Francisco Clascá

Insular cortex and neighboring fields in the cat: A redefinition based on cortical microarchitecture and connections with the thalamus

The insular areas of the cerebral cortex in carnivores remain vaguely defined and fragmentarily characterized. We have examined the cortical microarchitecture and thalamic connections of the insular region in cats, as a part of a broader study aimed to clarify their subdivisions, functional affiliations, and eventual similarities with other mammals. We report that cortical areas, which resemble the insular fields of other mammals, are located in the cats orbital gyrus and anterior rhinal sulcus. Our data suggest four such areas: (a) a “ventral agranular insular area” in the lower bank of the anterior rhinal sulcus, architectonically transitional between iso‐ and allocortex and sparsely connected to the thalamus, mainly with midline nuclei; (b) a “dorsal agranular insular area” in the upper bank of the anterior rhinal sulcus, linked to the mediodorsal, ventromedial, parafascicular and midline nuclei; (c) a “dysgranular insular area” in the anteroventral half of the orbital gyrus, characterized by its connections with gustatory and viscerosensory portions of the ventroposterior complex and with the ventrolateral nucleus; and (d) a “granular insular area”, dorsocaudal in the orbital gyrus, which is chiefly bound to spinothalamic‐recipient thalamic nuclei such as the posterior medial and the ventroposterior inferior. Three further fields are situated caudally to the insular areas. The anterior sylvian gyrus and dorsal lip of the pseudosylvian sulcus, which we designate “anterior sylvian area”, is connected to the ventromedial, suprageniculate, and lateralis medialis nuclei. The fundus and ventral bank of the pseudosylvian sulcus, or “parainsular area”, is associated with caudal portions of the medial geniculate complex. The rostral part of the ventral bank of the anterior ectosylvian sulcus, referred to as “ventral anterior ectosylvian area”, is heavily interconnected with the lateral posterior‐pulvinar complex and the ventromedial nucleus. Present results reveal that these areas interact with a wide array of sensory, motor, and limbic thalamic nuclei. In addition, these data provide a consistent basis for comparisons with cortical fields in other mammals. J. Comp. Neurol. 384:456–482, 1997.

Extracellular matrix molecules and synaptic plasticity : immunomapping of intracellular and secreted reelin in the adult rat brain

Reelin, a large extracellular matrix glycoprotein, is secreted by several neuron populations in the developing and adult rodent brain. Secreted Reelin triggers a complex signaling pathway by binding lipoprotein and integrin membrane receptors in target cells. Reelin signaling regulates migration and dendritic growth in developing neurons, while it can modulate synaptic plasticity in adult neurons. To identify which adult neural circuits can be modulated by Reelin‐mediated signaling, we systematically mapped the distribution of Reelin in adult rat brain using sensitive immunolabeling techniques. Results show that the distribution of intracellular and secreted Reelin is both very widespread and specific. Some interneuron and projection neuron populations in the cerebral cortex contain Reelin. Numerous striatal neurons are weakly immunoreactive for Reelin and these cells are preferentially located in striosomes. Some thalamic nuclei contain Reelin‐immunoreactive cells. Double‐immunolabeling for GABA and Reelin reveals that the Reelin‐immunoreactive cells in the visual thalamus are the intrinsic thalamic interneurons. High local concentrations of extracellular Reelin selectively outline several dendrite spine‐rich neuropils. Together with previous mRNA data, our observations suggest abundant axoplasmic transport and secretion in pathways such as the retino‐collicular tract, the entorhino‐hippocampal (‘perforant’) path, the lateral olfactory tract or the parallel fiber system of the cerebellum. A preferential secretion of Reelin in these neuropils is consistent with reports of rapid, activity‐induced structural changes in adult brain circuits.

Mapping of fluorescent protein-expressing neurons and axon pathways in adult and developing Thy1-eYFP-H transgenic mice

Transgenic mouse lines in which a fluorescent protein is constitutively expressed under the Thy1 gene promoter have become important models in cell biology and pathology studies of specific neuronal populations. As a result of positional insertion and/or copy number effects on the transgene, the populations expressing the fluorescent protein (eYFP+) vary markedly among the different mice lines. However, identification of the eYFP+ subpopulations has remained sketchy and fragmentary even for the most widely used lines such as Thy1-eYFP-H mice (Feng, G., Mellor, R.H., Bernstein, M., Keller-Peck, C., Nguyen, Q.T., Wallace, M., Nerbonne, J.M., Lichtman and J.W., Sanes. J.R. 2000. Imaging neuronal subsets in transgenic mice expressing multiple spectral variants of GFP. Neuron 28, 41-51). Here, we provide a comprehensive mapping of labeled cell types throughout the central nervous system in adult and postnatal (P0-P30) Thy1-eYFP-H mice. Cell type identification was based on somatodendritic morphology, axon trajectories, and, for cortical cells, retrograde labeling with Fast Blue to distinguish between subpopulations with different axonal targets. In the neocortex, eYFP+ cells are layers 5 and 6 pyramidal neurons, whose abundance and sublaminar distribution varies markedly between areas. Labeling is particularly prevalent in the corticospinal cells; as a result, the pyramidal pathway axons are conspicuously labeled down to the spinal cord. Large populations of hippocampal, subicular and amygdaloid projection neurons are eYFP+ as well. Additional eYFP+ cell groups are located in specific brainstem nuclei. Present results provide a comprehensive reference dataset for adult and developmental studies using the Thy1-eYFP-H mice strain, and show that this animal model may be particularly suitable for studies on the cell biology of corticospinal neurons.

