Hemochromatosis: Sequence based predictions

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Lab Journal

Secondary Structure

In this task, secondary structure of proteins is predicted using the programs reProf and PsiPred. The results are then compared to the DSSP[1] secondary structure assignments from corresponding crystal structures in the PDB.

<figtable id="sequences">

Uniprot PDB
UID Name Length ID Resolution [A] Chain Length
Q30201 Hereditary hemochromatosis protein 348 A16Z 2.60 A 275
P10775 Ribonuclease inhibitor 456 2BNH 2.30 A 457
Q9X0E6 Divalent-cation tolerance protein CutA 101 1VHF 1.54 A 113
Q08209 CAM-PRP catalytic subunit 521 1M63 2.80 A 372
Table 1: List of the four proteins for which several features were predicted in this task. The pdb structures were used for comparison.

</figtable>

Thus, the crystal structures listed in <xr id="sequences"/> were selected for comparison. The first priority for selection was to get the protein in its native state and not bound to another molecule. The other criteria were the quality of the structure and the alignment to the protein sequence (having one continous segment).

In the next step, the output of the prediction programs and the DSSP assignments have to be made comparable. DSSP assigns 8 different classes of secondary structure, whereas reProf and PsiPred only predict helix(H), sheet(E) and loop(L or C). Therefore, H and G are mapped to H, E to E and all other DSSP classes to C.

To assess the quality of the prediction, the class specific accuracy, coverage and F1-measure were used along with the Q3 and SOV3<ref>Zemla. A, et al.;A Modified Definition of Sov, a Segment-Based Measure for Protein Secondary Structure Prediction Assessment; PROTEINS 34:220–223 (1999)</ref> measures. The Q3 is defined as follows:

Q3 formula.gif

Reprof takes as input either sequences or PSSMs. Therefore, PSSMs were generated by querying the HFE (Q30201) sequence against the big_80, SwissProt and PDB databases. The tool of choice for this was PsiBlast with standard parameters (2 iterations and e-value cutoff of 0.002).


<figtable id="prediction quality">

Prediction methods
Reprof + Sequence Reprof + Big80 Reprof + SwissProt Reprof + PDB Psipred
Q3 0.76 0.81 0.86 0.84 0.84
SOV3 0.66 0.75 0.84 0.84 0.73
Acc Cov F1 Acc Cov F1 Acc Cov F1 Acc Cov F1 Acc Cov F1
H 0.63 0.33 0.44 0.74 0.48 0.59 0.84 0.65 0.74 0.85 0.52 0.64 0.98 0.77 0.86
C 0.57 0.69 0.63 0.63 0.75 0.68 0.68 0.81 0.74 0.64 0.83 0.72 0.61 0.95 0.74
E 0.79 0.63 0.70 0.81 0.84 0.83 0.89 0.86 0.87 0.88 0.85 0.86 0.94 0.55 0.69
Table 2: Quality of the Reprof predictions based on different inputs and the Psipred prediction for HFE.

</figtable>

The deciding criteria for the Reprof method choice were the Q3, SOV3 and F1-measures. For the Q3 and the SOV3, the SwissProt PSSM performed best and the F1-measures were also reasonable (see <xr id="prediction quality"/>). Therefore, this method was chosen for all future predictions.

The DSSP assignments and ReProf and PSiPred prediction for each of the four proteins can be found at Hemochromatosis SS Alignments.


<figtable id="comparison">

Protein Method Q3 SOV3
Q08209 ReProf 0.83 0.78
Psipred 0.87 0.79
Q30201 ReProf 0.86 0.84
Psipred 0.84 0.73
P10775 ReProf 0.91 0.93
Psipred 0.93 0.94
Q9X0E6 ReProf 0.75 0.65
Psipred 0.89 0.86
Table 3: .

</figtable>

<xr id="comparison"/> shows a comparison of the ReProf and PsiPred prediction quality. The predictions were compared to the DSSP assignment of the corresponding pdb structures. While SOV3 and Q3 do not always agree which of the two methods performs better, they do so most of the time. Nevertheless, it was decided that SOV3 is to be trusted more than Q3, because it takes into account the per segment accuracy rather than just the per residue accuracy. Thus, PsiPred outperforms reprof in 3 out of 4 cases. It is also notable, that the SOV3 values range from 0.65 for Q9X0E6(101 residues) to 0.94 for P10775(456 residues). So the performance of the method depends on the length of the protein and the protein itself, but PsiPred performed best overall.

TODO: Find out more about the example proteins (and yours) using UniProt and the PDB.


Disorder

We searched DisProt for the best matches to the four proteins, but there was only one direct match for Q08209. We used the PsiBlast and Smith Waterman search to find matches for the other three proteins. The first best matches are listed in <xr id="disprot id"/>.

