Motor neurons in Cu/Zn superoxide dismutase-deficient mice develop normally but exhibit enhanced cell death after axonal injury.

The discovery that some cases of familial amyotrophic lateral sclerosis (FALS) are associated with mutations in the gene encoding Cu/Zn superoxide dismutase (SOD1) has focused much attention on the function of SOD1 as related to motor neuron survival. Here we describe the creation and characterization of mice completely deficient for this enzyme. These animals develop normally and show no overt motor deficits by 6 months in age. Histological examination of the spinal cord reveals no signs of pathology in animals 4 months in age. However Cu/Zn SOD-deficient mice exhibit marked vulnerability to motor neuron loss after axonal injury. These results indicate that Cu/Zn SOD is not necessary for normal motor neuron development and function but is required under physiologically stressful conditions following injury.

Prefrontal projections to the mediodorsal nucleus of the thalamus in the rhesus monkey.

The corticothalamic projections to the prefrontal cortex have been shown to be topographically organized. However, the underlying basis for this topography as it relates to the organization of the different architectonically defined areas of the prefrontal cortex has not been systematically studied. In the present investigation we have reassessed the thalamic projections from the different architectonic areas of the prefrontal cortex by using the technique of autoradiography in the rhesus monkey. The results show that the prefronto-mediodorsal projections are organized according to the architectonic differentiation of the prefrontal cortices. Thus architectonically less differentiated medial and orbital prefrontal regions project to the medial sector of the mediodorsal nucleus, the magnocellular subdivision. In contrast, highly differentiated prefrontal area 8 projects to the most lateral sector of the mediodorsal nucleus, the multiformis subdivision. Lateral prefrontal areas with intermediate architectonic features project to the central parvocellular sector of the mediodorsal nucleus. Additionally, these projections also reveal a dorsoventral topography. Thus areas in the medial and dorsolateral cortices project to the dorsal part of the mediodorsal nucleus. In contrast, areas in orbital and ventrolateral cortices project to the ventral part of the mediodorsal nucleus. The topographic organization of the corticothalamic connections described in this study corresponds to the progressive elaboration and differentiation of the architectonic features of the different prefrontal areas. This successive and dichotomous organization of prefrontothalamic connections may provide the basis for the observed differential functions of the prefrontal cortex and the mediodorsal nucleus.

Mice lacking cytosolic copper/zinc superoxide dismutase display a distinctive motor axonopathy.

OBJECTIVE: To characterize the motor neuron dysfunction in two models by performing physiologic and morphometric studies. BACKGROUND: Mutations in the gene encoding cytosolic superoxide dismutase 1 (SOD1) account for 25% of familial ALS (FALS). Transgenes with these mutations produce a pattern of lower motor neuron degeneration similar to that seen in patients with FALS. In contrast, mice lacking SOD1 develop subtle motor symptoms by approximately 6 months of age. METHODS: Physiologic measurements, including motor conduction and motor unit estimation, were analyzed in normal mice, mice bearing the human transgene for FALS (mFALS mice), and knockout mice deficient in SOD1 (SOD1-KO). In addition, morphometric analysis was performed on the spinal cords of SOD1-KO and normal mice. RESULTS: In mFALS mice, the motor unit number in the distal hind limb declined before behavioral abnormalities appeared, and motor unit size increased. Compound motor action potential amplitude and distal motor latency remained normal until later in the disease. In SOD1-KO mice, motor unit numbers were reduced early but declined slowly with age. In contrast with the mFALS mice, SOD1-KO mice demonstrated only a modest increase in motor unit size. Morphometric analysis of the spinal cords from normal and SOD1-KO mice showed no significant differences in the number and size of motor neurons. CONCLUSIONS: The physiologic abnormalities in mFALS mice resemble those in human ALS. SOD1-deficient mice exhibit a qualitatively different pattern of motor unit remodeling that suggests that axonal sprouting and reinnervation of denervated muscle fibers are functionally impaired in the absence of SOD1.

