High-symmetry ill-fitting subunits in 3D form aggregates of all dimensions

Elena N. Govorun; Martin Lenz

arxiv: 2604.01109 · v3 · pith:AUI7UPGGnew · submitted 2026-04-01 · ❄️ cond-mat.soft

High-symmetry ill-fitting subunits in 3D form aggregates of all dimensions

Elena N. Govorun , Martin Lenz This is my paper

Pith reviewed 2026-05-19 17:48 UTC · model grok-4.3

classification ❄️ cond-mat.soft

keywords self-assemblyprotein aggregatesfilament formationdeformable subunitsill-fitting objectsmorphology predictionthree-dimensional assembly

0 comments

The pith

Ill-fitting deformable subunits in three dimensions self-assemble into clusters, filaments, layers or bulks depending on adhesivity and elasticity.

A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.

The paper examines how identical but geometrically ill-fitting deformable subunits, meant to mimic globular proteins, come together in solution. Deformations accumulate with aggregate size and eventually limit further growth. The authors map the mechanics onto two incompatible interconnected networks to analytically predict the stable shapes that minimize energy. They show that zero-dimensional clusters, one-dimensional filaments, two-dimensional layers and three-dimensional bulks all arise as ground states for different values of adhesivity and elasticity. A reader cares because the result supplies a purely mechanical route to filament formation that does not require special molecular recognition.

Core claim

We analytically predict the ground state morphologies of the resulting aggregates as a function of the subunit adhesivity and elasticity by mapping their mechanics onto those of two incompatible, interconnected networks. We find that zero-dimensional clusters, three-dimensional bulks as well as symmetry-broken one-dimensional filaments and two-dimensional layers can all form depending on assembly parameters. Poorly compressible, moderately adhesive subunits favor filaments.

What carries the argument

Mapping subunit mechanics onto two incompatible, interconnected networks that analytically predicts ground-state morphologies from adhesivity and elasticity.

Load-bearing premise

The mechanics of the self-assembling subunits can be mapped onto those of two incompatible, interconnected networks to analytically predict ground state morphologies as a function of adhesivity and elasticity.

What would settle it

Molecular-dynamics runs in which compressibility and adhesivity are varied across the predicted boundary should show a switch from filaments to isotropic clusters; absence of that switch would falsify the mapping.

Figures

Figures reproduced from arXiv: 2604.01109 by Elena N. Govorun, Martin Lenz.

**Figure 1.** Figure 1: Illustration of a subunit geometry that gives rise to the continuum model studied here. Note that our continuum models is built on the basis of symmetry considerations and is thus not restricted to this specific design. (a) Case of well-adjusted subunits. Here each subunit is a cube with its vertices alternately colored yellow and red. The yellow set of points and the red set of points each form a regular … view at source ↗

**Figure 3.** Figure 3: Displacement and stress in two-dimensional slabs at mechanical equilibrium. (a) Difference in the displacements of the networks and (b) stress tensor element [PITH_FULL_IMAGE:figures/full_fig_p008_3.png] view at source ↗

**Figure 4.** Figure 4 [PITH_FULL_IMAGE:figures/full_fig_p012_4.png] view at source ↗

**Figure 4.** Figure 4: Incompressible subunits are very difficult to deform into a bulk, as indicated by the divergence of and as approaches at fixed and . 5 Asymptotic morphological transitions for near-incompressible subunits To provide more transparent expressions of the implicit aggregate energies given in Sec. 3, here we derive their explicit asymptotic forms in the incompressible limit. As shown in [PITH_FULL_IMAGE:figure… view at source ↗

read the original abstract

Proteins can combine into functional elements in living cells or self-assemble into unwanted structures in a number of diseases. The resulting aggregates often display filamentous morphologies across a large range of protein shapes and molecular interactions. This has led to the suggestion that filament formation could be a generic outcome of the aggregation of geometrically complex, ill-fitting objects, although such a mechanism has not been demonstrated in three dimensions. To address this problem, we theoretically study the self-assembly of three-dimensional identical, ill-fitting deformable subunits mimicking globular proteins in solution. In our model, self-assembling subunits incur deformations that accumulate as the aggregate size increases and can eventually hamper further assembly. We analytically predict the ground state morphologies of the resulting aggregates as a function of the subunit adhesivity and elasticity by mapping their mechanics onto those of two incompatible, interconnected networks. We find that zero-dimensional clusters, three-dimensional bulks as well as symmetry-broken one-dimensional filaments and two-dimensional layers can all form depending on assembly parameters. Poorly compressible, moderately adhesive subunits favor filaments. These findings hint at a generic pathway to control self-assembly in three dimensions and suggests that such mechanisms could be investigated in more realistic protein models.

