Difference between revisions of "Task 3 (MSUD)"

Secondary structure

Lab journal

Result

The results for ReProf and PsiPred predictions and the DSSP assignments are in the following folders:

/mnt/home/student/schillerl/MasterPractical/task3/reprof/

/mnt/home/student/schillerl/MasterPractical/task3/psipred/

/mnt/home/student/schillerl/MasterPractical/task3/dssp/

Position specific scoring matrices (PSSM) used as input for ReProt are located at:

/mnt/home/student/schillerl/MasterPractical/task3/pssm/

Approach for predicting secondary structure with ReProf

For P10775, ReProf was run with the protein sequence fasta file and position specific scoring matrices (PSSM) derived from big_80 and SwissProt as input. The following tables show the comparison of the prediction results to the secondary structure assignment of DSSP. The f-measure is the harmonic mean of recall and precision, it gives a good indication for the quality of a classificator.

Predictions using a PSSM instead of a simple sequence have a considerably better quality. All methods predict helices better than loops and these better than beta sheets. The results of the run with the big_80 PSMM are better for E and L and only slightly worse for H than those using the SwissProt PSMM.

The percentages of correctly identified secondary structure (H, E or L) for the three methods are 61 %, 86 % and 82 %. So for the remaining sequences, the method with the best performance (usage of PSSM derived from big_80 as input for ReProf) was used.

Comparison of ReProf to PsiPred and DSSP

The following tables show the percentages of agreement for secondary structure between ReProf and PsiPred or DSSP.

P12694

P10775

Q08209

Q9X0E6

Altogether, ReProf agrees in 80-85% of the predictions with PsiPred and DSSP. In most cases the agreement for H and L is higher than for E.

Information from UniProt and PDB

A summary of interesting features for the proteins taken from UniProt and PDB:

P12694, 2BFD:

• name: 2-oxoisovalerate dehydrogenase subunit alpha, mitochondrial
• EC: 1.2.4.4
• gene: BCKDHA
• organism: Homo sapiens (Human)
• sequence length: 445 AA
• subunit structure: heterotetramer of alpha and beta chains
• subcellular location: mitochondrion matrix
• secondary structure: 42% helical, 10% beta sheet
• 3D similarity: pyruvate dehydrogenase E1
• ligands: chloride ion, glycerol, potassium ion, manganese (II) ion, (4S)-2-methyl-2,4-pentanediol, thiamin diphosphate

P10775, 2BNH:

• name: ribonuclease inhibitor
• gene: RNH1
• organism: Sus scrofa (Pig)
• sequence length: 456 AA
• subcellular location. cytoplasm
• sequence similarities: contains 15 LRR (leucine-rich) repeats
• secondary structure: alternating helix and strand, 42% helical, 12% beta sheet

Q08209, 1AUI:

• name: serine/threonine-protein phosphatase 2B catalytic subunit alpha isoform
• EC: 3.1.3.16
• gene: PPP3CA
• organism: Homo sapiens (Human)
• sequence length: 521 AA
• subunit structure: heterodimer of alpha and beta chain (human calcineurin heterodimer)
• subcellular location: nucleus
• secondary structure: 27% helical, 11% beta sheet
• ligands: calcium ion, Fe (III) ion, zinc ion

Q9X0E6, 1KR4:

• name: divalent-cation tolerance protein CutA
• gene: cutA
• organism: Thermotoga maritima (strain ATCC 43589 / MSB8 / DSM 3109 / JCM 10099)
• sequence length: 101 AA
• subunit structure: homotrimer
• subcellular location: cytoplasm
• secondary structure: great fraction of strands, 29% helical, 35% beta sheet

Discussion

In the first step, the ReProf results for P10775 were evaluated against the DSSP assignment. Here, DSSP was viewed as a standard of truth, because it assigns secondary structure based on the measured 3D structure by examining angles and H bonds between atoms.

The prediction of secondary structure is much better if a PSSM is used instead of the sequence. The reason is that a PSSM describes the requirements for each position better than the amino acid sequence, because it uses evolutionary information. So it identifies for each position alternatives for the residues in the primary sequence, that don't alter the overall structure of the protein. The difference between the usage of big_80 or SwissProt for generating the PSSM is not that obvious, but we decided to take big_80 for the remaining proteins because it showed a slightly better performance in our test with the example protein P10775.

For all proteins these ReProf results were compared to PsiPred and DSSP, to see how much the methods agree in the secondary structure assignment. The methods agree for most residues. The highest discrepancies can be observed for the prediction of beta strands, which shows that these are not as easy to predict as alpha helices or loops. A reason for this could be that beta strands are less frequent than alpha helices in most proteins, as can be seen in the informations taken from UniProt and PBD.

Other method for prediction of secondary structure are GOR, Jpred and PHDsec. Another secondary structure assignment tool is STRIDE.

