Regulation of Transcriptional Bursting and Spatial Patterning in Early Drosophila Embryo Development

César Nieto; Zahra Vahdat; Bomyi Lim; Abhyudai Singh

doi:10.7554/eLife.107610.1

eLife Assessment

This study presents a valuable quantitative framework for analyzing transcription dynamics data for enhancers and genes expressed in the early Drosophila embryo. By analyzing existing data across both synthetic reporters and an endogenous gene (eve), this work provides evidence that spatial gene expression patterns within the embryo are largely determined by "activity time" - the time during which a gene is bursting. The methods and evidence are solid and should be of broad interest to researchers in developmental biology and quantitative gene regulation, but the study would be significantly enhanced by clarifying the novelty of the findings relative to prior work and presenting a rigorous benchmarking of their algorithm against previously used algorithms.

https://doi.org/10.7554/eLife.107610.1.sa4

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Abstract

Nascent RNA synthesis often occurs in periods of high transcriptional activity, interspersed with basal or no activity periods. This phenomenon, known as transcriptional bursting, drives high intercellular variability in gene expression levels. How do key patterning genes in early Drosophila melanogaster embryos overcome this variability to establish precise spatial patterns for tissue development? To address this question, we study single cell transcriptional activity from MS2-based live imaging data of four transgenic constructs (rho, Kr, sna shadow, sna proximal enhancers) and the endogenous eve gene. We developed an algorithm to infer promoter states in hundreds of cells within the embryo using transcriptional activity data. Results show that while mean transcription levels exhibit spatial gradients, the burst duration and interburst timing remain surprisingly invariant across the embryo and different constructs. The time between consecutive bursts was consistent with a memoryless exponential distribution, whereas the burst duration exhibited tighter control with lesser stochastic variations. Our analysis identified two regulatory mechanisms for gene expression gradients: (1) similar burst-timing statistics across genes, with the activity time (the time from the first to the last burst) being modulated to regulate distinct expression levels; (2) for the same gene with different enhancers (sna shadow and sna proximal), we observed changes in the mean burst duration and variability of the inter-burst timing. This study provides a comprehensive approach to analyzing transcriptional bursting kinetics, revealing activity time as a major regulator of spatiotemporal expression patterning in early embryonic development.

Introduction

Robust regulation of gene expression is essential for normal cell physiology and embryo development. Variations in expression levels or ectopic activation at inappropriate times or locations can significantly affect cell phenotypes, fitness, survival, and differentiation [1–3]. Gene misregulation can be related to different developmental defects and disease phenotypes [4, 5]. Despite the need for strict control, single cell imaging has revealed random fluctuations (noise) in promoter transcriptional activity over time [6, 7]. Several studies have characterized transcriptional noise in the expression of developmental genes across organisms [8–15], and it is important to understand how this noise in single cells affects overall spatial expression patterning and subsequent development.

Gene expression is characterized by transcriptional bursts: intermittent periods of promoter activity followed by periods of inactivity in which transcripts are not produced [16–26]. Randomness in switching between active and inactive promoter states has been shown to be a key driver of intercellular variability in gene product levels across isogenic cell populations [27–37]. By analyzing the properties of transcriptional bursting in various genetic backgrounds, we can better understand the mechanisms for regulating the levels of gene products [16, 38, 39].

We present a comprehensive analysis of the transcriptional bursting properties of reporter genes driven by various regulatory enhancers and endogenous genes in early Drosophila embryos. We analyze publicly available live imaging data where single-cell transcriptional activity is tracked as a function of time and position in the embryo [40,41]. Each gene is labeled with the 24x MS2 sequence, which allows visualization of nascent transcripts in each cell with a fluorescent marker (MCP-GFP), allowing high temporal resolution to investigate the dynamics of bursting [42, 43]. We develop a simple yet robust algorithm to estimate promoter transcriptional states based on the accumulation and decay of individual fluorescence trajectories. These inferred promoter states are then used to quantify the spatiotemporal statistics of transcriptional bursting across the gene expression domain.

Among the properties of transcriptional bursting studied, we consider the burst duration (ON time), the time between successive bursts (OFF time), the rate of nascent mRNA transcription (loading rate), and the span from the first to the last burst (activity time). To examine how parameters such as spatial heterogeneity, different genes, or different enhancers affect burst dynamics, we selected enhancers of Krüppel (Kr) and rhomboid (rho) genes. The mean transcriptional activity of these genes drives expression that follows a graded pattern along the anterior-posterior and dorsoventral axes of an embryo, respectively [44, 45]. Interestingly, we find that the mean ON and OFF times are homogeneous across the expression domain, not showing the expression gradient observed in the average transcription activity. This heterogeneity can be mainly explained by differences in activity time, suggesting that different cells have different durations of active transcription but similar bursting properties once activated.

We compare two redundant sna enhancers (sna shadow and sna proximal), which drive spatially homogeneous ventral expression, revealing distinct bursting characteristics and indicating that enhancers can modulate burst timing statistics [46]. Furthermore, we study the endogenous even-skipped (eve) gene, with its seven-strip spatial pattern [47, 48]. Although eve shows homogeneous burst duration, we also found spatially varied activity time and inter-burst duration, aligning with observations from the Kr and rho constructs.

Results

This study characterizes the spatiotemporal dynamics of key genes involved in Drosophila embryonic development. We analyze gene expression dynamics during the 14th nuclear cycle (NC14), which corresponds approximately to a time window of 2-3 hours after fertilization. We use the enhancers of rho, Kr, and sna, which drive transcription of the MS2 reporter genes that recapitulate endogenous gene expression [21]. We also analyze the transcription of the endogenous eve gene (see Methods). All of these genes play an important role in the formation of body patterns in Drosophila [49].

Spatio-temporal properties of transcription bursts

The experiments analyzed (see Methods) consist of confocal microscope images of living Drosophila embryos (Figure 1A). These images discern fluorescence dynamics from individual cells, allowing single-cell resolution analysis along the anteriorposterior and dorsoventral axes of the embryo (Figure 1B). This fluorescence trajectory corresponds to transcription dynamics captured using the MS2/MCP system (Figure 1C). In this system, the number of nascent mRNA molecules is proportional to the fluorescence signal (Figure 1D, top panel). This trajectory reveals different periods of intense activity (referred to as bursts) with stochastic duration indicated by τ_ON and intervals between successive bursts denoted as τ_OFF . To estimate the transcriptional state, we developed an algorithm (see Methods) based on the finding that the fluorescence signal increase (during ON state) and decrease (during OFF state) is approximately linear over time (Figure S1), with relatively similar slopes (Figure S2). In Figure 1D bottom, we show an example of an inferred transcription state trajectory from the fluorescence signal (see Supplementary Information Section S3 and Figure S3 for technical details of the inference algorithm).

The MCP/MS2-mediated live imaging system enables the visualization of transcriptional activity at the single-cell level in living *Drosophila* embryos.
**(A)** Representative snapshot of MS2-based imaging, where endogenous *eve* is tagged with MS2 to visualize the spatial expression pattern in embryos. Regions of the embryo (ventral, dorsal, anterior and posterior) are provided. **(B)** A single cell in the embryo showing GFP fluorescence with intensity assumed to be proportional to the number of nascent mRNAs. **(C)** Schematic showing how the nascent transcripts are tagged with fluorescent proteins using the MS2/MCP system. **(D)** (Top:) Representative snapshots of a single nucleus producing transcripts (green puncta) over time. (Bottom:) Fluorescence dynamics over time (green line) and the inferred transcriptional state (red line). From the inferred state, we estimate the duration of active (ON) states (τ_ON ) and the duration of inactive (OFF) states (τ_OFF ). The black dashed line shows the burst threshold: the level where any sudden increase from the base level is considered as a burst (see Methods). Bracket in the top of the trajectory represents the activity time: the time between the beginning of the first burst and the end of the last one.

