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Stochastic Gene Expression in a Single Cell

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Science  16 Aug 2002:
Vol. 297, Issue 5584, pp. 1183-1186
DOI: 10.1126/science.1070919

Abstract

Clonal populations of cells exhibit substantial phenotypic variation. Such heterogeneity can be essential for many biological processes and is conjectured to arise from stochasticity, or noise, in gene expression. We constructed strains of Escherichia coli that enable detection of noise and discrimination between the two mechanisms by which it is generated. Both stochasticity inherent in the biochemical process of gene expression (intrinsic noise) and fluctuations in other cellular components (extrinsic noise) contribute substantially to overall variation. Transcription rate, regulatory dynamics, and genetic factors control the amplitude of noise. These results establish a quantitative foundation for modeling noise in genetic networks and reveal how low intracellular copy numbers of molecules can fundamentally limit the precision of gene regulation.

Living cells possess very low copy numbers of many components, including DNA and important regulatory molecules (1). Thus, stochastic effects in gene expression may account for the large amounts of cell-cell variation observed in isogenic populations (2, 3). Such effects can play crucial roles in biological processes, such as development, by establishing initial asymmetries that, amplified by feedback mechanisms, determine cell fates (4). However, experimental evidence for stochasticity in gene expression has been circumstantial (5,6). For any particular gene, it remains unknown whether cell-cell variation in the abundance of its product is set by noise in expression of the gene itself or by fluctuations in the amounts of other cellular components. The difficulty of experimentally distinguishing between these two possibilities has thus far precluded detection of intrinsic noise in living cells. The magnitude of the noise intrinsic to gene expression, and its relative importance compared with other sources of cell-cell variability, are fundamental characteristics of the cell that require measurement.

In general, the amount of protein produced by a particular gene varies from cell to cell. The noise (defined as the standard deviation divided by the mean) in this distribution is labeled ηtot and can be divided into two components. Because expression of each gene is controlled by the concentrations, states, and locations of molecules such as regulatory proteins and polymerases, fluctuations in the amount or activity of these molecules cause corresponding fluctuations in the output of the gene. Therefore, they represent sources of extrinsic noise (denoted ηext) that are global to a single cell but vary from one cell to another. On the other hand, consider a population of cells identical not just genetically but also in the concentrations and states of their cellular components. Even in such a (hypothetical) population, the rate of expression of a particular gene would still vary from cell to cell because of the random microscopic events that govern which reactions occur and in what order. This inherent stochasticity, or intrinsic noise, denoted ηint, is that remaining part of the total noise arising from the discrete nature of the biochemical process of gene expression. No matter how accurately the levels of regulatory proteins are controlled, intrinsic noise fundamentally limits the precision of gene regulation.

Operationally, intrinsic noise for a given gene may be defined as the extent to which the activities of two identical copies of that gene, in the same intracellular environment, fail to correlate (Fig. 1, A and B). Therefore, we built strains of Escherichia coli, incorporating the distinguishable cyan (cfp) and yellow (yfp) alleles of green fluorescent protein in the chromosome. In each strain, the two reporter genes were controlled by identical promoters. To avoid systematic differences in copy number, we integrated the genes at loci equidistant from, and on opposite sides of, the origin of replication (fig. S1). The two fluorescent proteins exhibited statistically equivalent intensity distributions and thus displayed the necessary independence and equivalence to detect noise (7).

Figure 1

Intrinsic and extrinsic noise can be measured and distinguished with two genes (cfp, shown in green; yfp, shown in red) controlled by identical regulatory sequences. Cells with the same amount of each protein appear yellow, whereas cells expressing more of one fluorescent protein than the other appear red or green. (A) In the absence of intrinsic noise, the two fluorescent proteins fluctuate in a correlated fashion over time in a single cell (left). Thus, in a population, each cell will have the same amount of both proteins, although that amount will differ from cell to cell because of extrinsic noise (right). (B) Expression of the two genes may become uncorrelated in individual cells because of intrinsic noise (left), giving rise to a population in which some cells express more of one fluorescent protein than the other.

