Human interpretable grammar encodes multicellular systems biology models to democratize virtual cell laboratories

Jeanette A.I. Johnson; Daniel R. Bergman; Heber L. Rocha; David L. Zhou; Eric Cramer; Ian C. Mclean; Yoseph W. Dance; Max Booth; Zachary Nicholas; Tamara Lopez-Vidal; Atul Deshpande; Randy Heiland; Elmar Bucher; Fatemeh Shojaeian; Matthew Dunworth; André Forjaz; Michael Getz; Inês Godet; Furkan Kurtoglu; Melissa Lyman; John Metzcar; Jacob T. Mitchell; Andrew Raddatz; Jacobo Solorzano; Aneequa Sundus; Yafei Wang; David G. DeNardo; Andrew J. Ewald; Daniele M. Gilkes; Luciane T. Kagohara; Ashley L. Kiemen; Elizabeth D. Thompson; Denis Wirtz; Laura D. Wood; Pei Hsun Wu; Neeha Zaidi; Lei Zheng; Jacquelyn W. Zimmerman; Jude M. Phillip; Elizabeth M. Jaffee; Joe W. Gray; Lisa M. Coussens; Young Hwan Chang; Laura M. Heiser; Genevieve L. Stein-O'Brien; Elana J. Fertig; Paul Macklin

doi:10.1016/j.cell.2025.06.048

Human interpretable grammar encodes multicellular systems biology models to democratize virtual cell laboratories

Jeanette A.I. Johnson
, Daniel R. Bergman
, Heber L. Rocha
, David L. Zhou
, Eric Cramer
, Ian C. Mclean
, Yoseph W. Dance
, Max Booth
, Zachary Nicholas
, Tamara Lopez-Vidal
, Atul Deshpande
, Randy Heiland
, Elmar Bucher
, Fatemeh Shojaeian
, Matthew Dunworth
, André Forjaz
, Michael Getz
, Inês Godet
, Furkan Kurtoglu
, Melissa Lyman

John Metzcar, Jacob T. Mitchell, Andrew Raddatz, Jacobo Solorzano, Aneequa Sundus, Yafei Wang, David G. DeNardo, Andrew J. Ewald, Daniele M. Gilkes, Luciane T. Kagohara, Ashley L. Kiemen, Elizabeth D. Thompson, Denis Wirtz, Laura D. Wood, Pei Hsun Wu, Neeha Zaidi, Lei Zheng, Jacquelyn W. Zimmerman, Jude M. Phillip, Elizabeth M. Jaffee, Joe W. Gray, Lisa M. Coussens, Young Hwan Chang, Laura M. Heiser, Genevieve L. Stein-O'Brien, Elana J. Fertig, Paul Macklin

Research output: Contribution to journal › Article › peer-review

10 Scopus citations

Abstract

Cells interact as dynamically evolving ecosystems. While recent single-cell and spatial multi-omics technologies quantify individual cell characteristics, predicting their evolution requires mathematical modeling. We propose a conceptual framework—a cell behavior hypothesis grammar—that uses natural language statements (cell rules) to create mathematical models. This enables systematic integration of biological knowledge and multi-omics data to generate in silico models, enabling virtual “thought experiments” that test and expand our understanding of multicellular systems and generate new testable hypotheses. This paper motivates and describes the grammar, offers a reference implementation, and demonstrates its use in developing both de novo mechanistic models and those informed by multi-omics data. We show its potential through examples in cancer and its broader applicability in simulating brain development. This approach bridges biological, clinical, and systems biology research for mathematical modeling at scale, allowing the community to predict emergent multicellular behavior.

Original language	English
Pages (from-to)	4711-4733.e37
Journal	Cell
Volume	188
Issue number	17
DOIs	https://doi.org/10.1016/j.cell.2025.06.048
State	Published - Aug 21 2025

Keywords

agent-based modeling
cancer biology
cell behavior hypothesis grammar
cell behaviors
cell interactions
immunology
immunotherapy
mathematical biology
mathematical modeling
modeling language
multi-omics
multicellular systems
multicellular systems biology
physics of multicellular biology
simulation
spatial transcriptomics
tissue dynamics

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10.1016/j.cell.2025.06.048

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Johnson, J. A. I., Bergman, D. R., Rocha, H. L., Zhou, D. L., Cramer, E., Mclean, I. C., Dance, Y. W., Booth, M., Nicholas, Z., Lopez-Vidal, T., Deshpande, A., Heiland, R., Bucher, E., Shojaeian, F., Dunworth, M., Forjaz, A., Getz, M., Godet, I., Kurtoglu, F., ... Macklin, P. (2025). Human interpretable grammar encodes multicellular systems biology models to democratize virtual cell laboratories. Cell, 188(17), 4711-4733.e37. https://doi.org/10.1016/j.cell.2025.06.048

