Metadata-Version: 2.4
Name: afpdb
Version: 0.3.0
Summary: A Numpy-based PDB structure manipulation package
Home-page: https://github.com/data2code/afpdb
Author: Yingyao Zhou
Author-email: yingyao.zhou@novartis.com
License: MIT
Project-URL: homepage, https://github.com/data2code/afpdb
Project-URL: documentation, https://github.com/data2code/afpdb/tutorial
Project-URL: issues, https://github.com/data2code/afpdb/issues
Classifier: Development Status :: 5 - Production/Stable
Classifier: Intended Audience :: Science/Research
Classifier: License :: OSI Approved :: MIT License
Classifier: Operating System :: POSIX :: Linux
Classifier: Programming Language :: Python :: 3.7
Requires-Python: >=3.7
Description-Content-Type: text/markdown
License-File: LICENSE
Requires-Dist: pandas
Requires-Dist: numpy
Requires-Dist: scipy
Requires-Dist: biopython
Requires-Dist: dm-tree
Requires-Dist: py3Dmol
Requires-Dist: tabulate
Requires-Dist: requests
Dynamic: author
Dynamic: author-email
Dynamic: classifier
Dynamic: home-page
Dynamic: license
Dynamic: license-file
Dynamic: requires-dist
Dynamic: requires-python
Dynamic: summary

# Afpdb - An Efficient Protein Structure Manipulation Tool

<a href="https://pypi.org/project/afpdb" rel="nofollow">
<img alt="PyPI - Version" src="https://img.shields.io/pypi/v/afpdb?logo=pypi">
</a>
<a href="https://anaconda.org/bioconda/afpdb" rel="nofollow">
<img alt="Conda Version" src="https://img.shields.io/conda/vn/bioconda/afpdb">
</a>

The advent of AlphaFold and other protein AI models has transformed protein design, necessitating efficient handling of large-scale data and complex workflows. Traditional programming packages, developed before these AI advancements, often lead to inefficiencies in coding and slow execution. To bridge this gap, we introduce Afpdb, a high-performance Python module built on AlphaFold’s NumPy architecture. Afpdb leverages RFDiffusion's contig syntax to streamline residue and atom selection, making coding simpler and more readable. By integrating PyMOL’s visualization capabilities, Afpdb enables automatic visual quality control, enhancing productivity in structural biology. With over 190 methods commonly used in protein AI design, Afpdb supports the development of concise, high-performance code, addressing the limitations of existing tools like Biopython. Afpdb is designed to complement powerful AI models such as AlphaFold and ProteinMPNN, providing the additional utility needed to effectively manipulate protein structures and drive innovation in protein design.

Automatic chain alignment, antibody analysis, simplified PyMOL visualization for multiple protein objects, and many methods have been added in version 0.3. The algorithm to identify gaps within a chain are improved to minimize false gaps. Tests, docstring, and argument typing are improved to help Github Coplit to understand the module better. To explore these new features, please search for the tag "#2025JUL" in the Notebook or tutorial documentation.

Please read our short artical published in <a href="https://doi.org/10.1093/bioinformatics/btae654">Bioinformatics</a>.

<img src="https://github.com/data2code/afpdb/blob/main/tutorial/img/afpdb.png?raw=true">

## Tutorial

The tutorial book is availabe in <a href="tutorial/Afpdb_Tutorial.pdf">PDF</a>.

The best way to learn and practice Afpdb is to open [Tutorial Notebook](https://colab.research.google.com/github/data2code/afpdb/blob/main/tutorial/afpdb.ipynb) in Google Colab.

Table of Content

1. Demo
2. Fundamental Concepts
   - Internal Data Structure
   - Contig 
3. Selection
   - Atom Selection
   - Residue Selection
   - Residue List
4. Read/Write
  - PDB Information
5. Sequence & Chain
  - Extarction
  - Missing Residues
  - REsidue Numbering
6. Geometry, Measurement, & Visualization
   - Select Neighboring Residues
   - Display
   - B-factors
   - PyMOL Interface
   - PyMOL3D Display
   - RMSD
   - Solvent-Accessible Surface Area (SASA)
   - Secondary Structures - DSSP
   - Bond Length
   - Internal Coordinates
7. Object Manipulation
   - Move Objects
   - Align
   - Automatic Chain Mapping & Alignment
   - Split & Merge Objects
8. Antibodies
   - CDR Identification
   - CDR Visualization
   - scFv Analysis
9. Parsers for AI Models

## AI Use Cases

Interested in applying Afpdb to AI protein design? Open [AI Use Case Notebook](https://colab.research.google.com/github/data2code/afpdb/blob/main/tutorial/AI.ipynb) in Google Colab.