Unveiling the diversity of thalamocortical neuron subtypes

Our current understanding of thalamocortical (TC) circuits is largely based on studies investigating so‐called ‘specific’ thalamic nuclei, which receive and transmit sensory‐triggered input to specific cortical target areas. TC neurons in these nuclei have a striking point‐to‐point topography and a stereotyped laminar pattern of termination in the cortex, which has made them ideal models to study the organization, plasticity, and development of TC circuits. However, despite their experimental importance, neurons within these nuclei only represent a fraction of all thalamic neurons and do not reflect the diversity of the TC neuron population. Here we review the distinct subtypes of projection neurons that populate the thalamus, both within and across anatomically‐defined nuclei, with regard to differences in their morphology, input/output connectivity and target specificity, as well as more recent findings on their neuron type‐specific gene expression and development. We argue that a detailed understanding of the biology of TC neurons is critical to understand the role of the thalamus in normal and pathological perception, voluntary movement, cognition and attention.

Reelin-Immunoreactive Neurons, Axons, and Neuropil in the Adult Ferret Brain: Evidence for Axonal Secretion of Reelin in Long Axonal Pathways

Reelin is a large secretable protein which, when developmentally defective, causes the reeler brain malformation in mice and a recessive form of lissencephaly with cerebellar hypoplasia in humans. In addition, Reelin is heavily expressed throughout the adult brain, although its function/s there are still poorly understood. To gain insight into which adult neuronal circuits may be under the influence of Reelin, we systematically mapped Reelin‐immunoreactive neuronal somata, axons, and neuropil in the brain and brainstem of ferrets. Results show that Reelin immunoreactivity is found in widespread but specific sets of neuronal bodies, axonal tracts, and gray matter neuropil regions. Depending on the region, the immunoreactive neuronal somata correspond to interneurons, projection neurons, or both. Some well‐defined axonal projection systems are immunoreactive, whereas most other white matter tracts are unlabeled. The labeled pathways include, among others, the lateral olfactory tract, the entorhinohippocampal (perforant) pathway, the retroflex bundle, and the stria terminalis. Labeled axons in these tracts contain large numbers of discrete, very small, immunoreactive particles, suggestive of secretory vesicles under the light microscope. The neuropil in the terminal arborization fields of these axons is also heavily immunoreactive. Taken together, our observations are consistent with the notion that some neurons may anterogradely transport Reelin along their axons in large membrane‐bound secretory vesicles (Derer et al. [ 2001 ] J. Comp. Neurol. 440:136–143) and secrete it into their terminal arborization fields, which may be quite distant from the somata synthesizing the protein. These findings have implications for identifying where Reelin acts in adult brain circuits. J. Comp. Neurol. 463:92–116, 2003.

Reelin immunoreactivity in the adult neocortex: a comparative study in rodents, carnivores, and non-human primates

Recent evidence indicates that, in addition to playing a crucial role in early cortical development, intercellular signaling mediated by the protein Reelin may be widely active in the adult neocortex. The extent of Reelin distribution and its functional role in the adult are not clear yet. Here, we have examined Reelin immunoreactivity in the neocortex of an adult rodent (rat, Rattus norvegicus), a carnivore (ferret, Mustela putorius), and a primate (macaque monkeys Macaca nemestrina, Macaca mulatta) at the optic microscope level. Our data show that the neocortex of all three species contains several morphologically distinct populations of interneurons whose perikaryon and proximal dendritic processes are heavily immunoreactive for Reelin. The laminar distribution of these cells is species-specific. In addition, discrete reelin-immunoreactive pericellular structures are present in virtually all neocortical neurons of macaques.

Long-range projection neurons of the mouse ventral tegmental area: a single-cell axon tracing analysis

