Sequence and multiple alignments
Contents
Sequence Alignments
Database search
We used different tools for the search in a non-reduntant(NR) database like BLAST, FASTA and PSI-BLAST. Because of the absence of the database in a hmm format, we decided not to integrate the hhpred web-results. These results are not comparable.
We called BLAST and FASTA with the standard parameters.
blast -p blastp -i 1a6z.fasta -d /data/nr/nr -o blastp_1a6z_on_NR.txt runtime 5:34
../../Desktop/fasta-36.3.4/bin/fasta36 -q 1a6z.fasta /data/nr/nr >fasta_1a6z_on_nr.txt the runtime was 10:44.
PSI-BLAST was used with different parameter settings.
blastpgp -i 1a6z.fasta -d /data/nr/nr runtime 21:40
blastpgp -i 1a6z.fasta -d /data/nr/nr -j 6 -e 10E-6 > psiblast_on_NR_itera3_e-val_10E-6.txt runtime 23:49
blastpgp -i 1a6z.fasta -d /data/nr/nr -j 3 -e 10E-6 > psiblast_on_NR_itera6_e-val_10E-6.txt runtime 15:08
blastpgp -i 1a6z.fasta -d /data/nr/nr -j 3 > psiblast_on_NR_itera3.txt runtime 9:41
blastpgp -i 1a6z.fasta -d /data/nr/nr -j 6 > psiblast_on_NR_itera6.txt runtime 23:30
We also compared the runtime of the different tools. Surprisingly for PSI-BLAST, in our case, the e-Value and the number of iterations had no impact on the results, so we used PSI-BLAST with standard parameters for the comparison.
As we looked for an overlap between the reference sequences given by HSSP, no overlap occured.
The HSSP reference is given with UniProt AC, so we mapped the ID's on the GenBank ID's using PIR<ref>pir.georgetown.edu/pirwww/search/idmapping.shtml</ref>. Than we compared the ID's without any result.
We also mapped the PDB ID's found by FASTA to UniProt. Here we found a small overlap of about 34 Proteins.
But the issue is, that the highest identity given by a pdb entry is abput 40%.
Multiple Alignments
Used Sequences
SeqIdentifier | Seq Identity | Protein description | |
---|---|---|---|
99-90% Sequence Identity | |||
AAG29574.1 | 94% | !EXCLUDED hemochromatosis splice variant | |
89-60% Sequence Identity | |||
AAO47091.1 | 87% | hemochromatosis | |
NP_620576.1 | 86% | hereditary hemochromatosis protein isoform 7 precursor | |
NP_620577.1 | 86% | hereditary hemochromatosis protein isoform 8 precursor | |
AAH74721.1 | 84% | HFE protein | |
NP_620578.1 | 78% | hereditary hemochromatosis protein isoform 9 precursor | |
AAF01222.1 | 75% | !EXCLUDED hereditary haemochromatosis protein precursor | |
Q9GL42.1 | 68% | HFE_DICSU RecName | |
Q9GL43.1 | 68% | HFE_DICBI RecName | |
NP_001166905.1 | 63% | hereditary hemochromatosis protein homolog isoform 2 precursor | |
EDL86571.1 | 62% | hemochromatosis, isoform CRA_c | |
P70387.1 | 61% | HFE_MOUSE | |
59-40% Sequence Identity | |||
XP_001511789.1 | 41% | PREDICTED: similar to MHC class I heavy chain antigen | |
XP_002713938.1 | 40% | PREDICTED: histocompatibility 2, Q region locus 10-like | |
39-20% Sequence Identity | |||
AAR25266.1 | 37% | MHC class I heavy chain | |
XP_585880.4 | 37% | PREDICTED: histocompatibility 2, Q region locus 10-like | |
AAX51393.1 | 36% | MHC class I antigen alpha chain precursor | |
BAD23967.1 | 35.7% | MHC class I antigen | |
AAZ30022.1 | 34% | MHC class I antigen alpha chain |
Because our first results were really bad, we are given the advice to include/exclude some of our sequences. We decided to exclude the two sequences, that cause the most gaps. Both had around ~120 aminoacids, so they caused the insertion of long strands of gaps that lead to bad conservated regions.
Excluded sequences from all MSAs:
- tr|Q9HC71|Q9HC71_HUMAN (AAG29574.1 / 105 aa)
- gi|6010711|gb|AAF01222.1|AF184234_1 (129 aa)
Thus we have no more sequences in the region of 99 to 90% sequenced identity, but the one we had was only a fragment and therefore only partial alignmentable. Without these sequences our alignments and other analysis should get quite better.
Programs
All programs except cobalt were preinstalled at our VM. Cobalt was downloaded from ftp://ftp.ncbi.nlm.nih.gov/pub/cobalt/executables/2.0.1/ (file depending on system architecture) and extracted. Afterwards the current directory was changed to ~/usr/bin and a symbolic link was created (ln -s <extraced-cobalt-runnable> cobalt).
