Kiyoon Kang

Enhanced production of melatonin by ectopic overexpression of human serotonin N‐acetyltransferase plays a role in cold resistance in transgenic rice seedlings

Abstract:  Serotonin N‐acetyltransferase (SNA), a rate‐limiting enzyme in melatonin biosynthesis in vertebrates, is responsible for the production of N‐acetylserotonin; this molecule is then converted to melatonin by hydroxyindole‐O‐methyltransferase. We generated transgenic rice plants via expression of the human SNA gene under the constitutive ubiquitin promoter using Agrobacterium‐mediated gene transformation. We investigated the role of SNA in the biosynthesis of melatonin and the physiological role of melatonin in rice plants. The integration and expression of the transgene were confirmed in T1 transgenic rice seedlings by Southern, Northern, and RT‐PCR analyses. High SNA‐specific enzyme activities were observed in the transgenic rice plants, whereas the wild type revealed a trace level of SNA enzyme activity. The functional expression of SNA protein was closely associated with the elevated synthesis of N‐acetylserotonin and melatonin in the transgenic rice plants. Experiments using both exogenous treatment of serotonin and senescent detached leaves, which contain a pool of serotonin, significantly enhanced melatonin biosynthesis, indicating that endogenous serotonin levels play a bottleneck role in the pathway of melatonin biosynthesis. Finally, the transgenic rice seedlings with high levels of melatonin showed elevated chlorophyll synthesis during cold stress, suggesting a role for melatonin in cold‐stress resistance.

Characterization of tryptamine 5-hydroxylase and serotonin synthesis in rice plants

Serotonin is a well-known pineal hormone that in mammals plays a key role in mood. In plants, serotonin is implicated in several physiological roles such as flowering, morphogenesis, and adaptation to environmental changes. However, its biosynthetic enzyme in plants has not been characterized. Therefore, we measured the serotonin content and enzyme activity responsible for serotonin biosynthesis in rice seedlings. Tryptamine 5-hydroxylase (T5H), which converts tryptamine into serotonin, was found as a soluble enzyme that had maximal activity in the roots. The maximal activity of T5H was closely associated with the enriched synthesis of serotonin in roots. Tetrahydropterine-dependent T5H activity was inhibited by tyramine, tryptophan, 5-OH-tryptophan, and octopamine, but remained unaltered by dopamine in vitro. The tissues of rice seedlings grown in the presence of tryptamine exhibited a dose-dependent increase in serotonin in parallel with enhanced T5H enzyme activity. However, no significant increase in serotonin was observed in rice tissues grown in the presence of tryptophan, suggesting that tryptamine is a bottleneck intermediate substrate for serotonin synthesis.

Molecular cloning of a plant N-acetylserotonin methyltransferase and its expression characteristics in rice.

Abstract:  N‐acetylserotonin methyltransferase (ASMT), the last enzyme in the synthesis of melatonin, catalyzes N‐acetylserotonin into melatonin. For the first time, we cloned ASMT from rice through the analysis of recombinant Escherichia coli harboring putative rice O‐methyltransferase (OMT) cDNAs. In total, 18 full‐length cDNAs, which show homology to wheat caffeic acid 3‐O‐methyltransferase, were expressed in E. coli and induced in the presence of N‐acetylserotonin; we then analyzed the production of melatonin. Only recombinant E. coli line 15 showed melatonin synthesis; no other recombinant lines produced melatonin with the addition of N‐acetylserotonin in E. coli culture. Line 15 clearly exhibited in vitro ASMT enzyme activity with 0.27 pkat/mg protein. ASMT enzyme activity was inhibited by various related compounds such as N‐acetyltryptamine and N‐acetyltyrosine. The open reading frame of ASMT consists of 364 amino acids possessing well‐conserved motifs found in plant OMT such as S‐adenosyl‐L‐methionine–binding and catalytic sites. Induction patterns of ASMT mRNA were well matched with the production of melatonin in rice leaves during senescence, as well as several stressors.

