Plant communities dominated by Salix gracilistyla in Korean Peninsula and Japan

Riverside vegetation dominated by Salix gracilistyla was analysed. In total, 77 phytocoenological relevés from Japan and both Korean Republics were compared. Based on 20 own relevés from Kumgang-san Mts (North Korea) a new association Artemisio feddei-Salicetum gracilistylae was described. It occupies alluvia of rivers and streams flooded for several times yearly. This species-rich community differs from the most similar, but species-poor association Salicetum gracilistylae Minamikawa 1963, described from Japan and known also from South Korea by numerous differential taxa.     

Partial flooding enhances aeration in adventitious roots of black willow (Salix nigra) cuttings

Black willow (Salix nigra) cuttings are used for streambank stabilization where they are subjected to a range of soil moisture conditions including flooding. Flooding has been shown to adversely impact cutting performance, and improved understanding of natural adaptations to flooding might suggest handling and planting techniques to enhance success. However, data assessing the root aeration in adventitious roots that are developed on cuttings of woody species are scant. In addition, it appears that no data are available regarding aeration of the root system under partially flooded conditions. This experiment was designed to examine the effects of continuous flooding (CF) and partial flooding (PF) on aerenchyma formation and radial oxygen loss (ROL) in black willow cuttings. Photosynthetic and growth responses to these conditions were also investigated. Under laboratory condition, replicated potted cuttings were subjected to three treatments: no flooding (control, C), CF, and PF. Water was maintained above the soil surface in CF and at 10 cm depth in PF. Results indicated that after the 28-d treatments, root porosity ranged between 28.6% and 33.0% for the CF and C plants but was greater for the PF plants (39.2% for the drained and 37.2% for the flooded portions). A similar response pattern was found for ROL. In addition, CF treatment led to decreases in final root biomass and root/shoot ratio. Neither CF nor PF had any detectable adverse effects on plant gas exchange or photosystem II functioning. Our results indicated that S. nigra cuttings exhibited avoidance mechanisms in response to flooding, especially the partially flooded condition which is the most common occurrence in riparian systems.     

Photosynthetic responses of Populus przewalski subjected to drought stress

Cuttings of P. przewalski were exposed to two different watering regimes which were watered to 100 and 25 % of field capacity (WW and WS, respectively). Drought stress not only significantly decreased net photosynthetic rate (P _N), transpiration rate (E), stomatal conductance (g _s), efficiency of photosystem 2 (PS2) (F_v/F_m and yield), and increased intrinsic water use efficiency (WUE_i) under controlled optimal conditions, but also altered the diurnal changes of gas exchange, chlorophyll fluorescence, and WUE_i. On the other hand, WS also affected the P _N-photosynthetically active radiation (PAR) response curve. Under drought stress, P _N peak appeared earlier (at about 10:30 of local time) than under WW condition (at about 12:30). At midday, there was a depression in P _N for WS plants, but not for WW plants, and it could be caused by the whole microclimate, especially high temperature, low relative humidity, and high PAR. There were stomatal and non-stomatal limitations to photosynthesis. Stomatal limitation dominated in the morning, and low P _N at midday was caused by both stomatal and non-stomatal limitations, whereas non-stomatal limitation dominated in the afternoon. In addition, drought stress also increased compensation irradiance and dark respiration rate, and decreased saturation irradiance and maximum net photosynthetic rate. Thus drought stress decreased plant assimilation and increased dissimilation through affected gas exchange, the diurnal pattern of gas exchange, and photosynthesis-PAR response curve, thereby reducing plant growth and productivity.     

