Autometallographic enhancement of the Golgi-Cox staining enables high resolution visualization of dendrites and spines

We present a method for autometallographic (AMG) enhancement of the Golgi-Cox staining enabling high resolution visualization of dendrites and spines. The method is cheaper and more flexible than conventional enhancement procedures performed with commercial photographic developers. The staining procedure is thoroughly described and we demonstrate with qualitative and quantitative data, how histological tissue sectioning, Golgi-Cox immersion time and different AMG enhancement length may influence the staining of dendrites and spines in the rat hippocampus. The described method will be of value for future behavioural-anatomical studies, examining changes in dendrite branching and spine density caused by brain diseases and their subsequent treatment.     

延迟5分钟剖宫产造全脑缺氧缺血新生大鼠模型

目的建立围产期全脑缺氧缺血性损伤的新生大鼠模型。方法 SD雌性大鼠妊娠21 d时,颈椎脱臼法处死,用止血钳夹闭双侧子宫角血管5 min后,剖宫产取出新生大鼠,交由代乳鼠喂养。结果造模组雌性大鼠9只,共娩出新生大鼠91只,出生3 d内死亡7只,死亡率7.7%。新生大鼠出生第2天进行翻身实验,第14天进行悬吊实验和斜坡实验,造模组和其余各组均有显著性差异。新生大鼠出生后21 d,取脑组织切片行HE染色,显示大脑皮层典型的缺氧缺血性损伤,与正常组相比,可见神经细胞明显的病理形态学改变。结论采用延迟5min剖宫产和代乳鼠喂养的方法,操作简便,并结合行为学测试筛选行为异常者,可建立稳定可靠、可供长期实验使用的围产期全脑缺氧缺血性损伤的新生大鼠模型。     

Participation of neuronal NO-synthase in regulation of hypothalamus vasopressinergic neurons of rat pups at early stages of postnatal ontogeny

To reveal character of interaction of catecholamines (CA) and NO in regulation of development and of the functional state of vasopressinergic (VP-ergic) neurons of supraoptic (SON) and paraventricular (PVN) nuclei, the female rats were injected intraperitoneally with the inhibitor of CA synthesis α-methyl-p-tyrosine, daily, from the 13th to the 20th days of pregnancy. Rat pups born by the females administered with saline at the same period of pregnancy as well as intact pups and adult rats were used as control. Expression of neuronal NO-synthase (nNOS) in neurons of SON and PVN of rat pups at early stages of postnatal development was found to be significantly higher than the definitive level, which allows suggesting participation of NO in development of hypothalamic VP-ergic neurons. The revealed differences of periods of the maximal nNOS expression in the SON and PVN neurons have permitted suggesting development of SON to be completed earlier than that of PVN. The pups exposed to stress at the last third of embryonic development had a long-lasting effect on the state of VP-ergic neurons of the pups after birth. The nNOS expression in neurons does not change, which suggests that NO is not involved in regulation of VP-ergic neurons after exposure to stress at early stages of ontogenesis. A decrease of CA level in the brain at the last third of embryogenesis led to a long preserved decrease of the functional activity of VP-ergic neurons. The nNOS expression in VP-ergic neurons of SON and PVN rose substantially under effect of a compensatory enhancement of tyrosine hydroxylase (TH) expression in neurons of SON and of an increase of the level of CA-ergic innervation of PVN. Thus, we have shown that a decrease of CA level in the embryonic brain leads to an increase of nNOS expression of hypothalamic VP-ergic neurons of rat pups after birth and that the character of NO action on function of VP-ergic neurons does not differ from that of adult animals as soon as at early stages of ontogenesis.     