The fluorescence intensity averaged throughout the nuclear cycle reveals a distinct spatial pattern in the embryo (Figure 1A). Here, we relate this mean fluorescence to the statistics of τ_ON and τ_OFF . In addition to τ_ON and τ_OFF , our algorithm also estimates the loading rate λ^*, which is defined as the signal increase rate that best predicts the signal dynamics (see Methods) and is specific for each cell. Finally, we also estimate the time between the beginning of the first burst and the end of the last burst, which is called the activity time. We will study how these different burst properties vary spatially across the embryo, and which properties have the best concordance with the single-cell averaged mean fluorescence level.

The activity time as an important contributor to the control of gene expression

We first analyze the burst statistics of the embryos expressing rho and Kr genes. rho shows a graded expression along the dorsoventral (vertical) axis and Kr shows a gradient along the anterior-posterior (horizontal) axis (see Figure 2A and 2G) [44, 45]. rhoNEE enhancer that drives the neuroectodermal expression of rho is used to drive the reporter gene MS2-yellow expression [45]. On the other hand, the expression pattern of Kr is driven by the enhancer Kr CD2 [50].

Heterogeneous spatial expression patterns for enhancer *rho* and Kr.
(A,G) Gene expression driven by the *rho* (A) and Kr (G) enhancers which exhibit a dorsoventral and anterior-posterior gradient, respectively. The yellow box indicates, approximately, the region imaged by live imaging. (B,H) Representative fluorescence trajectories (green) and the inferred transcriptional state (red) for *rho* (B) and Kr (G). Fluorescence signals are normalized to their maximum. Activity time is represented by black brackets. Dashed horizontal line represents the burst threshold. (C,I) Average fluorescence intensity, (D,J) cell averaged τ_ON , (E,K) average τ_OFF , and (F,L) the activity time. The position of each point represents one cell in the beginning of NC14 and its color represents the mentioned average burst property. Cells presented in (B,H) are highlighted in red in (C-F) and (I-L) respectively. Marginal plots show the mean variables calculated with a spatial binning. The error bars show the 5% and 95% quantiles, while the length of the boxes show the 25% and 75% quantiles for each bin. Black dots represent the mean value. The means are connected by lines to show the spatial trends. Marginal plots also present the color scale at their edges used in the central scatter plot.

Our initial hypothesis was that gene expression can be directly associated with the frequency and duration of transcriptional bursts. This means that in regions with low or high mean gene expression, we expect less or more frequent bursts, respectively. To verify the validity of this hypothesis, we plot the spatial patterns of the average fluorescence intensity of rho (Figure 2C-F). As examples of observed dynamics, four representative nuclei from the gene expression domain were selected and their transcriptional trajectories were plotted (Figure 2B). In Figure 2C, we show a scatter plot with each dot representing one cell. The position of each dot represents the position of the respective tracked cell at the beginning of NC14. The color of the dots represents the fluorescence level averaged throughout NC14. To better visualize the spatial gradient of the burst properties, we also made marginal plots by grouping the cells into bins along the dorsoventral and anterior-posterior axis and calculating the statistics for each bin.

Figure 2D shows spatial patterns of the cell-averaged τ_ON . We excluded cells that did not show fluorescence levels above the burst threshold, as it is not possible to estimate the average τ_ON . The marginal plots in Figure 2D show the variation of the cellaveraged τ_ON for the selected bins. These bins reveal that the mean τ_ON for multiple regions of the embryo is constant, with a value of about 1 min. Similar spatial trends for τ_OFF are presented in Figure 2E. Marginal plots show that the mean τ_OFF along the axes also shows a low variation throughout the embryo. In this case, the average τ_OFF is around 3 min.

The finding that the cell averaged τ_ON and τ_OFF is spatially uniform contradicts the hypothesis of a non-homogeneous gene switching rate. To explain pattern formation in the selected genes, we noticed, as presented in Figure 2B, that the dynamics of gene expression can be simplified as periods of activity. During these long periods, multiple bursts of similar duration occur at an approximately constant rate. This motivated us to define the activity time as the span from the first burst to the final one. The duration of this activity time is marked with a bracket on the signal trajectory in Figure 2B.

We notice that spatial gene expression corresponds better to the patterns of activity time (Figure 2F) than to the cell-averaged τ_ON and τ_OFF . This suggests that the activity time better reflects the spatial heterogeneity of gene expression. This is confirmed by the Kr construct, where mean fluorescence shows a similar spatial pattern to activity time (Figures 2G-2L). Although Kr has different mean fluorescence levels along the embryo axis compared to rho, the average τ_ON and τ_OFF in Kr are relatively homogeneous with mean durations similar to those in rho. Our analysis indicates that the graded expression pattern results from the modulation of activity time rather than bursting properties.

Different enhancers can modify the time between successive bursts

Enhancers are short non-coding DNA sequences that interact with the target promoter to drive transcription (Figure 1C). Particular enhancers can increase the likelihood of transcriptional initiation by containing binding sites for transcription factors and other proteins that promote transcription [51]. We now ask whether different enhancers of the same gene can affect the burst-timing statistics. We studied the sna gene, which has a broad expression domain on the ventral side of an embryo, as shown in Figure 3A. sna is regulated by two enhancers, the proximal enhancer (snaPE ) that is located right upstream of the transcription start site (TSS) and the distal or shadow enhancer (snaSE ) located 8kb upstream of the TSS [46]. Both enhancers are known to drive sna expression in the same domain at the same time, but snaPE drives weaker expression than snaSE (Figures 3B and 3G) [52].

Spatial patterns of *sna* gene expression for different enhancers: shadow (SE) and proximal (PE)
(A) Image of the *sna* expression across the embryo. The yellow box indicates, approximately, the region imaged. (**B, G**) Representative gene expression trajectories normalized to the maximum (green) and the inferred transcriptional state (red) for *sna*PE (B) and *sna*SE (G). Activity time is represented by black brackets. Dashed horizontal line represents the burst threshold. These cells are highlighted in red in (C-F) and (H-K). (**C, H**) Spatial trends of average fluorescence, (**D, I**) average τ_ON , (**E, J**) average τ_OFF , and (**F, L**) activity time. Marginal plots show how the mean changes in different spatial bins of the expression domain. Bar length represents the 25-75% interquantile distance and error bars, the 5-95% interquantile distance.

Comparing the bursting properties of snaPE and snaSE, we find some similarities with the rho and Kr genes. For example, τ_ON and τ_OFF have low spatial heterogeneity and the activity time is highly correlated with the average fluorescence (Figures 3C-F and 3H-K). However, some differences are also observed. For example, the mean fluorescence intensity is higher for the SE enhancer than for the PE enhancer, although both regulate the same gene (Figures 3C and 3H). This difference can be explained by a shorter average τ_OFF for the SE enhancer. Since snaSE is considered a stronger enhancer than snaPE, producing more mRNA at a given duration, our results suggest that snaSE can drive stronger expression by spending less time in the OFF state, which can also explain similar results found previously [40]. Our analysis indicates that different enhancers of the same gene can induce different bursting behaviors and therefore regulate the level of mRNA production differently.

Statistical analysis of transcriptional bursting events

To better understand the statistical properties of the burst timing variables, we collect all the values of τ_ON and τ_OFF for different replicate embryos and study their statistical distribution without discrimination by cell or position. More specifically, we quantify the mean τ_ON and τ_OFF (denoted by ⟨τ_ON⟩ and ⟨τ_OFF⟩, respectively). The random variability in τ_ON and τ_OFF is measured by the squared coefficient of variation (the variance over the mean squared) and represented by and , respectively. These statistics are estimated over all cells in the embryo during NC14 for 3 different embryos (biological replicas) per construct.

