Layer-specific innervation of the dopamine-deficient frontal cortex in weaver mutant mice by grafted mesencephalic dopaminergic neurones

Summary The dopamine innervation of the frontal cortex originates in the A9 and A10 mesencephalic dopamine cell groups. In weaver mutant mice, there is a 77% frontocortical dopamine deficiency associated with losses of dopamine neurones in areas A9 and A10. The dopamine-depleted cortical areas of weaver mutant mice are receptive to reinnervation by afferent fibres originating in dopamine-containing mesencephalic grafts from normal donor embryos. In the anteromedial frontal lobe, reinnervation by tyrosine hydroxylase immunoreactive fibres is largely confined to the basal cortical layers whereas in the anterior cingulate cortex, tyrosine hydroxylase immunoreactive fibres also occupy superficial layers, including the molecular layer. Normally, the dopaminergic innervation of the anteromedial frontal lobe is distributed among the basal cortical layers (IV–VI), and the dopaminergic innervation of the cingulate cortex occupies both basal and superficial cortical layers. The pattern of innervation following transplantation indicates that, in repopulating dopamine-deficient cortical areas of recipient weaver mutants, graft-derived dopamine fibres show a preference for those layers which are normally invested by dopamine afferents.     

A quantitative ultrastructural study of the honeybee antennal lobe

This paper describes the ultrastructural organization of the honeybee antennal lobe, including the distribution of synapses within the antennal lobe neuropile and the distribution of the afferent fibres in the antennal nerve and its afferent tracts. We show that: 1) The antennal nerve and tracts T3-T6 are composed of a heterogeneous population of fibres, with respect to their diameters, whereas two afferent tracts (T1 and T2) are composed of fibres of almost homogeneous diameter. 2) Synapses are mainly localized in the glomeruli with a higher frequency in the cortical layer than in the core of the glomerulus. Nevertheless a few synapses are found in the coarse neuropile. 3) Reciprocal synapses have been identified in the cortical layer. At the ultrastructural level, the organization of the bee antennal lobe was largely unknown and these results bring the anatomical background needed in order to carry out a developmental study related to the bee antennal lobe structures.     

Spinal, thalamic and cortical levels of splanchno-splanchnic interactions]

Using the occlusion method, we have shown splanchno splanchnic interactions on spinal, thalamic and cortical cells in cat. 1. At the first level, splanchno splanchnic interactions concern only the cells located in the Rexed V layer. The splanchnic fibres involved are small sized ones (Agammadelta, B and C types). 2. At the second level, splanchno splanchnic interactions have been observed in the VPL nucleus. The latencies of responses suggest that only large fibres are concerned. 3. At the third level, cortical cells of SI and SII areas have been studied. Splanchno splanchnic interactions have been elicited by different afferent splanchnic fibres (medullated and non medullated ones).     

The structure of the first auditory cortex (A I) in the cat. I.--Light microscopic observations on its organization

The cyto- and mieloarchitecture of the first auditory cortex (A I) was studied in the cat. The cortical layers II, III and IV are very densely populated by relatively uniform, round or stellate cells with 20 to 30 micro perikaryal diameter. The separation between these three layers, which is not possible in Nissl stained sections, becomes visible in 1 to 3 micro thick sections of plastic embedded material. nerve cells in layer II are randomly disposed, whilst they form in laver III loose rounded cellular groups, and in layer IV vertical cylinders which have 50 to 60 micro in outside diameter and a cell poor centre. These cylinders are best visible in 100 micro thick Nissl preparations, cut parallel to the pial surface. The cylinders may extend into layer V, which is comparatively cell poor. The VIth layer contains numerous round, stellate or fusiform cells with 20 to 30 micro in diameter. The IIIrd and Vth layers have few pyramidal perikarya which are small. Large or giant pyramidal cells are not found in A I. The overall thickness of the cortex in the convexity of A I is 2,000 micro, measured in sections of plastic blocks. The thickness of the 6 layers is 200 to 250 micro for layer I; 300 micro for layer II; 300 micro for layer III; 300 to 400, for layer IV; 350 micro for layer V; and 400 micro for layer VI. In preparations stained for myelin sheats A I is characterized by the presence of a very dense plexus of fibres running in all directions in the IVth, Vth anti VIth layers. These plexus obscurs the radiations of Meynert, giving a characteristic appearance to A I, since these radiations are prominent in the neighbouring cortical areas. In preliminary studies of Golgi rapid preparations of A I the cell types commonly present in others cortical areas were found. Pyramidal cells have small perikarya, and very long (600 micro) horizontal basal dendrites. Modified pyramidal cells (star pyramids) are the main cellular element in layer II and constitute one of the main sources of efferent fibres of A I. Several types of stellate cells were found, including a particular cell type, found very often in the IVth layer, with a very long horizontal axon. The specific thalamic afferents were identified as fibres with 5 or 8 micro in diameter, which run obliquely and sinuously through the VIth and Vth layers of A I. These fibres give off many branches with 1 to 2 micro in diameter, which pass to the IVth layer where they give off very thin sinuous branches, ending in small terminal knobs. The ramification of one of these fibres may spread horizontally over 800 micros, at the level of the IVth layer.     

