Histological and ultrastructural characterization of interfascicular neurons in the rat anterior commissure

Complex Neurochemical Microstructure of the Stria Terminalis in Infant and Adult Macaque Monkey

The stria terminalis (ST) is a major bidirectional fiber tract anchored in the amygdala and bed nucleus (BNST). Extensive investigations in rodents report a complex arrangement of neurochemically diverse neurons within the ST, but fewer data are available for non-human primates. Given the functional importance of the ST, we investigated its microarchitecture in one newborn, four infant, and two adult macaque brains, by parallel immunocytochemical series for cells or fibers. Main results are as follows: (1) The pan-neuronal marker NeuN shows scattered neurons and small neuronal clusters in both the dorsal and ventral ST, but more numerous dorsally; (2) smaller neuronal subpopulations are labeled by calretinin (CR), neuropeptide Y (NPY), calbindin (CB), and somatostatin (SOM), of which the CR + neurons are the most numerous; (3) the infant brains on average have more neurons in the ST than the adult brains, but across our sample, there is notable individual variability; and (4) fiber architectonics have a complex organization, which can be referenced to myelin-poor or myelin-dense zones. Myelin-poor zones coincide with concentrations of fibers positive for CB, CR, or tyrosine hydroxylase (TH). Neurons have been reported in other white matter domains (e.g., anterior commissure, corpus callosum, cingulum bundle, and subcortical white matter). Like these, at least some neurons within the ST may give rise to long-distance connections, and/or participate in more local functions, such as vascular regulation or axon guidance/maintenance.

Development of piriform cortex interhemispheric connections via the anterior commissure: progressive and regressive strategies

The anterior commissure (AC) is a phylogenetically conserved inter-hemispheric connection found among vertebrates with bilateral symmetry. The AC connects predominantly olfactory areas but many aspects of its development and structure are unknown. To fill this gap, we investigated the embryonic and postnatal development of the AC by tracing axons with DiI and the piggyback transposon multicolor system. With this strategy, we show that axon growth during establishment of the AC follows a strictly regulated timeline of events that include waiting periods ("regressive strategies") as well as periods of active axon outgrowth ("progressive strategies"). We also provide evidence that these processes may be regulated in the midline via overexpression of chondroitin sulfate proteoglycans. Additionally, we demonstrate that the ipsi- and contralateral innervation of piriform cortex occurs simultaneously. Morphologically, we found that 20% of axons were myelinated by postnatal day (P) 22, in a process that occurred fundamentally around P14. By immunohistochemistry, we described the presence of glial cells and two new subtypes of neurons: one expressing a calretinin (CR)^-/MAP2⁺ phenotype, distributed homogeneously inside the AC; and the other expressing a CR⁺/MAP2⁺ phenotype that lies beneath the bed nucleus of the stria terminalis. Our results are consistent with the notion that the AC follows a strictly regulated program during the embryonic and postnatal development similarly to other distal targeting axonal tracts.

Transient Hypothyroidism During Lactation Arrests Myelination in the Anterior Commissure of Rats. A Magnetic Resonance Image and Electron Microscope Study

Thyroid hormone deficiency at early postnatal ages affects the cytoarchitecture and function of neocortical and telencephalic limbic areas, leading to impaired associative memory and in a wide spectrum of neurological and mental diseases. Neocortical areas project interhemispheric axons mostly through the corpus callosum and to a lesser extent through the anterior commissure (AC), while limbic areas mostly project through the AC and hippocampal commissures. Functional magnetic resonance data from children with late diagnosed congenital hypothyroidism and abnormal verbal memory processing, suggest altered ipsilateral and contralateral telencephalic connections. Gestational hypothyroidism affects AC development but the possible effect of transient and chronic postnatal hypothyroidism, as occurs in late diagnosed neonates with congenital hypothyroidism and in children growing up in iodine deficient areas, still remains unknown. We studied AC development using in vivo magnetic resonance imaging and electron microscopy in hypothyroid and control male rats. Four groups of methimazole (MMI) treated rats were studied. One group was MMI-treated from postnatal day (P) 0 to P21; some of these rats were also treated with L-thyroxine (T4) from P15 to P21, as a model for early transient hypothyroidism. Other rats were MMI-treated from P0 to P150 and from embryonic day (E) 10 to P170, as a chronic hypothyroidism group. The results were compared with age paired control rats. The normalized T2 signal using magnetic resonance image was higher in MMI-treated rats and correlated with the number and percentage of myelinated axons. Using electron microscopy, we observed decreased myelinated axon number and density in transient and chronic hypothyroid rats at P150, unmyelinated axon number increased slightly in chronic hypothyroid rats. In MMI-treated rats, the myelinated axon g-ratio and conduction velocity was similar to control rats, but with a decrease in conduction delays. These data show that early postnatal transient and chronic hypothyroidism alters AC maturation that may affect the transfer of information through the AC. The alterations cannot be recovered after delayed T4-treatment. Our data support the neurocognitive delay found in late T4-treated children with congenital hypothyroidism.

