Chronic Methamphetamine Induces Structural Changes in Frontal Cortex Neurons and Upregulates Type I Interferons

While methamphetamine-induced changes in brain neurotransmitters, their receptors, and transporters are well studied, the means by which methamphetamine abuse results in cognitive and behavioral abnormalities is unknown. Here, we administered methamphetamine chronically, in doses relevant to recreational usage patterns, to nonhuman primates. Neurostructural analysis revealed decreased dendritic material and loss of spines in frontal lobe neurons. Molecular examination demonstrated that type I interferons (interferon-alpha and interferon-beta) increased in the frontal lobe in response to chronic methamphetamine treatment, in correlation with the neuronal changes. Chronic methamphetamine thus results in significant changes in the primate brain, inducing cytokines and altering neuronal structure, both of which can contribute to functional abnormalities.     

The immune response of mice and cynomolgus monkeys to macaque mucin 1-mannan

Mice immunised with human epithelial mucin MUC1 coupled to oxidised mannan produce MUC1 specific MHC Class 1 restricted CD8⁺ cytotoxic T cells and are completely protected from the development of MUC1⁺ tumours; such therapy may be applicable to humans. In this light we describe pre-clinical studies in cynomolgus monkeys (Macaca fascicularis), to test the efficacy of mannan-MUC1 in higher primates. Monkey MUC1 genomic clones were isolated from a macaque library, peptides and fusion protein synthesised and mice and monkeys immunised with macaque MUC1-mannan. In mice CTL responses were induced (as has been found with human MUC1 mannan conjugates), but in contrast monkeys produced a humoral response, with no T cell proliferative, cytotoxic responses or CTLp found. In spite of the presence of anti-MUC1 auto-antibodies, there was no toxicity or induction of autoimmunity.     

Distribution of high affinity choline transporter immunoreactivity in the primate central nervous system

A mouse monoclonal antibody (clone 62-2E8) raised against a human recombinant high-affinity choline transporter (CHT)-glutathione-S-transferase fusion protein was used to determine the distribution of immunoreactive profiles containing this protein in the monkey central nervous system (CNS). Within the monkey telencephalon, CHT-immunoreactive perikarya were found in the striatum, nucleus accumbens, medial septum, vertical and horizontal limb nuclei of the diagonal band, nucleus basalis complex, and the bed nucleus of the stria terminalis. Dense fiber staining was observed within the islands of Calleja, olfactory tubercle, hippocampal complex, amygdala; moderate to light fiber staining was seen in iso- and limbic cortices. CHT-containing fibers were also present in sensory and limbic thalamic nuclei, preoptic and hypothalamic areas, and the floccular lobe of the cerebellum. In the brainstem, CHT-immunoreactive profiles were observed in the pedunculopontine and dorsolateral tegmental nuclei, the Edinger-Westphal, oculomotor, trochlear, trigeminal, abducens, facial, ambiguus, dorsal vagal motor, and hypoglossal nuclei. In the spinal cord, CHT-immunoreactive ventral horn motoneurons were seen in close apposition to intensely immunoreactive C-terminals at the level of the cervical spinal cord. CHT immunostaining revealed a similar distribution of labeled profiles in the aged human brain and spinal cord. Dual fluorescent confocal microscopy revealed that the majority of CHT immunoreactive neurons contained the specific cholinergic marker, choline acetyltransferase, at all levels of the monkey CNS. The present observations indicate that the present CHT antibody labels cholinergic structures within the primate CNS and provides an additional marker for the investigation of cholinergic neuronal function in aging and disease.     

Architectonics and cortical connections of the upper bank of the superior temporal sulcus in the rhesus monkey: an analysis in the tangential plane