The effect of destroying the whisker follicles in mice on the sensory nerve, the thalamocortical radiation and cortical barrel development.

Electrolytic destruction of whisker follicles in mice on the day of birth has been found to cause degeneration in the sensory nerve fibres supplying the follicles. The severity of the degeneration has been assessed in animals between 2 and 20 days old by counting the total number of myelinated fibres in the maxillary nerves on both normal and lesioned sides. The degeneration is apparent after 2 days and by 20 days the nerve on the lesioned side contains only 38% of the normal fibre content. This degeneration has also been shown to involve the trigeminal root, central to the ganglion. In addition, the lesioning procedure modifies the terminations of thalamocortical fibres in the barrel region of the sensory cortex. These terminations are normally in clusters, each corresponding to a barrel, but, after lesioning the follicles, the terminals appear to be evenly distributed in layer IV and cortical barrel structures no longer develop. In postnatal mice, electrolytic destruction of whisker follicles had less effect upon maxillary nerve fibres and cortical barrels. The number of myelinated axons surviving until day 20 increased progressively with later lesioning to reach nearly 80% of the control level when lesions were made on day 10. Cortical barrels became secure earlier than the maxillary nerve, for a normal number of cortical barrels was present at day 12 when follicles were destroyed on day 4. The implications of these results for the formation of cortical barrels is discussed.     

Analysis of the efferent projections of the lateral geniculate nucleus with special reference to the innervation of the subcommissural organ and related areas

In order to define central neurons projecting to the subcommissural organ (SCO) and to related areas in the postero-medial diencephalon, Phaseolus vulgaris-leucoagglutinin (PHA-L) was injected into the lateral geniculate nucleus of the rat. PHA-L-labelled neurons send axonal processes medially through the posterior thalamic nuclei and the posterior commissure to the other hemisphere. Branches of fibres originating from this projection form a plexus of nerve terminals in the underlying precommissural nucleus and in the nucleus of the posterior commissure. A small number of PHA-L-immunoreactive nerve fibres penetrate from the precommissural nucleus into the lateral part of the SCO. A few labelled fibres penetrate directly from the posterior commissure into the medial part of the caudal SCO. Most of the PHA-L-immunoreactive fibres occur in the hypendymal layer, although a few terminate near the ependymal cells of the organ. Many labelled fibres are found in the ventricular ependyma adjacent to the SCO, some fibres lying close to the ventricular lumen. These results were obtained only if the tracer was delivered into the intergeniculate leaflet of the lateral geniculate nucleus (IGL). The IGL innervates both the suprachiasmatic nucleus and the pineal organ; the connections between the IGL and the midline structures, including the SCO, suggest that these areas are influenced by the circadian system.     

Form and motion coherence activate independent, but not dorsal/ventral segregated, networks in the human brain

There is much evidence in primates' visual processing for distinct mechanisms involved in object recognition and encoding object position and motion, which have been identified with 'ventral' and 'dorsal' streams, respectively, of the extra-striate visual areas [1] [2] [3]. This distinction may yield insights into normal human perception, its development and pathology. Motion coherence sensitivity has been taken as a test of global processing in the dorsal stream [4] [5]. We have proposed an analogous 'form coherence' measure of global processing in the ventral stream [6]. In a functional magnetic resonance imaging (fMRI) experiment, we found that the cortical regions activated by form coherence did not overlap with those activated by motion coherence in the same individuals. Areas differentially activated by form coherence included regions in the middle occipital gyrus, the ventral occipital surface, the intraparietal sulcus, and the temporal lobe. Motion coherence activated areas consistent with those previously identified as V5 and V3a, the ventral occipital surface, the intraparietal sulcus, and temporal structures. Neither form nor motion coherence activated area V1 differentially. Form and motion foci in occipital, parietal, and temporal areas were nearby but showed almost no overlap. These results support the idea that form and motion coherence test distinct functional brain systems, but that these do not necessarily correspond to a gross anatomical separation of dorsal and ventral processing streams.     

