【 摘 要 】

BackgroundGene expression within cells is known to fluctuate stochastically in time. However, the origins of gene expression noise remain incompletely understood. The bacterial cell cycle has been suggested as one source, involving chromosome replication, exponential volume growth, and various other changes in cellular composition. Elucidating how these factors give rise to expression variations is important to models of cellular homeostasis, fidelity of signal transmission, and cell-fate decisions.ResultsUsing single-cell time-lapse microscopy, we measured cellular growth as well as fluctuations in the expression rate of a fluorescent protein and its concentration. We found that, within the population, the mean expression rate doubles throughout the cell cycle with a characteristic cell cycle phase dependent shape which is different for slow and fast growth rates. At low growth rate, we find the mean expression rate was initially flat, and then rose approximately linearly by a factor two until the end of the cell cycle. The mean concentration fluctuated at low amplitude with sinusoidal-like dependence on cell cycle phase. Traces of individual cells were consistent with a sudden two-fold increase in expression rate, together with other non-cell cycle noise. A model was used to relate the findings and to explain the cell cycle-induced variations for different chromosomal positions.ConclusionsWe found that the bacterial cell cycle contribution to expression noise consists of two parts: a deterministic oscillation in synchrony with the cell cycle and a stochastic component caused by variable timing of gene replication. Together, they cause half of the expression rate noise. Concentration fluctuations are partially suppressed by a noise cancelling mechanism that involves the exponential growth of cellular volume. A model explains how the functional form of the concentration oscillations depends on chromosome position.

【 授权许可】

CC BY   
© Walker et al. 2016

【 预 览 】

附件列表

Files	Size	Format	View
RO202311109607347ZK.pdf	1222KB	PDF	download
Fig. 1	104KB	Image	download
Fig. 1	3761KB	Image	download
12944_2023_1927_Article_IEq24.gif	1KB	Image	download
MediaObjects/42004_2023_1019_MOESM1_ESM.pdf	3492KB	PDF	download
Fig. 1	156KB	Image	download
Fig. 4	885KB	Image	download
Fig. 1	103KB	Image	download
Fig. 3	2073KB	Image	download
MediaObjects/12974_2023_2924_MOESM3_ESM.tiff	13318KB	Other	download
Fig. 2	467KB	Image	download
12951_2017_297_Article_IEq1.gif	1KB	Image	download
MediaObjects/40560_2023_693_MOESM4_ESM.docx	59KB	Other	download
MediaObjects/13690_2023_1197_MOESM1_ESM.docx	16KB	Other	download
Fig. 2	177KB	Image	download
MediaObjects/40249_2023_1146_MOESM8_ESM.png	1162KB	Other	download
	465KB	Image	download
MediaObjects/13041_2023_1060_MOESM1_ESM.pdf	438KB	PDF	download

【 图 表 】

Fig. 2

12951_2017_297_Article_IEq1.gif

Fig. 2

Fig. 3

Fig. 1

Fig. 4

Fig. 1

12944_2023_1927_Article_IEq24.gif

Fig. 1

Fig. 1

【 参考文献 】

• [1]
• [2]
• [3]
• [4]
• [5]
• [6]
• [7]
• [8]
• [9]
• [10]
• [11]
• [12]
• [13]
• [14]
• [15]
• [16]
• [17]
• [18]
• [19]
• [20]
• [21]
• [22]
• [23]
• [24]
• [25]
• [26]
• [27]
• [28]
• [29]
• [30]
• [31]
• [32]
• [33]
• [34]
• [35]
• [36]
• [37]
• [38]
• [39]
• [40]
• [41]
• [42]
• [43]
• [44]
• [45]
• [46]
• [47]
• [48]
• [49]