Cobalt
call:
- cobalt -i input.txt -norps T -outfmt clustalw > cobalt.aln
switches:
- -norps T: use no downloaded database
- -outfmt clustalw: use output formatting of clustalw
time:
- 0,55s user
- 0,02s system
ClustalW
call:
- clustalw input.txt
time:
- 1,32s user
- 0,04s system
Muscle
call:
- muscle -in input.txt -clw -out muscle.aln
switches:
- -clw: use output formatting of clustalw
- -out muscle.aln: write output to muscle.aln
time:
- 1,25s user
- 0,00s system
T-Coffee
standard
call:
- t_coffee input.txt
time:
- 11,00s user
- 0,18s system
3dcoffee/expresso
Unfortunately were we not able to run the 3dcoffee, because it crashed everytime. Therefore we used -mode expresso.
call:
- t_coffee input.txt -mode expresso
switches:
- -mode expresso: use special mode with 3d structure supported alignment
time:
- 4m22s user
- 0,11s system
Alignments
All programs worked fine and produced a tight aligned part from the mid to the end (position ~170 to 390) with high conservation and of good quality. Without the two short sequences, all extremely gapped parts in the alignments disappeard. Even the use of the structure supported alignment at t-coffee resulted in an nice alignment. But our best pdb entry was at ~40% sequence identity, so gaps had to be inserted in order to incorporate the structure. This problem affects also the following sections, like the amount and quality of conserved regions or the amount of introduced gaps.
All programs except the special mode of t-coffee have an clearly obvious gap between ~160 and ~170, by expresso it is between ~190 - ~200. That gap is caused by insertions at the hfe protein in the rat and mouse.
Residues
But in order to present a visible result, we used the conserved region calculation of JalView.
The values ranges from 0 (no conservation at all) to 11 (full conserved row).
name | 0 | 2 | 5 | 7 | 9 | 11 | |
---|---|---|---|---|---|---|---|
quality | very bad | medium | very good | length of msa | |||
cobalt | 161 | 21 | 37 | 23 | 16 | 34 | 402 |
clustalW | 156 | 26 | 34 | 22 | 0 | 33 | |
muscle | 157 | 22 | 33 | 23 | 11 | 34 | |
t-coffee (std) | 193 | 23 | 34 | 20 | 17 | 34 | |
t-coffee (expresso) | 280 | 16 | 29 | 16 | 11 | 26 |
It is clearly visible that all our alignments have a large region of bad conservation in the beginning of the alignments, propably a region of no functional importance. After position ~160 to ~200, a large block of medium to good conservation is visible. Maybe that part contains the biological function or important domains. This block ends around position ~340 to ~400.
Around .4 to .7 percentage of the alignments are no conservation and therefore gaps or many mutation. It it logical, that t-coffee expresso produces the most non-conservations because of the additional constraint to use the structural information.
Functional Important
We used the information available at UniProt for determining functional important residues and regions.
key | positions | length | description | cobalt | clustalW | muscle | t-coffee (std) | t-coffee (ex) |
---|---|---|---|---|---|---|---|---|
Glycosylation | 110 | 1 | N-linked (GlcNAc...) Potential | c2 | c2 | c1 | c2 | c2 |
Glycosylation | 130 | 1 | N-linked (GlcNAc...) Potential | c4 | c4 | c0 | c4 | c4 |
Glycosylation | 234 | 1 | N-linked (GlcNAc...) Potential | c6 | c6 | c1 | c6 | c5 |
Disulfide bond | 124 ↔ 187 | 1 | c11/c11 | c11/c11 | c11/c11 | c11/c11 | c11/c11 | |
Disulfide bond | 225 ↔ 282 | 1 | c11/c11 | c11/c11 | c11/c11 | c11/c11 | c5/c11 |
We excluded all domain and other regions, because they are of no use this time. The only important functional positions are the position of the glycosylation and the both position of the disulfide bond.
We are using the conserved region index from JalView again, cX stands for the value of conservation at this position. One can see, that the conservation of the glycosylation is only low to medium, so not important for the function of the protein. All disulfide bonds, except in expresso are perfectly conserved, that could be a result of a slightly different folding with maintaining the linking between the both cysteine residues.
Gaps
name | gaps# |
---|---|
cobalt | 85 |
clustalW | 78 |
muscle | 83 |
t-coffee (std) | 114 |
t-coffee (ex) | 166 |
There are very less gaps in the reference sequence in fraction to its length of 348 aa. Only both of the t-coffee variants create more gaps. We dont not know why the standard version produces also more gaps, but we are sure the expresso mode has to follow the contraint to align two position only if the structure matches and thus inserts more gaps.
Gaps in Secondary Structure
name | helix | beta strand | turn | no sse |
---|---|---|---|---|
cobalt | 0 | 8 | 1 | 70 |
clustalW | 0 | 9 | 0 | 1 |
muscle | 0 | 8 | 0 | 40 |
t-coffee (std) | 0 | 8 | 0 | 116 |
t-coffee (ex) | 5 | 8 | 0 | 64 |
The vast majority of the gaps were in regions with no important secondary structure and therefore broke nothing. Every alignment broke also some of the beta strands but only t-coffee (expresso) broke an helix totally. Cobalt also broke the leading turn into the helix, but not the helix itself. We were suprised by expresso, because it incorporated the secondary structure in the alignment and thus was the method, that must absolutely not brake the helix.