White matter in temporal lobe epilepsy: clinico-pathological correlates of water diffusion abnormalities

Using magnetic resonance imaging, it is possible to measure the behavior of diffusing water molecules, and the metrics derived can be used as indirect markers of tissue micro-architectural properties. Numerous reports have demonstrated that patients with temporal lobe epilepsy (TLE) have water diffusion abnormalities in several white matter structures located within and beyond the epileptogenic temporal lobe, showing that TLE is not a focal disorder, but rather a brain network disease. Differences in severity and spatial extent between patients with or without mesial temporal sclerosis (MTS), as well as differences related to hemispheric seizure onset, are suggestive of different pathophysiological mechanisms behind different forms of TLE, which in turn result in specific cognitive disabilities. The biological interpretation of diffusion abnormalities is based on a wealth of information from animal models of white matter damage, and is supported by recent reports that directly correlate diffusion metrics with histological characteristics of surgical specimens of TLE patients. Thus, there is now more evidence showing that the increased mean diffusivity (MD) and concomitant reductions of diffusion anisotropy that are frequently observed in several white matter bundles in TLE patients reflect reduced axonal density (increased extra-axonal space) due to smaller-caliber axons, and abnormalities in the myelin sheaths of the remaining axons. Whether these histological and diffusion features are a predisposing factor for epilepsy or secondary to seizures is still uncertain; some reports suggest the latter. This article summarizes recent findings in this field and provides a synopsis of the histological features seen most frequently in post-surgical specimens of TLE patients in an effort to aid the interpretation of white matter diffusion abnormalities.

The morphological and developmental changes of the anterior commissure of male Wistar rats submitted to protein malnutrition in the postnatal period

The aim of this project was to study the effects of protein malnutrition in the anterior commissure of male albino Wistar rats, submitted to diets with different levels of protein to evaluate the possible morphological and developmental changes of the myelinated nervous fibers and glial cells of this important neural structure during the postnatal period until 120 days of age. In this study the animals (dams and pups) were divided into three groups: the control group which received a commercial diet from the laboratory (22% protein); the nourished group which received a diet of 16% of protein (casein); and the malnourished group which received a diet of 6% of protein (casein). Rat pups were fed by lactating females during the lactation period. After weaning the pups received the same diet until 120 days of age. The results obtained showed that the malnourished animals presented less body and brain growth and important morphological changes in the anterior commissure such as the retard in the myelination, damaged myelinic nervous fibers, and the increase of the interstitial space characterizing edema and vacuolization. The current study shows that the effects of protein malnutrition in the anterior commissure cause a bigger alteration in the posterior limb of the referred commissure, indicating that it is more vulnerable to malnutrition and more susceptible to damages of the anterior limb.

Chandelier and interfascicular neurons in the adult mouse piriform cortex

The structure of two neuron types native to the adult mouse piriform cortex (PC) is described. The first cell, termed an interfascicular neuron (IFN), lies between the axon fascicles of layer I. The IFN axon divides dichotomously and daughter fibrils run horizontally in the domain of layer Ia. The frequent apposition of the IFN axon to distal dendrites of the underlying pyramidal cells suggests an en passage synaptic interaction with them. A second neuron observed in layer II, or less frequently in layer III, matched in most respects the structure of the chandelier cell (CC) described elsewhere in the neo- and archi-cortex. In the PC, chandelier cells (PC-CC) display the following peculiarities. First, the PC-CC axonal field distributes in the neuropil of layers II and III and candlesticks are in close apposition to the initial axonal segment of the pyramidal cell, although somatic interactions cannot be rule out. Second, the PC-CC ascending dendrites pierce layer I, receiving short collaterals and boutons en passage from the olfactory axons therein. The possible role of IFN's and PC-CC and their interactions with the adjacent cells is discussed in the broad context of the cellular organization of the PC.

