हमारा समूह 1000 से अधिक वैज्ञानिक सोसायटी के सहयोग से हर साल संयुक्त राज्य अमेरिका, यूरोप और एशिया में 3000+ वैश्विक सम्मेलन श्रृंखला कार्यक्रम आयोजित करता है और 700+ ओपन एक्सेस जर्नल प्रकाशित करता है जिसमें 50000 से अधिक प्रतिष्ठित व्यक्तित्व, प्रतिष्ठित वैज्ञानिक संपादकीय बोर्ड के सदस्यों के रूप में शामिल होते हैं।
ओपन एक्सेस जर्नल्स को अधिक पाठक और उद्धरण मिल रहे हैं
700 जर्नल और 15,000,000 पाठक प्रत्येक जर्नल को 25,000+ पाठक मिल रहे हैं
Amanda Pennington,Vasyl Sava,Shijie Song,Niketa Patel,Sanchez-Ramos
Introduction: Granulocyte colony stimulating factor (G-CSF) administration produces beneficial effects in rodent models of stroke, trauma and neurodegenerative diseases by acting on both bone marrow-derived and neuronal cells. The aim of the study was to elucidate cellular mechanism(s) of G-CSF action by direct application to neuronal and monocytic cell lines.
Method: Cell culture models of monocytes (THP-1) and neurons (SH-SY5Y) cells were incubated with G-CSF. The following parameters were measured: G-CSF receptor binding kinetics; DNA synthesis; signal transduction, in particular expression of alternatively spliced protein kinase C (PKCδVIII) and the anti-apoptotic protein Bcl-2; changes in adhesiveness and migratory properties induced by G-CSF in the monocytic cells.
Results: G-CSF receptor binding kinetics in the two lines differed, with Kd in the neuronal line being significantly higher than that of the monocytic cells. Despite higher affinity of G-CSF for receptors on the monocytic cells, G-CSF treatment increased Bcl-2 expression in the neuronal line at lower concentrations than that required in the monocytic cell line. G-CSF did not increase either cellular adhesiveness or migration through a semi-permeable membrane, whereas monocyte chemotactic protein (MCP-1) significantly improved migration.
Conclusions: The cellular and molecular responses to G-CSF treatment of monocytic cells suggest that neither changes in adhesiveness nor migratory capacity are responsible for the beneficial effects of G-CSF administration in models of neurologic diseases. G-CSF induction of anti-apoptotic signaling in neurons is an important component of its neuroprotective effects in models of brain injury.