While τ_OFF follows an exponential distribution, τ_ON has a hypo-exponential distribution

The analysis of ⟨τ_ON ⟩ and ⟨τ_OFF ⟩ is presented in Figure 4A. There, we show that ⟨τ_ON ⟩ ≈ 1 min while ⟨τ_OFF ⟩ ≈ 3 min for Kr, rho, and snaPE. The main outlier corresponds to snaSE ⟨τ_OFF⟩ ≈ 2 min. These results show that the properties of the burst dynamics are consistent not only for different replicas, but also among different genes. Regarding the random variability of the time intervals, Figure 4B shows how while in all replicas and genes, for Kr, rho, and snaPE. The main outlier, snaSE, shows a variability of . As a reference for the interpretation of this metric, we recall that the coefficient of variation for an exponentially-distributed random variation is 1 (dashed line in Figure 4B).

Statistical properties of transcriptional bursting timing across different constructs.
(A) Mean duration of τ_ON and τ_OFF for the four studied enhancers, each with three replicas. (B) Random variability of τ_ON and τ_OFF measured by the squared coefficient of variation and respectively. The dashed line represents the coefficient of variation of one for an exponentially-distributed random variable. (C) Probability density for τ_ON for the *sna* enhancers. The PE enhancer (left) is compared to the SE enhancer (right). The mean and squared coefficients of variation are presented with the 95% confidence interval. The solid line represents the best fit to a gamma distribution. (D) Analysis similar to (C) but for τ_OFF . The resolution of τ_ON and τ_OFF is 20 s.

To better visualize the interpretation of the metrics of and , we plot the histograms of τ_ON for snaPE and snaSE (Figure 4C). For these enhancers . This means that the distribution of τ_ON is hypoexponential, i.e., with less random variation than an exponential distribution (which has a coefficient of variation of 1). We also plot the histogram of τ_OFF in Figure 4D for the same enhancers. τ_OFF for snaPE has a mean of approximately 2.8 min and a noise of similar to the exponential distribution. snaSE, on the contrary, shows a shorter ⟨τ_OFF ⟩ ≈ 1.7 min and a lower variability .

Correlation between burst variables an mean fluorescence

In this section, we explicitly examine how the cell-averaged fluorescence relates to four other variables: cell-averaged τ_ON , cellaveraged τ_OFF , activity time and optimal loading rate λ^* (equation (3) in Methods). We gather data from three biological replicate embryos for each construct and observe the trends between these variables.

We observe that activity time increases monotonically with increasing mean fluorescence intensity, reaching saturation at high levels of mean fluorescence (Figure 5A). On the other hand, cellaveraged τ_ON , cell-averaged τ_OFF , and λ^* show weaker correlations with mean fluorescence. Cell-averaged τ_ON increases slightly with increasing mean fluorescence, validating our simplification that τ_ON is essentially constant across transgenic constructs (Figure 5B). The cell-averaged τ_OFF shows a slightly decreasing trend with mean fluorescence, although the trend is weaker compared to the relationship between activity time and mean fluorescence (Figure 5C). Relatively longer periods of τ_OFF are observed for nuclei with lower gene expression. Finally, there is almost no correlation between the loading rate λ^* and the mean fluorescence (Figure 5D).

Statistical properties of the transcriptional bursts with respect to the mean fluorescence for different enhancers.
We plot the trend of different signal statistics such as (A) activity time, (B) mean ON state duration, (C) mean OFF state duration, and (D) mean loading rate (the rate of signal increase) relative to the mean fluorescence. Each dot in the plots represents the mean value of a single cell obtained from its fluorescence trajectory during NC14. These trends suggest that the activity time aligns better with mean fluorescence.

The statistics of the eve gene expression

Until now, the data analyzed to estimate the burst statistics correspond to transgenic constructs. Next, we performed a similar analysis of the transcriptional burst statistics of eve, an endogenous gene with a more complex spatial pattern of expression. The average fluorescence level of eve has a pattern of seven stripes during early embryonic development (Figure 6A) [47]. These stripes are the result of interactions between eve and gap genes defining the position of specific para-segments that set the stages for the final segmentation of the embryo body [53]. As observed in Figure 6A, we analyze transcription trajectories of the nuclei corresponding to stripes 2-5. Examples of typical fluorescence trajectories of eve expression can be seen in Figure 6B showing, in general, a lower average intensity than the synthetic constructs (Kr, rho and sna) but a similar basal intensity. Regarding the timing statistics, we observe low spatial variability on the cell-averaged τ_ON and τ_OFF on the spatial domain of eve (Figure 6D and 6E). Furthermore, these mean times also show values similar to those of the synthetic constructs: ⟨ τ_ON ⟩ ≈ 1 min and ⟨τ_OFF⟩ ≈ 3 min. Again, the activity time appears to align better with the average fluorescence pattern (Figure 6F).

Spatial patterns of endogenous *eve* gene expression.
(A) Expression pattern of the *eve* gene. The yellow box indicates, approximately, the region imaged. (B) Expression trajectories normalized to the maximum (green) and the state of the inferred gene (red). Activity time is represented by black brackets. The horizontal dashed line represents the burst threshold which is the same as used in the constructs. These cells are highlighted in red in (C-F). (C) Spatial trends of average fluorescence, (D) average τ_ON , (E) average τ_OFF , and (F) the activity time in the studied embryo domain. Bar length represents the 25-75% interquantile distance and error bars, the 5-95% interquantile distance.

Figure 7 presents a more detailed analysis of the relationship between mean fluorescence and burst properties for the eve gene, based on data from six biological replicates. As with synthetic constructs, cell-averaged fluorescence shows a strong alignment with activity time (Figure 7A), but only a weak correlation with cell-averaged τ_ON (Figure 7B) and loading rate (Figure 7D). Cell-averaged τ_OFF shows a stronger decrease with mean fluorescence compared to the one observed in synthetic constructs (Figure 7C). The mean burst duration for eve shows relative consistency over replicas with similar mean (Figure 7E) and (Figure 7F). However, τ_OFF has slightly less consistency on the mean ⟨τ_OFF ⟩ while the random variability was hyperexponential .

Properties of transcriptional burst timing for the expression of endogenous *eve* gene.
Plots of average burst properties with respect to single-cell averaged fluorescence level (A) activity time. (B) Mean τ_ON , (C) Mean τ_OFF and (D) Mean loading rate. Each dot in these plots corresponds to a cell and the statistics are calculated over the NC14 time-span. Error bars represent the binned mean trend with 95% confidence. We also present the statistics of the burst timing estimated using all bursts and all cells for 6 different biological replicas: (E) mean burst duration ⟨τ_ON ⟩, (F) variability on burst duration , (G) mean time between successive bursts ⟨τ_OFF ⟩ and (H) variability in the time between bursts . Horizontal dashed lines in (F) and (H) correspond to a coefficient of variation of 1 for the exponential distribution. Error bars represent the 95% confidence interval.

The relatively large observed in eve is mainly due to the presence of abnormally long inter-burst times, often exceeding 12 min (Figure S4A). To validate this concept, we reanalyzed the burst statistics, focusing exclusively on cells with inter-burst times of less than 12 min. After excluding these cells, all burst properties align with those observed in synthetic constructs: ⟨τ_ON ⟩ ≈ 1 min and ⟨τ_OFF ⟩ ≈ 3 min, while and (Figure S4C-D). The comparison of the burst properties versus the mean fluorescence after this filtration is also presented in Figure S4E showing a clearer trend in activity time versus fluorescence and a flatter relationship between the mean τ_OFF and the mean fluorescence. We believe that these long periods are due to the eve regulation by multiple stripe-specific enhancers, in contrast to transgenic constructs, which typically correspond to the effects of a single enhancer. The complex interaction between these enhancers likely contributes to increased time variability while maintaining a similar spatial pattern of ⟨τ_ON⟩ and ⟨τ_OFF⟩ across stripes. In addition, it is known that eve stripe expression shifts anteriorly during NC14, such that some cells expressing eve at the posterior boundary of a stripe early in NC14 become transcriptionally inactive later [41]. For example, a cell located between stripe 1 and stripe 2 may initially express genes early in NC14 due to the activity of stripe 1 enhancers. Midway through NC14, it becomes transcriptionally inactive and later in NC14, as the expression domain shifts, it begins to express genes regulated by stripe 2-specific enhancers. This trajectory results in a long inactivity period between bursts, which contributes to higher variability. In fact, nuclei with inter-burst times of more than 12 min are mostly located at the edges of each stripe (Figure S4B).

