Prediction of hydrophobic regions effectively in transmembrane proteins using digital filter

doi:10.4236/jbise.2011.48072

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J. Biomedical Science and Engineering, 2011, 4, 562-568

doi:10.4236/jbise.2011.48072 Published Online August 2011 (http://www.SciRP.org/journal/jbise/

JBiSE

Published Online August 2011 in SciRes. http://www.scirp.org/journal/JBiSE

Prediction of hydrophobic regions effectively in

transmembrane proteins using digital filter

Jayakishan M e he r 1, Mukesh Kumar Raval2, Gananath Dash3, Pramod Kumar Meher4

1Department of Computer Science and Engineering, Vikash College of Engineering for Women, Bargarh, Odisha, India;

2Department of Chemistry, G. M. College, Sambalpur, Odisha, India;

3School of Physics, Sambalpur University, Jyoti Vihar, Odisha, India;

4Department of Embedded System, Institute for Infocomm Research, Singapore City, Singapore.

Email: jk_meher@yahoo.co.in; mraval@yahoo.com; gndash@ieee.org; pkmeher@i2r.astar.edu.sg

Received 18 June 2011; revised 8 July 2011; accepted 20 July 2011.

ABSTRACT

The hydrophobic effect is the major factor that

drives a protein molecule towards folding and to a

great degree the stability of protein structures.

Therefore the knowledge of hydrophobic regions and

its prediction is of great help in understanding the

structure and function of the protein. Hence deter-

mination of membrane buried region is a computa-

tionally intensive task in bioinformatics. Several pre-

diction methods have been reported but there are

some deficiencies in prediction accuracy and adapta-

bility of these methods. Of these proteins that are

found embedded in cellular membranes, called as

membrane proteins, are of particular importance

because they form targets for over 60% of drugs on

the market. 20% - 30% of all the proteins in any or-

ganism are membrane proteins. Thus transmem-

brane protein plays important role in the life activity

of the cells. Hence prediction of membrane buried

segments in transmembrane proteins is of particular

importance. In this paper we have proposed signal

processing algorithms based on digital filter for pre-

diction of hydrophobic regions in the transmembrane

proteins and found improved prediction efficiency

than the existing methods. Hydrophobic regions are

extracted by assigning physico-chemical parameter

such as hydrophobicity and hydration energy index

to each amino acid residue and the resulting numeri-

cal representation of the protein is subjected to digi-

tal low pass filter. The proposed method is validated

on transmembrane proteins using Orientation of

Proteins in Membranes (OPM) dataset with various

prediction measures and found better prediction ac-

curacy than the existing methods.

Keywords: Hydrophobic Region; Transmembrane

Protein; Wavelet Transform; Physico-chemical

Parameter; Digital Filter

1. INTRODUCTION

Proteins are important functional molecules in living

organisms. Every protein assumes a specific shape and

performs a specific function. A key characteristic of the

protein is the three-dimensional structure into which

linear chain folds which is referred to as tertiary struc-

ture. This structure results in electrochemical interaction

domains of protein and gives it the ability to interact

with other proteins and ligands to carry out specific

functions [1]. Of these proteins that are found embedded

in cellular membranes, called as membrane proteins, are

of particular importance because they form targets for

over 60% of drugs on the market. 20% - 30% of all the

proteins in any organism are membrane proteins [2].

Knowledge of segments of transmembrane proteins, the

bends in helices and the membrane buried regions help

in the study of tertiary structure. Understanding the

structure of a protein helps in understanding the role

played by that protein.

It is widely known that amino acid sequences of pro-

teins carry all the information needed to form their three-

dimensional structures [3]. Thus, the protein structure

theoretically can be predicted based solely on amino acid

sequences. Structural or biological information such as

secondary structure [4,5], kink [6,7] and hydrophobic

regions [8] are derived by assigning a physicochemical

index to an amino acid sequence. The knowledge of hy-

drophobic regions and its prediction is of great help in

understanding the structure and function of the protein.

Several steps have been taken to predict these regions.

The transmembrane structure and the membrane buried

region are shown in Figure 1.

In sliding window averaging technique the physico-

J. K. Meher al. / J. Biomedical Science and Engineering 4 (2011) 562-568 563

Figure 1. Definition of transmembrane structures. [A;D] is a

transmembrane helix (TMH) and [B;C] represents the trans-

membrane segment (TMS)which is the embedded part of

TMH.

chemical value for each residue inside the frame is

summed up and assigned in the middle of the window.