Identification of cholinergic and non-cholinergic neurons in the pons expressing phosphorylated cyclic adenosine monophosphate response element-binding protein as a function of rapid eye movement sleep.

Recent studies have shown that in the pedunculopontine tegmental nucleus (PPT), increased neuronal activity and kainate receptor-mediated activation of intracellular protein kinase A (PKA) are important physiological and molecular steps for the generation of rapid eye movement (REM) sleep. In the present study performed on rats, phosphorylated cyclic AMP response element-binding protein (pCREB) immunostaining was used as a marker for increased intracellular PKA activation and as a reflection of increased neuronal activity. To identify whether activated cells were either cholinergic or noncholinergic, the PPT and laterodorsal tegmental nucleus (LDT) cells were immunostained for choline acetyltransferase (ChAT) in combination with pCREB or c-Fos. The results demonstrated that during high rapid eye movement sleep (HR, approximately 27%), significantly higher numbers of cells expressed pCREB and c-Fos in the PPT, of which 95% of pCREB-expressing cells were ChAT-positive. With HR, the numbers of pCREB-positive cells were also significantly higher in the medial pontine reticular formation (mPRF), pontine reticular nucleus oral (PnO), and dorsal subcoeruleus nucleus (SubCD) but very few in the locus coeruleus (LC) and dorsal raphe nucleus (DRN). Conversely, with low rapid eye movement sleep (LR, approximately 2%), the numbers of pCREB expressing cells were very few in the PPT, mPRF, PnO, and SubCD but significantly higher in the LC and DRN. The results of regression analyses revealed significant positive relationships between the total percentages of REM sleep and numbers of ChAT+/pCREB+ (Rsqr=0.98) cells in the PPT and pCREB+ cells in the mPRF (Rsqr=0.88), PnO (Rsqr=0.87), and SubCD (Rsqr=0.84); whereas significantly negative relationships were associated with the pCREB+ cells in the LC (Rsqr=0.70) and DRN (Rsqr=0.60). These results provide evidence supporting the hypothesis that during REM sleep, the PPT cholinergic neurons are active, whereas the LC and DRN neurons are inactive. More importantly, the regression analysis indicated that pCREB activation in approximately 98% of PPT cholinergic neurons, was caused by REM sleep. Moreover the results indicate that during REM sleep, PPT intracellular PKA activation and a transcriptional cascade involving pCREB occur exclusively in the cholinergic neurons.

Visual-field map in the callosal recipient zone at the border between areas 17 and 18 in the cat.

The representation of the visual field in the callosal fiber recipient zone of area 17 and the adjacent area 17/18 transition zone was determined in the cat. The callosal fiber recipient zone was identified by anterograde transport of tritiated amino acids that had been injected into transcallosal sending zone of the opposite hemisphere. Application of autoradiographic procedures revealed that transcallosal projections are densest in the area 17/18 transition zone, and that their density in area 17 diminishes within 1-2 mm of the transition zone. Of 980 sites sampled in the visual-field mapping part of the study, 507 proved to be in the zone demarcated by transcallosally transported label. In this zone, both ipsilateral- and contralateral-field positions are represented, and the representation of the visual field at the different elevations is not equal. When ipsilateral-field positions are considered, the representation extends to about 4 deg close to the visual axis, and to 15-20 deg at elevations greater than +/- 30 deg, the representation is approximately mirror-symmetric about the horizontal meridian, and the representation is concordant with that of the representation in the area 17 transcallosal sending zone of the opposite hemisphere.

Receptive fields of neurons at the confluence of cerebral cortical areas 17, 18, 20a, and 20b in the cat.

The activity of neurons was recorded extracellularly at the junction of visual cortical areas 17, 18, 20a, and 20b in the cat. The receptive fields of these neurons were striking for their size, which ranged from a diameter of more than 40 deg of visual angle to the complete visual field of the contralateral eye. It is speculated that these large receptive fields may be generated by perturbations in the individual maps as the four areas merge together.

The visual map in the corpus callosum of the cat.