@article{0dd3d4c0cc8c45019e3b2a040af2d61f,

title = "Human interpretable grammar encodes multicellular systems biology models to democratize virtual cell laboratories",

abstract = "Cells interact as dynamically evolving ecosystems. While recent single-cell and spatial multi-omics technologies quantify individual cell characteristics, predicting their evolution requires mathematical modeling. We propose a conceptual framework—a cell behavior hypothesis grammar—that uses natural language statements (cell rules) to create mathematical models. This enables systematic integration of biological knowledge and multi-omics data to generate in silico models, enabling virtual “thought experiments” that test and expand our understanding of multicellular systems and generate new testable hypotheses. This paper motivates and describes the grammar, offers a reference implementation, and demonstrates its use in developing both de novo mechanistic models and those informed by multi-omics data. We show its potential through examples in cancer and its broader applicability in simulating brain development. This approach bridges biological, clinical, and systems biology research for mathematical modeling at scale, allowing the community to predict emergent multicellular behavior.",

keywords = "agent-based modeling, cancer biology, cell behavior hypothesis grammar, cell behaviors, cell interactions, immunology, immunotherapy, mathematical biology, mathematical modeling, modeling language, multi-omics, multicellular systems, multicellular systems biology, physics of multicellular biology, simulation, spatial transcriptomics, tissue dynamics",

author = "Johnson, \{Jeanette A.I.\} and Bergman, \{Daniel R.\} and Rocha, \{Heber L.\} and Zhou, \{David L.\} and Eric Cramer and Mclean, \{Ian C.\} and Dance, \{Yoseph W.\} and Max Booth and Zachary Nicholas and Tamara Lopez-Vidal and Atul Deshpande and Randy Heiland and Elmar Bucher and Fatemeh Shojaeian and Matthew Dunworth and Andr{\'e} Forjaz and Michael Getz and In{\^e}s Godet and Furkan Kurtoglu and Melissa Lyman and John Metzcar and Mitchell, \{Jacob T.\} and Andrew Raddatz and Jacobo Solorzano and Aneequa Sundus and Yafei Wang and DeNardo, \{David G.\} and Ewald, \{Andrew J.\} and Gilkes, \{Daniele M.\} and Kagohara, \{Luciane T.\} and Kiemen, \{Ashley L.\} and Thompson, \{Elizabeth D.\} and Denis Wirtz and Wood, \{Laura D.\} and Wu, \{Pei Hsun\} and Neeha Zaidi and Lei Zheng and Zimmerman, \{Jacquelyn W.\} and Phillip, \{Jude M.\} and Jaffee, \{Elizabeth M.\} and Gray, \{Joe W.\} and Coussens, \{Lisa M.\} and Chang, \{Young Hwan\} and Heiser, \{Laura M.\} and Stein-O'Brien, \{Genevieve L.\} and Fertig, \{Elana J.\} and Paul Macklin",

note = "Publisher Copyright: {\textcopyright} 2025 The Authors",

year = "2025",

month = aug,

day = "21",

doi = "10.1016/j.cell.2025.06.048",

language = "English",

volume = "188",

pages = "4711--4733.e37",

journal = "Cell",

issn = "0092-8674",

number = "17",

}

Johnson, JAI, Bergman, DR, Rocha, HL, Zhou, DL, Cramer, E, Mclean, IC, Dance, YW, Booth, M, Nicholas, Z, Lopez-Vidal, T, Deshpande, A, Heiland, R, Bucher, E, Shojaeian, F, Dunworth, M, Forjaz, A, Getz, M, Godet, I, Kurtoglu, F, Lyman, M, Metzcar, J, Mitchell, JT, Raddatz, A, Solorzano, J, Sundus, A, Wang, Y, DeNardo, DG, Ewald, AJ, Gilkes, DM, Kagohara, LT, Kiemen, AL, Thompson, ED, Wirtz, D, Wood, LD, Wu, PH, Zaidi, N, Zheng, L, Zimmerman, JW, Phillip, JM, Jaffee, EM, Gray, JW, Coussens, LM, Chang, YH, Heiser, LM, Stein-O'Brien, GL, Fertig, EJ & Macklin, P 2025, 'Human interpretable grammar encodes multicellular systems biology models to democratize virtual cell laboratories', Cell, vol. 188, no. 17, pp. 4711-4733.e37. https://doi.org/10.1016/j.cell.2025.06.048

TY - JOUR

T1 - Human interpretable grammar encodes multicellular systems biology models to democratize virtual cell laboratories

AU - Johnson, Jeanette A.I.