Monoclonal antibody to rat brain actin antigenically enhanced with HVJ (Sendai Virus) M protein

Summary Monoclonal antibody to rat brain actin was easily produced using HVJ (Sendai Virus) M protein to enhance the antigenicity of the actin. This monoclonal antibody was determined to be IgM with a kappa light chain. By immunoblot analysis the antibody was also shown to react with rat brain actin but not with HVJ M protein on nitrocellulose sheets. Utilizing the antibody, neuronal cytoplasm in the cerebral cortex, the anterior and posterior horns in the spinal cord, the spinal ganglion and astrocytes showed positive immunohistochemical staining by light microscopy. However, Purkinje cells showed variable staining, some staining intensely, while others were negative. All of neurons in specific anatomical locations showed always positive staining but variable intensities. Vascular walls were stained only faintly. By electron microscopy, neuronal cytoplasm showed diffuse positive staining. Other areas showed a positive reaction, including dendrites, the postsynaptic densities, and a few capillary endothelial cells and arterial smooth muscle cells. The results suggest that the HVJ M protein was effective for producing monoclonal antibody to brain actin, and that the antibody could be utilized for the immunohistochemical study of neuronal elements in both normal and pathological conditions.     

Methylphenidate treatment recovers stress-induced elevated dendritic spine densities in the rodent dorsal anterior cingulate cortex

Exposing pups of the rodent species Octodon degus to periodic separation stress during the first three postnatal weeks leads to behavioral alterations, which include reduced attention towards an emotional stimulus and motoric hyperactivity. These behavioral changes, which are reminiscent of symptoms of attention deficit hyperactivity disorder (ADHD), are paralleled by synaptic changes in the dorsal anterior cingulate cortex (ACd), a limbic cortex region, which plays a key role in the modulation of attentional and executive functions. ADHD is typically treated with methylphenidate (MP), a drug acting on the dopaminergic system. However, the effect of chronic MP-treatment on neuronal and synaptic maturation in the developing brain is unknown. Applying the Golgi-Cox stainining technique, we tested in which way chronic MP-treatment interferes with dendritic and synaptic development in the ACd and whether this treatment can restore the stress-induced changes of neuronal connectivity. We found that chronic treatment with 1 mg/kg MP recovers stress-induced changes of spine densities in the ACd. Furthermore, MP-treatment resulted in increased dendritic length and complexity in both, stressed as well as unstressed control animals. These results indicate that synaptic reorganization as well as dendritic growth in the prefrontal cortex continue into prepuberty and are modulated by MP-treatment.     

Monoclonal antibody to rat brain actin antigenically enhanced with HVJ (Sendai virus) M protein

Monoclonal antibody to rat brain actin was easily produced using HVJ (Sendai Virus) M protein to enhance the antigenicity of the actin. This monoclonal antibody was determined to be IgM with a kappa light chain. By immunoblot analysis the antibody was also shown to react with rat brain actin but not with HVJ M protein on nitrocellulose sheets. Utilizing the antibody, neuronal cytoplasm in the cerebral cortex, the anterior and posterior horns in the spinal cord, the spinal ganglion and astrocytes showed positive immunohistochemical staining by light microscopy. However, Purkinje cells showed variable staining, some staining intensely, while others were negative. All of neurons in specific anatomical locations showed always positive staining but variable intensities. Vascular walls were stained only faintly. By electron microscopy, neuronal cytoplasm showed diffuse positive staining. Other areas showed a positive reaction, including dendrites, the postsynaptic densities, and a few capillary endothelial cells and arterial smooth muscle cells. The results suggest that the HVJ M protein was effective for producing monoclonal antibody to brain actin, and that the antibody could be utilized for the immunohistochemical study of neuronal elements in both normal and pathological conditions.     

Perfusion method for preparing pig brain cortex for Golgi-Cox impregnation

The perfusion procedure described in this paper produces high quality impregnation of pig visual and somatosensory cortical neurons with a Golgi-Cox solution. Starting within 30 min after death, pig heads were perfused with a fixative solution composed of a mixture (v/v) of liquid phenol, 5%; formalin, 14%; ethylene glycol, 25%; methanol, 28%; and water, 28% for two periods of 4 hr each. After perfusion, the heads were chilled for at least 18 hr. The entire brain was removed from the skull and then placed in 10% buffered formalin, where it remained for at least 10 days before taking the blocks that were to be immersed in the Golgi-Cox solution. Three weeks spent in the Golgi-Cox solution typically produced uniform neuron impregnation. The tissue blocks were then embedded in celloidin and sectioned at 120 micron. This procedure avoids the following difficulties: Golgi-Cox methods that produced excellent results with rodent or primate tissue were unsuccessful with pig tissue, placing fresh tissue in Golgi-Cox solution resulted in incomplete neuron impregnation, and immersion fixation in 10% buffered formalin without perfusion resulted in excessive staining of glia.     

