Scott D. Oddie

Theta band oscillation and synchrony in the hippocampal formation and associated structures: the case for its role in sensorimotor integration.

The current review advances the argument that it is naïve to ascribe a unitary function to the hippocampal formation (HPC). Rather, it is more productive to consider the hippocampal formation as consisting of a number of subsystems, each subsystem defined by its own particular neural circuitry. Among examples of neural circuitry appearing in current hippocampal literature are theta, beta and gamma oscillations, sharp waves, place cells and head orientation cells. Data are reviewed supporting the case that theta band oscillation and synchrony is involved in mechanisms underlying sensorimotor integration. Specifically, the neural circuitry underlying the production of oscillation and synchrony (theta) in limbic cortex and associated structures function in the capacity of providing voluntary motor systems with continually updated feedback on their performance relative to changing environmental (sensory) conditions. A crucial aspect of this performance is the intensity with which the motor programs are initiated and maintained. The ascending brainstem HPC synchronizing pathways make the primary contribution in this regard. These pathways originate in the rostral pontine region, ascend and synapse with caudal diencephalic nuclei, which in turn send projections to the medial septal region. The medial septum functions as the node in the ascending pathways, sending both cholinergic and GABA-ergic projections to the HPC. An updated version of the sensorimotor integration model including anatomical details is presented and discussed.

Anatomical, electrophysiological and pharmacological studies of ascending brainstem hippocampal synchronizing pathways.

The present review has provided evidence that very potent ascending brainstem hippocampal synchronizing pathways originate in the rostral pons region (RPO and PPT), and ascend to and synapse with several midline caudal diencephalic nuclei (posterior hypothalamic and supramammillary) which send projections to the medial septal region (MS/vDBB). The medial septal region in turn is a critical nodal point, sending projections to limbic structures such as the hippocampal formation, cingulate cortex, and entorhinal cortex. The pontine and diencephalic nuclei appear to play a critical role in determining the translation of increasing levels of activation into moment to moment changes in the frequency of hippocampal theta field and theta-related cellular discharges, relayed to the MS/vDBB nuclei. The MS/vDBB nuclei appear to play a critical role in translating increasing levels of ascending synchronizing activation into moment to moment changes in the amplitude of hippocampal theta field activity and the accompanying rate and pattern of phasic theta-ON cells. The MS/vDBB carries out this role through a balance of activity in the septohippocampal cholinergic and GABA-ergic projections. Cholinergic projections provide the afferent excitatory drive for hippocampal theta-ON cells and the GABA-ergic projections act to reduce the overall level of inhibition by inhibiting hippocampal GABA-ergic interneurons (theta-OFF cells). Both activities must be present for the generation of hippocampal theta and theta-related cellular activities. The balance between the cholinergic and GABA-ergic projections may determine whether hippocampal synchrony (theta) or asynchrony (LIA, large amplitude irregular activity) occurs. These same ascending pathways influence the electrophysiological and pharmacological properties of the neocortex as well. The functional significance of the ascending brainstem synchronizing pathways is the generalized regulation of activities in these cortical structures as they relate to sensorimotor behavior.

Hippocampal Formation Theta Activity and Movement Selection

Hippocampal theta activity results from activation in the ascending synchronizing system. It occurs during sensory/signal processing prior to and coincident with voluntary movements in mammals. The experiments summarized here suggest that it is involved in the organization of motor behaviour. (1) Procaine (a local anaesthetic) infused into the medial septum (MS) abolishes hippocampal theta activity and running behaviour elicited by electrical posterior hypothalamic (PH) stimulation. This indicates that movement elicited by PH stimulation, is dependent on ascending hypothalamo-septal circuitry. (2) Theta can also be recorded in immobile rats prior to the initiation of lateral dodging movements they make in response to conspecific rats attempting to steal their food. Following infusion of atropine into the MS, theta recorded during immobility is abolished and the rats are severely impaired at initiating movements in defence of their food. It is suggested that atropine-sensitive theta is involved in the initiation of movements made by rats in response to sensory stimuli. (3) Rats with fimbria-fornix transections were also less likely to engage in lateral dodging movements in defence of their food, were hyperactive, less thigmotaxic, and defecated more often, compared to control animals. Depth profile analysis of hippocampal field activity in lesioned animals revealed an absence of theta during electrical or chemical pons stimulation. These findings provide evidence that these neural systems are involved in signal processing relevant to movements underlying adaptive behaviour.