Editorial analysis

A structured set of objections, weighed in public.

Desk editor's note, referee report, simulated authors' rebuttal, and a circularity audit. Tearing a paper down is the easy half of reading it; the pith above is the substance, this is the friction.

Desk Editor's Note private letter to a colleague

This paper analytically maps 3D ill-fitting subunits to incompatible networks to predict filament formation and other morphologies, but the mapping's handling of 3D strain needs close inspection.

read the letter

The punchline is that ill-fitting 3D subunits can form filaments, layers, clusters or bulks depending on adhesivity and elasticity, according to an analytical model. The paper does something new by taking the idea of filament formation from geometric mismatch and working it out in three dimensions. Previous work was limited to two dimensions or simulations. Here the authors use a mapping to two incompatible interconnected networks to predict the favored aggregate dimension as a function of how adhesive and how elastic the subunits are. This approach has the advantage of giving closed predictions without running large simulations for every parameter set. The result that poorly compressible and moderately adhesive subunits favor one-dimensional filaments comes out of balancing the energy costs in that mapped system. The main soft spot is whether that mapping accurately reflects the full three-dimensional geometry. Local deformations have to add up in a way that respects closure in all directions. If the network model simplifies the strain accumulation or misses some incompatibility constraints that only appear in 3D, the filament regime could be sensitive to that choice. The abstract does not report any direct comparison between the mapped energies and the original subunit Hamiltonian, so that check would strengthen the claim. This is for people who think about self-assembly in soft materials or biological aggregates. A reader who wants a simple rule for when filaments emerge from complex shapes will find the parameter dependence helpful as a guide. I would send this to peer review. The three-dimensional analytical treatment is a substantive step, and referees can sort out whether the mapping holds up under detailed scrutiny.

Referee Report

2 major / 2 minor

Summary. The manuscript theoretically studies the self-assembly of three-dimensional identical ill-fitting deformable subunits mimicking globular proteins. By mapping the mechanics of these subunits onto two incompatible interconnected networks, the authors analytically predict ground-state aggregate morphologies (zero-dimensional clusters, one-dimensional filaments, two-dimensional layers, and three-dimensional bulks) as a function of subunit adhesivity and elasticity, finding that poorly compressible, moderately adhesive subunits favor filaments.

Significance. If the mapping is rigorously validated, the work identifies a generic, parameter-controlled mechanism for dimension selection in 3D self-assembly of geometrically complex objects. This could explain the prevalence of filamentous protein aggregates across diverse molecular systems and provide a framework for designing or controlling assembly outcomes in soft-matter and biological contexts.

major comments (2)

[Network mapping and energy minimization] The central analytical mapping (described in the section on the network model and used to derive the morphology predictions) must be shown to reproduce the energy minima of the original 3D deformable-subunit Hamiltonian. Specifically, the mapping needs to demonstrate how local ill-fitting accumulates under full 3D geometric closure constraints rather than assuming additive pairwise strains or lower-dimensional networks; without this verification the selection of symmetry-broken filament states for poorly compressible, moderately adhesive subunits risks being an artifact of the reduction.
[Results on morphology dependence] The phase diagram or morphology selection as a function of adhesivity and elasticity (presented in the results) should include an explicit error analysis or sensitivity check on the network incompatibility parameters; the abstract states the mapping is 'analytical' yet the favored filament regime appears to depend on specific ranges of the two free parameters, requiring a clear statement of how ground states are identified without fitting.

minor comments (2)

Notation for adhesivity and elasticity should be defined consistently when first introduced and cross-referenced in any phase diagrams or tables.
The abstract would benefit from a one-sentence statement of the key assumption underlying the two-network mapping.

Simulated Author's Rebuttal

2 responses · 0 unresolved

We thank the referee for their careful reading of our manuscript and for the constructive comments, which help us clarify the foundations of our analytical mapping. We address each major comment below and indicate the revisions we will make.

read point-by-point responses

Referee: [Network mapping and energy minimization] The central analytical mapping (described in the section on the network model and used to derive the morphology predictions) must be shown to reproduce the energy minima of the original 3D deformable-subunit Hamiltonian. Specifically, the mapping needs to demonstrate how local ill-fitting accumulates under full 3D geometric closure constraints rather than assuming additive pairwise strains or lower-dimensional networks; without this verification the selection of symmetry-broken filament states for poorly compressible, moderately adhesive subunits risks being an artifact of the reduction.