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<figtable id="disprot id">

UID DisProt ID SeqID E-value Method
Q30201 DP00670 0.29 2e-30 psiblast
P10775 DP00554 0.4 7e-30 psiblast
Q9X0E6 DP00564 0.25 0.36 smith-waterman
Q08209 DP00092 - - direct match
Table 4: DisProt matches for Q30201, P10775, Q9X0E6 and Q08209. The 'method' column specifies how the match was found.

</figtable>

IUPred is a disorder prediction server that predicts three different types:

  • long disorder
  • short disorder
  • global (globular not disordered domains)

When prediction the long and short types of disorder, the output contains a likelihood of disorder for each residue and the globular domains prediction contains the start and end positions.

MetaDisorder (MD) is a predictor that is based on several prediction program from predict protein. It combines those predictions into one value for each residue, which is the likelihood of being part of a disordered region.

<figure id=disorder pred1">

Disorder plot Q30201.png Hemo plot P10775.png
Q30201 glob.png P10775 globular.png

</figure>

<figure id="disorder pred2">

Hemo plot Q9X0E6.png Hemo plot Q08209.png
Q9X0E6 globular.png Q08209 globular.png
Table 4: Disprot and Metadisorder predictions. The upper plot for each protein contains the local and global predictions from IUPred, the MetaDisorder prediction and the DisProt annotation of the corresponding match in the database. The upper part of the top plot with the red and blue bars is the DisProt annotation. The lower plot contains the global IUPred prediction, where the blue bar indicates the globular domain. The x-axies of both plots show the protein sequence and the y-axes the tendency of each residue for being disordered. The scale ranges from 0 to 1.

</figure>

All predictions are combined into plots in <xr id="disorder pred2"/>. A residue is predicted to be disordered if its likelihood is higher than 0.5, indicated by the gray horizontal line.

Unfortunately could we not find good matches in the DisProt database, apart from the direct match for Q08209. The matches for Q30201 and Q9X0E6 have a sequence identity below 30% and the e-value for Q9X0E6 is much too high with 0.36. But the hit for P10775 with a sequence identity of 40% and an e-value of 7e-30 can possibly be used for an annotation transfer. Nevertheless, we included the annotations for the Q30201 and Q9X0E6 matches for the sake of completeness.

All predictions for the HFE protein Q30201 show nearly no disordered regions. The MD tendencies are always below 0.5 and there is only a short region after residue 250 where IUPred predicted long and short disordered regions. The DisProt annotation contain a small disordered region after residue 150, but this region can be neglected due to the low sequence identity of the corresponding DisProt protein. IUPred predicted, that the HFE protein consists of a simgle globular not disordered domain. In summary, the HFE protein is correctly predicted to be not disordered.

P10775 was also predicted to be not disordered by all methods. The region of the DisProt entry DP00465 that matched P10775 does not contain an disordered region, so the predictions are also right in this case.

The DisProt annotation of the entry DP00564 that matched the Q9X0E6 contains a long disordered region. In contrast, IUPred predicts no disordered residues in Q9X0E6. Only the MD likelihoods for disorder are higher, always above 0.3. But we trust DisPot the most, since all IUPred predictions, including the global, agree that Q9X0E6 is not disordered and DP00564 has an e-value of 0.36.

In contrast to the first three proteins, is Q08209 clearly disordered. The DisProt annotation of the protein contains several disordered regions near the C-terminus. IUPred's global prediction agrees that the C-terminus is disordered, and also the long, short and MD predictions are above 0.5.

Alle N and C-termini of the proteins have short disorder tendencies with values above 0.5, but since the ends of all protein chains can be characterized as disordered, to some extend, we would not count that as false predictions.

Transmembrane Helices

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</css> <figtable id="pdb structures">

Uniprot PDB
UID Name Length ID Resolution [A] Chain Length
Q30201 Hereditary hemochromatosis protein 348 A16Z 2.60 A 275
P35462 D(3) dopamine receptor 400 3PBL 2.89 A 400
Q9YDF8 Voltage-gated potassium channel 295 1ORQ 3.20 C 223
1ORS 1.90 C 132
P47863 Aquaporin-4 323 2D57 3.20 A 301
Table 5: Description of the four proteins Q30201, Q9YDF8, P35462 and P47863 and the corresponding pdb structures with the highest resolution.

</figtable>

HFE

The HFE protein is a single pass membrane protein and thus located at the membrane. Nevertheless, there are no entries in the OPM and PDBTM databases. A single pass membrane protein is a protein that has its N-terminus in the extracellular space and the C-terminus inside the mebrane. The N-terminal signal sequence is cleaved off after the translocation. The

<figtable id="TM hfe">

HFE (Q30201)
Memsat Polyphobius OPM PDBTM
Hemo memsat Q30201.png
Hemo poly Q30201.png
- -
Table 6:Visualisation of the Memsat and Polyphobius predictions for HFE.

