[Comparison on feeding habits of Cervus wallichii and sympatric ungulates and domestic animals in green grass period]. / 西藏马鹿与同域野生有蹄类、家畜草青期食性比较.

Tibetan red deer (Cervus wallichii) is an endemic species to China, which was once considered extinct in the wild. As there are several other wild ungulates and domestic animals with similar feeding habits within its habitat range, it's thus essential to study interspecific competition and co-existence between Tibetan red deer and other cohabiting ungulates in the highly unique environment of Qinghai-Tibet Plateau. Using microscopic analysis on fresh fecal samples collected in Sangri Tibetan Red Deer Nature Reserve from August to September in 2013 and 2014, the trophic niche width and overlap index were calculated on the basis of diet composition of C. wallichii, Cervus albirostris, Procapra picticaudata, Bos mutus and Capra hircas in green grass period. We analyzed and compared the overlap and differentiation of feeding habits between Tibetan red deer and other wild ungulates and domestic animals. The results showed that C. wallichii fed on similar edible plants with other species, but differed in proportion of different dietary components, with the main edible plants of C. wallichii being mostly the secondary edible plants to other species. Leontopodium pusillum was the common main edible plant for C. wallichii (percentage in animal recipes was 11.2%) and B. mutus (10.2%), Salix xizangensis was the common main edible plant of C. wallichii (9.6%) and C. albirostris (11.4%). At plant family level, Leguminosae was the common main edible plant family for C. wallichii (21.4%) and P. picticaudata (42.5%). Cyperaceae was the common main edible plant family for C. albirostris (49.2%), B. mutus (33.4%) and C. hircas (50.3%). Compositae was main edible plant family for C. wallichii (29.6%), as well as the secondary edible plant family for C. albirostris (7.6%), P. picticaudata (11.6%), B. mutus (17.3%) and C. hircas (14.1%). As the secondary edible plant family for C. wallichii (7.1%), Gramineae took up a lower proportion than that of the other ungulates (C. albirostris (13.6%), P. picticaudata (12.3%), B. mutus (11.5%) and C. hircas (16.0%)). Food overlap indices between C. wallichii and the other ungulates were all higher than 0.5, and the highest with B. mutus (0.65). The food diversity index (1.32), evenness index (0.37) and niche width index (15.79) of C. wallichii were all at high values. Compared with the results from 2007 to 2008, dietary composition of Tibetan red deer changed greatly as the proportion of Leguminosae increased while that of Cyperaceae decreased, resulting in improvement of food quality. In addition, there was greater competition of food resources between C. wallichii and domestic animals, which would further affect the distribution range and living space of C. wallichii.

Mitochondrial BNIP3 upregulation precedes endonuclease G translocation in hippocampal neuronal death following oxygen-glucose deprivation.

BACKGROUND: Caspase-independent apoptotic pathways are suggested as a mechanism for the delayed neuronal death following ischemic insult. However, the underlying signalling mechanisms are largely unknown. Recent studies imply the involvement of several mitochondrial proteins, including endonuclease G (EndoG) and Bcl-2/adenovirus E1B 19 kDa-interacting protein (BNIP3), in the pathway of non-neuronal cells. RESULTS: In this report, using western blot analysis and immunocytochemistry, we found that EndoG upregulates and translocates from mitochondria to nucleus in a time-dependent manner in cultured hippocampal neurons following oxygen-glucose deprivation (OGD). Moreover, the translocation of EndoG occurs hours before the observable nuclear pyknosis. Importantly, the mitochondrial upregulation of BNIP3 precedes the translocation of EndoG. Forced expression of BNIP3 increases the nuclear translocation of EndoG and neuronal death while knockdown of BNIP3 decreases the OGD-induced nuclear translocation of EndoG and neuronal death. CONCLUSION: These results suggest that BNIP3 and EndoG play important roles in hippocampal neuronal apoptosis following ischemia, and mitochondrial BNIP3 is a signal protein upstream of EndoG that can induce neuronal death.