SAIBR: a simple, platform-independent method for spectral autofluorescence correction

Rodrigues, Nelio T. L.; Bland, Tom; Borrego-Pinto, Joana; Ng, KangBo; Hirani, Nisha; Gu, Ying; Foo, Sherman; Goehring, Nathan W.

doi:10.1242/dev.200545

Cited by 8 publications

(8 citation statements)

References 49 publications

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“…Raw or SAIBR processed images were used for quantification (Rodrigues et al, 2022). In order to measure cortical concentrations, a 100-pixel-wide (15.5 μm) line following the membrane around the embryo was computationally straightened, and a 20-pixel-wide (3.1 μm) rolling average filter was applied to the straightened image.…”

Section: Methodsmentioning

confidence: 99%

Cleavage furrow-directed cortical flows bias mechanochemical pathways for PAR polarization in theC. elegansgerm lineage

Hirani

Bland

et al. 2022

Preprint

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During development, the conserved PAR polarity network is continuously redeployed, requiring that it adapts to changing cellular contexts and environmental cues. How it does so and the degree to which these adaptations reflect changes in its fundamental design principles remain unclear. Here, we investigate the process of PAR polarization within the highly tractable C. elegans germline P lineage, which undergoes a series of iterative asymmetric stem cell-like divisions. Compared to the zygote, we observe significant differences in the pattern of polarity emergence, including an inversion of the initial unpolarized state, changes in symmetry breaking cues, and the timings with which anterior and posterior PARs segregate. Beneath these differences, however, polarity establishment remains reliant on the same core pathways identified in the zygote, including conserved roles for cortical actin flows and PAR-dependent self-organization. Intriguingly, we find that cleavage furrow-directed cortical actin flows play a similar symmetry-breaking role for the germline cell P1 as centrosome-induced cortical flows in the zygote. Through their ability to induce asymmetric accumulation of PAR-3 clusters, these furrow-directed flows directly couple the geometry of polarization to cell division, which could be a general strategy for cells to ensure proper organization within dynamically growing systems, such as embryos. In summary, our data suggest that coupling of novel symmetry-breaking cues with highly adaptable core mechanochemical circuits enable robust PAR polarity in response to changing developmental contexts.

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Section: Methodsmentioning

confidence: 99%

Cleavage furrow-directed cortical flows bias mechanochemical pathways for PAR polarization in theC. elegansgerm lineage

Hirani

Bland

et al. 2022

Preprint

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“…Raw images were processed using SAIBR using N2 or NWG0038 animals for the autofluorescence calibration as required and ortical concentrations were obtained as described previously (Rodrigues et al, 2022). Briefly, a 50-pixel-wide (12.8 µm) line following the membrane around the embryo was extracted and computationally straightened, and a 20-pixel-wide (5.1 µm) rolling average filter was applied to the straightened image to reduce noise.…”

Section: Methodsmentioning

confidence: 99%

Design principles for selective polarization of PAR proteins by cortical flows

Illukkumbura

Hirani

Borrego-Pinto

et al. 2022

Preprint

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Clustering of membrane-associated molecules has long been proposed to promote size-dependent interactions with the actomyosin cortical network, thereby allowing them to be transported by actin flow. Consistent with such a model, clustering of the conserved polarity protein PAR-3 in the C. elegans zygote is essential for its polarization by cortical actomyosin flows, and clusters of PAR-3 visibly move with flows. However, here we show that advection by cortical flow is independent of clustering. Clustered and non-clustered PAR-3 variants are advected equally well over short timescales by cortical actin flow as are other PAR proteins. Moreover, we see no strong links between advection and either cluster size or diffusivity that would be consistent with size-dependent interactions with the actin cortex. Instead, using a combination of experiment and theory, we find that efficient long range transport of PAR proteins by cortical flow is primarily tuned by the stability of membrane association, which is enhanced by clustering and determines the persistence of both transport by flow and the resulting asymmetries once flows cease. Consistent with this model, stabilizing membrane association was sufficient to induce segregation of a non-segregating PAR protein, effectively inverting its polarity. We conclude that the impact of advection on membrane-associated proteins is much broader than previously anticipated and thus cells must appropriately tune membrane association dynamics to achieve selectivity in the long range transport of membrane-associated molecules by cortical flows.

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“…Subtraction can be done on a pixel-by-pixel basis (allowing for spatial signal correction) or on an embryo-by-embryo basis (e.g., to quantify whole-embryo fluorescence intensities, as indicated above). Note that SAIBR is also compatible when quantifying GFP fluorescence in embryos that co-express additional, spectrally-distinct fluorophores (such as mCherry), as detailed in (Rodrigues et al, 2022).…”

Section: Image Analysis -Quantitation Of Total and Cortical Fluorescencementioning

confidence: 99%

“…To address these questions, we set out to explicitly measure the sensitivity of embryos to perturbations in PAR protein dosage. By combining established methods for manipulation of protein dosage in C. elegans (Oegema, 2006) with a recently developed image quantitation-based workflow (Rodrigues et al, 2022), we were able to directly relate dosage to phenotype in individual embryos. Our data support a model in which pathway responses are highly canalized against variation in spatial signals at multiple levels, leading to quantitative decoupling between symmetry-breaking, polarity, spindle positioning and fate segregation modules.…”

Section: Introductionmentioning

confidence: 99%

Nonlinear readout of spatial cues underlies robustness of asymmetric cell division

Rodrigues,

Bland,

et al. 2023

Preprint

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A key challenge in the development of an organism is to maintain robust phenotypic outcomes in the face of perturbation. Yet, how such robust outcomes are encoded by developmental networks remains poorly explored. Here we use theC. eleganszygote as a model to understand sources of developmental robustness during PAR polarity-dependent asymmetric cell division. By quantitatively linking alterations in protein dosage to phenotype in individual embryos, we show that spatial information in the zygote is read out in a highly nonlinear fashion and, as a result, phenotypes are highly canalized against substantial variation in input signals. Specifically, our data point towards an intrinsic robustness of the conserved PAR polarity network that renders polarity axis specification resistant to variations in both the strength of upstream symmetry-breaking cues and PAR protein dosage. At the same time, we find that downstream pathways involved in cell size and fate asymmetry are similarly robust to dosage-dependent changes in the local concentrations of PAR proteins, implying non-trivial complexity in translating PAR signals into pathway outputs. We propose that “quantitative decoupling” of symmetry-breaking, polarity, and asymmetric division modules acts to suppress the accumulation of error as embryos move along this developmental trajectory, thereby ensuring that asymmetric division is robust to perturbation. Such modular organization of developmental networks is likely to be a general mechanism to achieve robust developmental outcomes.

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SAIBR: a simple, platform-independent method for spectral autofluorescence correction

Cited by 8 publications

References 49 publications

Cleavage furrow-directed cortical flows bias mechanochemical pathways for PAR polarization in theC. elegansgerm lineage

Cleavage furrow-directed cortical flows bias mechanochemical pathways for PAR polarization in theC. elegansgerm lineage

Design principles for selective polarization of PAR proteins by cortical flows

Nonlinear readout of spatial cues underlies robustness of asymmetric cell division

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