Medial temporal lobe projections to the retrosplenial cortex of the macaque monkey

The projections to the retrosplenial cortex (areas 29 and 30) from the hippocampal formation, the entorhinal cortex, perirhinal cortex, and amygdala were examined in two species of macaque monkey by tracking the anterograde transport of amino acids. Hippocampal projections arose from the subiculum and presubiculum to terminate principally in area 29. Label was found in layer I and layer III(IV), the former seemingly reflecting both fibers of passage and termination. While the rostral subiculum mainly projects to the ventral retrosplenial cortex, mid and caudal levels of the subiculum have denser projections to both the caudal and dorsal retrosplenial cortex. Appreciable projections to dorsal area 30 [layer III(IV)] were only seen following an extensive injection involving both the caudal subiculum and presubiculum. This same case provided the only example of a light projection from the hippocampal formation to posterior cingulate area 23 (layer III). Anterograde label from the entorhinal cortex injections was typically concentrated in layer I of 29a-c, though the very caudal entorhinal cortex appeared to provide more widespread retrosplenial projections. In this study, neither the amygdala nor the perirhinal cortex were found to have appreciable projections to the retrosplenial cortex, although injections in either medial temporal region revealed efferent fibers that pass very close or even within this cortical area. Finally, light projections to area 30V, which is adjacent to the calcarine sulcus, were seen in those cases with rostral subiculum and entorhinal injections. The results reveal a particular affinity between the hippocampal formation and the retrosplenial cortex, and so distinguish areas 29 and 30 from area 23 within the posterior cingulate region. The findings also suggest further functional differences within retrosplenial subregions as area 29 received the large majority of efferents from the subiculum. ? 2012 Wiley Periodicals, Inc.     

Corticocortical projections to the monkey temporal lobe with particular reference to the visual processing pathways

Cortico-cortical connections occurring within the temporal lobe and afferent projections to the temporal cortex particularly from the prefrontal and parahippocampal areas were studied in the monkey by means of retrograde axonal transport of horseradish peroxidase (HRP) or wheat-germ-agglutinin-conjugated HRP (WGA-HRP). In particular, 0.1-0.3 microliter of 50% HRP or 5% WGA-HRP was injected into various parts of the temporal cortex, i.e. the rostral (TEr), the caudal (TEc), and the most caudal (TEO) parts of the inferotemporal cortex, the superior temporal gyrus, and the temporal pole (TG), and in the upper bank of the inferior arcuate sulcus in the frontal lobe. Labeled cells, which represent cells of origin of association fibers projecting to the injection site, appeared in various cortical regions. The main findings of the present study are the following. The temporal pole (TG) receives fibers almost exclusively from the most rostral part of the TE. The rostral part of the TE receives many fibers from both the caudal part of the TE and the TEO. The caudal part of the TE receives fibers from the TEO, and the TEO from the prestriate cortex (OA and OB). Taking these findings together, the morphological basis of the "step-wise" progression of visual impulses from the prestriate cortex to the TEO, TE and finally to the TG is clearly presented. The superior temporal gyrus (TA or area 22) receives most fibers from the dorsolateral frontal gyrus, while the inferotemporal cortex (TE or areas 21 and 20) receives most fibers from the ventrolateral frontal gyrus (inferior frontal convexity). Both the temporal pole (TG) and the inferotemporal cortex (TE) receives a fair number of fibers from the parahippocampal region (TH and TF).     

Premeiotic aster as a device to anchor the germinal vesicle to the cell surface of the presumptive animal pole in starfish oocytes

The germinal vesicle (GV) of starfish oocytes stays just beneath the oocyte cortex at the presumptive animal pole during the long period of oogenesis. We subjected oocytes to a centrifugal force field to detach the GV from the cortex. The association between the cortex and the GV persisted and withstood a small amount of centrifugal acceleration at 200 g. The GV was eventually separated from the cortex at 700 g. The amount of acceleration sufficient for the GV separation was lowered when the oocytes were pretreated with Nocodazole and was increased by Taxol pretreatment. Observation of microtubular structures with an anti-alpha-tubulin antibody revealed the presence of a complex of spots and radiating arrays as was described by J. J. Otto and T. E. Schroeder (1984, Dev. Biol. 101, 274-281) and called the premeiotic aster. Nocodazole shortened the astral arrays, and Taxol enhanced them. These observations indicate that the premeiotic aster works as a device to hold the GV in an eccentric position just beneath the oocyte cortex.     

