2020
Zero-Valent Iron Sand Filtration Can Reduce Human and Plant Pathogenic Bacteria While Increasing Plant Growth Promoting Bacteria in Reclaimed Water
Kulkarni P, Olson N, Bui A, Bradshaw R, Del Collo L, Hittle L, Handy E, Paulson J, Ghurye J, Nasko D, East C, Van Kessel J, Kniel K, Chiu P, Mongodin E, Pop M, Sharma M, Sapkota A. Zero-Valent Iron Sand Filtration Can Reduce Human and Plant Pathogenic Bacteria While Increasing Plant Growth Promoting Bacteria in Reclaimed Water. Frontiers In Environmental Science 2020, 8: 541921. DOI: 10.3389/fenvs.2020.541921.Peer-Reviewed Original ResearchProportion of open reading framesNitrogen-fixing bacterial generaZVI-sand filtrationPlant pathogenic genusPlant growth-promoting bacteriaPlant pathogenic bacteriaRRNA gene sequencesOpen reading frameMetagenomic shotgun sequencingExploratory functional analysisAntimicrobial susceptibility testingGrowth-promoting bacteriaBacterial community structureTetracycline-resistant E. coliReclaimed waterOxidative stress responseShotgun sequencingReading frameZVI-sandGene sequencesBacterial generaPathogenic generaBacterial communitiesIron-rich environmentsPromoting bacteria
2016
Dynamic metabolic exchange governs a marine algal-bacterial interaction
Segev E, Wyche T, Kim K, Petersen J, Ellebrandt C, Vlamakis H, Barteneva N, Paulson J, Chai L, Clardy J, Kolter R. Dynamic metabolic exchange governs a marine algal-bacterial interaction. ELife 2016, 5: e17473. PMID: 27855786, PMCID: PMC5148602, DOI: 10.7554/elife.17473.Peer-Reviewed Original ResearchConceptsIndole-3-acetic acidAlgal cellsBacterial production of indole-3-acetic acidProduction of indole-3-acetic acidPhytohormone indole-3-acetic acidProgrammed cell deathPromote algal growthRoseobacter groupAlgal hostOxidative stress responseCoccolithophore physiologyMicro-algaeBacterial productionAlgal deathLaboratory model systemsCell deathAlgalAlgal growthMetabolic exchangeStress responsePopulation dynamicsBacteriaGrowth enhancementModel systemRoseobacter