Differences in the response of sunflower (Helianthus annuus) subjected to flooding and drought stress

Wample, R. L. and Thornton, R. K. 1984. Differences in the response of sunflower ( Helianthus annuus ) subjected to flooding and drought stress.
Comparison of drought- and flood-stressed sunflower plants ( Helianthus annuus L. hybrid 894) showed some similarities in response but differences in the mechanisms responsible for the responses to stress. Drought–stressed plants showed typical reductions in leaf water potential with increasing stress accompanied by increased leaf resistance. Photosynthesis declined while photorespiration increased after 48 and 96 h of drought stress. A primary reason for reduced photosynthesis in drought-stressed plants was increased stomatal resistance. No significant 0change in leaf water potential or in leaf resistance in flooded plants was found in this study. However, photosynthesis declined in a manner similar to that in drought-stressed plants and photorespiration showed only a transient increase at 48 h. Dark respiration was significantly higher at 48 and 96 h but the magnitude of the increase cannot account for the reduction in photosynthesis. Since the photosynthetic rate of flooded plants declined while stomata remained open, an effect at a more fundamental level is suggested and is thought to be related to disruption of carbohydrate transport.     

Biochemical responses in leaves of two apple tree cultivars subjected to progressing drought

The influence of water deprivation on potted apple trees (Malus domestica Borkh.) was investigated. Biochemical responses including ascorbic acid, glutathione (GSH), tocopherols, chlorophylls, carotenoids, free amino acids, and soluble carbohydrates were measured in leaves of diploid ‘Elstar’ and triploid ‘Jonagold Wilmuta’ subjected to progressive drought. Leaf water potential was chosen to be the primary indicator of water stress in tested plants. Time courses of measured biochemical parameters showed that mild drought did not significantly affect the chosen stress indicators. Moderate drought increased the concentrations of ascorbic acid, total GSH, β-carotene, zeaxanthin and -tocopherol, indicating the adaptation to oxidative stress in apple trees. Moderate drought also increased concentration of soluble carbohydrates, mostly due to increased sorbitol concentration. Severe drought negatively affected vitality of apple trees, and caused a decrease in sorbitol concentration. Severe drought also caused decreases in ascorbic acid, total GSH, β-carotene, -tocopherol and chlorophyll concentrations, which, together with the increase in oxidised GSH concentration, indicated severe damage due to oxidative stress. Severe drought increased free amino acid concentration, which was probably the result of increased proteolysis. Zeaxanthin concentration remained high even in leaves of apple trees subjected to severe drought stress. The results were similar for both tested apple cultivars.     

Responses to drought and flooding in tropical forage grasses

Seasonal drought and flooding severely limit pasture growth in tropical savannas. The objective of this study is to analyze and compare yield, biomass allocation, leaf growth rate and nutrient concentration of four important perennial C₄ forage grasses to short term flooding and moderate drought under controlled conditions. The grasses studied were the tufted Andropogon gayanus (CIAT 621) and Hyparrhenia rufa and the stoloniferous Echinochloa polystachya and Brachiaria mutica. All grasses were able to adjust their growth and development in response to flooding and drought: leaf growth and total biomass decreased under both treatments but the specific responses to these treatments differed markedly. Considering only total yield and leaf area, A. gayanus and H. rufa were relatively more tolerant to and less affected by drought whereas B. mutica and E. polystachya were more flood tolerant. In A. gayanus and H. rufa, both treatments reduced the proportion of assimilates devoted to roots and culms while increasing that of leaves decreasing the root/shoot ratio. In contrast, in B. mutica and E. polystachya only the proportion devoted to culms or stolons increased under flooding but the root/shoot ratio remained relatively stable under both treatments. All grasses produced adventitious rootlets except A. gayanus which was the most affected by flooding. Waterlogging decreased leaf nutrient concentration in all grasses which contributed to growth reduction. All species were relatively tolerant to both stresses. The results confirm the empirical observation that stoloniferous species B. mutica and E. polystachya are more tolerant to flooding thanks to adaptations typical of wetland plants such as hollow stolons which enhance oxygen diffusion to the roots and the development of adventitious rootlets that promotes water and nutrient absorption.     