Disordered protein

Lab journal

Result

IUPred

IUPred performs prediction of intrinsic disordered regions of proteins by the observation of pairwise energy content from proteins with known structures. The results of IUPred fall into 3 categories: long (disordered regions), short (disordered regions) and globular (regions of protein where pairwise interactions between residues are more potential).

For the prediction of disordered regions (prediction mode long and short), position-specific score is assigned to each residue of the query sequence. The score indicates the tendency that the corresponding residue belongs disordered region. Following are the profiles of disorder tendency generated by web-tool of IUPred:

BCKDHA

• Profiles for disorders and globular regions of BCKDHA
• 

  Profile of long range and short range disorders

• 

  Difference between scores of long range disorders and short range disorders

• 

  Prediction of globular regions

P10775

• Profiles for disorders and globular regions of P10775
• 

  Profile of long range and short range disorders

• 

  Difference between scores of long range disorders and short range disorders

• 

  Prediction of globular regions

Q9X0E6

• Profiles for disorders and globular regions of Q9X0E6
• 

  Profile of long range and short range disorders

• 

  Difference between scores of long range disorders and short range disorders

• 

  Prediction of globular regions

Q08209

• Profiles for disorders and globular regions of Q08209
• 

  Profile of long range and short range disorders

• 

  Difference between scores of long range disorders and short range disorders

• 

  Prediction of globular regions

Statistics

• Relations between profiles of long and short disorders
• 
• 

Metadisorder

• Profile of raw scores and predicted globular regions
• 

  Predicted disordered and globular regions of BCKDHA

• 

  Predicted disordered and globular regions of P10775

• 

  Predicted disordered and globular regions of Q9X0E6

• 

  Predicted disordered and globular regions of Q08209

DisProt

Because DisProt dose not contain all uniprot sequences, we have searched for homologous sequences in DisProt for the protein sequences.

• Disordered regions found in DisProt (yellow: whole protein, red:disordered regions, blue:ordered regions)
• 

  Homologous sequence for BCKDHA in DisProt (E-value: 0.19). Homologous region is 47-127 (in BCKDHA 351-432).

• 

  Homologous sequence for P10775 in DisProt (E-value: 1.4e-24). Homologous region is 780-985 (in P10775 248-456).

• 

  Homologous sequence for Q9X0E6 in DisProt (E-value: 0.34). Homologous region is 10-90 (in Q9X0E6 12-101).

• 

  There is an entry for Q08209 in DisProt.

Discussion

IUPred

Structural stability of Q9X0E6. Red parts have symmetry-related crystal contacts (within 5 Å). Thickness of backbone represents variation of B-values.

• Generally the profiles of long and short disorders are similar because they are overall highly correlated (except for protein Q9X0E6).
• At both ends of the protein short disorder scores are much higher. This reflects the fact that residues at ends of proteins have higher spatial flexibility and are structurally more unstable.
• High short disorder scores of Q9X0E6 can be explained by its structure.
  • As is shown in its X-ray structure, at the both ends of the thick representation of backbone indicates high B-values which mean the conformation of residues is either very flexible or even undefined.
  • While red parts of the protein show symmetry-related crystal contacts (within 5 Å), the remaining parts have barely symmetry-related crystal contacts.
  • The overall lower long disorder score may be explained by the fact that the protein still fold into a definite 3D structure, despite of local flexibility.
• Q9X0E6 also falls into different category in comparison to the other 3 proteins.
  • As is described in InterPro its function is not clear but should have a role in signal transduction.
  • The other 3 proteins are either subunits or inhibitor of enzymes.

MetaDisorder

TODO: discussion

• In comparison to IUPred, MetaDisorder seems to be more sensitive to input data. It finds out more short structural regions that locate in disordered regions.
  • For sequence Q08209, the prediction result of MetaDisorder shows almost the same disordered regions which are annotated in DisProt.
• Generally IUPred and MetaDisorder share very similar results.
  • For sequence Q9X0E6, the predicted results are most dissimilar. The annotation of homologous sequence in DisProt can not show significant information for comparison to prediction methods because the E-value of local alignment is too high.

Transmembrane helices

Lab journal

Result

Discussion

Signal peptides

Lab journal

Result

SignalP predictions

The following diagrams show the C- (cleavage site), S- (signal peptide) and Y- (combined cleavage site) scores for the three proteins according to SignalP version 4.1. The combined cleavage site score combines the cleavage score with the slope of the signal peptide score to optimize the recognition of cleavage sites.

For P02768 and P11279 signal peptides are predicted, with the clevage site between position 18 and 19 for P02768 and between 28 and 29 for P11279. For P47863, no signal peptide is predicted.

SignalP version 3.0 (results see /mnt/home/student/schillerl/MasterPractical/task3/signalp/) came to the same result for P02768 and P11279. However for P47863 it predicts a signal peptide with cleavage site between positions 54 and 55 (neural network) or 56 and 57 (hidden markov model), although only with the probability 0.723 compared to near 1 for the other two proteins.

