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
Nadine Griesche, Verena Pesch, Rohit Nalavade, Stephanie Weber, Ireen König, Manuel Schölling, Christoph Möhl and Sybille KrauB
Traditionally, studies on protein translation rely on systems, in which cells have been lysed prior determination of levels of the protein of interest. However, these assays do not reflect the protein synthesis in living cells in real time, but analyze protein levels after a given incubation time, leading to limitations in results based on experimental parameters. To overcome this problem, we have previously established a Fluorescence recovery after photobleaching (FRAP)-based technique to monitor protein translation in living cells. For this, the protein of interest fused to green fluorescent protein (GFP) is expressed in cell lines. After bleaching the entire cell, the fluorescent signal of the protein of interest is lost, allowing to capture the signal recovery of newly translated GFPtagged protein over time. Here we present two improved versions of this technique using different fluorescent dyes: tFRAP (translational FRAP). For the first improved version of tFRAP we have inserted a second fluorescent dye, red fluorescent protein (RFP), into the same expression vector that drives expression of the protein of interest fused to GFP driven by a second promoter. For the second improved version of tFRAP we have fused our protein of interest to a photo-switchable dye, Dendra2. Both improved versions allow to correct the fluorescence signal intensity of the protein of interest for different transfection rates of individual cells. These two advanced techniques are new powerful tools for quantifying translation rates in living cells and will be useful in future studies on mRNA translation.