Protein sequence analysis based on hydropathy profile of amino acids

Xie, Xiao; Zheng, Lifei; Yu, Ying Ching; Liang, Liping; Guo, Mancai; Song, John I.; Yuan, Zhifa

doi:10.1631/jzus.b1100052

Cited by 8 publications

(13 citation statements)

References 27 publications

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“…They categorized the 20 amino acids into different types, including as a word with three to five different letters. Their processes not only describe amino acid sequence, but also determine the similarity/dissimilarity of different protein sequences [14,47,[50][51][52][53][54][55][56][57]. However, their methods only consider the physical information of the sequences that are conserved in a particular amino acid sequences.…”

Section: Discussionmentioning

confidence: 99%

“…But one distinguished limitation on their methods is the limited sample of sequences which can only determine a fraction of total sequences. Further, few group works with the converted amino acid sequences of proteins into three letter sequence based on the hydropathy profile of amino acid and algor a conditional probability as a new invariant for the protein sequences [14]. Their method can also show the distribution of amino acids at different positions in the sequences.…”

Section: Discussionmentioning

confidence: 99%

“…Several groups have worked with reduced amino acid alphabets to tackle to the above stated problems by reducing the sample size which can perform at the same level as the full alphabets in correct pair wise alignment of sequences with regards to structure similarity but low sequence identity [12,13]. Recently XIE et al [14] proposed a new method by using hydropathy group of amino acids to analyze the similarity/ dissimilarity of protein sequence based on the conditional probability of the protein sequence [14]. Studies are also done on using the substitution matrices from several protein blocks of aligned sequence segments resulting the characterization of related proteins [15].…”

Section: Introductionmentioning

confidence: 99%

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Mathematical Characterization of Protein Sequences Using Patterns as Chemical Group Combinations of Amino Acids

Das

Ray

et al. 2016

PLoS ONE

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Comparison of amino acid sequence similarity is the fundamental concept behind the protein phylogenetic tree formation. By virtue of this method, we can explain the evolutionary relationships, but further explanations are not possible unless sequences are studied through the chemical nature of individual amino acids. Here we develop a new methodology to characterize the protein sequences on the basis of the chemical nature of the amino acids. We design various algorithms for studying the variation of chemical group transitions and various chemical group combinations as patterns in the protein sequences. The amino acid sequence of conventional myosin II head domain of 14 family members are taken to illustrate this new approach. We find two blocks of maximum length 6 aa as ‘FPKATD’ and ‘Y/FTNEKL’ without repeating the same chemical nature and one block of maximum length 20 aa with the repetition of chemical nature which are common among all 14 members. We also check commonality with another motor protein sub-family kinesin, KIF1A. Based on our analysis we find a common block of length 8 aa both in myosin II and KIF1A. This motif is located in the neck linker region which could be responsible for the generation of mechanical force, enabling us to find the unique blocks which remain chemically conserved across the family. We also validate our methodology with different protein families such as MYOI, Myosin light chain kinase (MLCK) and Rho-associated protein kinase (ROCK), Na+/K+-ATPase and Ca2+-ATPase. Altogether, our studies provide a new methodology for investigating the conserved amino acids’ pattern in different proteins.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Mathematical Characterization of Protein Sequences Using Patterns as Chemical Group Combinations of Amino Acids

Das

Ray

et al. 2016

PLoS ONE

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“…The first visualization protein model was proposed by Randić et al until 2004 [19]. Some researchers have studied on graphical representation of protein sequences from different perspectives [20][21][22][23][24][25][26][27][28][29].…”

Section: Introductionmentioning

confidence: 99%

DV-Curve Representation of Protein Sequences and Its Application

Deng

Luan

2014

Computational and Mathematical Methods in Medicine

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Based on the detailed hydrophobic-hydrophilic(HP) model of amino acids, we propose dual-vector curve (DV-curve) representation of protein sequences, which uses two vectors to represent one alphabet of protein sequences. This graphical representation not only avoids degeneracy, but also has good visualization no matter how long these sequences are, and can reflect the length of protein sequence. Then we transform the 2D-graphical representation into a numerical characterization that can facilitate quantitative comparison of protein sequences. The utility of this approach is illustrated by two examples: one is similarity/dissimilarity comparison among different ND6 protein sequences based on their DV-curve figures the other is the phylogenetic analysis among coronaviruses based on their spike proteins.