Alterations in Cortical Morphology after Neonatal Stroke: Compensation in the Contralesional Hemisphere?

Although neonatal arterial ischemic stroke is now well‐studied, its complex consequences on long‐term cortical brain development has not yet been solved. In order to understand the brain development after focal early brain lesion, brain morphometry needs to be evaluated using structural parameters. In this work, our aim was to study and analyze the changes in morphometry of ipsi‐ and contralesional hemispheres in seven‐year‐old children following neonatal stroke. Therefore, we used surface‐based morphometry in order to examine the cortical thickness, surface area, cortical volume, and local gyrification index in two groups of children that suffered from neonatal stroke in the left (n = 19) and right hemispheres (n = 15) and a group of healthy controls (n = 30). Reduced cortical thickness, surface area, and cortical volumes were observed in the ipsilesional hemispheres for both groups in comparison with controls. For the group with left‐sided lesions, higher gyrification of the contralesional hemisphere was observed primarily in the occipital region along with higher surface area and cortical volume. As for the group with right‐sided lesions, higher gyrification was detected in two separate clusters also in the occipital lobe of the contralesional hemisphere, without a significant change in cortical thickness, surface area, or cortical volume. This is the first time that alterations of structural parameters are detected in the “healthy” hemisphere after unilateral neonatal stroke indicative of a compensatory phenomenon. Moreover, findings presented in this work suggest that lesion lateralization might have an influence on brain development and maturation.     

The ultrafine structure of the body wall of sexually mature thorny-headed worms Echinorhynchus gadi (Acanthocephala)]

Studies of the fine structure of the adult acanthocephalan Echinorhynchus gadi have given a new information on the structure and organization of the body wall of these parasitic helminths. Their body surface is covered by glycocalyx of mucopolysaccharide nature. Just under it there is the surface membrane which has numerous invaginations forming a network of branching canals from which membrane vesicles are isolating. In their turn these canals pass through "the cytoplasmic canals" of the cortical matrix. Between the surface membrane and cortical matrix there is the base plate. These three structures form the striped layer underlain by the felt layer. It is formed by three layers of fibrous strands (one circular and two longitudinal), which are parallel to the body surface. These strands consist of loosely laid fibrils. The lowest layer is a radial one which occupies 2/3 of the body wall. It consists of the radial strands beginning from the cortical matrix and ending at the basement membrane. Numerous lipid droplets and glycogen granules are formed here. Two types of fibrils with 0.26 and 0.05 diameter have been detected for the first time. The radial layer in the cytoplasm was found to have crystalline structures and polymembrane bodies, numerous nuclei with light karyoplasm and distinct nucleoli. The location of the nuclei is of two types: either in the cytoplasm or in the "lacunae". We have shown that the "lacunae" are specialized sites of the cytoplasm whose boundaries are marked by the fibres of two types. Besides, this type of the acanthocephalan was found to have two "giant lacunae" extending along the body.(ABSTRACT TRUNCATED AT 250 WORDS)     

Neurobiology of the scallop. II. structure of the parietovisceral ganglion lateral lobes in relation to afferent projections from the mantle eyes

