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evo-final

A multi-source protein complex dataset for self-supervised preference training. Every cross-species swap is ortholog-aligned (swap human_A with yeast_A — the orthologous gene's product — not a random yeast protein) and labelled with three sequence-identity metrics + TimeTree species divergence time.

Identity filter (v3.1): L2/L3/L4 are restricted to ortholog pairs whose BLAST-style identity ≥ 0.80 on both chain A and chain B. Below this the "swap" is too divergent to be an informative dispreferred negative for preference training. Unfiltered parquets remain available locally as *_unfiltered.parquet for ablation studies.

Same-species & no-data filter (v3.4): Rows where both interacting partners come from the same organism (taxid_1 == taxid_2) are dropped — they were leaking through from AFCDB genus-only labels (e.g. "Homo" vs "Homo sapiens", both taxid 9606) and don't represent a real cross-species swap. Rows whose species pair has no TimeTree calibration (e.g. Alouatta vs other primates) are also dropped. As a result, every shipped row has divergence_mya non-null and strictly positive (0.29 – 1530 Mya).

Unified configs (v3.7): All layers (swap_relationships, swap_complexes, preference_pairs) bundle within-source AND cross-source rows into single configs. Filter by the source column ∈ {nvda, conglab, cross} on any layer. The *_cross_source configs from earlier versions are retired.

Train/val/test splits (v3.6 — rescued): L3 and L4 carry a split column ∈ {train, validation, test}. Pipeline:

  1. mmseqs2 easy-cluster every unique chain across L3 (within + cross-source) at 30% min-seq-id, 80% coverage → 14,814 chains collapse to 1,716 clusters.
  2. Cluster co-occurrence merge: if any L3 row has chains in two different clusters, union those clusters. The 1,716 clusters collapse to 545 connected components (largest = ~21% of rows).
  3. Greedy 80/10/10 bin-pack by component size: largest-first, place each component into the split with the most remaining capacity. Lands exactly at 80.00% / 10.00% / 10.00%.
  4. Every L3 row's 4 chains live in a single component → single split. No rows dropped (was ~25% drop in v3.5). L4 inherits the parent L3 row's split via swap_complex_id.
  5. Leak-free guarantee: every chain belongs to exactly one component, every component belongs to exactly one split, so no chain appears in multiple splits. Verified by mmseqs2 easy-search at -s 7.5: 0 exact-string overlaps train↔val/test; residual borderline-PID hits (mean ~33%, 95th 39–44%) reflect mmseqs2 cluster's heuristic boundary, typical of paper-grade homology-reduced splits.

The combined swap_complexes row split is exactly 80/10/10 (58,008 / 7,251 / 7,251). Earlier strict-drop variants are reproducible via Phase 23 + a chosen seed; the rescue path is Phase 36.

Five-layer structure

Layer config_name Rows Purpose
L1 natives 85,554 All native heterodimers, no filter.
L1ʹ natives-filtered 50,357 Same, Opisthokonta + NCBI-genus-mappable.
L2 swap_relationships 77,571 FK-only pairs of natives sharing an ortholog group. Combined within + cross-source (filter via the source column). (unsplit)
L3 swap_complexes 72,510 wjiaqi/evo-style — 4 sequences inline per row + gene/species/identity/mya labels. Combined within + cross-source. Split: 58,008 / 7,251 / 7,251 (exact 80/10/10).
L4 preference_pairs (default) 290,040 Train-ready. Per-row (preferred native, dispreferred chimera) with species+gene labels on every chain. Combined within + cross-source. Split: 232,032 / 29,004 / 29,004 (exact 80/10/10).
from datasets import load_dataset
prefs     = load_dataset("wjiaqi/evo-final")["train"]                       # L4, combined (default)
complexes = load_dataset("wjiaqi/evo-final", "swap_complexes")["train"]     # L3, combined
relations = load_dataset("wjiaqi/evo-final", "swap_relationships")["train"] # L2, combined
# Filter by source via the `source` column ∈ {"nvda", "conglab", "cross"} on any layer.

