Chronic Beryllium Disease: Revealing the Role of Beryllium Ion and Small Peptides Binding to HLA-DP2

Petukh, Marharyta; Wu, Bohua; Stefl, Shannon; Smith, Nick L.; Hyde-Volpe, David; Wang, Li; Alexov, Emil

doi:10.1371/journal.pone.0111604

Cited by 15 publications

(11 citation statements)

References 51 publications

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“…Due to the presence of beryllium in the pocket, the self-peptide gets displaced and is seen as foreign by HLA-DPspecific CD4 T cells. 124,125 Peptides of the plexin A protein may be the potential source of the displaced self-peptide. 126 Plexins are proteins involved in cell movement and response.…”

Section: Metalsmentioning

confidence: 99%

Etiology and Immunopathogenesis of Sarcoidosis: Novel Insights

Beijer

Veltkamp

Meek

et al. 2017

Semin Respir Crit Care Med

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Sarcoidosis is a disorder of unknown etiology. It is a systemic disease, frequently involving the lungs, skin, eyes, and lymph nodes. It is characterized by formation of noncaseating granulomas at the site(s) of disease. Sarcoidosis has a complex disease pathogenesis, with involvement of both the innate and adaptive immune systems. Several innate immune system receptors including NOD-like receptors and Toll-like receptors appear to be involved in the development of sarcoidosis as well as cellular players such as dendritic cells and macrophages. Furthermore, lymphocytes from the adaptive immune system including Th1, Th17, regulatory T cells, and B cells are likely to play a role in the sarcoidosis disease pathogenesis as well. Possibly, genetic susceptibility and exposure to particular etiologic agents including mycobacterial and propionibacterial antigens, metals, and silica can cause sarcoidosis. Besides exogenous triggers, also self-compounds such as serum amyloid A and vimentin, have been found to play a role in the development of sarcoidosis. It is likely that sarcoidosis does not have one single cause but rather is the result of the interplay between different etiologic agents and the immune system in predisposed individuals.

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Section: Metalsmentioning

confidence: 99%

Etiology and Immunopathogenesis of Sarcoidosis: Novel Insights

Beijer

Veltkamp

Meek

et al. 2017

Semin Respir Crit Care Med

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“…Furthermore, specific studies could be focusing on revealing the changes in the hydrogen bonds (HBs) and salt bridges (SBs) induced by the amino acid mutation [Takano et al, 2012;Zhang et al, 2013;Boccuto et al, 2014;Dolzhanskaya et al, 2014]. Along the same line, in many cases, researchers will be interested to find out the effect of amino acid mutation on thermodynamic properties of the corresponding protein [Zhang et al, 2012b;Nishi et al, 2013;Li et al, 2014;Petukh et al, 2014]. It should be mentioned that the last several quantities, changes in the folding and binding free energies, HBs, and SBs, can be measured experimentally and thus providing ultimate feedback for the in silico modeling [Zhang et al, 2011;Takano et al, 2012].…”

Section: Introductionmentioning

confidence: 99%

On Human Disease-Causing Amino Acid Variants: Statistical Study of Sequence and Structural Patterns

2015

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Statistical analysis was carried out on large set of naturally occurring human amino acid variations and it was demonstrated that there is a preference for some amino acid substitutions to be associated with diseases. At an amino acid sequence level, it was shown that the disease-causing variants frequently involve drastic changes of amino acid physico-chemical properties of proteins such as charge, hydrophobicity and geometry. Structural analysis of variants involved in diseases and being frequently observed in human population showed similar trends: disease-causing variants tend to cause more changes of hydrogen bond network and salt bridges as compared with harmless amino acid mutations. Analysis of thermodynamics data reported in literature, both experimental and computational, indicated that disease-causing variants tend to destabilize proteins and their interactions, which prompted us to investigate the effects of amino acid mutations on large databases of experimentally measured energy changes in unrelated proteins. Although the experimental datasets were linked neither to diseases nor exclusory to human proteins, the observed trends were the same: amino acid mutations tend to destabilize proteins and their interactions. Having in mind that structural and thermodynamics properties are interrelated, it is pointed out that any large change of any of them is anticipated to cause a disease.

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“…Many disease-causing mutations affect protein–protein and protein–DNA interactions [ 4 , 9 , 20 , 21 , 22 , 23 , 24 , 25 ]. Thus, predicting binding free energy changes caused by amino acid mutations has implications for discriminating disease-causing mutations from harmless mutations [ 8 , 16 , 26 ].…”

Section: Introductionmentioning

confidence: 99%

SAAMBE: Webserver to Predict the Charge of Binding Free Energy Caused by Amino Acids Mutations

Petukh

Dai

Alexov

2016

IJMS

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Predicting the effect of amino acid substitutions on protein–protein affinity (typically evaluated via the change of protein binding free energy) is important for both understanding the disease-causing mechanism of missense mutations and guiding protein engineering. In addition, researchers are also interested in understanding which energy components are mostly affected by the mutation and how the mutation affects the overall structure of the corresponding protein. Here we report a webserver, the Single Amino Acid Mutation based change in Binding free Energy (SAAMBE) webserver, which addresses the demand for tools for predicting the change of protein binding free energy. SAAMBE is an easy to use webserver, which only requires that a coordinate file be inputted and the user is provided with various, but easy to navigate, options. The user specifies the mutation position, wild type residue and type of mutation to be made. The server predicts the binding free energy change, the changes of the corresponding energy components and provides the energy minimized 3D structure of the wild type and mutant proteins for download. The SAAMBE protocol performance was tested by benchmarking the predictions against over 1300 experimentally determined changes of binding free energy and a Pearson correlation coefficient of 0.62 was obtained. How the predictions can be used for discriminating disease-causing from harmless mutations is discussed. The webserver can be accessed via .

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Chronic Beryllium Disease: Revealing the Role of Beryllium Ion and Small Peptides Binding to HLA-DP2

Cited by 15 publications

References 51 publications

Etiology and Immunopathogenesis of Sarcoidosis: Novel Insights

Etiology and Immunopathogenesis of Sarcoidosis: Novel Insights

On Human Disease-Causing Amino Acid Variants: Statistical Study of Sequence and Structural Patterns

SAAMBE: Webserver to Predict the Charge of Binding Free Energy Caused by Amino Acids Mutations

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