Stephen L. Foote

Efferent projections of nucleus locus coeruleus: Topographic organization of cells of origin demonstrated by three-dimensional reconstruction

The present study examines the spatial distribution within rat locus coeruleus of neurons projecting to particular brain regions. In order to accurately recreate, in digital and pictorial formats, the spatial distribution of neurons for the entire nucleus locus coeruleus, three-dimensional reconstructions were created which specified the location of each individual Nissl-stained locus coeruleus cell in each of five nuclei. Dynamic computerized displays were visually analyzed and statistically compared. The nuclei from different brains were found to be strikingly similar in density and distribution of cells. In order to determine whether the cells of origin for particular locus coeruleus projections were clustered within the nucleus, reconstructions were created of the distributions of cells labeled by injections of a retrograde tracer, horseradish peroxidase, into particular terminal regions. Groups consisting of animals with injections into the same target areas were visually and statistically compared. The cells of origin of most efferent projections were found to be spatially organized within locus coeruleus. Specifically, projections to both the dorsal and ventral hippocampus originated solely from the dorsal segment of the nucleus, while spinal cord projections originated from ventral-posterior locus coeruleus. Cells of origin of cerebral and cerebellar cortical efferents, as well as hypothalamic efferents, exhibited less clustering, although reliable differences in distribution were observed. The most striking example of clustered cells of origin was exhibited by the large norepinephrine-containing cells constituting the anterior pole of locus coeruleus which were labeled only by hypothalamic injections. This analysis of spatial organization within locus coeruleus is unique in its utilization of a defined control group, experimental groups consisting of strictly defined replications, accurate three-dimensional reconstruction, and statistical comparisons. The demonstrated spatial heterogeneity of locus coeruleus neurons with respect to efferent projections can now be compared to the spatial distributions of other cellular characteristics such as soma morphology, colocalized transmitters and physiological properties. Presumably, such spatial segregation reflects the operation of functionally important organizing principles within the nucleus.

The Locus Coeruleus as a Site for Integrating Corticotropin-Releasing Factor and Noradrenergic Mediation of Stress Responsesa

Anatomic and electrophysiologic studies have provided evidence that CRF meets some of the criteria as a neurotransmitter in the noradrenergic nucleus, the locus coeruleus (LC), although some of the criteria have yet to be satisfied. Thus, immunohistochemical findings suggest that CRF innervates the LC, but this must be confirmed at the ultrastructural level. CRF alters discharge activity of LC neurons and these effects are mimicked by some stressors. Moreover, the effects of hemodynamic stress on LC activity are prevented by a CRF antagonist. However, it has not been demonstrated that stimulation of CRF neurons that project to the LC activates the LC or that the effects of such stimulation are prevented by a CRF antagonist. The role of CRF in LC activation by stressors other than hemodynamic stress needs to be determined. It could be predicted that the effects of CRF neurotransmission in the LC during stress would enhance information processing concerning the stressor or stimuli related to the stressor by LC target neurons. One consequence of this appears to be increased arousal. Although this may be adaptive in the response to an acute challenge, it could be predicted that chronic CRF release in the LC would result in persistently elevated LC discharge and norepinephrine release in targets. This could be associated with hyperarousal and loss of selective attention as occurs in certain psychiatric diseases. Manipulation of endogenous CRF systems may be a novel way in which to treat psychiatric diseases characterized by these maladaptive effects.

Loss of pigmented dopamine-β-hydroxylase positive cells from locus coeruleus in senile dementia of alzheimer's type

Serial sections of human brainstem were used to determine the total number of pigmented cells in locus coeruleus and, by immunohistochemical staining using an antiserum directed against human dopamine-beta-hydroxylase (DBH), the number of DBH-positive cells. In 12 brains from elderly control and dementia subjects there wer not significant differences in the total cell populations determined in the same brain by the two techniques. In 6 patients with senile dementia of Alzheimers type there was a variable loss (average about 60% reduction) in locus coeruleus cells when compared to controls of similar age. The loss of noradrenergic neurones from locus coeruleus was accompanied by an average reduction of similar magnitude in noradrenaline concentration in temporal cortex, with no change or an increase in dopamine content. There was also a significant reduction in the cholinergic marker choline acetyltransferase in cortex samples from the dementia cases.

