Single units in the medial prefrontal cortex with anxiety-related firing patterns are preferentially influenced by ventral hippocampal activity

The medial prefrontal cortex (mPFC) and ventral hippocampus (vHPC) functionally interact during innate anxiety tasks. To explore the consequences of this interaction, we examined task-related firing of single units from the mPFC of mice exploring standard and modified versions of the elevated plus maze (EPM), an innate anxiety paradigm. Hippocampal local field potentials (LFPs) were simultaneously monitored. The population of mPFC units distinguished between safe and aversive locations within the maze, regardless of the nature of the anxiogenic stimulus. Strikingly, mPFC units with stronger task-related activity were more strongly coupled to theta-frequency activity in the vHPC LFP. Lastly, task-related activity was inversely correlated with behavioral measures of anxiety. These results clarify the role of the vHPC-mPFC circuit in innate anxiety and underscore how specific inputs may be involved in the generation of behaviorally relevant neural activity within the mPFC.     

Neural dynamics of the cognitive map in the hippocampus

The rodent hippocampus has been thought to represent the spatial environment as a cognitive map. In the classical theory, the cognitive map has been explained as a consequence of the fact that different spatial regions are assigned to different cell populations in the framework of rate coding. Recently, the relation between place cell firing and local field oscillation theta in terms of theta phase precession was experimentally discovered and suggested as a temporal coding mechanism leading to memory formation of behavioral sequences accompanied with asymmetric Hebbian plasticity. The cognitive map theory is apparently outside of the sequence memory view. Therefore, theoretical analysis is necessary to consider the biological neural dynamics for the sequence encoding of the memory of behavioral sequences, providing the cognitive map formation. In this article, we summarize the theoretical neural dynamics of the real-time sequence encoding by theta phase precession, called theta phase coding, and review a series of theoretical models with the theta phase coding that we previously reported. With respect to memory encoding functions, instantaneous memory formation of one-time experience was first demonstrated, and then the ability of integration of memories of behavioral sequences into a network of the cognitive map was shown. In terms of memory retrieval functions, theta phase coding enables the hippocampus to represent the spatial location in the current behavioral context even with ambiguous sensory input when multiple sequences were coded. Finally, for utilization, retrieved temporal sequences in the hippocampus can be available for action selection, through the process of reverting theta rhythm-dependent activities to information in the behavioral time scale. This theoretical approach allows us to investigate how the behavioral sequences are encoded, updated, retrieved and used in the hippocampus, as the real-time interaction with the external environment. It may indeed be the bridge to the episodic memory function in human hippocampus.     

Selection of preconfigured cell assemblies for representation of novel spatial experiences

Internal representations about the external world can be driven by the external stimuli or can be internally generated in their absence. It has been a matter of debate whether novel stimuli from the external world are instructive over the brain network to create de novo representations or, alternatively, are selecting from existing pre-representations hosted in preconfigured brain networks. The hippocampus is a brain area necessary for normal internally generated spatial–temporal representations and its dysfunctions have resulted in anterograde amnesia, impaired imagining of new experiences, and hallucinations. The compressed temporal sequence of place cell activity in the rodent hippocampus serves as an animal model of internal representation of the external space. Based on our recent results on the phenomenon of novel place cell sequence preplay, we submit that the place cell sequence of a novel spatial experience is determined, in part, by a selection of a set of cellular firing sequences from a repertoire of existing temporal firing sequences in the hippocampal network. Conceptually, this indicates that novel stimuli from the external world select from their pre-representations rather than create de novo our internal representations of the world.     

Behavioral adaptations to parasites: an ethological approach.

Wild vertebrate animals must live in an environment with the ever present threat of internal and external parasites. This threat by macroparasites is responsible for the natural selection of an array of behavioral adaptations that, together with the immune system and other physiological forms of resistance, enable the animals to survive and reproduce in this environment. Several lines of research, some quite recent, illustrate that specific behavioral patterns can be effective in helping animals or their offspring avoid or control macroparasites that can affect adversely the animal's fitness. These behavioral patterns fall under the general strategies of avoidance behavior and mate selection.     

