비교

본 연구는 배추의 유전자 기능분석을 위한 RNAi 유전자 침묵 기법과 T-DNA 삽입 기법을 비교하기 위해 수행하였다. 두 종류의 형질전환 계통이 이용되었으며 BrSAMS-knockout(KO) 계통은 T-DNA 삽입으로 한 개의 Brassica rapa S-adenosylmethionine synthetase(BrSAMS) 유전자가 기능을 상실한 계통이었으며 BrSAMS-knockdown(KD) 계통은 RNAi 방법을 통해 BrSAMS 유전자들의 발현이 억제된 계통이었다. KO 계통과 KD 계통의 microarray 분석 결과에서는 SAMS 유전자와 관련된 sterol, 자당, homogalacturonan 생합성 및 glutaredoxin-related protein, serine/threonine protein kinase, 그리고 gibberellin-responsive protein 유전자들의 발현 수준이 뚜렷한 차이를 보여 주었다. 그러나 KO 계통의 유전자 발현 양상은 하나의 BrSAMS 유전자가 기능을 상실하였음에도 불구하고 대조 계통과 비교하여 RNAi기법을 적용한 KD 계통에 비해 큰 차이를 보여주지 못했다. 또한 직접적으로 SAMS 유전자와 관련된 폴리아민과 에틸렌 합성 유전자들의 발현 변화도 KD 계통에서 더 잘 나타났다. 본 연구에서 microarray 결과를 이용한 KO 계통의 BrSAMS 기능분석은 배추과식물의 게놈 triplication 발생으로 인하여 다수로 존재하는 SAMS 유전자들 때문에 명확한 결론을 얻을 수 없었다. 결론적으로 배추와 같은 배수체 작물의 유전자 기능 분석은 RNAi silencing에 의한 유전자 knock-down 기법이 T-DNA 삽입에 의한 knock-out 기법보다 더욱 효율적인 것으로 나타났다. To compare RNA interference-mediated gene silencing technique and T-DNA integration for gene function analysis in Chinese cabbage, BrSAMS-knockout (KO) line and BrSAMS-knockdown (KD) line were used. The KO line had lost the function of a Brassica rapa S-adenosylmethionine synthetase (BrSAMS) gene by T-DNA insertion and the KD line had shown down-regulated BrSAMS genes' expression by dsRNA cleavage. From microarray results of the KO and KD lines, genes linked to SAMS such as sterol, sucrose, homogalacturonan biosynthesis and glutaredoxin-related protein, serine/threonine protein kinase, and gibberellin-responsive protein showed distinct differences in their expression levels. Even though one BrSAMS gene in the KO line was broken by T-DNA insertion, gene expression pattern of that line did not show remarkable differences compared to wild type control. However, the KD line obtained by RNAi technique showed prominent difference in its gene expression. Besides, change of polyamine and ethylene synthesis genes directly associated with BrSAMS was displayed much more in the KD line. In the microarray analysis of the KO line, BrSAMS function could not be clearly defined because of BrSAMS redundancy due to the genome triplication events in Brassicaceae. In conclusion, we supposed that gene knock-down method by RNAi silencing is more effective than knock-out method by T-DNA insertion for gene function analysis of polyploidy crops such as Chinese cabbage.

Detection ofCryptosporidiumSpecies in the Sea and Tap Water Samples of Black Sea, Turkey

The aim of this study was to evaluate Cryptosporidium spp. contamination of sea and tap water samples from Sinop and Ordu Provinces, Black Sea, Turkey. The samples (10 L) were collected in spring, summer, autumn, and winter in 2011. A total of 128 water samples was analyzed using an immunofluorescence test (IFT), as well as loop-mediated isothermal amplification (LAMP) and nested polymerase chain reaction (PCR). Cryptosporidium spp. oocysts were detected by IFT in 43 of the 70 samples (61.4%; 1-40 oocysts per 0.5 L) and 35 of the 58 samples (60.3%; 1-23 oocysts per 0.5 L) in the sea water samples from Ordu and Sinop, respectively. The highest number of oocysts by IFT were detected in spring and winter in Ordu and Sinop, respectively. The results of the S-adenosylmethionine synthetase (SAM) gene LAMP assays were 65.5% positive for Cryptosporidium parvum , Cryptosporidium hominis , and Cryptosporidium meleagridis in all examined samples, while the SSUrRNA gene nested PCR assay was 31.0% positive. Six C. parvum nested PCR products from all positive samples were successfully sequenced.

