HPO

This library is a Rust implementation of PyHPO.

What is this?

HPO, the Human Phenotype Ontology is a standard vocabulary of phenotypic abnormalities in human diseases. It is an Ontology, so all terms are connected to each other, similar to a directed graph.

This library provides convenient APIs to work with the ontology. The main goals are to compare terms - or sets of terms - to each other and run statistics for enrichment analysis.

Features

• Calculate the similarity of HPO terms
• Calculate the similarity of multiple sets of HPO terms (e.g. a patient's clinical information)
• Enrichment analysis of genes and diseases in sets of HPO terms
• Compare different HPO versions
• Graph based analysis of the ontology
• Completely written in Rust, so it's 🚀blazingly fast🚀^TM (Benchmarks)

What is the current state?

The library is pretty much feature-complete, at least for my use-cases. If you have any feature-requests, please open an Issue or get in touch. I'm very much interested in getting feedback and new ideas what to improve.

The API is mostly stable, but I might refactor some parts a bit for easier use and performance gain.

If you find this project interesting and want to contribute, please get in touch, I could definitely need some help.

Documentation

The public API is fully documented on docs.rs

The main structs used in hpo are: - The Ontology is the main struct and entrypoint in hpo. - HpoTerm represents a single HPO term and contains plenty of functionality around them. - HpoSet is a collection of HpoTerms, like a patient's clinical information. - Gene represents a single gene, including information about associated HpoTerms. - OmimDisease represents a single OMIM-diseases, including information about associated HpoTerms.

The most relevant modules are: - annotations contains the Gene and OmimDisease structs, and some related important types. - similarity contains structs and helper functions for similarity comparisons for HpoTerm and HpoSet. - stats contains functions to calculate the hypergeometric enrichment score of genes or diseases.

Examples

Some (more or less random) examples are included in the examples folder.

Ontology

```rust use hpo::{Ontology, HpoTermId}; use hpo::annotations::{GeneId, OmimDiseaseId};

fn example() { let ontology = Ontology::from_standard("/path/to/master-data/").unwrap();

// iterate HPO terms
for term in &ontology {
    // do something with term
}

// iterate Genes
for gene in ontology.genes() {
    // do something with gene
}

// iterate omim diseases
for disease in ontology.omim_diseases() {
    // do something with disease
}

// get a single HPO term using HPO ID
let hpo_id = HpoTermId::try_from("HP:0000123").unwrap();
let term = ontology.hpo(hpo_id);

// get a single HPO term using `u32` part of HPO ID
let term = ontology.hpo(123u32);

// get a single Omim disease
let disease_id = OmimDiseaseId::from(12345u32);
let disease = ontology.omim_disease(&disease_id);

// get a single Gene
let hgnc_id = GeneId::from(12345u32);
let gene = ontology.gene(&hgnc_id);

// get a single Gene by its symbol
let gene = ontology.gene_by_name("GBA");

} ```

HPO term

```rust use hpo::Ontology;

fn example() { let ontology = Ontology::from_binary("/path/to/binary.hpo").unwrap();

let term = ontology.hpo(123u32).unwrap();

assert_eq!("Abnormality of the nervous system", term.name());
assert_eq!("HP:000123".to_string(), term.id().to_string());

// iterate all parents
for p in term.parents() {
    println!("{}", p.name())
}

// iterate all children
for p in term.children() {
    println!("{}", p.name())
}

let term2 = ontology.hpo(1u32).unwrap();

assert!(term2.parent_of(&term));
assert!(term.child_of(&term2));

} ```

Similarity

```rust use hpo::Ontology; use hpo::similarity::GraphIc; use hpo::term::InformationContentKind;

fn example() { let ontology = Ontology::from_binary("/path/to/binary.hpo").unwrap(); let term1 = ontology.hpo(123u32).unwrap(); let term2 = ontology.hpo(1u32).unwrap();

let ic = GraphIc::new(InformationContentKind::Omim);
let similarity = term1.similarity_score(&term2, &ic);

} ```

Enrichment

Identify which genes (or diseases) are enriched in a set of HpoTerms, e.g. in the clinical information of a patient or patient cohort

```rust use hpo::Ontology; use hpo::{HpoSet, term::HpoGroup}; use hpo::stats::hypergeom::gene_enrichment;

fn example() { let ontology = Ontology::from_binary("/path/to/binary.hpo").unwrap();

let mut hpos = HpoGroup::new();
hpos.insert(2943u32);
hpos.insert(8458u32);
hpos.insert(100884u32);
hpos.insert(2944u32);
hpos.insert(2751u32);
let patient_ci = HpoSet::new(&ontology, hpos);

let mut enrichments = gene_enrichment(&ontology, &patient_ci);

// the results are not sorted by default
enrichments.sort_by(|a, b| {
    a.pvalue().partial_cmp(&b.pvalue()).unwrap()
});

for gene in enrichments {
    println!("{}\t{}\t({})", gene.id(), gene.pvalue(), gene.enrichment());
}

} ```

Benchmarks

As the saying goes: "Make it work, make it good, make it fast". The work and good parts are realized in PyHPO. And even though I tried my best to make it fast, I was still hungry for more. So I started developing the hpo Rust library in December 2022. Even without micro-benchmarking and tuning performance as much as I did for PyHPO, hpo is indeed much much faster already now.

The below benchmarks were run non scientificially and your mileage may vary. I used a MacBook Air M1, rustc 1.68.0, Python 3.9 and /usr/bin/time for timing.

| Benchmark | PyHPO | hpo (single-threaded) | hpo (multi-threaded) | | --------- | ----- | --- | --- | | Read and Parse Ontology | 6.4 s | 0.22 s | 0.22 s | | Similarity of 17,245 x 1,000 terms | 98.5 s | 4.6 s | 1.0 s | | Similarity of GBA1 to all Diseases | 380 s | 15.8 s | 3.0 s | | Disease enrichment in all Genes | 11.8 s | 0.4 s | 0.3 s | | Common ancestors of 17,245 x 10,000 terms | 225.2 s | 10.5 | 2.1 |

Technical design

There is some info about the plans for the implementation in the Technical Design document