Bioherbicidal ability and weed management of allelopathic methyl esters from Lantana camara

Allelochemicals are secondary metabolites which are not edible and can be used as growth regulators and bio-herbicides. The goal of current study was to assess allelopathic ability of Lantana camara (Sage-plant) flowers against weeds viz. Avena fatua (Wild oat), Euphorbia helioscopia (Sun-spurge), Chenopodium album (Goosefoot), Phalaris minor (Canary-grass), and Rumex dentatus (Knotweed). Bioassay analysis of three methanolic fractions of the Combiflash from L. camara was performed at 50%, 75% and 100% concentration using germination percentage parameters, inhibition of plumule and radicle size. The fraction II of Combiflash strongly suppressed all weeds with negligible effect on T. aestivum. Gas chromatography-mass spectroscopy was conducted for the fraction, and isolated compounds were used to perform bioassays. From fraction II GC–MS detected four methyl esters of allelopathic fatty acid viz. Methyl oleate, methyl palmitate, methyl stearate and methyl linoleate. The evaluation of physiological effects of the bioassay revealed substantial suppression of chlorophyll, antioxidant enzymes (superoxide, dismutase peroxidase) and protein material in all weeds by methyl palmitate. Bioassay activity and study of physiological parameters revealed that the effective bio-herbicidal compound in Lantana camara flowers is methyl palmitate. This is the first time that methyl palmitate (a fatty acid methyl ester) has been related to herbicidal activity in L. camara flowers. It is proposed that field studies based on hormesis research and the mechanism of action of this compound be carried out.     

Cryopreservation of dog semen: the effects of Equex STM paste on plasma membrane fluidity and the control of intracellular free calcium

Understanding cryoinjury of dog spermatozoa is crucial to preserving fertilizing ability. This study examined flow cytometric indicators of sperm function to explore the reported benefits of Equex STM paste. The motility of cryopreserved spermatozoa immediately and 1h after thawing was higher in the extender containing 0.5% Equex; no significant differences between the two extenders were observed regarding viability, acrosomal integrity and intracellular Ca(2+) concentration. The proportion of spermatozoa having high membrane fluidity increased significantly post-thawing. The interaction between time after thawing and treatment was significant for plasma membrane fluidity. Dilution in a commercial diluent for transport before processing caused a significant increase in intracellular Ca(2+), which may affect functional survival. No significant difference with or without Equex was detected in plasma membrane fluidity. However, a significant interaction between Equex and dogs was detected. A significant decrease in intracellular Ca(2+) was detected in the live cell population both after dilution in Andersen's buffer and again after cooling and equilibration. One hour post-thaw, the proportion of live spermatozoa with high calcium concentration increased to a similar proportion as that seen in diluted semen; the interaction between diluent and dog was significant. The results suggest that Equex in the diluent benefited motility after cryopreservation. Live spermatozoa with high intracellular Ca(2+) after cryopreservation seem to have a favoured survival in the first hour after thawing. Nevertheless, survival after cryopreservation was severely compromised, explaining the relatively poor fertility of cryopreserved dog semen.     

UV radiation reduces epidermal cell expansion in Arabidopsis thaliana leaves without altering cellular microtubule organization