Response of Salix nigra [Marsh.] cuttings to horizontal asymmetry in soil saturation

The objective of this research was to determine if localized morphological and physiological responses of Salix nigra [Marsh.] would reflect heterogeneous soil conditions, and if these changes would alter functioning at the whole-plant level. This experiment utilized split-root rhizotrons with two separate chambers, allowing for half of the root system of each plant to be flooded while the other half was allowed to drain. Plants from these heterogeneous treatments (F/D) were compared to plants in which the entire root system was flooded (F/F) or drained (D/D). Data on soil Eh, leaf area, and photosynthesis were recorded weekly. In situ root analysis compared pre- and post-treatment visible root surface area, root length, tortuosity (τ), fractal dimension (D_F), and fractal lacunarity (Λ). Soil in the chambers of the F/F became anoxic by day seven, and remained so for the remainder of the study. Chambers of the D/D treatment and the F/D treatment remained oxic, regardless of whether or not the individual chamber was flooded, indicating that partial root system aeration may enhance amelioration of anoxic or reducing conditions. For the measures related to photosynthetic activity, only net photosynthesis demonstrated an overall treatment effect. Generally, root length and D_F increased in response to flooding treatments, whereas Λ decreased. τ demonstrated an interactive effect wherein changes in roots within an individual chamber depended upon the flooding condition of the neighboring chamber. D_F was found to be highly sensitive to flooding, even if the flooding did not result in measurable soil reduction. Overall these results indicate that S. nigra may demonstrate unique morphological responses to heterogeneity in soil saturation, but localized amelioration of anoxia, rather than reallocation predominates under mildly reducing conditions.     

Effects of nutrients and arbuscular mycorrhizal colonization on the growth of Salix gracilistyla seedlings in a nutrient-poor fluvial bar

A field survey and a pot culture experiment were conducted to examine the effects of nutrients (N and P) and arbuscular mycorrhizal (AM) fungi on the growth of Salix gracilistyla, a pioneer plant in riparian habitats. The plants growing in the field were colonized by AM and/or ectomycorrhizal fungi. However, the direct effect of AM colonization on seedling growth was not detected in the pot culture experiment. In contrast, N application significantly promoted plant growth, suggesting that the growth of S. gracilistyla seedlings is largely limited by the availability of N in the field.     

Diurnal and seasonal responses of stomatal conductance for cowpea plants subjected to different levels of environmental drought

Summary Previously we reported that leaf conductance of cowpea (Vigna unguiculata) decreased with small changes in soil water status without associated changes in leaf water status. In these studies a larger range of soil water deficits was imposed in a rain-free environment by prolonged soil drying, and by weekly irrigation with different amounts of water. With progressive soil water deficits, leaf conductance and xylem pressure potential both declined, but in a manner which indicated that they were not related. Diurnal courses of leaf conductance usually indicated that stomatal opening occurred in the morning, and partial or complete stomatal closure occurred during midday and afternoon. This stomatal closure was associated with increases in air vapor pressure deficit. Day-to-day increases in leaf conductance, at times when radiation was not limiting stomatal opening, were associated with decreases in air vapor pressure deficits. However, maximum leaf conductances and their responses to vapor pressure deficit were generally smaller for plants subjected to greater depletion of soil water.     

