Emel Ulupinar

Role of semaphorin III in the developing rodent trigeminal system.

Semaphorins are a large family of secreted and transmembrane glycoproteins. Sema III, a member of the Class III semaphorins is a potent chemorepulsive signal for subsets of sensory axons and steers them away from tissue regions with high levels of expression. Previous studies in mutant mice lacking sema III gene showed various neural and nonneural abnormalities. In this study, we focused on the developing trigeminal pathway of sema III knockout mice. We show that the peripheral and central trigeminal projections are impaired during initial pathway formation when they develop into distinct nerves or tracts. These axons defasciculate and compromise the normal bundling of nerves and restricted alignment of the central tract. In contrast to trigeminal projections, thalamocortical projections to the barrel cortex appear normal. Furthermore, sema III receptor, neuropilin, is expressed during a short period of development when the tract is laid down, but not in the developing thalamocortical pathway. Peripherally, trigeminal axons express neuropilin for longer duration than their central counterparts. In spite of projection errors, whisker follicle innervation appears normal and whisker-related patterns form in the trigeminal nuclei and upstream thalamic and cortical centers. Our observations suggest that sema III plays a limited role during restriction of developing trigeminal axons to proper pathways and tracts. Other molecular and cellular mechanisms must act in concert with semaphorins in ensuring target recognition, topographic order of projections, and patterning of neural connections.

Differential effects of NGF and NT-3 on embryonic trigeminal axon growth patterns.

We examined the effects of neurotrophins nerve growth factor (NGF) and neurotrophin‐3 (NT‐3) on trigeminal axon growth patterns. Embryonic (E13–15) wholemount explants of the rat trigeminal pathway including the whisker pads, trigeminal ganglia, and brainstem were cultured in serum‐free medium (SFM) or SFM supplemented with NGF or NT‐3 for 3 days. Trigeminal axon growth patterns were analyzed with the use of lipophilic tracer DiI. In wholemount cultures grown in SFM, trigeminal axon projections, growth patterns, and differentiation of peripheral and central targets are similar to in vivo conditions. We show that in the presence of NGF, central trigeminal axons leave the tract and grow into the surrounding brainstem regions in the elongation phase without any branching. On the other hand, NT‐3 promotes precocious development of short axon collaterals endowed with focal arbors along the sides of the central trigeminal tract. These neurotrophins also affect trigeminal axon growth within the whisker pad. Additionally, we cultured dissociated trigeminal ganglion cells in the presence of NGF, NT‐3, or NGF+NT‐3. The number of trigeminal ganglion cells, their size distribution under each condition were charted, and axon growth was analyzed following immunohistochemical labeling with TrkA and parvalbumin antibodies. In these cultures too, NGF led to axon elongation and NT‐3 to axon arborization. Our in vitro analyses suggest that aside from their survival promoting effects, NGF and NT‐3 can differentially influence axon growth patterns of embryonic trigeminal neurons. J. Comp. Neurol. 425:202–218, 2000.

Corticospinal Motor Neurons Are Susceptible to Increased ER Stress and Display Profound Degeneration in the Absence of UCHL1 Function

Corticospinal motor neurons (CSMN) receive, integrate, and relay cerebral cortexs input toward spinal targets to initiate and modulate voluntary movement. CSMN degeneration is central for numerous motor neuron disorders and neurodegenerative diseases. Previously, 5 patients with mutations in the ubiquitin carboxy-terminal hydrolase-L1 (UCHL1) gene were reported to have neurodegeneration and motor neuron dysfunction with upper motor neuron involvement. To investigate the role of UCHL1 on CSMN health and stability, we used both in vivo and in vitro approaches, and took advantage of the Uchl1nm3419 (UCHL1−/−) mice, which lack all UCHL1 function. We report a unique role of UCHL1 in maintaining CSMN viability and cellular integrity. CSMN show early, selective, progressive, and profound cell loss in the absence of UCHL1. CSMN degeneration, evident even at pre-symptomatic stages by disintegration of the apical dendrite and spine loss, is mediated via increased ER stress. These findings bring a novel understanding to the basis of CSMN vulnerability, and suggest UCHL1−/− mice as a tool to study CSMN pathology.

