The drift distances and time spent in the drift by freshwater shrimps, Gammarus pulex, in a small stony stream, and their implications for the interpretation of downstream dispersal

1. The objectives were (i) to determine experimentally and to model the relationship between mean water velocity and both the mean distance travelled, and the mean time spent, in the drift by freshwater shrimps, Gammarus pulex; (ii) to develop a drift distance–water velocity model from the experimental study, and validate it with field data; (iii) to examine the relationship between drift rate, water velocity and benthic density with the latter expressed as a mean value for the whole stream and a mean value corrected for the distance travelled in the drift. 2. In field experiments at 10 water velocities (0.032–0.962 m s^?1), the significant relationship between the mean drift distance and mean water velocity was described both by a power function (power, 0.96) and a linear relationship. The mean drift time was fairly constant at 8.3 s (95% CL ± 0.4). A simple model estimated the drift distance and time spent in the drift by different percentages of the drifting invertebrates. This model predicted correctly the positive relationship between drift rate and water velocity for field data over a year. 3. The relationship between drift rate per hour and the independent variables, water velocity and benthic density, was well described by a multiple‐regression model. Adding temperature and date did not improve model fit. Variations in water velocity and benthic density explained 96% of the variation in nocturnal drift rate (65% to velocity, 31% to benthic density), but only 40% of the variation in diurnal drift rate (29% to velocity, 11% to benthic density). Correcting benthic density for the drift distances did not improve model fit. 4. The significance of this study is that it developed models to predict drift distances and time, values being similar to those obtained in another, larger stream. It also illustrated the importance of spatial scale in the interpretation of drift by showing that when drift distances were taken into account, the impact of drift on the population was higher (4–10% lost day^?1) than when drift distances were ignored (usually < 3% lost day^?1), especially at a local level.     

Increases in lake phytoplankton biomass caused by future climate‐driven changes to seasonal river flow

For the many lakes world‐wide with short residence times, changes to the rate of water throughput may have important effects on lake ecology. We studied relationships between current and predicted residence times and phytoplankton biomass using a eutrophic lake in the north‐west of England with an annual residence time averaging about 20 days, as a test case. Using 32 years of recent hydrological flow data for Bassenthwaite Lake, multiple sets of scaled flow for each year, and the process‐based phytoplankton response model, PROTECH, we modelled the effects of changing river flow on phytoplankton biomass in the lake. The impact on biomass was shown to depend on seasonal changes in flow rather than annual changes. Furthermore, there was a qualitative difference in impact depending on whether the nutrient loading to the lake came principally from flow‐independent sources, or from flow‐dependent ones. Predictions for changes in river flow under future climate scenarios in the north‐west of England have suggested that, despite little change in the annual flow magnitude, there will be a shift to greater flow in the winter and lesser flow in the summer. Applying these flow predictions to our modelling of Bassenthwaite Lake revealed that, with flow‐independent nutrient loading, and no overall increase in nutrient load, phytoplankton abundance in the summer could increase by up to 70%, including an increased proportion of Cyanobacteria. Conversely, were the loading completely dependent on the flow, the biomass would fall. In many parts of the world, river flow is expected to decrease in the summer even more than in England, suggesting these areas may expect substantial changes to seasonal phytoplankton biomass as a result of climate‐driven changes to seasonal river flow. Such changes would be in addition to any other changes owing to warming effects or eutrophication.     

A Response Surface Analysis of the Effects of Cyclohexanecarboxylic Acid and 2,4-Dichlorophenoxy Acetic Acid on Nitrogen Metabolism in Phaseolus vulgaris L.

Primary leaves of 2-week-old bush bean plants (Phaseolus vulgariscv ‘Top Crop’) were treated with one of 36 combinationsof cyclohexanecarboxylic acid (CHCA) and 2,4-dichlorophenoxyacetic acid (2,4-D), each at six equally spaced concentrationsFive, 7, 9 and 11 days after treatment, one plant from eachcombination was harvested, and primary leaves were monitoredfor nitrate reductase activity (NRA), nitrate nitrogen (N) concentration,organic N concentration, and d wt NRA was assayed by an in vivoprocedure Data from the resulting 6 x 6 x 4 factorial configuration foreach of the four responses were analysed using the method oforthogonal polynomials, which is described in detail This method,based on equally spaced levels, produced independent polynomialexpressions in CHCA concentration, 2,4-D concentration, and/ortime-to-harvest after treatment, which were then fitted to thedata on each response by simple linear regression analyses.A graphical procedure was used to compare predicted responsesfrom the best fit equations with the actual data. Examination of computer-generated plots of the three-dimensionalresponse surfaces revealed that NRA, organic N concentration,and d wt decreased with increasing 2,4-D concentration, whereasnitrate N content increased Increasing CHCA concentration generallyhad the opposite effect on NRA and nitrate N content, althoughinteraction between the two chemicals was evident in the latterresponse Organic N content remained unchanged as CHCA concentrationincreased, while d wt first increased then decreased Possibleexplanations for these results are discussed, as are the advantagesof using factorial designs with equally-spaced levels in plantgrowth studies. Phaseolus vulgaris L, bush bean, nitrogen metabolism, plant growth regulators, cyclohexanecarboxylic acid, 2,4-dichlorophenoxy acetic acid, regression analysis, orthogonal polynomials, response surfaces analysis     

House Finch Carpodacus mexicanus roosting behaviour during the non-breeding season and possible effects of mycoplasmal conjunctivitis

We studied House Finch Carpodacus mexicanus roosting behaviour during the non-breeding season using radiotracking and direct observations in Ithaca, NY, USA. In contrast to what has been reported in the literature and in contrast to what should be expected from Newton's European studies of cardueline finches, House Finches roost in small groups (mean 3.5; maximum 11) and do not display at roost sites. Seventy-seven per cent of the birds re-used the same tree on successive observations. In winter, birds re-used the same roost tree more often than in the autumn, and birds with mycoplasmal conjunctivitis tended to move more between roost trees than did birds without conjunctivitis. A small number of radiotagged birds that roosted in the same tree were observed together in the daytime more often than by chance, suggesting the existence of social bonds between birds (some same sex) during the non-breeding season. In the autumn the birds often roosted in leafed deciduous trees and closer to their daytime feeding locations than they did in winter. In winter all birds roosted in evergreen trees. It is possible that the reliable and predictable food sources at feeding sites offered by the public might have changed House Finch roosting behaviour.