Unitary responses of the hypothalamic nuclei to stimulation of the frontobasal neocortex

Unitary responses in the hypothalamic nuclei to stimulation of the frontobasal zones of the cortex (proreal, orbito-insular, and basal temporal regions) were studied. Cortico-thalamic connections were found to possess definite topical organization: the orbito-frontal zones of the cortex have a more marked effect on unit activity of the hypothalamic nuclei than the basal temporal cortex. Antidromic activation, during stimulation of a particular region of the cortex, of neurons excited orthodromically by stimulation of another cortical structure, enables a number of neuronal circuits functioning within the forebrain to be distinguished. The first circuit includes the orbital gyrus, preoptic zone, and proreal gyrus. The second circuit has the same cortical components as the first, but its relay in the hypothalamus takes place in the region of the mamillary bodies. The third circuit is represented by the basal temporal cortex, lateral hypothalamus, and prefrontal cortex.M. Gor'kii Donetsk Medical Institute. Translated from Neirofiziologiya, Vol. 10, No. 1, pp. 44–53, January–February, 1978.     

Yeast Cdk1 translocates to the plus end of cytoplasmic microtubules to regulate bud cortex interactions

The budding yeast spindle aligns along the mother- bud axis through interactions between cytoplasmic microtubules (CMs) and the cell cortex. Kar9, in complex with the EB1-related protein Bim1, mediates contacts of CMs with the cortex of the daughter cell, the bud. Here we established a novel series of events that target Kar9 to the bud cortex. First, Kar9 binds to spindle pole bodies (SPBs) in G(1) of the cell cycle. Secondly, in G(1)/S the yeast Cdk1, Cdc28, associates with SPBs and phosphorylates Kar9. Thirdly, Kar9 and Cdc28 then move from the SPB to the plus end of CMs directed towards the bud. This movement is dependent upon the microtubule motor protein Kip2. Cdc28 activity is required to concentrate Kar9 at the plus end of CMs and hence to establish contacts with the bud cortex. The Cdc28-regulated localization of Kar9 is therefore an integral part of the program that aligns spindles.     

Corticofugal projections to the periaqueductal gray matter in the cat midbrain

Stereotaxic microinjections of horseradish peroxidase (HP) were made into different parts of the rostral and caudal periaqueductal gray (PAG) in cats to study corticofugal projections to the PAG. The method of retrograde axonal transport of HP demonstrated labeled neurons in the I and II somatosensory areas, frontal, cingular and insular cortex of the brain. It was shown that the II somatosensory cortex projects to all the areas of the rostral and caudal PAG. The frontal cortex projects to the dorsolateral quadrant of the PAG. The findings obtained enabled the detection of the morphological substrate of the corticofugal effects on one of the antinociceptive brain structures--the PAG.     

Differences of the medial lemniscus and spinothalamic tract according to the cortical termination areas: A diffusion tensor tractography study

Abstract

We investigated differences of the medial lemniscus and its thalamocortical pathway (ML), and the spinothalamic tract and its thalamocortical pathway (STT) according to the cortical termination areas. We found that the ML and STT terminated in the motor cortex and the somatosensory cortex. The ML may be closely related to the motor cortex for motor planning and execution, while the STT may be closely related to the cerebral cortex for somatosensory function and motor execution.     

The long-term potentiation of the late NMDA-dependent components of the responses of the cat motor cortex neurons to stimulation of the direct cortical input of area 5 in the parietal cortex]

Activity of neurons in the motor cortex was recorded in anesthetized cats with glass micropipettes filled with bicuculline solution (bicuculline methiodide, 10 mM in 1 M NaCl). Under these conditions, the minimal (near-threshold) electrical stimulation of the area 5 of the parietal cortex evoked the late neuronal discharges (in 30-200-ms poststimulus interval) in the motor cortex. Such discharges resembled the late NMDA-dependent discharges recorded in the motor cortex of awake cats in response to stimulation of the parietal cortex, which produced the preliminary elaborated conditioned forepaw placing. Under the same conditions, tetanic stimulation of the parietal cortex (100 Hz, 10-20s) led to the long-term potentiation of the late response, which manifested itself as response amplitude augmentation and latency shortening.     

