Additional file 1: of Genome-wide transcriptome analysis and identification of benzothiadiazole-induced genes and pathways potentially associated with defense response in banana

Table S7. Gene-specific primers used for qRT-PCR. (XLSX 10 kb

Additional file 5: of Genome-wide transcriptome analysis and identification of benzothiadiazole-induced genes and pathways potentially associated with defense response in banana

Table S4. The significantly enriched pathways of DEGs in banana leaves and roots. (XLSX 11 kb

Additional file 3: of Genome-wide transcriptome analysis and identification of benzothiadiazole-induced genes and pathways potentially associated with defense response in banana

Table S2a. Expression information of DEGs in leaves at 1 day after BTH treatment. Table S2b. Expression information of DEGs in leaves at 3 day after BTH treatment. Table S2c. Expression information of DEGs in roots at 1 day after BTH treatment. Table S2d. Expression information of DEGs in roots at 3 day after BTH treatment. (XLSX 2340 kb

Additional file 6: of Genome-wide transcriptome analysis and identification of benzothiadiazole-induced genes and pathways potentially associated with defense response in banana

Table S5. Differentially expressed genes involved in protein kinases and transcription factors. (XLSX 225 kb

Additional file 7: of Genome-wide transcriptome analysis and identification of benzothiadiazole-induced genes and pathways potentially associated with defense response in banana

Table S6. Expression information of DEGs in Figs. 5 and 6. (XLSX 123 kb

Additional file 2: of Genome-wide transcriptome analysis and identification of benzothiadiazole-induced genes and pathways potentially associated with defense response in banana

Table S1. The information of 3996 identified banana novel protein-coding transcripts in the study. (XLSX 4797 kb

Additional file 4: of Genome-wide transcriptome analysis and identification of benzothiadiazole-induced genes and pathways potentially associated with defense response in banana

Table S3. GO terms of biological process enriched in banana leaves and roots. (XLSX 29 kb

Additional file 1 of Association of maternal BMI during early pregnancy with infant anemia: a large Chinese birth cohort

Additional file 1 Fig. S1. Summary of mediation analysis. The a and Sa respectively represent logistic regression coefficients and corresponding standard errors in relation of maternal BMI to maternal anemia, and the b and Sb respectively represent logistic regression coefficients and corresponding standard errors in relation of maternal anemia to infant anemia at 6 months

RAD51 localization in wild type and <i>rfc1-2.</i>

<p>(A–H) Localization of RAD51. (A and E) leptotene, (B and F) zygotene, (C, D and G) pachytene, (H) An enlarged image from (G), (D) the <i>rad51</i> mutant. The <i>rfc1-2</i> mutant showed RAD51 foci highly similar to the wild type ones before pachytene, but with persisted signals at pachytene (G). In each row of three panels, the left panel shows blue colored chromosomes strained with DAPI; the middle panel shows red colored signals for proteins as indicated above the panel; and the right panel shows the merged image of DAPI and protein signals. Bar, 10 µm.</p

Additional file 2 of Association of maternal BMI during early pregnancy with infant anemia: a large Chinese birth cohort

Additional file 2 Table S1. Adjusted ORs (95% CI) of infant anemia, stratified by maternal anemia during mid-pregnancy. Table S2. Crude and adjusted ORs (95% CI) of 6-month old infant anemia, using cutoffs for western population. Table S3. Crude and adjusted ORs (95% CI) of infant anemia for maternal BMI during early pregnancy categorized by deciles. Table S4. Adjusted ORs (95% CI) of 6-month old infant anemia, stratified by supplementation type