Then the window slides across the sequence [9]. How-

ever, the relationship between segments and structure

does not always correspond. As extracting structural

information from amino acid sequences alone is difficult,

various prediction methods have been developed using

evolutionary information and neural network [10].

The span of window size is investigated in [11], which

reflected the interior and exterior portions of proteins.

Hydrophobicity profiles using the shortest window size

were noisy, and size less than seven residues produce

unsatisfactory result. On the other hand, long spans

tended to lose structural segments. Thus the optimum

choice between hydrophobic region and position of

amino acid residues was obtained with a nine for globu-

lar proteins. The problem with this technique is noisy in

the smoothed profiles, which makes it particularly diffi-

cult to find segments in case of globular proteins.

Recently signal processing methods play a major role

in predicting hydrophobic regions. Fourier analysis has

been applied to predict secondary structures from a se-

quential dotted hydrophobicity index [12]. The utilities

of the Fourier transform lie in its ability to analyze a

signal in the time domain for its frequency content. The

transform works by first translating a function in the

time domain into a function in the frequency domain.

The signal can then be analyzed for its frequency content

because the Fourier coefficients of the transformed func-

tion represent the contribution of each sine and cosine

function at each frequency. Although the Fourier analy-

sis is useful for acquiring structural information, this

method tends to cause positional error.

Wavelets are mathematical functions that divide data

into different frequency components. This approach has

advantages over traditional Fourier methods in analyzing

data where the signal contains discontinuities or high

frequency noise. Recently, the use of wavelet transform,

both continuous and discrete in the Bioinformatics field

is promising [13]. Continuous Wavelet Transform (CWT)

allows one-dimensional signal to be viewed in a more

discriminative two-dimensional time-scale representa-

tion. CWT is calculated by the continuous shifting of the

continuously scalable wavelet over the signal. In discrete

wavelet transform (DWT) a subset of scales and posi-

tions are chosen, in which the correlation between the

signal and the shifted and dilated waveforms are calcu-

lated. Consequently, the signal is decomposed into sev-

eral groups of coefficients, each containing signal fea-

tures corresponding to a group of frequencies. Small

scales refer to compressed wavelets, depicted by rapid

variations appropriate for extracting high frequency fea-

tures of the signal. An important attribute of wavelet

methods is that, due to the limited duration of every

wavelet, local variations of the signal are better extracted

and information on the location of these local features is

retained in the constituent waveforms. DWT has been

applied on hydrophobicity signals in order to predict

hydrophobic cores in proteins [14,15]. Protein sequence

similarity has also been studied using DWT of a signal

associated with the average energy states of all valence

electrons of each amino acid [16]. Wavelet transform

has been applied for transmembrane structure prediction

[17]. DWT has been used to decompose the amino acids

of TM proteins into a series of structures in different

layers, then predicting the location of TMHs according

to the information of the amino acids sequence in dif-

ferent scales [18]. A method based on discrete wavelet

transform has been developed to predict the number and

location of TMHs in membrane proteins [19].

The existing methods have their limitations in terms

of accuracy. As mentioned above, numerous attempts

have been made by researchers to define the relation

between interior and exterior regions directly from the

amino acid sequence. However, it is difficult to divide

interior and exterior position of amino acid residues by

assigning a hydrophobicity threshold, because of unac-

ceptable noise level. Hence there is a need to develop

advanced algorithm for faster and accurate prediction of

hydrophobic regions. This motivates to develop novel

approach based on digital filtering method to effectively

predict these regions in transmembrane α-helices.

The rest of the paper is organised as follows. Sec-

tion-2 deals with the proposed method for prediction of

hydrophobic regions in transmembrane α-helices. This

paper focuses on the development of signal processing

algorithms based on digital filter. Section-3 deals with

discussion of simulation results of proposed methods

using standard data set in terms of prediction measures.

Section-4 presents the conclusions of this paper.

