The effects of exposing winter-grown tomato {Lycopersicon esculentum L.) to various sunlight irradiances and CO2 concentrations, on dark respiration (Ro), night respiration (/?},}), net photosynthetic' rate (P^), dry matter production (DMP), yield earliness and yield amount were studied. Plants were grown in greenhouses under controlled temperatures and exposed to: fiill (FS) oř half (HS) sunlight irradiance in combination with atmospheric (A) oř enriched (E) concentrations of 300-330 or 1400-1500 g(C02) m'^, respectively. The of intact leaves at noontime reached 10.7, 15.2, 5.9 and 9.6 pmol(C02) m-2 s-i in treatments of FSA, FSE, HSA and HSE, respectively. The irradiances on the upper leaf surface during the measurements ranged between 160-190 and 450-550 pmol s'^ in the HS and FS treatments, respectively. of leaves which were kept in darkness following the measurement amved at efflux of 2.6, 2.5, 1.4 and 1.4 pmol(C02) m‘2 s'* while their Pn G^etween 20:00 and 24:00) reached values of 0.9, 1.3, 0.8 and 0.8 pmol(C02) treatments of FSA, FSE, HSA and HSE, respectively. Elevating the CO2 concentration from 300 to 1500 g m'^ increased P^ by 16, 28, 30 and 46 % under an irradiance of 160 pmol m‘2 s'*, and 19, 34, 59 and 44 % under irradiance of 320 pmol m-2 s'* in the FSA, FSE, HSA and HSE treatments, respectively. Increasing the measurement irradiance from 160 to 320 pmol m'2 s'* enhanced P^ by 69, 78, 23 and 49 % in an atmosphere of 300 g m-^ CO2, and by 73, 84, 49 and 47 % in an atmosphere of 1500 g m-^ CO2, in the FSA, FSE, HSA and HSE treatments, respectively. DMP was strongly influenced by the different environmental conditions and the total dry matter accumulation in the shoot per plant during 145 d reached 580, 347, 398 and 235 g in the FSA, FSE, HSA and HSE treatments, respectively. CO2 emichment promoted early yield under both full and partial sunlight irradiance. The HSE treatment led to earlier yield harvesting than the FSA and HSA treatments. The yield of the seven first trusses reached 6.8, 4.6, 5.7 and 3.2 kg per plant in the FSA, FSE, HSA and HSE treatments, respectively. Some increase in fruit fresh matter and diameter of fruits was detected in the C02-enrichéd treatments as compared to the non-enriched ones. Thus the combination of moderate shading and CO2 enrichment might provide a more productive option for winter- grown tomatoes in regions of subtropical climate, even in the winter, than the conventional management of aerated greenhouses without CO2 enrichment which are exposed to fiill sunlight.
Accumulation of glycollate or glyoxylate on irradiation of leaf discs in the presence of a-hydroxypyridinemethane sulfonate (a-HPMS) oř glycidate, respectively, was studied in C3-C4 intermediates of Altemanthera species (A. ficoides, A. tenellá) and Paríhenium hysíerophorus in comparison with the partem in C3 or C4 species. The levels of these two photorespiratory metabolites were reduced in the intermediates (< 75 % of that in C3) while being very low in the C4 species (about 10 % of that in C3). The inhibitory effect of bicarbonate on the glycollate or glyoxylate accumulation was pronounced in the C3 species (60 % inhibition), moderate in the intermediates (about 45 %), and very low (< 2 %) in the C4 plants. The negligible effect of bicarbonate on these photorespiratory metabolites in the C4 species is expected to be due to their C4 acid-based C02-concentrating mechanism. In the presence of 5 mM bicarbonate, the levels of glycollate and glyoxylate in the C3 species were similar to those in the C3-C4 intermediates. We speculate that a high intemal CO2 pool, possibly due to an efficient CO2 recycling/refixation mechanism, may be an additional reason besides the partial reduction in photorespiratory enžymic capacity for reduced levels of photorespiratory glycollate/glyoxylate in C3-C4 intermediates.Accumulation of glycollate or glyoxylate on irradiation of leaf discs in the presence of a-hydroxypyridinemethane sulfonate (a-HPMS) oř glycidate, respectively, was studied in C3-C4 intermediates of Altemanthera species (A. ficoides, A. tenellá) and Paríhenium hysíerophorus in comparison with the partem in C3 or C4 species. The levels of these two photorespiratory metabolites were reduced in the intermediates (< 75 % of that in C3) while being very low in the C4 species (about 10 % of that in C3). The inhibitory effect of bicarbonate on the glycollate or glyoxylate accumulation was pronounced in the C3 species (60 % inhibition), moderate in the intermediates (about 45 %), and very low (< 2 %) in the C4 plants. The negligible effect of bicarbonate on these photorespiratory metabolites in the C4 species is expected to be due to their C4 acid-based C02-concentrating mechanism. In the presence of 5 mM bicarbonate, the levels of glycollate and glyoxylate in the C3 species were similar to those in the C3-C4 intermediates. We speculate that a high intemal CO2 pool, possibly due to an efficient CO2 recycling/refixation mechanism, may be an additional reason besides the partial reduction in photorespiratory enžymic capacity for reduced levels of photorespiratory glycollate/glyoxylate in C3-C4 intermediates.
Some general characteristics of the observed plasma motions in the actlve region are described. The data concerning the birth and evolution of sunspots, intrinaic internal motiona, the balance of plasma fluxes in individual sunspots and in the active region as a whole are presented. Special attention is paid to rotational plasma motion in sunspots and torsional oscillations of the spots. The.
importance of data on torsional oscillations of aunspots has been established for the study of the magnetic field structure and plasma convection in subphotospheric layers of the Sun.