Area TPO in the upper bank of the superior temporal sulcus (STS) of macaque monkeys is thought to correspond to the superior temporal polysensory (STP) cortex, but has been shown to have neurochemical/connectional subdivisions. To examine directly the relationship between chemoarchitecture and cortical connections of area TPO, the upper bank of the STS was sectioned tangential to the cortical surface. Three subdivisions of area TPO (TPOr, TPOi, and TPOc) were examined with cytochrome oxidase (CO) histochemistry and neurofilament protein (NF) immunoreactivity and architectonic patterns were compared with connections on the same or adjacent sections. Area TPOc, which may partly overlap with the location of the medial superior temporal area MST, exhibited regular patchy staining for CO in layers III/IV and a complementary pattern in the NF stain. Area TPOr, but not TPOi, also had a patchy pattern of complementary staining in CO and neurofilament similar to TPOc, although not as distinct. Tracer injections within cortex including the frontal eye fields (areas 46 and 8) labeled areas TPOc, TPOi, and TPOr. The caudal inferior parietal lobule (IPL) projected to all three areas. The projections from prearcuate and posterior parietal cortices showed both overlap and nonoverlap with each other within TPOc, TPOi, and TPOr. Projections were to all neurochemical components within the subdivisions of TPO. The findings support the parcellation of area TPO into three subdivisions and extend findings of chemoarchitectonic modules within high-order association cortices.     

Projections from the lateral,basal, and accessory basal nuclei of the amygdala to the entorhinal cortex in the macaque monkey

We used the anterograde tracers Phaseolus vulgaris-leucoagglutinin (PHA-L) and biotinylated dextran amine (BDA) to examine the projections from the lateral, basal, and accessory basal nuclei of the amygdaloid complex to the entorhinal cortex in Macaca fascicularis monkeys. The heaviest amygdaloid projections originate in the lateral nucleus, which innervates the rostrally situated entorhinal fields but does not project to the caudal entorhinal cortex. The most extensive projections originate in the ventral division of the lateral nucleus. Injections in this subdivision lead to moderate to heavy fiber and terminal labeling in the entorhinal cortex, rostral levels of the rostral intermediate El (ER) and lateral fields, (ELr), and light labeling in the olfactory field EO. The projections from all portions of the lateral nucleus terminate most heavily in layer III. Layer II of EO and ER also receives a substantial input from the ventral division of the lateral nucleus. Layer II of ELr receives light innervation from all portions of the lateral nucleus that project to layer III. Projections from the basal nucleus arise mainly from the parvicellular division and are light to moderate in density. Fibers terminate predominantly in ELr, ER, EO, and the caudal portion of the lateral field (Elc); only the most rostral portion of El receives projections. While fibers from the basal nucleus innervate the same layers as the projections from the lateral nucleus, they tend to have a more vertical or radial orientation within the entorhinal cortex. Electron microscopic analysis of these fibers and terminals indicates that they overwhelmingly form asymmetrical synapses onto dendrites and dendritic spines. The accessory basal nucleus provides a light projection to the same regions of the entorhinal cortex innervated by the lateral and basal nuclei.     

Chemical organization of the macaque monkey olfactory bulb: II. Calretinin, calbindin D-28k, parvalbumin, and neurocalcin immunoreactivity

The distribution and morphologic features of calcium-binding protein- (calbindin D-28k, calretinin, neurocalcin, and parvalbumin) immunoreactive elements were studied in the macaque monkey olfactory bulb by using specific antibodies and the avidin-biotin-immunoperoxidase method. A characteristic laminar pattern of stained elements was observed for each marker. Scarce superficial short-axon cells and superficial stellate cells demonstrated calbindin D-28k immunoreactivity in the outer layers, whereas a moderate number of calbindin D-28k-immunoreactive granule cells and scarce deep short-axon cells were observed in the inner layers. Calretinin-staining demonstrated abundant periglomerular cells and granule cells and a scarce number of other interneuronal populations. Most neurocalcin-immunopositive elements were external and medial tufted cells and periglomerular cells, although other scarcer interneuronal populations were also immunostained. A few superficial and deep short-axon cells as well as small interneurons in the external plexiform layer were the only elements immunoreactive to parvalbumin. The distribution of the immunoreactive elements in the olfactory bulb of the macaque monkey showed a high similarity to that reported in the human, whereas it demonstrated a different and simpler pattern to what has been reported in the olfactory bulb of macrosmatic animals. It suggests more homogeneous calcium-mediated cell responses after stimulation that could be correlated to the lower capability to modulate olfactory signals in microsmatic animals. In addition, these results indicate that experimental models in rodents do not provide an accurate estimation of calcium-binding protein-immunoreactive neuronal populations in the primate olfactory system.     

