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Scaling single-cell genomics from phenomenology to mechanism

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Abstract

Three of the most fundamental questions in biology are how individual cells differentiate to form tissues, how tissues function in a coordinated and flexible fashion and which gene regulatory mechanisms support these processes. Single-cell genomics is opening up new ways to tackle these questions by combining the comprehensive nature of genomics with the microscopic resolution that is required to describe complex multicellular systems. Initial single-cell genomic studies provided a remarkably rich phenomenology of heterogeneous cellular states, but transforming observational studies into models of dynamics and causal mechanisms in tissues poses fresh challenges and requires stronger integration of theoretical, computational and experimental frameworks.

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Figure 1: The temporal axis.
Figure 2: The spatial axis.
Figure 3: The mechanism axis.

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Acknowledgements

We thank L. Gaffney for help with artwork. A.R. is a Howard Hughes Medical Institute investigator. A.T. is a Kimmel investigator and is supported by the Flight Attendant Medical Research Institute and the European Research Council.

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Correspondence to Amos Tanay or Aviv Regev.

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A.R. is a member of the scientific advisory boards of Thermo Fisher Scientific and Syros Pharmaceuticals and is a consultant to the Driver Group.

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Tanay, A., Regev, A. Scaling single-cell genomics from phenomenology to mechanism. Nature 541, 331–338 (2017). https://doi.org/10.1038/nature21350

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