Suharti Maslam

Prominent decline of newborn cell proliferation, differentiation, and apoptosis in the aging dentate gyrus, in absence of an age-related hypothalamus-pituitary-adrenal axis activation

Neurogenesis and apoptosis in the hippocampal dentate gyrus (DG) occur during development and adulthood. However, little is known about how these two processes relate to each other during aging. In this study, we examined apoptosis, proliferation, migration, and survival of newborn cells in the young (2 weeks), young-adult (6 weeks), middle-aged (12 months), and old (24 months) rat DG. We also measured dentate volume and cell numbers, along with basal corticosterone and stress response parameters. We show that new cell proliferation and apoptosis slow down profoundly over this time period. Moreover, migration and differentiation into a neuronal or glial phenotype was strongly reduced from 6 weeks of age onwards; it was hardly present in middle-aged and old rats as confirmed by confocal analysis. Surprisingly, we found no correlation between cell birth and corticosterone levels or stress response parameters in any age group.

Brief treatment with the glucocorticoid receptor antagonist mifepristone normalises the corticosterone-induced reduction of adult hippocampal neurogenesis.

The glucocorticoid receptor antagonist mifepristone has been shown to rapidly and effectively ameliorate symptoms of psychotic major depression. To better understand its mechanism, we investigated mifepristones cellular effects, and found that it rapidly reversed a chronic corticosterone‐induced reduction of adult neurogenesis in rats. Unlike other antidepressants, mifepristone is particularly potent in a high corticosterone environment. These data indicate that similarly to its clinical efficacy, mifepristones effects on adult neurogenesis are rapid and positive, and may therefore be important for its mechanism of action.

The Corticosterone Synthesis Inhibitor Metyrapone Prevents Hypoxia/Ischemia-Induced Loss of Synaptic Function in the Rat Hippocampus

BACKGROUND AND PURPOSE Ischemia is accompanied by abundant corticosterone secretion, which could potentially exacerbate brain damage via activation of glucocorticoid receptors. We addressed whether manipulating steroid levels during ischemia affects hippocampal synaptic function along with neuronal structure. Moreover, we established whether pretreatment with the glucocorticoid receptor antagonist RU38486 is as effective in preventing deleterious effects after ischemia as is the steroid synthesis inhibitor metyrapone. METHODS Rats underwent 20 minutes of unilateral hypoxia/ischemia (HI). Convulsions were monitored after HI, and 24 hours later, field potentials were recorded in vitro in the hippocampal CA1 area in response to stimulation of the Schaffer collateral/commissural fibers. Morphological alterations were determined in brain slices from the same animals. Data were correlated with steroid treatment before HI. RESULTS Metyrapone suppressed plasma corticosteroid levels during HI, whereas corticosterone treatment significantly elevated plasma steroid levels. These treatments affected the incidence of visible seizures after HI: corticosterone treatment resulted in the highest incidence, whereas metyrapone attenuated the occurrence of seizures. Moreover, the HI-induced impairment in synaptic transmission in the CA1 area in vitro was exacerbated by concomitant corticosteroid treatment and alleviated by pretreatment with metyrapone. In parallel, degenerative changes in the hippocampus after HI were most pronounced after corticosterone treatment, whereas metyrapone reduced these alterations. RU38486 was effective only in reducing the incidence of seizures shortly after ischemia. CONCLUSIONS We tentatively conclude that synaptic function along with cellular integrity is preserved after HI by preventing the ischemia-evoked rise in corticosteroid levels rather than blocking the glucocorticoid receptor.

