Imaging cellular activity simultaneously across all organs of a vertebrate reveals body-wide circuits

  1. Virginia M. S. Ruetten
  2. Wei Zheng
  3. Igor Siwanowicz
  4. Brett D. Mensh
  5. Mark Eddison
  6. Amy Hu
  7. Yunfeng Chi
  8. Andrew L. Lemire
  9. Caiying Guo
  10. Mykola Kadobianskyi
  11. Marc Renz
  12. Sara Lelek-Greskovic
  13. Yisheng He
  14. Kari Close
  15. Gudrun Ihrke
  16. Aparna Dev
  17. Alyson Petruncio
  18. Yinan Wan
  19. Florian Engert
  20. Mark C. Fishman
  21. Benjamin Judkewitz
  22. Mikail Rubinov
  23. Philipp J. Keller
  24. Chie Satou
  25. Guoqiang Yu
  26. Paul W. Tillberg
  27. Maneesh Sahani
  28. Misha B. Ahrens
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Abstract

All cells in an animal collectively ensure, moment-to-moment, the survival of the whole organism in the face of environmental stressors1,2. Physiology seeks to elucidate the intricate network of interactions that sustain life, which often span multiple organs, cell types, and timescales, but a major challenge lies in the inability to simultaneously record time-varying cellular activity throughout the entire body.

We developed WHOLISTIC, a method to image second-timescale, time-varying intracellular dynamics across cell-types of the vertebrate body. By advancing and integrating volumetric fluorescence microscopy, machine learning, and pancellular transgenic expression of calcium sensors in transparent young Danio rerio (zebrafish) and adult Danionella, the method enables real-time recording of cellular dynamics across the organism. Calcium is a universal intracellular messenger, with a large array of cellular processes depending on changes in calcium concentration across varying time-scales, making it an ideal proxy of cellular activity3.

Using this platform to screen the dynamics of all cells in the body, we discovered unexpected responses of specific cell types to stimuli, such as chondrocyte reactions to cold, meningeal responses to ketamine, and state-dependent activity, such as oscillatory ependymal-cell activity during periods of extended motor quiescence. At the organ scale, the method uncovered pulsating traveling waves along the kidney nephron. At the multi-organ scale, we uncovered muscle synergies and independencies, as well as muscle-organ interactions. Integration with optogenetics allowed us to all-optically determine the causal direction of brain-body interactions. At the whole-organism scale, the method captured the rapid brainstem-controlled redistribution of blood flow across the body.

Finally, we advanced Whole-Body Expansion Microscopy4 to provide ground-truth molecular and ultrastructural anatomical context, explaining the spatiotemporal structure of activity captured by WHOLISTIC. Together, these innovations establish a new paradigm for systems biology, bridging cellular and organismal physiology, with broad implications for both fundamental research and drug discovery.

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