Gender- and anxiety level-dependent effects of perinatal stress exposure on medial prefrontal cortex

Early life stress leads to psychopathological processes correlated with the predisposition of individuals. Prolonged development of the prefrontal cortex (PFC), playing a critical role in the cognition, personality and social behavior, makes it susceptible to adverse conditions. In this study, we evaluated the dendritic morphology of medial PFC neurons in rats subjected to perinatal stress exposure. Unbiased stereological counting methods showed that total number estimation of c-Fos (+) nuclei, indicating the neuronal activation upon stressful challenge, significantly increased in high anxious animals compared with low anxious and control groups, in both gender. Golgi-Cox staining of neurons displayed anxiety level- and sex-dependent reduction in the dendritic complexity and spine density of pyramidal neurons, especially in the stressed males. While the total length of dendrites were not correlational; density of spines, specifically the mushroom subtypes, showed a negative correlation with the anxiety level of stressed animals. These results suggest that medial PFC is a critical site of neural plasticity within the stressor controllability paradigm. Outcomes of early life stress might be predicted by analyzing the density and morphology of spines in the apical dendrites of pyramidal neurons in correlation with the anxiety-like behavior of animals.

Effects of sertraline on behavioral alterations caused by environmental enrichment and social isolation

Environmental conditions are known to play a critical role in the pathogenesis of affective disorders. In this study, the effects of sertraline, a selective serotonin (5-HT) reuptake inhibitor, on anxiety- and depression-like behaviors were investigated in rats reared in different housing conditions. Wistar rats of both sexes were divided into three groups according to their rearing conditions (Enriched = EC, Isolated = IC and Standard = SC), after weaning at postnatal day 21. While animals in control conditions were housed as a group of 4 rats in regular size plexiglass cages, social isolation groups were housed individually in metal cages. Animals in enriched conditions were housed as a group of 12 rats in specially designed cages equipped with different stimulating objects. Six weeks later, activitymeter, elevated plus maze, rotarod, grip, forced swimming and sucrose preference tests were applied to all animals and all of the tests were repeated after i.p. injection of sertraline (10 mg/kg/day) for 7 days. Environmental enrichment reduced the stereotypic behavior, improved the motor coordination and facilitated the learning skills in animals. However, housing conditions affected depression-like parameters, but not anxiety-like parameters. Sertraline treatment reduced the depression-like effect in EC and SC, but not in IC. It decreased anxiety-like behavior in IC while increased in EC. Socially isolated animals preferentially consumed more sucrose and water than the other groups, and interestingly, these differences became more significant following sertraline treatment. These results show that the responses of animals to anti-depressive drugs could be differentially affected by the behavioral consequences of the diverse housing conditions. Thus, to improve the treatment of depression; behavioral consequences of diverse housing conditions should be taken into consideration.

Rearing conditions differently affect the motor performance and cerebellar morphology of prenatally stressed juvenile rats

The cerebellum is one of the most vulnerable parts of the brain to environmental changes. In this study, the effect of diverse environmental rearing conditions on the motor performances of prenatally stressed juvenile rats and its reflection to the cerebellar morphology were investigated. Prenatally stressed Wistar rats were grouped according to different rearing conditions (Enriched=EC, Standard=SC and Isolated=IC) after weaning. Six weeks later, male and female offspring from different litters were tested behaviorally. In rotarod and string suspension tests, females gained better scores than males. Significant gender and housing effects were observed especially on the motor functions requiring fine skills with the best performance by enriched females, but the worst by enriched males. The susceptibility of cerebellar macro- and micro-neurons to environmental conditions was compared using stereological methods. In female groups, no differences were observed in the volume proportions of cerebellar layers, soma sizes and the numerical densities of granule or Purkinje cells. However, a significant interaction between housing and gender was observed in the granule to Purkinje cell ratio of males, due to the increased numerical densities of the granule cells in enriched males. These data imply that proper functioning of the cerebellum relies on its well organized and evolutionarily conserved structure and circuitry. Although early life stress leads to long term behavioral and neurobiological consequences in the offspring, diverse rearing conditions can alter the motor skills of animals and synaptic connectivity between Purkinje and granular cells in a gender dependent manner.

