Finding one’s way in space is of primary importance for organisms when it comes to vital behaviors such as feeding or breeding. The ability to process spatial information is shared by numerous mobile animals and reaches various degrees of complexity in line with the wide diversity of neural structures underlying this function.
In mammals, however, the hippocampus appears to be a central component of the global navigation system dedicated to spatial processing. This forebrain region, located in the medial temporal lobe, has been under close scrutiny for decades, but the discovery of a particular class of cells in the early ‘70s by John O’Keefe shed new light on the hippocampal cognitive mapping theory. These pyramidal cells, termed “place cells”, are thought to provide the mammalian brain with a unique spatial signature for any given environment, and to encode a memory trace of the animal’s location.
However, although there is little doubt about the role played by place cells across these various species in spatial processing, some differences remain, especially regarding their properties in the primate brain. It is possible, however, that these discrepancies arise from the experimental design per se, rather than from any interspecies differences.
At the cellular level, with the advent of molecular techniques in the late 1980s and the development of transgenic mouse models, a growing number of studies have attempted to decipher the fundamental mechanisms supporting place cell function. In line with these cellular considerations, intracellular electrophysiological recordings allow researchers to gain precise knowledge of the mechanisms by which the brain processes spatial information and provide therefore an essential means of investigation. The use of computational models is also of primary importance to understand the mechanism of place-field activity in particular and spatial processing in general.
To summarize, this Research Topic aims to review the role of hippocampal place cells in spatial processing and other cognitive functions using a comparative approach (drawing on evidence gathered from the whole vertebrate group), and focusing on multiple levels of analysis (including behavioral, computational, anatomical, molecular and physiological aspects of place cell function).
Finding one’s way in space is of primary importance for organisms when it comes to vital behaviors such as feeding or breeding. The ability to process spatial information is shared by numerous mobile animals and reaches various degrees of complexity in line with the wide diversity of neural structures underlying this function.
In mammals, however, the hippocampus appears to be a central component of the global navigation system dedicated to spatial processing. This forebrain region, located in the medial temporal lobe, has been under close scrutiny for decades, but the discovery of a particular class of cells in the early ‘70s by John O’Keefe shed new light on the hippocampal cognitive mapping theory. These pyramidal cells, termed “place cells”, are thought to provide the mammalian brain with a unique spatial signature for any given environment, and to encode a memory trace of the animal’s location.
However, although there is little doubt about the role played by place cells across these various species in spatial processing, some differences remain, especially regarding their properties in the primate brain. It is possible, however, that these discrepancies arise from the experimental design per se, rather than from any interspecies differences.
At the cellular level, with the advent of molecular techniques in the late 1980s and the development of transgenic mouse models, a growing number of studies have attempted to decipher the fundamental mechanisms supporting place cell function. In line with these cellular considerations, intracellular electrophysiological recordings allow researchers to gain precise knowledge of the mechanisms by which the brain processes spatial information and provide therefore an essential means of investigation. The use of computational models is also of primary importance to understand the mechanism of place-field activity in particular and spatial processing in general.
To summarize, this Research Topic aims to review the role of hippocampal place cells in spatial processing and other cognitive functions using a comparative approach (drawing on evidence gathered from the whole vertebrate group), and focusing on multiple levels of analysis (including behavioral, computational, anatomical, molecular and physiological aspects of place cell function).
