A dominant negative effect of eth-1r, a mutant allele of the Neurospora crassa S-adenosylmethionine synthetase-encoding gene conferring resistance to the methionine toxic analogue ethionine

The combination of ultraviolet mutagenesis and PPX1 overexpression synergistically enhanced S-adenosyl-L-methionine synthesis in industrial Saccharomyces cerevisiae

S-adenosyl-L-methionine (SAM) is the only injectable drug among the hepatoprotective and choleretic drugs, which has remarkable efficacy and is favored by hepatopaths. The demand for SAM is constantly increasing in clinical settings. Therefore, many efforts have been made to increase SAM biosynthesis from L-methionine and ATP in Saccharomyces cerevisiae. This study aimed to construct a stable and high-accumulating SAM industrial strain through successive ultraviolet irradiation (UV) mutations coupled with three resistant (ethionine, nystatin, and cordycepin, respectively) screening procedures and metabolic engineering strategies. Following multiple UV mutagenesis, a higher production mutant strain ZJT15-33 was successfully obtained. In addition, the recombinant strain spe2△-PPX1 was derived from ZJT15-33 by deleting the SPE2 and overexpressing the PPX1, resulting in a 2.5-fold enhanced ATP accumulation, which promoted the synthesis of 2.41 g/L SAM in the shake-flask, representing an 11.4-fold enhancement over the original strain (0.21 g/L). Furthermore, 11.65 g/L SAM was accumulated with 113 mg/g DCW SAM content in a 5-L fermenter at 96 h, marking a 36.57 % increase compared to strain ZJT15-33 (8.53 g/L). These results indicated that UV mutagenesis combined with PPX1 overexpression could effectively improve SAM synthesis in S. cerevisiae, providing a feasible approach for developing highly SAM industrial production.

S-Adenosylmethionine Synthetase Is Required for Cell Growth, Maintenance of G0 Phase, and Termination of Quiescence in Fission Yeast

S-adenosylmethionine is an important compound, because it serves as the methyl donor in most methyl transfer reactions, including methylation of proteins, nucleic acids, and lipids. However, cellular defects in the genetic disruption of S-adenosylmethionine synthesis are not well understood. Here, we report the isolation and characterization of temperature-sensitive mutants of fission yeast S-adenosylmethionine synthetase (Sam1). Levels of S-adenosylmethionine and methylated histone H3 were greatly diminished in sam1 mutants. sam1 mutants stopped proliferating in vegetative culture and arrested specifically in G2 phase without cell elongation. Furthermore, sam1 mutants lost viability during nitrogen starvation-induced G0 phase quiescence. After release from the G0 state, sam1 mutants could neither increase in cell size nor re-initiate DNA replication in the rich medium. Sam1 is thus required for cell growth and proliferation, and maintenance of and exit from quiescence. sam1 mutants lead to broad cellular and drug response defects, as expected, since S. pombe contains more than 90 S-adenosylmethionine-dependent methyltransferases.

Comparison of Fusarium graminearum Transcriptomes on Living or Dead Wheat Differentiates Substrate-Responsive and Defense-Responsive Genes

Fusarium graminearum is an opportunistic pathogen of cereals where it causes severe yield losses and concomitant mycotoxin contamination of the grains. The pathogen has mixed biotrophic and necrotrophic (saprophytic) growth phases during infection and the regulatory networks associated with these phases have so far always been analyzed together. In this study we compared the transcriptomes of fungal cells infecting a living, actively defending plant representing the mixed live style (pathogenic growth on living flowering wheat heads) to the response of the fungus infecting identical, but dead plant tissues (cold-killed flowering wheat heads) representing strictly saprophytic conditions. We found that the living plant actively suppressed fungal growth and promoted much higher toxin production in comparison to the identical plant tissue without metabolism suggesting that molecules signaling secondary metabolite induction are not pre-existing or not stable in the plant in sufficient amounts before infection. Differential gene expression analysis was used to define gene sets responding to the active or the passive plant as main impact factor and driver for gene expression. We correlated our results to the published F. graminearum transcriptomes, proteomes, and secretomes and found that only a limited number of in planta- expressed genes require the living plant for induction but the majority uses simply the plant tissue as signal. Many secondary metabolite (SM) gene clusters show a heterogeneous expression pattern within the cluster indicating that different genetic or epigenetic signals govern the expression of individual genes within a physically linked cluster. Our bioinformatic approach also identified fungal genes which were actively repressed by signals derived from the active plant and may thus represent direct targets of the plant defense against the invading pathogen.

Random mutagenesis and recombination of sam1 gene by integrating error-prone PCR with staggered extension process

An efficient method for creating a DNA library is presented in which gene mutagenesis and recombination can be introduced by integrating error-prone PCR with a staggered extension process in one test tube. In this process, less than 15 cycles of error-prone PCR are used to introduce random mutations. After precipitated and washed with ethanol solution, the error-prone PCR product is directly used both as template and primers in the following staggered extension process to introduce DNA recombination. The method was validated by using adenosyl-methionine (AdoMet) synthetase gene, sam1, as a model. The full-length target DNA fragment was available after a single round. After being selected with a competitive inhibitor, ethionine, a mutated gene was obtained that increased AdoMet accumulation in vivo by 56%.

In vivo levels of S-adenosylmethionine modulate C:G to T:A mutations associated with repeat-induced point mutation in Neurospora crassa

In Neurospora crassa, the mutagenic process termed repeat-induced point mutation (RIP) inactivates duplicated DNA sequences during the sexual cycle by the introduction of C:G to T:A transition mutations. In this work, we have used a collection of N. crassa strains exhibiting a wide range of cellular levels of S-adenosylmethionine (AdoMet), the universal donor of methyl groups, to explore whether frequencies of RIP are dependent on the cellular levels of this metabolite. Mutant strains met-7 and eth-1 carry mutations in genes of the AdoMet pathway and have low levels of AdoMet. Wild type strains with high levels of AdoMet were constructed by introducing a chimeric transgene of the AdoMet synthetase (AdoMet-S) gene fused to the constitutive promoter trpC from Aspergillus nidulans. Crosses of these strains against tester duplications of the pan-2 and am genes showed that frequencies of RIP, as well as the total number of C:G to T:A transition mutations found in randomly selected am(RIP) alleles, are inversely correlated to the cellular level of AdoMet. These results indicate that AdoMet modulates the biochemical pathway leading to RIP.