Mechanisms of Neural Synchrony in the Septohippocampal Pathways Underlying Hippocampal Theta Generation

Using urethane-anesthetized rats, 18 simultaneously recorded septohippocampal cell pairs (36 individual cells), each classified as theta-related according to the criteria of Colom and Bland (1987), were studied during four spontaneously occurring hippocampal field conditions: (1) large amplitude irregular activity (LIA) only; (2) the transition from LIA to theta; (3) theta only; and (4) the transition from theta to LIA. The main objective was to study the temporal relationships and degree of neural synchrony between the discharges of the cell pairs, using both time-averaged and time-dependent joint peristimulus time histogram correlation techniques, during the four conditions, to determine their contribution to the control of oscillation and synchrony (theta) in the hippocampus. The study demonstrated that the transition from the LIA state to the theta field state in the hippocampus required a temporal sequence of changes in theta-related cellular activity occurring on average 500 msec preceding the transition: (1) the medial septum inhibits hippocampal theta-OFF cells; (2) medial septal tonic theta-ON cells provide tonic depolarizing inputs to initiate membrane potential oscillations (MPOs) in hippocampal phasic theta-ON cells, whereas medial septal phasic theta-ON cells synchronize the MPOs of hippocampal phasic theta-ON cells and the discharges of hippocampal tonic theta-ON cells. Much of the time preceding the LIA to theta transition is accounted for by recruitment of these theta-related cell populations. Conversely, “turning off” the theta state occurs abruptly and involves the medial septal disinhibition of hippocampal theta-OFF cells.

Intraseptal Microinfusion of Muscimol: Effects on Hippocampal Formation Theta Field Activity and Phasic Theta-ON Cell Discharges

The effect of intraseptal microinfusions of the GABA-A agonist muscimol on spontaneously occurring or hypothalamically induced hippocampal formation (HPC) theta field activity and the simultaneously occurring discharge properties of CA1 pyramidal and dentate granule layer phasic theta-ON cells, was investigated in urethane-anesthetized rats. The microinfusion of 5.0-12.5 nmol of muscimol into the medical septum/vertical limb of the diagonal band of Broca (MS/vDBB) resulted in a progressive reduction (beginning 5 min postinfusion) in the power (amplitude) and finally the total loss of theta field activity. In contrast, theta field frequency remained unaffected during the entire postinfusion period that theta field activity was present. In the time immediately following the first 1-min intraseptal microinfusion of 5 nmol muscimol, (before changes in theta amplitude occurred) a brief period of increased phasic theta-ON cell excitability was noted. This was manifested as an increase in the number of discharges per rhythmic burst. Associated with the progressive reduction of the amplitude of theta field activity, phasic theta-ON cell discharge rates progressively decreased for a period beginning 5 min postinfusion of 5 nmol muscimol. Despite the progressive decrease in the number of discharges and a noticeable reduction in the degree of rhythmicity, phasic theta-ON cells maintained their preferred timing of discharges in relation to the phase of theta field activity, while the latter was present. Just prior to the complete abolishment of theta field activity, phasic theta-ON cells ceased discharging. During the period when theta field activity was replaced on low amplitude asynchronous activity, phasic theta-ON cells discharged in bursts correlated with every occurrence of sharp wave field activity. The results support the following conclusions: (1) the brief excitatory effect on HPC theta-ON cell discharges may be correlated pharmacologically with an initial brief increase in HPC ACh turnover. The reduction of phasic theta-ON cell discharges and theta field activity may be correlated with the longer lasting reduction of HPC ACh turnover, controlled by MS/vDBB GABA-A inputs to MS/vDBB cholinergic septohippocampal neurons, possibly along with a direct inhibition of the GABAergic septohippocampal projection; (2) the primary contribution of the MS/vDBB nuclei, as a nodal point in the ascending brainstem HPC synchronizing system, is the modulation of the amplitude of HPC formation theta field activity and secondarily to relay frequency-coded inputs from the posterior hypothalamic region (posterior and supramammillary nuclei); (3) HPC theta and sharp wave field activity represent functionally distinct neural inputs to the same population of phasic theta-ON cells located in both the CA1 pyramidal and dentate granule cell layers.

