Plant virus inhibitors from marine algae

Methanolic extracts from 30 species of marine algae were assayed for antiviral activity against Potato virus X (PVX) in local lesion assays, using Chenopodium quinoa L. as host. Extracts from six algal species (Fucus gardneri Silva, Alaria marginata Postels & Ruprecht, Ralfsia sp. (Berkeley), Codium fragile (Suringar) Hariot, Fragilaria oceanica Cleve, and Egregia menziesii (Turner) J.E. Areschoug) inhibited PVX infectivity by more than 80%. Most extracts with antiviral activity came from algae that belong to the phylum Heterokontophyta. Fractionation of a crude extract from F. gardneri resulted in identification of the polysaccharide alginate as an antiviral component. Alginate inhibited PVX infectivity by 95%, and the mode of action may be via aggregation of virus particles. The present study is the first to investigate New World algae for compounds with activity against plant viruses and the first report that extracts of F. gardneri, Ralfsia sp., and Fragilaria oceanica are sources of antiviral activity.Key words: marine algae, plant viruses, antiviral activity, alginate, polysaccharides, Fucus gardneri.

First Report of Pepino mosaic virus in Canada and the United States

During the winter of 2000, tomatoes (Lycopersicon esculentum) with a bright yellow leaf mosaic were observed in a commercial greenhouse in southern Ontario, Canada. Examination of leaf extracts, using leaf dips and immunosorbent absorption electron microscopy (ISEM), showed flexuous rods consistent with the potexvirus group. Polyclonal antibodies raised against the original Peruvian Pepino mosaic virus (PepMV) isolate (1) and commercial antibodies obtained from Deutsche Sammlung von Mikro-organismen und Zellkulturen (DSMZ), GmbH, Braunsweig, Germany, and Plant Research International (PRI), Wageningen, the Netherlands, were used in ISEM. Leaves tested positive in double-antibody sandwich-enzyme-linked immunosorbent assay (ELISA) with antibodies from DSMZ and PRI. A triple-antibody sandwich-ELISA obtained from Adgen Ltd. (Nellies Gate, UK) gave similar results. Potato virus X did not react with PepMV antiserum in ELISA. Positive PepMV ELISA controls were a U.K. and a Dutch isolate supplied by R. Mumford and R. A. A. van Vlugt, respectively, and DSMZ. Using primers generated from a sequence of the RNA polymerase region of a U.K. PepMV isolate (R. Mumford, unpublished data), a reverse transcription-polymerase chain reaction test showed the expected 312-bp amplicon for the Canadian, Dutch, and U.K. isolates. The primer sequences used were forward 5' CTA TTA CAA CTC CGG AAG CCA 3' and reverse 5' TGG TCT GGC CAG GCT TTG AC 3'. The three isolates were maintained in tomato cv. Bush Beefsteak. When mechanically inoculated on L. esculentum cv. Rapsodie, the Canadian isolate caused a bright yellow mosaic in 1 to 2 weeks, while the two European isolates caused a faint yellow mosaic and mild puckering of the leaves. When mechanically inoculated on 17 indicator plants, the Canadian isolate had a host range similar to the U.K. isolate. The most striking difference in symptoms occurred in L. pimpinellifolium, in which the Canadian isolate caused a yellow mosaic, the Dutch isolate caused no symptoms, and the U.K. isolate caused a marked puckering of the leaves, suggesting virus strain differences among the isolates. Tomato fruits originating from the United States were collected during border inspections by the Canadian Food Inspection Agency and tested for PepMV by ELISA with antisera from DSMZ. PepMV was not detected in 7 samples from California, but was detected in 6 of 12 samples from Colorado, 6 of 7 samples from Arizona, and 1 of 5 samples from Texas. PepMV was originally isolated from pepino (Solanum muricatum) in Peru in 1980 (1) and subsequently from tomato in the Netherlands in 1999 (2). To our knowledge, this is the first report of PepMV in North America. References: (1) R. Jones et al. Ann. Appl. Biol. 94:61, 1980. (2) R. A. A. van Vlugt et al. Plant Dis. 84:103, 2000.

The purification of 3 beta-hydroxysteroid sulfotransferase of the hamster epididymis

The purification of a hydroxysteroid sulfotransferase from the cytosolic fraction of the hamster epididymis is described using ammonium sulfate precipitation, gel filtration and PAP agarose affinity chromatography. A purification of 360-fold was achieved and resulted in the isolation of one major protein as evidenced by HPLC and SDS gel-electrophoresis. The "native" enzyme is a dimer of mol. wt 106,000 and is composed of subunits having the same molecular weight.

The assay and partial characterization of 3 beta-hydroxysteroid sulfotransferase of the hamster epididymis

Using a partially purified enzyme preparation obtained from hamster epididymis, a simple assay has been developed to measure the sulfurylation of dehydroisoandrosterone (DHA) and desmosterol in the presence of 3'-phosphoadenosine 5'-phospho[35S]sulfate [( 35S]PAPS). After stopping the enzymatic reaction with methanol and KCl, the 35S-labelled steroid sulfates are readily extracted into an organic phase. Optimal conditions for the sulfurylation of the two steroids were compared; optimum pH is 8.7 for DHA and 9.8 for desmosterol. Sulfoconjugation of desmosterol increases with magnesium concentrations up to 6 mM, while 40 mM concentrations of the divalent ion are required for the optimal sulfurylation of DHA. Maximum sulfurylation of these steroids requires the presence of 15 mM cysteine. Michaelis-Menten kinetics are observed with DHA which has an apparent Km of 32 microM, while desmosterol inhibits sulfotransferase activity at high concentrations. Saturation of the enzyme with PAPS results in an allosteric behaviour. Only the 3 beta-hydroxyl function of the steroid nucleus appears to be an appropriate sulfate acceptor for the epididymal hydroxysteroid sulfotransferase.

Distribution of steroid sulfotransferase in the male hamster reproductive tract

Steroid sulfotransferase activity has been assayed in cytosol extracts obtained from the male hamster reproductive tract. Dehydroisoandrosterone and desmosterol were used as substrates in the presence of phosphoadenosine phosphosulfate-35S as sulfate donor. No significant sulfotransferase activity was found in the testis. In the epididymis, a severalfold increase in activity was found in the tissue from the caput to the caudal regions. A lower but significant activity was detected in the vas deferens. The enzyme appears to be secreted into the luminal fluid while little activity is associated with the spermatozoa. This increase in activity along the epididymis is undoubtedly responsible for the accumulation of sterol sulfates reported previously. In view of the fact that sterol sulfates are potent and specific inhibitors of acrosin, as reported for the porcine and confirmed herein for hamster acrosin, the epididymal production of steroid and sterol sulfates may represent a protective mechanism against the premature release of proteolytic activity within the male reproductive tract.

Steroid sulfotransferase in hamster epididymis

Steroid sulfotransferase activity is present in the cytosol fraction of hamster epididymis. The activity of this enzyme is increased by magnesium ion. Cysteine is essential to assure optimal activity. Adenosine-3'-phosphate-5'-phosphosulfate is required as sulfate donor and an apparent Km of 62 microM was calculated. Inhibition studies suggest that this enzyme preferentially catalyzes the sulfurylation of the 3 beta-hydroxyl group of delta 5-steroids. An unusual feature of the enzyme is a pH optimum at pH 10.