30S ribosomal protein S17
AF-Q83I69-F1-v4
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Predicted aligned error (PAE)
Click and drag a box on the PAE viewer to select regions of the structure and highlight them on the 3D viewer.
PAE data is useful for assessing inter-domain accuracy – go to Help section below for more information.
Start a structural similarity search to discover similar proteins.
AlphaFold database protein sequences clustered by the MMseqs2 algorithm (Steinegger M. and Soeding J., Nat. Commun. 9, 2018). Each cluster is comprised of sequences that fulfil two criteria: maintaining a maximum sequence identity of 50% and achieving a 90% bi-directional sequence overlap with the longest sequence of the cluster representative.
AFDB accession | Description | Species | Sequence length | Average pLDDT |
---|---|---|---|---|
AFDB accessionAF-Q83I69-F1 | Description 30S ribosomal protein S17 30S ribosomal protein S17 | SpeciesTropheryma whipplei (strain TW08/27) Tropheryma whipplei (strain TW08/27)... Tropheryma whipplei (strain TW08/27) | Sequence length 86 | Average pLDDT 94.88 |
AFDB accessionAF-Q82XQ7-F1 | Description Primosomal replication protein N Primosomal replication protein N | SpeciesNitrosomonas europaea (strain ATCC 19718 / CIP 103999 / KCTC 2705 / NBRC 14298) Nitrosomonas europaea (strain ATCC 19718 / CIP 103999 / KCTC 2705 / NBRC 14298)... Nitrosomonas europaea (strain ATCC 19718 / CIP 103999 / KCTC 2705 / NBRC 14298) | Sequence length 108 | Average pLDDT 94.29 |
AFDB accessionAF-Q81J33-F1 | Description 30S ribosomal protein S17 30S ribosomal protein S17 | SpeciesBacillus cereus (strain ATCC 14579 / DSM 31 / JCM 2152 / NBRC 15305 / NCIMB 9373 / NRRL B-3711) Bacillus cereus (strain ATCC 14579 / DSM 31 / JCM 2152 / NBRC 15305 / NCIMB 9373 / NRRL B-3711)... Bacillus cereus (strain ATCC 14579 / DSM 31 / JCM 2152 / NBRC 15305 / NCIMB 9373 / NRRL B-3711) | Sequence length 87 | Average pLDDT 93.98 |
AFDB accessionAF-C3P9R4-F1 | Description 30S ribosomal protein S17 30S ribosomal protein S17 | SpeciesBacillus anthracis (strain A0248) Bacillus anthracis (strain A0248) | Sequence length 87 | Average pLDDT 93.97 |
AFDB accessionAF-Q1WS99-F1 | Description 30S ribosomal protein S17 30S ribosomal protein S17 | SpeciesLactobacillus salivarius (strain UCC118) Lactobacillus salivarius (strain UCC118)... Lactobacillus salivarius (strain UCC118) | Sequence length 88 | Average pLDDT 93.93 |
AFDB accessionAF-A7Z0P7-F1 | Description 30S ribosomal protein S17 30S ribosomal protein S17 | SpeciesBacillus velezensis (strain DSM 23117 / BGSC 10A6 / FZB42) Bacillus velezensis (strain DSM 23117 / BGSC 10A6 / FZB42)... Bacillus velezensis (strain DSM 23117 / BGSC 10A6 / FZB42) | Sequence length 87 | Average pLDDT 93.91 |
AFDB accessionAF-Q03ZN6-F1 | Description 30S ribosomal protein S17 30S ribosomal protein S17 | SpeciesLeuconostoc mesenteroides subsp. mesenteroides (strain ATCC 8293 / DSM 20343 / BCRC 11652 / CCM 1803 / JCM 6124 / NCDO 523 / NBRC 100496 / NCIMB 8023 / NCTC 12954 / NRRL B-1118 / 37Y) Leuconostoc mesenteroides subsp. mesenteroides (strain ATCC 8293 / DSM 20343 / BCRC 11652 / CCM 1803 / JCM 6124 / NCDO 523 / NBRC 100496 / NCIMB 8023 / NCTC 12954 / NRRL B-1118 / 37Y)... Leuconostoc mesenteroides subsp. mesenteroides (strain ATCC 8293 / DSM 20343 / BCRC 11652 / CCM 1803 / JCM 6124 / NCDO 523 / NBRC 100496 / NCIMB 8023 / NCTC 12954 / NRRL B-1118 / 37Y) | Sequence length 88 | Average pLDDT 93.91 |
AFDB accessionAF-B9IZK3-F1 | Description 30S ribosomal protein S17 30S ribosomal protein S17 | SpeciesBacillus cereus (strain Q1) Bacillus cereus (strain Q1) | Sequence length 87 | Average pLDDT 93.9 |
