Environmental Influences on Spatial Memory and the Hippocampus in Food-Caching Chickadees

The adult hippocampus in birds and mammals undergoes neurogenesis and the resulting new neurons appear to integrate structurally and functionally into the existing neural architecture. However, the factors underlying the regulation of new neuron production is still under scrutiny. In recent years, the concept that spatial memory affects adult hippocampal neurogenesis has gained acceptance, although results attempting to causally link memory use to neurogenesis remain inconclusive, possibly owing to confounds of motor activity, task difficulty or training for the task. Here, we show that ecologically relevant, spatial memory-based experiences of food caching and retrieving directly affect hippocampal neurogenesis in mountain chickadees ( Poecile gambeli ). We found that restricting memory experiences in captivity caused significantly lower rates of neurogenesis, as determined by doublecortin expression, compared with captive individuals provided with such experiences. However, neurogenesis rates in both groups of captive birds were still greatly lower than those in free-ranging conspecifics. These findings show that ecologically relevant spatial memory experiences can directly modulate neurogenesis, separate from other confounds that may also independently affect neurogenesis.

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Sex, estradiol, and spatial memory in a food-caching corvid

Hormones and Behavior ◽

10.1016/j.yhbeh.2015.07.022 ◽

2015 ◽

Vol 75 ◽

pp. 45-54 ◽

Cited By ~ 11

Author(s):

Michelle A. Rensel ◽

Jesse M.S. Ellis ◽

Brigit Harvey ◽

Barney A. Schlinger

Keyword(s):

Spatial Memory ◽

Food Caching

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Variation in hippocampal morphology along an environmental gradient: controlling for the effects of day length

Proceedings of The Royal Society B Biological Sciences ◽

10.1098/rspb.2010.2585 ◽

2011 ◽

Vol 278 (1718) ◽

pp. 2662-2667 ◽

Cited By ~ 21

Author(s):

Timothy C. Roth ◽

Lara D. LaDage ◽

Vladimir V. Pravosudov

Keyword(s):

Spatial Memory ◽

Snow Cover ◽

Cognitive Abilities ◽

Memory Function ◽

Geographical Area ◽

Brain Regions ◽

Day Length ◽

Relative Role ◽

Food Caching ◽

Significant Difference

Environmental conditions may create increased demands for memory, which in turn may affect specific brain regions responsible for memory function. This may occur either via phenotypic plasticity or selection for individuals with enhanced cognitive abilities. For food-caching animals, in particular, spatial memory appears to be important because it may have a direct effect on fitness via their ability to accurately retrieve food caches. Our previous studies have shown that caching animals living in more harsh environments (characterized by low temperatures, high snow cover and short day lengths) possess more neurons within a larger hippocampus (Hp), a part of the brain involved in spatial memory. However, the relative role of each of these environmental features in the relationship is unknown. Here, we dissociate the effects of one theoretically important factor (day length) within the environmental severity/Hp relationship by examining food-caching birds (black-capped chickadee, Poecile atricapillus ) selected at locations along the same latitude, but with very different climatic regimes. There was a significant difference in Hp attributes among populations along the same latitude with very different climatic features. Birds from the climatically mild location had significantly smaller Hp volumes and fewer Hp neurons than birds from the more harsh populations, even though all populations experienced similar day lengths. These results suggest that variables such as temperature and snow cover seem to be important even without the compounding effect of reduced day length at higher latitudes and suggest that low temperature and snow cover alone may be sufficient to generate high demands for memory and the hippocampus. Our data further confirmed that the association between harsh environment and the hippocampus in food-caching animals is robust across a large geographical area and across years.

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Environmental influences on spatial memory: A study with Space Syntax

10.31234/osf.io/kx86n ◽

2018 ◽

Author(s):

Marianna Pagkratidou ◽

Alexia Galati ◽

Marios N Avraamides

Keyword(s):

Spatial Memory ◽

Virtual Environment ◽

Model Building ◽

Spatial Information ◽

Environmental Influences ◽

Space Syntax ◽

Fan Effect ◽

Environmental Properties ◽

Pointing Task ◽

Other Information

In this study we employed Space Syntax techniques to investigate the relation between environmental properties and spatial memory resulting from navigation of an unfamiliar environment. Participants first navigated two main routes in a virtual environment, memorizing the names and locations of buildings in them, and then carried out from memory a pointing task and a model-building task. In the pointing task, participants pointed more accurately to locations of high than low connectivity and integration. However, they pointed less accurately from locations of higher than lower connectivity and integration. This finding can be contextualized by broader memory phenomena (namely, the fan effect), whereby the ease of retrieval of a piece of information depends on its connections with other information. Additionally, both memory tasks here provide evidence that participants maintained the two routes they experienced as distinct representations. Together, our findings suggest that space syntax metrics, such as the connectivity and integration of locations, along with other environmental properties we explore (e.g., whether locations are experienced along the same route or not, and whether locations are intervisible) account well for the way spatial information is stored in and retrieved from memory.