J. K. Meher et al. / J. Biomedical Science and Engineering 4 (2011) 562-568

564

2. PROPOSED METHOD FOR

PREDICTION OF HYDROPHOBIC

REGIONS

The signal processing approach plays a major role in

prediction of membrane buried regions in amino acid

sequence and separate variations in signal from back-

ground noise. In this paper the membrane buried regions

in transmembrane proteins is determined effectively us-

ing digital filter. Previously, methods for hydrophobic

region prediction using only amino acid sequences have

been reported [20,21] and it was shown that hydropho-

bicity tended to be low at the loop region. These studies

suggested that hydrophobic residues were buried in the

core of protein that could be predicted using a hydro-

phobicity index. The minimal hydrophobicity profile

corresponded to the loop region, and the turn region

could be predicted effectively. Highly hydrophobic re-

gions tended to form a α-helix. Thus a hydrophobicity

plot involving hydrophobicity index is useful for the

purpose of prediction of hydrophobic regions in amino

acid sequences. We made use of digital filter to extract

low frequencies and detected the hydrophobic regions

more effectively.

In this section a technique for identification of hydro-

phobic regions in transmembrane helices using digital

filter is described. As it is seen that hydrophobic regions

are observed in low frequencies, suitable digital low pass

filter can easily filter low frequency components and

thus hydrophobic regions can be extracted. A widely

used family of low pass filters is the set of Butterworth

filters [22,23]. Butterworth filters are characterized by a

magnitude response that is maximally flat in the pass-

band and monotonic overall. A low pass Butterworth

filter of order n has the following magnitude response.



1, 1

Hf n





(1)



HF, where Fc is called the 3-dB cutoff

frequency of the filter. The magnitude response of butter

filters with different filter orders are shown in Figure 3.

As the order increases, the magnitude response comes

closer and closer to the ideal low pass characteristic. The

transfer function of the low pass Butterworth filter of

order n with radian cutoff frequency ωc = 2πFc can be

expressed as follows.



12 2

ann n

Hs sas as





 



(2)

where ωc = 1 rad/sec or Fc = 1/2π Hertz.

Cutoff frequency ωn is that frequency where the mag-

nitude response of the filter is 12. For butter, the

normalized cutoff frequency ωn must be a number be-

tween 0 and 1, where 1 corresponds to the Nyquist fre-

quency, π radians per sample. A butterworth low pass

filter of order 2 with cut-off frequency ωn = 0.4 can per-

fectly select the hydrophobic regions of the protein se-

quences. The pole-zero plot and frequency response of

second order low pass butterworth filter are shown in

Figures 2 and 3 respectively. The filter is used to let

pass a low frequency component of a signal and attenu-

ates a high frequency component of the signal.

The Butterworth low pass filter gives rise to patterns

that are distinct between the interior and exterior loca-

tions. To analyze the protein sequence for prediction of

hydrophobic regions, it is first transformed into a nu-

merical signal based on hydrophobicity indices of resi-

dues along a protein sequence. The numerical hydro-

phobicity indices of 20 amino acid residues obtained

from Hyperchempro 8.0 software of HyperCube Inc.,

Figure 2. Pole-Zero plot of Butterworth low pass filter of order

n = 2

Figure 3. Magnitude response plot of Butterworth low pass

filter of order n = 1, 2, 3 and 4.

J. K. Meher al. / J. Biomedical Science and Engineering 4 (2011) 562-568 565

USA (Table 1) are assigned to the protein sequence. The

resulting numerical sequence is passed through the pro-

posed lowpass filter and plotted. The peaks observed in

the plot indicate the hydrophobic regions.

For a given protein sequence x[i], the numerical se-

quence using hydrophobicity index, x[n] is expressed as

x[i]= [KYAAKEGDPNQLSKEL]

x[n]= [–3.9 –1.3 1.8 1.8 –3.9 –3.5 –0.4 –3.5 –1.6 –3.5

–3.5 3.8 –0.8 –3.9 –3.5 3.8].

The filter output y[n] is plotted for observation of

peaks at low frequency regions.

A step-by-step procedure of the proposed method for

prediction of hydrophobic regions is as follows:

1) Convert the protein sequence into numerical se-

quence using hydrophobic indices of each amino acid

residue;

2) The resulting numerical sequence is passed through

proposed low pass filter that would select low frequency;

3) Plot the magnitude response and determine the

threshold to observe peaks where the low frequency re-

gions are dominant;

4) Locate the hydrophobic regions by locating the en-

ergy peaks in the filtered signal.