Upon chronic UV treatment pavement cell expansion in Arabidopsis leaves is reduced, implying alterations in symplastic and apoplastic properties of the epidermal cells. In this study, the effect of UV radiation on microtubule patterning is analysed, as microtubules are thought to serve as guiding rails for the cellulose synthase complexes depositing cellulose microfibrils. Together with hemicelluloses, these microfibrils are regarded as the load-bearing components of the cell wall. Leaves of transgenic plants with fluorescently tagged microtubules (GFP-TUA6) were as responsive to UV as wild type plants. Despite the UV-induced reduction in cell elongation, confocal microscopy revealed that cellular microtubule arrangements were seemingly not affected by the UV treatments. This indicates an unaltered deposition of cellulose microfibrils in the presence of UV radiation. Therefore, we surmise that the reduction in cell expansion in UV-treated leaves is most probably due to changes in cell wall loosening and/or turgor pressure.Key words: arabidopsis, cell expansion, GFP-TUA6, leaf development, microtubule cytoskeleton, UV radiationPhotosynthetic functions such as solar light capture and carbon fixation are highly evolved features of plant leaves. To fulfil these functions in an optimal way, leaf development needs to be tuned to environmental conditions. Leaves are continuously exposed and subjected to environmental influences, which serve as co-regulators of leaf and plant development.¹ This ability of plants to adapt, secures the plant''s survival, even under non-optimal conditions. An example of a regulatory environmental parameter is solar light, indispensable for photosynthesis but potentially causing photoinhibition and/or UV-radiation stress. The highly energetic ultraviolet B (UV-B) rays of short wavelengths (280–315 nm) can both cause damage, as well as induce a range of specific metabolic and morphogenic plant responses. It was reported before that exposure to low dose UV radiation reduces Arabidopsis leaf size due to a decreased cell size.² Expansion of leaf epidermal cells of Arabidopsis thaliana is the combined action of promotion and restriction of growth, resulting in the typical irregular sinuous pavement cells. It has been postulated that cellulose microfibrils are responsible for generating a force opposing isotropic expansion by creating neck regions in between outgrowing lobes.³ As the microtubule cytoskeleton is believed to serve as guiding rails for the cellulose synthase complexes (CESAs),⁴ the deposition of the cellulose fibrils is intimately linked to the cortical microtubule arrangement. We have studied the UV-effect on microtubule organisation in leaf epidermal cells whose expansion had decreased upon this UV radiation. Microtubules in the adaxial pavement cells of the fourth leaf were monitored on several successive days in a transgenic line containing GFP fused to tubulin A6.⁵ The chronic UV treatment was started on day 0 when the plants were 2 weeks old, using UV exposure conditions as described in reference ². First the responsiveness of the GFP-TUA6 plants to UV radiation was evaluated. Similar to wild type (WT) plants,² the GFP-TUA6 plants had smaller leaves following 8 days of UV treatment (t-test, p < 0.01) (Fig. 1). This was caused by a significant reduction in the generalized cell area average of all measured cells, irrespective of the location within the leaf (Fig. 1; t-test, p < 0.01). In more detail, the average cell area within the base, middle and top zones of the GFP-TUA6 leaf was systematically lower in UV-treated leaves from 8 days after the treatment started onwards (data not shown).Open in a separate windowFigure 1Effect of UV radiation on leaf and cell area after different days of UV radiation. Open asterisks indicate a statistically significant difference in leaf area between UV-treated and control plants, black asterisks indicate statistically significant difference in cell area (t-test, *p < 0.05, **p < 0.01, ***p < 0.001). Error bars indicate the standard error for five different leaves at all measured time-points and 600, 170 and 180 cells at day 0, 8 and 12 respectively.As GFP-TUA6 leaves were as responsive to UV radiation as wild type leaves, confocal microscopy was used to visualize the organisation of the cortical microtubules facing the outer periclinal wall of the adaxial epidermis. No clear difference in microtubule (re)organization could be detected during the development of pavement cells, and throughout the UV treatment period. As shown in Figure 2 at day 2, pavement cells with comparable areas are similarly shaped in control and UV-irradiated plants and contain similar microtubule arrangements (Fig. 2 and marked cells). This means that microtubule organization is not directly affected by the UV exposure and that shape development proceeds in an analoguous manner as under control conditions. This lack of alteration in the microtubule arrangement can be observed for cells at the leaf tip, which were already in the process of lobe formation at the start of the exposure period, as well as for cells at the leaf base. Under our growth conditions, and in the monitored leaf number 4, cell proliferation still took place in this part of the leaf and lobes only started to appear on the cell surface. As microtubules are linked to the deposition of cellulose microfibrils, it can be assumed that no alterations in cellulose deposition occur upon UV treatment either. We can therefore conclude that the process of lobe formation and microtubule patterning is not impeded and that only the extent of cell expansion is restricted upon UV exposure.Open in a separate windowFigure 2Microtubule pattern in control and UV-exposed leaves visualized using GFP-TUA6 and confocal microscopy. Both images are from cells at the mid zone of the fourth leaf at day 2. Microtubules are similarly arranged in equally shaped and sized cells of control and UV-exposed leaves. The marked cells show a pattern whereby the tubules are centred in the neck regions between two outgrowing lobes.According to the Lockhart equation,⁶ cell (wall) growth is modulated by wall biomechanics and turgor pressure. Concerning turgor pressure, no clear differences in this factor between UV-exposed and control plants of Lactuca sativa L.⁷ and Pisum sativum⁸ could be observed, reinforcing the idea that especially the modulation of cell wall properties is the main factor causing the observed UV-induced reduction in cell expansion. Some reports indicate differential expression of wall loosening enzymes like expansins or xyloglucan endotransglycosylase/hydrolases (XTHs),^9,10 or cell wall strengthening enzymes as particular peroxidases⁷ after UV exposure. Another key event could involve UV-mediated changes in the phenylpropanoid pathway, which may cause changes in the lignin biosynthesis. As shown by the literature^11–14 lignin may well be an important modulator of cell wall architecture in Arabidopsis and therefore alterations in lignin synthesis could form the basis for morphological modifications. Further research on the cell wall properties of UV-treated plants may resolve this uncertainty.As a general conclusion we can state that the patterning of microtubules is not altered, but that alterations in cell wall composition or arrangements are the most plausible candidates for the observed reduction in pavement cell expansion upon chronic UV treatment.     

