Supplementary Figure S2 from RAB27B Drives a Cancer Stem Cell Phenotype in NSCLC Cells Through Enhanced Extracellular Vesicle Secretion

Supplementary Figure S2: RAB27B is required for the stem-like phenotype of NSCLC CSCs</p

Supplementary Figure S1 from RAB27B Drives a Cancer Stem Cell Phenotype in NSCLC Cells Through Enhanced Extracellular Vesicle Secretion

Supplementary Figure S1: RAB27B expression in CSC cultures</p

Supplementary Figure S6 from RAB27B Drives a Cancer Stem Cell Phenotype in NSCLC Cells Through Enhanced Extracellular Vesicle Secretion

Supplementary Figure S6: Effects of ShRAB27B CSC-derived EVs on the expression of stemness genes in BCCs</p

Supplementary Figure S3 from RAB27B Drives a Cancer Stem Cell Phenotype in NSCLC Cells Through Enhanced Extracellular Vesicle Secretion

Supplementary Figure S3: RAB27B is required for NSCLC tumorigenicity in vivo</p

Supplementary Table S1 from RAB27B Drives a Cancer Stem Cell Phenotype in NSCLC Cells Through Enhanced Extracellular Vesicle Secretion

Supplementary Table S1: Primers and shRNAs used in Experimental Procedures</p

Supplementary Figure S4 from RAB27B Drives a Cancer Stem Cell Phenotype in NSCLC Cells Through Enhanced Extracellular Vesicle Secretion

Supplementary Figure S4: Characterization of RAB27B knockdown NSCLC CSC derived EVs</p

Supplementary Figure S5 from RAB27B Drives a Cancer Stem Cell Phenotype in NSCLC Cells Through Enhanced Extracellular Vesicle Secretion

Supplementary Figure S5: Cellular uptake of DiI-labeled BCC and CSC EVs</p

EcoFABs: advancing microbiome science through standardized fabricated ecosystems.

Microbiomes play critical roles in ecosystems and human health, yet in most cases scientists lack standardized and reproducible model microbial communities. The development of fabricated microbial ecosystems, which we term EcoFABs, will provide such model systems for microbiome studies