In vivo intracellular correlates of hippocampal formation theta-on and theta-off cells

Using urethane-anesthetized rat, intracellular recordings were made in hippocampal formation cells classified according to previously established criteria as either theta-on or theta-off, in order to further define the electrophysiological characteristics of these cells. Four cells classified as phasic theta-off cells had short duration spikes (less than 1 ms), high input resistances (54-61 M omega) and large fast afterhyperpolarizations (6-10 mV), thus sharing some of the properties of identified hippocampal interneurons. Phasic theta-off cells also exhibited rhythmic membrane potential oscillations (MPOs) ranging from 4 to 10 mV in amplitude during the simultaneous occurrence of extracellular theta field activity, but not during the occurrence of large amplitude irregular field activity (LIA). The MPOs of phasic theta-off cells were the same frequency as and were highly coherent with the extracellular theta field activity. In all four phasic theta-off cells the positive peak of the MPO was in phase with the positive peak of the local theta field activity. At the onset of extracellular theta field activity above 4-5 Hz, the membrane potentials of phasic theta-off cells showed a 5-10-mV hyperpolarizing shift, accompanied by MPOs without spike discharges. As theta frequency slowed down there was a return to baseline membrane potential levels and spike discharges occurred near the positive peak of the MPOs. The seven cells classified as phasic theta-on had longer duration spikes (greater than 1 ms), lower input resistances (22-36 M omega) and small (approx. 1.0 mV) fast afterhyperpolarizations, thus sharing some of the properties of hippocampal projection cells.(ABSTRACT TRUNCATED AT 250 WORDS)

Hippocampal formation is involved in movement selection: evidence from medial septal cholinergic modulation and concurrent slow-wave (theta rhythm) recording

Hippocampal rhythmical slow-wave field activity which occurs in response to sensory stimulation is predominantly cholinergic (atropine-sensitive theta rhythm), can precede movement initiation, and co-occurs during non-cholinergic theta rhythm associated with ongoing movement (atropine-resistant). This relationship suggests that theta rhythm plays some role in movement control. The present naturalistic experiments tested the idea that atropine-sensitive theta rhythm plays a role in sensory integration and planning required for initiating appropriate movements. One of a pair of hungry rats, the victim, implanted with hippocampal field recording electrodes, a septal injection cannula, and a posterior hypothalamic stimulating electrode, was given food which the other, the robber, tries to steal. Since the victim dodges from the robber with a latency, distance, and velocity dependent upon the size of the food, elapsed eating time, and proximity of the robber, the movement requires sensory integration and planning. Although eating behavior seemed normal, atropine-sensitive theta rhythm and dodging were disrupted by an infusion of a cholinergic antagonist into the medial septum. When the victim in turn attempted to steal the food back, Type 1 theta rhythm was present and robbery attempts seemed normal. Prior to cholinergic blockade, posterior hypothalamic stimulation produced theta rhythm and dodges, even in the absence of the robber, but following injections, atropine-sensitive theta rhythm and dodging were absent as the animals dropped the food and ran. The results provide the first evidence to link atropine-sensitive theta rhythm and hippocampal structures to a role in sensory integration and planning for the initiation of movement.

Impaired dodging in food-conflict following fimbria-fornix transection in rats: a novel hippocampal formation deficit

It is well known that damage to the hippocampal formation (Ammons horn, dentate gyrus, fimbria-fornix, and other pathways) produces impairments in spatial navigation and in certain forms of learning. Lesions within these structures have also been reported to produce some motor impairments, but the nature of these impairments is less understood. The present study examined the effects of fimbria-fornix lesions on food wrenching and dodging, social interactions that occur when one rat attempts to steal food from a conspecific, who in turn attempts to protect the food by an evasive movement. Lesion effectiveness was confirmed histologically and electrophysiologically, by the loss of hippocampal rhythmical slow-wave activity (RSA or theta), and by changes in open field behavior (increased open field behavior, less thigmotaxis and more defecation). Analysis of the social interaction indicated when an eating control rat was approached by a conspecific that was attempting to steal its food, it prevented the theft by dodging, a rapid lateral maneuver involving forequarter turning and stepping with the rear limbs. Rats with fimbria-fornix lesions were significantly impaired in dodging and so were more likely to lose their food to the robber. This novel deficit in motor behavior is discussed in relation to contemporary theories of hippocampal function and it is suggested that the deficit may be caused by an inability of the fimbria-fornix damaged animals to disengage attention from eating in order to initiate an evasive movement to protect food. The finding of this novel deficit underscores the importance of considering both loss as well as release phenomena in the analysis of hippocampal formation function.