AU - Bergman, Daniel R.

AU - Rocha, Heber L.

AU - Zhou, David L.

AU - Cramer, Eric

AU - Mclean, Ian C.

AU - Dance, Yoseph W.

AU - Booth, Max

AU - Nicholas, Zachary

AU - Lopez-Vidal, Tamara

AU - Deshpande, Atul

AU - Heiland, Randy

AU - Bucher, Elmar

AU - Shojaeian, Fatemeh

AU - Dunworth, Matthew

AU - Forjaz, André

AU - Getz, Michael

AU - Godet, Inês

AU - Kurtoglu, Furkan

AU - Lyman, Melissa

AU - Metzcar, John

AU - Mitchell, Jacob T.

AU - Raddatz, Andrew

AU - Solorzano, Jacobo

AU - Sundus, Aneequa

AU - Wang, Yafei

AU - DeNardo, David G.

AU - Ewald, Andrew J.

AU - Gilkes, Daniele M.

AU - Kagohara, Luciane T.

AU - Kiemen, Ashley L.

AU - Thompson, Elizabeth D.

AU - Wirtz, Denis

AU - Wood, Laura D.

AU - Wu, Pei Hsun

AU - Zaidi, Neeha

AU - Zheng, Lei

AU - Zimmerman, Jacquelyn W.

AU - Phillip, Jude M.

AU - Jaffee, Elizabeth M.

AU - Gray, Joe W.

AU - Coussens, Lisa M.

AU - Chang, Young Hwan

AU - Heiser, Laura M.

AU - Stein-O'Brien, Genevieve L.

AU - Fertig, Elana J.

AU - Macklin, Paul

PY - 2025/8/21

Y1 - 2025/8/21

N2 - Cells interact as dynamically evolving ecosystems. While recent single-cell and spatial multi-omics technologies quantify individual cell characteristics, predicting their evolution requires mathematical modeling. We propose a conceptual framework—a cell behavior hypothesis grammar—that uses natural language statements (cell rules) to create mathematical models. This enables systematic integration of biological knowledge and multi-omics data to generate in silico models, enabling virtual “thought experiments” that test and expand our understanding of multicellular systems and generate new testable hypotheses. This paper motivates and describes the grammar, offers a reference implementation, and demonstrates its use in developing both de novo mechanistic models and those informed by multi-omics data. We show its potential through examples in cancer and its broader applicability in simulating brain development. This approach bridges biological, clinical, and systems biology research for mathematical modeling at scale, allowing the community to predict emergent multicellular behavior.

AB - Cells interact as dynamically evolving ecosystems. While recent single-cell and spatial multi-omics technologies quantify individual cell characteristics, predicting their evolution requires mathematical modeling. We propose a conceptual framework—a cell behavior hypothesis grammar—that uses natural language statements (cell rules) to create mathematical models. This enables systematic integration of biological knowledge and multi-omics data to generate in silico models, enabling virtual “thought experiments” that test and expand our understanding of multicellular systems and generate new testable hypotheses. This paper motivates and describes the grammar, offers a reference implementation, and demonstrates its use in developing both de novo mechanistic models and those informed by multi-omics data. We show its potential through examples in cancer and its broader applicability in simulating brain development. This approach bridges biological, clinical, and systems biology research for mathematical modeling at scale, allowing the community to predict emergent multicellular behavior.

KW - agent-based modeling

KW - cancer biology

KW - cell behavior hypothesis grammar

KW - cell behaviors

KW - cell interactions

KW - immunology

KW - immunotherapy

KW - mathematical biology

KW - mathematical modeling

KW - modeling language

KW - multi-omics

KW - multicellular systems

KW - multicellular systems biology

KW - physics of multicellular biology

KW - simulation

KW - spatial transcriptomics

KW - tissue dynamics

UR - https://www.scopus.com/pages/publications/105011743325

U2 - 10.1016/j.cell.2025.06.048

DO - 10.1016/j.cell.2025.06.048

M3 - Article

C2 - 40713951

AN - SCOPUS:105011743325

SN - 0092-8674

VL - 188

SP - 4711-4733.e37

JO - Cell

JF - Cell

IS - 17

ER -

Human interpretable grammar encodes multicellular systems biology models to democratize virtual cell laboratories

Abstract

Keywords

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