Immunocytochemical Localization of TASK-3 Protein (K2P9.1) in the Rat Brain

Among all K2P channels, TASK-3 shows the most widespread expression in rat brain, regulating neuronal excitability and transmitter release. Using a recently purified and characterized polyclonal monospecific antibody against TASK-3, the entire rat brain was immunocytochemically analyzed for expression of TASK-3 protein. Besides its well-known strong expression in motoneurons and monoaminergic and cholinergic neurons, TASK-3 expression was found in most neurons throughout the brain. However, it was not detected in certain neuronal populations, and neuropil staining was restricted to few areas. Also, it was absent in adult glial cells. In hypothalamic areas, TASK-3 was particularly strongly expressed in the supraoptic and suprachiasmatic nuclei, whereas other hypothalamic nuclei showed lower protein levels. Immunostaining of hippocampal CA1 and CA3 pyramidal neurons showed strongest expression, together with clear staining of CA3 mossy fibers and marked staining also in the dentate gyrus granule cells. In neocortical areas, most neurons expressed TASK-3 with a somatodendritic localization, most obvious in layer V pyramidal neurons. In the cerebellum, TASK-3 protein was found mainly in neurons and neuropil of the granular cell layer, whereas Purkinje cells were only faintly positive. Particularly weak expression was demonstrated in the forebrain. This report provides a comprehensive overview of TASK-3 protein expression in the rat brain.     

Perfusion Method for Preparing Pig Brain Cortex for Golgi-Cox Impregnation

The perfusion procedure described in this paper produces high quality impregnation of pig visual and somatosensory cortical neurons with a Golgi-Cox solution. Starting within 30 min after death, pig heads were perfused with a fixative solution composed of a mixture (v/v) of liquid phenol, 5%; formalin, 14%; ethylene glycol, 25%; methanol, 28%; and water, 28% for two periods of 4 hr each. After perfusion, the heads were chilled for at least 18 hr. The entire brain was removed from the skull and then placed in 10% buffered formalin, where it remained for at least 10 days before taking the blocks that were to be immersed in the Golgi-Cox solution. Three weeks spent in the Golgi-Cox solution typically produced uniform neuron impregnation. The tissue blocks were then embedded in celloidin and sectioned at 120 μm. This procedure avoids the following difficulties: Golgi-Cox methods that produced excellent results with rodent or primate tissue were unsuccessful with pig tissue, placing fresh tissue in Golgi-Cox solution resulted in incomplete neuron impregnation, and immersion fixation in 10% buffered formalin without perfusion resulted in excessive staining of glia.     

Dendritic morphology and spine density is not altered in motor cortex and dentate granular cells in mice lacking the ganglioside biosynthetic gene B4galnt1 - A quantitative Golgi cox study

Gangliosides are characteristic plasma membrane constituents of vertebrate brain used as milestones of neuronal development. As neuronal morphology is a good indicator of neuronal differentiation, we analyzed how lack of the ganglioside biosynthetic gene Galgt1 whose product is critical for production of four major adult mammalian brain complex gangliosides (GM1, GD1a, GD1b and GT1b) affects neuronal maturation in vivo. To define maturation of cortical neurons in mice lacking B4galnt1 we performed a morphological analysis of Golgi-Cox impregnated pyramidal neurons in primary motor cortex and granular cells of dentate gyrus in 3, 21 and 150 days old B4galnt1-null and wild type mice. Quantitative analysis of basal dendritic tree on layer III pyramidal neurons in the motor cortex showed very immature dendritic picture in both mice at postnatal day 3. At postnatal day 21 both mice reached adult values in dendritic length, complexity and spine density. No quantitative differences were found between B4galnt1-null and wild type mice in pyramidal cells of motor cortex or granular cells of dentate gyrus at any examined age. In addition, the general structural and neuronal organization of all brain structures, qualitatively observed on Nissl and Golgi-Cox, were similar Our results demonstrate that neurons can develop normal dendritic complexity and length without presence of complex gangliosides in vivo. Therefore, behavioral differences observed in B4galnt1-null mice may be attributed to functional rather than morphological level of dendrites and spines of cortical pyramidal neurons.     