Biosynthesis and biotechnological production of serotonin derivatives

Serotonin derivatives belong to a class of phenylpropanoid amides found at low levels in a wide range of plant species. Representative serotonin derivatives include feruloylserotonin (FS) and 4-coumaroylserotonin (CS). Since the first identification of serotonin derivatives in safflower seeds, their occurrence, biological significance, and pharmacological properties have been reported. Recently, serotonin N-hydroxycinnamoyl transferase (SHT), which is responsible for the synthesis of serotonin derivatives, was cloned from pepper (Capsicum annuum) and characterized in terms of its enzyme kinetics. Using the SHT gene, many attempts have been made to either increase the level of serotonin derivatives in transgenic plants or produce serotonin derivatives de novo in microbes by dual expression of key genes such as SHT and 4-coumarate-CoA ligase (4CL). Due to the strong antioxidant activity and other therapeutic properties of serotonin derivatives, these compounds may have high potential in treatment and prophylaxis, as cosmetic ingredients, and as major components of functional foods or feeds that have health-improving effects. This review examines the biosynthesis of serotonin derivatives, corresponding enzymes, heterologous production in plants or microbes, and their applications.

Induction of serotonin biosynthesis is uncoupled from the coordinated induction of tryptophan biosynthesis in pepper fruits {Capsicum annuum) upon pathogen infection

It has been suggested that serotonin biosynthesis is regulated by tryptophan decarboxylase (TDC) in plants. To determine if TDC plays a rate-limiting role in serotonin biosynthesis, two TDC genes, PepTDC1 and PepTDC2, were cloned from pepper (Capsicum annuum L.) fruits infected with anthracnose fungus and their expression was then examined in various organs, including fruit that had been treated with the fungus or various chemicals. PepTDC1 expression was highly induced in pepper fruits after treatment with fungus and ethylene, while PepTDC2 was constitutively expressed at low levels in all pepper tissues. Additionally, predominant induction of PepTDC1 mRNA and TDC enzyme activity was detected in the unripe-green fruit, but not in the ripe-red fruit upon pathogen infection. Higher expression of TDC in unripe-green fruit was closely associated with increased levels of tryptamine, serotonin, and serotonin derivatives. However, unlike the enhanced serotonin synthesis, tryptophan levels responded unchanged when challenged with the pathogen in both the unripe-green fruit and the ripe-red fruit. Expression of two key tryptophan biosynthetic genes, anthranilate synthase (ASα) and tryptophan synthase (TSβ), remained unchanged in response to treatment. Also, anthranilate synthase enzyme activity remained steady regardless of pathogen infection. Taken together, these results suggest that the synthesis of serotonin was regulated by the induction of TDC without a simultaneous increase in tryptophan levels in pepper fruits.

Methanol is an endogenous elicitor molecule for the synthesis of tryptophan and tryptophan‐derived secondary metabolites upon senescence of detached rice leaves

During senescence of detached rice leaves, tryptophan (Trp) and Trp-derived secondary metabolites such as serotonin and 4-coumaroylserotonin accumulated in concert with methanol (MeOH) production. This senescence-induced MeOH induction was closely associated with levels of pectin methylesterase (PME)1 mRNA and PME enzyme activity. Exogenous challenge of detached rice leaves with 1% MeOH accelerated Trp and serotonin biosynthesis with induction of the corresponding genes. No other solvents, including ethanol, resulted in a Trp-inducing effect. This MeOH-induced Trp synthesis was positively regulated by abscisic acid but negatively regulated by cytokinin, suggesting hormonal involvement in the action of MeOH. Endogenous overproduction or suppression of MeOH either by PME1 overexpression or RNA interference (RNAi) gene silencing revealed that PME1 overexpressing lines produced twofold higher Trp levels with elevated Trp biosynthetic gene expression, whereas RNAi lines showed twofold reduction in Trp level in healthy control rice leaves, suggesting that MeOH acts as an endogenous elicitor to enhance Trp biosynthesis. Among many transcription factors induced following MeOH treatment, the WRKY family showed significant induction patterns, of which WRKY14 appeared to play a key regulatory role in MeOH-induced Trp and Trp-derived secondary metabolite biosynthesis.

