Heterologous expression of proteins from Plasmodium falciparum: results from 1000 genes.

As part of a structural genomics initiative, 1000 open reading frames from Plasmodium falciparum, the causative agent of the most deadly form of malaria, were tested in an E. coli protein expression system. Three hundred and thirty-seven of these targets were observed to express, although typically the protein was insoluble. Sixty-three of the targets provided soluble protein in yields ranging from 0.9 to 406.6 mg from one liter of rich media. Higher molecular weight, greater protein disorder (segmental analysis, SEG), more basic isoelectric point (pI), and a lack of homology to E. coli proteins were all highly and independently correlated with difficulties in expression. Surprisingly, codon usage and the percentage of adenosines and thymidines (%AT) did not appear to play a significant role. Of those proteins which expressed, high pI and a hypothetical annotation were both strongly and independently correlated with insolubility. The overwhelmingly important role of pI in both expression and solubility appears to be a surprising and fundamental issue in the heterologous expression of P. falciparum proteins in E. coli. Twelve targets which did not express in E. coli from the native gene sequence were codon-optimized through whole gene synthesis, resulting in the (insoluble) expression of three of these proteins. Seventeen targets which were expressed insolubly in E. coli were moved into a baculovirus/Sf-21 system, resulting in the soluble expression of one protein at a high level and six others at a low level. A variety of factors conspire to make the heterologous expression of P. falciparum proteins challenging, and these observations lay the groundwork for a rational approach to prioritizing and, ultimately, eliminating these impediments.

Post-transcriptional regulation of phenylalanine ammonia-lyase expression in tobacco following recovery from gene silencing.

Introduction of a bean phenylalanine ammonia-lyase (PAL) transgene into tobacco plants results in epigenetic post-transcriptional gene silencing which is unstable, such that after self-pollination first generation progeny may become PAL over-expressors. The change from gene silencing to PAL over-expression is accompanied by a loss of cytosine methylation of the PAL transgene and reduced methylation of the endogenous tobacco PAL2 gene, but not the PAL1 gene. These changes are associated with the appearance of high levels of bean PAL and tobacco PAL2 transcripts in the total RNA fraction from PAL over-expressing plants. However, tobacco PAL2 transcripts are inefficiently recruited into polysomes, and tobacco PAL2 protein is not detected in leaves of PAL over-expressing or wild-type lines. Thus, in spite of the post-transcriptionally controlled increase in tobacco PAL2 transcripts in PAL over-expressors, the increased PAL activity is primarily the result of the increase in bean PAL transcripts and corresponding enzymatic activity. These results reveal a complex cross-talk between expression of the PAL transgene and the corresponding endogenous PAL genes at the levels of transcription, transcript stability and polysomal recruitment during sense transgene-mediated silencing and subsequent over-expresson of PAL in tobacco.

Prospects for the metabolic engineering of bioactive flavonoids and related phenylpropanoid compounds.

The successful engineering of complex metabolic pathways will require, in addition to availability of cloned genes and promoters, knowledge of the regulatory mechanisms that control metabolic flux into the pathway including post-translational phenomena such as metabolite channeling. We are interested in modifying pathways for the synthesis of isoflavonoids and other bioactive phenylpropanoid compounds in transgenic plants. We describe studies on flux control utilizing transgenic tobacco plants that under- and over-express key biosynthetic enzymes, and outline experimental approaches for the molecular dissection of potential metabolic channels in the synthesis of antimicrobial flavonoid derivatives in alfalfa and other species.

Stress responses in alfalfa (Medicago sativa L). XXII. cDNA cloning and characterization of an elicitor-inducible isoflavone 7-O-methyltransferase.

Medicarpin, the major phytoalexin in alfalfa, is synthesized via the isoflavonoid branch of phenylpropanoid metabolism. The methyl group at the 9 position of medicarpin is generally accepted to arise via the methylation of the 4' position (B-ring) of daidzein. Surprisingly, the isoflavone-O-methyltransferase (IOMT), which is induced along with other enzymes involved in medicarpin biosynthesis, methylates the A-ring 7-hydroxyl group of daidzein in vitro, a reaction that probably does not occur in vivo. Utilizing internal amino acid sequence information from purified alfalfa IOMT, we have isolated three full-length IOMT cDNA clones. A search of the protein databases revealed sequence similarities to O-methyltransferases from various sources. The highest match (50.5% identity) was found between IOMT8 and 6a-hydroxymaackiain 3-O-methyltransferase from Pisum sativum. The molecular weight of alfalfa IOMT expressed in Escherichia coli was similar to that of purified IOMT from alfalfa cell cultures (41 kDa by SDS-PAGE). The recombinant enzyme catalyzed the O-methylation of A-ring hydroxyl group(s) of isoflavones, and could also methylate the pterocarpan (+) 6a-hydroxymaackiain. Alfalfa contains multiple IOMT genes, and closely related sequences are present in the genomes of chickpea and cowpea, species that also produce B-ring methylated isoflavonoids in vivo. Northern blot analysis indicated that IOMT transcripts are rapidly induced following elicitation, prior to the increase in IOMT activity and medicarpin accumulation. The possible role of the isoflavone 7-OMT in the synthesis of formononetin in vivo is discussed.