In summary, our analysis suggests that the bursting properties of endogenous genes are comparable to those of developmental enhancers. These findings align with a previous study that characterized the bursting properties of eve using a reporter construct based on bacterial artificial chromosomes [48, 54]. Similarly to what has been observed in enhancers, the mean gene expression level for the eve gene is mainly aligned with changes in activity time despite showing a more complex spatial pattern (Figure 7A). We observed some cells with anomaly long interburst duration that biased the τ_OFF statistics. We hypothesized that these long periods are likely due to the coordinated action of multiple enhancers that collectively regulate eve expression.

Discussion

In this article, we aim to explain how the spatial pattern of mean gene expression in the early embryonic development of Drosophila emerges from the temporal dynamics of transcriptional burst activity at the single cell level. We analyze the dynamics of the amount of nascent RNA molecules measured using MS2 tagging. To infer the transcriptional state (active or inactive), we propose an algorithm based on the signal slope (see Methods). The simplicity of our algorithm helps us analyze thousands of fluorescence trajectories from individual nuclei with high throughput, providing reproducible results on inferred transcriptional states. Our analysis reveals that fluorescence accumulation and decay follow linear functions of time (Figure S1). Although simple, this dynamics requires a careful explanation using a model that considers a detailed description of RNA polymerase recruitment and elongation on the gene. Although this kind of modeling is beyond the scope of this article, we show that the process can be simplified by a two-state model as described by equations (1) and (2) in Methods to capture key transcriptional burst properties.

On the basis of the statistics of transcriptional bursts, it is possible to infer properties of the mechanism controlling the burst timing. There are known mechanisms that drive and regulate transcriptional bursting, such as chromatin dynamics [55–59], 3D enhancer-promoter interactions [54, 60–63], transcription factor binding [64–68], mRNA polymerase pausing [69], and interactions between developmental promoter motifs and associated proteins [70]. Our observation of exponentially-distributed interburst timing (Figure 4B) suggests that burst initiation may be governed by a single rate-limiting step in these developmental enhancers. The observation of burst-duration timing to be hypoexponentially distributed as shown in Figure 4 B (that is, these times have statistical fluctuations less than an exponential distribution) implies a more complex transcriptional turn-OFF with multiple rate-limited steps. Findings of non-exponential promoter state durations have previously been made for other promoters in their OFF times [71, 72], and also for their ON times [73]. Further analysis of whether the durations of consecutive bursts are related (Figure S5) revealed weak correlations suggesting ON/OFF times being independent and identically distributed random variables as good approximations for the observed bursting behavior.

There is a rich body of literature connecting transcriptional bursting to fluctuations in levels of a given gene product [74–84]. Borrowing this recent mathematical modeling framework, we explore the impact of non-exponential promoter switching times on the statistical fluctuations in gene expression levels. We linked transcription states (ON/OFF) to the generation and degradation of a gene product, with the time spent in each state itself being an independent and identically distributed random variable following an arbitrary distribution (see Supplementary Information Section S5). Our analysis shows that the noise in mRNA levels increases with the noise in the time spent in either of the ON and OFF states (Figure S6). These results imply that tight control of transcriptional burst durations, as seen in this study, will function to buffer stochastic variations in expressed mRNA levels. An intriguing finding is the consistency in the statistics of promoter ON/OFF times across cells and different genes suggesting common mechanisms controlling bursting timing. It is worth mentioning that many studies have suggested that the kinetics of bursting can vary under different conditions [48, 85, 86], and that the time between successive bursts was observed to be controlled by the gene enhancer. This control includes, as shown here, decreasing the mean duration and regulating its random variability to hypoexponential levels. In future research, we plan to modify the distance and position of the enhancer relative to the promoter to better understand the mechanisms of bursting regulation.

We found that one of the main contributors to the formation of the gene expression pattern is activity time (Figure 5), and there is also a weak dependence of the mean ⟨τ_OFF⟩ on transcription activity. This observation is similar to previous findings [85, 87]. The activity time and ⟨τ_OFF⟩ are related variables and their regulation can share similar mechanisms of action. Specifically, we found cells with isolated periods of long inactivity (>12 min) in between bursts suggesting that these cells can have more than one activity time. In recent work [88], monitoring the transcriptional activity of a promoter under the control of Polycomb proteins has shown a switch between an OFF state and a transcriptionally permissive state, with multiple bursts occurring during the permissive period. In this context, the activity time can be understood as the permissive period that is developmentally regulated to drive spatial expression patterning.

The observed importance of activity time in controlling gene expression patterns raises interesting questions about its molecular regulation. Since activity time represents the temporal window during which a gene undergoes bursting cycles, it probably reflects the duration of allowed promoter states for transcriptional activation. We hypothesize that binding of transcription factors (TFs) to cis-regulatory sequences could control this window of activity. For example, Dorsal, a transcription factor that activates sna and rho studied here, shows a graded expression along the dorsoventral axis of the embryo, showing its highest expression at the most ventral point and a gradual decrease in expression level [89]. The activity time of the Dorsal target genes (sna and rho), correlates with Dorsal level. Specifically, Dorsal target genes show a longer activity time in the ventral region compared to the more dorsolateral domain. Moreover, cooperative binding of multiple TFs at enhancers may create a stable microenvironment that persists for the duration of the activity time. Our observation that different enhancers (such as snaPE versus snaSE ) exhibit distinct activity time distributions supports this model, as these enhancers contain different combinations of TF binding sites that could affect the stability and duration of active transcriptional states.

In summary, we present a simplified model to capture the stochastic dynamics of transcription in single cells and propose high-throughput techniques to infer promoter states. Our results reveal that these burst timing statistics exhibit uniform spatial patterns within the embryo, with ON times showing tighter statistical fluctuations compared to the OFF times. Moreover, a major determinant of spatial expression regulation for different developmental enhancers is the activity time that is related to the permissive period of transcription.

Methods

Experimental details

MS2/MCP system is used to visualize nascent transcripts (Figure 1C). To build the MS2/MCP mechanism, 24 copies of MS2 sequences are inserted into the 5’ UTR or 3’ UTR of the target gene of interest. Upon transcription, MS2 sequences form a stem-loop structure, which can bind to maternally loaded MCP proteins fused with GFP. As a result, clustered MCP-GFP molecules at the site of active transcription can be detected as fluorescent puncta in each nucleus (Figure 1B).

The data analyzed in this article, for rho, Kr, and sna genes, correspond to the experiments carried out by the reference [40], where the regulatory enhancer of each gene drives the expression of the MS2-yellow reporter gene (Figure 1C). For eve, we used data from [41], where endogenous eve is tagged with MS2 using CRISPR-mediated genome editing. For the nonendogenous data, it has been observed that the dynamics of the reporter gene recapitulate the expression of the endogenous gene. All images are taken in embryos 2-3 hours after fertilization, corresponding to the 14th nuclear cycle (NC14). From each live imaging movie, we track the fluorescence intensity of the MS2 puncta in each nucleus for the duration of NC14 and use it as a measure of instantaneous transcriptional activity (Figure 1D).

Transcription state Inference

As shown in Figure 1D, a typical fluorescence trajectory reveals complex dynamics. We can segment the complete signal into periods of no activity when the fluorescence stays at a basal level (before the first burst and after the last one) and periods of activity when transcriptional bursting occurs. Our goal is to determine the precise moments at which these bursts occur which are related to the moment in which the fluorescence signal rises. To do so, we first explain the model on which the inference method is based and then explain the method itself.