Interaction of recovery cycles of evoked potentials in the cerebral cortex of the cat in response to stimulation of the superior colliculi and pulvinar

Similar character of recovery cycles of evoked potentials in the visual cortex to electric stimulation of the superior colliculi (SC) and pulvinar was found in chronic experiments on alert cats irrespective of stimuli presentation order. In the association cortex preceding SC stimulation facilitated the response to test stimulation of pulvinar almost at all delays between the stimuli. If the pulvinar stimulation was applied as a conditioned stimulus, then the response to SC stimulation under intervals of 20-200 ms was depressed. The obtained data point to equivalence of the inputs from SC and pulvinar to the visual cortex, to different informational value of inputs from SC to the association and visual cortex, and to mutual function dependence of the inputs from SC and pulvinar to the association cortex.     

Evoked potentials in the rat neostriatum during local cooling of the cortex in the zone of primary response to the applied stimulus

The effect of local cooling of the surface of the somatosensory cortex was studied while recording primary response (PR) in the center of a cooled area and evoked potentials (EP) in the striatum to the forepaw stimulation. The cooling which served to arise the amplitude of the PR, served also to arise the amplitude of the EP in the striatum. EP to the stimulus, the sensory representation of which in the cortex was cooled, were facilitated only. Facilitation of the striatal EP was more intense than facilitation of the cortical PR in the cooled area. The level of facilitation of the EP was the same in the region of the striatum which receives corticofugal fibers from the cooled area of the cortex and in other regions of the striatum, receiving the corticofugal fibers from other parts of the cortex. The data show a possibility for the interactions in the striatum of the corticofugal signals from different cortical areas with each other and with the ascending afferent signals.     

Projections from lamina V of the cerebral cortex to the dorsomedial thalamic nucleus and neighboring nuclei]

The laminar projections from the cerebral cortex to the mediodorsal thalamic nucleus and adjacent thalamic nuclei were studied by means of the horseradish peroxidase (HRP) retrograde axonal transport method. A possible correlation was found between the connectivity arising from layer V of the cerebral cortex, and the rich-acetylcholinesterase (AChE) regions within the subcortical structures under study. This suggests the possibility that layer V of the cerebral cortex in Alzheimer's disease is initially affected and subsequently those rich-AChE subcortical regions with which it is connected.     

Modality-specific neural effects of selective attention to taste and odor

The insular cortex is implicated in general attention and in taste perception. The effect of selective attention to taste on insular responses may therefore reflect a general effect of attention or it may be (taste) modality specific. To distinguish between these 2 possibilities, we used functional magnetic resonance imaging to evaluate brain response to tastes and odors while subjects passively sampled the stimuli or performed a detection task. We found that trying to detect a taste (attention to taste) resulted in activation of the primary taste cortex (anterior and mid-dorsal insula) but not in the primary olfactory cortex (piriform). In contrast, trying to detect an odor (attention to odor) increased activity in primary olfactory but not primary gustatory cortex. However, we did identify a region of far anterior insular cortex that responded to both taste and odor "searches." These results demonstrate modality-specific activation of primary taste cortex by attention to taste and primary olfactory cortex by attention to odor and rule out the possibility that either response reflects a general effect of attentional deployment. The findings also support the existence of a multimodal region in far anterior insular cortex that is sensitive to directed attention to taste and smell.     

INCENP binds directly to tubulin and requires dynamic microtubules to target to the cleavage furrow

Inner centromere protein (INCENP) is a chromosomal passenger protein with an essential role in mitosis. At the metaphase/anaphase transition, some INCENP transfers from the centromeres to the central spindle; the remainder then transfers to the equatorial cortex prior to cleavage furrow formation. The molecular associations dictating INCENP behavior during mitosis are currently unknown. Here we show that targeting INCENP to the cleavage plane requires dynamic microtubules, but not F-actin. When microtubules are eliminated, INCENP is dispersed across the entire cell cortex. Yeast two-hybrid and in vitro binding data demonstrate that INCENP binds directly to beta-tubulin via a conserved domain encompassing residues 48-85. Furthermore, INCENP binds to microtubules polymerized from purified tubulin in vitro and appears to bundle microtubules when expressed in the interphase cytoplasm. These data indicate that INCENP is a microtubule-binding protein that targets to the equatorial cortex through interactions requiring microtubules.     

