Hippocampal specialization of food-storing birds.

Krebs, John R.; Sherry, David F.; Healy, Susan D.; Perry, V. Hugh; Vaccarino, Anthony L.

doi:10.1073/pnas.86.4.1388

Cited by 572 publications

(457 citation statements)

References 11 publications

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“…This is seen in recent research on differential experience conducted with different species of the crow family. Species that cache food in a variety of locations for future use are found to have significantly larger hippocampal formations than related species that do not cache food (Krebs et al 1989. But the difference in hippocampal size is not found in young birds still in the nest; it appears only after food storing has started, a few weeks after the birds have left the nest (Healy & Krebs 1993).…”

Section: Experience May Be Necessary For Full Growth Of Brain and Of mentioning

confidence: 88%

Aspects of the Search for Neural Mechanisms of Memory

Rosenzweig

1996

Annu. Rev. Psychol.

102

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The search for neural mechanisms of memory has been under way for more than a century. The pace quickened in the 1960s when investigators found that training or differential experience leads to significant changes in brain neurochemistry, anatomy, and electrophysiology. Many steps have now been identified in the neurochemical cascade that starts with neural stimulation and ends with encoding information in long-term memory. Applications of research in this field are being made to child development, successful aging, recovery from brain damage, and animal welfare. Extensions of current research and exciting new techniques promise novel insights into mechanisms of memory in the decades ahead. CONTENTS

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Section: Experience May Be Necessary For Full Growth Of Brain and Of mentioning

confidence: 88%

Aspects of the Search for Neural Mechanisms of Memory

Rosenzweig

1996

Annu. Rev. Psychol.

102

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“…The hippocampus is important in spatial orientation, and examples exist of enlargement of the hippocampus in both birds (Krebs et al, 1989;Krebs, 1990;Jacobs and Liman, 1991) and mammals (Sherry et al, 1992;Jacobs and Spencer, 1994;Lavenex et al, 2000) involved in seasonal caching behavior, as well as sex differences in space use (related to breeding system) in some small mammals (Jacobs and Spencer, 1994;Sherry et al, 1996;Lavenex et al, 2000). Moreover, among species of primates, enlargement of the neocortex has been correlated with the likelihood of using deception as a strategy for social advancement (Byrne and Corp, 2004).…”

Section: Discussionmentioning

confidence: 99%

“…Increases in relative brain size (relative to body mass) in mammals have been correlated with enhanced sensory abilities (Jerison, 1973;Catania, 2005), spatial memory (Krebs et al, 1989;Krebs, 1990;Jacobs and Liman, 1991;Jacobs and Spencer, 1994) and aspects of cognition (Jerison, 1973;Byrne and Corp, 2004;Peper et al, 2009;Mehlhorn et al, 2010). The 'principle of proper mass', first articulated by Jerison (Jerison, 1973), states that the size of a given neural structure reflects the complexity of the function that it subserves.…”

Section: Introductionmentioning

confidence: 99%

Mice selectively bred for high voluntary wheel running have larger midbrains: support for the mosaic model of brain evolution