Genetic and behavioral analysis of natural variation in Drosophila melanogaster pupation position

Drosophila melanogaster pupae are exposed to many biotic and abiotic dangers while immobilized during several days of metamorphosis. As a passive defense mechanism, appropriate pupation site selection represents an important mitigation of these threats. Pupation site selection is sensitive to genetic and environmental influences, but the specific mechanisms of the behavior are largely unknown. Using a set of 76 recombinant inbred strains we identify a single quantitative trait locus, at polytene position 56A01-C11, associated with pupation site variation. We furthermore present a detailed investigation into the wandering behaviors of two strains expressing different pupation position tendencies, and identify behavioral differences. Larvae from a strain that tends to pupate relatively far from the food also tend to travel significantly farther from the media during wandering. We did not observe consistent differences in either the number or duration of wandering forays made by near or far pupating strains. The ability of larvae to integrate several internal and external environmental cues while choosing a contextually appropriate pupation site, and specifically, the variation in this ability, presents a very interesting behavioral phenotype in this highly tractable genetic model organism.     

Zum konzept der »inneren« selektion: Stellungnahme zu einer evolutionstheoretischen kontroverse

Recently the concept of natural selection in Darwin’s sense has been criticized by some authors. It has been argued that this concept does not explain certain phenomena of evolutionary change, especially in the reach of macroevolution. Some biologists, therefore, demanded for evolution a new model of selection which focuses internal factors in phytogeny. — This paper is a brief discussion of some aspects of “internal” selection and its meaning in contemporary evolutionary biology. The argument of the paper is that evolution can only be explained by a theory taking cognizance of interactions between external and internal selective agencies. Such a theory would be a systems theory of evolution.     

One tool, many uses: precopulatory sexual selection on genital morphology in Aquarius remigis

While congruent evidence indicates that sexual selection is the most likely selective force explaining the rapid divergence of male genital morphology in insects, the mechanisms involved in this process remain unclear. In particular, little attention has been paid to precopulatory sexual selection. We examine sexual selection for mating success on male genital components in six populations of Aquarius remigis, a water strider characterized by unique genital morphology. Multivariate selection analysis confirms previous findings that precopulatory sexual selection favours longer external genitalia, and provides new evidence that this selection acts independently on external genital components. In contrast, the size of the major internal genital sclerite is not correlated with mating success. Thus, precopulatory sexual selection acts strongly on the size of the external genitalia, but not on the intromittent organ itself. These results highlight the multiple functions of genital organs and the importance of both precopulatory and post-copulatory sexual selection in shaping the remarkable diversity of male genitalia in insects.     

Neuromodulation by Glutamate and Acetylcholine can Change Circuit Dynamics by Regulating the Relative Influence of Afferent Input and Excitatory Feedback

Substances such as acetylcholine and glutamate act as both neurotransmitters and neuromodulators. As neuromodulators, they change neural information processing by regulating synaptic transmitter release, altering baseline membrane potential and spiking activity, and modifying long-term synaptic plasticity. Slice physiology research has demonstrated that many neuromodulators differentially modulate afferent, incoming information compared to intrinsic and recurrent processing in cortical structures such as piriform cortex, neocortex, and the hippocampus. The enhancement of afferent (external) pathways versus the suppression at recurrent (internal) pathways could cause cortical dynamics to switch between a predominant influence of external stimulation to a predominant influence of internal recall. Modulation of afferent versus intrinsic processing could contribute to the role of neuromodulators in regulating attention, learning, and memory effects in behavior.     

Experimental evolution of external immune defences in the red flour beetle

The red flour beetle, Tribolium castaneum, secretes quinones that control the microbial flora in the surrounding environment. These secretions act as an external immune defence that provides protection against pathogens. At high concentrations, however, these secretions are harmful to the host itself, and selection may thus have optimized the level of expression under natural conditions. Here, we show that the expression of external immunity responded to selection during experimental evolution within a few generations. At the same time, one component of internal immune defence (phenoloxidase activity) was compromised in beetles selected for either high or low external defences. Intriguingly, offspring protection against a natural pathogen was reduced in flour obtained from beetle lines selected for low amounts of secretions. Altogether, this suggests that external and internal immune defences work together efficiently under natural conditions, whereas every manipulation on the side of external immune defence comes with costs to the internal immune defence.     

Proximate mechanisms driving circadian control of neuroendocrine function: Lessons from the young and old

Circadian rhythms impact a variety of behavioral and physiological functions contributing to longevity and successful reproduction. In their natural environments, individuals of a species are faced with a multitude of challenges and the coordination of internal processes and behavior with external pressures has been hypothesized to be an important target of natural selection. Several lines of evidence from cyanobacteria, Drosophila, and plants provide strong support for an important role of the circadian clock in survival and reproductive success. Similarly in mammals, disruptions in circadian function markedly impact reproduction and lifespan. The present review discusses research outlining the proximate and ultimate mechanisms responsible for the central and peripheral control of the reproductive axis. Because precise temporal coordination of the endocrine system is particularly crucial for reproduction by females, the present overview focuses on the role of circadian timing in this sex.     