Lesion-induced synaptic plasticity in the somatosensory cortex of prenatally stressed rats

Prenatal stress exposure causes long-lasting impairments of the behavioral and neuroendocrine responses to later stressors of the offspring. Although mechanisms underlying these effects remain largely unknown, abnormalities in the neuronal plasticity might be responsible for neurobiological alterations. This study used the whisker-to-barrel pathway as a model system to investigate the effects of prenatal stress on lesion-induced plasticity of neurons. Pregnant rats were subjected to immobilization stress during the trigeminal neurogenesis period, corresponding to gestational days 12 to 17, for three hours a day. After birth, the middle row (C) whisker follicles of pups from the control and stressed groups were electrocauterized. Ten days later, tangentially sectioned cortical hemispheres were stained with cytochrome oxidase histochemistry to calculate the volumes of each barrel row (A-E) in both lesioned and intact sides of the cortex, using stereological methods. The adrenal to body weight ratios were significantly increased in stressed animals, when compared to the controls. The pattern and total volume of the barrel subfield remained unaltered, but the lesion-induced map plasticity index, calculated as the D/C ratio, decreased in stressed animals. In addition, the BDNF (Brain Derived Neurotrophic Factor), NT-3 (neurotrophin-3) and the cyclic AMP response element binding protein (CREB) phosphorylation levels in tissue homogenates of the barrel cortices were measured using the ELISA method. In prenatally stressed animals, the BDNF and NT-3 levels were reduced on the lesioned side, but significant CREB activation was observed on the intact side of the barrel cortex. Taken together, the results show that prenatal stress exposure negatively affects critical period plasticity by reducing the expansion of active barrels following peripheral whisker lesion. These changes arise independent of CREB phosphorylation and appear to be mediated by reduced levels of neurotrophins.

Pyridoxine might not have a preventive effect on the retinyl palmitate-induced viscerocranial anomalies.

Viscerocranial anomalies are induced in the presence of various teratogens. Vitamin A-induced cleft palate formation is one of the most frequently used experimental models in these studies. However, the underlying mechanisms are not yet fully understood. Several studies have shown that exogenous vitamin A disrupts the fusion of the palatal shelves by increasing the expression of epidermal growth factor receptor (EGFR). More recently, pyridoxine (vitamin B6) has been reported to have a potentially protective effect in regard to viscerocranial malformations. Therefore, in this study, we aimed to investigate whether pyridoxine has a preventive effect on retinyl palmitate-induced viscerocranial anomalies. The frequency of gross malformations induced by retinyl palmitate, the natural form of vitamin A, has been studied in a dose dependent manner. Low doses of retinyl palmitate (100 mg/kg) exposure on embryonic day (ED) 10 caused no gross anomalies in the rat fetuses. Teratogenic effects were observed only after exposure to higher dosages (1000 mg/kg) and primarily targeted the developing eyes and palates. On the other hand, co-administration of 10mg/kg pyridoxine, at ED 9 and 10, significantly increased the frequencies of anomalies, even in the moderate dosage (500 mg/kg) group. In all cleft palates, sustained expression of EGFR in the medial edge epithelium was detected by immunohistochemistry. These results show that co-administration of pyridoxine has an inductive rather than protective effect on the formation of viscerocranial malformations after exposure to hypervitaminosis-A.

Agmatine co‐treatment attenuates allodynia and structural abnormalities in cisplatin‐induced neuropathy in rats

Cisplatin is a widely used antineoplastic agent in the treatment of various cancers. Peripheral neuropathy is a well‐known side effect of cisplatin and has potential to result in limiting and/or reducing the dose, decreasing the quality of life. Thus, effective treatments are needed. Agmatine is an endogenous neuromodulator that has been shown to exert antiallodynic effects in various animal studies. The first aim of this study was to investigate the in vitro effects of agmatine on cisplatin‐induced neurotoxicity. Primary cultures of dorsal root ganglia (DRG) which are the primary target of drug injury were prepared. DRG cells were incubated with cisplatin (100, 200, 500 μm). Then, agmatine (10, 100, 500 μm) was administered with the submaximal concentration of cisplatin. Cisplatin caused concentration‐dependent neurotoxicity, and agmatine did not alter this effect. The second aim was to investigate the effects of agmatine on cisplatin‐induced peripheral neuropathy in rats and the influence of nitric oxide synthase (NOS) inhibitor, L‐NAME, in this effect. Female Sprague Dawley rats received intraperitoneal saline (control), cisplatin (3 mg/kg), cisplatin+agmatine (100 mg/kg), or cisplatin+agmatine+L‐NAME (10 mg/kg) once a week for 5 weeks. The mechanical allodynia, hot plate, and tail clip tests were performed, and DRG cells and sciatic nerves were analyzed. Agmatine and agmatine+L‐NAME combination attenuated CIS‐induced mechanical allodynia and degeneration in DRG cells and sciatic nerves. However, L‐NAME did not potentiate the antiallodynic or neuroprotective effect of agmatine. These findings indicate that agmatine co‐administration ameliorates cisplatin‐induced neuropathy and may be a therapeutic alternative.