The lateral lobes of the scallop parietovisceral ganglion have been examined morphologically with respect to their functional role as optic lobes. The gross morphology of the lateral lobe and projections of optic nerve fibers within it were investigated by 1) supravital methylene blue staining, and 2) autoradiography using tritiated proline injected intraocularly for incorporation and transport by the optic fibers. Ultrastruc‐turally, the lateral lobe was examined using standard electron microscopic techniques. The lateral lobe is composed of a cortical rind of cells, 8–15 μm in diameter at the ventral surface and 15–20 μm in diameter at the ventral surface, surrounding a central neuropil. The neuropil contains three distinct regions: 1) the glomerular neuropil, a series of densely staining spherical subunits associated with the eyes and pallial nerves, 2) the subcellular neuropil, a synaptic region adjacent to the ventral cell layer also having a visual function, and 3) the subglomerular neuropil, the remaining, rather unspecialized neuropil of the lateral lobe. Synaptic profiles with symmetrical membrane thickenings, a 32 nm synaptic cleft, and three types of vesicles are seen throughout the neuropil, although the density of synapses is greater in the glomerular region. Clear, dense core and neurosecretory vesicles are seen individually or as mixed populations in the presynaptic terminals. Autoradiographic experiments have revealed that optic fibers enter the lateral lobe and project directly to the subcellular neuropil where they synapse with cells located on the ventral surface of the lateral lobe cells. These cells in turn form the dense glomerular structures previously identified as visual association centers and send efferent fibers into the pallial nerves. The projection of optic fibers to the ventral surface of the lobe is consistent with previous electrophysiological recordings of visual activity at this site.     

Zinc transporter 3 immunohistochemical tracing of sprouting mossy fibres

Zinc transporter 3 (ZNT3) has been shown to transport zinc ions from the cytosol into presynaptic vesicles in the mammalian brain. Several studies have stated that the zinc ion containing synaptic vesicles of zinc-enriched neurons (ZEN) are loaded with ZNT3 proteins in their membranes. This fact makes it possible to trace sprouting mossy fibres in the temporal lobe epileptic hippocampus. In the present study, we examined the expression and distribution patterns of ZNT3 protein and chelatable zinc ions in the mouse hippocampus after pilocarpine treatment. Our results demonstrate that both ZNT3 immunostaining and autometallography reveal identical patterns of sprouting mossy fibres in the inner molecular layer in the mouse hippocampus. Using ZNT3 immuno-electron microscopic analysis we confirmed the presence of ectopic mossy fibre terminals in the inner molecular layer and found additionally by immuno-blotting a significant increase of ZNT3 in the pilocarpine-treated mouse hippocampi compared to age-matched controls. The increase of ZNT3 after pilocarpine treatment was time-dependent. The results support the notion that ZNT3 immunohistochemistry provides an excellent tool for tracing sprouting of ZEN terminals. The progressive increase of ZNT3 immunostaining in the temporal lobe epileptic hippocampus may relate to the increased levels of vesicular zinc ions during seizure.     

Immunocytochemical localization of substance P in the neurohypophysis and hypothalamus of the mouse compared with the distribution of other neuropeptides

Summary Substance-P immunoreactivity has been located in semithin sections of mouse hypothalami and pituitaries and compared with the distribution of other hypothalamic peptides. In the mouse, nerve fibres and terminals reacting with antibodies against substance P (SP) were detected both in the external zone of the median eminence (ME) and in the neural lobe of the pituitary. Immunoreactive SP (ISP) axons of the ME did not react with antibodies against other peptides, i.e. arginine-vasopressin (AVP), oxytocin (OT), somatostatin and enkephalin, and were also negative with an antibody to serotonin. In the neural lobe, SP immunostaining occurred in AVP but not in OT axons. In the hypothalamus, ISP axons were widespread but conspicuously lacking in areas containing AVP neurones, i. e. in the suprachiasmatic nucleus and the clusters of AVP cells in the SO and PV nuclei. In contrast, multiple ISP endings were seen in contact with OT neurones. Immunoreactive cell bodies, only detected after colchicine treatment, belonged to two distinct classes of neurones: 1) single AVP neurones of the SO and PV nuclei; 2) specific (staining only for SP) neurones, scattered or grouped in different areas of the hypothalamus, not showing relationship with any circumscribed nucleus. These results reinforce the opinion that SP can be released as a neurohormone into the vascular portal system and can directly affect the pars distalis. The presence of immunoreactive SP in the neural lobe, which has not been reported in species other than the mouse, may have a different physiological significance.     

