Attendance of general practitioners at child protection case conferences.

OBJECTIVE--To investigate general practitioners'' attendance at and views on child protection conferences and their confidence in dealing with sexual abuse in children. DESIGN--Anonymous postal questionnaire sent to all general practitioners in Tower Hamlets and review of consecutive case conferences held by social services for three months in 1989. SETTING--Tower Hamlets health district. SUBJECTS--91 general practitioners, 56 of whom (62%) responded. MAIN OUTCOME MEASURES--Number of conferences attended, reasons for non-attendance, and reported confidence in dealing with sexual abuse. RESULTS--General practitioners estimated that 202 child protection conferences had been held in 1989 on their patients and that they had attended 85 of these. Information from social services for three months suggested that general practitioners had attended only nine of the 114 conferences reviewed. Timing of the conference was the most important reason for non-attendance. All respondents wanted access to the minutes of these conferences irrespective of their own attendance. Most general practitioners were very or moderately confident of their ability to detect child sexual abuse and non-accidental injury and to communicate with the family. CONCLUSION--More effort should be made to ensure that general practitioners are notified of case conferences and that the timing and location of conferences is compatible with their other commitments.     

Salinity Reduces Water Use and Nitrate-N-use Efficiency of Citrus

Five-month-old Cleopatra mandarin (Citrus reticulata Blanco)(CM) and Volkamer lemon (Citrus volkameriana Ten. and Pasq.)(VL) seedlings were grown in a glasshouse in 2·3-1 potsof Candler fine sand. Plants were irrigated with either non-saline(EC_e = 0·23 dS m^-1) or saline (6·13 dS m^-1) waterusing 3:1 NaCl:CaCl₂ solution over a 4-week period. A singleapplication of K¹⁵NO₃ (19·64 atom % excess ¹⁵N) at 212mg N1^-1, was substituted for a normal weekly fertilization after3 weeks and plants were harvested 7 d later. The transpirationrate, uptake of nitrogen, growth and nitrogen-use efficiency(NUE) on a dry weight basis (mg d. wt mg^-1 N) of both specieswas reduced by salinity. Based on growth, water-use and chloride(Cl) accumulation in leaves, VL was more salt-sensitive thanCM, but ¹⁵N uptake was equally reduced by salinity in both species.Salinity reduced ¹⁵N uptake relatively more than shoot growthover the 7-d period, such that the ¹⁵NUE (mg d. wt µg^-115N) of new shoot growth of both species increased. There wasno evidence of Cl antagonism of nitrate (NO₃) uptake but totalplant ¹⁵NO₃ uptake was positively correlated with whole planttranspiration in both species. Thus, it appears that reductionsin NO₃ uptake are more strongly related to reduced water usethan to Cl antagonism from salt stress.Copyright 1993, 1999Academic Press Sodium, chloride, salinity, calcium, nitrate, ¹⁵NO₃ uptake, nitrogen allocation, nitrogen-use efficiency, water use, Citrus reticulata, Citrus volkameriana     

Phytophthora aquimorbida sp. nov. and Phytophthora taxon 'aquatilis' recovered from irrigation reservoirs and a stream in Virginia, USA

Two distinct subgroups (L2 and A(-2)) were recovered from irrigation reservoirs and a stream in Virginia, USA. After molecular, morphological and physiological examinations, the L2 subgroup was named Phytophthora aquimorbida and the A(-2) designated as Phytophthora taxon 'aquatilis'. Both taxa are homothallic. P. aquimorbida is characterized by its noncaducous and nonpapillate sporangia, catenulate and radiating hyphal swellings and thick-walled plerotic oospores formed in globose oogonia mostly in the absence of an antheridium. P. taxon 'aquatilis' produces plerotic oospores in globose oogonia mostly with a paragynous antheridium. It has semi-papillate, caducous sporangia with variable pedicels, but it does not have hyphal swelling. Analyses of ITS, CO1, β-tubulin and NADH1 sequences revealed that P. aquimorbida is closely related to P. hydropathica, P. irrigata and P. parsiana, and P. taxon 'aquatilis' is related to P. multivesiculata. The optimum temperature for culture growth is 30 and 20 C for P. aquimorbida and P. taxon 'aquatilis' respectively. Both taxa were pathogenic to rhododendron plants and caused root discoloration, pale leaves, wilting, tip necrosis and dieback. Their plant biosecurity risk also is discussed.     