Kolb

Rezende

Holness

et al. 2013

Journal of Experimental Biology

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SUMMARYIncreased brain size, relative to body mass, is a primary characteristic distinguishing the mammalian lineage. This greater encephalization has come with increased behavioral complexity and, accordingly, it has been suggested that selection on behavioral traits has been a significant factor leading to the evolution of larger whole-brain mass. In addition, brains may evolve in a mosaic fashion, with functional components having some freedom to evolve independently from other components, irrespective of, or in addition to, changes in size of the whole brain. We tested whether long-term selective breeding for high voluntary wheel running in laboratory house mice results in changes in brain size, and whether those changes have occurred in a concerted or mosaic fashion. We measured wet and dry brain mass via dissections and brain volume with ex vivo magnetic resonance imaging of brains that distinguished the caudate-putamen, hippocampus, midbrain, cerebellum and forebrain. Adjusting for body mass as a covariate, mice from the four replicate high-runner (HR) lines had statistically larger non-cerebellar wet and dry brain masses than those from four non-selected control lines, with no differences in cerebellum wet or dry mass or volume. Moreover, the midbrain volume in HR mice was ~13% larger (P<0.05), while volumes of the caudate-putamen, hippocampus, cerebellum and forebrain did not differ statistically between HR and control lines. We hypothesize that the enlarged midbrain of HR mice is related to altered neurophysiological function in their dopaminergic system. To our knowledge, this is the first example in which selection for a particular mammalian behavior has been shown to result in a change in size of a specific brain region.Key words: activity, allometry, cerebellum, dopamine, exercise behavior, locomotion, motor control. convergences within primates, spatio-sensory convergences within insectivores). Similar evidence for mosaic evolution in the avian brain has also been found and correlated to functional differences in the enlarged brain regions (Iwaniuk et al., 2006). Cellular changes have also been observed with increased brain size. As brain volume increases, axon diameters and the fraction of myelinated axons increase, thereby reducing the delay in neural signaling between more distant regions (Wang et al., 2008). Moreover, different cellular scaling rules apply across different mammalian orders (Herculano-Houzel, 2010). For example, in rodents, neuronal cell size increases with brain size, such that neuronal density is lower in larger-brained species (albeit with a greater absolute number of neurons) (Herculano-Houzel et al., 2006). Conversely, in primates, neuronal cell size is constant and neuron density is constant, such that total neuron number is much greater with increasing brain size (Herculano-Houzel et al., 2007). Therefore, an increase in the size of a brain region could be the product of a variety of cellular changes (e.g. neuron number, neuron density, glial density, gray-to-white matte...

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“…Volume measurements. A video camera connected to a Leica light microscope was used to capture the image of the brain sections into an Image 1.42 program in a Macintosh computer to measure the areas of the lesions within the Hf, the areas of the transplants, and the areas of the hippocampus for calculation of the estimated total lesion volume, total transplant volumes, and total Hf volume (according to the method in Krebs et al, 1989;Clayton and Krebs, 1994). The latter will be an approximate estimate because of the distortion of the Hf after lesioning and transplantation.…”

Section: Methodsmentioning

confidence: 99%

Hippocampal Tissue Transplants Reverse Lesion-Induced Spatial Memory Deficits in Zebra Finches (Taeniopygia guttata)

1997

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The avian hippocampal formation (Hf ) plays an important role in spatial memory for food storing. Here we examined the effects of excitotoxic lesions of the Hf and subsequent neural transplantation on a one-trial associative memory task in zebra finches. The results showed (1) that small ibotenic acid lesions of the dorsal Hf of zebra finches produced significant spatial memory impairments compared with controls, sham-lesioned birds, and prelesion performance; and (2) that Hf-lesioned birds given transplants of embryonic hippocampal (H) tissue, but not those given transplants of embryonic anterior telencephalon (AT ) tissue, showed a significant reversal of the performance deficits on the spatial memory task. Lesioned-only birds and lesioned birds given H or AT transplants that did not survive did not show behavioral improvement. Sham-lesioned and untreated control birds maintained good performance throughout the experiment. The H and AT transplants were found to be growing partially within the Hf and partially within the underlying ventricle. The transplants appeared healthy and contained neurons with beaded and unbeaded fibers (shown by immunohistochemistry with antibodies to parvalbumin, substance P, and a 200 kDa neurofilament protein). Blood vessels and erythrocytes were also present within the transplants. The results show that neural transplants can survive within the bird brain and that small lesions of the Hf produce significant spatial memory deficits that can only be reversed by surviving homologous H transplants, and not by heterologous telencephalon transplants.

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Hippocampal specialization of food-storing birds.

Cited by 572 publications

References 11 publications

Aspects of the Search for Neural Mechanisms of Memory

Aspects of the Search for Neural Mechanisms of Memory

Mice selectively bred for high voluntary wheel running have larger midbrains: support for the mosaic model of brain evolution

Hippocampal Tissue Transplants Reverse Lesion-Induced Spatial Memory Deficits in Zebra Finches (Taeniopygia guttata)

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