Table of Content

- Example AI Protein Design Use Cases
   - Handle Missing Residues in AlphaFold Prediction
   - Structure Prediction with ESMFold
   - Create Side Chains for de novo Designed Proteins
   - Compute Binding Scores in EvoPro

## Developer's Note

Open [Developer Notebook](https://colab.research.google.com/github/data2code/afpdb/blob/main/tutorial/Developer.ipynb) in Google Colab.

## Install
Stable version:
```
pip install afpdb
```
or
```
conda install bioconda::afpdb
```
Development version:
```
pip install git+https://github.com/data2code/afpdb.git
```
or
```
git clone https://github.com/data2code/afpdb.git
cd afpdb
pip install .
```
To import the package use:
```
from afpdb.afpdb import Protein,RS,RL,ATS
```
## Demo

### Structure Read & Summary
```
# load the ab-ag complex structure 5CIL from PDB
p=Protein("5cil")
# show key statistics summary of the structure
p.summary().display()
```
Output
```
    Chain    Sequence                    Length    #Missing Residues    #Insertion Code    First Residue Name    Last Residue Name
--  -------  ---------------------------------------------------------------------------------------------------------------------
 0  H        VQLVQSGAEVKRPGSSVTVS...        220                    8                 14                     2                  227
 1  L        EIVLTQSPGTQSLSPGERAT...        212                    0                  1                     1                  211
 2  P        NWFDITNWLWYIK                   13                    0                  0                   671                  683
```
### Residue Relabeling

```
print("Old P chain residue numbering:", p.rs("P").name(), "\n")

Output:
Old P chain residue numbering: ['671', '672', '673', '674', '675', '676', '677', '678', '679', '680', '681', '682', '683'] 

p.renumber("RESTART", inplace=True)
print("New P chain residue numbering:", p.rs("P").name(), "\n")

Output:
New P chain residue numbering: ['1', '2', '3', '4', '5', '6', '7', '8', '9', '10', '11', '12', '13'] 

p.summary()
```
Output

```
    Chain    Sequence                    Length    #Missing Residues    #Insertion Code    First Residue Name    Last Residue Name
--  -------  ---------------------------------------------------------------------------------------------------------------------
 0  H        VQLVQSGAEVKRPGSSVTVS...        220                    8                 14                     1                  226
 1  L        EIVLTQSPGTQSLSPGERAT...        212                    0                  1                     1                  211
 2  P        NWFDITNWLWYIK                   13                    0                  0                     1                   13
```
### Replace Missing Residues for AI Prediction
```
print("Sequence for AlphaFold modeling, with missing residues replaced by Glycine:")
print(">5cil\n"+p.seq(gap="G")+"\n")
```
Output
```
Sequence for AlphaFold modeling, with missing residues replaced by Glycine:
>5cil
VQLVQSGAEVKRPGSSVTVSCKASGGSFSTYALSWVRQAPGRGLEWMGGVIPLLTITNYAPRFQGRITITADRSTSTAYLELNSLRPEDTAVYYCAREGTTGDGDLGKPIGAFAHWGQGTLVTVSSASTKGPSVFPLAPSGGGGGGGGGTAALGCLVKDYFPEPVTVGSWGGGGNSGALTSGGVHTFPAVLQSGSGLYSLSSVVTVPSSSLGTGGQGTYICNVNHKPSNTKVDKKGGVEP:EIVLTQSPGTQSLSPGERATLSCRASQSVGNNKLAWYQQRPGQAPRLLIYGASSRPSGVADRFSGSGSGTDFTLTISRLEPEDFAVYYCQQYGQSLSTFGQGTKVEVKRTVAAPSVFIFPPSDEQLKSGTASVVCLLNNFYPREAKVQWKVDNALQSGNSQESVTEQDSKDSTYSLSSTLTLSKADYEKHKVYACEVTHQGLSSPVTKSFNR:NWFDITNWLWYIK
```
### Interface Computing
```
# identify H,L chain residues within 4A to antigen P chain
rs_binder, rs_seed, df_dist=p.rs_around("P", dist=4)

# show the distance of binder residues to antigen P chain
df_dist[:5].display()
```
Output
```
     chain_a      resn_a    resn_i_a    resi_a  res_a    chain_b    resn_b      resn_i_b    resi_b  res_b       dist  atom_a    atom_b
---  ---------  --------  ----------  --------  -------  ---------  --------  ----------  --------  -------  -------  --------  --------
408  P                 6           6       437  T        H          94                94        97  E        2.63625  OG1       OE2
640  P                 4           4       435  D        L          32                32       252  K        2.81482  OD1       NZ
807  P                 2           2       433  W        L          94                94       314  S        2.91194  N         OG
767  P                 1           1       432  N        L          91                91       311  Y        2.9295   ND2       O
526  P                 7           7       438  N        H          99E               99       107  K        3.03857  ND2       CE
```
### Residue Selection & Boolean Operations
```
# create a new PDB file only containing the antigen and binder residues
q=p.extract(rs_binder | "P")
```
### Structure I/O
```
# save the new structure into a local PDB file
q.save("binders.pdb")
```
### Structure Display within Jupyter Notebook
```
# display the PDB struture, default is show ribbon and color by chains.
q.show(show_sidechains=True)
```
Output (It will be 3D interactive within Jupyter Notebook)<br>
```
<img src="https://github.com/data2code/afpdb/blob/main/tutorial/img/demo.png?raw=true">
```