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“…While Nandy [8][9][10], Nandy and Nandy [11] and Larionov et al [12] have used 2D graphical systems to determine DNA systematics, Liao et al [13,14] used the novel techniques for alignment-free phylogeny to determine sequence ancestry, Wiesner and Wiesnerova [15] found the new methodology giving better insights into germ-plasm identifiers, Gonzalez-Diaz and his group presented several papers using the concept for alignment-free prediction of polygalacturonases [16], alternative "in silico" technique for chemical research in toxicology [17] and predicting antimicrobial drugs and targets [18], Nandy et al [19] were able to model influenza hemagglutinin and neuraminidase interdependence which provided predictability to new possible viral assortments [20]. The technique of numerical characterization was extended to proteins initially by Randic et al [21] and led to several approaches being proposed [6,22,23], analyzing phylogenetic relationships between protein families [24], hydropathy profiles of amino acids [25] and others. Thus, numerical characterization of bio-molecular sequences can be considered to have wide-ranging applicability leading to acceptable results, and occasionally new insights.…”

mentioning

confidence: 99%

Rational design of peptide vaccines against the Zika virus through sequence descriptors: Techniques and Problems

Nandy¹,

Basak²

2016

IJVR

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The sudden emergence of an epidemic of Zika virus infections in South America has raised concerns of its virulence and transmission potential, especially in view of mass gatherings at carnivals, Olympic Games, Hajj and others within this year [1]; the as yet unproven link between the Zika epidemic and heightened cases of microcephaly among newborns for which the World Health Organization (WHO) have declared on February 1, 2016 the suspected association of the virus to cases of microcephaly and Guillain-Barre disease to be Public Health Emergency of International Concern [2] has added to the anxieties. The main vector of the Zika virus is the Aedes aegypti mosquito prevalent in tropical countries but whose range is increasing with the effects of global warming, recognized as causing shifts in distribution of vector-borne diseases [3]; spread of the virus through mass gatherings to other countries becomes an additional worrying possibility. The issues here are of serious concern since the Aedes aegypti mosquito is also a primary carrier of the dengue virus and Brazil has not had much success in controlling that [4]. Coming soon after the scare of Ebola virus, and with the background of the 2009 H1N1 pandemic, the MERS and SARS epidemics, the near-pandemic of H5N1 bird flu and fatalities associated with the H7N9, the Zika virus epidemic has focused questions on containment and mitigation of viral activity and further zoonotic issues that may arise.Such recurrent viral incidences and emergence necessitate a combinatorial analysis and perspective on confronting and containing the menace. Given the nature and diversity of infective viruses, it would seem difficult for such a task to be contemplated by a priori experimental means, whereas theories behind such phenomena are yet to be devised. In such a circumstance, phenomenological approaches as offered by numerical characterizations of bio-molecular sequences arising from their graphical representations hold some promise of approaching the issue. Numerical characterizations of DNA, RNA and protein sequences provide descriptors that are characteristic of each sequence, albeit depending upon the particular methodology used [5]. Developing upon initial work on DNA sequences, these descriptors have been used to characterize genes to genomes [5] and proteins [6] to proteomes [7], and have seen applications in many areas. While Nandy [8-10], Nandy and Nandy [11] and Larionov et al [12] have used 2D graphical systems to determine DNA systematics, Liao et al [13,14] used the novel techniques for alignment-free phylogeny to determine sequence ancestry, Wiesner and Wiesnerova [15] found the new methodology giving better insights into germ-plasm identifiers, Gonzalez-Diaz and his group presented several papers using the concept for alignment-free prediction of polygalacturonases [16], alternative "in silico" technique for chemical research in toxicology [17] and predicting antimicrobial drugs and targets [18], Nandy et al [19] were able to model influenza hemagglutinin and neura...

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Protein sequence analysis based on hydropathy profile of amino acids

Cited by 8 publications

References 27 publications

Mathematical Characterization of Protein Sequences Using Patterns as Chemical Group Combinations of Amino Acids

Mathematical Characterization of Protein Sequences Using Patterns as Chemical Group Combinations of Amino Acids

DV-Curve Representation of Protein Sequences and Its Application

Rational design of peptide vaccines against the Zika virus through sequence descriptors: Techniques and Problems

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