Molecular cloning and characterization of S-adenosylmethionine synthetase gene from Lycoris radiata

S-adenosylmethionine (SAM) synthetase catalyzes the synthesis of SAM, a molecule important for all cellular organisms. It is also considered to play an important role in salt tolerance of plants. Here, we cloned a Lycoris radiata (L. radiata) SAM synthetase gene LrSAMS to determine its biological function. The gene encodes a protein of 401 amino acids with a calculated molecular weight of 43.9kDa. Amino acid sequence analysis of the deduced protein LrSAMS reveals high sequence identity to SAM synthetases from other organisms, such as Arabidopsis thaliana and Oryza sativa. The deduced LrSAMS protein contains conserved amino acids residues and sequences motifs that closely related to the function of SAM synthetase. Otherwise, the transcript levels of LrSAMS were significantly induced by NaCl treatment in L. radiata leaves, which implied that LrSAMS might play an important role in tolerance to salt stress in L.radiata. Complete ORF of LrSAMS was inserted into expression vector pET-29a(+) and transformed into Escherichia coli BL21 (DE3). The difference between the growth curve of the transgenic strain and control strain with blank vector showed that over-expressing LrSAMS could provide growth advantage to the engineered strain in high salt concentration.

Coordinated regulation of sulfur and phospholipid metabolism reflects the importance of methylation in the growth of yeast

A yeast strain lacking Met4p, the primary transcriptional regulator of the sulfur assimilation pathway, cannot synthesize methionine. This apparently simple auxotroph did not grow well in rich media containing excess methionine, forming small colonies on yeast extract/peptone/dextrose plates. Faster-growing large colonies were abundant when overnight cultures were plated, suggesting that spontaneous suppressors of the growth defect arise with high frequency. To identify the suppressor mutations, we used genome-wide single-nucleotide polymorphism and standard genetic analyses. The most common suppressors were loss-of-function mutations in OPI1, encoding a transcriptional repressor of phospholipid metabolism. Using a new system that allows rapid and specific degradation of Met4p, we could study the dynamic expression of all genes following loss of Met4p. Experiments using this system with and without Opi1p showed that Met4 activates and Opi1p represses genes that maintain levels of S-adenosylmethionine (SAM), the substrate for most methyltransferase reactions. Cells lacking Met4p grow normally when either SAM is added to the media or one of the SAM synthetase genes is overexpressed. SAM is used as a methyl donor in three Opi1p-regulated reactions to create the abundant membrane phospholipid, phosphatidylcholine. Our results show that rapidly growing cells require significant methylation, likely for the biosynthesis of phospholipids.

The SAM‐responsive SMK box is a reversible riboswitch

The S(MK) (SAM-III) box is an S-adenosylmethionine (SAM)-responsive riboswitch found in the 5' untranslated region of metK genes, encoding SAM synthetase, in many members of the Lactobacillales. SAM binding causes a structural rearrangement in the RNA that sequesters the Shine-Dalgarno (SD) sequence by pairing with a complementary anti-SD (ASD) sequence; sequestration of the SD sequence inhibits binding of the 30S ribosomal subunit and prevents translation initiation. We observed a slight increase in the half-life of the metK transcript in vivo when Enterococcus faecalis cells were depleted for SAM, but no significant change in overall transcript abundance, consistent with the model that this riboswitch regulates at the level of translation initiation. The half-life of the SAM-S(MK) box RNA complex in vitro is shorter than that of the metK transcript in vivo, raising the possibility of reversible binding of SAM. We used a fluorescence assay to directly visualize reversible switching between the SAM-free and SAM-bound conformations. We propose that the S(MK) box riboswitch can make multiple SAM-dependent regulatory decisions during the lifetime of the transcript in vivo, acting as a reversible switch that allows the cell to respond rapidly to fluctuations in SAM pools by modulating expression of the SAM synthetase gene.