Phenomenological modeling of the fluorescence signal dynamics

To simplify our analysis, we consider that the fluorescence signal dynamics is driven mainly by the transcriptional state. This state exists in two modes: ON and OFF. When the transcriptional state is ON, high transcriptional activity results in rising fluorescence levels (illustrated by dark green periods in Figure 1D). Conversely, during the OFF state, the absence of RNA polymerase recruitment causes the fluorescence signal to decrease or stabilize at its base level (light green periods in Figure 1D).

Given the possible transcriptional states (ON and OFF), we define the function ϕ(t ) as follows:

which quantifies the transcriptional state value. When the state is ON, we assume that the fluorescence levels increase at a constant rate. Similarly, when the gene is OFF, the fluorescence also decreases at a constant rate. This linear accumulation and decay approximation was concluded after a detailed analysis of fluorescence accumulation and decay trajectories in response to ON/OFF states, as presented in Figure S1. In addition to a good fit with linear functions of time, we observe that the slopes for decreasing/increasing dynamics have very similar mean absolute values (Figure S2).

In this context, we simplify the dynamics of the fluorescence signal assuming that the signal increases and decreases with the same absolute rate λ that could be different for each cell. Given the transcriptional state ϕ(t ), the fluorescence signal y^m is modeled as per the following ordinary differential equation:

with the superscript m standing for the model-predicted signal. The burst threshold y ^† is defined such that below this threshold, we assume that no bursting occurs and the transcription state is OFF (Figure 1). To determine y ^†, we selected the maximum fluorescence level in cells that did not exhibit noticeable bursts. This value was found to be y ^† = 0.1 (a.u.). Since basal fluorescence levels did not differ significantly between genes, we used the same threshold for all genes. Next, we will explain how, assuming (2), we infer the most probable λ and the corresponding transcriptional state for each cell.

Transcription state inference method

Since the data consists of sampling the fluorescence signal every Δt = 20s, we consider a discrete-time analog of (2) that follows

where t = {0, Δt , 2Δt , … }. Given experimental measurements y_t , our objective is to infer the transcriptional state ϕ_t that best explains the data. The technical details of the defined algorithm are presented in Supplementary Information Section S3, and are briefly summarized here.

The inference method starts with the experimental trajectory y_t, which is first smoothed to obtain the signal by convolving it with a triangular kernel function to not flatten the signal peaks too much (see Supplementary Information Section S3). Next, we propose a value for λ for all transcriptional bursts in a single nucleus. Given and λ, we first obtain the transcription activity ρ_t defined as

and is a quantity which estimates the rate of signal increase relative to λ. We perform a new round of smoothing of ρ_t with a square kernel function (see Supplementary Information section 3) obtaining the smoothed . In this way, the inferred transcriptional state ϕ_t is calculated as follows:

The resulting ϕ_t is replaced in (3) obtaining a trajectory that depends parametrically on the particular λ. Finally, the optimal λ, denoted as λ^*, is defined as the loading rate for that specific nuclei that minimizes the mean square distance between the data y_t and the resultant defined as:

The optimal λ^* will predict the optimal ϕ_t by using (5) which is taken as the most accurate trajectory of the transcriptional state. Examples of best-fit trajectories ϕ_t and are shown in Figure S3D-E, respectively.

Data accessibility statement

Data set and data processing scripts are publicly available at https://doi.org/10.5281/zenodo.13208281 [90].

Acknowledgements

B.L. is funded by NIH R35 GM133425. A.S. and C.N. acknowledge support from NIH-NIGMS through grant R35GM148351.

Additional information

Author Contributions

Conceptualization: B.L. C.N., A.S.
Investigation: Z.V., C.N.
Data Curation: B.L., Z.V., C.N.
Formal Analysis: Z.V., C.N.
Funding Acquisition: A.S., B.L.
Investigation: C.N., Z.V., B.L., A.S.
Methodology: B.L., Z.V., C.N.
Resources: A.S., B.L.
Software: C.N., Z.V.
Supervision: A.S., B.L.
Visualization: C.N., Z.V.
Writing: C.N., B.L., A.S.
Writing – Review Editing: B.L., A.S.

Funding

National Institutes of Health (R35GM133425)

National Institutes of Health (R35GM148351)