Ontogeny of vasopressin and oxytocin in the fetal rat: Early vasopressinergic innervation of the fetal brain

The content and distribution of vasopressin and oxytocin were determined during fetal development in the rat brain and pituitary by means of radioimmunoassay and immunocytochemistry. The vasopressin content in the fetal brain showed a gradual rise from day 16 of pregnancy onwards, while pituitary vasopressin rapidly increased from fetal day 19 until birth. The oxytocin content in the fetal brain was considerably lower than the vasopressin content. A decrease in oxytocin content was seen between day 16 and day 18 while from day 18 of pregnancy onwards a slight increase was found. The pituitary oxytocin content starts to rise between day 17 and 18 of pregnancy, but at term the pituitary oxytocin content was only of the vasopressin value. Immunocytochemistry revealed that vasopressin levels in the fetal rat brain were not only due to the presence of the classical hypothalamoneurohypophyseal system, but also to the early development of exohypothalamic fibers. Vasopressin containing cells were seen from fetal day 16 in the supraoptic nucleus, and from fetal day 18 in the paraventricular nucleus. The fiber outgrowth of these cells towards the pituitary and extrahypothalamic brain sites seems to be well synchronized, as on day 17 vasopressin containing fibers could be demonstrated in the olfactory bulb as well as in the median eminence. No positive staining for oxytocin could be obtained in the fetal rat, while during the entire fetal period no positive staining was found in cell bodies in the region of the suprachiasmatic nucleus. The early peptidergic innervation of the brain, which enabled the tracing of the source of some exohypothalamic fibers, might be related to several central processes among which brain development itself is included.     

Ontogeny of vasopressin and oxytocin in the fetal rat: Early vasopressinergic innervation of the fetal brain

The content and distribution of vasopressin and oxytocin were determined during fetal development in the rat brain and pituitary by means of radioimmunoassay and immunocytochemistry. The vasopressin content in the fetal brain showed a gradual rise from day 16 of pregnancy onwards, while pituitary vasopressin rapidly increased from fetal day 19 until birth. The oxytocin content in the fetal brain was considerably lower than the vasopressin content. A decrease in oxytocin content was seen between day 16 and day 18 while from day 18 of pregnancy onwards a slight increase was found. The pituitary oxytocin content starts to rise between day 17 and 18 of pregnancy, but at term the pituitary oxytocin content was only 1/20 of the vasopressin value. Immunocytochemistry revealed that vasopressin levels in the fetal rat brain were not only due to the presence of the classical hypothalamoneurohypophyseal system, but also to the early development of exohypothalamic fibers. Vasopressin containing cells were seen from fetal day 16 in the supraoptic nucleus, and from fetal day 18 in the paraventricular nucleus. The fiber outgrowth of these cells towards the pituitary and extrahypothalamic brain sites seems to be well synchronized, as on day 17 vasopressin containing fibers could be demonstrated in the olfactory bulb as well as in the median eminence. No positive staining for oxytocin could be obtained in the fetal rat, while during the entire fetal period no positive staining was found in cell bodies in the region of the suprachiasmatic nucleus. The early peptidergic innervation of the brain, which enabled the tracing of the source of some exohypothalamic fibers, might be related to several central processes among which brain development itself is included.     

Rat MYH,a glycosylase for repair of oxidatively damaged DNA,has brain-specific isoforms that localize to neuronal mitochondria

Mitochondrial genomes are exposed to a heavy load of reactive oxygen species (ROS) that damage DNA. Since in neurons, mitochondrial DNA integrity must be maintained over the entire mammalian life span, neuronal mitochondria most likely repair oxidatively damaged DNA. We show that the Escherichia coli MutY DNA glycosylase homolog (MYH) in rat (rMYH) involved in repair of oxidative damage is abundantly expressed in the rat brain, with isoforms that are exclusive to brain tissue. Confocal microscopy and western analyses reveal localization of rMYH in neuronal mitochondria. To assess involvement of MYH in the neuronal response to oxidative DNA damage, we used a rat model of respiratory hypoxia, in which acutely reduced blood oxygenation leads to generation of superoxide, and formation and subsequent removal of 8-hydroxy-2'-deoxyguanosine (8OHdG). Removal of 8OHdG is accompanied by a spatial increase in rMYH immunoreactivity in the brain and an increase in levels of one of the three mitochondrial MYH isoforms, suggesting that inducible and non-inducible MYH isoforms exist in the brain. The mitochondrial localization of oxidative DNA damage repair enzymes in neurons may represent a specialized neuronal mechanism that safeguards mitochondrial genomes in the face of routine and accidental exposures to heavy loads of injurious ROS.     

