Fetal and infant head circumference sexual dimorphism in primates

Studies have shown that after controlling for the effects of body size on brain size, the brains of adult humans, rhesus monkeys, and chimpanzees differ in relative size, where males have a greater volume of cerebral tissue than females. We assess whether head circumference sexual dimorphism is present during early development by evaluating sex differences in relative head circumference in living fetuses and infants within the first year of life. Head circumference is used as a proxy for brain size in the fetus and infant. Femur length is used as a proxy for body length in the fetus. Ultrasonography was used to obtain fetal measures, and anthropometry was used to obtain postnatal measures in humans, rhesus monkeys, baboons, and common marmosets. We show that statistically significant but low levels of head circumference sexual dimorphism are present in humans, rhesus monkeys, and baboons in early life. On average, males have head circumferences about 2% larger than females of comparable femur/body length in humans, rhesus monkeys, and baboons. No evidence for head circumference sexual dimorphism in the common marmoset was found. Dimorphism was present across all body size ranges. We suggest that head circumference sexual dimorphism emerges largely postnatally and increases throughout maturation, particularly in humans who reach adult dimorphism values greater than the monkeys. We suggest that brain dimorphism is not likely to impose an additional energetic burden to the gestating or lactating mother. Finally, some of the problems with ascribing functional significance to brain size sexual dimorphism are discussed, and the energetic implications for brain size sexual dimorphism in infancy are assessed.     

Oils for Increased Efficacy of Metarhizium anisopliae to Control Whiteflies

The efficacy of Metarhizium anisopliae in combination with sublethal concentrations of oils and potassium-oleate for biological control of whiteflies was tested under controlled conditions. Three commercial products (Biola ® , Naturen ® , Neudosan ® ) and five experimental formulations of plant oils were tested. The efficacy of M. anisopliae against Trialeurodes vaporariorum and Bemisia tabaci without additives was about 50%. At 1/20 of their recommended dosages, all compounds tested significantly increased the efficacy of M. anisopliae for the control of T. vaporariorum , with the formulated sunflower oil Biola ® giving the highest synergistic effect, reaching nearly 100% control. Not only was the level of control increased but also the speed of action was improved, resulting in a higher reliability of control. Three of seven additives showed no effects on the viability of conidia on the leaf surface, whereas the formulations of the other oils and oleates reduced the longevity of spores. The synergistic effect of Biola resulted from the more even distribution of M. anisopliae conidia on leaves and insects. Other positive effects of oils on the efficacy of M. anisopliae are discussed in relation to an extended spectrum of environmental conditions and pests to be controlled.     

Spatially Resolved Sulphur K-edge XANES Spectroscopy for in situ Characterization of the Fungus–plant Interaction Puccinia triticina and Wheat Leaves

An innovative application of X‐ray absorption near edge structure (XANES) spectroscopy for the characterization of interactions of biotrophic plant pathogens with their hosts as exemplified by Puccinia triticina colonizing wheat leaves is described. Spatially resolved, synchrotron radiation‐based XANES spectroscopy was used for the detection of changes in sulphur metabolism induced by leaf rust infections. A significant accumulation of sulphate occurred at the site of the sporulating urediniosori of P. triticina. Compared with non‐infected leaf areas, minor changes in the spectra were observed for the non‐visibly colonized tissue neighbouring the rust sori. As the spectra for isolated urediniospores and the healthy leaf areas did not match the spectra of the urediniosori, a significant impact of the biotrophic pathogen on sulphur metabolism of wheat has been demonstrated. Spatially resolved XANES spectroscopy will extend the range of qualitative and quantitative methods for in situ investigations of host–pathogen interactions, thus contributing to enlarge our knowledge about the metabolism of diseased plants.     

Impact of growth conditions on the occurrence of<Emphasis Type="Italic">Fusarium</Emphasis> spp. and the mycotoxin content of wheat

In 1997–99 the occurrence ofFusarium spp. on winter wheat and the contamination with mycotoxins was investigated at three locations in the Rhineland, Germany. All cultivation methods investigated had an effect on the level ofFusarium infection, however, rainfall during flowering was the most important factor. The choice of cultivar and soil cultivation proved to be the most promising tools to reduce head scab severity and mycotoxin contamination.     

Significance of different inoculum sources for the Fusarium infection of wheat ears

From 1997 to 1999 the occurrence ofFusarium spp. on wheat grain and its contamination with the mycotoxins deoxynivalenol and invalenol were investigated under organic farming conditions in the Rhineland, Germany. For comparison, some trials were also run under integrated farming conditions. The importance of the seed contamination withFusarium spp. as well as the impact of farming system, previous crop and soil preparation on the inoculum sources ofFusarium spp. in the soil were investigated. The data on the inoculum sources was compared to the Fusarium infection of grains and their content of DON and NIV. The crop residues in the soil were the most important inoculum source for the Fusarium species infecting wheat ears and grains. The amount of potential inoculum in the soil largely depended on the previous crop and the system of soil preparation.     

