Difference between revisions of "Hemochromatosis: Sequence based predictions"

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(Disorder)
(Disorder)
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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.
 
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.
 
==Disorder==
 
==Disorder==
  +
{|
 
UID DisProt ID SeqID Eval method
+
!UID || DisProt ID || SeqID || E-value | Method
  +
|-
Q08209 DP00092 - - direct match
 
  +
Q08209 || DP00092 || - || - || direct match
Q30201 DP00670 0.29 2e-30 psiblast
 
  +
|-
P10775 DP00465 0.4 7e-30 psiblat
 
  +
|Q30201 ||DP00670 || 0.29 ||2e-30|| psiblast
Q9X0E6 DP00564 0.25 0.36 smith-waterman
 
  +
|-
 
  +
|P10775|| DP00465|| 0.4 ||7e-30|| psiblast
  +
|-
  +
|Q9X0E6|| DP00564 ||0.25 ||0.36 ||smith-waterman
  +
|}
   
 
<table><tr>
 
<table><tr>

Revision as of 17:55, 2 June 2013

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. Thus, the following crystal structures 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).

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


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:
<math> Q_3 = \frac{\text{correct predictions}}{ \text{all predictions}} = \frac{TP + TN}{TP + FP + TN + FN } } </math>

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).


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

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. Therefore, this method was chosen for all future predictions.

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


Hemochromatosis SS Alignments


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.

Disorder

Q08209 || DP00092 || - || - || direct match
UID DisProt ID SeqID Method
Q30201 DP00670 0.29 2e-30 psiblast
P10775 DP00465 0.4 7e-30 psiblast
Q9X0E6 DP00564 0.25 0.36 smith-waterman

<figure id="Disorder_plot_Q30201"><xr nolink id="Disorder_plot_Q30201"/>Description</figure>

<figure id="hemo_plot_P10775"><xr nolink id="hemo_plot_P10775"/>Description</figure>

<figure id="hemo_plot_Q9X0E6"><xr nolink id="hemo_plot_Q9X0E6"/>Description</figure>

<figure id="hemo_plot_Q08209"><xr nolink id="hemo_plot_Q08209"/>Description</figure>

Transmembrane Helices

Uniprot PDB
UID Name Length ID Resolution [A] Chain Length
Q30201 Hereditary hemochromatosis protein 348 A16Z 2.60 A 275
Q9YDF8 Voltage-gated potassium channel 295 1ORQ 3.20 C 223
P35462 D(3) dopamine receptor 400 3PBL 2.89 A 481
P47863 Aquaporin-4 323 2D57 3.20 A 301

Memsat

<figure id="">[[File:|thumb|300px|<xr nolink id=""/>
Description]]</figure>

<figure id="Hemo_memsat_Q30201">
<xr nolink id="Hemo_memsat_Q30201"/>
Memsat-SVM prediction for Q30201
</figure>
<figure id="hemo_memsat_P35462">
<xr nolink id="hemo_memsat_P35462"/>
Memsat-SVM prediction for P35462
</figure>
<figure id="hemo_memsat_P47863">
<xr nolink id="hemo_memsat_P47863"/>
Memsat-SVM prediction for P47863
</figure>
<figure id="hemo_memsat_Q9YDF8">
<xr nolink id="hemo_memsat_Q9YDF8"/>
Memsat-SVM prediction for Q9YDF8
</figure>

Test the reference <xr id="Hemo_memsat_Q30201" />

Polyphobius

<figure id="hemo_poly_Q30201">
<xr nolink id="hemo_poly_Q30201"/>
Polyphobius prediction for Q30201
</figure>
<figure id="hemo_poly_P35462">
<xr nolink id="hemo_poly_P35462"/>
Polyphobius prediction for P35462
</figure>
<figure id="hemo_poly_P47863">
<xr nolink id="hemo_poly_P47863"/>
Polyphobius prediction for P47863
</figure>
<figure id="hemo_poly_Q9YDF8">
<xr nolink id="hemo_poly_Q9YDF8"/>
Polyphobius prediction for Q9YDF8
</figure>

OPM

<figure id="1orq_opm">
<xr nolink id="1orq_opm"/>
OPM picture for 1ORQ
</figure>
<figure id="2d57_opm">
<xr nolink id="2d57_opm"/>
OPM picture for 2D57
</figure>
<figure id="3pbl_opm">
<xr nolink id="3pbl_opm"/>
OPM picture for 3PBL
</figure>

TMPDB

<figure id="Hemo_1orq_lm">
<xr nolink id="Hemo_1orq_lm"/>
PDBTM picture for 1ORQ
</figure>
<figure id="hemo_2d57_lm">
<xr nolink id="hemo_2d57_lm"/>
PDBTM picture for 2D57
</figure>
<figure id="hemo_3pbl_lm">
<xr nolink id="hemo_3pbl_lm"/>
PDBTM picture for 3PBL
</figure>

Signal Peptides

GO Terms

References

<references />