Serotonergic ligand binding in aging brain of experimental animals

Although the use of aging expeimental animals for studying serotonergic neuronal changes is limited because of species differences, cholinergic neuronal deterioration does appear to be a feature common to mammalian aging brains. In the present study, a recently introduced experimental animal, Suncus murinus (house musk shrew, an insectivore classified as being at the stem of the mammalian phylogenic tree) which in certain physiological characteristics is more closely related to the primate than is the rat, was used as an experimental animal model for serotonergic neuronal deterioration in aging brain. We examined the changes in binding to the membrane fraction of aging brain cortex of the experimental animals Suncus and Fischer rat of the serotonergic ligands, 5-HT, imipramine, and 8-OH-DPAT. Morphological study of the brain stem including the Nucleus raphae by immunohistochemical staining demonstrated that in Suncus all the serotonergic ligands had decreasing affinity to the membrane of aging brain; binding of 8-OH-DPAT and imipramine decreased to a greater extent than that of 5-HT. In contrast, the aging rat brain showed no appreciable change in the binding of serotonergic ligands.     

Neonatal administration of N-acetyl-L-aspartyl-L-glutamate induces early neurodegeneration in hippocampus and alters behaviour in young adult rats

N-acetyl-L-aspartyl-L-glutamate (NAAG) is a dipeptide that could be considered a sequestered form of L-glutamate. As much as 25% of L-glutamate in brain may be present in the form of NAAG. NAAG is also one of the most abundant neuroactive small molecules in the CNS: it is an agonist at Group II metabotropic glutamate receptors (mGluR II) and, at higher concentrations, at the N-methyl-D-aspartate (NMDA) type of ionotropic glutamate receptors. As such, NAAG can be either neuroprotective or neurotoxic and, in fact, both characteristics have been discussed and described in the literature. In the present studies, 250 nmol NAAG was infused into each lateral cerebral ventricle of 12-day-old rat pups and, using Nissl-stained sections, neurodegeneration in the hippocampus was evaluated 24 or 96 h after the infusion. In several experiments, the neuronal death was also visualised by Fluoro-Jade B staining and studied by TUNEL technique. Some of the NAAG-treated animals were allowed to survive until 50 days post partum and subjected to behavioural (open field) tests. The administration of NAAG to 12-day-old rats resulted in extensive death of neurons particularly in the dentate gyrus of the hippocampus. The neurodegeneration was, in part, prevented by administration of an NMDA receptor antagonist MK-801 (0.1 mg/kg). The nuclear DNA-fragmentation demonstrated by TUNEL technique pointed to the presence of non-specific single-strand DNA cleavage. The NAAG-associated neonatal neuronal damage may have perturbed development of synaptic circuitry during adolescence as indicated by an altered performance of the experimental animals in the open field testing (changes in grooming activity) at postnatal day 50. The results underscore the potential neurotoxicity of NAAG in neonatal rat brain and implicate neonatally induced, NMDA receptor-mediated neuronal loss in the development of abnormal behaviour in young adult rats.     

Ethanol induces cell death by activating caspase-3 in the rat cerebral cortex

Ethanol has long been implicated in triggering apoptotic neurodegeneration. We examined the effects of ethanol on the rat brain during synaptogenesis when a spurt in brain growth occurs. This period corresponds to the first 2 postnatal weeks in rats and is very sensitive to ethanol exposure. Ethanol was administered subcutaneously to 7-day- postnatal rat pups by a dosing regimen of 3 g/kg at 0 h and again at 2 h. Blood ethanol levels peaked (677+/-16.4 mg/dl) at 4 h after the first ethanol administration. The cerebral cortexes of the ethanol-treated group showed several typical symptoms of apoptosis such as chromosome condensation and disintegration of cell bodies. Activated caspase-3 positive cells were found in the cortex within 2 h of the first injection, and reached a peak at 12 h. In addition, TUNEL staining revealed DNA fragmentation in the same regions. These results demonstrate that acute ethanol administration causes neuronal cell death via a caspase-3-dependent pathway within 24 h, suggesting that activation of caspase-3 is a marker of the developmental neurotoxicity of ethanol.     