Conversion of 5-Hydroxytryptophan into Serotonin by Tryptophan Decarboxylase in Plants, Escherichia coli, and Yeast

The L-tryptophan decarboxylase (TDC) gene of rice was heterologously expressed in various organisms. Transgenic rice overexpressing TDC showed accumulation of serotonin upon 5-hydroxytryptophan treatment, which was consistent with the in vitro 5-hydroxytryptophan decarboxylase enzyme activity of purified recombinant rice TDC in a pyridoxal phosphate-dependent manner. Recombinant yeast harboring TDC produced serotonin at the expense of the endogenous 5-hydroxytryptophan levels.

Production of phenylpropanoid amides in recombinant Escherichia coli.

Plant-specific phenylpropanoid amides were produced in a recombinant Escherichia coli that expressed 4-coumarate:coenzyme A ligase from Arabidopsis and serotonin N-hydroxycinnamoyltransferase from pepper plants. Upon exogenous treatment with several precursors, high concentrations of the following phenylpropanoid amides were produced abundantly in the culture medium in a few hours: 4-coumaroylserotonin (215 mg/l), 4-coumaroyloctopamine (208 mg/l), and 4-coumaroyltyramine (187 mg/l).

Tyramine accumulation in rice cells caused a dwarf phenotype via reduced cell division

Transgenic rice plants overexpressing a rice tyrosine decarboxylase (TyDC) exhibited a dwarf phenotype with a high level of tyramine accumulation. The height of transgenic rice was reduced on average to 35% of the wild-type height, whereas the number of tillers increased to 190% that of wild type. When judged by cellular distribution of tyramine and tyramine derivatives, the level of tyramine in soluble and insoluble fractions was higher than that of tyramine derivatives such as 4-coumaroyltyramine (CT) in the transgenic rice plants, suggesting that tyramine rather than its derivatives was a causative compound triggering the dwarf phenotype. Microscopic observation revealed that cell size in the transgenic lines was maintained, with a slightly irregular arrangement in the leaf mesophyll cells. When wild-type rice seeds were grown in the presence of tyramine, rice seedlings also showed stunted phenotypes in a dose-dependent manner. When these stunted seedlings were employed to measure the degree of cellular proliferation by bromodeoxyuridine incorporation, only small numbers of cells were found to retain labeled nuclei in shoot tips compared with the untreated control. These results show that the dwarf phenotype associated with tyramine accumulation in transgenic rice plants is attributable to a reduction in cell number rather than cell size. In addition, our dwarf phenotype caused by tyramine was not closely associated with known dwarf genes such as D88.

Endosperm-Specific Expression of Serotonin N-Hydroxycinnamoyltransferase in Rice

Serotonin N-hydroxycinnamoyltransferase (SHT) is a key enzyme in the synthesis of feruloylserotonin (FS) and 4-coumaroylserotonin (CS). These serotonin derivatives show strong antioxidant activity, making them valuable for both nutritional and pharmacological use in humans. Ectopic expression of SHT under the control of the endosperm specific-glutelin and prolamin promoters from rice was produced via Agrobacterium-mediated transformation. SHT expression was confirmed by Southern blot analysis, followed by Northern blotting and SHT enzyme activity analyses using total RNA and protein, respectively, extracted from transgenic seeds. The glutelin A3 (GluA3) promoter produced low SHT mRNA expression in rice seeds, whereas the prolamin promoter expressed high levels of SHT mRNA. In spite of the ectopic expression of SHT in rice seeds, both transgenic genotypes accumulated levels of serotonin derivatives similar to those found in wild-type rice. Furthermore, our data suggest that serotonin, rather than phenylpropanid-CoAs, is the rate-limiting substrate in the biosynthesis of serotonin derivatives in SHT-overexpressing transgenic rice seeds.