Physiology of stomata of R̲u̲m̲e̲x̲ p̲a̲t̲i̲e̲n̲t̲i̲a̲,

Sayre, Jasper Dean,

January 1926

Thesis (Ph. D.)--Ohio state university, 1922. / Cover-title. Autobiography. "Papers from the Department of botany, the Ohio state university, no. 171." "Literature cited": p. 265-266.

Stomata. Plants Rumex patientia.

Leaf Development of Rurnex patientia L. Exposed to UV Irradiation (280-320 nm)

Dickson, Judith G.

01 May 1978

Two factors which affect leaf ontogeny and ultimate leaf size: (1) the rate and duration of cell expansion, and (2) the rate and duration of cell division, were examined for their role in the slowed early growth rate and smaller ultimate leaf size when plants are exposed to ultraviolet-B (UV-B) radiation. Rumex patientia L. was grown in controlled environment chambers under enhanced UV-B radiation (equivalent to daily solar UV-B irradiation at 40°N latitude in mid-May with an atmospheric ozone concentration of 0.20 atm-cm) and control treatments. The pattern of growth as expressed in changes of mean cell size of two distinct cell types, tissue cell density, and length of the entire blade are consistent with the hypothesis that the radiation primarily affects cell division rather than cell expansion. Furthermore, it appears that the radiation probably alters the rate rather than the duration of cell division. An understanding of the mechanism of radiation damage should facilitate prediction of how this stress may interact with other stresses to which plants are normally subjected.

leaf development

rumex patientia L.

UV Irradiation

Cell and Developmental Biology

Plant Sciences

Effect of Mild Water Stress and Enhanced Ultraviolet-B Irradiation on Leaf Growth of Rumex obtusifolius L. and Rumex patientia L. (Polygonaceae).

Holman, Steven R.

01 May 1981

Leaves of Rumex obtusifolius L. and R. patientia L.were exposed to combinations of mild water stress and enhanced ultraviolet-B irradiation during their ontogeny. Two UV-B treatments (enhanced UV-B and control) and three water stress treatments (-0.0 MPa, -0.2 MPa and -0.4 MPa rooting medium matric potentials) were employed. The impact of the stress interaction was assessed on the basis of changes in leaf area, average adaxial epidermal cell size, and total number of adaxial epidermal cells per leaf. Although the level of UV-B irradiation applied was insufficient to significantly alter leaf growth at any given water stress, UV-B did interact with water stress to alter the pattern o= plant response to water stress. The interaction was only apparent when the water stress was greater than -0.2 MPa root matric potential. For both species UV-B irradiation exacerbated the depression of leaf growth due to -0.4 MPa water stress. For R. obtusifolius the basis of the reduction in leaf growth was likely a reduction in the rate of cell division during the early phase of leaf growth. For R. patientia the effect of the interaction on cell division was less clear. Cell expansion was not directly affected by UV-B irradiation in either species, although the reduction in cell size with increasing water stress was apparent. In terrestrial ecosystems, mild water stress is a common occurrence and with predicted anthropogenic modifications of the atmospheric ozone layer, UV-B radiation reaching the earth's surface can be expected to increase. The effect or. higher plants of the stress interaction may thus be of considerable significance under natural conditions.

water stress

Ultraviolet-B Irradiation

leaf growth

rumex obtusifolius L.

Rumex patientia L.

Ecology and Evolutionary Biology

Environmental Sciences

Plant Sciences

Photosynthesis, Dark Respiration, and Growth of Rumex Patientia L. Exposed to UV-B (280-315 nm) Irradiance Corresponding to Reduced Atmospheric Ozone Concentrations

Sisson, William B.

01 May 1976

Net photosynthesis, dark respiration, chlorophyll concentrations and growth were determined for Rumex patientia L. exposed to UV-B radiation corresponding to reduced atmospheric ozone concentrations. The hypothesis of whether reciprocity is maintained in the response of R. patientia to polychromatic UV-B radiation was tested. On the basis of the relationships derived from these studies, a simulation model was developed for the prediction of photosynthesis and growth of R. patientia exposed to UV-B radiation corresponding to any atmospheric ozone reduction. Photosynthetic rates were found to be depressed after two hours exposure to UV-B irradiance simulating a 0.18 atm•cm ozone column when the sun is at 30° from the zenith. During this initial exposure period, partial stomatal closure was implicated in the suppression of photosynthesis. However, after one day exposure, substantial increases in photosynthetic resistances apart from stomatal diffusion resistance occurred in the UV-irradiated plants and no differences in stomatal diffusion resistance were apparent between UV-irradiated and control plants. Dark respiration rates were slightly higher in those plants exposed to UV radiation. Leaf expansion of R. patientia was substantially repressed but only during the initial few days of exposure. Thereafter, leaf expansion was similar in the UV-irradiated and control plants. A reduction in total plant dry weight and leaf area of approximately 50 percent occurred after 22 days treatment while chlorophyll concentrations remained unaltered. Time of leaf initiation was shawm to be delayed in those plants exposed to UV-B radiation. Leaf longevity was decreased with increased UV radiation but accelerated whole-plant senescence and death was not observed. Photosynthetic rates determined through the ontogeny of the third leaf of R. patientia exposed to four levels of UV irradiance were found to be depressed as a function of the accumulated biologically effective UV irradiation. Thus, reciprocity was demonstrated between 6350 and 3175 J biologically effective UV irradiation. Results of the simultion model showed that under reduced atmospheric ozone concentrations, suppression of photosynthesis and leaf growth would be more severe during mid-sunnner (i . e. June) than would occur during the March to early May period, This results from smaller solar angles from the zenith and lower prevailing ozone concentrations prevalent during June. A validation test of the model was made with photosynthetic data obtained during a field study with R. patientia exposed to UV-B radiation corresponding to a 38 percent atmospheric ozone reduction (0.18 atm•cm when the sun was at 30° from the zenith). This validation test showed a reasonable correspondence between the measured and predicted photosynthetic rates. R. patientia was selected as the test species for this study because (1) it is reasonably sensitive to UV radiation as determined in preliminary studies evaluating approximately 20 native and agricultural plant species, (2) it is normally exposed to full sunlight in · its natural habitat, and (3) individual leaves are relatively long - lived (about 60 days) and are not normally shaded by other leaves of the same plant. Although this species probably represents one of the more sensitive plants to UV radiation, it would be this group of sensitive plants that would be initially affected under conditions of reduced atmospheric ozone. If more resistant plants with long-lived plant parts also accumulate UV radiation damage as was shown to occur in R. patientia, over sufficient periods of time even these species might be significantly impacted under conditions of reduced atmospheric ozone.

photosynthesis

dark respiration

growth

rumex patientia

UV-B

irradiance

atmospheric ozone

reduced concentrations

Life Sciences

Plant Sciences