AFDB accessionAF-B7HQV3-F1 | Description 30S ribosomal protein S17 30S ribosomal protein S17 | SpeciesBacillus cereus (strain AH187) Bacillus cereus (strain AH187) | Sequence length 87 | Average pLDDT 93.86 |
AFDB accessionAF-Q65P98-F1 | Description 30S ribosomal protein S17 30S ribosomal protein S17 | SpeciesBacillus licheniformis (strain ATCC 14580 / DSM 13 / JCM 2505 / NBRC 12200 / NCIMB 9375 / NRRL NRS-1264 / Gibson 46) Bacillus licheniformis (strain ATCC 14580 / DSM 13 / JCM 2505 / NBRC 12200 / NCIMB 9375 / NRRL NRS-1264 / Gibson 46)... Bacillus licheniformis (strain ATCC 14580 / DSM 13 / JCM 2505 / NBRC 12200 / NCIMB 9375 / NRRL NRS-1264 / Gibson 46) | Sequence length 87 | Average pLDDT 93.83 |
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How to interpret the Predicted Aligned Error
The Predicted Aligned Error (PAE) measures the confidence in the relative position of two residues within the predicted structure, providing insight into the reliability of relative position and orientations of different domains. Consider the human protein encoded by the gene GNE (Q9Y223). GNE has two distinct domains according to experimentally determined structures in the Protein Data Bank (PDBe-KB). Does AlphaFold confidently predict their relative positions? We can use the interactive Predicted Aligned Error (PAE) plot to answer this question. The PAE plot is not an inter-residue distance map or a contact map. Instead, the shade of green indicates the expected distance error in Ångströms (Å), ranging from 0 Å to an arbitrary cut-off of 31 Å. The colour at (x, y) corresponds to the expected distance error in the residue x’s position when the predicted and the true structures are aligned on residue y. The two low-error, dark green squares correspond to the two domains. By clicking and dragging, you can highlight these squares on the structure. If you want to remove the highlighting, click the cross icon. When selecting an off-diagonal region, the plot visually represents the relationship between the selected ranges on the sequence and structure. The x range corresponds to the selection for scored residues, highlighted in orange, while the y range of aligned residues is highlighted in emerald green. Let’s consider another inter-domain example, the human protein encoded by DIP2B (Q9P265). In this case, we have confidence in the relative position of scored residues around 1450 when aligned with residues around 850, suggesting a packing between the small central domains. Note that the PAE scores are asymmetrical, meaning there might be variations in PAE values between (x,y) and (y,x) positions. This is particularly relevant for loop regions with highly uncertain orientations, as seen on the DNA topoisomerase 3 (Q8T2T7).
A dark green tile corresponds to a good prediction (low error), whereas a light green tile indicates poor prediction (high error). For example, when aligning on residue 300:
The high PAE values across the whole inter-domain region indicate that for this particular protein, AlphaFold does not reliably predict the relative position of the domains.
Last updated
Last updated in AlphaFold DB version 2022-11-01, created with the AlphaFold Monomer v2.0 pipeline.
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If you make use of an AlphaFold prediction, please cite the following papers: Jumper, J et al. Highly accurate protein structure prediction with AlphaFold. Nature (2021).
Varadi, M et al. AlphaFold Protein Structure Database in 2024: providing structure coverage for over 214 million protein sequences. Nucleic Acids Research (2024).
If you use data from AlphaMissense in your work, please cite the following paper: Cheng, J et al. Accurate proteome-wide missense variant effect prediction with AlphaMissense. Science (2023).
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