Brenton G. Cooper

Hippocampal Representational Organization and Spatial Context

The hippocampus appears to undergo continual representational reorganization as animals navigate their environments. This reorganization is postulated to be reflected spatially in terms of changes in the ensemble of place cells activated, as well as changes in place field specificity and reliability for cells recorded in both hilar/CA3 and CA1 regions. The specific contribution of the hilar/CA3 region is suggested to be to compare the expected spatial context with that currently being experienced, then relay discrepancies to CA1. The properties of CA1 place fields in part reflect the spatial comparisons made in the hilar/CA3 area. In addition, CA1 organizes the input received from the hilar/CA3 place cells according to different temporal algorithms that are unique to different tasks. In this way, hippocampus helps to distinguish temporally one spatial context from another, thereby contributing to episodic memories. Hippocampus 1999;9:444–451.

Finding your way in the dark: the retrosplenial cortex contributes to spatial memory and navigation without visual cues.

Path integration is presumed to rely on self-motion cues to identify locations in space and is subject to cumulative error. The authors tested the hypothesis that rats use memory to reduce such errors and that the retrosplenial cortex contributes to this process. Rats were trained for 1 week to hoard food in an arena after beginning a trial from a fixed starting location; probe trials were then conducted in which they began a trial from a novel place in light or darkness. After control injections, rats searched around the training location, showing normal spatial memory. Inactivation of the retrosplenial cortex disrupted this search preference. To assess accuracy during navigation, rats were then trained to perform multiple trials daily, with a fixed or a different starting location in light or darkness. Retrosplenial cortex inactivation impaired accuracy in darkness. The retrosplenial cortex may provide mnemonic information, which decreases errors when navigating in the dark.

Retrosplenial cortex inactivation selectively impairs navigation in darkness.

There is an emerging consensus that retrosplenial and posterior parietal cortex importantly contribute to navigation. Several theories of navigation have argued that these cortical areas, particularly retrosplenial cortex, are involved in path integration. In an effort to characterize the role of retrosplenial cortex in active navigation, the effects of temporary inactivation of retrosplenial cortex on spatial memory performance were evaluated in light and dark testing conditions. Inactivation of retrosplenial cortex selectively resulted in behavioral impairments when animals were tested in darkness. These data support the hypothesis that retrosplenial cortex contributes to navigation in darkness, perhaps by providing mnemonic associations of the visual and nonvisual environment that can be used to correct for cumulative errors that occur during path integration.

Peripheral Motor Dynamics of Song Production in the Zebra Finch

Abstract: Singing behavior in songbirds is a model system for motor control of learned behavior. The target organs of its central motor programs are the various muscle systems involved in sound generation. Investigation of these peripheral motor mechanisms of song production is the first step toward an understanding of how different motor systems are coordinated. Here we review physiological studies of all major motor systems that are involved in song production and modification in the zebra finch (Taeniopygia guttata). Acoustic syllables of zebra finch song are produced by a characteristic air sac pressure pattern. Electromyographic (EMG) and sonomicrometric recording of expiratory muscle activity reveals that respiratory motor control is tightly coordinated with syringeal gating of airflow. Recordings of bronchial airflow demonstrate that most of the song syllables are composed of simultaneous independent contributions from the two sides of the syrinx. Sounds generated in the syrinx can be modified by the resonance properties of the upper vocal tract. Tracheal length affects resonance, but dynamic changes of tracheal length are unlikely to make a substantial contribution to sound modification. However, beak movements during song contribute to sound modification and, possibly, affect the vibratory behavior of the labia. Rapid beak aperture changes were associated with nonlinear transitions in the acoustic structure of individual syllables. The synergy between respiratory and syringeal motor systems, and the unique bilateral, simultaneous, and independent sound production, combined with dynamic modification of the acoustic structure of song, make the zebra finch an excellent model system for exploring mechanisms of sensorimotor integration underlying a complex learned behavior.

A neural systems analysis of adaptive navigation.

In the field of the neurobiology of learning, significant emphasis has been placed on understanding neural plasticity within a single structure (or synapse type) as it relates to a particular type of learning mediated by a particular brain area. To appreciate fully the breadth of the plasticity responsible for complex learning phenomena, it is imperative that we also examine the neural mechanisms of the behavioral instantiation of learned information, how motivational systems interact, and how past memories affect the learning process. To address this issue, we describe a model of complex learning (rodent adaptive navigation) that could be used to study dynamically interactive neural systems. Adaptive navigation depends on the efficient integration of external and internal sensory information with motivational systems to arrive at the most effective cognitive and/or behavioral strategies. We present evidence consistent with the view that during navigation: 1) the limbic thalamus and limbic cortex is primarily responsible for the integration of current and expected sensory information, 2) the hippocampal-septal-hypothalamic system provides a mechanism whereby motivational perspectives bias sensory processing, and 3) the amygdala-prefrontal-striatal circuit allows animals to evaluate the expected reinforcement consequences of context-dependent behavioral responses. Although much remains to be determined regarding the nature of the interactions among neural systems, new insights have emerged regarding the mechanisms that underlie flexible and adaptive behavioral responses.