Plant responses to drought and rewatering

Plants would be more vulnerable to water stress and thereafter rewatering or a cycled water environmental change, which occur more frequently under climatic change conditions in terms of the prediction scenarios. Effects of water stress on plants alone have been well-documented in many reports. However, the combined responses to drought and rewatering and its mechanism are relatively scant. As we know, plant growth, photosynthesis and stomatal aperture may be limited under water deficit, which would be regulated by physical and chemical signals. Under severe drought, while peroxidation may be provoked, the relevant antioxidant metabolism would be involved to annihilate the damage of reactive oxygen species. As rewatering, the recoveries of plant growth and photosynthesis would appear immediately through growing new plant parts, re-opening the stomata, and decreasing peroxidation; the recovery extents (reversely: pre-drought limitation) due to rewatering strongly depend on pre-drought intensity, duration and species. Understanding how plants respond to episodic drought and watering pulse and the underlying mechanism is remarkably helpful to implement vegetation management practices in climatic changing.Key words: drought stress, peroxidation, photosynthesis, relative growth rate, pre-drought limitation, rewatering, signals, stomatal conductanceUnder the climatic changing context, drought has been, and is becoming an acute problem most constraining plant growth, terrestrial ecosystem productivity, in many regions all over the world, particularly in arid and semi-arid area.^1–3 Based on the fourth assessment report by IPCC, global surface average temperature will have a 1.1–6.4°C range increase by the end of this century.³ It is indicated that a warming above 3°C would eliminate thoroughly fixed carbon function of global terrestrial vegetation, shift a net carbon source. With global warming, it is expected that water deficit would be escalated by increasing evapotranspiration, increasing the frequency and intensity of drought with an increase from 1% to 30% in extreme drought land area by 2100;³ which would offset the beneficial effect from the elevated CO₂ concentration, further limiting the structure and function of the terrestrial ecosystem. The global climate models may forecast the precipitation regimes including its distribution and amount, but the complicated responses of terrestrial ecosystem to climate change may adversely affect the predict accuracy.^1,4Plant would response to water stress by dramatically complex mechanisms from genetic molecular express, biochemical metabolism through individual plant physiological processes to ecosystem levels^2,5,6 which may mainly includes six aspects: (1) drought escape via completing plant life cycle before severe water deficit. E.g., earlier flowering in annuals species before the onset of severe drough;⁷ (2) drought avoidance via enhancing capacity of getting water. E.g., developing root systems or conserving it such as reduction of stomata and leaf area/canopy cover;^8,9 (3) drought tolerance mainly via improving osmotic adjustment ability and increasing cell wall elasticity to maintain tissue turgidity;¹⁰ (4) drought resistance via altering metabolic path for life survives under severe stress (e.g., increased antioxidant metabolism);^11,12 (5) drought abandon by removing a part of individual, e.g., shedding elder leaves under water stress;² (6) drought-prone biochemical-physiological traits for plant evolution under long-term drought condition via genetic mutation and genetic modification.^13–15 The processes may be involved in multi-aspects simultaneously in responses of plants to drought stress and thereafter rewatering.In the field context, there is always interval occurrence in drought and/or rewetting events, particular under climatic change conditions predicting more frequent drought and flooding events.³ The water cycle change may greatly impact plant growth, photosynthesis and many key metabolic functions, thereby ecosystem productivity and agricultural achievement.^5,16–18 Actually, sporadic precipitation would become a critical issue for maintaining ecosystem structural stability and even it''s surviving in arid and semi-arid area. For example, a small rainfall pulse can induce a rapid response in a desert ecosystem, which quickly triggers plant growth so that the plants can survive.¹⁹ Thus, to highlight how plant and terrestrial ecosystem cope with adverse abnormal climatic change variables is, and always will be crucial research issue in practical management of plant growth and vegetation productivity. Here, we try to provide a brief insight into how plant responses to the pre-drought and rewatering in terms of the plant growth, gas exchange and key related-physiological processes such as reactive oxygen species (ROS) metabolism. Finally a regulation path schematic is presented to try to explain the involved processes.     

Changes in prostaglandin concentration in blood subjected to repetitive freezing and thawing

Successive freezing and thawing of whole blood results in a consistently higher yield of various prostaglandin (PG) compounds. Evaluations were made with radioimmunological assay. The increase in PG concentrations seems to be more associated with cell fragmentation and not with the dissociation of albumin-PG complex. Our data suggest that there may be some dissociation of non-albumin-PG complexes. Artifactually high PG concentrations due to in vitro PG synthetase activity appears minimal at least with respect to indomethacin blocking of this enzyme. There are, in general, only slight differences in PG concentrations in samples with and without indomethacin.     

