This repository is no longer being maintained and has been archived for historical purposes.
There is a new version called DeepRank-GNN-esm which incorporates the ESM embeddings as replacement of the PSSM profile as features. This version is accessible from a separate repository here. Next to providing ESM features, it has the same functionalities as the original DeepRank-GNN version. For details refer to the following publication.
Next to that, there is a new DeepRank2 version, an improved and unified version of DeepRank-GNN, DeepRank, and DeepRank-Mut.
✨ DeepRank2 allows for transformation and storage of 3D representations of both protein-protein interfaces (PPIs) and protein single-residue variants (SRVs) into either graphs or volumetric grids containing structural and physico-chemical information. These can be used for training neural networks for a variety of patterns of interest, using either our pre-implemented training pipeline for graph neural networks (GNNs) or convolutional neural networks (CNNs) or external pipelines.
- 🔧 Pull Requests at github.com/DeepRank/deeprank2/pulls
- 🐛 Bugs: Reports of bugs can be filed agains our new repo github.com/DeepRank/deeprank2/issues
- ⭐ Feature Requests: Add your request or discuss the project w/ the community at github.com/DeepRank/deeprank2/issues
We look forward to seeing you in our new space - DeepRank2!
Before installing DeepRank-GNN you need to install pytorch_geometric according to your needs. You can find detailled instructions here :
- pytorch_geometric : https://pytorch-geometric.readthedocs.io/en/latest/notes/installation.html
By default the CPU version of pytorch will be installed but you can also customize that installation following the instructions at:
- pytorch : https://pytorch.org/
Once the dependencies installed, you can install the latest release of DeepRank-GNN using the PyPi package manager:
pip install DeepRank-GNN
Alternatively you can get all the new developments by cloning the repo and installing the code with
git clone https://github.com/DeepRank/Deeprank-GNN
cd DeepRank-GNN
pip install -e ./
The documentation can be found here : https://deeprank-gnn.readthedocs.io/
All the graphs/line graphs of all the pdb/pssm stored in data/pdb/ and data/pssm/ with the GenGraph.py script. This will generate the hdf5 file graph_residue.hdf5 which contains the graph of the different conformations.
from GraphGenMP import GraphHDF5
pdb_path = './data/pdb'
pssm_path = './data/pssm'
ref = './data/ref'
GraphHDF5(pdb_path=pdb_path,ref_path=ref,pssm_path=pssm_path,
graph_type='residue',outfile='graph_residue.hdf5')Using the graph interaction network is rather simple :
from deeprank_gnn.NeuralNet import NeuralNet
from deeprank_gnn.ginet import GINet
database = './hdf5/1ACB_residue.hdf5'
NN = NeuralNet(database, GINet,
node_feature=['type', 'polarity', 'bsa',
'depth', 'hse', 'ic', 'pssm'],
edge_feature=['dist'],
target='irmsd',
index=range(400),
batch_size=64,
percent=[0.8, 0.2])
NN.train(nepoch=250, validate=False)
NN.plot_scatter()It is also possible to define new network architecture and to specify the loss and optimizer to be used during the training.
def normalized_cut_2d(edge_index, pos):
row, col = edge_index
edge_attr = torch.norm(pos[row] - pos[col], p=2, dim=1)
return normalized_cut(edge_index, edge_attr, num_nodes=pos.size(0))
class CustomNet(torch.nn.Module):
def __init__(self):
super(Net, self).__init__()
self.conv1 = SplineConv(d.num_features, 32, dim=2, kernel_size=5)
self.conv2 = SplineConv(32, 64, dim=2, kernel_size=5)
self.fc1 = torch.nn.Linear(64, 128)
self.fc2 = torch.nn.Linear(128, 1)
def forward(self, data):
data.x = F.elu(self.conv1(data.x, data.edge_index, data.edge_attr))
weight = normalized_cut_2d(data.edge_index, data.pos)
cluster = graclus(data.edge_index, weight)
data = max_pool(cluster, data)
data.x = F.elu(self.conv2(data.x, data.edge_index, data.edge_attr))
weight = normalized_cut_2d(data.edge_index, data.pos)
cluster = graclus(data.edge_index, weight)
x, batch = max_pool_x(cluster, data.x, data.batch)
x = scatter_mean(x, batch, dim=0)
x = F.elu(self.fc1(x))
x = F.dropout(x, training=self.training)
return F.log_softmax(self.fc2(x), dim=1)
device = torch.device('cuda' if torch.cuda.is_available() else 'cpu')
model = NeuralNet(database, CustomNet,
node_feature=['type', 'polarity', 'bsa',
'depth', 'hse', 'ic', 'pssm'],
edge_feature=['dist'],
target='irmsd',
index=range(400),
batch_size=64,
percent=[0.8, 0.2])
model.optimizer = torch.optim.Adam(model.parameters(), lr=0.01)
model.loss = MSELoss()
model.train(nepoch=50)After installing h5xplorer (https://github.com/DeepRank/h5xplorer), you can execute the python file deeprank_gnn/h5x/h5x.py to explorer the connection graph used by DeepRank-GNN. The context menu (right click on the name of the structure) allows to automatically plot the graphs using plotly as shown below.