Location and head direction representation in the dorsal striatum of rats

The activity of dorsal striatal location and head direction neurons were recorded as rats performed a hippocampal-dependent spatial working memory task. Relative to previous descriptions of hippocampal fields, striatal fields appeared more dependent on the visual environment in which the maze was performed. Striatal head direction correlates were also shown to be dependent upon the visual context in a lit environment: The directional preferences rotated with the rotation of distal visual cue, and maze or rat rotations had no effect. However, when animals performed the maze in darkness, idiothetic information gained greater control over head direction preferences: Passive movement of the rat in darkness (but not in light) disrupted directional firing. During both light and dark trials, the same head direction preferences were observed. A special contribution of the dorsal striatum to navigation may be to facilitate an animal’s ability to switch between navigational strategies, thereby maintaining behavioral constancy in changing environments.

Species-typical songs in white-crowned sparrows tutored with only phrase pairs

Modern theories of learned vocal behaviours, such as human speech and singing in songbirds, posit that acoustic communication signals are reproduced from memory, using auditory feedback. The nature of these memories, however, is unclear. Here we propose and test a model for how complex song structure can emerge from sparse sequence information acquired during tutoring. In this conceptual model, a population of combination-sensitive (phrase-pair) detectors is shaped by early exposure to song and serves as the minimal representation of the template necessary for generating complete song. As predicted by the model, birds that were tutored with only pairs of normally adjacent song phrases were able to assemble full songs in which phrases were placed in the correct order; birds that were tutored with reverse-ordered phrase pairs sang songs with reversed phrase order. Birds that were tutored with all song phrases, but presented singly, failed to produce normal, full songs. These findings provide the first evidence for a minimal requirement of sequence information in the acoustic model that can give rise to correct song structure.

Superior colliculus and active navigation: Role of visual and non‐visual cues in controlling cellular representations of space

To begin investigation of the contribution of the superior colliculus to unrestrained navigation, the nature of behavioral representation by individual neurons was identified as rats performed a spatial memory task. Similar to what has been observed for hippocampus, many superior collicular cells showed elevated firing as animals traversed particular locations on the maze, and also during directional movement. However, when compared to hippocampal place fields, superior collicular location fields were found to be more broad and did not exhibit mnemonic properties. Organism‐centered spatial coding was illustrated by other neurons that discharged preferentially during right or left turns made by the animal on the maze, or after lateralized sensory presentation of somatosensory, visual, or auditory stimuli. Nonspatial movement‐related neurons increased or decreased firing when animals engaged in specific behaviors on the maze regardless of location or direction of movement. Manipulations of the visual environment showed that many, but not all, spatial cells were dependent on visual information. The majority of movement‐related cells, however, did not require visual information to establish or maintain the correlates. Several superior collicular cells fired in response to multiple maze behaviors; in some of these cases a dissociation of visual sensitivity to one component of the behavioral correlate, but not the other, could be achieved for a single cell. This suggests that multiple modalities influence the activity of single neurons in superior colliculus of behaving rats. Similarly, several sensory‐related cells showed dramatic increases in firing rate during the presentation of multisensory stimuli compared to the unimodal stimuli. These data reveal for the first time how previous findings of sensory/motor representation by the superior colliculus of restrained/anesthetized animals might be manifested in freely behaving rats performing a navigational task. Furthermore, the findings of both visually dependent and visually independent spatial coding suggest that superior colliculus may be involved in sending visual information for establishing spatial representations in efferent structures and for directing spatially‐guided movements. Hippocampus 1998;8:340–372.

Songbirds use pulse tone register in two voices to generate low-frequency sound.

The principal physical mechanism of sound generation is similar in songbirds and humans, despite large differences in their vocal organs. Whereas vocal fold dynamics in the human larynx are well characterized, the vibratory behaviour of the sound-generating labia in the songbird vocal organ, the syrinx, is unknown. We present the first high-speed video records of the intact syrinx during induced phonation. The syrinx of anaesthetized crows shows a vibration pattern of the labia similar to that of the human vocal fry register. Acoustic pulses result from short opening of the labia, and pulse generation alternates between the left and right sound sources. Spontaneously calling crows can also generate similar pulse characteristics with only one sound generator. Airflow recordings in zebra finches and starlings show that pulse tone sounds can be generated unilaterally, synchronously or by alternating between the two sides. Vocal fry-like dynamics therefore represent a common production mechanism for low-frequency sounds in songbirds. These results also illustrate that complex vibration patterns can emerge from the mechanical properties of the coupled sound generators in the syrinx. The use of vocal fry-like dynamics in the songbird syrinx extends the similarity to this unusual vocal register with mammalian sound production mechanisms.

Age-related changes in the Bengalese finch song motor program

It is well established that there are remarkable similarities between song learning in oscine birds and acquisition of speech in young children. Human speech shows marked changes with senescence, but few studies have evaluated how song changes with advanced age in songbirds. To investigate the effect of old age on song, we compared song of old Bengalese finches (Lonchura striata domestica) with that of middle-aged birds. The main observed difference was a decrease in the song tempo, largely due to an increased intersyllable duration. Aging also affected the acoustic characteristics of the song, causing a decrease in pitch and in the range of frequency modulations. Gross morphological measurements of selected vocal muscles did not show detectable changes over this age range, suggesting that song deterioration may be due to neural deterioration. The age-induced temporal and acoustic changes in song parallel the acoustic changes that occur in human speech, suggesting songbirds as a suitable model for aging studies on learned vocal behavior.