https://doi.org/10.5061/dryad.7d7wm3845

Description of the data and file structure

Data on Escherichia coli elongation rates, doubling times, and survival over time were obtained by culturing populations in microfluidic devices. All populations were grown in LB media at 37°C. Cell segmentation and tracking was performed on ImageJ.

Files and variables

File: Data_for_Fig_2A.csv

Description: Growth over time for bacteria growing in continuous exponential phase in mother machine microfluidic devices.

Variables

• Time (hours): time of birth, recorded immediately after cell division.
• Elongation.rate (min-1): rate of length elongation for a given cell, measured between birth and division. Data is normalized by population means.
• Age (categorical): 0 = old daughter, 1 = new daughter

File: Data_for_Fig_2B.csv

Description: Doubling times of mother and daughter cells in consecutive generations, for bacteria growing in continuous exponential phase in mother machine microfluidic devices.

Variables

• mother (min): normalized maternal doubling times.
• daughter (min): normalized daughter doubling times.
• daughter.age (categorical): Age of the daughter cell. 0 = old daughter, 1 = new daughter

File: Data_for_Fig_2D.csv

Description: Growth over time for bacteria growing in continuous exponential phase in dial-a-wave devices, in unstressed conditions for 9 h, followed by exposure to 100 µg/ml Ampicilin.

Variables

• time.of.birth (hours): time at which a given generation starts, right after cell division.
• time.of.division (hours): time at which a given generation end, right before cell division.
• r (min-1): elongation rates
• age (categorical): 0 = old daughter, 1 = new daughter

File: Data_for_Fig_3A.csv

Description: Growth over time for bacteria growing in continuous exponential phase in mother machine microfluidic devices. Cells were grown under photo-oxidative treatment, followed by Streptomycin exposure.

Variables

• time.of.birth (hours): time at which a given generation starts, right after cell division.
• time.of.division (hours): time at which a given generation end, right before cell division.
• r (min-1): elongation rates
• age (categorical): 0 = old daughter, 1 = new daughter

File: Data_for_Fig_3B.csv

Description: Growth over time for bacteria growing in continuous exponential phase in mother machine microfluidic devices. Cells were grown under sub-inhibitory Streptomycin treatment, followed by Nalidixic Acid exposure.

Variables

• time.of.birth (hours): time at which a given generation starts, right after cell division.
• time.of.division (hours): time at which a given generation end, right before cell division.
• r (min-1): elongation rates
• age (categorical): 0 = old daughter, 1 = new daughter

File: Data_for_Fig_3C.csv

Description: Growth over time for bacteria growing in continuous exponential phase in mother machine microfluidic devices. Cells were exposed to a bacteriostatic Tetracycline treatment for 30 min, followed by Ampicillin exposure and subsequent recovery.

Variables

• time.of.birth (hours): time at which a given generation starts, right after cell division.
• time.of.division (hours): time at which a given generation end, right before cell division.
• r (min-1): elongation rates
• age (categorical): 0 = old daughter, 1 = new daughter

File: Data_for_Fig_4A.xlsx

Description: Bacteria grown in microfluidic devices. Populations were initially maintained in exponential phase, then transitioned to stationary phase through a gradual dilution of the culture media with spent medium. After 24h, cells were treated with Ampicillin. Persister cells were observed upon recovery.

Variables

• Time.of.birth (hours): time at which a given generation starts, right after cell division.
• Time.of.division (hours): time at which a given generation end, right before cell division.
• Elongation rates (min-1): elongation rates
• Age (categorical): 0 = old daughter, 1 = new daughter

File: Data_for_Fig_4C.xlsx

Description: Doubling times of mother and daughter cells in consecutive generations, for bacteria transitioning between exponential and stationary phase within mother machine microfluidic devices.

Variables

• Maternal doubling time (min): doubling time of the mother cell
• New daughter (min): doubling time of the daughter cell inheriting a maternal new pole
• Old daughter (min): doubling time of the daughter cell inheriting a maternal old pole
• Phase (categorical): Exponential or Stationary

File: Data_for_Fig_5AB.csv

Description: Size of bacteria protein aggregates, measured on strains expressing IbpA-YFP in agarose pads with or without Streptomycin.

Variables

• strep: 0µg/ml or 1µg/ml Streptomycin
• aggregate.area (px): area of the IbpA-YFP fluorescent foci
• relative.aggregate.area: ratio between the area of the IbpA-YFP fluorescent foci and the cell area

File: Data_for_Fig_S3B.xlsx

Description: Bacterial growth over time in dial-a-wave microfluidic devices.

Variables

• Time.of.birth (hours): time at which a given generation starts, right after cell division.
• Time.of.division (hours): time at which a given generation end, right before cell division.
• Elongation.rates (min-1): elongation rates
• Age (categorical): 0 = old daughter, 1 = new daughter
• Strain (categorical): E. coli MG1655 WT (wildtype) or hipA7

File: Data_for_Fig_S3A.xlsx

Description: Bacterial doubling times in dial-a-wave microfluidic devices.

Variables

• Maternal doubling time (min): doubling time of the mother cell 
• New daughter (min): doubling time of the daughter cell inheriting a maternal new pole
• Old daughter (min): doubling time of the daughter cell inheriting a maternal old pole
• Strain (categorical): E. coli MG1655 WT (wildtype) or hipA7

Note on NA variables

For all files listed above, measurements of elongation rates and/or doubling times were only recorded when a given cell could be followed from birth to division (a complete generation). For example, if a cell did not divide until the end of the imaging period, its doubling time is unkown (=NA). If a cell entered or exited the imaging field at an unkown timepoint of its cell cycle, its doubling time is NA. Similarly, the age of a cell can only be known after we have followed the lineage for at least two consecutive divisions, and therefore the age of the first cell in the lineage is unknown (=NA).