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Hippocampal volumes and neuron numbers increase along a gradient of environmental harshness: a large-scale comparison

Proceedings of The Royal Society B Biological Sciences ◽

10.1098/rspb.2008.1184 ◽

2008 ◽

Vol 276 (1656) ◽

pp. 401-405 ◽

Cited By ~ 98

Author(s):

Timothy C Roth ◽

Vladimir V Pravosudov

Keyword(s):

Spatial Memory ◽

Large Scale ◽

Memory Function ◽

Brain Regions ◽

Climatic Conditions ◽

Day Length ◽

Harsh Environments ◽

Environmental Pressures ◽

Food Caching ◽

Climatic Severity

Environmental conditions may provide specific demands for memory, which in turn may affect specific brain regions responsible for memory function. For food-caching animals, in particular, spatial memory appears to be important because it may have a direct effect on fitness via the accuracy of cache retrieval. Animals living in more harsh environments should rely more on cached food, and thus theoretically should have better memory to support cache retrieval, which may be crucial for survival. Consequently, animals in harsh environments may benefit from more neurons within a larger hippocampus (Hp), a part of the brain involved in spatial memory. Here, we present the first large-scale test of the hypothesis that Hp structure is related to the severity of the environment within a single food-caching species (the black-capped chickadee, Poecile atricapillus ) with a large range encompassing a great diversity of climatic conditions. Hp size in birds collected at five locations along a gradient of environmental harshness from Alaska to Kansas ranked perfectly with climatic severity. Birds from more harsh northern climates (defined by lower ambient temperature, shorter day length and more snow cover) had significantly larger Hp volumes and more Hp neurons (both relative to telencephalon volume) than those from more mild southern latitudes. Environmental pressures therefore seem capable of influencing specific brain regions independently, which may result in enhanced memory, and hence survival, in harsh climates.

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What makes specialized food-caching mountain chickadees successful city slickers?

Proceedings of The Royal Society B Biological Sciences ◽

10.1098/rspb.2016.2613 ◽

2017 ◽

Vol 284 (1855) ◽

pp. 20162613 ◽

Cited By ~ 15

Author(s):

Dovid Y. Kozlovsky ◽

Emily A. Weissgerber ◽

Vladimir V. Pravosudov

Keyword(s):

Spatial Memory ◽

Hippocampal Neurons ◽

Urban Environments ◽

Modern World ◽

Memory Retention ◽

Generalist Species ◽

Food Caching ◽

Dominant Feature ◽

Mountain Chickadees

Anthropogenic environments are a dominant feature of the modern world; therefore, understanding which traits allow animals to succeed in these urban environments is especially important. Overall, generalist species are thought to be most successful in urban environments, with better general cognition and less neophobia as suggested critical traits. It is less clear, however, which traits would be favoured in urban environments in highly specialized species. Here, we compared highly specialized food-caching mountain chickadees living in an urban environment (Reno, NV, USA) with those living in their natural environment to investigate what makes this species successful in the city. Using a ‘common garden’ paradigm, we found that urban mountain chickadees tended to explore a novel environment faster and moved more frequently, were better at novel problem-solving, had better long-term spatial memory retention and had a larger telencephalon volume compared with forest chickadees. There were no significant differences between urban and forest chickadees in neophobia, food-caching rates, spatial memory acquisition, hippocampus volume, or the total number of hippocampal neurons. Our results partially support the idea that some traits associated with behavioural flexibility and innovation are associated with successful establishment in urban environments, but differences in long-term spatial memory retention suggest that even this trait specialized for food-caching may be advantageous. Our results highlight the importance of environmental context, species biology, and temporal aspects of invasion in understanding how urban environments are associated with behavioural and cognitive phenotypes and suggest that there is likely no one suite of traits that makes urban animals successful.

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Memory Performance Influences Male Reproductive Success in a Wild Bird

10.26686/wgtn.13927889.v1 ◽

2021 ◽

Author(s):

Rachael Shaw ◽

Regan MacKinlay ◽

NS Clayton ◽

Kevin Burns

Keyword(s):

New Zealand ◽

Reproductive Success ◽

Spatial Memory ◽

Memory Performance ◽

Divergent Selection ◽

Large Prey ◽

Memory Ability ◽

Food Caching ◽

New Zealand Robin ◽

Cognitive Traits

© 2019 Elsevier Ltd Despite decades of comparative research, how selection shapes the evolution of cognitive traits remains poorly understood [1–3]. Several lines of evidence suggest that natural selection acts on spatial memory in food-caching species [3–6]. However, a link between reproductive fitness and spatial memory ability has yet to be demonstrated in any caching species [1, 3, 6]. Here, we show that memory performance influences reproductive success differentially for males and females in a caching songbird, the New Zealand robin (Petroica longipes). Males’ memory performance in a spatial task during winter influenced their subsequent breeding success; individuals with more accurate performance produced more fledglings and independent offspring per nesting attempt. Males with superior memory performance also provided an increased proportion of large prey items to chicks in the nest and spent less time flying while foraging and provisioning. No such effects were found for females. Previous research reveals that trade-offs may constrain selection and act to maintain variation in cognitive traits [7]. The gender dimorphism in the reproductive benefits of robin memory performance suggests an additional role for divergent selection between the sexes in constraining runaway selection on male memory ability [8], ultimately maintaining variation in this cognitive trait. Shaw et al. investigate whether spatial memory performance influences reproductive success in a food-caching bird, the New Zealand robin. The sexes differ in the reproductive and behavioral consequences of memory performance, suggesting that divergent selection between the sexes may constrain selection and maintain cognitive variation in the wild.

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