PHLOWER leverages single-cell multimodal data to infer complex, multi-branching cell differentiation trajectories

Mingbo Cheng; Jitske Jansen; Katharina C. Reimer; Vincent P. Grande; James S. Nagai; Zhijian Li; Paul Kießling; Martin Grasshoff; Christoph Kuppe; Michael T. Schaub; Rafael Kramann; Ivan G. Costa

doi:10.1038/s41592-025-02870-5

PHLOWER leverages single-cell multimodal data to infer complex, multi-branching cell differentiation trajectories

Mingbo Cheng
, Jitske Jansen
, Katharina C. Reimer
, Vincent P. Grande
, James S. Nagai
, Zhijian Li
, Paul Kießling
, Martin Grasshoff
, Christoph Kuppe
, Michael T. Schaub
, Rafael Kramann^*
, Ivan G. Costa^*

^*Corresponding author for this work

Internal Medicine

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

1 Citation (Scopus)

Abstract

Computational trajectory analysis is a key computational task for inferring differentiation trees from this single-cell data. An open challenge is the prediction of complex and multi-branching trees from multimodal data. To address these challenges, we present PHLOWER (decomposition of the Hodge Laplacian for inferring trajectories from flows of cell differentiation), which leverages the harmonic component of the Hodge decomposition on simplicial complexes to infer trajectory embeddings from single-cell multimodal data. These natural representations of cell differentiation facilitate the estimation of their underlying differentiation trees. We evaluate PHLOWER through benchmarking with multi-branching differentiation trees and using kidney organoid multimodal and spatial single-cell data. These demonstrate the power of PHLOWER in both the inference of complex trees and the identification of transcription factors regulating off-target cells in kidney organoids. Thus, PHLOWER enables inference of complex branching trajectories and prediction of transcriptional regulators by leveraging multimodal data.

Original language	English
Pages (from-to)	2328-2336
Number of pages	9
Journal	Nature Methods
Volume	22
Issue number	11
DOIs	https://doi.org/10.1038/s41592-025-02870-5
Publication status	Published - Nov 2025

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PHLOWER leverages single-cell multimodal data to infer complex, multi-branching cell differentiation trajectoriesFinal published version, 33.6 MBLicence: CC BY

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title = "PHLOWER leverages single-cell multimodal data to infer complex, multi-branching cell differentiation trajectories",

abstract = "Computational trajectory analysis is a key computational task for inferring differentiation trees from this single-cell data. An open challenge is the prediction of complex and multi-branching trees from multimodal data. To address these challenges, we present PHLOWER (decomposition of the Hodge Laplacian for inferring trajectories from flows of cell differentiation), which leverages the harmonic component of the Hodge decomposition on simplicial complexes to infer trajectory embeddings from single-cell multimodal data. These natural representations of cell differentiation facilitate the estimation of their underlying differentiation trees. We evaluate PHLOWER through benchmarking with multi-branching differentiation trees and using kidney organoid multimodal and spatial single-cell data. These demonstrate the power of PHLOWER in both the inference of complex trees and the identification of transcription factors regulating off-target cells in kidney organoids. Thus, PHLOWER enables inference of complex branching trajectories and prediction of transcriptional regulators by leveraging multimodal data.",

author = "Mingbo Cheng and Jitske Jansen and Reimer, \{Katharina C.\} and Grande, \{Vincent P.\} and Nagai, \{James S.\} and Zhijian Li and Paul Kie{\ss}ling and Martin Grasshoff and Christoph Kuppe and Schaub, \{Michael T.\} and Rafael Kramann and Costa, \{Ivan G.\}",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025.",

year = "2025",

month = nov,

doi = "10.1038/s41592-025-02870-5",

language = "English",

volume = "22",

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T1 - PHLOWER leverages single-cell multimodal data to infer complex, multi-branching cell differentiation trajectories

AU - Cheng, Mingbo

AU - Jansen, Jitske

AU - Reimer, Katharina C.

AU - Grande, Vincent P.

AU - Nagai, James S.

AU - Li, Zhijian

AU - Kießling, Paul

AU - Grasshoff, Martin

AU - Kuppe, Christoph

AU - Schaub, Michael T.

AU - Kramann, Rafael

AU - Costa, Ivan G.

PY - 2025/11

Y1 - 2025/11

N2 - Computational trajectory analysis is a key computational task for inferring differentiation trees from this single-cell data. An open challenge is the prediction of complex and multi-branching trees from multimodal data. To address these challenges, we present PHLOWER (decomposition of the Hodge Laplacian for inferring trajectories from flows of cell differentiation), which leverages the harmonic component of the Hodge decomposition on simplicial complexes to infer trajectory embeddings from single-cell multimodal data. These natural representations of cell differentiation facilitate the estimation of their underlying differentiation trees. We evaluate PHLOWER through benchmarking with multi-branching differentiation trees and using kidney organoid multimodal and spatial single-cell data. These demonstrate the power of PHLOWER in both the inference of complex trees and the identification of transcription factors regulating off-target cells in kidney organoids. Thus, PHLOWER enables inference of complex branching trajectories and prediction of transcriptional regulators by leveraging multimodal data.

AB - Computational trajectory analysis is a key computational task for inferring differentiation trees from this single-cell data. An open challenge is the prediction of complex and multi-branching trees from multimodal data. To address these challenges, we present PHLOWER (decomposition of the Hodge Laplacian for inferring trajectories from flows of cell differentiation), which leverages the harmonic component of the Hodge decomposition on simplicial complexes to infer trajectory embeddings from single-cell multimodal data. These natural representations of cell differentiation facilitate the estimation of their underlying differentiation trees. We evaluate PHLOWER through benchmarking with multi-branching differentiation trees and using kidney organoid multimodal and spatial single-cell data. These demonstrate the power of PHLOWER in both the inference of complex trees and the identification of transcription factors regulating off-target cells in kidney organoids. Thus, PHLOWER enables inference of complex branching trajectories and prediction of transcriptional regulators by leveraging multimodal data.

UR - https://www.scopus.com/pages/publications/105019519937

U2 - 10.1038/s41592-025-02870-5

DO - 10.1038/s41592-025-02870-5

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AN - SCOPUS:105019519937

SN - 1548-7091

VL - 22

SP - 2328

EP - 2336

JO - Nature Methods

JF - Nature Methods

IS - 11

ER -

PHLOWER leverages single-cell multimodal data to infer complex, multi-branching cell differentiation trajectories

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