Ethylene and nitric oxide involvement in the up-regulation of key genes related to iron acquisition and homeostasis in Arabidopsis

In a previous work it was shown that ethylene participates in the up-regulation of several Fe acquisition genes of Arabidopsis, such as AtFIT, AtFRO2, and AtIRT1. In this work the relationship between ethylene and Fe-related genes in Arabidopsis has been looked at in more depth. Genes induced by Fe deficiency regulated by ethylene were searched for. For this, studies were conducted, using microarray analysis and reverse transcription-PCR (RT-PCR), to determine which of the genes up-regulated by Fe deficiency are simultaneously suppressed by two different ethylene inhibitors (cobalt and silver thiosulphate), assessing their regulation by ethylene in additional experiments. In a complementary experiment, it was determined that the Fe-related genes up-regulated by ethylene were also responsive to nitric oxide (NO). Further studies were performed to analyse whether Fe deficiency up-regulates the expression of genes involved in ethylene biosynthesis [S-adenosylmethionine synthetase, 1-aminocyclopropane-1-carboxylate (ACC) synthase, and ACC oxidase genes] and signalling (AtETR1, AtCTR1, AtEIN2, AtEIN3, AtEIL1, and AtEIL3). The results obtained show that both ethylene and NO are involved in the up-regulation of many important Fe-regulated genes of Arabidopsis, such as AtFIT, AtbHLH38, AtbHLH39, AtFRO2, AtIRT1, AtNAS1, AtNAS2, AtFRD3, AtMYB72, and others. In addition, the results show that Fe deficiency up-regulates genes involved in both ethylene synthesis (AtSAM1, AtSAM2, AtACS4, AtACS6, AtACS9, AtACO1, and AtACO2) and signalling (AtETR1, AtCTR1, AtEIN2, AtEIN3, AtEIL1, and AtEIL3) in the roots.

Cloning and expression of S-Adenosyl Methionine (SAMe) Synthetase gene in recombinant E. coli strain for large scale production of SAMe

Adenosyl Methionine (SAMe) Synthetase is an enzyme which catalyses the synthesis of S-Adenosyl Methionine using methionine and ATP. It is also known as AdoMet which is well known methyl donor, which modifies DNA, RNA, histones and other proteins, dictating replicational, transcriptional and translational fidelity, mismatch repair, chromatin modeling, epigenetic modifications and imprinting. The objective of the present work is to clone the SAMe Synthetase gene in recombinant E. coli strain in order to express, characterize and purify it for further synthesis of SAMe in a large scale fermentation. Expression was induced by 1 mM IPTG and expressed protein was characterized by SDS-PAGE. The recombinant E. coli cells were used for the production of SAMe through batch and fed batch fermentation operations. The produced SAMe was purified through paper chromatography in order to use it in our future studies.

S-Adenosylmethionine (SAM) and antibiotic biosynthesis: effect of external addition of SAM and of overexpression of SAM biosynthesis genes on novobiocin production in Streptomyces

The production of antibiotics in different Streptomyces strains has been reported to be stimulated by the external addition of S-adenosylmethionine (SAM) and by overexpression of the SAM synthetase gene metK. We investigated the influence of SAM addition, and of the expression of SAM biosynthetic genes, on the production of the aminocoumarin antibiotic novobiocin in the heterologous producer strain Streptomyces coelicolor M512 (nov-BG1). External addition of SAM did not influence novobiocin accumulation. However, overexpression of a SAM synthase gene stimulated novobiocin formation, concomitant with an increase of the intracellular SAM concentration. Streptomyces genomes contain orthologs of all genes required for the SAM cycle known from mammals. In contrast, most other bacteria use a different cycle for SAM regeneration. Three secondary metabolic gene clusters, coding for the biosynthesis of structurally very different antibiotics in different Streptomyces strains, were found to contain an operon comprising all five putative genes of the SAM cycle. We cloned one of these operons into an expression plasmid, under control of a strong constitutive promoter. However, transformation of the heterologous novobiocin producer strain with this plasmid did not stimulate novobiocin production, but rather showed a detrimental effect on cell viability in the stationary phase and strongly reduced novobiocin accumulation.