Known signal peptides

On the Signal Peptide Website there are entries for P02768 and P11279 but not for P47863:

Discussion

The predictions of the newest version of SignalP agree with the confirmed signal peptides. The older version predicted a signal peptide in P47863, where no one is. According to UniProt, P47863 has transmembrane helices, so these might be mistaken for a signal peptide by the old version because they resemble each other.

Other methods for signal peptide prediction are Phobius, PrediSi and Signal-3L.

GO terms

Lab journal

Result

GOPET

Most terms concerning the catalytic activity (GO:0003824, GO:0016491, GO:0016624, GO:0003863, GO:0003826, GO:0047101) are consitent with the knowledge about the enzyme activity of the 2-oxoisovalerate dehydrogenase (see biochemical description of MSUD). Also the terms about metal binding (GO:0030955, GO:0046872) correspond to the characterization in PDB.

ProtFun

############## ProtFun 2.2 predictions ##############

>gi_11386135

# Functional category                  Prob     Odds
  Amino_acid_biosynthesis              0.187    8.520
  Biosynthesis_of_cofactors            0.246    3.413
  Cell_envelope                        0.035    0.581
  Cellular_processes                   0.041    0.560
  Central_intermediary_metabolism   => 0.321    5.096
  Energy_metabolism                    0.208    2.310
  Fatty_acid_metabolism                0.023    1.738
  Purines_and_pyrimidines              0.257    1.059
  Regulatory_functions                 0.031    0.194
  Replication_and_transcription        0.170    0.636
  Translation                          0.047    1.078
  Transport_and_binding                0.029    0.071

# Enzyme/nonenzyme                     Prob     Odds
  Enzyme                            => 0.769    2.683
  Nonenzyme                            0.231    0.324

# Enzyme class                         Prob     Odds
  Oxidoreductase (EC 1.-.-.-)          0.178    0.857
  Transferase    (EC 2.-.-.-)          0.238    0.690
  Hydrolase      (EC 3.-.-.-)          0.190    0.601
  Lyase          (EC 4.-.-.-)          0.076    1.614
  Isomerase      (EC 5.-.-.-)          0.010    0.321
  Ligase         (EC 6.-.-.-)       => 0.085    1.673

# Gene Ontology category               Prob     Odds
  Signal_transducer                    0.098    0.458
  Receptor                             0.006    0.038
  Hormone                              0.001    0.206
  Structural_protein                   0.005    0.170
  Transporter                          0.025    0.226
  Ion_channel                          0.009    0.163
  Voltage-gated_ion_channel            0.004    0.170
  Cation_channel                       0.010    0.215
  Transcription                        0.060    0.470
  Transcription_regulation             0.053    0.427
  Stress_response                      0.010    0.110
  Immune_response                      0.012    0.136
  Growth_factor                        0.009    0.609
  Metal_ion_transport                  0.012    0.025

//

The protein is predicted to have a function in the central intermediary metabolism, be an enzyme and belong to the enzyme class EC 6 (ligase). The last aspect is not correct, since it is a oxidoreductase (compare Information from UniProt and PDB).

Pfam

Pfam sequence search gives one significant Pfam-A match:

• E1_dh (dehydrogenase E1 component, PF00676)
  • use thiamine pyrophosphate as cofactor
  • includes pyruvate dehydrogenase, 2-oxoglutarate dehydrogenase and 2-oxoisovalerate dehydrogenase
  • members of multienzyme complex
  • interactions: E1_dh, Transketolase_C (transketolase, C-terminal domain), Transket_pyr (transketolase, pyrimidine binding domain)
  • 9023 sequences
  • belongs to clan THDP-binding (CL0254): thiamin diphosphate-binding superfamily

Discussion

The GOPET results give a good overview about the catalytic and binding activities of our protein, of which most are consitstent with the current knowledge. If the enzyme can really accept the other substrates pyruvate, 2-dehydropantoate and acetoin as the prediction suggests is not clear. It is possible that these activities were only predicted because of the high sequence identity to pyruvate dehydrogenase and other dehydrogenases. The fact that the confidences for these predictions are not as high as for some of the others, argues for this interpretation.

That ProtFun predicted the false enzyme class for our protein shows that this prediction is not always easy. In support of the method it has to be stated, that the probability and odds values for the different enzyme classes are close to each other. Also these values for the "right" enzyme class (EC 1) are some of the higher ones.

Pfam helps to find related proteins that are clustered into families that have common domains. Families are grouped together in clans, so one can also find out more about the distant relationship between proteins. Pfam found a family with different dehydrogenases from diverse organisms that are homolog to our protein. They have in common to be the first part of a large enzyme complex. So the concept of oxidative decarboxylation has adapted to different substrates and different organisms during evolution, but still uses the same basic principle.

Other methods for GO term prediction are GOPred, Blast2GO and GOCat.