Authors: The mapping is derived by projecting the local 3D geometric mismatch of the deformable subunits onto two orthogonal, interconnected networks whose incompatibility encodes the cumulative strain that arises when multiple subunits close into a 3D structure. Because the network energy is minimized globally subject to the connectivity constraints of the aggregate, the accumulation of ill-fitting is not treated as a simple sum of independent pairwise terms; the 3D closure is enforced through the requirement that the two networks remain compatible at every vertex. We will add an appendix that explicitly derives the network incompatibility parameters from the 3D subunit geometry and shows that the resulting energy expression reproduces the leading-order deformation cost of the original Hamiltonian for both open and closed clusters. This addition will make the non-artifactual character of the filament selection explicit. revision: yes
Referee: [Results on morphology dependence] The phase diagram or morphology selection as a function of adhesivity and elasticity (presented in the results) should include an explicit error analysis or sensitivity check on the network incompatibility parameters; the abstract states the mapping is 'analytical' yet the favored filament regime appears to depend on specific ranges of the two free parameters, requiring a clear statement of how ground states are identified without fitting.

Authors: Ground-state morphologies are identified by direct analytic minimization of the total network energy (adhesion plus elastic deformation) with respect to the possible aggregate topologies (0D cluster, 1D filament, 2D layer, 3D bulk). The two free parameters are the dimensionless adhesivity and the compressibility modulus; the filament regime is the region in which the energy minimum lies at a linear, symmetry-broken configuration. We will revise the results section to state the minimization procedure explicitly and to include a brief sensitivity analysis demonstrating that the boundaries of the filament regime shift only quantitatively, not qualitatively, under small variations of the incompatibility parameters. revision: yes

Circularity Check

0 steps flagged

Analytical mapping to incompatible networks is self-contained derivation

full rationale

The paper derives morphologies by mapping subunit deformations to two incompatible interconnected networks, then analytically predicting ground states (0D clusters, 1D filaments, 2D layers, 3D bulks) as functions of adhesivity and elasticity. No quoted equation or step reduces a claimed prediction to a fitted parameter or self-citation by construction; the mapping is introduced as an independent analytical step that encodes accumulation of deformations. The derivation remains self-contained against the model Hamiltonian without load-bearing self-citations or renaming of known results. This is the normal case of an honest theoretical construction.

Axiom & Free-Parameter Ledger

2 free parameters · 1 axioms · 0 invented entities

The model rests on deformation accumulation with aggregate size and the network-mapping approximation; adhesivity and elasticity act as tunable inputs rather than derived quantities.

free parameters (2)

subunit adhesivity
Controls binding strength and is varied to determine which morphology is favored.
subunit elasticity
Controls deformability and compressibility; poorly compressible case favors filaments.

axioms (1)

domain assumption Self-assembling subunits incur deformations that accumulate as the aggregate size increases and can eventually hamper further assembly.
Invoked to justify the mapping to incompatible networks and the existence of a ground-state morphology.

pith-pipeline@v0.9.0 · 5737 in / 1299 out tokens · 61110 ms · 2026-05-19T17:48:19.644130+00:00 · methodology

Review history (2 revisions) →

discussion (0)

Lean theorems connected to this paper

Citations machine-checked in the Pith Canon. Every link opens the source theorem in the public Lean library.

IndisputableMonolith/Foundation/AlexanderDuality.lean alexander_duality_circle_linking unclear

?

unclear
Relation between the paper passage and the cited Recognition theorem.

We analytically predict the ground state morphologies ... by mapping their mechanics onto those of two incompatible, interconnected networks.
IndisputableMonolith/Cost/FunctionalEquation.lean washburn_uniqueness_aczel unclear

?

unclear
Relation between the paper passage and the cited Recognition theorem.

Poorly compressible, moderately adhesive subunits favor filaments.

What do these tags mean?

matches: The paper's claim is directly supported by a theorem in the formal canon.
supports: The theorem supports part of the paper's argument, but the paper may add assumptions or extra steps.
extends: The paper goes beyond the formal theorem; the theorem is a base layer rather than the whole result.
uses: The paper appears to rely on the theorem as machinery.
contradicts: The paper's claim conflicts with a theorem or certificate in the canon.
unclear: Pith found a possible connection, but the passage is too broad, indirect, or ambiguous to say the theorem truly supports the claim.

Reference graph

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Aggregate morphology depending on normalized surface tension A morphological diagram of the aggregates can be presented in the coordinates and , where − is the normalized surface tension (Fig. S1). This diagram describes the same transitions as the diagram in the coordinates and in Sec. 4 (Fig. 3a), however its general view is different. Since the normali...