The Overexpression of Cyanidioschyzon merolae S-adenosylmethionine Synthetase Enhances Salt Tolerance in Transgenic Arabidopsis thaliana

High salinity is one of the most serious threats to crop production. The primitive red alga, Cyanidioschyzon merolae, inhabits an extreme environment (42°C, pH 2.5, high salt, metal ion). We have utilized the ability of C. merolae cells to adapt to 0.3 M sodium salt, as well as information from its fully sequenced genome, to produce salt-tolerant transgenic higher plants. To reveal the mechanisms of high salt tolerance, we analyzed, by RT-PCR, genes that were expressed at high levels after salt stress (0.3 M NaCl). The C. merolae S-adenosylmethionine synthetase (CmSAMS) gene that codes for an enzyme in the polyamine biosynthesis pathway was expressed at high levels (4 to 5 expression ratio). Our results are in accordance with our previously reported DNA microarray data. The CmSAMS gene codes for a 393-aa protein contain 3 conserved domains at the N-terminal and a semi-conserved domain at the C-terminal. The particle bombardment method revealed that the recombinant CmSAMS-green fluorescent protein was localized in the cytoplasm and the nuclei of the plant cells. To further investigate tolerance to salt stress, we produced, by Agrobacterium-mediated transformation, 4 transgenic Arabidopsis thaliana plant lines expressing CmSAMS. Compared to wild-type plants, the CmSAMS transgenic plants were more tolerant to salt stress, clearly defining a role for the CmSAMS gene in conferring salt-stress tolerance.

A gene expression analysis of syncytia laser microdissected from the roots of the Glycine max (soybean) genotype PI 548402 (Peking) undergoing a resistant reaction after infection by Heterodera glycines (soybean cyst nematode)

The syncytium is a nurse cell formed within the roots of Glycine max by the plant parasitic nematode Heterodera glycines. Its development and maintenance are essential for nematode survival. The syncytium appears to undergo two developmental phases during its maturation into a functional nurse cell. The first phase is a parasitism phase where the nematode establishes the molecular circuitry that during the second phase ensures a compatible interaction with the plant cell. The cytological features of syncytia undergoing susceptible or resistant reactions appear the same during the parasitism phase. Depending on the outcome of any defense response, the second phase is a period of syncytium maintenance (susceptible reaction) or failure (resistant reaction). In the analyses presented here, the localized gene expression occurring at the syncytium during the resistant reaction was studied. This was accomplished by isolating syncytial cells from Glycine max genotype Peking (PI 548402) by laser capture microdissection. Microarray analyses using the Affymetrix soybean GeneChip directly compared Peking syncytia undergoing a resistant reaction to those undergoing a susceptible reaction during the parasitism phase of the resistant reaction. Those analyses revealed lipoxygenase-9 and lipoxygenase-4 as the most highly induced genes in the resistant reaction. The analysis also identified induced levels of components of the phenylpropanoid pathway. These genes included phenylalanine ammonia lyase, chalcone isomerase, isoflavone reductase, cinnamoyl-CoA reductase and caffeic acid O-methyltransferase. The presence of induced levels of these genes implies the importance of jasmonic acid and phenylpropanoid signaling pathways locally at the site of the syncytium during the resistance phase of the resistant reaction. The analysis also identified highly induced levels of four S-adenosylmethionine synthetase genes, the EARLY-RESPONSIVE TO DEHYDRATION 2 gene and the 14-3-3 gene known as GENERAL REGULATORY FACTOR 2. Subsequent analyses studied microdissected syncytial cells at 3, 6 and 9 days post infection (dpi) during the course of the resistant reaction, resulting in the identification of signature gene expression profiles at each time point in a single G. max genotype, Peking.