Phosphorylation of Microtubule Proteins in Rat Brain at Different Developmental Stages: Comparison with That Found in Neuronal Cultures

The phosphorylation of rat brain microtubule protein on intracranial injection of labeled phosphate has been analyzed. The major microtubule protein components phosphorylated in vivo in rat brain are the high-molecular-weight microtubule-associated proteins (MAPs) MAP-1A, MAP-1B, and MAP-2. A slight phospholabeling of beta-tubulin, which corresponds to the phosphorylation of a minor neuronal beta-tubulin isotype, is also observed. Whereas MAP-1B, MAP-2, and beta-tubulin are phosphorylated in the brain of 5-day-old rat pups, when most neurons of the CNS are extending processes, MAP-1A phosphorylation is observed only after neuronal maturation takes place. The phosphorylation of MAP-1A, MAP-1B, and beta-tubulin may be due mainly to casein kinase II or a related enzyme, whereas MAP-2 appears to be modified by other enzymes such as the cyclic AMP-dependent protein kinase (protein kinase A) and the calcium/phospholipid-dependent protein kinase (protein kinase C). Microtubule protein phosphorylation has also been studied in neuronal cultures. In differentiated neuroblastoma cells, only MAP-1B and beta-tubulin are phosphorylated in a manner coupled to neurite outgrowth. In primary cultures of fetal rat brain neurons, the pattern of microtubule protein phosphorylation resembles that found in vivo in rat pup brain. As phosphorylated MAP-1A and MAP-1B are present mainly on assembled microtubules, whereas the phosphorylation of MAP-2 decreases its interaction with microtubules, a role can be suggested for the phosphorylation of these proteins in the regulation of microtubule assembly and disassembly during neuronal development.     

Early stress affects neurogenesis in the rat rostral migratory stream

Stressful experience during the early postnatal period may influence processes associated with neurogenesis (i.e. proliferation, cell death, appearance of astrocytes or cell differentiation) in the neonatal rat rostral migratory stream (RMS). To induce stress, pups were subjected to maternal deprivation daily for three hours, starting from the first postnatal day till the seventh postnatal day. Immunohistochemical methods were used to visualize proliferating cells and astrocytes; dying cells and nitrergic cells were visualized using histochemical staining. Quantitative analysis showed that maternal deprivation decreased the number of proliferating cells and significantly increased the number of dying cells in the RMS. Maternal deprivation did not influence the appearance of astrocytes in the RMS, but caused premature differentiation of nitrergic cells. In control rats, nitrergic cells can be observed in the RMS as early as the tenth postnatal day. In maternally deprived pups, these cells were detected as early as the seventh postnatal day. The observed earlier appearance of nitrergic cells in the RMS was associated with altered proliferation and increased cell dying and this observation supports the hypothesis that nitric oxide has an anti-proliferative role in the RMS. Our study demonstrates that maternal deprivation represents a stressful condition with a profound impact on early postnatal neurogenesis.     

Laterization of spatial preference in the female rat

Female rat pups were either left undisturbed in infancy and raised in lab cages or were handled in infancy and raised in enriched environments. In adulthood, animals underwent brain surgery consisting of: 1) a right neocortical ablation, 2) a left neocortical ablation, 3) a sham operation, or 4) no surgery. After recovering, they were tested for the initial direction of movement (left or right) in the open field. Nonhandled intact females were biased to move leftward indicating an asymmetrical brain organization. The intact handled-enriched group was unbiased. The right and left lesions caused the animals to move ipsilateral to the lesion, but there was no difference in the magnitude or response in either early experience group. Thus, early experience in the female rat has a different effect then in the male, and the nature of the brain organization in the two sexes is markedly different.