A cell-type-specific abnormality of cell proliferation in mutant (curly tail) mouse embryos developing spinal neural tube defects

The mouse mutant curly tail (ct) provides a model system for studies of neurulation mechanisms. 60% of ct/ct embryos develop spinal neural tube defects (NTD) as a result of delayed neurulation at the posterior neuropore whereas the remaining 40% of embryos develop normally. In order to investigate the role of cell proliferation during mouse neurulation, cell cycle parameters were studied in curly tail embryos developing spinal NTD and in their normally developing litter-mates. Measurements were made of mitotic index, median length of S-phase and percent reduction of labelling index during a [3H]thymidine pulse-chase experiment. These independent measures of cell proliferation rate indicate a reduced rate of proliferation of gut endoderm and notochord cells in the neuropore region of embryos developing spinal NTD compared with normally developing controls. The incidence of cell death and the relative frequency of mitotic spindle orientations does not differ consistently between normal and abnormal embryos. These results suggest a mechanism of spinal NTD pathogenesis in curly tail embryos based on failure of normal cell proliferation in gut endoderm and notochord.     

Visual control of turning responses to tactile stimuli in the crayfishProcambarus clarkii

Summary Specimens of the crayfishProcambarus clarkii turn to face in the direction of a brief tactile stimulus delivered to a walking leg. The control system that guides this directed behavior was investigated under closed-loop and open-loop conditions. The accuracy of turns exhibited in these experiments was compared to baseline accuracy established by animals restrained from forward and backward walking but allowed to rotate in the yaw plane. Procambarus clarkii individuals deprived of visual feedback tended to undershoot the target angle. Response accuracy increased when a uniform field of stripes moved across the visual field in accordance with the turning movements of the animal. Response accuracy did not match the accuracy observed under baseline conditions, however, unless the responding animal encountered a novel visual image, such as the silhouette of a crayfish, in the moving visual field.Visual feedback thus influences the accuracy of turning in crayfish in two important ways. Movement of stripes across the visual field of a crayfish feeds back positively and promotes rapid turning during the initial phase of a response. This effect obtains regardless of the direction or rate of movement of the stripes in the visual field. The appearance of a novel image in the visual field feeds back negatively to inhibit at least partially further turning. Feedback from the visual system appears to fine tune basic turning movements initiated by a tactile stimulus and crudely directed according to that input. Turning behavior in the crayfish resembles in this respect compensatory eye movements in the lobster and escape responses in a number of arthropods.Neural mechanisms that may explain the experimental results are discussed with particular emphasis on the possibility of interaction between voluntary turning responses and optomotor reactions.     

Ecology of fish spawning and nursery zones in the flood plain,using a new sampling approach

Horizontal zonation of fish reproduction, a lotic-to-lentic succession similar to that seen with increasing stream order, was evident from the relative abundance of larval and 0 + juvenile fishes in three floodplain spawning and nursery areas (lotic, semi-lotic, lentic) of the Upper Rhône River, France. Although the lotic and lentic ecosystems provided similar estimates of standing crop (0 + juveniles), differences were apparent in the reproductive and trophic guild structure of the YOY taxocoenoses at the three sites. A new sampling approach (Random Point-Abundance Sampling and modified electrofishing) is described for early-life fish ecology. The electrofishing method employed is mobile, effective for all sizes of larvae and 0 + juveniles of most species, quantitative, and applicable to a number of freshwater situations; and the punctual data resulting from this sampling approach are comparable both spatially and temporally.     