</figtable>

Memsat predicts one transmembrane helix for the HFE protein and also a signal peptide consisting of the first 12 N-terminal residues (see <xr id="TM hfe"/>). The signal peptide is actually longer, it spans the first 22 residues (Uniprot), but the transmembrane helix from residue 306 to 329 is correctly predicted (307 to 330 in Uniprot).

Polyphobius prediction for HFE:

ID   sp|Q30201|HFE_HUMAN
FT   SIGNAL        1     25
FT   REGION        1      7       N-REGION.
FT   REGION        8     19       H-REGION.
FT   REGION       20     25       C-REGION.
FT   TOPO_DOM     26    304       NON CYTOPLASMIC.
FT   TRANSMEM    305    329
FT   TOPO_DOM    330    348       CYTOPLASMIC.

Polyphobius is even more accurate in its prediction. The predicted signal sequence ranges from residue 1 to 25 and the transmembrane region from 305 to 329, which is only slightly shifted. The graphical prediction plot in <xr id="TM hfe"/> shows in grey the transmembrane region and in red the signal peptide. The cytoplasmic region is indicated by the green line and the non cytoplasmic region in blue.

Both prediction programs were able to predict the transmembrane helices topology of the HFE protein.

D(3) dopamine receptor

A D(3) dopamine receptor is a located in the cell membrane of neurons. It is a multi-pass membrane protein that spans the membrane more than once.

<figtable id="TM P35462">

D(3) dopamine receptor (P35462)
Memsat Polyphobius OPM PDBTM
Hemo memsat P35462.png
Hemo poly P35462.png
3pbl opm.png
Hemo 3pbl lm.png
Table 6:Visualisation of the Memsat and Polyphobius predictions for the D(3) dopamine receptor (P35462) and the assignments in OPM and PDBTM.

</figtable>

The OPM and PDTM databases contain membrane assignments for crystal structures of known transmembrane proteins. Those reference assignments for 3PBL are shown in <xr id="TM P35462"/> In the OPM visualisation, the extracellular side of the membrane is marked with red and the cytoplasmic side with blue. The N-terminus of the protein is assigned to be extracellular. PDBTM colors the cytosolic part of the protein in red and the extracellular part in blue. Transmembrane helices are colored in yellow. Both databases have 7 transmembrane helices assigned to the structure of the D(3) dopamine receptor.


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</css> <figtable id="helices assignment P35462">

# TM helix OPM PDBTM
1 34-52 35-52
2 67-91 68-84
3 101-126 109-123
4 150-170 152-166
5 187-209 191-206
6 330-351 334-347
7 363-386 368-382
Table 4: Location of the seven helices in 3PBL as assigned in OPM and PDBTM .

</figtable>

Memsat predicts a signal peptide from positions 1 to 29, however, the Uniprot entry does not contain a signal peptide. Besides, Memsat correclty locates the N-terminus of the sequence in the etracellular space and predicts 6 transmembrane helices in total. The positions of all transmambrane helices graetly overlap with those of the OPM and PDBTM assignments, only the 7th helix is not predicted.

The Polyphobius prediction is the following:

ID   sp|P35462|DRD3_HUMAN
FT   TOPO_DOM      1     29       NON CYTOPLASMIC.
FT   TRANSMEM     30     55
FT   TOPO_DOM     56     65       CYTOPLASMIC.
FT   TRANSMEM     66     88
FT   TOPO_DOM     89    104       NON CYTOPLASMIC.
FT   TRANSMEM    105    126
FT   TOPO_DOM    127    149       CYTOPLASMIC.
FT   TRANSMEM    150    170
FT   TOPO_DOM    171    187       NON CYTOPLASMIC.
FT   TRANSMEM    188    212
FT   TOPO_DOM    213    328       CYTOPLASMIC.
FT   TRANSMEM    329    352
FT   TOPO_DOM    353    366       NON CYTOPLASMIC.
FT   TRANSMEM    367    386
FT   TOPO_DOM    387    400       CYTOPLASMIC.

The location of the N-terminus is correct as non cytoplasmic and all 7 transmembrane helices are predicted at the right positions. The graphcal plot also shows that there is no signal peptide. Thus, Polyphobius was able to determine the toplogy of the D(3) dopamine receptor.


voltage-gated potassium channel

There are two different pdb structures that both match the Q9YDF8 sequence. The annotations in OMP and PDBTM differ a bit, thus we combined the annotations from both structures, see <xr id="helices assignment Q9YDF8"/>.