Structural and kinetic properties of Bacillus subtilis S-adenosylmethionine synthetase expressed in Escherichia coli

S-adenosylmethionine (SAM) synthetase (EC 2.5.1.6) catalyzes the synthesis of S-adenosylmethionine using l-methionine and ATP as substrates. SAM synthetase gene ( metE) from Bacillus subtilis was cloned and over-expressed, for the first time, in the heterologus host Escherichia coli as an active enzyme. Size-exclusion chromatography (SEC) revealed a molecular weight of ~ 180 kDa, suggesting that the enzyme is a homotetramer stabilized by non-covalent interactions. SAM synthetase exhibited optimal activity at pH 8.0 and 45 °C with the requirement of divalent cation Mg 2+, and stimulated by the monovalent cation K +. The enzyme followed sequential mechanism with a V max of 0.362 µmol/min/mg, and a K m of 920 µM and 260 µM for ATP and l-methionine, respectively. The urea-induced unfolding equilibrium of the recombinant enzyme revealed a multistate process, comprising partially unfolded tetramer, structural dimer, structural monomer and completely unfolded monomer, as evidenced by intrinsic and extrinsic fluorescence, circular dichroism (CD) and SEC. Absence of trimer in the SEC implicates that the enzyme is a dimer of dimer. Concordance between results of SEC and enzyme activity in the presence of urea amply establishes that tetramer alone with intersubunit active site(s) exhibits enzyme activity.

Microarray Analysis Reveals S-Adenosylmethionine (SAM) Synthetase Involvement in Salt Tolerance of Cyanidioschyzon merolae

We searched for candidate genes for producing salt tolerant plants from the red alga Cyanidioschyzon merolae, which lives in an extreme environment (hot springs). Arabidopsis thaliana plants die under 0.1 M salt culture, whereas the red algal cells survived under 0.3 M salt for 7 d. However, their chloroplasts changed from green to white and they soon died under 0.4 M, which is the concentration of seawater. Genes that were selectively expressed at 2 h and 24 h in 0.3 M salt concentrations were examined by microarray analysis. Under salt stress, the numbers of highly expressed genes at 2 h increased from 70 to 95 after culture for 24 h. The highly expressed genes included those encoding proteins similar to low molecular weight heat shock proteins, heat shock protein 70, and S-adenosylmethionine (SAM) synthetase. On the base of the present data and on the known metabolic functions of the proteins, we suggest that the SAM synthetase gene from C. merolae is a candidate gene for genetic engineering to produce salt tolerance plants.

Improving heterologous polyketide production in Escherichia coli by overexpression of an S-adenosylmethionine synthetase gene

An S-adenosylmethionine synthetase gene (metK) from Streptomyces spectabilis was cloned into an expression plasmid under the control of an inducible T7 promoter and introduced into a strain of Escherichia coli (BAP1(pBP130/pBP144)) capable of producing the polyketide product 6-deoxyerythronolide B (6-dEB). The metK coexpression in BAP1(pBP130/pBP144) improved the specific production of 6-dEB from 10.86 to 20.08 mg l(-1) OD(600)(-1). In an effort to probe the reason for this improvement, a series of gene deletion and expression experiments were conducted based on a metK metabolic pathway that branches between propionyl-CoA (a 6-dEB precursor) and autoinducer compounds. The deletion and expression studies suggested that the autoinducer pathway had a larger impact on improved 6-dEB biosynthesis. Supporting these results were experiments demonstrating the positive effect conditioned media (the suspected location of the autoinducer compounds) had on 6-dEB production. Taken together, the results of this study show an increase in heterologous 6-dEB production concomitant with heterologous metK gene expression and suggest that the mechanism for this improvement is linked to native autoinducer compounds.

