Re-evaluation of the prospects of marker-assisted selection for improving insect resistance against Diatraea spp. in tropical maize by cross validation and independent validation

Cross validation (CV) and validation with an independent sample (IV) are new biometric approaches in QTL analysis to obtain unbiased estimates of QTL effects and the proportion of the genetic variance explained by the detected marker-QTL association (p). Our objective with these methods was to obtain a realistic picture on the prospects of marker-assisted selection (MAS) for improving the resistance of maize against the tropical stem borer species Diatraea grandiosella (SWCB) and Diatraea saccharalis (SCB). Published QTL mapping studies on leaf-damage ratings (LDR) with populations of F_2:3 lines and recombinant inbred lines (RIL) from crosses CML131×CML67 and Ki3× CML139 of tropical maize inbreds were re-analyzed with CV and IV. With CV, the reduction in p for LDR compared to p obtained with the whole data set varied between 41.0 and 79.6% in the populations of F_2:3 lines and between 30.1 and 65.2% in the two populations of RIL. Estimates of p for SCB LDR were similar for CV and IV. For SWCB LDR, p estimates obtained with IV were larger than those obtained with CV in CML131× CML67. The reverse was observed for Ki3×CML139. Under the assumption of identical selection intensities, and based on the re-estimates of p, MAS using only molecular marker information is less-efficient than conventional phenotypic selection (CPS). MAS combining marker and phenotypic data increases the relative efficiency by only 4% in comparison to CPS. In conclusion, MAS for improving SWCB and SCB LDR seems not-promising unless additional QTLs with proven large effects are available or the costs of marker assays are considerably reduced. Received: 7 December 2000 / Accepted: 5 February 2001     

Development of enzyme-immunoassays based on egg yolk antibodies for the detection of mycotoxins

Enzyme-linked immunosorbent assays (ELISA) proved to be a fast and simple method for the detection of mycotoxins and other undesired contaminants in food and feed. The present study is focused on the optimisation and exploitation of the egg yolk antibody technology in order to develop competitive ELISAs for the detection of mycotoxins in cereals. Due to its importance as one of the most relevant Fusarium mycotoxins, the trichothecene deoxynivalenol (DON) was selected as representative. Chickens were immunised with different protein conjugates performing varying booster intervals. The antibodies were isolated by the poly(ethylene glycol) precipitation method according to Polson. By use of these antibodies an indirect competitive ELISA was developed for the detection of DON. First investigations of naturally contaminated wheat samples showed a good correspondence with results obtained by GC-ECD when calibration in blank wheat extracts was performed.     

Two models for transforming auditory signals from head-centered to eye-centered coordinates

Two models for transforming auditory signals from head-centered to eye-centered coordinates are presented. The vector subtraction model subtracts a rate-coded eye position signal from a topographically weighted auditory target position signal to produce a rate-code of target location with respect to the eye. The rate-code is converted into a place-code through a graded synaptic weighting scheme and inhibition. The dendrite model performs a mapping of head-centered auditory space onto the dendrites of eye-centered units. Individual dendrites serve as logical comparators of target location and eye position. Both models produce a topographic map of auditory space in eye-centered coordinates like that found in the primate superior colliculus. Either type can be converted into a model for transforming visual signals from retinal to head-centered coordinates.     

Western Diet Triggers NLRP3-Dependent Innate Immune Reprogramming

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Highly Replicated Evolution of Parapatric Ecotypes

Parallel evolution of ecotypes occurs when selection independently drives the evolution of similar traits across similar environments. The multiple origins of ecotypes are often inferred based on a phylogeny that clusters populations according to geographic location and not by the environment they occupy. However, the use of phylogenies to infer parallel evolution in closely related populations is problematic because gene flow and incomplete lineage sorting can uncouple the genetic structure at neutral markers from the colonization history of populations. Here, we demonstrate multiple origins within ecotypes of an Australian wildflower, Senecio lautus. We observed strong genetic structure as well as phylogenetic clustering by geography and show that this is unlikely due to gene flow between parapatric ecotypes, which was surprisingly low. We further confirm this analytically by demonstrating that phylogenetic distortion due to gene flow often requires higher levels of migration than those observed in S. lautus. Our results imply that selection can repeatedly create similar phenotypes despite the perceived homogenizing effects of gene flow.     

Estrogen receptor subtype β2 is involved in neuromast development in zebrafish (Danio rerio) larvae

Estrogens are known to play a role in both reproductive and non-reproductive functions in mammals. Estrogens and their receptors are involved in the development of the central nervous system (brain development, neuronal survival and differentiation) as well as in the development of the peripheral nervous system (sensory-motor behaviors). In order to decipher possible functions of estrogens in early development of the zebrafish sensory system, we investigated the role of estrogen receptor β₂ (ERβ₂) by using a morpholino (MO) approach blocking erβ₂ RNA translation. We further investigated the development of lateral line organs by cell-specific labeling, which revealed a disrupted development of neuromasts in morphants. The supporting cells developed and migrated normally. Sensory hair cells, however, were absent in morphants' neuromasts. Microarray analysis and subsequent in situ hybridizations indicated an aberrant activation of the Notch signaling pathway in ERβ₂ morphants. We conclude that signaling via ERβ₂ is essential for hair cell development and may involve an interaction with the Notch signaling pathway during cell fate decision in the neuromast maturation process.     

