Table_3_Physiology of Highly Radioresistant Escherichia coli After Experimental Evolution for 100 Cycles of Selection.xlsx by Steven T. Bruckbauer (6256799)

“…Utilizing experimental evolution and continuing previous work, we have generated the most IR-resistant Escherichia coli populations developed to date. After 100 cycles of selection, the dose required to kill 99% the four replicate populations (IR9-100, IR10-100, IR11-100, and IR12-100) has increased from 750 Gy to approximately 3,000 Gy. …”

Image_3_Physiology of Highly Radioresistant Escherichia coli After Experimental Evolution for 100 Cycles of Selection.TIF by Steven T. Bruckbauer (6256799)

“…Utilizing experimental evolution and continuing previous work, we have generated the most IR-resistant Escherichia coli populations developed to date. After 100 cycles of selection, the dose required to kill 99% the four replicate populations (IR9-100, IR10-100, IR11-100, and IR12-100) has increased from 750 Gy to approximately 3,000 Gy. …”

Image_4_Physiology of Highly Radioresistant Escherichia coli After Experimental Evolution for 100 Cycles of Selection.TIF by Steven T. Bruckbauer (6256799)

“…Utilizing experimental evolution and continuing previous work, we have generated the most IR-resistant Escherichia coli populations developed to date. After 100 cycles of selection, the dose required to kill 99% the four replicate populations (IR9-100, IR10-100, IR11-100, and IR12-100) has increased from 750 Gy to approximately 3,000 Gy. …”

Image_3_Physiology of Highly Radioresistant Escherichia coli After Experimental Evolution for 100 Cycles of Selection.TIF by Steven T. Bruckbauer (6256799)

“…Utilizing experimental evolution and continuing previous work, we have generated the most IR-resistant Escherichia coli populations developed to date. After 100 cycles of selection, the dose required to kill 99% the four replicate populations (IR9-100, IR10-100, IR11-100, and IR12-100) has increased from 750 Gy to approximately 3,000 Gy. …”

Image_2_Physiology of Highly Radioresistant Escherichia coli After Experimental Evolution for 100 Cycles of Selection.TIF by Steven T. Bruckbauer (6256799)

“…Utilizing experimental evolution and continuing previous work, we have generated the most IR-resistant Escherichia coli populations developed to date. After 100 cycles of selection, the dose required to kill 99% the four replicate populations (IR9-100, IR10-100, IR11-100, and IR12-100) has increased from 750 Gy to approximately 3,000 Gy. …”

Image_1_Physiology of Highly Radioresistant Escherichia coli After Experimental Evolution for 100 Cycles of Selection.TIF by Steven T. Bruckbauer (6256799)

“…Utilizing experimental evolution and continuing previous work, we have generated the most IR-resistant Escherichia coli populations developed to date. After 100 cycles of selection, the dose required to kill 99% the four replicate populations (IR9-100, IR10-100, IR11-100, and IR12-100) has increased from 750 Gy to approximately 3,000 Gy. …”

Image_2_Physiology of Highly Radioresistant Escherichia coli After Experimental Evolution for 100 Cycles of Selection.TIF by Steven T. Bruckbauer (6256799)

“…Utilizing experimental evolution and continuing previous work, we have generated the most IR-resistant Escherichia coli populations developed to date. After 100 cycles of selection, the dose required to kill 99% the four replicate populations (IR9-100, IR10-100, IR11-100, and IR12-100) has increased from 750 Gy to approximately 3,000 Gy. …”

Table_2_Physiology of Highly Radioresistant Escherichia coli After Experimental Evolution for 100 Cycles of Selection.xlsx by Steven T. Bruckbauer (6256799)

“…Utilizing experimental evolution and continuing previous work, we have generated the most IR-resistant Escherichia coli populations developed to date. After 100 cycles of selection, the dose required to kill 99% the four replicate populations (IR9-100, IR10-100, IR11-100, and IR12-100) has increased from 750 Gy to approximately 3,000 Gy. …”