L1, L2, L3, L4 are mathematically equivalent at the information level — L3 is expand(L2) ⨝ natives, L4 is expand(L3, {AB,BA} × {sp1,sp2}) = 4 × L3. Pick whichever layer matches your consumption pattern.

Three sequence-identity metrics on every L2/L3/L4 row

metric formula use case
seq_identity_* (primary) matches / aligned columns (non-gap) BLAST-style "% identity"; what's in literature; aligned-region conservation
seq_identity_*_min_len matches / min(len_a, len_b) core-domain identity; bounded by shorter chain
seq_identity_*_max_len matches / max(len_a, len_b) conservative; penalises length mismatch

Computed via BLOSUM62 global alignment (Biopython PairwiseAligner, open gap −11, extend −1). For orthologs with different lengths (e.g. human UQCRH 91 aa vs yeast QCR6 135 aa), the three values differ — BLAST ≈ 44%, max-len ≈ 30%. Standard literature reports the BLAST number.

Distance label B — TimeTree divergence time

divergence_mya = species-pairwise Median Time from TimeTree, molecular-clock calibrated. Examples:

species pair mya
Mouse ↔ Rat 13
Human ↔ Mouse 87
Human ↔ Zebrafish 429
S. cerevisiae ↔ S. pombe 543
Fly ↔ Worm 727
Human ↔ Yeast 1,275

We rejected NCBI tree-edge distance as a label: it's cladistic, not chronological, and inverts biological ordering (NCBI: human-fly 58 > human-yeast 38; reality: 686 < 1,275 Mya).

For conglab, where lineage only carries genus, we map each genus to its lowest-taxid species descendant in NCBI before querying TimeTree.

L1 sources and species filter

Source natives natives-filtered Provenance
nvda 69,693 34,620 wjiaqi/evo-afcdb-final — NVIDIA AFDB strict (ipSAE_min ≥ 0.6 & N_clash_backbone ≤ 10).
conglab 15,861 15,737 wjiaqi/evo-conglab-final — Cong-lab human-PPI orthologs filtered through Boltz (iptm ≥ 0.7 & complex_plddt ≥ 70). 124 rows dropped from filtered for no-NCBI-genus.

Filter: Opisthokonta (Metazoa + Fungi = clade ≤ human-yeast distance) AND a valid NCBI scientific-name genus so every row maps to a taxid for TimeTree lookup.

Schemas

L3 — swap_complexes (wjiaqi/evo-style; one row = one cross-species ortholog pair)

Column Notes
swap_complex_id, relationship_id, source, interaction_group_id identifiers; source ∈ {nvda, conglab, cross}
species_1, taxid_1, organism_acc_1 sp1 organism metadata (organism_acc filled for conglab only)
protein_A_sp1_{uniprot,gene,seq,len} chain A of native 1
protein_B_sp1_{uniprot,gene,seq,len} chain B of native 1
species_2, taxid_2, organism_acc_2, protein_A_sp2_*, protein_B_sp2_* same for native 2
role_key_A, role_key_B ortholog group ids — STRING OG_<n> for nvda and cross, canonical human UniProt for conglab
seq_identity_A, seq_identity_A_min_len, seq_identity_A_max_len three identity metrics for chain A
seq_identity_B, seq_identity_B_min_len, seq_identity_B_max_len three identity metrics for chain B
divergence_mya TimeTree species divergence in Mya (NaN where TimeTree has no data)
split train / val / test; assigned by 30%-PID mmseqs2 cluster, 60/20/20 ratio, mixed-cluster rows → train (no leakage)

L4 — preference_pairs (training-ready)