Additional files

Supplementary Information

References

[1]
1. Halder Georg
2. Callaerts Patrick
3. Gehring Walter J
1995Induction of ectopic eyes by targeted expression of the eyeless gene in DrosophilaScience 267:1788–1792Google Scholar
[2]
1. Riedel-Kruse Ingmar H
2. Muller Claudia
3. Oates Andrew C
2007Synchrony dynamics during initiation, failure, and rescue of the segmentation clockScience 317:1911–1915Google Scholar
[3]
1. Dubuis Julien O
2. Samanta Reba
3. Gregor Thomas
2013Accurate measurements of dynamics and reproducibility in small genetic networksMolecular Systems Biology 9:639Google Scholar
[4]
1. Sakabe Noboru Jo
2. Savic Daniel
3. Nobrega Marcelo A
2012Transcriptional enhancers in development and diseaseGenome Biology 13:1–11Google Scholar
[5]
1. Claringbould Annique
2. Zaugg Judith B
2021Enhancers in disease: molecular basis and emerging treatment strategiesTrends in Molecular Medicine 27:1060–1073Google Scholar
[6]
1. Elowitz M. B.
2. Levine A. J.
3. Siggia E. D.
4. Swain P. S.
2002Stochastic gene expression in a single cellScience 297:1183–1186Google Scholar
[7]
1. Raj Arjun
2. Van Oudenaarden Alexander
2008Nature, nurture, or chance: stochastic gene expression and its consequencesCell 135:216–226Google Scholar
[8]
1. Holmes William R
2. de Mochel Nabora Soledad Reyes
3. Wang Qixuan
4. Du Huijing
5. Peng Tao
6. Chiang Michael
7. Cinquin Olivier
8. Cho Ken
9. Nie Qing
2017Gene expression noise enhances robust organization of the early mammalian blasto-cystPLOS Computational Biology 13:e1005320Google Scholar
[9]
1. Voortman Lukas
2. Jr Robert J Johnston
2022Transcriptional repression in stochastic gene expression, patterning, and cell fate specificationDevelopmental Biology 481:129–138Google Scholar
[10]
1. Araújo Ilka Schultheiß
2. Pietsch Jessica Magdalena
3. Keizer Emma Mathilde
4. Greese Bettina
5. Balkunde Rachappa
6. Fleck Christian
7. Hülskamp Martin
2017Stochastic gene expression in arabidopsis thalianaNature Communications 8:2132Google Scholar
[11]
1. Ferraro Teresa
2. Esposito Emilia
3. Mancini Laure
4. Ng Sam
5. Lucas Tanguy
6. Coppey Mathieu
7. Dostatni Nathalie
8. Walczak Aleksandra M
9. Levine Michael
10. Lagha Mounia
2016Transcriptional memory in the Drosophila embryoCurrent Biology 26:212–218Google Scholar
[12]
1. Zhang Lei
2. Radtke Kelly
3. Zheng Likun
4. Cai Anna Q
5. Schilling Thomas F
6. Nie Qing
2012Noise drives sharpening of gene expression boundaries in the zebrafish hindbrainMolecular Systems Biology 8:613Google Scholar
[13]
1. Desai Ravi V
2. Chen Xinyue
3. Martin Benjamin
4. Chaturvedi Sonali
5. Hwang Dong Woo
6. Li Weihan
7. Yu Chen
8. Ding Sheng
9. Thomson Matt
10. Singer Robert H
11. et al.
2021A DNA repair pathway can regulate transcriptional noise to promote cell fate transitionsScience 373:eabc6506Google Scholar
[14]
1. Keskin Sevdenur
2. Devakanmalai Gnanapackiam S
3. Bin Kwon Soo
4. Vu Ha T
5. Hong Qiyuan
6. Lee Yin Yeng
7. Soltani Mohammad
8. Singh Abhyudai
9. Ay Ahmet
10. rul Ertuğ
11. Özbudak M
2018Noise in the vertebrate segmentation clock is boosted by time delays but tamed by notch signalingCell Reports 23:2175–2185Google Scholar
[15]
1. Zinani Oriana QH
2. lu Kemal Keseroğ
3. Dey Supravat
4. Ay Ahmet
5. Singh Abhyudai
6. rul Ertuğ
7. Özbudak M
2022Gene copy number and negative feedback differentially regulate transcriptional variability of segmentation clock genesiScience 25Google Scholar
[16]
1. Raj A.
2. Peskin C.S.
3. Tranchina D.
4. Vargas D.Y.
5. Tyagi S.
2006Stochastic mRNA synthesis in mammalian cellsPLOS Biology 4:e309Google Scholar
[17]
1. Ramsköld Daniel
2. Hendriks Gert-Jan
3. Larsson Anton JM
4. Mayr Juliane V
5. Ziegenhain Christoph
6. Hagemann-Jensen Michael
7. Hartmanis Leonard
8. Sandberg Rickard
2024Single-cell new RNA sequencing reveals principles of transcription at the resolution of individual burstsNature Cell Biology 26:1725–1733Google Scholar
[18]
1. Jeziorska DM
2. Tunnacliffe EAJ
3. Brown JM
4. Ayyub H
5. Sloane-Stanley J
6. Sharpe JA
7. Lagerholm BC
8. Babbs C
9. Smith AJH
10. Buckle VJ
11. et al.
2022On-microscope staging of live cells reveals changes in the dynamics of transcriptional bursting during differentiationNature Communications 13:6641Google Scholar
[19]
1. Wan Yihan
2. Anastasakis Dimitrios G
3. Rodriguez Joseph
4. Palangat Murali
5. Gudla Prabhakar
6. Zaki George
7. Tandon Mayank
8. Pegoraro Gianluca
9. Chow Carson C
10. Hafner Markus
11. et al.
2021Dynamic imaging of nascent RNA reveals general principles of transcription dynamics and stochastic splice site selectionCell 184:2878–2895Google Scholar
[20]
1. Porello Emilia A Leyes
2. Trudeau Robert T
3. Lim Bomyi
2023Transcriptional bursting: stochasticity in deterministic developmentDevelopment 150:dev201546Google Scholar
[21]
1. Fukaya Takashi
2023Enhancer dynamics: Unraveling the mechanism of transcriptional burstingScience Advances 9:eadj3366Google Scholar
[22]
1. Dar Roy D.
2. Shaffer Sydney M.
3. Singh Abhyudai
4. Razooky Brandon S.
5. Simpson Michael L.
6. Raj Arjun
7. Weinberger Leor S.
2016Transcriptional bursting explains the noise–versus–mean relationship in mRNA and protein levelsPLOS One 11Google Scholar
[23]
1. Corrigan Adam M.
2. Chubbemail Jonathan R.
2014Regulation of transcriptional bursting by a naturally oscillating signalCurrent Biology 24:205–211Google Scholar
[24]
1. Ochiai Hiroshi
2. Hayashi Tetsutaro
3. Umeda Mana
4. Yoshimura Mika
5. Harada Akihito
6. Shimizu Yukiko
7. Nakano Kenta
8. Saitoh Noriko
9. Liu Zhe
10. Yamamoto Takashi
11. et al.
2020Genome-wide kinetic properties of transcriptional bursting in mouse embryonic stem cellsScience Advances 6Google Scholar
[25]
1. Larson Daniel R
2. Fritzsch Christoph
3. Sun Liang
4. Meng Xiuhau
5. Lawrence David S
6. Singer Robert H
2013Direct observation of frequency modulated transcription in single cells using light activationeLife 2Google Scholar
[26]
1. Cavallaro Massimo
2. Walsh Mark D
3. Jones Matt
4. Teahan James
5. Tiberi Simone
6. Finkenstädt Bärbel
7. Heben-streit Daniel
20213’-5’ crosstalk contributes to transcriptional burstingGenome Biology 22:1–20Google Scholar
[27]
1. Yunger Sharon
2. Rosenfeld Liat
3. Garini Yuval
4. Shav-Tal Yaron
2010Single-allele analysis of transcription kinetics in living mammalian cellsNature Methods 7:631–633Google Scholar
[28]
1. Larson Daniel R
2. Zenklusen Daniel
3. Wu Bin
4. Chao Jeffrey A
5. Singer Robert H
2011Real-time observation of transcription initiation and elongation on an endogenous yeast geneScience 332:475–478Google Scholar
[29]
1. Corrigan Adam M
2. Tunnacliffe Edward
3. Cannon Danielle
4. Chubb Jonathan R
2016A continuum model of transcriptional burstingeLife 5Google Scholar
[30]
1. Bothma Jacques P
2. Garcia Hernan G
3. Esposito Emilia
4. Schlissel Gavin
5. Gregor Thomas
6. Levine Michael
2014Dynamic regulation of eve stripe 2 expression reveals transcriptional bursts in living Drosophila embryosProceedings of the National Academy of Sciences 111:10598–10603Google Scholar
[31]
1. Dar Roy D
2. Razooky Brandon S
3. Singh Abhyudai
4. Trimeloni Thomas V
5. McCollum James M
6. Cox Chris D
7. Simpson Michael L
8. Weinberger Leor S
2012Transcriptional burst frequency and burst size are equally modulated across the human genomeProceedings of the National Academy of Sciences 109:17454–17459Google Scholar
[32]
1. Padovan-Merhar Olivia
2. Nair Gautham P
3. Biaesch Andrew G
4. Mayer Andreas
5. Scarfone Steven
6. Foley Shawn W
7. Wu Angela R
8. Churchman L Stirling
9. Singh Abhyudai
10. Raj Arjun