Storage and mobilization of extracellular matrix proteins during sea urchin development

After fertilization, sea urchin embryos surround themselves with an extracellular matrix, or hyaline layer, to which cells adhere during early development. Hyalin, the major protein component of the hyaline layer has been isolated and partially characterized in several laboratories. Although other proteins are present in the hyaline layer, little is known about their origin, distribution, or functions. The present report characterizes a set of hyaline layer proteins that are secreted after fertilization from a class of vesicles that are distinct from cortical granules. The group of proteins in these vesicles were identified by a monoclonal antibody (8d11) which recognizes a carbohydrate epitope common to each of these molecules. 8d11 polypeptides range in molecular weight from 105 to 225 kDa. Oogonia and oocytes in early stages of vitellogenesis do not express the antigen. The proteins are first observed by immunofluorescence during oogenesis as a peripheral band in mid-vitellogenic oocytes. Following germinal vesicle breakdown 8d11 moves to be distributed evenly throughout the cytoplasm. The proteins are transported to the egg surface by a cytochalasin-sensitive mechanism after fertilization, and secreted predominately within the first 30 min of development. 8d11 proteins are depleted in areas of cell contact during early embryogenesis, and become concentrated on the apical surface of ectoderm cells where they are assembled into high-molecular-weight aggregates. Three of the molecules in this group may be proteins previously described as "apical lamina" proteins. These observations provide evidence of a third pathway (cortical granules and basal lamina granules being the other two) for synthesis, storage, and exocytosis of matrix proteins that are release after fertilization.     

Ultrastructural aspects of the development of the hyaline layer and extracellular matrix lining the gastrointestinal tract in embryos and larvae of the starfish Pisaster ochraceus preserved by freeze substitution.

Embryos and larvae of the starfish Pisaster ochraceus are surrounded by a complex extracellular matrix (ECM) layer called the hyaline layer (HL). A similar but less well-organized ECM layer lines some regions of the larval gut. Examination of material preserved by freeze substitution shows that the HL consists of a coarse outer meshwork, a boundary layer, a supporting layer, which is divided into three sublayers, H1, H2, and H3, and an intervillus layer. The development of the HL has been studied in material preserved by freeze substitution. Development begins at fertilization when exocytosis of the cortical granules releases ECM into the perivitelline space and elevates the fertilization membrane. Shortly after, plaques of dense material with attached fibers are present on the outer surface of the egg plasmalemma. Following this, these plaques and fibers are associated with the tips of short microvilli, suggesting that they may induce microvillus formation. Next, the tips of some of the microvilli are joined by short regions of the H1 sublayer. Some of these H1 regions have short segments of boundary layer material associated with their outer surfaces while others are naked. Just prior to hatching, the H1 and boundary layers completely surround the embryo, separating the developing coarse meshwork and intervillus layers. Short segments of the H2 and H3 sublayers are also present. Posthatching, the microvilli and all HL layers increase in thickness and density, particularly the H2, boundary, and coarse outer meshwork layers. The results suggest a sequential organization of HL components from ECM that is secreted into the perivitelline space.     

The hypothalamo-hypophysial system in acipenseridae

Summary The distribution of adrenergic and peptidergic (Gomori-positive) structures of the hypophysial neuro-intermediate complex in Acipenseridae has been studied by means of light, fluorescence, and electron microscopy. Adrenergic fibres (B-fibres) and their terminals have been detected in the neurohypophysis of these fishes. The terminal swellings of B-fibres as well as the terminals of the neurosecretory peptidergic fibres (A₁ and A₂) make contact with the basement membrane of the connective tissue layer separating the neurohypophysis from the intermediate lobe. Capillaries are situated within this layer and, therefore, the main part of the fibre terminals is in contact with the pericapillary space. The release of catecholamines from the adrenergic terminals into the capillaries connected with the general circulation is supposed. The diffusion of catecholamines through the connective tissue layer into the parenchyma of the intermediate lobe is also suggested. Hence, the glandular activity of the intermediate lobe seems to be under the dual control of adrenergic and peptidergic elements of the hypothalamus.The authors wish to express their deep appreciation to G. M. Persov, Dr. Sc. Biol., Head of the Laboratory of Experimental Ichthyology, Petershof Biological Institute of the University of Leningrad, for the material supplied for fluorescence microscopy, and to Mr. G. V. Sabinin for photographic services.     

Intrinsic organization of snake dorsomedial cortex: an electron microscopic and golgi study.