Microbiological and Sybr® Green real-time PCR detection of major Fusarium head blight pathogens on wheat ears

Fusarium head blight (FHB) caused by several Fusarium species is one of the most serious diseases affecting wheat throughout the world. The efficiency of microbiological assays and real-time PCR to quantify major FHB pathogens in wheat ears after inoculation with F. graminearum, F. culmorum, F. avenaceum and F. poae under greenhouse and field conditions were evaluated. The frequency of infected kernel, content of fungal biomass, disease severity and kernel weight were determined. To measure the fungal biomass an improved DNA extraction method and a Sybr® Green real-time PCR were developed. The Sybr® Green real-time PCR proved to be highly specific for individual detection of the species in a matrix including fungal and plant DNA. The effect of Fusarium infection on visible FHB severity, frequency of infected kernels and thousand-kernel mass (TKM) significantly depended on the Fusarium species/isolate. F. graminearum resulted in highest disease level, frequency of infected kernels, content of fungal biomass, and TKM reduction followed by F. culmorum, F. avenaceum and F. poae, respectively. The comparison of frequency and intensity of kernel colonization proved differences in aggressiveness and development of the fungi in the kernels. Only for F. graminearum, the most aggressive isolate, application of microbiological and real-time PCR assays gave similar results. For the other species, the intensity of kernel colonization was lower than expected from the frequency of infection.     

Thermal imaging of cucumber leaves affected by downy mildew and environmental conditions

Pathogenesis of Pseudoperonospora cubensis causing downy mildew of cucumber resulted in changes in the metabolic processes within cucumber leaves including the transpiration rate. Due to the negative correlation between transpiration rate and leaf temperature, digital infrared thermography permitted a non-invasive monitoring and an indirect visualization of downy mildew development. Depending on the stage of pathogenesis and the topology of chloroses and necroses, infection resulted in a typical temperature pattern. Spatial heterogeneity of the leaf temperature could be quantified by the maximum temperature difference (MTD) within a leaf. The MTD increased during pathogenesis with the formation of necrotic tissue and was related to disease severity as described by linear and quadratic regression curves. Under controlled conditions, changes in temperature of infected leaves allowed the discrimination between healthy and infected areas in thermograms, even before visible symptoms of downy mildew appeared. Environmental conditions during thermographic measurement, in particular air temperature and humidity, as well as water content and age of the leaf influenced the temperature of its surface. Conditions enhancing the transpiration rate facilitated the detection of changes in leaf temperature of infected leaves at early stages of infection. As modified by environmental conditions, MTD alone is not suitable for the quantification of downy mildew severity in the field.     

Diurnal variation of salivary cortisol in captive African elephants (Loxodonta africana) under routine management conditions and in relation to a translocation event

The present study assessed the diurnal variation in salivary cortisol in captive African elephants during routine management (baseline) and in relation to a potential stressor (translocation) to evaluate to what extent acute stress may affect diurnal cortisol patterns. Under baseline conditions, we collected morning and afternoon saliva samples of 10 animals (three zoos) on different days in two study periods (n = 3–10 per animal, daytime and period). Under stress conditions, we sampled the transported cow (newcomer) and the two cows of the destination zoo before and after the transport in the morning and afternoon (n = 3–9 per animal, daytime and transport phase), as well as after the first introduction of the newcomer to the bull (n = 1 per animal). Cortisol was measured in unextracted samples by enzyme immunoassay. Under baseline conditions, we observed the expected diurnal variation with higher cortisol levels in the morning than in the afternoon. Under stress conditions, neither a significant difference between pre- and posttransport, nor between morning and afternoon levels was found. The percentage difference between morning and afternoon cortisol after the transport, however, was remarkably lower than before the transport in the newcomer potentially indicating a stress response to familiarization. Saliva samples taken immediately after the introduction of the newcomer to the bull revealed a marked cortisol increase. Our findings indicate that stressors may disturb the diurnal cortisol rhythm. Furthermore, provided that samples can be collected promptly, salivary cortisol is a useful minimally invasive measure of physiological stress in the African elephant.     

Nuclear magnetic resonance: a tool for imaging belowground damage caused by Heterodera schachtii and Rhizoctonia solani on sugar beet

Belowground symptoms of sugar beet caused by the beet cyst nematode (BCN) Heterodera schachtii include the development of compensatory secondary roots and beet deformity, which, thus far, could only be assessed by destructively removing the entire root systems from the soil. Similarly, the symptoms of Rhizoctonia crown and root rot (RCRR) caused by infections of the soil-borne basidiomycete Rhizoctonia solani require the same invasive approach for identification. Here nuclear magnetic resonance imaging (MRI) was used for the non-invasive detection of belowground symptoms caused by BCN and/or RCRR on sugar beet. Excessive lateral root development and beet deformation of plants infected by BCN was obvious 28 days after inoculation (dai) on MRI images when compared with non-infected plants. Three-dimensional images recorded at 56 dai showed BCN cysts attached to the roots in the soil. RCRR was visualized by a lower intensity of the MRI signal at sites where rotting occurred. The disease complex of both organisms together resulted in RCRR development at the site of nematode penetration. Damage analysis of sugar beet plants inoculated with both pathogens indicated a synergistic relationship, which may result from direct and indirect interactions. Nuclear MRI of plants may provide valuable, new insight into the development of pathogens infecting plants below- and aboveground because of its non-destructive nature and the sufficiently high spatial resolution of the method.