Column Notes
preference_id, swap_complex_id, relationship_id, source identifiers + FKs
crossover 'AB' = dispreferred is (sp1.A, sp2.B); 'BA' = (sp2.A, sp1.B)
preferred_native_id, preferred_species, preferred_taxid, preferred_organism_acc which native is the positive
preferred_A_{uniprot,gene,seq,len}, preferred_B_* the native heterodimer
dispreferred_A_species, dispreferred_A_taxid, dispreferred_A_organism_acc species of the A chain of the swap chimera
dispreferred_A_{uniprot,gene,seq,len} the A chain of the swap
dispreferred_B_* same for B (different species — that's the swap!)
seq_identity_A, seq_identity_A_min_len, seq_identity_A_max_len, seq_identity_B, … identity metrics inherited from L3
divergence_mya TimeTree distance between the two natives' species (inherited from L3)
split inherited from L3 via swap_complex_id

L2 — swap_relationships (FK-only, lightweight)

Column Notes
relationship_id, source, swap_kind identifiers; swap_kind always 'cross_species_ortholog'
native1_id, native2_id FK → L1
taxid_1, taxid_2, organism_1, organism_2, role_key_A, role_key_B, interaction_group_id minimal metadata for filtering / joining
seq_identity_A, seq_identity_A_min_len, seq_identity_A_max_len, seq_identity_B, …, divergence_mya labels (same values as L3/L4)

L1 — natives / natives-filtered

Vocabulary of native heterodimers; identical schema, the _filtered variant just applies the Opisthokonta + NCBI-genus filter.

Column Notes
native_id, source nvda-AF-… or conglab-PPI…@organism_acc
taxid, organism, organism_key, lineage, clade, phylum taxonomy (NaN where unavailable)
A_{uniprot,gene,seq,len}, B_{uniprot,gene,seq,len} the two chains
nvda_ipSAE_min, nvda_ipTM, nvda_pDockQ, nvda_n_clash, nvda_complex_id NVIDIA AF-Multimer scores (NaN for conglab)
boltz_iptm, boltz_plddt, boltz_ptm, boltz_conf, ppi_id conglab Boltz scores (NaN for nvda)

Within-source vs cross-source

Each layer has two variants:

  • within-source (no _cross_source suffix): pairs are NVIDIA × NVIDIA (via STRING ortholog groups) or conglab × conglab (via shared ppi_id). Both natives are from the same upstream dataset.
  • cross-source (_cross_source): pairs are NVIDIA × conglab. They exist because 337 STRING ortholog signatures appear in BOTH NVIDIA and conglab (= 30% of NVIDIA signatures, 40% of conglab signatures). For these signatures we get to pair an NVIDIA AF-multimer-verified native with a conglab Boltz-verified native of the same conserved interaction.

Keep them separate so consumers can opt in to one, the other, or both.

Construction summary

NVIDIA AFDB strict + conglab Boltz-filtered  → L1 natives
            ↓
STRING orthologs over 30 Opisthokonta species  → role_keys
            ↓
L2 swap_relationships (within-source: nvda×nvda via STRING, conglab×conglab via ppi_id;
                       cross-source: signature overlap)
            ↓
L3 swap_complexes  ( = L2 ⨝ natives,  4 sequences inline per row)
            ↓
L4 preference_pairs ( = expand L3 to 4 rows: {AB, BA} × {sp1 preferred, sp2 preferred} )

Plus per-row:

  • BLOSUM62 global alignment → 3 identity metrics
  • TimeTree pairwise Median Time → divergence Mya

Code: w-jiaqi/EvoData (scripts 01–20, plus species_config.py).

Citation

  • NVIDIA AFDB: Han Y, Tsenkov MI, Venanzi NAE, et al. bioRxiv (2026), doi:10.64898/2026.03.27.714458.
  • STRING: Szklarczyk et al., Nucleic Acids Research (2023).
  • UniProt: UniProt Consortium, Nucleic Acids Research (2025).
  • TimeTree: Kumar et al., Mol Biol Evol (2022).
  • Cong-lab Boltz-filtered PPI set (forthcoming).
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