Control of Passive Permeability in the Chara Plasmalemma

Conductance to K⁺ alters as a function of membrane potential(_m). Conductance to H⁺ (or OH^–) changes with externalpH (pH^o) This conductance change can be modulated by alteringcytoplasmic pH or external K⁺ concentration, both of which alsoalter _m. We suggest a role for H⁺ conductance in regulatingcytoplasmic pH above pH^o 7.0.     

Efficiency and regulation of root respiration in a legume: Effects of the N source

A comparison was made of energy metabolism of nodulated N₂ fixing plants and non-nodulated NO₃-fed plants of Lupinus albus L. Growth, N-increment, root respiration (O₂ uptake and CO² production) and the contribution of a SHAM-sensitive oxidative pathway (the alternative pathway) in root respiration were measured. Both growth rate and the rate of N-increment were the same in both series of plants. The rate of root respiration, both O₂ uptake and CO₂ production, and the activity of the SHAM-sensitive pathway were higher in NO₃-fed plants than in N₂ fixing plants. The rate of ATP production in oxidative phosphorylation was computed also to be higher in NO₃-fed plants. It is concluded that both carbohydrate costings and ATP costings for synthesis + maintenance of root material were lower in N₂ fixing than in NO₃-fed plants. The respiratory quotient of root respiration was 1.6 in N₂-fixing plants and 1.4 in NO₃-fed plants. These values were slightly higher than the values calculated on the basis of CO₂ output due to N-assimilation and the experimental values of O₂ uptake, but showed the same trend: highest in N₂ fixing plants. Root respiration of NO₃-fed plants showed a diurnal pattern (both O₂ uptake, CO₂ production and the activity of the SHAM-sensitive pathway), whilst no diurnal variation in root respiration was found in N₂ fixing plants. However, C₂H₂ reduction did show a diurnal rhythm, which is suggested to be related to the diurnal variation in transpiration. Addition of NO₃ to N₂ fixing plants increased the rate of root respiration and the activity of the alternative pathway. This treatment did not decrease C₂H₂ reduction and H₂ evolution within 4 days. Withdrawal of NO₃-supply from NO₃-fed plants decreased the rate of root respiration but had no effect on the relative activity of the alternative pathway. It is suggested that the higher rate of root respiration and the higher activity of the SHAM-sensitive pathway in NO₃-fed plants is due to a larger supply of carbohydrates to the roots, partly due to a better photosynthetic performance of the shoots and partly due to a higher capacity of the roots to attract carbohydrates.     

Intercellular Transport in Plants: II. CYCLOSIS AND THE RATE OF INTERCELLULAR TRANSPORT OF CHLORIDE IN CHARA

The effect of streaming speed on intercellular transport ofchloride has been studied using pairs of internodal cells ofChara. The rate of transport was measured by that fraction ofthe chloride that entered one internode which was transportedout of it into the cells of the node and the next internode.The speed of cytoplasmic streaming was altered by treating thefirst cell with cytochalasin B. The relative rate of intercellular transport depended markedlyon the streaming speed at all speeds up to those found in untreatedcells. The chloride influx into the treated cell did not dependon the streaming speed. It is concluded that the rate of intercellular transport oflow molecular weight solutes in Chara will be normally limitedby the rate at which cytoplasmic streaming brings solute tothe plasmodesmata, rather than by the diffusion permeabilityof the plasmodesmata. This conclusion may well apply to othercharophyte plants, and could in principle apply to higher plants.