Spherical convolutions on molecular graphs for protein model quality
assessment
- URL: http://arxiv.org/abs/2011.07980v2
- Date: Wed, 6 Jan 2021 14:06:20 GMT
- Title: Spherical convolutions on molecular graphs for protein model quality
assessment
- Authors: Ilia Igashov (MIPT, NANO-D), Nikita Pavlichenko (MIPT), Sergei
Grudinin (NANO-D)
- Abstract summary: In this work, we propose Spherical Graph Convolutional Network (S-GCN) that processes 3D models of proteins represented as molecular graphs.
Within the framework of the protein model quality assessment problem, we demonstrate that the proposed spherical convolution method significantly improves the quality of model assessment.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Processing information on 3D objects requires methods stable to rigid-body
transformations, in particular rotations, of the input data. In image
processing tasks, convolutional neural networks achieve this property using
rotation-equivariant operations. However, contrary to images, graphs generally
have irregular topology. This makes it challenging to define a
rotation-equivariant convolution operation on these structures. In this work,
we propose Spherical Graph Convolutional Network (S-GCN) that processes 3D
models of proteins represented as molecular graphs. In a protein molecule,
individual amino acids have common topological elements. This allows us to
unambiguously associate each amino acid with a local coordinate system and
construct rotation-equivariant spherical filters that operate on angular
information between graph nodes. Within the framework of the protein model
quality assessment problem, we demonstrate that the proposed spherical
convolution method significantly improves the quality of model assessment
compared to the standard message-passing approach. It is also comparable to
state-of-the-art methods, as we demonstrate on Critical Assessment of Structure
Prediction (CASP) benchmarks. The proposed technique operates only on geometric
features of protein 3D models. This makes it universal and applicable to any
other geometric-learning task where the graph structure allows constructing
local coordinate systems.
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