Biology and interactions of two distinct monopartite begomoviruses and betasatellites associated with radish leaf curl disease in India

Background

Emerging whitefly transmitted begomoviruses are major pathogens of vegetable and fibre crops throughout the world, particularly in tropical and sub-tropical regions. Mutation, pseudorecombination and recombination are driving forces for the emergence and evolution of new crop-infecting begomoviruses. Leaf curl disease of field grown radish plants was noticed in Varanasi and Pataudi region of northern India. We have identified and characterized two distinct monopartite begomoviruses and associated beta satellite DNA causing leaf curl disease of radish (Raphanus sativus) in India.

Results

We demonstrate that RaLCD is caused by a complex of two Old World begomoviruses and their associated betasatellites. Radish leaf curl virus-Varanasi is identified as a new recombinant species, Radish leaf curl virus (RaLCV) sharing maximum nucleotide identity of 87.7% with Tomato leaf curl Bangladesh virus-[Bangladesh:2] (Accession number AF188481) while the virus causing radish leaf curl disease-Pataudi is an isolate of Croton yellow vein mosaic virus-[India] (CYVMV-IN) (Accession number AJ507777) sharing 95.8% nucleotide identity. Further, RDP analysis revealed that the RaLCV has a hybrid genome, a putative recombinant between Euphorbia leaf curl virus and Papaya leaf curl virus. Cloned DNA of either RaLCV or CYVMV induced mild leaf curl symptoms in radish plants. However, when these clones (RaLCV or CYVMV) were individually co-inoculated with their associated cloned DNA betasatellite, symptom severity and viral DNA levels were increased in radish plants and induced typical RaLCD symptoms. To further extend these studies, we carried out an investigation of the interaction of these radish-infecting begomoviruses and their associated satellite, with two tomato infecting begomoviruses (Tomato leaf curl Gujarat virus and Tomato leaf curl New Delhi virus). Both of the tomato-infecting begomoviruses showed a contrasting and differential interaction with DNA satellites, not only in the capacity to interact with these molecules but also in the modulation of symptom phenotypes by the satellites.

Conclusion

This is the first report and experimental demonstration of Koch's postulate for begomoviruses associated with radish leaf curl disease. Further observations also provide direct evidence of lateral movement of weed infecting begomovirus in the cultivated crops and the present study also suggests that the exchange of betasatellites with other begomoviruses would create a new disease complex posing a serious threat to crop production.     

Airborne Pollen Grains of Gurdur,Turkey

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