2015Single mammalian cells compensate for differences in cellular volume and DNA copy number through independent global transcriptional mechanismsMolecular Cell 58:339–352Google Scholar
[33]
1. Chong Shasha
2. Chen Chongyi
3. Ge Hao
4. Xie X. Sunney
2014Mechanism of transcriptional bursting in bacteriaCell 158:314–326Google Scholar
[34]
1. Singh A.
2. Razooky Brandon
3. Cox Chris D.
4. Simpson Michael L.
5. Weinberger Leor S.
2010Transcriptional bursting from the HIV-1 promoter is a significant source of stochastic noise in HIV-1 gene expressionBiophysical Journal 98:L32–L34Google Scholar
[35]
1. Schuh Lea
2. Saint-Antoine Michael
3. Sanford Eric M
4. Emert Benjamin L
5. Singh Abhyudai
6. Marr Carsten
7. Raj Arjun
8. Goyal Yogesh
2020Gene networks with transcriptional bursting recapitulate rare transient coordinated high expression states in cancerCell Systems 10:363–378Google Scholar
[36]
1. Singh A.
2. Razooky B. S.
3. Dar R. D.
4. Weinberger L. S.
2012Dynamics of protein noise can distinguish between alternate sources of gene-expression variabilityMolecular Systems Biology 8Google Scholar
[37]
1. Mold Jeff E
2. Weissman Martin H
3. Ratz Michael
4. Hagemann-Jensen Michael
5. Hård Joanna
6. Eriksson Carl-Johan
7. Toosi Hosein
8. Berghenstråhle Joseph
9. Ziegenhain Christoph
10. von Berlin Leonie
11. et al.
2024Clonally heritable gene expression imparts a layer of diversity within cell typesCell Systems 15:149–165Google Scholar
[38]
1. Chubb Jonathan R
2. Trcek Tatjana
3. Shenoy Shailesh M
4. Singer Robert H
2006Transcriptional pulsing of a developmental geneCurrent Biology 16:1018–1025Google Scholar
[39]
1. Golding Ido
2. Paulsson Johan
3. Zawilski Scott M
4. Cox Edward C
2005Real-time kinetics of gene activity in individual bacteriaCell 123:1025–1036Google Scholar
[40]
1. Fukaya Takashi
2. Lim Bomyi
3. Levine Michael
2016Enhancer control of transcriptional burstingCell 166:358–368Google Scholar
[41]
1. Lim Bomyi
2. Fukaya Takashi
3. Heist Tyler
4. Levine Michael
2018Temporal dynamics of pair-rule stripes in living Drosophila embryosProceedings of the National Academy of Sciences 115:8376–8381Google Scholar
[42]
1. Bertrand Edouard
2. Chartrand Pascal
3. Schaefer Matthias
4. Shenoy Shailesh M
5. Singer Robert H
6. Long Roy M
1998Localization of ash1 mrna particles in living yeastMolecular Cell 2:437–445Google Scholar
[43]
1. Garcia Hernan G
2. Tikhonov Mikhail
3. Lin Albert
4. Gregor Thomas
2013Quantitative imaging of transcription in living Drosophila embryos links polymerase activity to patterningCurrent Biology 23:2140–2145Google Scholar
[44]
1. Herbert Jächle
2. Hoch Michael
3. Ankratz Michael J
4. Gerwin Nicole
5. Sauer Frank
6. Brönner Günter
1992Transcriptional control by Drosophila gap genesJournal of Cell Science 1992:39–51Google Scholar
[45]
1. Ip Y Tony
2. Park Ronald E
3. Kosman David
4. Bier Ethan
5. Levine Michael
1992The dorsal gradient morphogen regulates stripes of rhomboid expression in the presumptive neuroectoderm of the Drosophila embryoGenes & Development 6:1728–1739Google Scholar
[46]
1. Perry Michael W
2. Boettiger Alistair N
3. Bothma Jacques P
4. Levine Michael
2010Shadow enhancers foster robustness of Drosophila gastrulationCurrent Biology 20:1562–1567Google Scholar
[47]
1. Goto Tadaatsu
2. Macdonald Paul
3. Maniatis Tom
1989Early and late periodic patterns of even skipped expression are controlled by distinct regulatory elements that respond to different spatial cuesCell 57:413–422Google Scholar
[48]
1. Berrocal Augusto
2. Lammers Nicholas C
3. Garcia Hernan G
4. Eisen Michael B
2020Kinetic sculpting of the seven stripes of the Drosophila even-skipped geneeLife 9Google Scholar
[49]
1. Ingham PW
1988The molecular genetics of embryonic pattern formation in drosophilaNature 335:25–34Google Scholar
[50]
1. Hoch Michael
2. Schröder C
3. Seifert Eveline
4. Jäckle H
1990cis-acting control elements for krüppel expression in the Drosophila embryoThe EMBO journal 9:2587–2595Google Scholar
[51]
1. Mahat Dig B
2. Tippens Nathaniel D
3. Martin-Rufino Jorge D
4. Waterton Sean K
5. Fu Jiayu
6. Blatt Sarah E
7. Sharp Phillip A
2024Single-cell nascent RNA sequencing unveils coordinated global transcriptionNature :1–8Google Scholar
[52]
1. Bothma Jacques P
2. Garcia Hernan G
3. Ng Samuel
4. Perry Michael W
5. Gregor Thomas
6. Levine Michael
2015Enhancer additivity and non-additivity are determined by enhancer strength in the Drosophila embryoeLife 4Google Scholar
[53]
1. Pankratz Michael J
2. Jäckle Herbert
1990Making stripes in the Drosophila embryoTrends in Genetics 6:287–292Google Scholar
[54]
1. Berrocal Augusto
2. Lammers Nicholas C
3. Garcia Hernan G
4. Eisen Michael B
2024Unified bursting strategies in ectopic and endogenous even-skipped expression patternseLife 12Google Scholar
[55]
1. Gabriele Michele
2. Brandão Hugo B
3. Grosse-Holz Simon
4. Jha Asmita
5. Dailey Gina M
6. Cattoglio Claudia
7. Hsieh Tsung-Han S
8. Mirny Leonid
9. Zechner Christoph
10. Hansen Anders S
2022Dynamics of ctcf-and cohesin-mediated chromatin looping revealed by live-cell imagingScience 376:496–501Google Scholar
[56]
1. Fraser LaTasha CR
2. Dikdan Ryan J
3. Dey Supravat
4. Singh Abhyudai
5. Tyagi Sanjay
2021Reduction in gene expression noise by targeted increase in accessibility at gene lociProceedings of the National Academy of Sciences 118:e2018640118Google Scholar
[57]
1. May Dennis
2. Yun Sangwon
3. Gonzalez David G
4. Park Sangbum
5. Chen Yanbo
6. Lathrop Elizabeth
7. Cai Biao
8. Xin Tianchi
9. Zhao Hongyu
10. Wang Siyuan
11. et al.
2023Live imaging reveals chromatin compaction transitions and dynamic transcriptional bursting during stem cell differentiation in vivoeLife 12Google Scholar
[58]
1. Kenworthy Charles A
2. Haque Nayem
3. Liou Shu-Hao
4. Chandris Panagiotis
5. Wong Vincent
6. Dziuba Patrycja
7. Lavis Luke D
8. Liu Wei-Li
9. Singer Robert H
10. Coleman Robert A
2022Bromodomains regulate dynamic targeting of the pbaf chromatin-remodeling complex to chromatin hubsBiophysical Journal 121:1738–1752Google Scholar
[59]
1. Brouwer Ineke
2. Kerklingh Emma
3. van Leeuwen Fred
4. Lenstra Tineke L
2023Dynamic epistasis analysis reveals how chromatin remodeling regulates transcriptional burstingNature structural & molecular biology 30:692–702Google Scholar
[60]
1. Bohrer Christopher H
2. Larson Daniel R
2023Synthetic analysis of chromatin tracing and live-cell imaging indicates pervasive spatial coupling between geneseLife 12Google Scholar
[61]
1. Bartman Caroline R.
2. Hsu Sarah C.
3. Hsiung Chris C.-S.
4. Raj Arjun
5. Blobel Gerd A.
2016Enhancer regulation of transcriptional bursting parameters revealed by forced chromatin loopingMolecular Cell 62:237–247Google Scholar
[62]
1. Robles-Rebollo Irene
2. Cuartero Sergi
3. Canellas-Socias Adria
4. Wells Sarah
5. Karimi Mohammad M
6. Mereu Elisabetta
7. Chivu Alexandra G
8. Heyn Holger
9. Whilding Chad
10. Dormann Dirk
11. et al.
2022Cohesin couples transcriptional bursting probabilities of inducible enhancers and promotersNature Communications 13:4342Google Scholar
[63]
1. Du Manyu
2. Stitzinger Simon Hendrik
3. Spille Jan-Hendrik
4. Cho Won-Ki
5. Lee Choongman
6. Hijaz Mohammed
7. Quintana Andrea
8. Cissé Ibrahim I
2024Direct observation of a condensate effect on super-enhancer controlled gene burstingCell 187:331–344Google Scholar
[64]
1. Keller Samuel H
2. Jena Siddhartha G
3. Yamazaki Yuji
4. Lim Bomyi
2020Regulation of spatiotemporal limits of developmental gene expression via enhancer grammarProceedings of the National Academy of Sciences 117:15096–15103Google Scholar