Immunocytochemical analysis of the dopamine system in the brain and spinal cord of the European eel, Anguilla anguilla

SummaryThe distribution of dopamine-containing perikarya and fibres in the central nervous system of the eel, Anguilla anguilla, was determined by using a specific dopamine antiserum. Telencephalic dopamine-immunoreactive somato are located in the external cell layer of the olfactory bulb and throughout the rostrocaudal extent of the subpallium; immunoreactive fibres are located primarily in the bulb and in ventral and lateral portions of the hemispheres. Diencephalic dopamine-immunoreactive neurons are associated with the ventricles in the preoptic area and hypothalamus and in the posterior tubercle. Many of the neurons in the hypothalamus are liquor-contacting. Very few immunoreactive neurons are located in the mesencephalon, and no dopamine-containing cells are found in regions that can be homologized with the ventral tegmental area and substantia nigra of amniotes. There is a rich innervation of the medial octavolateralis nucleus and certain layers of the torus semicircularis and of the tectum. dopamine-containing neurons are located in the vagal lobe, by the vagal motor nucleus and in the area postrema, which provides a rich dopaminergic innervation of the brainstem motor column and of the reticular formation. Immunoreactive liquor-contacting neurons line the central canal and another type of labelled neuron lies dorsally in the spinal cord.

Increased P27KIP1 protein expression in the dentate gyrus of chronically stressed rats indicates G1 arrest involvement.

Various chronic stress paradigms decrease new cell proliferation in the hippocampal dentate gyrus, yet the exact underlying mechanism is still unclear. In the first gap (G1) phase of the cell cycle, both stimulatory and inhibitory signals derived from the extracellular environment converge. Corticosteroids, which increase during stress and are well-known anti-mitotics, cause cells in vitro to arrest in the G1 phase. Following 3 weeks of unpredictable stress, we therefore expected a change in protein expression of various important G1 cell cycle regulators in the adult rat subgranular zone. Using quantitative immunocytochemistry, we show that particularly cyclin-dependent kinase inhibitor p27Kip1 expression is significantly increased. In addition, 3 weeks of recovery after stress normalized the numbers of p27Kip1-expressing cells, consistent with the recovered adult cell proliferation in these animals. P27Kip1-positive cells do not overlap with GFAP-staining and only to a limited extent with Ki-67-expressing cells. Numbers of cyclin E- and cyclin D1-expressing cells did not change after chronic stress. These results indicate that chronic stress causes cycling cells in the adult hippocampus to arrest in G1, thereby providing more mechanistic insight in the stress-induced decrease in cell proliferation.

Quantitative histochemistry of three mouse hind-limb muscles: the relationship between calcium-stimulated myofibrillar ATPase and succinate dehydrogenase activities.

SummaryA quantitative modification of Meijers calcium-lead capture method, for the demonstration of calcium-stimulated myofibrillar ATPase activity at physiological pH, is described. A range of myofibrillar ATPase activities has been found among fast muscle fibres in two mouse hind-limb muscles. The myofibrillar ATPase activity of fast muscle fibres is 1.5–3 times higher than the myofibrillar ATPase activity of slow muscle fibres.Myofibrillar ATPase activities and succinate dehydrogenase activities of individual muscle fibres have been determined in serial sections. Activities of the two enzymes are correlated positively in soleus (fast and slow fibres), and negatively in plantaris (almost all fast) and extensor digitorum longus muscle (all fast). However, this correlation is not significant among the oxidative fibres in the extensor digitorum longus. The fibres of the latter muscle cannot be classified satisfactorily into two sub-types.

Fos-like immunohistochemical identification of neurons active during the startle response of the rainbow trout

Activity‐dependent Fos‐like expression was investigated immunohistochemically in rainbow trout (Oncorhynchus mykiss) that had performed vibratory‐evoked startle responses. We found significantly higher numbers of Fos‐like‐immunoreactive neurons in the reticular formation, in the octavolateral area, and in several cranial nerve motor nuclei in the brain and in the motor column of the spinal cord of startled fish than in control fish. In one fish, in which stimulation did not evoke startle responses, substantial numbers of positive cells occurred in the brain, primarily in the magnocellular octavolateral nucleus. We observed Fos‐like‐immunoreactive neurons in cell groups that are known to participate in the startle response (e.g., the Mauthner cell) as well as in cell groups that have been proposed but until now not shown to be involved. J. Comp. Neurol. 439:306–314, 2001.

A polyclonal antibody against mammalian FOS can be used as a cytoplasmic neuronal activity marker in a teleost fish.

