Paul Anthony

SALINITY TOLERANCE AND ANTIOXIDANT STATUS IN COTTON CULTURES

This investigation focuses upon cell growth and antioxidant status in cultured cells of cotton (Gossypium herbaceum) cvs. Dhumad (salt-tolerant, TOL), H-14 (medium salt-tolerant, MED), and RAhs-2 (salt-sensitive, SEN) exposed to saline stress (50-200 mM NaCl). Mean (+/- SEM) callus fresh weight (f.wt.) and dry weight (d.wt.) gains were significantly (p <.05) greater on Murashige and Skoog (MS) [1]-based medium with 50 mM NaCl for the TOL cv. (62% and 16%, respectively) over NaCl-free controls (2020 +/- 45 and 166 +/- 4 mg, respectively); comparable differences were not observed for the MED cv. A significant (p <.05) decrease in mean f.wt. occurred with the SEN cv. exposed to 50 mM NaCl. For all cvs., there were (p <.05) reductions in mean f.wts. in medium with >or=100 mM NaCl. At 200 mM NaCl, mean f.wt. decreases were 52% (TOL), 89% (MED), and 91% (SEN), respectively. A strong correlation existed between antioxidant status and growth of cells with NaCl. Superoxide dismutase and glutathione reductase activities increased with increasing salinity in the TOL cv. to maximum values of 26.3 +/- 1.1 U mg(-1) protein and 1.05 +/- 0.01 AB(340 nm) min(-1) mg(-1) protein, respectively, at 150 mM NaCl; for the MED and SEN cvs., there were no changes in activities of these enzymes between control and salt treatments. Catalase activity decreased progressively with increasing salt concentration in all cvs. except for SEN with 100 mM NaCl, where mean catalase activity (1.75 +/- 0.04 AB(240 nm) min(-1) mg(-1) protein) was greater (p <.05) than control (1.13 +/- 0.08). Overall, cultured cotton cells provide an experimental system for investigating the role of antioxidants in salt tolerance at the cellular level.

Plant protoplast technology: current status

Robust and reproducible protoplast-to-plant systems are crucial for underpinning genetic manipulation technology involving somatic hybridisation and transformation. Novel and effective approaches for maximising the efficiency of such protoplast cultures include supplementation of media with surfactants and artificial gas carriers, such as perfluorochemicals and haemoglobin. Physical parameters, particularly electrostimulation, also enhance the development of protoplasts and protoplast-derived cells in culture. DNA uptake into protoplasts is now a routine and universally accepted procedure in plant biotechnology for introducing and evaluating both short-term (transient) and long-term (stable) expression of genes in cells and regenerated plants. Importantly, protoplast fusion overcomes pre- and post-zygotic sexual incompatibility barriers and generates novel germplasm through new nuclear-cytoplasmic combinations. In this respect, considerable progress has been made in generating somatic hybrid plants, particularly in citrus, brassicas and potato. Isolated protoplasts are also a unique single cell system for evaluating aspects of ultrastructure, genetics and physiology, with potential for the biosynthesis of novel secondary products, including commercially-important recombinant proteins (e.g. antibodies), and as systems in toxicity screening. Recent advances in protoplast technology have benefited from advances in animal and microbial cell culture, with interesting parallels existing between these systems. Further innovations will necessitate the strengthening of interdisciplinary links in these research fields and the requirement for continued dialogue and co-operation between workers with diverse but complementary skills.

Synergistic enhancement of protoplast growth by oxygenated perfluorocarbon and pluronic F-68

SummaryCell suspension-derived protoplasts of albino Petunia hybrida were grown for 10 d at the interface between aqueous culture medium (KM8P) and an oxygenated (10 mbar for 15 min) perfluorocarbon liquid, perfluorodecalin. Protoplasts synthesised new cell walls and divided normally at the perfluorodecalin/culture medium interface, with a mean viability after 10 d of > 92.0%. The mean plating efficiency of protoplasts was elevated by 37% (P<0.05) following culture at the perfluorodecalin/medium interface, but was unaltered by perfluorodecalin or oxygen separately. The mean plating efficiency of protoplasts cultured at the interface was further increased to a maximium of 52% above control, in the presence of oxygenated perfluorodecalin and KM8P medium supplemented with the non-ionic, co-polymer surfactant, Pluronic F-68 at 0.01% (w/v). These findings demonstrate the effectiveness of oxygenated perfluorodecalin for promoting protoplast growth, by facilitating oxygen delivery. The finding that Pluronic F-68 further increased the plating efficiency of protoplasts cultured at the perfluorocarbon/aqueous interface suggests that these agents improve growth through separate, but cumulative, mechanisms.