### Antibody Analysis & PyMOL Visualization
```
# identify the variable domain, CDR regions, use B-factors to represent different CDR regions
rs_cdr, rs_var, c_chain_type, c_cdr = p.rs_antibody(scheme="imgt", set_b_factor=True)
# remove constant domain, only keep the variable domain for antibody
# we translate the coordindate of the truncated protein by a small amount to avoid q being shadowed by p in the display
q=p.extract(rs_var | p.rs("P")).translate([0.5, 0.5, 0.5], inplace=True)
print(q.len_dict())
# The truncated antibody is smaller, as it only contains the variable domain

# color the full antibody variable+constant in white
# The truncated variable-only object in rainbow color
Protein.PyMOL3D() \
  .show(p, color="white") \
  .show(q, color="spectrum") \
  .show(output="myAb.pse", save_png=True, width=250, height=250)
# A PyMOL session file and png file are generated.
```
Output (myAb.pse can be opened with PyMOL)<br>
```
{'H': 220, 'L': 212, 'P': 13}
{'H': 126, 'L': 108, 'P': 13}
Save: Please wait -- writing session file...
Save: wrote "myAb.pse".
PyMOL session saved: myAb.pse
High-quality image saved: myAb.png

<img src="https://github.com/data2code/afpdb/blob/main/tutorial/img/myAb.png?raw=true">
```
### Automatic Object Alignment
```
# We remove constant domain, change chain names, and translate the new protein
q = p.truncate_antibody() \
    .rename_chains({"H":"X", "L":"Y", "P":"Z"}) \
    .translate([3, 4, 5], inplace=True)
# The new protein is shorter
print(q.len_dict())
# Automatic chain pairing and sequence alignment
p2, q2, rl_p, rl_q = p.align_two(q, auto_chain_map=True)
# aligned portion
# The alignment output indicates it figures out chain H/L/P should be paired with X/Y/Z.
print("Original protein p:", rl_p, "\n")
print("Truncated protein q:", rl_q, "\n")
print("RMSD (expecting 0):", p.rmsd(q, rl_p, rl_q, align=True))
```
Output<br>
```
{'X': 126, 'Y': 108, 'Z': 13}

Chain Mapped: H <> X
target            0 VQLVQSGAEVKRPGSSVTVSCKASGGSFSTYALSWVRQAPGRGLEWMGGVIPLLTITNYA
                  0 ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
query             0 VQLVQSGAEVKRPGSSVTVSCKASGGSFSTYALSWVRQAPGRGLEWMGGVIPLLTITNYA

target           60 PRFQGRITITADRSTSTAYLELNSLRPEDTAVYYCAREGTTGDGDLGKPIGAFAHWGQGT
                 60 ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
query            60 PRFQGRITITADRSTSTAYLELNSLRPEDTAVYYCAREGTTGDGDLGKPIGAFAHWGQGT

target          120 LVTVSS 126
                120 |||||| 126
query           120 LVTVSS 126

Chain Mapped: L <> Y
target            0 EIVLTQSPGTQSLSPGERATLSCRASQSVGNNKLAWYQQRPGQAPRLLIYGASSRPSGVA
                  0 ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
query             0 EIVLTQSPGTQSLSPGERATLSCRASQSVGNNKLAWYQQRPGQAPRLLIYGASSRPSGVA

target           60 DRFSGSGSGTDFTLTISRLEPEDFAVYYCQQYGQSLSTFGQGTKVEVK 108
                 60 |||||||||||||||||||||||||||||||||||||||||||||||| 108
query            60 DRFSGSGSGTDFTLTISRLEPEDFAVYYCQQYGQSLSTFGQGTKVEVK 108

Chain Mapped: P <> Z
target            0 NWFDITNWLWYIK 13
                  0 ||||||||||||| 13
query             0 NWFDITNWLWYIK 13

Original protein p: H2-113:L1-107:P 

Truncated protein q: X:Y:Z 

RMSD (expecting 0): 7.16936768611062e-15
```
