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
Clifton K. Fagerquist and William J. Zaragoza
Rationale: Shiga toxin-producing Escherichia coli (STEC) are often subjected to DNA damaging antibiotics during culturing in order to elicit the bacterial SOS response and up-regulation of bacteriophage-encoded proteins including Shiga toxin (Stx). However, such antibiotic exposure and stress may also have effects on protein expression.
Methods: Escherichia coli O157:H7 strain EDL933 was grown on Luria-Bertani agar (LBA) supplemented with a sub-inhibitory concentration of ciprofloxacin. Bacterial cells were harvested, suspended in water, gently vortexed and centrifuged. Supernatants were analyzed by MALDI-TOF and nano-LC-ESI-Orbitrap mass spectrometry. A gene knockout was constructed to delete the B-subunit gene from the stx2a operon in the EDL933 strain.
Results: We detected the B-subunits of Stx1a and Stx2a and also peaks in close proximity to these B-subunits. The mass difference between these variants and the Stx1a B-subunit are: -43 Da, +16 Da and +54 Da. For Stx2a B-subunit, the mass differences are: -111 Da, -91 Da, -72 Da, -59 Da, -44 Da, -29 Da, -15/-17 Da, +16 Da, +32 Da, +53/54 Da, +106 Da. When the stx2a gene knockout strain was cultured, it revealed the complete absence of the Stx2a B-subunit as well as its associated mass variants suggesting that the variants may be due to amino acid substitutions caused by translational errors.
Conclusions: Our results suggest that ciprofloxacin (a fluoroquinolone antibiotic) may cause translational errors in expression of Stx. Incorporation of mistranslated B-subunit sequences into the Stx AB5 holotoxin has the potential to subtly alter its quaternary structure and its binding affinity to surface receptors of eukaryotic cells.