Sekar, Karthik, Rusconi, Roberto, Sauls, John T., Fuhrer, Tobias, Noor, Elad, Nguyen, Jen, Fernandez, Vicente I., Buffing, Marieke F., Berney, Michael, Jun, Suckjoon, Stocker, Roman, and Sauer, Uwe. Synthesis and degradation of FtsZ quantitatively predict the first cell division in starved bacteria. Molecular Systems Biology 14.11 Web. doi:10.15252/msb.20188623.

Sekar, Karthik, Rusconi, Roberto, Sauls, John T., Fuhrer, Tobias, Noor, Elad, Nguyen, Jen, Fernandez, Vicente I., Buffing, Marieke F., Berney, Michael, Jun, Suckjoon, Stocker, Roman, & Sauer, Uwe. Synthesis and degradation of FtsZ quantitatively predict the first cell division in starved bacteria. Molecular Systems Biology, 14 (11). https://doi.org/10.15252/msb.20188623

Sekar, Karthik, Rusconi, Roberto, Sauls, John T., Fuhrer, Tobias, Noor, Elad, Nguyen, Jen, Fernandez, Vicente I., Buffing, Marieke F., Berney, Michael, Jun, Suckjoon, Stocker, Roman, and Sauer, Uwe. "Synthesis and degradation of FtsZ quantitatively predict the first cell division in starved bacteria". Molecular Systems Biology 14 (11). Country unknown/Code not available: DOI PREFIX: 10.15252. https://doi.org/10.15252/msb.20188623. https://par.nsf.gov/biblio/10118121.

@article{osti_10118121,
place = {Country unknown/Code not available}, title = {Synthesis and degradation of FtsZ quantitatively predict the first cell division in starved bacteria}, url = {https://par.nsf.gov/biblio/10118121}, DOI = {10.15252/msb.20188623}, abstractNote = {Not Available}, journal = {Molecular Systems Biology}, volume = {14}, number = {11}, publisher = {DOI PREFIX: 10.15252}, author = {Sekar, Karthik and Rusconi, Roberto and Sauls, John T. and Fuhrer, Tobias and Noor, Elad and Nguyen, Jen and Fernandez, Vicente I. and Buffing, Marieke F. and Berney, Michael and Jun, Suckjoon and Stocker, Roman and Sauer, Uwe}, }