For measurement, cells were grown in LB medium and photographed through cfp and yfp fluorescence filter sets and in phase contrast (Fig. 2) (7). A computerized image analysis system identified cells and quantified their mean fluorescent intensities. Both intrinsic and extrinsic noise could be determined from plots of CFP versus YFP fluorescence intensity in individual cells (Fig. 3A) (7). The value of ηint indicates the mean relative difference in fluorescence intensity of the two reporter proteins in the same cell; for instance, if ηint = 0.25, then the two colors typically differ by about 25%. Because ηint and ηext make orthogonal contributions to the total noise, ηtot, the three noise values satisfy the relation ηint 2 + ηext 2 = ηtot 2 (7, 8). Measurements of these variables for various strains and conditions are presented in Table 1.

Figure 2

Noise in E. coli. CFP and YFP fluorescence images were combined in the green and red channels, respectively. (A) In strain RP22, with promoters repressed by the wild-type lacI gene, red and green indicate significant amounts of intrinsic noise. (B) RP22 grown in the presence of lac inducer, 2 mM IPTG. Both fluorescent proteins are expressed at higher levels and the cells exhibit less noise. (C) As in (B), except the recA gene has been deleted, increasing intrinsic noise. (D) Another wild-type strain, MG22, shows noise characteristics similar to those of RP22. (E) Expression levels and noise in unrepressedlacI strain M22 are similar to those inlacI + strains induced with IPTG (B). (F) M22 cells regulated by the Repressilator (16), an oscillatory network that amplifies intrinsic noise.

Figure 3

Quantification of noise. (A) Plot of fluorescence in two strains: one quiet (M22) and one noisy (D22). Each point represents the mean fluorescence intensities from one cell. Spread of points perpendicular to the diagonal line on which CFP and YFP intensities are equal corresponds to intrinsic noise, whereas spread parallel to this line is increased by extrinsic noise. (B) Noise versus rate of transcription in strain M22 (recA +, lacI ), with LacI supplied by plasmid pREP4 (7). Fluorescence levels (x axis) are population means. The rightmost point represents the strain without pREP4 and therefore is fully induced; its value, set to 1.0, was used to normalize all fluorescence intensities. IPTG (0 to 2 mM) was added to cultures and ηtot, ηint, and ηext were measured. Error bars are 95% confidence intervals. Dashed line fits ηint 2 ≈ (c 1/m) +c 2, where m = fluorescence intensity (x axis),c 1 = 7 × 10−4, andc 2 = 3 × 10−3. (C) Noise versus induction level inrecA lacI strain D22, containing plasmid pREP4. All notations are as in (B). In the fit,c 1 = 5 × 10−4 andc 2 = 1 × 10−2.

Table 1

Measurements of noise in selected strains.

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To determine the importance of noise in vivo, we began with the least noisy gene expression conditions obtainable without feedback: strong constitutive promoters driving the expression of stable proteins. Specifically, we constructed strains incorporating artificial lac-repressible promoters (9) inlac strain backgrounds, in which the lac repressor gene, lacI, is deleted. We obtained low noise levels (ηint ≈ 0.05) and low cell-cell variation overall (ηtot ≈ 0.08) in these strains (Fig. 2E). We obtained similar results in another strain incorporating two copies of the somewhat stronger promoter λPR (Table 1). These results indicate (i) that constitutive gene expression can be remarkably uniform under some conditions, and (ii) that this low noise state does not strictly depend on a particular promoter sequence.

Few natural E. coli genes are transcribed as strongly as these phage-derived promoters (10). To see how much noise there is at lower rates of transcription, we moved the reporters into several wild-type (lacI +) E. colistrains, where they produced only 3 to 6% as much protein. Under these conditions, both intrinsic and extrinsic noise increased by a factor of ∼5 (Fig. 2, A and D, and Table 1). The effect was reversible: Addition of saturating amounts of isopropyl β-d-thiogalactopyranoside (IPTG), which binds and inactivates the lac repressor, restored noise (both ηint and ηext) and amounts of fluorescent protein expression to their approximate values inlac strains (Fig. 2B). Thus, the noise increase found in wild-type strains can be attributed directly to the activity of LacI and the corresponding reduction of transcription rate. LacI affects extrinsic noise as well, increasing it by a factor of ∼5, to ∼0.3. This change indicates the presence of cell-cell variation in LacI expression (8, 11).