The corpus callosum conveys all the fibers that connect areas 17 and 18 in the 2 cerebral hemispheres of the cat. The purpose of the present study was to ascertain the organization of the visual field map described by these fibers in the corpus callosum. This was achieved by injecting anterograde and retrograde pathway tracers at known locations in the callosally connected zones of areas 17 and 18. The positions of the injection sites were varied systematically to include all visual field elevations represented along the marginal and posterolateral gyri. Overall, the results show (1) that callosal fibers projecting between the 2 marginal gyri, where the lower visual fields are represented, pass through the body of the corpus callosum; (2) that fibers connecting the junction of the marginal and posterolateral gyri in the 2 hemispheres, where central fields are represented, pass through the dorsal splenium of the corpus callosum; and (3) that fibers passing between the ventral portions of the 2 posterolateral gyri, where upper fields are represented, pass through posterior and ventral splenium. In addition, the density of visual fibers in the splenium is greater than in the body of the corpus callosum. Within the overall pattern, a finer arrangement exists, and it was possible, by comparison with the cortical visual field maps, to describe a map of visual field elevations in the corpus callosum. In this map, the representations of the different visual field elevations are not a simple reflection of the map in the cortex. The map of the lower fields contained in the body is spread out, whereas the map of the central and upper fields in the splenium is highly compressed. The high degree with which observations can be reproduced in different cats indicates that the map is stereotyped from one animal to another.

Excitation of the brain stem pedunculopontine tegmentum cholinergic cells induces wakefulness and REM sleep.

Considerable evidence suggests that brain stem pedunculopontine tegmentum (PPT) cholinergic cells are critically involved in the normal regulation of wakefulness and rapid eye movement (REM) sleep. However, much of this evidence comes from indirect studies. Thus, although involvement of PPT cholinergic neurons has been suggested by numerous investigations, the excitation of PPT cholinergic neurons causal to the behavioral state of wakefulness and REM sleep has never been directly demonstrated. In the present study we examined the effects of three different levels of activation of PPT cholinergic cells in wakefulness and sleep behavior. The effects of glutamate on the activity of PPT cholinergic cells were studied by microinjection of one of the three different doses of L-glutamate (0.3, 1.0, and 3.0 microg) or saline (vehicle control) into the PPT cholinergic cell compartment while quantifying the effects on wakefulness and sleep in free moving chronically instrumented cats. All microinjections were made during wakefulness and were followed by 4 h of recording. Polygraphic records were scored for wakefulness, slow-wave sleep states 1 and 2, slow-wave sleep with pontogeniculooccipital waves, and REM sleep. Dependent variables quantified after each microinjection included the percentage of recording time spent in each state, the latency to onset of REM sleep, the number of episodes per hour for REM sleep, and the duration of each REM sleep episode. A total of 48 microinjections was made into 12 PPT sites in six cats. Microinjection of 0.3- and 1.0-microg doses of L-glutamate into the cholinergic cell compartment of the PPT increased the total amount of REM sleep in a dose-dependent manner. Both doses of L-glutamate increased REM sleep at the expense of slow-wave sleep but not wakefulness. Microinjection of 3.0 microg L-glutamate kept animals awake for 2-3 h by eliminating slow-wave and REM sleep. The results show that the microinjection of the excitatory amino acid L-glutamate into the PPT cholinergic cell compartments can increase wakefulness and/or REM sleep depending on the L-glutamate dosage. These findings unambiguously confirm the hypothesis that the excitation of the PPT cholinergic cells is causal to the generation of wakefulness and REM sleep.

Complex transcallosal interactions in visual cortex.

Reversible inactivation by cooling of the transcallosal projecting neurons in areas 17 and 18 of one hemisphere bring about complex changes in the spontaneous and evoked activity of neurons in the callosal receiving zone of the opposite hemisphere. These changes include increases and decreases in evoked and spontaneous activities. Overall, 90% of neurons in layers II and III, 50% in layer IV, and 100% in layers V and VI were affected by the block of transcallosal input. The complexity of the changes was greatest in layers II and III, which are the major callosal recipient layers. The results indicate that many excitatory and inhibitory circuits are under the direct control of transcallosal fibers in the normally functioning brain.

