The sense of naturally transcribed antisense RNAs in plants

Naturally occurring antisense transcripts are well documented in mammals and prokaryotes but little is known about their existence and effects in plants. Generally, antisense RNAs are believed to control gene expression negatively by annealing to the complementary sequences of the sense transcript. The resulting double-stranded RNAs are thought either to affect RNA stability, transcription and/or translation directly, or to generate a signal for gene silencing and defense against viruses

Composite Phaseolus vulgaris plants with transgenic roots as research tool

Large seeded grain legumes such as the common bean (Phaseolus vulgaris) and cowpea (Vigna unguiculata) are very important crops with seeds that are major protein source for people in developing countries, but their yields and improvement lag behind the economically more important cereals. For research purposes, genetic transformation is a powerful tool to obtain valuable information on gene expression and putative gene functions. In addition, through genetic transformation, candidate genes can be evaluated for their potential in agricultural biotechnology applications, such as resistance against biotic stresses. However, it remains difficult to stable genetically transform large seeded grain legumes such as Phaseolus and cowpea using Agrobacterium tumefaciens. In this paper a system is described to obtain so-called transgenic composite plants from P. vulgaris. These have a transgenic root system, obtained through Agrobacterium rhizogenes transformation of de-rooted seedlings. Their potentials for studies on important processes in the root system will be discussed

Light strongly promotes gene transfer from Agrobacterium tumefaciens to plant cells

Abstract Light conditions during Agrobacterium-based plant transformation, the most routinely used method in plant genetic engineering, differ widely and, to our knowledge, have not been studied systematically in relation to transformation efficiency. Here, light effects were examined in two already optimized transformation procedures: coculture of Agrobacterium tumefaciens with callus from two genotypes of the crop plant Phaseolus acutifolius (tepary bean) and coculture of root segments from two ecotypes of Arabidopsis thaliana. Except for the light conditions during coculture, all steps followed established procedures. Coculture was done either under continuous darkness, under a commonly used photoperiod of 16 h light/8 h darkness or under continuous light. b-glucuronidase (GUS) production due to the transient expression of an intron-containing uidA gene in the binary vector was used to evaluate T-DNA transfer. In all situations, uidA expression correlated highly and positively with the light period used during coculture; it was inhibited severely by darkness and enhanced more under continuous light than under a 16 h light/8 h dark photoperiod. The promotive effect of light was observed with Agrobacterium strains harboring either a nopaline-, an octopine-or an agropine/succinamopine-type nononcogenic helper Ti plasmid. The observed positive effect of light has obvious implications for developing and improving transient and stable transformation protocols, specifically those involving dark coculture conditions

Building academic and research partnerships for development using various funding schemes

Ghent University has a long tradition of university development cooperation (UDC) in various disciplines. The majority of these activities are funded by the Belgian Development Cooperation (DGD) through VLIR-UOS, the actor responsible on behalf of the Flemish universities for UDC. Other major funding agencies include the Flemish government and the European Commission through its so-called Framework programmes. This article illustrates a number of activities of academics forn Ghent University who have been successful in using different sources of funding to achieve both the academic goals of the Flemish academic partner and those of the UDC financer and southern partners. The goals of the latter are more focused on capacity building in education and research, development of the respective country and service to society, while the goals of the former aim primarily at scientific excellence

Plant genomics

AbstractThe rapidity with which genomic sequences of the model plant Arabidopsis thaliana and soon of rice are becoming available has strongly boosted plant molecular biology research. Here, two main genomic fields will be discussed: the progress in different structural genome projects, such as mapping, sequencing, genome organization and comparative genomics, and the so-called functional genomics approaches to analyze the genome using such molecular tools as transcript profiling, micro-arrays, and insertional mutagenesis. In addition a section on bioinformatics is included