Calbindin-D28k is a calcium-binding protein that mediates intracellular calcium concentrations and exerts a neuroprotective effect against ischemic injury. Ferulic acid provides a neuroprotective effect against focal cerebral ischemia through its anti-oxidative and anti-inflammatory mechanisms. In this study, we investigated whether ferulic acid regulates calbindin-D28k expression during focal cerebral ischemia and glutamate treatment-induced neuronal cell death. Middle cerebral artery occlusion (MCAO) was performed to induce focal cerebral ischemia. Ferulic acid (100 mg/kg, i.v.) or vehicle was immediately administered after MCAO, and brain tissues were isolated 24 h after MCAO. RT-PCR and Western blot analyses showed a decrease in calbindin-D28k in MCAO-operated animals. We found that ferulic acid treatment prevented the MCAO-induced decrease in calbindin-D28k expression. Glutamate exposure elevated the intracellular calcium levels in cultured hippocampal cells, and ferulic acid prevented the glutamate exposure-induced increase in calcium levels. Moreover, ferulic acid also attenuated the glutamate toxicity-induced decrease in calbindin-D28k. Taken together, these in vivo and in vitro results demonstrate that ferulic acid regulates calbindin-D28k expression in neuronal cell injury. Therefore, these findings suggest that ferulic acid exerts a neuroprotective effect by modulating calbindin-D28k expression.

본 연구는 중간대뇌동맥을 폐쇄한 대뇌허혈성 손상모델에서 ferulic acid에 의해 조절되는 HO-1과 HO-2의 발현에 관하여 조사하였다. 흰쥐(Sprague-Dawley, 수컷)에 ferulic acid (100 mg/kg) 또는 vehicle을 중간대뇌동맥폐쇄술(MCAO) 후 정맥으로 주사하였고 중간대뇌동맥폐쇄술(MCAO)을 실시한 24시간 후 대뇌피질의 조직을 적출하였다. Hematoxylin과 eosin 염색을 통하여 MCAO로 유도된 뇌 손상시 ferulic acid의 보호효과를 확인하였다. MCAO을 시행한 대뇌피질에서는 응축된 핵과 신경세포의 괴사 소견을 보였으나, ferulic acid 투여군에서는 이들 신경세포의 병변을 현저히 완화시켰다. HO-1과 HO-2의 RNA와 단백질 발현의 변화를 reverse-transcription PCR과 Western blot으로 분석하였다. HO-1 발현은 MCAO 후 vehicle 투여군에서 현저히 감소하였으나, MCAO 후 ferulic acid를 투여한 실험군에서는 이들 감소의 완화를 보였으며, MCAO를 시행하지 않은 실험군의 수준으로 유지되었다. 그러나, HO-2의 발현은 MCAO 후 vehicle 투여군과 ferulic acid 투여군에서 유의적인 차이는 관찰되지 않았고 MCAO를 시행하지 않은 실험군의 수준으로 유지되었다. 따라서, 본 연구의 결과는 허혈성 뇌 손상시 ferulic acid는 HO-1 발현을 조절하였으나, HO-2의 발현에는 영향을 미치지 못함을 확인하였다. 결론적으로, 허혈성 뇌손상시 ferulic acid는 HO-1의 발현을 조절하여 신경세포를 보호하는 역할을 수행한다는 사실을 확인하였다.

A stroke is the major cause of death and can cause neurological damage. The striatum serves as an input gate of the basal ganglia in assisting motor behavior. The activity-dependent synaptic plasticity in the dorsal striatum (DS) is known to play a key role for recovery of motor control after brain injury. Exercise supports functional recovery from ischemic brain injury through brain-derived neurotrophic factor (BDNF) -induced synaptic plasticity. Exercise upregulate the levels of BDNF within both the hippocampus and cerebral cortes and might act as a gate that primes the brain to respond to environmental stimulation, while simultaneously increasing the ability of neurons to resist insult. However, little is known about the effects of exercise on neuroprotection in the DS. Therefore, in this study we attempted to investigate the effects of exercise on the neuronal cell population in the DS. Transient focal brain ischemia was induced by middle cerebral artery occlusion (MCAO) on male Sprague-Dawley rats (300±30). Animals were subjected to forced treadmill exercise group and sedentary group after MCAO. Exercise improved neurologic functions measured by modified neurological severity score. Exercise group showed reduced infarct volume measured by vital staining with 2,3,5-triphenyltetrazolium chloride. Immunohistochemical analysis was performed in the DS with antibodies of neuronal nuclei (NeuN) protein, glial fibrillary acidic protein (GFAP), a matured neuronal marker and an astrocyte marker respectively and BDNF. Ischemic injury decreased NeuN+ cell population but exercise attenuated this decrease while increase in GFAP+ cell population induced by MCAO was inhibited by exercise. These findings suggest that the neurological function recovery by exercise after ischemic brain injury may be mediated by alteration of neuronal cell population in the DS.