Cuscuta reflexa invasion induces Ca release in its host.

Cuscuta reflexa induces a variety of reaction in its hosts. Some of these are visual reactions, and it is clear that these morphological changes are preceded by events at the molecular level, where signal transduction is one of the early processes. Calcium (Ca(2+)) release is the major second messenger during signal transduction, and we therefore studied Ca(2+) spiking in tomato during infection with C. reflexa. Bioluminescence in aequorin-expressing tomato was monitored for 48 h after the onset of Cuscuta infestation. Signals at the attachment sites were observed from 30 to 48 h. Treatment of aequorin-expressing tomato leaf disks with Cuscuta plant extracts suggested that the substance that induced Ca(2+) release from the host was closely linked to parasite haustoria.

Cell cycle activation by plant parasitic nematodes.

Sedentary nematodes are important pests of crop plants. They are biotrophic parasites that can induce the (re)differentiation of either differentiated or undifferentiated plant cells into specialized feeding cells. This (re)differentiation includes the reactivation of the cell cycle in specific plant cells finally resulting in a transfer cell-like feeding site. For growth and development the nematodes fully depend on these cells. The mechanisms underlying the ability of these nematodes to manipulate a plant for its own benefit are unknown. Nematode secretions are thought to play a key role both in plant penetration and feeding cell induction. Research on plant-nematode interactions is hampered by the minute size of cyst and root knot nematodes, their obligatory biotrophic nature and their relatively long life cycle. Recently, insights into cell cycle control in Arabidopsis thaliana in combination with reporter gene technologies showed the differential activation of cell cycle gene promoters upon infection with cyst or root knot nematodes. In this review, we integrate the current views of plant cell fate manipulation by these sedentary nematodes and made an inventory of possible links between cell cycle activation and local, nematode-induced changes in auxin levels.

Purification of cowpea mosaic virus RNA replication complex: Identification of a virus-encoded 110,000-dalton polypeptide responsible for RNA chain elongation.

An endogenous cowpea mosaic virus (CPMV) RNA-protein complex (CPMV replication complex) capable of elongating in vitro preexisting nascent chains to full-length viral RNAs has been solubilized from the membrane fraction of CPMV-infected cowpea leaves using Triton X-100 and purified by Sepharose 2B chromatography and glycerol gradient centrifugation in the presence of Triton X-100. Analysis of the polypeptide composition of the complex by NaDod-SO(4)/PAGE and silver staining revealed major polypeptides with molecular masses of 110, 68, and 57 kilodaltons (kDa), among which the 110-kDa polypeptide was consistently found to cosediment precisely with the RNA polymerase activity. Using antisera to specific viral proteins, we found the 110-kDa polypeptide to be the only known viral polypeptide associated with the RNA replication complex, the 68- and 57-kDa polypeptides being most probably host-specific. The host-encoded 130-kDa monomeric RNA-dependent RNA polymerase, which is known to be stimulated in CPMV-infected cowpea leaves, did not copurify with the virus-specific RNA polymerase complex. Our results dispute the hypothesis that plant viral RNA replication may be mediated by the RNA-dependent RNA polymerase of uninfected plants. We tentatively conclude that the 110-kDa polypeptide encoded by the bottom component RNA of CPMV constitutes the core of the CPMV RNA replication complex.