Spatial distribution of thalamic projections to the supplementary motor area and the primary motor cortex: A retrograde multiple labeling study in the macaque monkey

The exact knowledge on spatial organization of information sources from the thalamus to the supplementary motor area (SMA) and to the primary motor cortex (MI) has not been established. We investigated the distribution of thalamocortical neurons projecting to forelimb representations of the SMA and the MI using a multiple retrograde labeling technique in the monkey. The forelimb area of the SMA, and the distal and proximal forelimb areas of the MI were identified by electrophysiological techniques of intracortical microstimulation and single neuron recording. Injections were made into these three representations with three different dyes in the same animal (horseradish peroxidase conjugated to wheat germ agglutinin, diamidino yellow, and fast blue), and the thalamic neurons were retrogradely labeled. Injections into the SMA densely labeled thalamic neurons in nuclei ventralis lateralis pars oralis (VLo), ventralis lateralis pars medialis (VLm) and ventralis lateralis pars caudalis (VLc), but not in nucleus ventralis posterior lateralis pars oralis (VPLo). Injections into the MI labeled thalamic neurons primarily in VLo, VLc, and VPLo. We found that the distribution of projection neurons to the three areas was largely separate in the thalamus. However, in the middle part of VLo, and in a limited portion of VLc, thalamic neurons projecting to the SMA partially overlapped with those to the distal forelimb area of the MI. They overlapped little with those to the proximal forelimb area of the MI. We noted no overlap between the distributions of thalamic projection neurons to the distal and proximal forelimb areas of the MI. These findings suggest that the SMA and MI receive separate information from the thalamus, while sharing minor sources of common inputs. © 1995 Wiley-Liss, Inc.     

Importance of CD49d- VCAM interactions in human monocyte adhesion to porcine endothelium

Abstract: By using a primate model of natural antibody depletion, we have previously shown that delayed rejection of porcine cardiac xenografts in unmodified primate recipients resulted from xenograft infiltration with monocyte/macrophage lineage cells. In the present study, we initially showed that human monocytes/macrophages demonstrated significantly greater adherence to unstimulated pig aortic endothelial cells (PAEC) than to human umbilical vein endothelial cells (HUVEC). Human TNF-alpha augmented monocyte adhesion to HUVEC by 5-fold higher levels than to PAEC. This effect could not be explained on the basis of incompatibility between human TNF-alpha and its receptor on PAEC since porcine VCAM expression increased by 75–85% after stimulation with TNF-alpha. TNF-augmented monocyte adherence was abrogated by either treatment of PAEC with an anti-VCAM Mab or monocytes with an anti-CD49d Mab. These results suggest that VCAM-CD49d interactions are important in adhesion of human monocytes to PAEC but may not be as effective as those between human monocytes and allogeneic endothelium, perhaps because of structural differences across species. Other interactions, as yet undefined, must explain the relative increase in adhesiveness of human monocytes for unstimulated PAEC versus HUVEC. In experiments investigating the functional consequences of this enhanced monocyte adherence, PAEC stimulation induced 10-fold higher levels of macrophage-derived IL-1 beta and 3-fold higher levels of T cell proliferation compared with HUVEC. Using an anti-DR Mab to interrupt antigen presentation by autologous macrophages markedly reduced the T cell proliferative response to PAEC. Together, these results indicate that the enhanced adherence of human monocytes to PAEC contributes to xenograft rejection beyond the hyperacute period by leading to tissue infiltration, elaboration of cytokines, and an augmented indirect pathway of T cell xenoantigen recognition.     

Female Germ Cell Loss From Radiation and Chemical Exposures

Female germ cell in some mammals are extremely sensitive to killing by ionizing radiation, especially during development. Primordial oocytes in juvenile mice have an LD₃₀ of only 6-7 rad, and the germ cell pool in squirrel monkeys is destroyed by prenatal exposure of 0.7 rad/day. Sensitivity varies greatly with species and germ cell stage. Unusually high sensitivity has not been found in macaques and may not occur in man, but this has not been established for all developmental stages. The exquisite oocyte radiosensitivity in mice apparently reflects vulnerability of the plasma membrane, not DNA, which may have implications fur estimating human genetic risks. Germ cells can be killed also by chemicals. Such oocyte loss, with similarities to radiation effects, is under increasing study, including chemotherapy observations in women. More than 75 compounds have been tested in mice, with in vivo toxicity quantified by oocyte loss; certain chemicals apparently act on the membrane.