Reelin-expressing neurons in the anterior commissure and corpus callosum of the rat

Reelin is an extracellular matrix protein, which plays a crucial role for the formation of laminated and nonlaminated structures in the central nervous system. To elucidate its roles in the postnatal brain, in the present study, we raised a polyclonal antibody specific for rat Reelin, and investigated Reelin-expressing neurons in the rat brain during the postnatal periods in detail. We found that some Reelin-expressing cells existed in the anterior commissure and corpus callosum. These Reelin-expressing cells were also immunostained with the antibody specific for neurons, but not immunostained with the antibodies specific for astrocytes nor oligodendrocytes, suggesting that these Reelin-expressing cells in the white matter are neurons. They are also immunostained with anti-GAD67 antibody, indicating that Reelin-expressing cells in the commissure systems are GABAergic neurons. Reelin-expressing neurons in the anterior commissure had many conspicuous varicosities on their dendritic arbors and mimic to the interfascicular neurons. These results suggest that Reelin may participate in the regulatory mechanism of neuronal activities through the commissure structure during the postnatal periods.

Juxtacapsular nucleus of the stria terminalis of the adult rat: Extrinsic inputs, cell types, and neuronal modules: A combined Golgi and electron microscopic study

This study unravels the microscopic organization of the juxtacapsular nucleus of the bed nuclei of the stria terminalis (Ju) by using silver impregnation and electron microscopic techniques. Examination of Golgi-impregnated specimens demonstrates that the Ju has precise boundaries primarily determined by a conical condensation of fibers of the stria terminalis (StT) around the nucleus. The internal capsule, ansa peduncularis, and medial forebrain bundle together with the StT provide extrinsic afferents to the neuropil of the Ju. Two main neuron types are found in the Ju: interneurons (including basket and neurogliaform cells) and projection neurons (bipolar and small pyramidal cells). The bipolar cell type accounts for about 80% of the sampled neurons. Short-axon neurons located within the dorsal part of the Ju send descending fibers that appear to terminate on the bipolar neurons, suggesting the existence of vertically oriented functional units within the nucleus. With the electron microscope, Ju neurons are seen in clusters of two or three neurons coupled by gap junctions. The neuropil contains numerous dendrites, axons, myelinated axons, and several types of synaptic interactions, including axospinous, axoshaft, and axosomatic. Within the neuropil, Ju neurons appear to be presynaptically modulated by axoaxonal interactions. The present findings suggest a model wherein bipolar neurons represent the output system of the Ju controlled by the interneurons, which would, in turn, be modulated by collaterals arising from the tributary fiber tracts. Additional neural interaction between Ju neurons utilizes gap junction-mediated electrotonic coupling.

Electrophysiological responses of interfascicular neurons of the rat anterior commissure to activation from the anterior olfactory nucleus, medial frontal cortex, and posterior nucleus of the amygdala

Interfascicular neurons (IFNs) of the anterior commissure (AC) include short-axon and projection types which receive inputs from commissural collaterals. Therefore, it was proposed that IFNs may play a role in processing nerve impulses arising from the forebrain and delivered by these collaterals [Brain Res. 931 (2002) 81-91]. To determine possible inputs from the forebrain to IFNs we performed extracellular recordings of 25 neurons from anesthetized adult rats. Short-latency evoked potentials in IFNs were elicited by electrical stimulation of the anterior olfactory, posterior amygdaloid nuclei (PA), and medial frontal cortex. The IFN responses showed three distinct patterns, namely, a single action potential (AP) followed by what appear to be spontaneous discharge; a burst of high-frequency APs, and a single AP followed by a period devoid of APs. The latter response which was elicited by stimulation of the PA, may be explained by an intervening inhibitory interneuron, perhaps GABAergic in nature. Finally, IFNs seem not to project back to any of these three forebrain areas, as we failed to demonstrate antidromic activation.

Electrophysiological evidence that a set of interfascicular cells of the rat anterior commissure are neurons

In mammals, the anterior commissure (AC) provides a route that interconnects homonymous areas of the basal forebrain. Recently, we reported the presence of short-axon and projection neurons among the axonal fascicles of the rat AC (i.e. interfascicular neurons; IFNs). This, coupled with the commissural inputs to these neurons, suggests that in addition to conveying nerve impulses, the AC may be a site of neural processing. To test this hypothesis, the electrophysiological activity of IFNs was recorded in adult albino rats. From extracellular recordings performed in 11 IFNs, it was found that these cells: (1), have a spontaneous discharge of a relatively low frequency (i.e. 0.04 +/- 0.1 to 5.9 +/- 3.2 spikes per second); (2), application of anodic current in the adjacent commissural fibers decreased this frequency; and (3), application of cathodic current increased the number of action potentials. Since observations made in Golgi-impregnated sections suggest that the main input to IFNs arises from their commissural collaterals, it is concluded that these cells may participate in the integration of interhemispheric nerve impulses.