Agrobacterium infection of hemp (Cannabis sativa L.): establishment of hairy root cultures

Abstract

Experimental conditions were optimized for hemp, a difficult to transform plant, to be effectively infected with either Ri or Ti plasmid-bearing agrobacteria and to establish stably transformed tissues. Hypocotyl of intact seedlings was the most responsive material and the response depended on both bacterial strain and plant variety. Transformed tissues, hairy roots and tumors, were cultured and stabilized in vitro and showed the characteristic traits of fast and phytohormone-independent growth as well as high incidence of lateral branching and abundance of root hairs in the case of roots. They all contained T-DNA of the corresponding Ri or Ti plasmid as revealed by PCR analysis with specific primers and further hairy roots induced by AR10GUS strain showed normal pattern of β-glucuronidase positive staining. To our knowledge, this represents the first reported protocol for the establishment of Cannabis sativa hairy root cultures.     

Anti-inflammatory activity of a new triterpenoid saponin from carthamus tinctorius linn

A new bioactive triterpenoid saponin 3β-O-[β-D-xylopyranosyl(1 → 3)-O-β-D-galactopyranosyl]-lup-12-ene-28 oic acid-28-O-α-L-rhamnopyranosyl ester compound (A), was isolated from the methanolic fraction of the roots of this plant by various colour reactions, chemical degradations and spectral analysis. Compound (A) showed anti-inflammatory activity.     

Development of a dot immunobinding assay to detect Phytophthora spp. in naturally dark-rooted woody plants

An indirect dot immunobinding assay (DIBA) with a PAb raised against an isolate of P. cinnumomi was evaluated to detect Phytophthora spp. in naturally dark-rooted woody plants. Screening of different modifications of the procedure were done with root samples of Chamaecyparis lawsoniana non-infected and infected with P. cinnamomi. With the optimised DIBA procedure, root infection could be diagnosed by a clearly defined halo around the spot and by a colour change in the spot using Fast Red or Fast Blue substrate. Detection of different Phytophthora species in Chamaecyparis plants from commercial nurseries was successful with the optimised procedure.     

A study of the tensile force required to pull wheat roots from soil

Experiments were carried out to determine the tensile properties of mature wheat roots and the force necessary to pull roots from undisturbed soils at a range of moisture contents using an Instron materials testing rig. Roots decreased in cross sectional area from 1.5 to 0.1 mm²and in tensile strength from 7.0 to 2.3 Newtons (N) along the first 12 cm of their length. Breaking strain was constant along the root but the breaking stress increased. Increased seeding rate decreased root diameter and tensile strength but plant growth regulators and fertiliser nitrogen level did not affect the tensile properties. Roots were pulled from mesh tubes of soil (25 mm ± 75 mm) into which they had grown. The peak loads for sandy clay loam and sandy loam soils were 4.8 and 3.9 N respectively and increasing the soil moisture from 17% to 26% reduced the peak load from 5.2 N to 3.5 N. With the drier soil the inner stele pulled free leaving the outer periderm in the soil in a higher proportion of the roots indicating a stronger root/soil bond than in the wetter soil. The load us displacement relationship when pulling roots from soil resembled that for a fibre reinforced composite material. The presence of branch roots resulted in an uneven trace in which there were a number of sub-peaks as branch roots gave way. It is suggested that soil wetting could contribute to lodging of wheat by reducing the resistance of roots to slippage and breaking.     

Differential regulation of K+ channels in Arabidopsis epidermal and stelar root cells