Efferent projections of nucleus locus coeruleus: Morphologic subpopulations have different efferent targets

This study quantitatively addresses the hypothesis that there is a systematic relationship between the morphologic characteristics of locus neurons and the particular target regions they innervate. Following horseradish peroxidase injections into selected terminal fields, locus coeruleus cell bodies are heavily labeled by retrograde transport so that somata size and shape, and in many cases primary dendritic pattern can be observed. This allows the classification of neurons as one of six cell types: large multipolar cells within ventral locus coeruleus, large multipolar cells in the anterior pole of locus coeruleus, fusiform cells in dorsal LC, posterior pole cells, medium-sized multipolar cells (termed core cells in this report), and small round cells. It was found that while core cells contribute to the innervation of all terminal fields examined, other cell types project to more restricted sets of targets. The contributions of each type to selected efferents are presented in detail. In particular, fusiform cells project to hippocampus and cortex, large multipolar cells in ventral locus coeruleus project to spinal cord and cerebellum, and small round cells in central and anterior locus coeruleus, as well as large multipolar cells in anterior locus coeruleus, project to hypothalamus. These results, in conjunction with those described in the preceding report, indicate that locus coeruleus is intrinsically organized with respect to efferent projections with much more specificity than has previously been evident. This high degree of organization is consistent with other recent demonstrations of functional specificity exhibited by locus coeruleus neurons.

Distribution of dopamine beta-hydroxylase-like immunoreactive fibers within the shell subregion of the nucleus accumbens.

The nucleus accumbens (Acb) can be divided into distinct subfields, delineated on the basis of histochemical markers as well as by afferent and efferent projection patterns. The shell subregion has reciprocal relationships with a variety of limbic areas and brainstem autonomic structures, and has been suggested to participate in motivation‐related processes, including reward, stress, and arousal. The locus coeruleus (LC)‐noradrenergic system has similarly been implicated in the modulation of behavioral state and stress‐related processes, and previous studies have demonstrated reciprocal projections between the locus coeruleus and Acb shell. To better understand the anatomical substrate through which LC could influence activity within Acb shell, immunohistochemical methods were used to visualize the extent and the distribution of noradrenergic axons within this structure. Coronal sections of rat brain were processed to visualize immunoreactivity for the norepinephrine synthetic enzyme dopamine β‐hydroxylase (DBH), a specific marker for noradrenergic processes. In some cases, alternate sections were processed for immunohistochemical localization of substance P, in order to delineate core, shell, and pallidal compartments. Moderate‐to‐dense DBH‐like immunoreactivity (DBHir) was found in approximately the caudal half of the shell subregion, particularly in caudalmost (septal pole) and ventral zones. The innervation of the septal pole was contiguous with a dense innervation of the bed nucleus of the stria terminalis. Few immunoreactive fibers were observed in the caudate‐putamen, Acb core, or rostral Acb shell. Many DBHir fibers within the shell region were highly arborized with numerous varicosities, features indicative of terminal fields. These observations suggest noradrenergic systems might modulate certain processes associated with stress, behavioral state, or reinforcement via actions within the Acb shell. Synapse 27:230–241, 1997.

Laminar, tangential and regional organization of the noradrenergic innervation of monkey cortex: Dopamine-β-hydroxylase immunohistochemistry

An antiserum directed against human dopamine-beta-hydroxylase purified from pheochromocytoma tissue was employed in an immunohistochemical study of the organization of the noradrenergic innervation of monkey neocortex. A detailed description is given of the laminar pattern of noradrenergic innervation in the dorsolateral prefrontal cortex (Brodmann areas 9 and 10) and the primary somatosensory cortex of the postcentral gyrus (Brodmann areas 3,1,2). The noradrenergic innervation of these two regions is similar in the following respects: (1) fibers are present in all six layers, (2) the innervation is dense and terminal-like in layers IV and V, and (3) layer VI is characterized by fibers oriented parallel to the pial surface which follow the contours of the subcortical white matter. However, these regions differ with respect to specific laminar patterns of fiber distribution and orientation and by virtue of the fact that the primary somatosensory cortex has a very dense noradrenergic innervation, while the density of innervation in dorsolateral prefrontal cortex is low relative to the postcentral gyrus and most other neocortical areas. The laminar pattern of noradrenergic innervation in primary visual cortex differs fundamentally from both prefrontal and primary somatosensory cortices. In a separate series of experiments, dorsolateral frontal cortex lesions were used to investigate the intracortical trajectory of noradrenergic fibers. A discrete aspiration lesion confined to the grey matter of the prefrontal cortex led to a substantial loss of noradrenergic fibers in cortical regions caudal to the lesion. The decrease in density of noradrenergic innervation was particularly pronounced in the pre- and postcentral gyri. These results demonstrate that while the noradrenergic innervation of primate cortex exhibits a far greater degree of regional variation than is present in the rat cortex, the tangential intracortical trajectory that is characteristic of the lissencephalic rat brain is also a dominant feature of the noradrenergic innervation of the gyrencephalic primate brain.