An improved protocol for the culture of cassava leaf protoplasts

Viable protoplasts (yield > 1.9 × 107 g−1 fresh weight; mean viability 85±2%, n=5) were isolated from leaves of axenic shoot cultures of Manihot esculenta Crantz. cv. M. Thai 8. Protoplasts were cultured for up to 50 days in liquid, ammonium-free MS medium, overlaying agarose-solidified B5 medium with short glass rods embedded perpendicularly within, and protruding from, the agarose layer. Control protoplasts were cultured identically, but without glass rods. Sustained protoplast division was observed only in the presence of glass rods, where the initial plating efficiency was almost 6-fold greater than control (p < 0.05). The mean final plating efficiency of treated cultures was 1.0±0.2% while, in contrast, significant colony formation was not observed in controls.

Microgravity simulation by diamagnetic levitation: effects of a strong gradient magnetic field on the transcriptional profile of Drosophila melanogaster

BackgroundMany biological systems respond to the presence or absence of gravity. Since experiments performed in space are expensive and can only be undertaken infrequently, Earth-based simulation techniques are used to investigate the biological response to weightlessness. A high gradient magnetic field can be used to levitate a biological organism so that its net weight is zero.ResultsWe have used a superconducting magnet to assess the effect of diamagnetic levitation on the fruit fly D. melanogaster in levitation experiments that proceeded for up to 22 consecutive days. We have compared the results with those of similar experiments performed in another paradigm for microgravity simulation, the Random Positioning Machine (RPM). We observed a delay in the development of the fruit flies from embryo to adult. Microarray analysis indicated changes in overall gene expression of imagoes that developed from larvae under diamagnetic levitation, and also under simulated hypergravity conditions. Significant changes were observed in the expression of immune-, stress-, and temperature-response genes. For example, several heat shock proteins were affected. We also found that a strong magnetic field, of 16.5 Tesla, had a significant effect on the expression of these genes, independent of the effects associated with magnetically-induced levitation and hypergravity.ConclusionsDiamagnetic levitation can be used to simulate an altered effective gravity environment in which gene expression is tuned differentially in diverse Drosophila melanogaster populations including those of different age and gender. Exposure to the magnetic field per se induced similar, but weaker, changes in gene expression.

Diamagnetic levitation enhances growth of liquid bacterial cultures by increasing oxygen availability

Diamagnetic levitation is a technique that uses a strong, spatially varying magnetic field to reproduce aspects of weightlessness, on the Earth. We used a superconducting magnet to levitate growing bacterial cultures for up to 18 h, to determine the effect of diamagnetic levitation on all phases of the bacterial growth cycle. We find that diamagnetic levitation increases the rate of population growth in a liquid culture and reduces the sedimentation rate of the cells. Further experiments and microarray gene analysis show that the increase in growth rate is owing to enhanced oxygen availability. We also demonstrate that the magnetic field that levitates the cells also induces convective stirring in the liquid. We present a simple theoretical model, showing how the paramagnetic force on dissolved oxygen can cause convection during the aerobic phases of bacterial growth. We propose that this convection enhances oxygen availability by transporting oxygen around the liquid culture. Since this process results from the strong magnetic field, it is not present in other weightless environments, e.g. in Earth orbit. Hence, these results are of significance and timely to researchers considering the use of diamagnetic levitation to explore effects of weightlessness on living organisms and on physical phenomena.