Properties of doublecortin-(DCX)-expressing cells in the piriform cortex compared to the neurogenic dentate gyrus of adult mice

The piriform cortex receives input from the olfactory bulb and (via the entorhinal cortex) sends efferents to the hippocampus, thereby connecting the two canonical neurogenic regions of the adult rodent brain. Doublecortin (DCX) is a cytoskeleton-associated protein that is expressed transiently in the course of adult neurogenesis. Interestingly, the adult piriform cortex, which is usually considered non-neurogenic (even though some reports exist that state otherwise), also contains an abundant population of DCX-positive cells. We asked how similar these cells would be to DCX-positive cells in the course of adult hippocampal neurogenesis. Using BAC-generated transgenic mice that express GFP under the DCX promoter, we studied DCX-expression and electrophysiological properties of DCX-positive cells in the mouse piriform cortex in comparison with the dentate gyrus. While one class of cells in the piriform cortex indeed showed features similar to newly generated immature granule neurons, the majority of DCX cells in the piriform cortex was mature and revealed large Na+ currents and multiple action potentials. Furthermore, when proliferative activity was assessed, we found that all DCX-expressing cells in the piriform cortex were strictly postmitotic, suggesting that no DCX-positive "neuroblasts" exist here as they do in the dentate gyrus. We conclude that DCX in the piriform cortex marks a unique population of postmitotic neurons with a subpopulation that retains immature characteristics associated with synaptic plasticity. DCX is thus, per se, no marker of neurogenesis but might be associated more broadly with plasticity.     

Death of the cereal root cortex: its relevance to biological control of take-all

Cell death in the root cortex of cereals was assessed by an inability to detect nuclei, using acridine orangelfluorescence microscopy after fixation and mild acid hydrolysis. Seminal roots were scanned at x 100 magnification and their cortices were considered dead when nuclei were absent from all cell layers except the innermost one, adjacent to the endodermis; this cell layer remains alive long after the rest of the cortex has died. Cortical death of wheat and barley roots occurred in the absence of major pathogens. Cell death started behind the root hair zone of the main root axis, initially in the outermost cell layer of the cortex and then progressively inwards towards the endodermis; however, the cortex remained alive for a distance of c. 800 μm around emerging root laterals. The rate of cortical death was more rapid in wheat than in barley, both under field conditions and in the glasshouse at 20 °C. Thus, field-grown spring wheat (Sicca) showed 50% death of the root cortex in the top 6 cm of first seminal roots after 35 days (growth stage 1–2), whereas spring barley (Julia) showed 50% death of the root cortex after 67 days (growth stage 8). In the glasshouse, the top 9 cm of first seminal roots on 16-day plants showed 55% cortical death in wheat (Cappelle-Desprez) but only 2.5% cortical death in barley (Igri). The same rates of death were found in all subsequent seminal roots. The wheat root cortex died at the same rate in sterile and unsterile conditions, and at the same rate in the presence/absence of Phialophora radicicola Cain var. graminicola Deacon or Aureobasidium bolleyi (Sprague) von Arx. Hence, although P. radicicola and other soil microorganisms may benefit from root cortex death they do not exert biological control of take-all by enhancing or retarding the rate of this process. To study the effects of cortical death on take-all, Gaeumannomyces graminis (Sacc.) Arx & Olivier var. tritici Walker was point-inoculated at the tips and on older (5 and 15 day) regions of wheat seminal roots. After 17 days at 20 °C the fungus had grown to the same extent as runner-hyphae in all cases, but the severity of disease decreased with increasing age of the root cortex prior to inoculation; thus, G. graminis caused most extensive vascular discoloration and most intense vascular blockage in roots inoculated at their tips. Similar experiments on wheat and barley roots inoculated separately with P. radicicola and G. graminis suggest that at least three factors associated with cortical death influence infection by these fungi: (1) initially, cell death may enhance infection because nutrients are made available to the parasites and host resistance within the cortex is reduced; (2) weak parasites and soil saprophytes may colonise dead and dying cortices in competition with G. graminis and P. radicicola and thereby reduce infection by these fungi; (3) changes in the endodermis and adjacent cell layers may be associated with cortical death and may retard invasion of the stele. Future work will seek to establish the relative importance of these factors and extend this study to other cereal host-fungus combinations.     

The late excitatory responses of the motor cortex neurons in the cat to stimulation of the pyramidal tract

Under conditions of partial suppression of GAMKA-dependent cortical inhibition in the motor cortex of anesthetized cats, a weak electrical stimulation of the pyramidal tract evoked the late slow (50-200 ms) excitatory reactions in the motor cortex neurons similar to those previously recorded under the same conditions in response to stimulation of the parietal cortex. This finding favors the proposal that the late excitatory component of the cortico-cortical response reflects the repetitive activation of cortical neurons due to excitation spread via the system of cortical recurrent excitatory collaterals.     

