Studies on Foliar Penetration: 2. THE ROLE OF LIGHT IN DETERMINING THE PENETRATION OF 2,4 DICHLOROPHENOXYACETIC, ACID

A further study has been made of the factors determining thelevel of penetration of 2,4-dichlorophenoxyacetic acid (2,4-D)into leaves. The technique involves the use of leaf disks and2,4-D containing carbon-14 in the carboxyl group. For Phaseolus vulgaris the influence of the pH of the appliedsolution is greater in the light than in the dark. Between 0and 1,000 f.c. at 27° C there is a small increase in therate of penetration into the abaxial surface. Under these conditionsthe rates remain constant up to 56 hours. This linear relationshipholds for concentrations ranging from 100 to 1,000 mg/l, andthe rate of penetration is directly proportional to the concentration.For intensities in excess of 1,000 f.c. the light response ismarkedly different: over the first few hours there is a steadyand relatively slow rate of penetration which is followed bya second phase when the rate is greatly accelerated. This acceleratedrate can be reversed by transferring the disks to darkness,and does not take place at 1° C. Likewise, if excised disksare left for more than one hour in either the light or the darkbefore applying 2,4-D then there is subsequently no phase ofaccelerated penetration. The course of penetration into theadaxial surface exhibits no accelerated rate, and compared tothe abaxial surface the rates are lower. For leaves of Ligustrum ovalifolium, which lack stomata on theadaxial surface, the rates of penetration at 27° C intoboth surfaces remain constant in either light or darkness. Forboth the adaxial and abaxial surfaces, the rate progressivelyincreases from 0 to; 2000 f.c. and there is no phase of acceleratedpenetration. Penetration into the adaxial surface is less. At1° C the rates for both surfaces in either light or darknessare depressed. If disks of Phaseolus are irradiated with ultraviolet light,subsequent penetration is markedly depressed in the light at27° C, but in the dark or at 1° C it is enhanced. On the basis of these findings it is concluded that both physicaland metabolic factors control the rate of penetration of 2,4-DTransport through the cuticle will be dependent on adsorptionand the length of the diffusion paths. Once diffusion gradientshave been established between the surface of the cuticle andthe outer surface of the cytoplasm in the epidermal cells, thesteepness will be dependent on the rates at which 2,4-D is eitherconverted into some metabolite or moved away from the surfaceor into other cells. The relative importance of physical andmetabolic process will be dependent on the permeability andthickness of the cuticle and the level of metabolic activity.The possible role of ectodesmata in determining both the lengthand steepness of the diffusion paths is discussed.