Effects of locus coeruleus inactivation on electroencephalographic activity in neocortex and hippocampus

The effects of inhibition of locus coeruleus neuronal discharge activity on cortical and hippocampal electroencephalographic activity were examined in halothane-anesthetized rats. A combined recording/infusion probe was used to place 35-150-nl infusions of the alpha 2-noradrenergic agonist, clonidine (1 ng/nl) which inhibits locus coeruleus neuronal discharge activity, immediately adjacent to the locus coeruleus. The recording electrode allowed verification and quantification of the electrophysiological effects of these infusions. Simultaneously, electroencephalographic activity was recorded from sites in frontal neocortex and dorsal hippocampus and subjected to power spectrum analyses. Neither cortical nor hippocampal electroencephalographic activity was substantially affected following unilateral locus coeruleus inactivation. In contrast, bilateral clonidine infusions that completely suppressed locus coeruleus neuronal discharge activity in both hemispheres altered cortical and hippocampal electroencephalographic status. The cortical response to bilateral LC inhibition was characterized by a shift from low-amplitude, high-frequency to large-amplitude, slow-wave activity. Additionally, theta-dominated activity in the hippocampus was replaced with mixed frequency activity. The onset of these changes in forebrain electroencephalographic activity was coincident with the complete bilateral inhibition of locus coeruleus neuronal discharge activity. The resumption of pre-infusion electroencephalographic patterns closely followed recovery of locus coeruleus neuronal activity or could be induced with systemic administration of the alpha 2-noradrenergic antagonist, idazoxan. Clonidine infusions placed 800-1200 microns from the locus coeruleus were less effective at inducing a complete suppression of locus coeruleus activity. These infusions either did not completely inhibit locus coeruleus discharge (35 nl infusions), or did so with a longer latency to complete locus coeruleus inhibition and a shorter duration of inhibition (150 nl infusions). Changes in forebrain electroencephalographic activity occurred only following the complete bilateral suppression of locus coeruleus neuronal discharge activity. These electroencephalographic responses closely followed or coincided with the onset of complete bilateral locus coeruleus inhibition and persisted throughout the period during which bilateral LC neuronal discharge activity was completely absent (60-240 min). Recovery of electroencephalographic patterns was coincident with the reappearance of locus coeruleus discharge activity. These results suggest that the clonidine-induced changes in forebrain electroencephalographic activity were dependent on the complete bilateral suppression of locus coeruleus discharge activity, and that under the present experimental conditions the locus coeruleus/noradrenergic system exerts a potent and tonic activating influence on forebrain electroencephalographic state. These results support the hypothesis that this system may be an important modulator of behavioral state and/or state-dependent processes.

The dopaminergic innervation of monkey prefrontal cortex: a tyrosine hydroxylase immunohistochemical study.