Improved production of erythromycin A by expression of a heterologous gene encoding S-adenosylmethionine synthetase

An S-adenosylmethionine synthetase (SAM-s) gene from Streptomyces spectabilis was integrated along with vector DNA into the chromosome of a Saccharopolyspora erythraea E2. Elevated production of SAM was observed in the recombinant strain Saccharopolyspora erythraea E1. The results from the bioassay showed that the titer of erythromycin was increased from 920 IU ml(-1) by E2 to approximately 2,000 IU ml(-1) by E1. High performance liquid chromatography (HPLC) analysis revealed that there was a 132% increase in erythromycin A compared with the original strain, while the erythromycin B, the main impurity component in erythromycin, was decreased by 30%. The sporulation process was inhibited, while the SAM-s gene was expressed. The addition of the exogenous SAM also inhibited sporulation and promoted an increase in erythromycin titers.

S-adenosylmethionine synthetase genes from eleven marine dinoflagellates

L.D. Harlow, A. Koutoulis and G.M. Hallegraeff. 2007. S-adenosylmethionine synthetase genes from eleven marine dinoflagellates. Phycologia 46: 46–53. DOI: 10.2216/06-28.1Paralytic shellfish poisoning toxins (PSTs) such as saxitoxin are believed to be synthesised from precursor molecules including arginine, S-adenosylmethionine (SAM) and acetate. The enzyme SAM synthetase is a good candidate as an early acting enzyme in the PST biosynthetic pathway. We have used degenerate PCR to identify the gene encoding SAM synthetase, Sam, in dinoflagellates. Several different PCR products were cloned and sequenced from PST-producing strains of the dinoflagellates Alexandrium minutum, A. catenella and Gymnodinium catenatum and primers specific to dinoflagellate Sam used for further sequence analysis in 11 species of toxic and nontoxic dinoflagellate genera, including: Alexandrium, Gymnodinium, Karenia, Karlodinium, Noctiluca, Prorocentrum and Takayama. At the nucleotide level, Sam clones were unique to dinoflagellates and the most commonly identified Sam was highly conserved between dinoflagellate species. Dinoflagellate Sam G + C content was both typical (60.8%) or lower (40.7%) compared to A. tamarense. The derived protein sequences showed a low and equal level of similarity to Sam from other species representing a range of Kingdoms. DNA sequence information for dinoflagellate Sam provides important insights for dinoflagellate codon usage, which will facilitate primer design to target novel dinoflagellate genes.

An unusual S-adenosylmethionine synthetase gene from dinoflagellate is methylated

BackgroundS-Adenosylmethionine synthetase (AdoMetS) catalyzes the formation of S-Adenosylmethionine (AdoMet), the major methyl group donor in cells. AdoMet-mediated methylation of DNA is known to have regulatory effects on DNA transcription and chromosome structure. Transcription of environmental-responsive genes was demonstrated to be mediated via DNA methylation in dinoflagellates.ResultsA full-length cDNA encoding AdoMetS was cloned from the dinoflagellate Crypthecodinium cohnii. Phylogenetic analysis suggests that the CcAdoMetS gene, is associated with the clade of higher plant orthrologues, and not to the clade of the animal orthrologues. Surprisingly, three extra stretches of residues (8 to 19 amino acids) were found on CcAdoMetS, when compared to other members of this usually conserved protein family. Modeled on the bacterial AdeMetS, two of the extra loops are located close to the methionine binding site. Despite this, the CcAdoMetS was able to rescue the corresponding mutant of budding yeast. Southern analysis, coupled with methylation-sensitive and insensitive enzyme digestion of C. cohnii genomic DNA, demonstrated that the AdoMetS gene is itself methylated. The increase in digestibility of methylation-sensitive enzymes on AdoMet synthetase gene observed following the addition of DNA methylation inhibitors L-ethionine and 5-azacytidine suggests the presence of cytosine methylation sites within CcAdoMetS gene. During the cell cycle, both the transcript and protein levels of CcAdoMetS peaked at the G1 phase. L-ethionine was able to delay the cell cycle at the entry of S phase. A cell cycle delay at the exit of G2/M phase was induced by 5-azacytidine.ConclusionThe present study demonstrates a major role of AdoMet-mediated DNA methylation in the regulation of cell proliferation and that the CcAdoMetS gene is itself methylated.