The cellular populations present in dorsomedial cortex in the snakes Constrictor constrictor, Natrix sipendon and Thamnophis sirtalis are described at the light microscopic level using Nissl and Golgi preparations as well as at the ultrastructural level. This area plays a central role in cortical organization in snakes by participating in major commissural and association projections. Systematic analyses of Golgi preparations indicate that five populations of neurons are present in dorsomedial area and have a preferential laminar distribution. Layer 1 stellate cells have somata positioned in the center of the outermost cortical layer, layer 1. Their dendrites are confined to this layer. Double pyramidal cells have their somata loosely packed in layer 2. Their dendrites bear a moderate population of spines, ascending through layer 1 to the pial surface and descending partially through layer 3. Some double pyramidal cells have somata displaced downwards into the upper third of layer 3. These neurons closely resemble the layer 2 double pyramidal cells. Layer 3 stellate cells have somata positioned in the middle third of layer 3. Their dendrites extend in all directions throughout layer 3 and through layer 2 into layer 1. Finally, horizontal cells have their somata positioned deep in layer 3, near the ventricle, and dendrites aligned concentric with the ventricle. Comparison of the organization of the known afferents to dorsomedial area with the distribution of the five cell types suggests that the laminations of both afferent fibres and dorsomedial neurons places specific neuronal populations in synaptic contact with specific sets of afferents.     

Connections of the representational area of the distal section of the forelimb in the rat sensorimotor cortex

Using horseradish peroxidase, studies have been made on the distribution of retrogradely labeled nervous cells in the sensorimotor cortex of rats. The enzyme was injected into electrophysiologically identified zone of representation of the distal part of the forelimb in areas S2 and S1. It was found that this zone in S2 contains afferent connections mainly from representation of the same extremity in S1 and only a few afferents from other areas of S1, S2 and M1 of the same hemisphere. Single labeled neurones were found in areas S2, S1 and M1 of the contralateral hemisphere. Representation of the forelimb in S1 receives mainly cortical afferents from the same region of S1 and from single cells of homologous zones S2 of the same and S1 of the contralateral hemisphere. Connections from S1 to S2 are more numerous than the opposite ones. In contrast to cats and monkeys, in rats afferent cortical fibers to zone S2 pass not only from the third layer, but also from the fifth and sixth layers of the cortex. It is suggested that during progressive development of the neocortex in mammals, the increase in the degree of separation of neurones (which give origin to corticofugal and cortical connections) among different layers of the cortex takes place.     

Postembryonic changes in the optic primordia and optic bud in the flesh fly Sarcophaga ruficornis fabr. (Diptera: Sarcophagidae)

Differentiation of the optic lobe anlagen begin in the brain of second instar. Each is an elongated disc of cortical cells placed on the dorsolateral border of each protocerebrum. In the late second instar the disc elongates and its two ends bend inwards which gradually separate from the central region, thus giving three imaginal discs. The protocerebral neuropile extends into these discs and medulla interna and externa are formed. The rudiments of compound eyes (cephalic complex) appear in the early laid larva. These are attached with the brain and pharyngeal wall separately. The posterior portion of cephalic complex (optic bud), after establishing a nervous association with the central optic lobe anlage (lamina ganglionaris), forms the compound eye. Ech optic bud is attached to the brain by a non-nervous stalk. The epiblast cells of the optic bud do not migrate into the brain and the lamina is formed by the proliferation of the central imaginal disc. The reorientation of the optic lobe anlagen starts in the late third instar and the medulla interna divides into two unequal lobes. In 2 day pupa the nerve fibres from the lamina travel into the optic stalk and the optic nerve is formed. The epiblast cells of the optic bud differentiate to form a peripheral epithelial layer which becomes pigmented and gets apposed to the lateral boundary of the brain. The central epiblast cells of the optic bud form several ommatidia. The optic nerve degenerates gradually and various components of the compound eye are formed by the epiblast cells. Chiasm internum is present but chiasm externum is absent.     

lntracortical Connections in the Snakes Natrix sipedon and Thamnophis sirtalis

The association and commissural connections between the four cortical areas in water (Natrix sipedon) and garter (Thamnophis sirtalis) snakes were studied by placing lesions on the cortical surface and studying the resulting degeneration in Fink-Heimer preparations. Lateral cortex projects to the outer one third of layer 1 of ipsilateral medial cortex. Dorsal cortex projects to the middle third of layer 1 of ipsilateral medial cortex. Dorsomedial cortex projects bilaterally to the inner third of layer 1 and to layer 3 of me dial cortex. It also projects to layer 1 of contralateral dorsomedial cortex. Medial cortex projects ipsilaterally to each of the other cortical areas. With the apparent exception of the projection of medial cortex to lateral cortex, each projection is organized such that each rostrocaudal segment of a cortical area projects to all segments of the target area lying at the same or more caudal levels.