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[1] [1]

Mizrahi, R

I. Mizrahi, R. B ruinsma and J. Rudnick, Spanning tree model and the assembly kinetics of RNA viruses, Phys. Rev. E, 2022, 106, 044405

work page 2022

[2] [2]

L. E. Perotti, A. Aggarwal, J. Rudnick, R. Bruinsma, and W. S. Klug, Elasticity theory of the maturation of viral capsids, J. Mech. Phys. Solids, 2015, 77, 86

work page 2015

[3] [3]

J. D. Perlmutter and M. F. Hagan, Mechanisms of Virus Assembly, Annu. Rev. Phys. Chem. 2015, 66, 217

work page 2015

[4] [4]

R. F. Bruinsma and W. S. Klug, Physics of viral shells, Annu. Rev. Condens. Matter Phys. , 2015, 6, 245

work page 2015

[5] [5]

P. Alam, L. Bousset, R. Melki, and D. E. Otzen, α -synuclein oligomers and fibrils: a spectrum of species, a spectrum of toxicities, J. Neurochem., 2019, 150, 522

work page 2019

[6] [6]

Nelson and D

R. Nelson and D. Eisenberg, Recent atomic models of amyloid fibril structure, Curr. Opin. Struct. Biol., 2006, 16, 260

work page 2006

[7] [7]

Bousset, L

L. Bousset, L. Pieri, G. Ruiz-Arlandis, J. Gath, P. H. Jensen, B. Habenstein, K. Madiona, V. Olieric, A. Böckmann, B. H. Meier, and R. Melki, Structural and functional characterization of two alpha-synuclein strains, Nat. Commun., 2013, 4, 2575

work page 2013

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A. W . P. Fitzpatrick, B. Falcon, S. He, A. G. Murzin, G. Murshudov, H. J. Garringer, R. A. Crowther, B. Ghetti, M. Goedert, and S. H.W. Scheres, Cryo -EM structures of tau filaments from Alzheimer’s disease, Nature (London), 2017, 547, 185

work page 2017

[9] [9]

Eichner and S

T. Eichner and S. E . Radford, A diversity of assembly mechanisms of a generic amyloid fold, Mol. Cell, 2011, 43, 8

work page 2011

[10] [10]

A. W. P. Fitzpatrick, B. Falcon, S. He, A. G. Murzin, G. Murshudov, H. J. Garringer, R. A. Crowther, B. Ghetti, M. Goedert, and S. H.W. Scheres, Cryo -EM struct ures of tau filaments from Alzheimer’s disease, Nature (London), 2017, 547, 185

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W. A. Eaton and J. Hofrichter, Sickle cell haemoglobin polymerization, Adv. Protein Chem. , 1990, 40, 63

work page 1990

[12] [12]

M. F. Hagan and G. M. Grason, Equilibrium mechanisms of self -limiting assembly. Rev. Mod. Phys., 2021, 93, 025008

work page 2021

[13] [13]

V. N. Manoharan, Colloidal Matter: Packing, Geometry, and Entropy. Science, 2015, 349, 1253751

work page 2015

[14] [14]

Price, D

M. Price, D. Hayakawa, T. E. Videbæk, R. Saha, B. Tyukodi, S. Fraden, M. F. Hagan , G. M. Grason and W. B. Rogers, F rom toroids to helical tubules: Kirigami -inspired programmable assembly of two -periodic curved crystals from DNA origami, Proc. Natl. Acad. Sci. U.S.A., 2025, 122, e2516695122

work page 2025

[15] [15]

T. E. Videbæk, H. Fang, D. Hayakawa, B. Tyukodi, M. F. Hagan and W. B. Rogers, Tiling a tubule: How increasing complexity improves the yield of self -limited assembly, J. Phys. Condens. Matter, 2022, 34, 134003

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Aggregate morphology depending on normalized surface tension A morphological diagram of the aggregates can be presented in the coordinates and , where − is the normalized surface tension (Fig. S1). This diagram describes the same transitions as the diagram in the coordinates and in Sec. 4 (Fig. 3a), however its general view is different. Since the normali...

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Asymptotic energy for aggregates of near-incompressible subunits In Sec 5 we analyze asymptotic morphological transitions between slabs and filaments and between filaments and spheres in the limit of highly incompressible subunits ( ),. In this case the characteristic length scale is diverges (Fig. 4) and displacement gradients can be approximated as cons...

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