Single-cell 3D genome reconstruction in the haploid setting using rigidity theory

Sean Dewar; Georg Grasegger; Kaie Kubjas; Fatemeh Mohammadi; Anthony Nixon

doi:10.1007/s00285-025-02203-2

Single-cell 3D genome reconstruction in the haploid setting using rigidity theory

Sean Dewar, Georg Grasegger, Kaie Kubjas^*, Fatemeh Mohammadi, Anthony Nixon

^*Corresponding author for this work

School of Mathematics

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

1 Citation (Scopus)

Abstract

This article considers the problem of 3-dimensional genome reconstruction for single-cell data, and the uniqueness of such reconstructions in the setting of haploid organisms. We consider multiple graph models as representations of this problem, and use techniques from graph rigidity theory to determine identifiability. Biologically, our models come from Hi-C data, microscopy data, and combinations thereof. Mathematically, we use unit ball and sphere packing models, as well as models consisting of distance and inequality constraints. In each setting, we describe and/or derive new results on realisability and uniqueness. We then propose a 3D reconstruction method based on semidefinite programming and apply it to synthetic and real data sets using our models.

Original language	English
Article number	45
Number of pages	37
Journal	Journal of Mathematical Biology
Volume	90
Issue number	4
Early online date	29 Mar 2025
DOIs	https://doi.org/10.1007/s00285-025-02203-2
Publication status	Published - 1 Apr 2025

Bibliographical note

Publisher Copyright:
© The Author(s) 2025.

Keywords

92E10
52C25
Semidefinite programming
3D genome reconstruction
Hi-C
Rigidity

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title = "Single-cell 3D genome reconstruction in the haploid setting using rigidity theory",

abstract = "This article considers the problem of 3-dimensional genome reconstruction for single-cell data, and the uniqueness of such reconstructions in the setting of haploid organisms. We consider multiple graph models as representations of this problem, and use techniques from graph rigidity theory to determine identifiability. Biologically, our models come from Hi-C data, microscopy data, and combinations thereof. Mathematically, we use unit ball and sphere packing models, as well as models consisting of distance and inequality constraints. In each setting, we describe and/or derive new results on realisability and uniqueness. We then propose a 3D reconstruction method based on semidefinite programming and apply it to synthetic and real data sets using our models.",

keywords = "92E10, 52C25, Semidefinite programming, 3D genome reconstruction, Hi-C, Rigidity",

author = "Sean Dewar and Georg Grasegger and Kaie Kubjas and Fatemeh Mohammadi and Anthony Nixon",

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T1 - Single-cell 3D genome reconstruction in the haploid setting using rigidity theory

AU - Dewar, Sean

AU - Grasegger, Georg

AU - Kubjas, Kaie

AU - Mohammadi, Fatemeh

AU - Nixon, Anthony

N1 - Publisher Copyright: © The Author(s) 2025.

PY - 2025/4/1

Y1 - 2025/4/1

N2 - This article considers the problem of 3-dimensional genome reconstruction for single-cell data, and the uniqueness of such reconstructions in the setting of haploid organisms. We consider multiple graph models as representations of this problem, and use techniques from graph rigidity theory to determine identifiability. Biologically, our models come from Hi-C data, microscopy data, and combinations thereof. Mathematically, we use unit ball and sphere packing models, as well as models consisting of distance and inequality constraints. In each setting, we describe and/or derive new results on realisability and uniqueness. We then propose a 3D reconstruction method based on semidefinite programming and apply it to synthetic and real data sets using our models.

AB - This article considers the problem of 3-dimensional genome reconstruction for single-cell data, and the uniqueness of such reconstructions in the setting of haploid organisms. We consider multiple graph models as representations of this problem, and use techniques from graph rigidity theory to determine identifiability. Biologically, our models come from Hi-C data, microscopy data, and combinations thereof. Mathematically, we use unit ball and sphere packing models, as well as models consisting of distance and inequality constraints. In each setting, we describe and/or derive new results on realisability and uniqueness. We then propose a 3D reconstruction method based on semidefinite programming and apply it to synthetic and real data sets using our models.

KW - 92E10

KW - 52C25

KW - Semidefinite programming

KW - 3D genome reconstruction

KW - Hi-C

KW - Rigidity

U2 - 10.1007/s00285-025-02203-2

DO - 10.1007/s00285-025-02203-2

M3 - Article (Academic Journal)

C2 - 40156641

SN - 0303-6812

VL - 90

JO - Journal of Mathematical Biology

JF - Journal of Mathematical Biology

IS - 4

M1 - 45

ER -

Single-cell 3D genome reconstruction in the haploid setting using rigidity theory

Abstract

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Keywords

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