The sliding window averaging technique and fre-

quency domain and wavelet analysis are then compared

with proposed method based on corresponding results.

Table 1. Physico-chemical properties of amino acids.

Amino acids Hydrophobicity Hydration Energy

A Alanine 1.8 2.06

C Cysteine 2.5 –0.61

D Aspartic acid –3.5 0.82

E Glutamic acid –3.5 1.04

F Phenylalanine 2.8 –0.33

G Glycine –0.4 1.48

H Histidine –3.2 –7.6

I Isoleucine 4.5 3.07

K Lysine –3.9 –2.8

L Leucine 3.8 3.01

M Methionine 1.9 1.43

N Asparagine –3.5 –4.43

P Proline –1.6 –1.33

Q Glutamine –3.5 –3.94

R Arginine –4.5 –9.91

S Serine –0.8 –5.79

T Threonine –0.7 –4.18

V Valine 4.2 2.79

W Tryptophan –0.9 –3.49

Y Tyrosine –1.3 –7.13

Hydration Energy Index

In this section, we discuss a novel numerical representa-

tion of protein sequence generated by a physico-chemi-

cal property of amino acid residues called hydration en-

ergy to detect the membrane buried regions in trans-

membrane proteins. There are various physico-chemical

properties namely; hydration energy, dipole moment,

electron ion interaction pseudopotential (EIIP), polariza-

bility, refractivity, molar surface area and molar volume

which are frequently used for quantitative structure ac-

tivity relationship (QSAR) of molecules. Of these prop-

erties, specifically the numerical sequence based on the

hydration energy is found to produce sharp peak at

membrane buried region when used in digital filtering.

Hydration energy reflects the hydrophilicity (or hydro-

phobicity) of molecules. Hence it is correlated with the

solution of the problem. The hydration energy indices of

amino acids are obtained from Hyperchempro 8.0 soft-

ware of HyperCubeInc, USA (Table 1). The transmem-

brane protein sequence is first transformed into a nu-

merical signal by assigning hydration energy indices of

residues along a protein sequence. The resulting nu-

merical sequence is subjected to the proposed low pass

filter and plotted. The peaks observed in the plot indicate

the membrane buried regions.

3. RESULT AND DISCUSSION

We have used the proposed digital low pass filter to

detect the hydrophobic regions using numerical repre-

sentation based on hydrophobicity indices and hydration

energy of amino acid residues. List of transmembrane

proteins and their coordinate files were obtained from

the Orientation of Proteins in Membranes (OPM) data-

base at College of Pharmacy, University of Michigan

(http://www.phar.umich.edu). Transmembrane proteins

from OPM data sets are used as bench mark for this

purpose. In a good number of cases the proposed method

performed well.

The performance analysis of various methods can be

made by prediction measures such as accuracy (A), pre-

cision (P) and recall (R) which are defined in terms of

four parameters true positive (tp), false positive (fp), true

negative (tn) and false negative (fn) (Table 2). tp denotes

the number of actual buried regions and are also pre-

dicted as buried regions, fp denotes the number of actu-

ally residues exposed but are predicted to be buried, tn is

the number of actually exposed and also predicted to be

exposed, and fn is the number of actually buried and pre-

dicted to be exposed.

3.1. Accuracy

The accuracy of prediction of hydrophobic regions in

amino acid sequence is defined as the percentage of bur-

J. K. Meher et al. / J. Biomedical Science and Engineering 4 (2011) 562-568

566

ied regions correctly predicted of the total buried and

exposed present. It is computed as follows:

umber of correct buired predictions

Total number of buired and exposed

ppnn

Atftf







(3)

3.2. Precision

JBiSE

It is defined as the percentage of buried regions correctly

predicted to be one class of the total buried predicted to

be of that class. Precision is computed as:

umber of correctly predicted buired

Total number of buired predicted

Ptf





(4)

3.3. Recall

It is defined as the percentage of the buried regions that

belong to a class that are predicted to be that class. Re-

call is computed as:

Number of correctly predicted buired

Total number of actual buired

Atf





(5)

We attempted to predict hydrophobic regions in

transmembrane proteins, using digital low pass filter.

The sliding window averaging technique and wavelet

analysis were then compared with the proposed method

based on corresponding results.

