Wild Brassica plants release seeds by a pod shattering mechanism; in related crop plants, such as oil‐seed rape, this can result in substantial loss of seed, and hence loss of revenue, and also in the distribution of seeds which can contaminate future crops and the environment. To identify strategies which may be used to reduce shatter, either by conventional breeding programmes or by genetic engineering, we have examined fruit development in oil‐seed rape (Brassica napus), and in the related B. juncea and Arabidopsis, using a combination of cytological, cytochemical and molecular techniques. We report here on the patterns of cellular differentiation and tissue development during fruit maturation, and suggest how this results in the shattering phenotype.
The green fluorescent protein (GFP) was targeted to the endoplasmic reticulum (ER) of living plant cells using a virus‐based expression system. The signal peptide from the storage protein, patatin was fused to the amino‐terminus of the GFP while the ER retention signal KDEL was fused to the carboxy‐terminus. The chimaeric gfp cDNA was inserted into a potato virus X‐based expression vector and in‐vitro transcripts, representing the recombinant viral genome, were inoculated on to Nicotiana benthamiana and N. clevelandii plants. In virus‐infected cells, the GFP was targeted both to the cortical ER and to a mobile system of ER elements which underwent streaming in the cytoplasm. In addition, a population of GFP‐containing inclusions was apparent. These inclusions were motile but remained closely associated with elements of the ER. Staining of the ER with membrane potential‐sensitive dyes confirmed that the GFP had been targeted to the ER. The utility of virus‐mediated delivery systems in studies of the plant endomembrane system is discussed.
Malaria is a responsible for approximately 600 thousand deaths worldwide every year. Appropriate and timely treatment of malaria can prevent deaths but is dependent on accurate and rapid diagnosis of the infection. Currently, microscopic examination of the Giemsa stained blood smears is the method of choice for diagnosing malaria. Although it has limited sensitivity and specificity in field conditions, it still remains the gold standard for the diagnosis of malaria. Here, we report the development of a fluorescence in situ hybridization (FISH) based method for detecting malaria infection in blood smears and describe the use of an LED light source that makes the method suitable for use in resource-limited malaria endemic countries. The Plasmodium Genus (P-Genus) FISH assay has a Plasmodium genus specific probe that detects all five species of Plasmodium known to cause the disease in humans. The P. falciparum (PF) FISH assay and P. vivax (PV) FISH assay detect and differentiate between P. falciparum and P. vivax respectively from other Plasmodium species. The FISH assays are more sensitive than Giemsa. The sensitivities of P-Genus, PF and PV FISH assays were found to be 98.2%, 94.5% and 98.3%, respectively compared to 89.9%, 83.3% and 87.9% for the detection of Plasmodium, P. falciparum and P. vivax by Giemsa staining respectively.
The characterization of the promoter of a wheat (Triticum aestivum) cv. Cheyenne high molecular weight glutenin subunit (HMW subunit) gene, Glu-1D-1 is reported. The nucleotide sequence of the promoter from position -1191 to -650 with respect to the transcription start site was determined, to add to that already determined. Analysis of this region of the promoter revealed the presence of an additional copy of part of the primary enhancer sequence and sequences related to regulatory elements present in other wheat seed protein genes. A chimaeric gene was constructed comprising the 5' flanking region of the Glu-1D-1 gene from position -1191 to +58, the coding region of the UID:A (Gus) gene, and the nopaline synthase (Nos) gene terminator. This chimaeric gene was introduced into wheat (Triticum durum cv. Ofanto) by particle bombardment of inflorescence explants. Two independent transgenic lines were produced, and both showed expression of the Gus gene specifically in the endosperm during mid-development (first detected 10-12 d after anthesis). Histochemical analysis of homozygous T(2) seed confirmed this pattern of expression, and showed that expression was initiated first in the central lobes of the starchy endosperm, and then spread throughout the endosperm tissue, while no expression was detected in the aleurone layer. Native HMW subunit protein was detectable by Western analysis 12-14 d after anthesis, consistent with concurrent onset of activity of the native and introduced HMW subunit gene promoters.
A survey of the morphological characters of 36 clonal axenic strains of Arthrospira showed that 34 had helical and 2 had straight trichomes. Of those with helical trichomes, five were right‐handed and 29 left‐handed. After repeated subculture for 1 year, the orientation of one helical strain (D893) had changed from right‐ to left‐handed, suggesting a probable genetic shift. The influence of environmental factors on helix orientation was tested on a subset of 10 strains. A temperature upshift from 30 to 32–34° C for 7 days led to a change in orientation in three strains (D918/H, D923, D925). Incubation at 32° C (D918/H, D923) or 34° C (D925) for periods less than needed for the morphological change to show still permitted the change to take place subsequently, when the temperature was reduced to 30° C; however, further subculture at 30° C led to the orientation reverting to its original state. In strain D925, but not the other nine strains, continuous shaking at 30° C also led to a change in helix orientation. In this case, some trichomes showed both orientations in a single trichome, with a snag at the point of reversion. A repeat survey of the stock cultures of all 34 strains after 2 years showed that another strain (D918/H) had now changed orientation from right‐handed to left‐handed. These observations are compared with the behavior of other helical structures in the literature, including filamentous Bacillus subtilis mutants and helix reversal in tendrils of climbing plants.
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