A polyclonal antibody raised against a conserved region of a mammalian FOS sequence was tested for its use as an activity marker in the rainbow trout. The FOS-like expression in the trout is entirely cytoplasmic and appears in a Nissl-like pattern. The reaction is specifically induced by both orthodromic and antidromic electrical stimuli and during motor responses evoked by natural stimulation, although some positive neurons are found at locations that are not obviously related to the presented stimuli. Following spinal nerve stimulation, antidromically activated motoneurons were found to be positive in the ipsilateral spinal cord. Orthodromic driving of spinal moto- and interneurons by stimulation of the medial longitudinal fasciculus (MLF) in the hindbrain evoked FOS-like immunoreactivity throughout the motor column in the spinal cord, but not in regions lying caudal to a lesion of the MLF-axons. Evoking about 25 startle responses by natural auditory stimulation gives FOS-like immunoreactivity in the Mauthner cell, which initiates the response, whereas positive Mauthner cells were never observed in control fish. The stimulation protocols that were used strongly activated the stimulated cells and so the observed FOS-like immunoreactivity might be related to an increase protein synthesis needed to restore their depleted transmitter levels.

Postischemic Steroid Modulation: Effects on Hippocampal Neuronal Integrity and Synaptic Plasticity

Elimination of corticosteroids after ischemia, by removal of the adrenals, has been reported to preserve neuronal integrity later. To establish the therapeutic potential of this observation, the authors address two questions: first, whether clinically more relevant steroid manipulations after ischemia exert similar protective effects, and second, whether changes in synaptic functioning occur along with structural alterations. To test this, the authors treated animals immediately after hypoxia—ischemia with (1) the steroid synthesis inhibitor metyrapone, (2) the synthetic glucocorticoid receptor agonist dexamethasone, (3) the selective glucocorticoid antagonist RU 38486, or (4) corticosterone. Metyrapone, but none of the other compounds, attenuated the occurrence of seizures immediately after ischemia, Twenty-four hours after hypoxia—ischemia, CA1 hippocampal field potentials in response to stimulation of fibers were found to be reduced. The attenuation of synaptic transmission was partly prevented by metyrapone. None of the other experimental treatments influenced the impaired synaptic function, Gross morphologic analysis revealed no differences in the loss of neuronal structure between the experimental groups at this time point. Taken together, these data suggest that metyrapone preserves neuronal functioning despite loss of neuronal structure. The authors tentatively conclude that preventing the ongoing production of steroids shortly after ischemia can delay and attenuate the appearance of ischemia-related pathology.

Gene expression profiles associated with survival of individual rat dentate cells after endogenous corticosteroid deprivation.

Removal of circulating corticosterone by adrenalectomy (ADX) leads to apoptosis after 3 days in a small population of rat dentate granule neurons, whereas most surrounding cells remain viable. Interestingly, a specific expression profile is triggered in surviving granule cells that may enhance their survival. Hippocampal slices prepared 1, 2 or 3 days after ADX or sham operation were stained ex vivo with Hoechst 33258, which serves to identify apoptotic neurons. After electrophysiological analysis, multiple gene expression in surviving individual granule cells was assessed by linear antisense RNA amplification and hybridization to slot blots containing various neuronal cDNAs. Hierarchical clustering and principal component analysis was performed on two physiological variables and 14 mRNA ratios from ADX cells from every time point. Our results indicate that surviving 3‐day ADX granule cells display lower membrane capacitance, lower relative N‐methyl‐d‐aspartate (NMDA) R1 mRNA expression and higher relative mineralocorticoid receptor (MR), α1A voltage‐gated Ca‐channel, Bcl‐2 and NMDA R2C mRNA expression. Some 1‐ and 2‐day ADX cells cluster with these 3‐day survivors; therefore, one or more components of their mRNA expression profile may represent predictive markers for apoptosis resistance. The functional relevance of two candidate genes was tested by in vivo local over‐expression in the same model system; of these, Bcl‐2 conferred partial protection when induced shortly before ADX. Therefore, removal of corticosteroids triggers a specific gene expression profile in surviving dentate granule cells; key components of this profile may be associated with their survival.