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1. Biotechnological and protein-engineering implications of ancestral protein resurrection

   https://doi.org/10.1016/j.sbi.2018.02.007  

   Risso, Valeria A; Sanchez-Ruiz, Jose M; Ozkan, S Banu (August 2018, Current Opinion in Structural Biology)
2. Effects of SARS‐CoV‐2 mutations on protein structures and intraviral protein–protein interactions

   https://doi.org/10.1002/jmv.26597  

   Wu, Siqi; Tian, Chang; Liu, Panpan; Guo, Dongjie; Zheng, Wei; Huang, Xiaoqiang; Zhang, Yang; Liu, Lijun (April 2021, Journal of Medical Virology)

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3. Protein-lipid interactions and protein anchoring modulate the modes of association of the globular domain of the Prion protein and Doppel protein to model membrane patches

   https://doi.org/10.3389/fbinf.2023.1321287  

   Soto, Patricia; Thalhuber, Davis T; Luceri, Frank; Janos, Jamie; Borgman, Mason R; Greenwood, Noah M; Acosta, Sofia; Stoffel, Hunter (January 2024, Frontiers in Bioinformatics)

   The Prion protein is the molecular hallmark of the incurable prion diseases affecting mammals, including humans. The protein-only hypothesis states that the misfolding, accumulation, and deposition of the Prion protein play a critical role in toxicity. The cellular Prion protein (PrP^C) anchors to the extracellular leaflet of the plasma membrane and prefers cholesterol- and sphingomyelin-rich membrane domains. Conformational Prion protein conversion into the pathological isoform happens on the cell surface.In vitroandin vivoexperiments indicate that Prion protein misfolding, aggregation, and toxicity are sensitive to the lipid composition of plasma membranes and vesicles. A picture of the underlying biophysical driving forces that explain the effect of Prion protein - lipid interactions in physiological conditions is needed to develop a structural model of Prion protein conformational conversion. To this end, we use molecular dynamics simulations that mimic the interactions between the globular domain of PrP^Canchored to model membrane patches. In addition, we also simulate the Doppel protein anchored to such membrane patches. The Doppel protein is the closest in the phylogenetic tree to PrP^C, localizes in an extracellular milieu similar to that of PrP^C, and exhibits a similar topology to PrP^Ceven if the amino acid sequence is only 25% identical. Our simulations show that specific protein-lipid interactions and conformational constraints imposed by GPI anchoring together favor specific binding sites in globular PrP^Cbut not in Doppel. Interestingly, the binding sites we found in PrP^Ccorrespond to prion protein loops, which are critical in aggregation and prion disease transmission barrier (β2-α2 loop) and in initial spontaneous misfolding (α2-α3 loop). We also found that the membrane re-arranges locally to accommodate protein residues inserted in the membrane surface as a response to protein binding. 

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4. The BR-body proteome contains a complex network of protein-protein and protein-RNA interactions

   https://doi.org/10.1016/j.celrep.2023.113229  

   Nandana, Vidhyadhar; Rathnayaka-Mudiyanselage, Imalka W; Muthunayake, Nisansala S; Hatami, Ali; Mousseau, C Bruce; Ortiz-Rodríguez, Luis A; Vaishnav, Jamuna; Collins, Michael; Gega, Alisa; Mallikaarachchi, Kaveendya S; et al (October 2023, Cell Reports)
5. A computational exploration of resilience and evolvability of protein–protein interaction networks

   https://doi.org/10.1038/s42003-021-02867-8  

   Klein, Brennan; Holmér, Ludvig; Smith, Keith M.; Johnson, Mackenzie M.; Swain, Anshuman; Stolp, Laura; Teufel, Ashley I.; Kleppe, April S. (December 2021, Communications Biology)

   Abstract Protein–protein interaction (PPI) networks represent complex intra-cellular protein interactions, and the presence or absence of such interactions can lead to biological changes in an organism. Recent network-based approaches have shown that a phenotype’s PPI network’s resilience to environmental perturbations is related to its placement in the tree of life; though we still do not know how or why certain intra-cellular factors can bring about this resilience. Here, we explore the influence of gene expression and network properties on PPI networks’ resilience. We use publicly available data of PPIs for E. coli , S. cerevisiae , and H. sapiens , where we compute changes in network resilience as new nodes (proteins) are added to the networks under three node addition mechanisms—random, degree-based, and gene-expression-based attachments. By calculating the resilience of the resulting networks, we estimate the effectiveness of these node addition mechanisms. We demonstrate that adding nodes with gene-expression-based preferential attachment (as opposed to random or degree-based) preserves and can increase the original resilience of PPI network in all three species, regardless of gene expression distribution or network structure. These findings introduce a general notion of prospective resilience , which highlights the key role of network structures in understanding the evolvability of phenotypic traits. 

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