Composition, diversity and bioactivity of culturable bacterial endophytes in mountain-cultivated ginseng in Korea.

Plants harbor diverse communities of bacterial species in their internal compartments. Here we isolated and identified bacterial endophytes from mountain-cultivated ginseng (MCG, Panax ginseng Meyer) to make working collection of endophytes and exploit their potentially beneficial properties toward plants and human being. A total of 1,886 bacteria were isolated from root, stem and leaf of MCGs grown in 24 different sites across the nation, using culture-dependent approach. Sequencing of 16S rDNA allowed us to classify them into 252 distinct groups. Taxonomic binning of them resulted in 117 operational taxonomic units (OTUs). Analysis of diversity indices across sampling sites and tissues suggested that composition of bacterial endophyte community within ginseng could differ substantially from one site to the next as well as from one host compartment to another. Assessment of 252 bacterial isolates for their beneficial traits to host plants showed that some bacteria possesses the ability to promote plant growth and produce ß-glucosidase, indicating their potential roles in plant growth promotion and bio-transformation. Taken together, our work provides not only valuable resources for utilization of bacterial endophytes in ginseng but also insights into bacterial communities inside a plant of medicinal importance.

Construction and expression of a dual vector for chemo-enzymatic synthesis of plant indole alkaloids in Escherichia coli.

A dual vector (pQE-70-STR1-SG) containing coding regions of strictosidine synthase (STR1, EC 4.3.3.2) and strictosidine glucosidase (SG, EC 3.2.1.105) from the Indian medicinal plant Rauvolfia serpentina was constructed. Functional expression of the vector in Escherichia coli cells (M15 strain) was proven by isolation of prepurified enzyme extracts, which show both STR1 and SG activities. Incubation of the enzyme in the presence of tryptamine and secologanin delivered the indole alkaloid cathenamine, demonstrating functional co-expression of both STR1- and SG-cDNAs. Cathenamine reduction by sodium borohydride leading to tetrahydroalstonine revealed the chemo-enzymatic indole alkaloid synthesis.

Biotransformation of tryptamine and secologanin into plant terpenoid indole alkaloids by transgenic yeast.

A transgenic Saccharomyces cerevisiae was constructed containing the cDNAs coding for strictosidine synthase (STR) and strictosidine beta-glucosidase (SGD) from the medicinal plant Catharanthus roseus. Both enzymes are involved in the biosynthesis of terpenoid indole alkaloids. The yeast culture was found to express high levels of both enzymes. STR activity was found both inside the cells (13.2 nkatal/g fresh weight) and in the medium (up to 25 nkatal/l medium), whereas SGD activity was present only inside the yeast cells (2.5 mkatal/g fresh weight). Upon feeding of tryptamine and secologanin, this transgenic yeast culture produced high levels of strictosidine in the medium; levels up to 2 g/l were measured. Inside the yeast cells strictosidine was also detected, although in much lower amounts (0.2 mg/g cells). This was due to the low permeability of the cells towards the substrates, secologanin and tryptamine. However, the strictosidine present in the medium was completely hydrolyzed to cathenamine, after permeabilizing the yeast cells. Furthermore, transgenic S. cerevisiae was able to grow on an extract of Symphoricarpus albus berries serving as a source for secologanin and carbohydrates. Under these conditions, the addition of tryptamine was sufficient for the transgenic yeast culture to produce indole alkaloids. Our results show that transgenic yeast cultures are an interesting alternative for the production of plant alkaloids.

Cloning and functional expression in Escherichia coli of a cDNA encoding cardenolide 16'-O-glucohydrolase from Digitalis lanata Ehrh.

A clone of cardenolide 16'-O-glucohydrolase cDNA (CGH I) was obtained from Digitalis lanata which encodes a protein of 642 amino acids (calculated molecular mass 73.2 kDa). The amino acid sequence derived from CGH I showed high homology to a widely distributed family of beta-glucohydrolases (glycosyl hydrolases family 1). The recombinant CGH I protein produced in Escherichia coli had CGH I activity. CGH I mRNA was detected in leaves, flowers, stems and fruits of D. lanata.

Autohydrolysis of plant polysaccharides using transgenic hyperthermophilic enzymes.

Commercial bioprocessing of plant carbohydrates, such as starch or cellulose, necessitates the use of commodity enzyme additives to accelerate polysaccharide hydrolysis. To simplify this procedure, transgenic plant tissues constitutively producing commodity enzymes were examined as a strategy for accelerating carbohydrate bioprocessing. Hyperthermophilic glycosyl hydrolases were selected to circumvent enzyme toxicity, because such enzymes are inactive at plant growth temperatures and are therefore physiologically benign. Transgenic tobacco lines were established that produced either a hyperthermophilic alpha-glucosidase or a beta-glycosidase using genes derived from the archaeon Sulfolobus solfataricus. Western blot and immunoprecipitation analyses were used to demonstrate the presence of recombinant enzymes in plant tissues. Transgenic enzyme levels exhibited an unusual delayed pattern of accumulation while their activities survived plant tissue preservation. Transgenic plant protein extracts released glucose from purified polysaccharide substrates at appreciable rates during incubation in high-temperature reactions. Glucose was also produced following enzymatic treatment of plant extracts enriched for endogenous polysaccharides. Direct conversion of plant tissue into free sugar was evident using whole plant extracts of either transgenic line, and could be significantly accelerated in a synergistic manner by combining transgenic line extracts.