Neuronal responses of the reticular and anterior ventral thalamic nuclei to stimulation of the thalamic ventrolateral nucleus and motor cortex

Responses of 137 neurons of the rostral pole of the reticular and anterior ventral thalamic nuclei to electrical stimulation of the ventrolateral nucleus and motor cortex were studied in 17 cats immobilized with D-tubocurarine. The number of neurons responding antidromically to stimulation of the ventrolateral nucleus was 10.5% of all cells tested (latent period of response 0.7–3.0 msec), whereas to stimulation of the motor cortex it was 11.0% (latent period of response 0.4–4.0 msec). Neurons with a dividing axon, one branch of which terminated in the thalamic ventrolateral nuclei, the other in the motor cortex, were found. Orthodromic excitation was observed in 78.9% of neurons tested during stimulation of the ventrolateral nucleus and in 52.5% of neurons during stimulation of the motor cortex. Altogether 55.6% of cells responded to stimulation of the ventrolateral nucleus with a discharge of 3 to 20 action potentials with a frequency of 130–350 Hz. Similar discharges in response to stimulation of the motor cortex were observed in 30.5% of neurons tested. An inhibitory response was recorded in only 6.8% of cells. Convergence of influences from the thalamic ventrolateral nucleus and motor cortex was observed in 55.7% of neurons. The corticofugal influence of the motor cortex on responses arising in these cells to testing stimulation of the ventrolateral nucleus could be either inhibitory or facilitatory.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 10, No. 5, pp. 460–468, September–October, 1978.     

Mechanics of the cellular actin cortex: From signalling to shape change

The actin cortex is a thin layer of actin, myosin and actin-binding proteins that underlies the membrane of most animal cells. It is highly dynamic and can undergo remodelling on timescales of tens of seconds, thanks to protein turnover and myosin-mediated contractions. The cortex enables cells to resist external mechanical stresses, controls cell shape and allows cells to exert forces on their neighbours. Thus, its mechanical properties are the key to its physiological function. Here, we give an overview of how cortex composition, structure and dynamics control cortex mechanics and cell shape. We use mitosis as an example to illustrate how global and local regulation of cortex mechanics gives rise to a complex series of cell shape changes.     

Reaction of microglia and astrocytes in the rat brain cortex to free-electron laser irradiation

Reactions of microglia and astrocytes in the sensorimotor cortex of the rat resulting from a cortex tissue lesion made by a free-electron laser were studied with immunohistochemical techniques. Lipocortin-1 (LC1) was used as a microglia marker, while S100-β glycoprotein was used to identify astrocytes. Three days after laser exposure, the quantity of LC1-positive microglial cells observed in the cortex along the edge of the laser lesion was 30% larger than that in the control. There was no reaction of S100-β-positive astrocytes observed within this time interval. Six days after laser exposure, the density of LC1-positive activated microglia along the edge of the laser lesion further increased (210% of the above index), and the density of S100-β-positive astrocytes also slightly increased (by 30%, compared with the control). The data provide evidence that LC1-positive microglia react to a laser-made cortex injury more rapidly and intensively than astrocytes. It can be supposed that namely LC1 plays the role of an anti-inflammatory messenger in cortex microglial cells after laser exposure. In general, the pattern of microglia and astrocyte reactions is indicative of comparatively mild traumatization of the cortex tissue after laser irradiation.     

Development of the noradrenergic system of the rat brain after prenatal exposure to corticosterone

The influence of corticosterone during the period of tyrosine hydroxylase gene expression (16th–18th days of rat embryogenesis), which is sensitive to hormonal induction, on the ontogenesis of presynaptic markers of the noradrenergic system has been studied. It has been found that hormone-induced changes in the level of noradrenaline and dopamine in the brain cortex and brainstem had a transitive character and were eliminated in adulthood. At the same time, the hormone increased the activity of tyrosine hydroxylase in the cortex of 7- to 16-day-old rat pups and in the cortex and brainstem of adult animals. It has been shown that the level of glucocorticoids is an important factor in development of the noradrenergic system of the brain, able during critical periods of ontogenesis to cause sustained changes of its functioning in subsequent periods of life.