Protein Surface Interactions—Theoretical and Experimental Studies

Almeida, Fábio C. L.; Sanches, Karoline; Pinheiro-Aguiar, Ramon; Almeida, Vitor S.; Caruso, Ícaro Putinhon

doi:10.3389/fmolb.2021.706002

Cited by 14 publications

(7 citation statements)

References 56 publications

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“…It was recently proposed that these proteins are stabilized by hydrophobic surface clusters acting as an independent folding unit. In the absence of a canonical hydrophobic core, the surface clusters promote the folding by the interaction of exposed hydrophobic residues with the adjacent side chains regulated by solvation forces ( Almeida et al, 2021 ).…”

Section: Disintegrin Structure: Nmr and Crystallization Studiesmentioning

confidence: 99%

Structure-Function Relationship of the Disintegrin Family: Sequence Signature and Integrin Interaction

Vasconcelos

Estrada

David

et al. 2021

Front. Mol. Biosci.

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Disintegrins are small cysteine-rich proteins found in a variety of snake venom. These proteins selectively modulate integrin function, heterodimeric receptors involved in cell-cell and cell-matrix interaction that are widely studied as therapeutic targets. Snake venom disintegrins emerged from the snake venom metalloproteinase and are classified according to the sequence size and number of disulfide bonds. Evolutive structure and function diversification of disintegrin family involves a stepwise decrease in the polypeptide chain, loss of cysteine residues, and selectivity. Since the structure elucidation of echistatin, the description of the structural properties of disintegrins has allowed the investigation of the mechanisms involved in integrin-cell-extracellular matrix interaction. This review provides an analysis of the structures of all family groups enabling the description of an expanded classification of the disintegrin family in seven groups. Each group presents a particular disulfide pattern and sequence signatures, facilitating the identification of new disintegrins. The classification was based on the disintegrin-like domain of the human metalloproteinase (ADAM-10). We also present the sequence and structural signatures important for disintegrin-integrin interaction, unveiling the relationship between the structure and function of these proteins.

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Section: Disintegrin Structure: Nmr and Crystallization Studiesmentioning

confidence: 99%

Structure-Function Relationship of the Disintegrin Family: Sequence Signature and Integrin Interaction

Vasconcelos

Estrada

David

et al. 2021

Front. Mol. Biosci.

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“…Third, the presence of charged amino acids in dipeptides can lead to electrostatic interactions that modulate PPI, especially between positively- and negatively-charged amino acids [53]. Fourth, differences in hydrophobicity within dipeptides can also influence interactions, particularly hydrophobic interactions [35].…”

Section: Resultsmentioning

confidence: 99%

“…Dipeptides with specific combinations of charged amino acids may create favorable or unfavorable electrostatic environments for PPI. Finally, some dipeptide compositions may contain hydrophobic amino acids, which tend to cluster together in the protein’s core [3, 51], while others may have hydrophilic amino acids exposed on the protein’s surface [1, 46]. Differences in dipeptide compositions can lead to variations in hydrophobic and hydrophilic regions, influencing protein-protein interactions, especially those that involve hydrophobic interactions, and dipeptide composition can be targeted to affect protein-protein interactions [26].…”

Section: Discussionmentioning

confidence: 99%

Physical-Chemical Features Selection Reveals That Differences in Dipeptide Compositions Correlate Most with Protein-Protein Interactions

Teimouri,

Medvedeva,

Kolomeisky

2024

Preprint

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The ability to accurately predict protein-protein interactions is critically important for our understanding of major cellular processes. However, current experimental and computational approaches for identifying them are technically very challenging and still have limited success. We propose a new computational method for predicting protein-protein interactions using only primary sequence information. It utilizes a concept of physical-chemical similarity to determine which interactions will most probably occur. In our approach, the physical-chemical features of protein are extracted using bioinformatics tools for different organisms, and then they are utilized in a machine-learning method to identify successful protein-protein interactions via correlation analysis. It is found that the most important property that correlates most with the protein-protein interactions for all studied organisms is dipeptide amino acid compositions. The analysis is specifically applied to the bacterial two-component system that includes histidine kinase and transcriptional response regulators. Our theoretical approach provides a simple and robust method for quantifying the important details of complex mechanisms of biological processes.

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“…IDRs sequences have often low hydropathy, i.e. hydrophilic sequences, so these sequences do not have the conditions to fold 27 . Therefore, it is expected that more chameleon sequences will be located in the inner parts of the protein.…”

Section: Discussionmentioning

confidence: 99%

Chameleon Sequences: Ordered or Disordered

Shahmirani

Goliaei

Bahramali

et al. 2023

Preprint

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Chameleon seqeuences represent a class of sequences violating the important paradigm of molecular biology of one sequence-one structure. Chameleon sequences adopt two different structures in the same protein or in another protein. Why these short sequences are capable of changing their structure has remained unknown. We have examined some properties of chameleon sequences and compared them with those from intreinsically disordered regions of proteins and sequences with known unique secondary structure. Our results show that chameleon sequences have charge distributions very similar to ordered sequences. The GRAVY value of ordered sequences differ from that of intrinsically disordered sequences. Chameleon sequences have GRAVY values close to ordered sequences. A charge-hydropathy plot cleary demonstrated the distribution of ordered, chameleon, and intrinsically disordered regions of proteins. Here again, chameleon sequences placed themselves close to ordered sequences. A conformational analysis of chameleon sequences revealed slight deviations of dihedral angles from ordered sequence values. Based on our analysis we propose that chameleon sequences, with close distance to ordered sequences, have gained limited capability of changing their secondary structure under suitable conditions.

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Protein Surface Interactions—Theoretical and Experimental Studies

Cited by 14 publications

References 56 publications

Structure-Function Relationship of the Disintegrin Family: Sequence Signature and Integrin Interaction

Structure-Function Relationship of the Disintegrin Family: Sequence Signature and Integrin Interaction

Physical-Chemical Features Selection Reveals That Differences in Dipeptide Compositions Correlate Most with Protein-Protein Interactions

Chameleon Sequences: Ordered or Disordered

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