Zoosporic Tolerance to pH Stress and Its Implications for Phytophthora Species in Aquatic Ecosystems

Phytophthora species, a group of destructive plant pathogens, are commonly referred to as water molds, but little is known about their aquatic ecology. Here we show the effect of pH on zoospore survival of seven Phytophthora species commonly isolated from irrigation reservoirs and natural waterways and dissect zoospore survival strategy. Zoospores were incubated in a basal salt liquid medium at pH 3 to 11 for up to 7 days and then plated on a selective medium to determine their survival. The optimal pHs differed among Phytophthora species, with the optimal pH for P. citricola at pH 9, the optimal pH for P. tropicalis at pH 5, and the optimal pH for the five other species, P. citrophthora, P. insolita, P. irrigata, P. megasperma, and P. nicotianae, at pH 7. The greatest number of colonies was recovered from zoospores of all species plated immediately after being exposed to different levels of pH. At pH 5 to 11, the recovery rate decreased sharply (P ≤ 0.0472) after 1-day exposure for five of the seven species. In contrast, no change occurred (P ≥ 0.1125) in the recovery of any species even after a 7-day exposure at pH 3. Overall, P. megasperma and P. citricola survived longer at higher rates in a wider range of pHs than other species did. These results are generally applicable to field conditions as indicated by additional examination of P. citrophthora and P. megasperma in irrigation water at different levels of pH. These results challenge the notion that all Phytophthora species inhabit aquatic environments as water molds and have significant implications in the management of plant diseases resulting from waterborne microbial contamination.Phytophthora species, a group of oomycetes in the kingdom of Stramenopila and well-known plant pathogens, were first listed as “water molds” by Blackwell in 1944 (5), and this notion has since been generally accepted. These species are phylogenetically close to golden-brown algae, although morphologically and physiologically, they resemble fungi. Most algae are aquatic in nature. Phytophthora species produce flagellate zoospores as their primary dispersal structure (35-37, 39). Zoospores can travel in aquatic environments actively on their own locomotion and passively through water movement (12, 13, 41).More than 20 species of Phytophthora, including P. ramorum, the sudden oak death pathogen, have been isolated from irrigation reservoirs and natural waterways (20-22, 30, 40, 43), and a number of previously unknown taxa also have been documented in aquatic environments (8, 24). These pathogens pose a threat to agricultural sustainability and natural ecosystems, as agriculture increasingly depends on recycled water for irrigation in light of rapidly spreading global water scarcity (19, 22). Recycling irrigation systems provide an efficient means of pathogen dissemination from a single point of infection to an entire farm and from a single farm to other farms sharing the same water resources (22, 24).A search of science-based solutions to this crop health issue reveals a surprising lack of information on the aquatic ecology of Phytophthora species. For instance, hydrogen ion concentration (pH) is among the most important water quality parameters which influence sporangium production and germination (1-3, 6, 32, 34, 38), survival of thick-walled chlamydospores and oospores in the soil environment, and disease development (2, 4, 33, 44). However, the effect of pH on the survival of zoospores and growth of germlings in aquatic environments is not known. As motile zoospores lack cell walls and encysted spores or cysts have thin walls, they are presumably more vulnerable to pH stress than chlamydospores and oospores are. On the other hand, the pH level is likely to fluctuate more regularly and at a greater range in aquatic systems, such as irrigation reservoirs, than in soil systems. pH can change diurnally due to respiration of aquatic plants and seasonally due to rain, oxidation of sulfide-containing sediments through the production of sulfuric acid, algal blooms, and released bases or acids from residues of fertilizer and pesticides. Thus, zoospores and aquatic systems are more prone to the influence of wide pH changes than chlamydospores/oospores in soil systems are. The aim of this study was to determine the impact of pH on zoospore survival and understand the aquatic ecology of different Phytophthora species.