Gene targeting: attention to detail

When it comes to silencing genes in mice, not all approaches are equal. An example published in this issue of Cell (Patrucco et al., 2004) suggests that caution should be used when validating potential drug targets by genetic disruption.     

Orienting reaction, organizing for action, and emotional processes

In the first half of the sixties, general notions were formulated concerning the functional role of the orienting reaction (OR) in adaptive activity, its elicitation and habituation. These notions included the following: a) The OR is elicited only by significant changes in a situation. This implies that OR elicitation is preceded by brain processes (usually unconscious) pertaining to the evaluation of the significance of changes according to an existing hierarchy of motivations, attitudes, and goals. Therefore, the OR is of an active (vs. reactive) nature, i.e., is inevitably determined by internal factors of brain activity. b) The OR is not a unitary reaction, but a complex polyfunctional activity, different aspects of which are reflected in different OR components which can be modified rather independently. c) The OR represents the processes of organizing new (non-standard) actions: sensory, motor, or intellectual. OR habituation is a manifestation of attenuation of the active control of an action, and an increase in its automation. Thus, the emphasis in understanding the OR has shifted from a predominantly "sensualistic" platform to a predominantly "actualistic" one. In recent experiments, the role of emotional processes in the elicitation and habituation of components of the OR has been analyzed. Complex relations between the GSR and anxiety were found in a study of patients with acute alcohol withdrawal syndrome treated with different psychopharmacological agents. The study of auditory evoked potential habituation in depressive patients has shown the emotional state influence on sensory aspects of the OR with the participation of the OR brain mechanisms in perceptual defense.(ABSTRACT TRUNCATED AT 250 WORDS)     

Neural network modelling of the influence of channelopathies on reflex visual attention

This paper introduces a model of Emergent Visual Attention in presence of calcium channelopathy (EVAC). By modelling channelopathy, EVAC constitutes an effort towards identifying the possible causes of autism. The network structure embodies the dual pathways model of cortical processing of visual input, with reflex attention as an emergent property of neural interactions. EVAC extends existing work by introducing attention shift in a larger-scale network and applying a phenomenological model of channelopathy. In presence of a distractor, the channelopathic network’s rate of failure to shift attention is lower than the control network’s, but overall, the control network exhibits a lower classification error rate. The simulation results also show differences in task-relative reaction times between control and channelopathic networks. The attention shift timings inferred from the model are consistent with studies of attention shift in autistic children.     

Different neurophysiological mechanisms underlying delayed reaction and trace conditioned reflex

Electrophysiological study of functional interactions of the prefrontal cortex, the hippocampus, the head of the caudate nucleus and the thalamic medio-dorsal nucleus in 2 monkeys in conditions of the trace reflex and delayed reaction has revealed various morphofunctional systems for these types of memory. The morphofunctional system of the trace CR is characterized by greater stability and a small number of functional connections (21%) in contrast to the dynamic morphofunctional system with a considerable percentage of functional contacts (54%) in case of the delayed reaction. This difference can be very likely related to the different dynamics of functional connections between brain structures rather than to the involvement of various brain structures.     

Orienting axon growth: spinal nerve segmentation and surround-repulsion

The study of spinal nerve trajectories in higher vertebrate embryos has revealed an inherent polarity within somites along the antero-posterior axis, and provides a simple system in which to study the factors that influence axon pathfinding. We argue that the orientation of spinal axons is determined by the simultaneous operation of two distinct guidance mechanisms, contact repulsion and chemorepulsion. Motor and sensory axons traverse the anterior half of each somite because they are excluded by contact repulsion from the posterior half-somite, and the molecular nature of several candidate contact repellents is reviewed. In contrast, we find that the dorsoventral trajectory of primary sensory axons is oriented by diffusible repellents originating from the notochord medially and dermamyotome laterally. In this system, therefore, repulsion by surrounding tissues ('surround-repulsion') is the main force directing axon growth in three dimensions.