The distribution of tyrosine hydroxylase (TH)-immunoreactive fibers was characterized immunohistochemically in the prefrontal cortical regions of both Old World cynomolgus monkeys (Macaca fascicularis) and New World squirrel monkeys (Saimiri sciureus). In both species, differences in the density and/or laminar distribution of TH-labeled fibers were detected both across and within almost every prefrontal cytoarchitectonic region. In cynomolgus monkeys, areas 9 and 24 had the greatest density of TH-labeled fibers, areas 11, 12, 13 and 25 were of intermediate density, and areas 10 and 46 had the lowest density of immunoreactive fibers. Differences in fiber density within many of these regions were also consistently observed. On a laminar basis, the distribution of labeled fibers in a given area of cynomolgus prefrontal cortex was systematically related to the overall fiber density of that area. For example, in the lightly innervated fundus of the principal sulcus (area 46), labeled fibers were primarily present in layer I and layers V-VI, whereas in area 9, the most densely innervated region, TH-labeled fibers were present in all cortical layers. Similar regional differences in the density and laminar distribution of TH-immunoreactive fibers were also present in squirrel monkey prefrontal cortex. In previous studies, we have analyzed the regional and laminar distributions of fibers immunoreactive for TH and dopamine-beta-hydroxylase (DBH), a specific marker for noradrenergic cortical fibers, in multiple areas of cortex from both normal and locus ceruleus-lesioned animals. These comparisons, which have been confirmed in the present report, indicate that anti-TH and anti-DBH label distinct populations of axons in monkey neocortex, which presumably are dopaminergic and noradrenergic, respectively. Thus, the distribution of TH immunoreactivity described in the present report suggests that dopaminergic fibers are distributed in a very heterogeneous fashion in monkey prefrontal cortex. The distinctive innervation patterns exhibited by these fibers reveal the regions and layers that may be the principle sites of action of dopamine in exerting its effects on prefrontal cortical function.

Corticotropin-Releasing Factor Disrupts Sensory Responses of Brain Noradrenergic Neurons

In order to elucidate the possible role of noradrenergic neurons of the nucleus locus coeruleus (LC) in stress responses, the effects of corticotropin-releasing factor (CRF) on LC neuronal activity were characterized. In haloth-aneanesthetized rats, intracerebroventricular administration of CRF was found to have two distinct actions: A dose-dependent increase in spontaneous discharge activity was observed 3 min after peptide injection, with 1.0 and 3.0 micrograms CRF increasing activity by 7 +/- 2 and 47 +/- 12%, respectively; Ala14CRF (3.0 micrograms), an inactive analogue of CRF, had no effect on LC spontaneous discharge rates. These results confirm and extend previous studies of CRF activation of LC basal discharge activity; additionally, CRF (1.0 and 3.0 micrograms) disrupted sensory responses of LC cells to sciatic nerve stimulation. As previously reported, responses of LC neurons to electrical stimulation of the sciatic nerve usually consisted of a brief activation beginning 20-40 ms after stimulus followed by a period of relatively suppressed activity lasting 100-200 ms. CRF attenuated both components. Responses plotted as normalized, cumulative histograms became more linear in the presence of CRF (1.0 and 3.0 micrograms), suggesting that discharge rates during phasic responses to sciatic stimulation were similar to spontaneous rates. Statistical comparison using the Kolmogorov-Smirnoff test or correlation coefficients demonstrated that both 1.0 and 3.0 micrograms CRF reduced response components, while 0.3 micrograms and Ala14CRF (3.0 micrograms) had no effect. The degree of attenuation of LC sensory responses by CRF was not linearly related to the magnitude of CRF-induced increases in spontaneous discharge rate, suggesting that these are distinct effects of CRF.(ABSTRACT TRUNCATED AT 250 WORDS)

Low doses of ethanol disrupt sensory responses of brain noradrenergic neurones

Ethanol is a widely abused drug which has many behavioural and psychological effects1. In spite of considerable research1–4, the brain mechanisms responsible for these effects are unknown. Previously, it has been proposed that noradrenaline (NA)-containing locus coeruleus (LC) neurones, which project throughout the brain5,6, mediate the effects of many abused as well as clinically effective psychoactive agents7,8. Recent studies9–11 have shown that in freely behaving, undrugged animals, NA-containing LC (NA-LC) neurones exhibit marked, short-latency responses to sensory stimuli of many modalities, perhaps serving to bias brain and behavioural activities towards adaptive responses to phasic, unexpected environmental events. We have now examined the effects of ethanol on these sensory responses of NA-LC neurones. In the present study, anaesthetized animals were used to minimize fluctuations in arousal, providing a more stable baseline for assessing pharmacological effects. A class of NA-LC sensory responses which mimic those observed in unanaesthetized animals was studied. In addition, using antidromic stimulation, we investigated the effects of ethanol on the soma excitability, axonal conduction velocity, and strength of recurrent collateral inhibition of these neurones. We now report that low intoxicating doses of ethanol substantially reduce the magnitude and temporal reliability of sensory-evoked responses in NA-LC neurones, perhaps due in part to enhanced feedback inhibition of these cells.