The models as well as sequence of the transmembrane

proteins are obtained from PDBTM database. When se-

quence file in fasta format is submitted to TMHMM

pred server then the sections for transmembrane regions

(TM), residues buried (rbu) and residues outside exposed

(rex) regions are identified. In transmembrane protein

Bovine Cytochrome BC1 Complex with Stigmatellin

bound having PDB Id: 2a06, proposed method have de-

tected all membrane buried regions as shown in Figure

4. The figure shows the hydrophobicity plot of the

original sequence, first order filter response and second

order filter response. The hydrophobicity profile smoo-

thed by the low frequencies extracted using digital low

filter of second order shows buried residues indicating

sharp peaks remained in the low frequency. Above the

threshold shows the membrane buried regions which is

embedded part the transmembrane helix (TMH). On the

other hand, the profile of the sliding window averaging

technique was hard to find segments corresponded to

buried residues. Table 3 summarizes the prediction ac-

curacy of hydrophobic regions by various methods such

as the sliding window averaging technique, wavelet

analysis and proposed filter method. Table 4 shows the

average prediction accuracy of hydrophobic regions of

88 dataset by the various methods. It is found that the

prediction accuracy of proposed method is the highest of

all tested cases. Thus the proposed method shows im-

proved accuracy in predicting hydrophobic regions.

The profile of assigning hydrophobicity index to

amino acid sequence is inherently noisy. To eliminate

noise from raw functions, various methods have been

proposed. Although the sliding window averaging tech-

nique is in wide use, the precise region of the hydropho-

bic region is difficult to determine because of the aver-

aging calculation. We extracted the low frequencies

from raw data using digital filter and investigated the

relationship between low frequencies of proteins. The

efficiency of filtering analysis for interior/exterior pre-

diction indicated the detection of segments related to a

Table 2. Contingency table for evaluation metrics.

Actual Predicted Residue buried (rbu) Residue exposed (rex)

Residue buried (rbu)tp f

Residue exposed (rex)fn t

Figure 4. Hydrophobicity plot of Bovine Cytochrome BC1

Stigmatellin bound using (a) raw sequence; (b) low pass filter

of 1st order; (c) low pass filter of 2st order. rbu and rex are

residues buried within TM and residues exposed separated by

threshold.

J. K. Meher al. / J. Biomedical Science and Engineering 4 (2011) 562-568 567

Table 3. Prediction accuracy of various methods using OPM datsets.

Prediction Measures

PDB Id Methods

A P R

sliding window averaging 0.66 0.66 1

wavelet transform 0.8 0.66 1

2a06

Bovine Cytochrome BC1 Stigmatellin bound

Digital filter 1 1 1

sliding window averaging 0.76 0.76 1

wavelet transform 0.83 0.83 1

3a0b

DXR from Thermooga maritia complex with fosmidmycin and NADPH

Digital filter 0.91 0.91 1

sliding window averaging 0.66 0.5 1

wavelet transform 0.75 0.66 1

3a3y

sodium-potassium pump with bound potassium and ouabain

Digital filter 1 1 1

sliding window averaging 0.6 0.5 1

wavelet transform 0.7 0.75 1

1A91

Subunit C of F1F0 ATP synthase of E. Coli NMR, 10 structures

Digital filter 0.88 0.87 1

sliding window averaging 0.8 0.9 1

wavelet transform 0.8 0.9 1

3abk

Bovine heart cytochrome C oxidase at the NO-bound fully reduced state

Digital filter 1 1 1

Table 4. Average prediction accuracy of 88 transmembrane

protein datasets.

Methods A P R

Sliding window averaging 0.69 0.66 1

Wavelet transform 0.84 0.79 1

Digital filter 0.94 0.92 1

hydrophobic region at peak, thus facilitating the accurate

prediction of buried residues directly from amino acid

sequences.

4. CONCLUSIONS

Digital low pass filter plays a vital role in the prediction

of hydrophobic regions in transmembrane proteins. The

proposed method is not only fast but also has improved

accuracy as compared to existing methods. However

prediction of membrane buried region in the protein de-

pends on the features of aminoacid sequence. Feature

vector with hydrophobicity and hydration energy indices

of amino acid residues are used for numerical represen-

tation. The prediction accuracy of proposed method is

the highest of all tested cases. It is found that the pro-

posed methods show better accuracy in predicting hy-

drophobic regions.

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