Sexuelle Selektion und ökologische Differenzierung*

Sexual selection and ecological differentiation The emphasis of this contribution is a synthesis of the concepts of sexual selection, ecological differentiation (= niche shift) and the phylogenetic patterns of the evolution of the internal fertilization, the gonochorism and the differences of species diversity of taxa of the metazoa. This synthesis leads to the suggestion that sexual selection has been crucial in the remarkable differences in the species richness of different taxa. A comparison of taxa that are descendend from stem species without or, respectively, with internal fertilization, clearly indicates that the latter are composed of much more species. However, internal fertilization is a sufficient prerequisite of sexual selection. Therefore, most probably sexual reproduction (a necessary prerequisite of sexual selection) is not a subject to the caprice of fortune, but a highly sophisticated trade over quality of mates. Due to the genetic correlation between heritable quality indicators (= sexual signals) and heritable phenotypic quality, the tempo of ecological differentiation by sexual selection increases 1. if the quality indicator increases with phenotypic and genetic quality and costs depends on advertisement and 2. if it pays in terms of increased fitness to mate with high quality mates. Therefore, adaptive radiation is more likely in taxonomic groups that are descended from stem species with internal fertilization or external fertilization, but a highly sophisticated mating behaviour, than in taxa with stem species which reproduce only by ancestral external fertilization. This synthesis of phylogenetic patterns in the diversity of species established over long periods of macroevolution and a set of experimental data says something about the nature of the selection forces operating in the coevolution of species and is therefore, a first step towards bridging the gap between observation of historical events an the lack of theory of coevolution.     

Parietal mechanisms of target representation

Recent single-neuron recordings show that representation of the external environment in the parietal lobe is highly selective for objects that are immediately relevant to behavior. Parietal neurons change their selectivity in accordance to immediate behavioral needs, integrate evidence about behavioral relevance from multiple sources, and appear to actively participate in the selection of potential behavioral targets. The selective parietal representations may represent a general-purpose attentional mechanism that can simultaneously specify targets for exploratory movements and for perception.     

Die revision des evolutionsdenkens

The criticism ofJ. Remane concerning the organism-centred conception of evolution is refuted. By referring to some strategic quotations most of the criticism can be shown to be based on an inadequate understanding of the criticized theory. It is shown that very recent attempts to base the theory of evolution on the competition of energy converting organismic systems must inevitably lead to a revised understanding of selection which encompasses internal, energetic, and environmental aspects. Consequently, phylogenetic transformation has to be conceived as a process that follows internal and external constraints. Malfunctioning organisms and abnormal ontogenetic stages testify internal organismic constraint as an indispensable component of the internal aspect of selection.     

对虾行为生态学研究进展Ⅱ.环境因子对对虾行为习性的影响

综述了近年来国内外关于外界环境因子对对虾行为习性影响的研究进展.着重介绍了光、水流和潮汐、溶解氧、底质及水温等环境因子对对虾摄食、运动、产卵、蜕皮及潜底和浮现等行为习性的影响,并探讨了对虾对环境因子变动的行为调节.提出了对虾行为生态学研究中存在的问题以及今后的研究方向,即对虾的行为习性和疾病传播间的关系、对虾的行为习性对养殖生态系统的影响和高密度工厂化养殖环境对对虾行为特征的综合影响等.     

Toward a cognitive ecology

The emergence of cognitive psychology as the dominant approach to understanding human behaviors and actions acknowledges the importance of internal mental operations in generating specific behavioral responses to sets of external stimuli. Traditional behaviorist interpretations that rely primarily on external inputs as the precursors of action have been largely replaced by cognitive approaches. The main intent of this article is to outline the major areas that require exploration if we wish to apply fully the principles and insight of cognitive science to behavioral ecology.     