The patch clamp technique was applied to protoplasts isolated from the epidermis and pericycle of Arabidopsis roots and their plasma membrane currents investigated. In the whole cell configuration, all protoplasts from the epidermis exhibited depolarization‐activated time‐dependent outwardly rectifying (OR) currents whereas OR currents were present in only 50% of cells from the pericycle. The properties of the OR currents in the epidermis and pericycle were compared with respect to their selectivity, pharmacology and gating. The time‐dependent activation kinetics, selectivity and sensitivity to extracellular tetraethyl ammonium of the OR current in each cell type were not significantly different. The reversal potential (E_rev) of the OR currents indicated that they were primarily due to the movement of K⁺. However, the gating properties of the OR currents from the epidermis differed markedly from those exhibited in the pericycle. Although both cell types displayed OR currents with voltage‐dependent gating modulated in a potassium‐dependent fashion [i.e. the activation threshold (V_0.5) was displaced to more positive voltages as extracellular K⁺ increased], the OR currents in the epidermis also displayed voltage‐independent gating by extracellular K⁺ which dramatically regulated current density. In the present study, reducing extracellular K⁺ activity from 40 to 0.87 mm reduced the OR current density in epidermal cells by approximately 80%. The chord conductance of the OR current saturated as a function of extracellular K⁺ and could be fitted with a Michaelis–Menten function to yield a binding constant (K_m) of 10.5 mm . The ability of other monovalent cations to substitute for K⁺‐gating of the OR currents was also investigated and shown to exhibit a relative sequence of K⁺ ≥ Rb⁺ > Cs⁺ > Na⁺ ≥ Li⁺ (Eisenmann sequence IV) with respect to efficacy of gating. Furthermore, single channel recordings demonstrated that channel activity rather than the single channel conductance was modulated by extracellular K⁺. In contrast, OR current density in the pericycle was largely independent of extracellular K⁺. It is suggested that the contrasting gating properties of the K⁺ channels in the epidermis and pericycle reflect their different physiological roles, particularly with respect to their role in K⁺ (nutrient) transport from the soil solution to the shoot.     

Effect of bacitracin on growth and monoclonal antibody production by tobacco hairy roots and cell suspensions

Hairy roots and suspended cells of transformedNicotiana tabacum were used to produce full length murine IgG₁ monoclonal antibody. The maximum amount of antibody accumulated per g dry weight in the hairy root cultures was 6.5 times that in the suspension cultures. Up to 48% of the antibody in the suspension cultures was found extracellularly, while a maximum of only 17% was recovered from the hairy root medium. The amount of assembled antibody in the root and suspension cultures was significantly reduced by intracellular and/or extracellular antibody degradation soon after the end of the exponential growth phase. Bacitracin, a polypeptide antibiotic, has been shown in previous work to prevent degradation of peptides and hormones in plant and mammalian systems. Treatment of hairy roots and cell suspensions with 100 μg/mL bacitracin was not sufficient to prevent loss of antibody from the cultures, but improved the specific growth rates by up to 53%. At concentrations of 250 μg/mL and above, bacitracin had a toxic effect on hairy roots, which may limit the application of this peptide in plant tissue culture.     

Root anatomy of <Emphasis Type="Italic">Pinus taeda</Emphasis> L.: seasonal and environmental effects on development in seedlings

The environmental and seasonal effects on anatomical traits of Pinus taeda L. seedling roots were studied in the laboratory in three contrasting root growth media and also in typical outdoor nursery culture. Growth media with lower water regimen and high penetration resistance caused a reduction in lengths of the white and condensed tannin (CT) zones and acceleration of development of suberin lamellae in the endodermis. As a possible counter to this reduction in zone lengths, second-order laterals were produced closer to the tips of first-order laterals. This suggested there may be an advantage to producing more shorter roots under stressful conditions. Under outdoor nursery conditions (June to mid-December) the white zone was always a rather small part of the root system surface area (4.5% in December), but it dominated as a provider of cortical plasmalemma surface area (CPSA) in contact with modified soil solution (65% in December) because of its live cortex and capacity to increase nearly three fold the amount of CPSA per unit root length. The CT zone always provided most of the total root surface area (80% in December). Although it had no live cortex, a few cells of the CT zone endodermis remained non-suberized passage cells, perhaps giving this major part of the root system some capacity for ion and water absorption. A late summer increase in CPSA was due largely to the rapid production of mycorrhizae. Root systems were capable of very rapid replacement of roots lost due to undercutting and lateral root pruning. The great variation in CPSA per unit root length contained in the white, mycorrhizal and CT zones suggested a capacity to adapt rapidly to changing conditions.