Pathways arising from the ventral tegmental area (VTA) release dopamine and other neurotransmitters during the expectation and achievement of reward, and are regarded as central links of the brain networks that create drive, pleasure, and addiction. While the global pattern of VTA projections is well-known, the actual axonal wiring of individual VTA neurons had never been investigated. Here, we labeled and analyzed the axons of 30 VTA single neurons by means of single-cell transfection with the Sindbis-pal-eGFP vector in mice. These observations were complemented with those obtained by labeling the axons of small populations of VTA cells with iontophoretic microdeposits of biotinylated dextran amine. In the single-cell labeling experiments, each entire axonal tree was reconstructed from serial sections, the length of terminal axonal arbors was estimated by stereology, and the dopaminergic phenotype was tested by double-labeling for tyrosine hydroxylase immunofluorescence. We observed two main, markedly different VTA cell morphologies: neurons with a single main axon targeting only forebrain structures (FPN cells), and neurons with multibranched axons targeting both the forebrain and the brainstem (F + BSPN cells). Dopaminergic phenotype was observed in FPN cells. Moreover, four “subtypes” could be distinguished among the FPN cells based on their projection targets: (1) “Mesocorticolimbic” FPN projecting to both neocortex and basal forebrain; (2) “Mesocortical” FPN innervating the neocortex almost exclusively; (3) “Mesolimbic” FPN projecting to the basal forebrain, accumbens and caudateputamen; and (4) “Mesostriatal” FPN targeting only the caudateputamen. While the F + BSPN cells were scattered within VTA, the mesolimbic neurons were abundant in the paranigral nucleus. The observed diversity in wiring architectures is consistent with the notion that different VTA cell subpopulations modulate the activity of specific sets of prosencephalic and brainstem structures.

Specific activation of the paralemniscal pathway during nociception

Two main neuronal pathways connect facial whiskers to the somatosensory cortex in rodents: (i) the lemniscal pathway, which originates in the brainstem principal trigeminal nucleus and is relayed in the ventroposterior thalamic nucleus and (ii) the paralemniscal pathway, originating in the spinal trigeminal nucleus and relayed in the posterior thalamic nucleus. While lemniscal neurons are readily activated by whisker contacts, the contribution of paralemniscal neurons to perception is less clear. Here, we functionally investigated these pathways by manipulating input from the whisker pad in freely moving mice. We report that while lemniscal neurons readily respond to neonatal infraorbital nerve sectioning or whisker contacts in vivo, paralemniscal neurons do not detectably respond to these environmental changes. However, the paralemniscal pathway is specifically activated upon noxious stimulation of the whisker pad. These findings reveal a nociceptive function for paralemniscal neurons in vivo that may critically inform context‐specific behaviour during environmental exploration.

Connectomic Analysis of Brain Networks : Novel Techniques and Future Directions

Brain networks, localized or brain-wide, exist only at the cellular level, i.e., between specific pre- and post-synaptic neurons, which are connected through functionally diverse synapses located at specific points of their cell membranes. “Connectomics” is the emerging subfield of neuroanatomy explicitly aimed at elucidating the wiring of brain networks with cellular resolution and a quantified accuracy. Such data are indispensable for realistic modeling of brain circuitry and function. A connectomic analysis, therefore, needs to identify and measure the soma, dendrites, axonal path, and branching patterns together with the synapses and gap junctions of the neurons involved in any given brain circuit or network. However, because of the submicron caliber, 3D complexity, and high packing density of most such structures, as well as the fact that axons frequently extend over long distances to make synapses in remote brain regions, creating connectomic maps is technically challenging and requires multi-scale approaches, Such approaches involve the combination of the most sensitive cell labeling and analysis methods available, as well as the development of new ones able to resolve individual cells and synapses with increasing high-throughput. In this review, we provide an overview of recently introduced high-resolution methods, which researchers wanting to enter the field of connectomics may consider. It includes several molecular labeling tools, some of which specifically label synapses, and covers a number of novel imaging tools such as brain clearing protocols and microscopy approaches. Apart from describing the tools, we also provide an assessment of their qualities. The criteria we use assess the qualities that tools need in order to contribute to deciphering the key levels of circuit organization. We conclude with a brief future outlook for neuroanatomic research, computational methods, and network modeling, where we also point out several outstanding issues like structure–function relations and the complexity of neural models.

Subset of Cortical Layer 6b Neurons Selectively Innervates Higher Order Thalamic Nuclei in Mice.

Abstract The thalamus receives input from 3 distinct cortical layers, but input from only 2 of these has been well characterized. We therefore investigated whether the third input, derived from layer 6b, is more similar to the projections from layer 6a or layer 5. We studied the projections of a restricted population of deep layer 6 cells (“layer 6b cells”) taking advantage of the transgenic mouse Tg(Drd1a-cre)FK164Gsat/Mmucd (Drd1a-Cre), that selectively expresses Cre-recombinase in a subpopulation of layer 6b neurons across the entire cortical mantle. At P8, 18% of layer 6b neurons are labeled with Drd1a-Cre::tdTomato in somatosensory cortex (SS), and some co-express known layer 6b markers. Using Cre-dependent viral tracing, we identified topographical projections to higher order thalamic nuclei. VGluT1+ synapses formed by labeled layer 6b projections were found in posterior thalamic nucleus (Po) but not in the (pre)thalamic reticular nucleus (TRN). The lack of TRN collaterals was confirmed with single-cell tracing from SS. Transmission electron microscopy comparison of terminal varicosities from layer 5 and layer 6b axons in Po showed that L6b varicosities are markedly smaller and simpler than the majority from L5. Our results suggest that L6b projections to the thalamus are distinct from both L5 and L6a projections.