Neurotransmitters and stress

In this article definitions of stress and distress are proposed and the relationships between stress and activities of neurohormonal systems explored. The idea is developed that stress is a condition where expectations--whether genetically programmed, established by prior learning, or deduced from circumstances--do not match the current or anticipated perceptions of the internal or external environment, and this discrepancy between what is observed or sensed and what is expected or programmed elicits patterned, compensatory responses. Distress is viewed here as a form of stress characterized by specific behavioral and autonomic communicated signs, pituitary-adrenocortical and sympathoadrenomedullary activation, and a negative experience that motivates escape or avoidance. During stress, many body systems--including the sympathoadrenal, parasympathetic, and hormonal homeostatic systems--are activated or inhibited in primitively specific patterns regulated by physiological, biochemical, and psychological homeostats. Many of these patterns, which are at least partly inherited, can be understood teleologically on the basis of preservation of the internal environmental and natural selection in evolution.     

Neuroecology and diet selection in phyllostomid bats

For many birds and mammals relative brain and hippocampus volume are positively related to enhanced behavioral flexibility and spatial memory. I tested for correlations between species-specific diet selection and relative brain and hippocampus volumes in the New World leaf-nosed bats (Phyllostomidae). To this end, I classified each of 53 species from this ecologically diverse family as one of the following: (i) predatory, (ii) omnivorous, (iii) frugivorous, or (iv) nectivorous. Species-level analyses and the comparative method (i.e. phylogenetically independent contrasts) revealed that relative hippocampus volume was greater in predatory species than in frugivorous and nectivorous species and that relative brain size was greater in frugivorous species than in predatory species. As previously reported, specialized frugivory appears to be associated with increased relative brain volume suggesting these two traits evolve together. I suggest some plausible functional explanations for variation in hippocampus volume in light of our current understanding of the acquisition of spatial information and its use by echolocating bats.     

Comparison of genotype imputation strategies using a combined reference panel for chicken population

Using whole-genome sequence (WGS) data are supposed to be optimal for genome-wide association studies and genomic predictions. However, sequencing thousands of individuals of interest is expensive. Imputation from single nucleotide polymorphisms panels to WGS data is an attractive approach to obtain highly reliable WGS data at low cost. Here, we conducted a genotype imputation study with a combined reference panel in yellow-feather dwarf broiler population. The combined reference panel was assembled by sequencing 24 key individuals of a yellow-feather dwarf broiler population (internal reference panel) and WGS data from 311 chickens in public databases (external reference panel). Three scenarios were investigated to determine how different factors affect the accuracy of imputation from 600 K array data to WGS data, including: genotype imputation with internal, external and combined reference panels; the number of internal reference individuals in the combined reference panel; and different reference sizes and selection strategies of an external reference panel. Results showed that imputation accuracy from 600 K to WGS data were 0.834±0.012, 0.920±0.007 and 0.982±0.003 for the internal, external and combined reference panels, respectively. Increasing the reference size from 50 to 250 improved the accuracy of genotype imputation from 0.848 to 0.974 for the combined reference panel and from 0.647 to 0.917 for the external reference panel. The selection strategies for the external reference panel had no impact on the accuracy of imputation using the combined reference panel. However, if only an external reference panel with reference size >50 was used, the selection strategy of minimizing the average distance to the closest leaf had the greatest imputation accuracy compared with other methods. Generally, using a combined reference panel provided greater imputation accuracy, especially for low-frequency variants. In conclusion, the optimal imputation strategy with a combined reference panel should comprehensively consider genetic diversity of the study population, availability and properties of external reference panels, sequencing and computing costs, and frequency of imputed variants. This work sheds light on how to design and execute genotype imputation with a combined external reference panel in a livestock population.     

A general model of the relation between phenotypic selection and genetic response

The phenotypic view of selection assumes that genetic responses can be predicted from selective forces and heritability — or in the classical quantitative genetic equation: R = h²S. However, data on selection in bird populations show that often no selection responses is found, despite consistent selective forces on phenotypes and significant heritable variation. Such discrepancies may arise due to the assumption that selection only acts on observed phenotypes. We derive a general selection equation that takes into account the possibility that some relevant (internal or external) traits are not measured. This equation shows that the classic equation applies if selection directly acts on the measured, phenotypic traits. This is not the case when, for instance, there are unknown internal genetic trade-offs, or unknown common environmental factors affecting both trait and fitness. In such cases, any relationship between phenotypic selection and genetic response is possible. Fortunately, the classical model can be tested by comparing phenotypic and genetic covariances between traits and fitness; an indication that important internal or external traits are missing can thus be obtained. Such an analysis was indeed found in the literature; for selection on fledging weight in Great Tits it yielded valuable extra information.