Additional file 1 of OsFTL4, an FT-like Gene, Regulates Flowering Time and Drought Tolerance in Rice (Oryza sativa L.)

Additional file 1. Fig. S1: Diurnal expression of Ehd1, OsphyB, and OsGI in GLA 4 and the osftl4 mutants under CLD and CSD conditions. Fig. S2 Protein sequence alignment of 14-3-3 proteins. Fig. S3 Analysis of OsFTL4 expression in ABA-treated rice seedlings. Fig. S4 Day length in Yangzhou and Lingshui during the period from sowing to flowering

Additional file 4 of OsFTL4, an FT-like Gene, Regulates Flowering Time and Drought Tolerance in Rice (Oryza sativa L.)

Additional file 4. Table S3: Primers used in this study

Additional file 2 of OsFTL4, an FT-like Gene, Regulates Flowering Time and Drought Tolerance in Rice (Oryza sativa L.)

Additional file 2. Table S1: Comparison of the major agronomic traits of GLA 4 and the osftl4 mutants

Additional file 3 of OsFTL4, an FT-like Gene, Regulates Flowering Time and Drought Tolerance in Rice (Oryza sativa L.)

Additional file 3. Table S2: Predicted hormone-responsive elements in the OsFTL4 promoter

Additional file 1: of Total coliforms as an indicator of human enterovirus presence in surface water across Tianjin city, China

Figure S1. contains the map of the water sampling site. Figures S2-S7. contain the standard curves for the quantification of HRVs, HuNoVs GII, AstVs, EnVs, HAdVs and HCVs. Figures S8-S9. contain the comparison of physicochemical and bacterial indices in water samples. Figure S10. contains the virus concentrations in water samples compared with season, temperature and bacterial indexes. Table S1. contains the primers and probes used in this study. (DOCX 1736 kb

Additional file 1 of Antibiotic resistance genes in gut of breast-fed neonates born by caesarean section originate from breast milk and hospital ward air

Additional file 1: Table S1. Primers of ARGs for conventional PCR. Table S2. Primers of ARGs and 16S rRNA for quantitative PCR. Table S3. Standard curves of ARGs and 16S rRNA for quantitative PCR. Table S4. Concentration and purity of standard plasmid of ARGs. Table S5. Primers of housekeeping genes of s. epidermidis [13]. Table S6. Effect of gender on thefrequencies of fecal resistance genes in newborns. Table S7. Difference and association of the frequencies of blaTEM in colostrums and the feces on the third day of newborns. Table S8. Difference and association of the frequencies of ampC in colostrums and the feces on the third day of newborns. Table S9. Difference and association of the frequencies of tetM in colostrums and the feces on the third day of newborns. Table S10. Difference and association of the frequencies of aac(6′)-Ib in colostrums and the feces on the third day of newborns. Table S11. Difference and association of the frequencies of ermB in colostrums and the feces on the third day of newborns. Table S12. Difference and association of the frequencies of sul2 in colostrums and the feces on the third day of newborns. Table S13. Difference and association of the frequencies of mecA in colostrums and the feces on the third day of newborns. Figure S1. The median of ARGs amount in the feces of six newborns on 3th day, 7th day and 30th day, respectively. Table S14. ST number of Staphylococcus epidermidis isolated from colostrum. Table S15. ST number of Staphylococcus epidermidis isolated from faeces on the third day. Table S16. ST number of Staphylococcus epidermidis isolated from ward air. Table S17. Resistance phenotypes and ARGs of Staphylococcus epidermidis isolated from colostrum. Table S18. Resistance phenotypes and ARGs of Staphylococcus epidermidis isolated from faeces on third day. Table S19. Resistance phenotypes and ARGs of Staphylococcus epidermidis isolated from ward air