Keerti S. Rathore

A cytoplasmic gradient of Ca2+ is correlated with the growth of lily pollen tubes☆

We have measured the distribution of cytoplasmic calcium in lily pollen tubes by microinjecting them with indo-1 and performing fluorescence ratio image analysis on them. All of the 16 tubes that were growing at the time of the calcium measurements showed a gradient of [Ca2+]i in the tip region, with Ca2+ being 1.25 to 3.32 times higher at the distal end in 15 cases and more than 5 times higher in one case. The extent of the gradient ranged from 22 to 65 microns. Most of the 15 nongrowing tubes either had no gradient or had lower Ca2+ in the tip region. While we have confirmed a previous report that lily pollen tubes can be loaded with the membrane-permeable acetoxymethyl ester forms of calcium indicators, the dyes loaded in this way are visibly partitioned into organelles and this method of loading is, therefore, not useful for the measurement of [Ca2+]i. Iontophoresis of the dye free acids into tubes produces a more uniform and diffuse fluorescence which does not appear to partition into organelles. Indo-1 remains in the pollen tubes longer than fura-2. The correlation between growth and the [Ca2+]i gradient in the apical portion of the pollen tube is discussed in relation to previous reports that have suggested that such a gradient should exist during polarized growth.

Use of bar as a selectable marker gene and for the production of herbicide-resistant rice plants from protoplasts

We have used the bar gene in combination with the herbicide Basta to select transformed rice (Oryza sativa L. cv. Radon) protoplasts for the production of herbicide-resistant rice plants. Protoplasts, obtained from regenerable suspension cultures established from immature embryo callus, were transformed using PEG-mediated DNA uptake. Transformed calli could be selected 2–4 weeks after placing the protoplast-derived calli on medium containing the selective agent, phosphinothricin (PPT), the active component of Basta. Calli resistant to PPT were capable of regenerating plants. Phosphinothricin acetyltransferase (PAT) assays confirmed the expression of the bar gene in plants obtained from PPT-resistant calli. The only exceptions were two plants obtained from the same callus that had multiple copies of the bar gene integrated into their genomes. The transgenic status of the plants was varified by Southern blot analysis. In our system, where the transformation was done via the protoplast method, there were very few escapes. The efficiency of co-transformation with a reporter gene gusA, was 30%. The To plants of Radon were self-fertile. Both the bar and gusA genes were transmitted to progeny as confirmed by Southern analysis. Both genes were expressed in T1 and T2 progenies. Enzyme analyses on T1 progeny plants also showed a gene dose response reflecting their homozygous and heterozygous status. The leaves of To plants and that of the progeny having the bar gene were resistant to application of Basta. Thus, the bar gene has proven to be a useful selectable and screenable marker for the transformation of rice plants and for the production of herbicide-resistant plants.

Ionic basis of currents in somatic embryos of Daucus carota

A vibrating probe was used to measure extracellular electrical currents around developing somatic embryos in two lines (RCC27, RCC48) of cultured cells of Daucus carota L. at the heart and torpedo stages. At pH 5.5, an inward current of 1.2±0.1 μA·cm-2 (n=23) was detected at the cotyledon, and an outward current of 1.0±0.1 μA·cm-2 (n=22) was found at the radicle in torpedostage embryos from the RCC27 line. At a pH of 5.75 the currents increased by 0.2–0.3 μA·cm-2 (n=60–62). In a few cases an additional small inward current was detected at the tip of the radicle in toepedo-stage embryos from RCC27 line. Such an inward current at the radicle seemed to appear earlier, some time after the heart stage, in embryos from the RCC48 line.Both extracellular pH measurements (using microelectrodes filled with ion-sensitive resin) and ion-substitution studies were carried out in order to ascertain the ionic composition of the currents in torpedo-stage embryos from the RCC27 line. Regions adjacent to the cotyledon and radicle, at the points of current entry and exit, were found to be more acidic by 0.02±0.01 (n=14) and 0.07±0.01 (n=12) pH units, respectively, than the bulk medium. Removal of K+ from the medium reversibly reduced the currents to about 25% of their original value at both cotyledon and radicle. Deletion of Cl- decreased the currents slightly. Removal of Ca2+ resulted in a rapid doubling of currents. Addition of either N,N′-dicyclohexylcarbodiimide or tetraethyl ammonium chloride substantially reduced overall currents, and their removal resulted in partial recovery of the currents. It is suggested that the inward current at the cotyledon is comprised largely of K+ influx and the outward current at the radicle is mainly the result of active H+ efflux.