Image_5_Physiology of Highly Radioresistant Escherichia coli After Experimental Evolution for 100 Cycles of Selection.TIF by Steven T. Bruckbauer (6256799)

“…Utilizing experimental evolution and continuing previous work, we have generated the most IR-resistant Escherichia coli populations developed to date. After 100 cycles of selection, the dose required to kill 99% the four replicate populations (IR9-100, IR10-100, IR11-100, and IR12-100) has increased from 750 Gy to approximately 3,000 Gy. …”

Image_1_Physiology of Highly Radioresistant Escherichia coli After Experimental Evolution for 100 Cycles of Selection.TIF by Steven T. Bruckbauer (6256799)

“…Utilizing experimental evolution and continuing previous work, we have generated the most IR-resistant Escherichia coli populations developed to date. After 100 cycles of selection, the dose required to kill 99% the four replicate populations (IR9-100, IR10-100, IR11-100, and IR12-100) has increased from 750 Gy to approximately 3,000 Gy. …”

Graphs showing periods of electrical activity of muscles at each grade across a normalized stride cycle (0%–100% hoof strike to subsequent hoof strike). by Yuji Takahashi (263525)

Ribosomal subunit pathways are decreased in <i>Resf1</i> knockdown cells. by Megan R. Majocha (18529925)

“…<p>(A) GO Pathway analysis snapshots of various ribosomal subunit pathways that are decreased in 6DT1 <i>Resf1</i> KD cells. (B) The GO Cytosolic Ribosome pathway had many (C) small and large ribosomal proteins decreased in <i>Resf1</i> KD cells. …”

Cell cycle analysis of A2780 cells following AGPAT3 overexpression. by Hadi Alizadeh (20854757)

Subjects:

Data_Sheet_1_Physiology of Highly Radioresistant Escherichia coli After Experimental Evolution for 100 Cycles of Selection.xlsx by Steven T. Bruckbauer (6256799)

“…Utilizing experimental evolution and continuing previous work, we have generated the most IR-resistant Escherichia coli populations developed to date. After 100 cycles of selection, the dose required to kill 99% the four replicate populations (IR9-100, IR10-100, IR11-100, and IR12-100) has increased from 750 Gy to approximately 3,000 Gy. …”

Data_Sheet_4_Physiology of Highly Radioresistant Escherichia coli After Experimental Evolution for 100 Cycles of Selection.xlsx by Steven T. Bruckbauer (6256799)

“…Utilizing experimental evolution and continuing previous work, we have generated the most IR-resistant Escherichia coli populations developed to date. After 100 cycles of selection, the dose required to kill 99% the four replicate populations (IR9-100, IR10-100, IR11-100, and IR12-100) has increased from 750 Gy to approximately 3,000 Gy. …”

Data_Sheet_2_Physiology of Highly Radioresistant Escherichia coli After Experimental Evolution for 100 Cycles of Selection.xlsx by Steven T. Bruckbauer (6256799)

“…Utilizing experimental evolution and continuing previous work, we have generated the most IR-resistant Escherichia coli populations developed to date. After 100 cycles of selection, the dose required to kill 99% the four replicate populations (IR9-100, IR10-100, IR11-100, and IR12-100) has increased from 750 Gy to approximately 3,000 Gy. …”

Data_Sheet_3_Physiology of Highly Radioresistant Escherichia coli After Experimental Evolution for 100 Cycles of Selection.xlsx by Steven T. Bruckbauer (6256799)

“…Utilizing experimental evolution and continuing previous work, we have generated the most IR-resistant Escherichia coli populations developed to date. After 100 cycles of selection, the dose required to kill 99% the four replicate populations (IR9-100, IR10-100, IR11-100, and IR12-100) has increased from 750 Gy to approximately 3,000 Gy. …”

Cytochrome c movement in <i>C</i>. <i>auris</i>. by Hammad Alam (530008)

Subjects:

The nsP4-Q192L and C483Y mutations decrease the 4′-FlU sensitivity of both replication and transcription. by Peiqi Yin (6533747)

Effects of nano-curcumin on cell cycle and apoptosis in breast cancer cells. by Taraneh Givi (22793530)