<figtable id="helices assignment Q9YDF8">

# TM helix OPM PDBTM
1ORS 1ORQ 1ORS 1ORQ
1 37-58 - 39-62 33-64
2 67-90 - 67-87 69-92
3 98-109 - 100-119 -
4 112-121 - - -
5 129-160 - 130-154 -
6 - 165-184 - 163-183
7 - 195-207 - 196-212 (re-entrant helix)
8 - 219-237 - 221-248
Table 4: Location of the seven helices in 3PBL as assigned in OPM and PDBTM .

</figtable>

The sequence of 1ORQ starts at postition 30 of the Q9YDF8 sequence and the sequence of 1ORS at position 33. However, the PDB file of 1ORQ contains a start annotation at position 18 and 1ORS a start at position 20. We added 12 to the positions in the pdb files to get the actual position in the reference sequence Q9YDF8. The OPM assignment contains eight transmambrane helices for both structures, but PDBTM six transmambrane helices and one loop that is actually a re-entrant helix in the structure. Both databases have the N-termini of the two pdb structures annptated as located in the cytoplasm.

<figtable id="TM Q9YDF8">

Voltage-gated potassium channel (Q9YDF8)
Memsat Polyphobius OPM (1ORQ) PDBTM (1ORQ)
Hemo memsat Q9YDF8.png
Hemo poly Q9YDF8.png
1orq opm.png
Hemo 1orq lm.png
Table 6:Visualisation of the Memsat and Polyphobius predictions for the voltage-gated potassium channel (Q9YDF8) and the assignments in OPM and PDBTM.

</figtable>

Memsat predicts six transmembrane helices and one re-entrant helix (see <xr id="TM Q9YDF8"/>. It combines the third and fourth OPM helix into one, but all other helices can be counted as corret. If compared to the PDBTM assignment, all predicted helices are at the right positions, event the re-entrant helix. The location of the C-terminus in the cytoplasm is also correct, but not the N-terminus. It actually is located in the extracellular space and not the cytoplasm.

Polyphobius predicted the following topology:

  ID   sp|Q9YDF8|KVAP_AERPE
  FT   TOPO_DOM      1     41       NON CYTOPLASMIC.
  FT   TRANSMEM     42     60
  FT   TOPO_DOM     61     67       CYTOPLASMIC.
  FT   TRANSMEM     68     88
  FT   TOPO_DOM     89    107       NON CYTOPLASMIC.
  FT   TRANSMEM    108    129
  FT   TOPO_DOM    130    136       CYTOPLASMIC.
  FT   TRANSMEM    137    157
  FT   TOPO_DOM    158    162       NON CYTOPLASMIC.
  FT   TRANSMEM    163    184
  FT   TOPO_DOM    185    195       CYTOPLASMIC.
  FT   TRANSMEM    196    213
  FT   TOPO_DOM    214    223       NON CYTOPLASMIC.
  FT   TRANSMEM    224    244
  FT   TOPO_DOM    245    295       CYTOPLASMIC.

Seven transmembrane helices are predicted and the third and fourth OPM helix are also combined into one single helix (108 - 129), as in the Memsat output. Polyphobius does not predict a signal peptide and correcly locates the N and C-termini non-cytoplasm and cytoplasm, which is correct. So, the Polyphobius prediction does not match the PDBTM helices assignments as good as the Memsat prediction does, but the termini are located on the right sides.

Aquaporin-4

Aquaporin 4 is a potein that forms a channel through the cell membrane that allow the entrance of water molecules into the cell.

<figtable id="TM P47863">

Aquaporin-4 (P47863)
Memsat Polyphobius OPM PDBTM
Hemo memsat P47863.png
Hemo poly P47863.png
2d57 opm.png
Hemo 2d57 lm.png
Table 6:Visualisation of the Memsat and Polyphobius predictions for the Aquaporin-4 (P47863) and the assignments in OPM and PDBTM.

</figtable>

Signal Peptides

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Protein Name HFE_HUMAN ALBU_HUMAN LAMP1_HUMAN AQP4_RAT
UID Q30201 P02768 P11279 P47863
SP id 13435 22229 17551 -
SP annotation 1-22 1-18 1-18 -
signalP prediction 1-22 1-18 1-18 no signal peptide
Q30201
P02768
P11279
P47863
Table 7: Signal peptide predictions from signalP compared with the corresponding annotations in the signal peptide database. The plots display three types of score. The

For all four proteins, the signalP predictions were completely correct, which is remarkable.

  • ALBU_HUMAN, the human serum albumin, is the most abundant protein in human blood plasma. Its main responsibility is the regulation of the osmotic blood pressure and since it is a globular protein, it has no transmembrane helices.
  • The lysosome-associated membrane glycoprotein 1 (LAMP1_HUMAN)

GO Terms

GoPet

GO id Aspect Confidence GO term
GO:0004872 F 91% receptor activity
GO:0030106 F 88% MHC class I receptor activity
Table 5: GoPet results for the Q30201 sequence.

References

<references />