Models of stochastic gene expression predict that intrinsic noise should increase as the amount of transcript decreases (8,12). To more effectively repress the reporter genes, we introduced a plasmid constitutively expressing the lac repressor (7) into strains otherwise deleted forlacI. We added different amounts of IPTG to growing cultures (Fig. 3, B and C). Intrinsic noise was much larger in the presence of the LacI plasmid because of reduced transcription rate, but it fell substantially as IPTG was added. ηint is expected to decrease as ηint 2 ≈ (c 1/m) +c 2, where m is the fluorescence intensity of the cell (assumed to be proportional to the average number of transcripts), and c 1 andc 2 are constants given by the microscopic parameters (7). This form fits the data, with strain D22 exhibiting higher amounts of intrinsic noise than M22 at all levels of expression (Fig. 3, B and C).

The extrinsic noise, ηext, behaves very differently as a function of IPTG concentration. Whereas ηintdecreases monotonically, ηext displays a maximum at intermediate rates of transcription. As a result, total cell-cell variability (ηtot) does not uniquely determine intrinsic noise. The presence of a maximum in ηext may be explained as a result of cell-cell variation in the concentration of LacI (13). Interestingly, ηext is substantially smaller in cells carrying a chromosomal copy of lacI than it is in cells carrying a plasmid-borne copy of the gene (at comparable expression levels; see Table 1 and Fig. 3). This is consistent with greater variability in copy number for the plasmid-borne lacIgene than for its wild-type chromosomal version (14). Extrinsic and intrinsic noise must be combined to explain the observed amount of variation; regulatory mechanisms aimed at suppressing noise, such as negative feedback (15), need to respond to both sources.

To be able to model the behavior of transcriptional regulatory circuits, it is essential to understand the interplay between regulatory dynamics and noise. We introduced a synthetic oscillatory network, termed the Repressilator (7, 16), into strain M22 (Table 1 and Fig. 2F). This network causes periodic synthesis of LacI, which repeatedly turns both promoters on and off. Large excursions in overall fluorescence intensity occur (high ηtot). An additional consequence is significant increases in ηint (compared with that in a similar strain with the same mean rate of transcription; see Table 1). This is consistent with theoretical predictions that noise is greater during the approach to, rather than at, a steady state (17). Thus, regulatory dynamics can cause substantial changes in noise levels.

If the amount of noisiness in a cell is genetically determined, then different strains might exhibit different basal noise levels (both intrinsic and extrinsic). Therefore, we inserted the two reporter genes in various genetic backgrounds. The amount of noise was similar in most strains, but one, D22, displayed about twice the amount of noise (Fig. 3, B and C, and Table 1). The known genotype of this strain differed from that of a related, less noisy, strain only by deletion of therecA gene, which suggests that lack of RecA was responsible for the increased noise. In agreement with this hypothesis, transduction of the ΔrecA allele into less noisy strains such as M22, JM22, and RP22 was sufficient to substantially increase ηint (Fig. 2, B and C, and Table 1). This increased noise in ΔrecA cells does not depend on a loss of viability (18). RecA acts to rescue stalled replication forks (19), which suggests that increased noise may arise from transient copy-number differences between different parts of the chromosome.

These results show that intrinsic and extrinsic classes of noise are important in setting cell-cell variation in gene expression. Both types of noise should similarly occur in all other intracellular reactions involving small numbers of reactants. Any cellular component that suffers intrinsic fluctuations in its own concentration will act as a source of extrinsic noise for other components with which it interacts. Thus, given the substantial noise measured here, reliable functioning of the cell may require genetic networks that suppress, or are robust to, fluctuations (15, 20). At the same time, it is clear that noise, if amplified, offers the opportunity to generate long-term heterogeneity in a clonal population.

Supporting Online Material

www.sciencemag.org/cgi/content/full/297/5584/1183/DC1

Materials and Methods

Fig. S1

  • * To whom correspondence should be addressed. E-mail: elowitm{at}rockefeller.edu

REFERENCES AND NOTES

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