Root growth, developmental changes in the apex, and hydraulic conductivity for Opuntia ficus-indica during drought

Developmental changes in the root apex and accompanying changes in lateral root growth and root hydraulic conductivity were examined for Opuntia ficus-indica (L.) Miller during rapid drying, as occurs for roots near the soil surface, and more gradual drying, as occurs in deeper soil layers. During 7 d of rapid drying (in containers with a 3-cm depth of vermiculite), the rate of root growth decreased sharply and most root apices died; such a determinate pattern of root growth was not due to meristem exhaustion but rather to meristem mortality after 3 d of drying. The length of the meristem, the duration of the cell division cycle, and the length of the elongation zone were unchanged during rapid drying. During 14 d of gradual drying (in containers with a 6-cm depth of vermiculite), root mortality was relatively low; the length of the elongation zone decreased by 70%, the number of meristematic cells decreased 30%, and the duration of the cell cycle increased by 36%. Root hydraulic conductivity ( L _P) decreased to one half during both drying treatments; L _P was restored by 2 d of rewetting owing to the emergence of lateral roots following rapid drying and to renewed apical elongation following gradual drying. Thus, in response to drought, the apical meristems of roots of O. ficus-indica near the surface die, whereas deeper in the substrate cell division and elongation in root apices continue. Water uptake in response to rainfall in the field can be enhanced by lateral root proliferation near the soil surface and additionally by resumption of apical growth for deeper roots.     

Cell Cycle Duration in the Root Meristem of Sonoran Desert Cactaceae as Estimated by Cell-flow and Rate-of-cell-production Methods

Slow rates of cactus growth in the Sonoran Desert and high productivityof some Cactaceae under cultivation suggest that relativelylow growth rates are not the consequence of a long cell divisioncycle but of short optimal periods for growth and adverse environmentalfactors. To verify this hypothesis, the duration of the celldivision cycle (T)in the root apical meristem of seedlings ofthree sympatric species from the Sonoran Desert [Ferocactuspeninsulae(F. A. C. Weber) Britton & Rose ‘Townsendianus’(Britton & Rose) N. P. Taylor, stat. nov.,Stenocereus gummosus(Engelm.)Gibson & Horak andPachycereus pringlei(S. Watson) Britton& Rose] was estimated with the rate-of-cell-production (RCP)and the cell-flow (colchicine) methods. Both methods were appliedduring the steady-state growth phase, which was relatively shortin the first two species because of the determinate patternof root growth. The RCP method permitted estimation ofTin eachroot individually. Durations of the cell division cycle wereinversely proportional to the rate of root growth (r²rangedfrom 0.42 to 0.88,P<0.05).T,determined by the cell-flow method,ranged from 14.4 to 19.3 h in these species and was within thesame range asTdetermined by the RCP method. The averageTdeterminedby the RCP method was 67 to 75% of that determined by the cell-flowmethod. Results obtained with both methods are compared andanalysed. The proposed hypothesis appears to be correct, indicatingthat these species can be more productive under cultivationthan in the wild due to the relatively short duration of thecell division cycle. Adaptive features of these findings arealso considered.Copyright 1998 Annals of Botany Company Cactaceae, cell division cycle, root growth, root meristem, Sonoran Desert     

Efficacy of algal metrics for assessing nutrient and organic enrichment in flowing waters

1. Algal-community metrics were calculated for periphyton samples collected from 976 streams and rivers by the U.S. Geological Survey's National Water-Quality Assessment (NAWQA) Programme during 1993–2001 to evaluate national and regional relations with water chemistry and to compare whether algal-metric values differ significantly among undeveloped and developed land-use classifications.
2. Algal metrics with significant positive correlations with nutrient concentrations included indicators of trophic condition, organic enrichment, salinity, motility and taxa richness. The relative abundance of nitrogen-fixing algae was negatively correlated with nitrogen concentrations, and the abundance of diatom species associated with high dissolved oxygen concentrations was negatively correlated with both nitrogen and phosphorus concentrations. Median algal-metric values and nutrient concentrations were significantly lower at undeveloped sites than those draining agricultural or urban catchments.
3. Total algal biovolume did not differ significantly among major river catchments or land-use classifications, and was only weakly correlated with nitrate (positive) and suspended-sediment (negative) concentrations. Estimates of periphyton chlorophyll a indicated an oligotrophic–mesotrophic boundary of about 21 mg m⁻² and a mesotrophic–eutrophic boundary of about 55 mg m⁻² based on upper and lower quartiles of the biovolume data distribution.
4. Although algal species tolerance to nutrient and organic enrichment is well documented, additional taxonomic and autecological research on sensitive, endemic algal species would further enhance water-quality assessments.