Endogenous and exogenous nitric oxide in the pedunculopontine tegmentum induces sleep.

Mesopontine cholinergic cells in the pedunculopontine tegmental (PPT) nuclei modulate the control of the wake-sleep cycle by releasing acetylcholine to their target structures. These cells also synthesize nitric oxide (NO) which diffuses into the extracellular space and acts as a neuronal messenger. The present study is based on the hypothesis that NO synthesis and its presence in the extracellular space in the PPT play a functional role in regulating the behavioral states of waking and sleep. This hypothesis was tested by microinjecting a control vehicle, NO donor, S-Nitroso-N-acetylpenicillamine (SNAP) and a competitive inhibitor of NO synthase enzyme (NOS), N(G)-Nitro-L-arginine methylester hydrochloride (L-NAME) into the PPT while quantifying the effects on wakefulness and sleep. Six cats were implanted with bilateral guide tubes for PPT microinjection and with standard electrodes to measure waking, slow-wave sleep (SWS), and rapid eye movement (REM) sleep. Five-hour free-moving polygraphic recordings were made following each microinjection (0.25 microl) of control saline, SNAP or L-NAME. Following microinjection of SNAP into the cholinergic cell compartments of the PPT, SWS and REM sleep were increased by 41.65% and 72.10% respectively, compared to the control microinjection. Microinjection of L-NAME reduced SWS and REM sleep by 40.33% and 62.05%, respectively, compared to controls. The present results demonstrate that endogenous NO synthesized within the PPT cholinergic cells functions as a paracrine signal in the control of waking and sleep by modulating local cholinergic cells.

Brainstem afferents of the cholinoceptive pontine wave generation sites in the rat.

The present study was designed to investigate the distribution of brainstem neurons projecting to the pontine wave (P-wave)-generating sites in the rat. In six rats, biotinylated dextran amine (BDA) was microinjected into the physiologically identified cholinoceptive P-wave generation site. In all cases, microinjections of BDA in the cholinoceptive P-wave generating site resulted in retrograde labeling of cell bodies in many parts of the brainstem. The majority of those retrogradely labeled cells were in the pedunculopontine tegmentum, pontine reticular nucleus oralis, parabrachial nucleus, vestibular nucleus, and gigantocellular reticular nucleus. The results presented in this study provide anatomical evidence that the cholinoceptive P-wave generation site in the rat receives anatomical projections from other parts of the brainstem known to be involved in the REM sleep-generation mechanism.

Localization of pontine PGO wave generation sites and their anatomical projections in the rat.

A number of experimental and theoretical reports have suggested that the ponto-geniculo-occipital (PGO) wave-generating cells are involved in the generation of rapid eye movement (REM) sleep and REM sleep dependent cognitive functions. No studies to date have examined anatomical projections from PGO-generating cells to those brain structures involved in REM sleep generation and cognitive functions. In the present study, pontine PGO wave-generating sites were mapped by microinjecting carbachol in 74 sites of the rat brainstem. Those microinjections elicited PGO waves only when made in the dorsal part of the nucleus subcoeruleus of the pons. In six rats, the anterograde tracer biotinylated dextran amine (BDA) was microinjected into the physiologically identified cholinoceptive pontine PGO-generating site to identify brain structures receiving efferent projections from those PGO-generating sites. In all cases, small volume injections of BDA in the cholinoceptive pontine PGO-generating sites resulted in anterograde labeling of fibers and terminals in many regions of the brain. The most important output structures of those PGO-generating cells were the occipital cortex, entorhinal cortex, piriform cortex, amygdala, hippocampus, and many other thalamic, hypothalamic, and brainstem nuclei that participate in the generation of REM sleep. These findings provide anatomical evidence for the hypothesis that the PGO-generating cells in the pons could be involved in the generation of REM sleep. Since PGO-generating cells project to the entorhinal cortex, piriform cortex, amygdala, and hippocampus, these PGO-generating cells could also be involved in the modulation of cognitive functions.