Novel approaches for regulating gas supply to plant systems in vitro: Application and benefits of artificial gas carriers

SummaryThe composition of the gaseous environment within tissue culture vessels is a critical factor in determining in vitro plant growth and morphogenic responsiveness. Consequently, the provision of an adequate and sustainable oxygen supply for cultured plant cells (including isolated protoplasts), tissues and organs is a crucial prerequisite for optimization and regulation of such cultural responses. During the past decade, research has focused on improving growth and development using artificial gas carriers based on inert perfluorocarbon (PFC) liquids and hemoglobin (Hb) solution. Supplementation of culture media with such artificial oxygen carriers has demonstrated beneficial effects of increased and sustainable cellular mitotic division and subsequent biomass production in a diverse range of plant species, during both short- and longer-term culture. Studies have targeted systems where oxygen availability is actually or potentially a major growth-limiting factor. Undoubtedly, gas carrier-facilitated improvements in regulating the supply of respiratory gases to cultured cells, tissues and organs will have increasingly important biotechnological and practical implications in the context of plant micropropagation, somatic hybridization, transgenic plant production, and secondary product biosynthesis.

Perfluorochemicals and Cell Biotechnology

Perfluorochemical (PFC) liquids have properties, especially high gas solubility, which make these compounds useful in medicine and biotechnology. PFCs are being employed to facilitate respiratory gas supply to both prokaryotic and eukaryotic cells and, in some systems, to improve biomass production and yields of commercially-important cellular products. Animal (including human) and plant cells have also been cultured at the interface between PFC liquids and aqueous culture medium, while fluorocarbon polymers have been employed as gaspermeable membranes in eukaryotic cell cultures. This paper presents an overview of the applications and beneficial effects of PFCs in microbial, animal and plant culture systems. PFCs have been compared with other physical and chemical options for manipulating respiratory gas supply to cultured cells. PFC-facilitated improvements in cell culture technology will have increasingly important biotechnological implications.

Meristematic cell proliferation and ribosome biogenesis are decoupled in diamagnetically levitated Arabidopsis seedlings

BackgroundCell growth and cell proliferation are intimately linked in the presence of Earth’s gravity, but are decoupled under the microgravity conditions present in orbiting spacecraft. New technologies to simulate microgravity conditions for long-duration experiments, with stable environmental conditions, in Earth-based laboratories are required to further our understanding of the effect of extraterrestrial conditions on the growth, development and health of living matter.ResultsWe studied the response of transgenic seedlings of Arabidopsis thaliana, containing either the CycB1-GUS proliferation marker or the DR5-GUS auxin-mediated growth marker, to diamagnetic levitation in the bore of a superconducting solenoid magnet. As a control, a second set of seedlings were exposed to a strong magnetic field, but not to levitation forces. A third set was exposed to a strong field and simulated hypergravity (2 g). Cell proliferation and cell growth cytological parameters were measured for each set of seedlings. Nucleolin immunodetection was used as a marker of cell growth. Collectively, the data indicate that these two fundamental cellular processes are decoupled in root meristems, as in microgravity: cell proliferation was enhanced whereas cell growth markers were depleted. These results also demonstrated delocalisation of auxin signalling in the root tip despite the fact that levitation of the seedling as a whole does not prevent the sedimentation of statoliths in the root cells.ConclusionsIn our model system, we found that diamagnetic levitation led to changes that are very similar to those caused by real- [e.g. on board the International Space Station (ISS)] or mechanically-simulated microgravity [e.g. using a Random Positioning Machine (RPM)]. These changes decoupled meristematic cell proliferation from ribosome biogenesis, and altered auxin polar transport.

Enhanced mitotic division of cultured Passiflora and Petuniaprotoplastsby oxygenated perfluorocarbon and haemoglobin

Cell suspension-derived protoplasts were cultured in (A) liquid medium, (B) medium overlaying oxygenated perfluoro-decalin (PFC), (C) medium containing 1:50 (v:v) of haemoglobin solution ( Erythrogen TM ), or (D) medium with 1:50 (v:v) Erythrogen TM overlaying oxygenated PFC. In Passiflora, mitotic division of protoplasts was increased (P < 0.05) by all treatments, with Erythrogen TM being the most effective (120% increase over control). For Petunia, treatment D induced maximum mitosis (140% over control), whilst Erythrogen TM alone produced a less pronounced (80% over control) increase.