Physiological mechanisms for plant distribution pattern: responses to flooding and drought in three wetland plants from Dongting Lake, China

Both flooding and drought are important in determining plant distribution in wetlands. However, the roles of plant’s physiological response to flooding and drought in accounting for plant distribution are far from clear. To this end, three typical wetland plants with different distribution patterns (high-elevation species Miscanthus sacchariflorus, low-elevation species Carex brevicuspis and Polygonum hydropiper) in Dongting Lake were treated with three water levels (flooding 25 cm, control 0 cm, drought ?25 cm), and relative growth rate (RGR), malondialdehyde (MDA) content, electrolyte leakage and proline content were investigated. The RGR of the three species decreased significantly in both flooding and drought treatments. Compared to the control, the RGR of M. sacchariflorus decreased more in the flooding treatment but less in the drought treatment compared to the other two species. The contents of MDA in the three species increased in both flooding and drought treatments, except for P. hydropiper in the flooding treatment. MDA contents increased more in M. sacchariflorus in the flooding treatment but less in the drought treatment compared to the other two species. Only M. sacchariflorus had a higher electrolyte leakage in the flooding treatment, and drought led to a higher electrolyte leakage in P. hydropiper and C. brevicuspis. Proline content increased 69.2, 66.7 and 39.6 % in P. hydropiper, C. brevicuspis and M. sacchariflorus in the flooding treatment, and increased 44.2, 13.0 and 45.3 % in the drought treatment, respectively. These results suggest that M. sacchariflorus has a higher tolerance to drought but a lower tolerance to flooding than do the other two species, which might be the intrinsic mechanisms accounting for their different distribution patterns.     

Changes in prostaglandin concentration in blood subjected to repetitive freezing and thawing.

Successive freezing and thawing of whole blood results in a consistently higher yield of various prostaglandin (PG) compounds. Evaluations were made with radioimmunological assay. The increase in PG concentrations seems to be more associated with cell fragmentation and not with the dissociation of albumin-PG complex. Our data suggest that there may be some dissociation of non-albumin-PG complexes. Artifactually high PG concentrations due to in vitro PG synthetase activity appears minimal at least with respect to indomethacin blocking of this enzyme. There are, in general, only slight differences in PG concentrations in samples with and without indomethacin.     

Morphological responses to different flooding regimes in Carex brevicuspis

Water regime can be described by the depth, duration, frequency, and timing and predictability of flooded and dry phases. Despite growing recognition of the importance of water regimes in the regulation of plant growth and distribution, which components of water regimes that determine plant growth are not well known. To identify the causative components, 72 ramets of Carex brevicuspis were grown under six different water regime treatments (treatment A: constant 0 cm water level; treatment B: constant 30 cm water level; treatment C: 0 cm water level to 30 cm water level for 30 days, repeated 2 times; treatment D: 30 cm water level to 0 cm water level for 30 days, repeated 2 times; treatment E: 0 cm water level to 30 cm water level for 5 days, repeated 12 times; and treatment F: 30 cm water level to 0 cm water level for 5 days, repeated 12 times). Biomass accumulation, below:above ground biomass ratio, number of ramets, and proportions of spreading and clumping ramet were assessed. Biomass accumulation decreased only in relation to length of flooding. The highest biomass accumulation occurred in the 120‐day + 0 cm water level treatment, it was intermediate in the four 60 day + 30 cm water level treatments, and lowest in the 120 day + 30 cm water level treatment. Likewise, the below:above ground ratio decreased only with increasing length of flooding. Ramet number was highest in the 120 day + 0 cm water level treatment, intermediate in the four 60 day + 30 cm water level treatments, and lowest in the 120 day + 30 cm water level treatment. The proportion of spreading ramets increased from 28.0% in the 120 day + 0 cm water level treatment to 76.4% in the 120 day + 30 cm water level treatment. These data suggest that the growth of C. brevicuspis was only limited by the duration of flooding. Reduction of the below:above ground ratio and change from phalanx to guerrilla growth form are effective strategies for C. brevicuspis to acclimate to flooding stress, because they allow the plant to grow above the water surface and escape from anoxic conditions. Our study provides experimental information on the role of different components of water regimes in regulating plant growth, and may assist in protection and restoration of the C. brevicuspis community.