Shifts in the microhabitat of larval and juvenile roach, Rutilus rutilus (L.), in a floodplain channel

The microhabitat of roach larvae (stages L1–L6) and 0+ juveniles was examined in a braided channel (Ilon) of the Upper Rhone River, France, from weekly samples (spring-autumn 1985) using Point Abundance Sampling by electrofishing. During early development, microhabitat exploitation was characterized by two transitions: the first at larval step L3, when morphological and physiological attributes permit the active choice of microhabitat; the second at the end of the larval and start of the juvenile period. At larval step L3, and up to L5, roach were strongly associated with lentic waters of medium depth (0.5–1.0m) and with either macrophytes or ligneous debris. The L6 and 0+ juveniles were found more often than expected in shallower waters (< 0.2m, 0.2–0.5 m) and were no longer associated with dense vegetation or ligneous debris. However, both larval (L3–L6) and 0+ juvenile roach preferred silty sand and/or silted gravel, and a lack of current. This shift, from moderately deep waters with vegetation and/or branches as larvae to open shallow waters as juveniles, demonstrates the young roach's perception and response to environmental change, with shallows exploited as a refuge from predation when protective structures become scarce or unavailable.     

Calcium uptake by placental plasma membrane vesicles.

The placental plasma membrane vesicles are capable of accumulating up to 190 mM Ca2+. This is 24-fold higher than the external Ca2+ concentration. This process is dependent on ATP hydrolysis by the placental Ca2+-ATPase. The Pi/Ca ratio is dependent on the external Ca2+ concentration, and reaches the value of 2 at 10 mM Ca2+. Phosphate (5 mM) can double Ca2+ uptake when measured in the presence of 5 mM Ca2+. Mg2+ increased Ca2+ uptake only at low Ca2+ concentrations, and had no significant effect at 5 mM Ca2+.     

Predicting and mapping the risk of introduction of marine non-indigenous species into Great Britain and Ireland

Non-indigenous species (NIS) can have adverse environmental, economic and social impacts. Their management is now incorporated into key legislation, including the European Union (EU) Marine Strategy Framework Directive and the EU Regulation on the prevention and management of the introduction and spread of invasive alien species. Prevention of NIS introductions and the early detection of NIS following their introduction are recognised as the most effective approaches for reducing the potential impacts of NIS. This is true for most aquatic environments but especially so for the marine environment, where control and/or eradication are often not achievable. By assessing introduction vector activity, it is possible to identify coastal areas and specific locations where marine NIS may be more likely to be introduced. This study uses data relating to the activity of key introduction vectors; shipping, recreational boating and live animal aquaculture import, to estimate the relative risk of introduction of NIS around coastal regions of Great Britain and Ireland. Spatial analysis was used to create “heat” maps indicating coastal areas of increased relative risk of introduction of NIS by these vectors. The results of the present study will be crucial for the implementation of targeted vector management plans, supporting preventive strategies, and will facilitate a risk analyses of NIS threats to inform monitoring and surveillance programmes.     

Pathways of ornamental and aquarium fish introductions into urban ponds of Epping Forest (London,England): the human vector*

To examine the role of humans in the non‐native fish introductions, we measured the frequency of occurrence and density of non‐native fishes in ponds (Epping Forest, Essex, England) that had been restored (drained of water and voided of fish or treated with rotenone) on a known date and into which no piscivorous or non‐native fishes had subsequently been stocked intentionally. For each pond, the period of time since pond restoration, pond area, distance to nearest residential housing, distance to nearest footpath, distance to nearest water body or stream, and the proportion of pond vegetated were measured. The occurrence of both non‐native and unexpected native fish species was non‐random, and the number of ornamental varieties was found to increase as pond distance from the nearest road decreased. Variety richness of each of three categories of fish (non‐native, goldfish Carassius auratus and native) was significantly correlated with at least two of the following variables: distance from nearest road, nearest footpath and nearest pond. The rate of non‐native fish introductions (adjusted variety richness per year) could also be estimated from pond distance to the nearest road, being about 3.5 ornamental varieties introduced per year in ponds adjacent to roads, but the rate appears to be much greater in ponds that had recently (<1.5 years) undergone restoration. Implications for conservation and management, as well as the potential role of societal issues such as recreational activities, cultural and religious practices, are discussed.