The responses of pollen to applied electrical fields

The growing pollen tubes of tomato and tobacco were exposed to electrical fields and the effect on the direction of growth was measured. They responded by turning toward the positive electrode (anode) and gave a detectable response in fields as small as 0.1 mV/tube diameter. The sites of germination of tobacco pollen grains were also affected by applied fields; the pollen tubes tended to emerge from the anodal side. This effect was detectable at a field of 0.4 mV/grain diameter.

Physical, chemical and physiological parameters for electroporation-mediated gene delivery into rice protoplasts

Transformation of cereal protoplasts has been reported using several methods; however, the efficiencies of transformations are still very low. We have evaluated a number of parameters that influence electroporation-mediated DNA uptake and have also compared the efficiency of transient GUS activity and stable transformation obtained using an optimized electroporation method with that of the PEG method. The electroporation conditions tested were ionic composition of buffer, ionic strength, resistivity of buffer, type of anions, voltage, and capacitance.Protoplasts isolated from suspension cultures derived from immature embryos of rice (cvs Radon and IR-54) were used for this study. Stable transformation or transient GUS expression experiments were carried out using a plasmid construct containing the CaMV 35S promoter driving thebar gene and a rice actin promoter driving thegus A (uid A) gene (pAG35bar). Electroporation under optimized conditions resulted in about 13-fold higher GUS activities compared to the PEG method. Protoplast survival following optimized electroporation conditions was 55–60%, compared to 35–40% with the PEG treatment. Protoplasts isolated from a suspension culture at different ages gave substantially different levels of transient GUS expression following electroporation-mediated DNA uptake. In contrast, the age of the suspension culture did not influence PEG-mediated DNA uptake and transient GUS activities, which remained low throughout the culture period examined (21 months). Putatively transformed calluses were selected after three to four weeks on medium containing phosphinothricin as the selection agent. The transformation frequencies ranged from 6.2×10−5 to 5.4×10−4 with the electroporation method compared to 1.3×10−5 to 5.3×10−5 with the PEG method. Southern blot analysis of PPT-resistant calluses obtained by the electroporation-mediated transformation showed simple intergration patterns of integrated DNA in most of the transformants.

Ionic currents around developing embryos of higher plants in culture

Plant cell and tissue cultures are being used extensively to study growth and early development of higher plants. This is because the egg cell of higher plants resides within the sporophyte and is difficult to isolate. Somatic embryogenesis offers an alternative that is being exploited by many investigators to produce large numbers of somatic embryos growing under controlled conditions. The development of somatic embryos in carrot tissue cultures was first demonstrated by Steward et al. (1958) and Reinert (1959). Asexual embryos develop from small embryogenic cell clusters (proembryos) that are growing in a medium containing the synthetic auxin 2,4dichlorophenoxyacetic acid (2,4-D). Embryo development is initiated by removing very large cell clusters and single differentiated cells by filtration from a suspension culture and then transferring the small cell clusters at a low cell density to a medium lacking the 2,4-D. Embryos develop from these clusters and pass successively through globular, heart, and torpedo stages, which are similar to their zygotic counterparts (Fig. 1). This and another system, in which tobacco pollen have been induced to form haploid embryos, have now been used to investigate endogenous currents traversing developing higher plant embryos. The vibrating probe studies have allowed us to see the similarities between the embryos derived from the two systems and also made it possible to detect subtle physiological variability between the somatic embryos of the same species that are derived from different culture lines. Brawley et al. (1984) were the first to use the carrot somatic embryogenesis system to study the endogenous currents. They found that the current (flow of positive charge) enters the apical pole and leaves the region near the presumptive radicle in the radially symmetric globular embryo. This electrical polarity precedes differentiation of vascular tissue and cotyledon development. The