Danni Shi
YOU?
Author Swipe
View article: 3’ to 5’ Translation of Circular RNAs?
3’ to 5’ Translation of Circular RNAs? Open
For decades, the 5’→3’ direction of translation has been a central dogma of molecular biology( 1 ). Here we present evidence that eukaryotic circular RNAs (circRNAs) can serve as templates for 3’→5’ backward translation (BT), yielding poly…
View article: Backward translation of circular RNAs
Backward translation of circular RNAs Open
Despite advancements in understanding protein synthesis, numerous eukaryotic proteins might have been overlooked and remain elusive. RNA translation, proceeding in the 5’ end-to-3’ end direction exclusively, has been recognized as the norm…
View article: Atmosphere-directed reconstruction of Cu-based metal–organic frameworks toward efficient CO<sub>2</sub> electroreduction
Atmosphere-directed reconstruction of Cu-based metal–organic frameworks toward efficient CO<sub>2</sub> electroreduction Open
Compared to the metallic Cu sites formed under a CO 2 flow, the reconstruction of HKUST-1 under an Ar flow generates Cu-*OH species, ultimately creating a Cu/Cu 2 O interface that enhances C 2 H 4 generation.
View article: Heterogeneous endocrine cell composition defines human islet functional phenotypes
Heterogeneous endocrine cell composition defines human islet functional phenotypes Open
SUMMARY Phenotyping and genotyping initiatives within the Integrated Islet Distribution Program (IIDP), the largest source of human islets for research in the U.S., provide standardized assessment of islet preparations distributed to resea…
View article: Association between hemoglobin A1c and abdominal aortic calcification: results from the National Health and Nutrition Examination Survey 2013–2014
Association between hemoglobin A1c and abdominal aortic calcification: results from the National Health and Nutrition Examination Survey 2013–2014 Open
View article: Restructuring multi-phase interfaces from Cu-based metal–organic frameworks for selective electroreduction of CO <sub>2</sub> to C <sub>2</sub> H <sub>4</sub>
Restructuring multi-phase interfaces from Cu-based metal–organic frameworks for selective electroreduction of CO <sub>2</sub> to C <sub>2</sub> H <sub>4</sub> Open
Directional in situ reconfiguration of Ag incorporating HKUST-1 frameworks was introduced to restructure multi-phase Ag/Cu/Cu 2 O electrocatalysts for the selective electro-reduction of CO 2 to C 2 H 4 .
View article: Supplementary Table 2 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence
Supplementary Table 2 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence Open
PDF file, 22K, Stratified analysis of the association between miR-146a rs2910164 and risk of bladder cancer.
View article: Supplementary Figure 4 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence
Supplementary Figure 4 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence Open
PDF file, 92K, MiR-146a rs2910164 allele and its association with cancer risk in the meta-analysis.
View article: Supplementary Figure 1 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence
Supplementary Figure 1 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence Open
PDF file, 73K, Stratification analyses of associations between miR-146a rs2910164 and bladder cancer risk.
View article: Supplementary Figure 2 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence
Supplementary Figure 2 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence Open
PDF, 18K, Quantitative real-time PCR was used to measure the levels of mature miR-146a expression in transected T24 and EJ cells.
View article: Supplementary Table 1 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence
Supplementary Table 1 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence Open
PDF file, 21K, Key information on the 14 selected miRNA polymorphisms.
View article: Supplementary Table 6 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence
Supplementary Table 6 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence Open
PDF file, 21K, Primers and probes for genotype screening by TaqMan allelic discrimination.
View article: Supplementary Table 7 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence
Supplementary Table 7 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence Open
PDF file, 355K, Primary information in miRNA SNPs.
View article: Supplementary Table 5 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence
Supplementary Table 5 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence Open
PDF file, 25K, The position of rs2910164 in the miRNA-146a.
View article: Supplementary Table 6 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence
Supplementary Table 6 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence Open
PDF file, 21K, Primers and probes for genotype screening by TaqMan allelic discrimination.
View article: Supplementary Table 4 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence
Supplementary Table 4 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence Open
PDF file, 21K, Clinical characteristics of 64 bladder cancer tissue samples.
View article: Supplementary Table 3 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence
Supplementary Table 3 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence Open
PDF file, 22K, Analysis of miR-146a rs2910164 polymorphism association with non-muscle invasive bladder cancer patients' recurrence, stratified by selected variables.
View article: Supplementary Figure 3 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence
Supplementary Figure 3 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence Open
PDF file, 17K, Association between miR-146a rs2910164 and expression of mature miR-146a.
View article: Supplementary Table 3 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence
Supplementary Table 3 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence Open
PDF file, 22K, Analysis of miR-146a rs2910164 polymorphism association with non-muscle invasive bladder cancer patients' recurrence, stratified by selected variables.
View article: Supplementary Table 4 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence
Supplementary Table 4 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence Open
PDF file, 21K, Clinical characteristics of 64 bladder cancer tissue samples.
View article: Supplementary Figure 2 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence
Supplementary Figure 2 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence Open
PDF, 18K, Quantitative real-time PCR was used to measure the levels of mature miR-146a expression in transected T24 and EJ cells.
View article: Supplementary Table 5 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence
Supplementary Table 5 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence Open
PDF file, 25K, The position of rs2910164 in the miRNA-146a.
View article: Supplementary Figure Legend from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence
Supplementary Figure Legend from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence Open
PDF file, 27K.
View article: Supplementary Figure Legend from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence
Supplementary Figure Legend from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence Open
PDF file, 27K.
View article: Supplementary Figure 5 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence
Supplementary Figure 5 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence Open
PDF file, 44K, The position of rs2910164 in the miRNA-146a. Sequences for mature miRNA are shown in red, and the position of the SNP in the miRNA is underlined.
View article: Data from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence
Data from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence Open
miRNAs play important roles in numerous cellular processes, including development, proliferation, apoptosis, and carcinogenesis. Because altered expression and function of miRNAs has been observed in bladder cancer, we investigated whether…
View article: Supplementary Table 1 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence
Supplementary Table 1 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence Open
PDF file, 21K, Key information on the 14 selected miRNA polymorphisms.
View article: Data from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence
Data from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence Open
miRNAs play important roles in numerous cellular processes, including development, proliferation, apoptosis, and carcinogenesis. Because altered expression and function of miRNAs has been observed in bladder cancer, we investigated whether…
View article: Supplementary Figure 5 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence
Supplementary Figure 5 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence Open
PDF file, 44K, The position of rs2910164 in the miRNA-146a. Sequences for mature miRNA are shown in red, and the position of the SNP in the miRNA is underlined.
View article: Supplementary Figure 1 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence
Supplementary Figure 1 from Genetic Variants in miRNAs Predict Bladder Cancer Risk and Recurrence Open
PDF file, 73K, Stratification analyses of associations between miR-146a rs2910164 and bladder cancer risk.