Sarcoglycan Complex: IMPLICATIONS FOR METABOLIC DEFECTS IN MUSCULAR DYSTROPHIES*

The sarcoglycans are known as an integral subcomplex of the dystrophin glycoprotein complex, the function of which is best characterized in skeletal muscle in relation to muscular dystrophies. Here we demonstrate that the white adipocytes, which share a common precursor with the myocytes, express a cell-specific sarcoglycan complex containing β-, δ-, and ϵ-sarcoglycan. In addition, the adipose sarcoglycan complex associates with sarcospan and laminin binding dystroglycan. Using multiple sarcoglycan null mouse models, we show that loss of α-sarcoglycan has no consequence on the expression of the adipocyte sarcoglycan complex. However, loss of β- or δ-sarcoglycan leads to a concomitant loss of the sarcoglycan complex as well as sarcospan and a dramatic reduction in dystroglycan in adipocytes. We further demonstrate that β-sarcoglycan null mice, which lack the sarcoglycan complex in adipose tissue and skeletal muscle, are glucose-intolerant and exhibit whole body insulin resistance specifically due to impaired insulin-stimulated glucose uptake in skeletal muscles. Thus, our data demonstrate a novel function of the sarcoglycan complex in whole body glucose homeostasis and skeletal muscle metabolism, suggesting that the impairment of the skeletal muscle metabolism influences the pathogenesis of muscular dystrophy.Muscle fat infiltration is recognized as a hallmark pathological feature in dystrophin glycoprotein complex (DGC)³-related muscular dystrophies (1) that include dystrophinopathies (2, 3) and sarcoglycanopathies (LGMD2C-F) (4). In agreement, magnetic resonance imaging measurements of fat infiltration allow accurate assessments of disease severity in Duchenne muscular dystrophy patients (3). Association of adipose tissue development with degenerative/regenerative or atrophic changes in skeletal muscle is also supported by the finding that adipogenesis-competent cells within the skeletal muscle are activated during muscle regeneration (5). However, the molecular mechanism(s) underlying muscle fatty metamorphosis remain unclear.Ectopic fat deposition in skeletal muscles is primarily described in animals and humans with lipodystrophy and sarcopenia. In these conditions, the accumulation of lipids and adipocytes in skeletal muscle is often accompanied by hyperglycemia and insulin resistance (6–11), both of which are strong indicators of muscle metabolic defects (12, 13) and deregulated adipogenesis (14). Furthermore, both adipose-derived and muscle-derived stem cells differentiate into adipocytes upon exposure to high levels of glucose (15), linking impaired muscle metabolism with muscle fat deposition.It is long held that the biogenesis of a basement membrane takes place in the earliest steps of adipogenesis and that extensive extracellular matrix (ECM) remodeling occurs throughout adipogenesis (16, 17). The concept that cell surface receptors play a role in the regulation of adipogenesis and thus may underlie metabolic disorders just recently emerged with a study of the integrin complexes (18). Given that the DGC in its capacity as an ECM receptor is critical for muscle integrity (19, 20) and that white adipocytes and skeletal muscle cells originate from the same mesenchymal precursor cells (21, 22), we set out to determine whether components of the skeletal muscle DGC are expressed in white adipocytes. Herein, we describe a unique adipose sarcoglycan (SG) complex that includes β-, δ-, and ϵ-SG. This complex is tightly associated with sarcospan (Sspn) and dystroglycan (DG). Moreover, we show that DG functions as a novel ECM receptor in white adipocytes. Because adipose tissue and skeletal muscle play critical roles in the maintenance of normal glucose homeostasis and whole body insulin sensitivity (23), we examined the metabolic consequences of the SG complex disruption in both adipose tissue and skeletal muscle. Using in vivo approaches, we observed that the β-SG null mouse (24), a mouse model of muscular dystrophy, is glucose-intolerant and exhibits whole body insulin resistance specifically due to impaired insulin-stimulated glucose uptake in skeletal muscle.     

Seeing sounds: visual and auditory interactions in the brain

Objects and events can often be detected by more than one sensory system. Interactions between sensory systems can offer numerous benefits for the accuracy and completeness of the perception. Recent studies involving visual-auditory interactions have highlighted the perceptual advantages of combining information from these two modalities and have suggested that predominantly unimodal brain regions play a role in multisensory processing.