[65]
1. Syed Sahla
2. Duan Yifei
3. Lim Bomyi
2023Modulation of protein-dna binding reveals mechanisms of spatiotemporal gene control in early Drosophila embryoseLife 12Google Scholar
[66]
1. Dobrinić Paula
2. Szczurek Aleksander T
3. Klose Robert J
2021Prc1 drives polycomb-mediated gene repression by controlling transcription initiation and burst frequencyNature Structural & Molecular Biology 28:811–824Google Scholar
[67]
1. Ma Liang
2. Gao Zeyue
3. Wu Jiegen
4. Zhong Bijunyao
5. Xie Yuchen
6. Huang Wen
7. Lin Yihan
2021Co-condensation between transcription factor and coactivator p300 modulates transcriptional bursting kineticsMolecular Cell 81:1682–1697Google Scholar
[68]
1. Fountas Charis
2. Lenstra Tineke L
2024Better together: how cooperativity influences transcriptional burstingCurrent Opinion in Genetics & Development 89Google Scholar
[69]
1. Tantale Katjana
2. Garcia-Oliver Encar
3. Robert Cécile
4. LÕhostis Adèle
5. Yang Yueyuxiao
6. Tsanov Nikolay
7. Topno Rachel
8. Gostan Thierry
9. Kozulic-Pirher Alja
10. Basu-Shrivastava Meenakshi
11. et al.
2021Stochastic pausing at latent hiv-1 promoters generates transcriptional burstingNature Communications 12:4503Google Scholar
[70]
1. Pimmett Virginia L
2. Dejean Matthieu
3. Fernandez Carola
4. Trullo Antonio
5. Bertrand Edouard
6. Radulescu Ovidiu
7. Lagha Mounia
2021Quantitative imaging of transcription in living Drosophila embryos reveals the impact of core promoter motifs on promoter state dynamicsNature Communications 12:4504Google Scholar
[71]
1. Suter David M
2. Molina Nacho
3. Gatfield David
4. Schneider Kim
5. Schibler Ueli
6. Naef Felix
2011Mammalian genes are transcribed with widely different bursting kineticsScience 332:472–474Google Scholar
[72]
1. Choubey Sandeep
2. Kondev Jane
3. Sanchez Alvaro
2015Deciphering transcriptional dynamics in vivo by counting nascent RNA moleculesPLOS Computational Biology 11:e1004345Google Scholar
[73]
1. Tantale Katjana
2. Mueller Florian
3. Kozulic-Pirher Alja
4. Lesne Annick
5. Victor Jean-Marc
6. Robert Marie-Cécile
7. Capozi Serena
8. Chouaib Racha
9. Bäcker Volker
10. Mateos-Langerak Julio
11. et al.
2016A single-molecule view of transcription reveals convoys of RNA polymerases and multi-scale burstingNature Communications 7:12248Google Scholar
[74]
1. Xu Zikai
2. Soltani Mohammad
3. Singh Abhyudai
2018Exact statistical moments of multi-mode stochastic hybrid systems with renewal transitionsIn: 2018 IEEE Conference on Decision and Control (CDC) IEEE pp. 3510–3515Google Scholar
[75]
1. Jia Tao
2. Kulkarni Rahul V.
2011Intrinsic noise in stochastic models of gene expression with molecular memory and burstingJournal of Mathematical Biology 106Google Scholar
[76]
1. Wu Renjie
2. Zhou Bangyan
3. Wang Wei
4. Liu Feng
2023Regulatory mechanisms for transcriptional bursting revealed by an event-based modelResearch 6Google Scholar
[77]
1. Shi Changhong
2. Yang Xiyan
3. Zhang Jiajun
4. Zhou Tianshou
2023Stochastic modeling of the mrna life process: A generalized master equationBiophysical Journal 122:4023–4041Google Scholar
[78]
1. Shi Changhong
2. Yang Xiyan
3. Zhou Tianshou
4. Zhang Jiajun
2024Nascent RNA kinetics with complex promoter architecture: Analytic results and parameter inferencePhysical Review E 110:034413Google Scholar
[79]
1. Chen Meiling
2. Luo Songhao
3. Cao Mengfang
4. Guo Chengjun
5. Zhou Tianshou
6. Zhang Jiajun
2022Exact distributions for stochastic gene expression models with arbitrary promoter architecture and translational burstingPhysical Review E 105:014405Google Scholar
[80]
1. Stinchcombe Adam R
2. Peskin Charles S
3. Tranchina Daniel
2012Population density approach for discrete mrna distributions in generalized switching models for stochastic gene expressionPhysical Review E—Statistical, Nonlinear, and Soft Matter Physics 85:061919Google Scholar
[81]
1. Kumar Niraj
2. Singh Abhyudai
3. Kulkarni Rahul V.
2015Transcriptional bursting in gene expression: analytical results for general stochastic modelsPLOS Computational Biology 11Google Scholar
[82]
1. Vahdat Zahra
2. Singh Abhyudai
2024Quantifying statistics of gene product copy-number fluctuations: A stochastic hybrid systems approachIn: 2024 IEEE 63rd Conference on Decision and Control (CDC) pp. 7792–7797Google Scholar
[83]
1. Cao Zhixing
2. Filatova Tatiana
3. Oyarzún Diego A
4. Grima Ramon
2020A stochastic model of gene expression with polymerase recruitment and pause releaseBiophysical Journal 119:1002–1014Google Scholar
[84]
1. Singh A
2014Transient changes in intercellular protein variability identify sources of noise in gene expressionBiophysical Journal 107:2214–2220Google Scholar
[85]
1. Zoller Benjamin
2. Little Shawn C
3. Gregor Thomas
2018Diverse spatial expression patterns emerge from unified kinetics of transcriptional burstingCell 175:835–847Google Scholar
[86]
1. Beadle Lauren Forbes
2. Zhou Hongpeng
3. Rattray Magnus
4. Ashe Hilary L
2023Modulation of transcription burst amplitude underpins dosage compensation in the Drosophila embryoCell Reports 42Google Scholar
[87]
1. Molina Nacho
2. Suter David M
3. Cannavo Rosamaria
4. Zoller Benjamin
5. Gotic Ivana
6. Naef Félix
2013Stimulus-induced modulation of transcriptional bursting in a single mammalian geneProceedings of the National Academy of Sciences 110:20563–20568Google Scholar
[88]
1. Szczurek Aleksander T
2. Dimitrova Emilia
3. Kelley Jessica R
4. Blackledge Neil P
5. Klose Robert J
2024The polycomb system sustains promoters in a deep off state by limiting pre-initiation complex formation to counteract transcriptionNature Cell Biology 26:1700–1711Google Scholar
[89]
1. Hong Joung-Woo
2. Hendrix David A
3. Papatsenko Dmitri
4. Levine Michael S
2008How the dorsal gradient works: insights from postgenome technologiesProceedings of the National Academy of Sciences 105:20072–20076Google Scholar
[90]
1. Nieto Cesar
2. Vahdat Zahra
2024Data processing pipeline for the article “Analysis of Transcriptional Bursting Dynamics and its Role on Spatial Patterning of D. melanogaster Embryo development”Zenodo https://doi.org/10.5281/zenodo.13324127

Article and author information

Author information

César Nieto
Department of Electrical and Computer Engineering, University of Delaware, Newark, United States
ORCID iD: 0000-0001-6504-4619
Zahra Vahdat
Department of Electrical and Computer Engineering, University of Delaware, Newark, United States, Dan L. Comprehensive Cancer Center, Baylor College of Medicine, Houston, United States, Department of Molecular and Cellular Biology, Baylor College of Medicine, Houston, United States
ORCID iD: 0000-0001-9794-5147
Bomyi Lim
Department of Chemical and Biomolecular Engineering, University of Pennsylvania, Philadelphia, United States
ORCID iD: 0000-0002-3058-9181
Abhyudai Singh
Department of Electrical and Computer Engineering, Biomedical Engineering, Mathematical Sciences, Center of Bioinformatics and Computational Biology, University of Delaware, Newark, United States
ORCID iD: 0000-0002-1451-2838
- For correspondence: absingh@udel.edu

Author Notes

Competing interests: No competing interests declared

Version history

Preprint posted: May 8, 2025
Sent for peer review: June 4, 2025
Reviewed Preprint version 1: September 23, 2025

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You can cite all versions using the DOI https://doi.org/10.7554/eLife.107610. This DOI represents all versions, and will always resolve to the latest one.

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