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1. The ribosome: A hot spot for the identification of new types of protein methyltransferases

   https://doi.org/10.1074/jbc.AW118.003235  

   Clarke, Steven G. (January 2018, Journal of Biological Chemistry)

   Cellular physiology depends on the alteration of protein structures by covalent modification reactions. Using a combination of bioinformatic, genetic, biochemical, and mass spectrometric approaches, it has been possible to probe ribosomal proteins from the yeast Saccharomyces cerevisiae for posttranslationally methylated amino acid residues and for the enzymes that catalyze these modifications. These efforts have resulted in the identification and characterization of the first protein histidine methyltransferase, the first N-terminal protein methyltransferase, two unusual types of protein arginine methyltransferases, and a new type of cysteine methylation. Two of these enzymes may modify their substrates during ribosomal assembly because the final methylated histidine and arginine residues are buried deep within the ribosome with contacts only with RNA. Two of these modifications occur broadly in eukaryotes, including humans, while the others demonstrate a more limited phylogenetic range. Analysis of strains where the methyltransferase genes are deleted has given insight into the physiological roles of these modifications. These reactions described here add diversity to the modifications that generate the typical methylated lysine and arginine residues previously described in histones and other proteins. 

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2. Amino acid hydrogen oxalate quasiracemates – hydrocarbon side chains

   https://doi.org/10.1039/D1CE01213D  

   Wells, Russell G.; Sahlstrom, Katriel D.; Ekelem, Franklin I.; Wheeler, Kraig A. (November 2021, CrystEngComm)

   Amino acid quasiracemates – generated from the assembly of pairs of chemically distinct amino acids of opposite handedness – continue to provide important opportunities to understand how self-assembly can be promoted despite using components with drastically different sizes and molecular shapes. Previous studies by Görbitz et al. and others cataloged 32 crystal structures of amino acid quasiracemates, with each showing the building blocks aligned with near inversion symmetry similar to their racemic counterparts. This investigation examined the impact of using a secondary coformer molecule, hydrogen oxalate, on the cocrystalline landscape of amino acid quasiracemates with hydrocarbon side chains. Eight racemic (4) and quasiracemic (4) hydrogen oxalate structures were generated. Crystal structures of these systems show the hydrogen oxalate moieties assembled into C(5) molecular columns by the construction of robust O–H⋯O − hydrogen bonds with the amino acid enantiomers and quasienantiomers linked to these column motifs using a complex blend of N + –H⋯O − , O–H⋯O − , and N + –H⋯OC contacts. The racemates and quasiracemates form similar packing motifs; however, due to the chemically non-identical nature of the quasiracemic components, the outcome is that the amino acids organize with near inversion symmetry. Both the conformational similarity ( χ RMS ) and degree of inversion symmetry ( C i ) of related pairs of quasienantiomeric components have been systematically assessed using readily available structural tools. This study shows how coformer molecules such as hydrogen oxalate can provide new and critical insight into the molecular recognition process of quasiracemic materials. 

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3. Entrenchment and contingency in neutral protein evolution with epistasis

   https://doi.org/10.1101/2025.01.09.632266  

   Schmelkin, Lisa; Carnevale, Vincenzo; Haldane, Allan; Townsend, Jeffrey P; Chung, Sarah; Levy, Ronald M; Kumar, Sudhir (January 2025, bioRxiv)

   Abstract Protein sequence evolution in the presence of epistasis makes many previously acceptable amino acid residues at a site unfavorable over time. This phenomenon of entrenchment has also been observed with neutral substitutions using Potts Hamiltonian models. Here, we show that simulations using these models often evolve non-neutral proteins. We introduce a Neutral-with-Epistasis (N×E) model that incorporates purifying selection to conserve fitness, a requirement of neutral evolution. N×E protein evolution revealed a surprising lack of entrenchment, with site-specific amino-acid preferences remaining remarkably conserved, in biologically realistic time frames despite extensive residue coupling. Moreover, we found that the overdispersion of the molecular clock is caused by rate variation across sites introduced by epistasis in individual lineages, rather than by historical contingency. Therefore, substitutional entrenchment and rate contingency may indicate that adaptive and other non-neutral evolutionary processes were at play during protein evolution. 

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4. Investigations of Dimethylglycine, Glycine Betaine, and Ectoine Uptake by a Betaine-Carnitine-Choline Transporter Family Transporter with Diverse Substrate Specificity in Vibrio Species

   https://doi.org/10.1128/JB.00314-20  

   Gregory, Gwendolyn J.; Dutta, Anirudha; Parashar, Vijay; Boyd, E. Fidelma (November 2020, Journal of Bacteriology)

   Brun, Yves V. (Ed.)

   ABSTRACT Fluctuations in osmolarity are one of the most prevalent stresses to which bacteria must adapt, both hypo- and hyperosmotic conditions. Most bacteria cope with high osmolarity by accumulating compatible solutes (osmolytes) in the cytoplasm to maintain the turgor pressure of the cell. Vibrio parahaemolyticus , a halophile, utilizes at least six compatible solute transporters for the uptake of osmolytes: two ABC family ProU transporters and four betaine-carnitine-choline transporter (BCCT) family transporters. The full range of compatible solutes transported by this species has yet to be determined. Using an osmolyte phenotypic microarray plate for growth analyses, we expanded the known osmolytes used by V. parahaemolyticus to include N , N -dimethylglycine (DMG), among others. Growth pattern analysis of four triple- bccT mutants, possessing only one functional BCCT, indicated that BccT1 (VP1456), BccT2 (VP1723), and BccT3 (VP1905) transported DMG. BccT1 was unusual in that it could take up both compounds with methylated head groups (glycine betaine [GB], choline, and DMG) and cyclic compounds (ectoine and proline). Bioinformatics analysis identified the four coordinating amino acid residues for GB in the BccT1 protein. In silico modeling analysis demonstrated that GB, DMG, and ectoine docked in the same binding pocket in BccT1. Using site-directed mutagenesis, we showed that a strain with all four residues mutated resulted in the loss of uptake of GB, DMG, and ectoine. We showed that three of the four residues were essential for ectoine uptake, whereas only one of the residues was important for GB uptake. Overall, we have demonstrated that DMG is a highly effective compatible solute for Vibrio species and have elucidated the amino acid residues in BccT1 that are important for the coordination of GB, DMG, and ectoine transport. IMPORTANCE Vibrio parahaemolyticus possesses at least six osmolyte transporters, which allow the bacterium to adapt to high-salinity conditions. In this study, we identified several additional osmolytes that were utilized by V. parahaemolyticus . We demonstrated that the compound DMG, which is present in the marine environment, was a highly effective osmolyte for Vibrio species. We determined that DMG is transported via BCCT family carriers, which have not been shown previously to take up this compound. BccT1 was a carrier for GB, DMG, and ectoine, and we identified the amino acid residues essential for the coordination of these compounds. The data suggest that for BccT1, GB is more easily accommodated than ectoine in the transporter binding pocket. 

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5. Deciphering the structural consequences of R83 and R152 methylation on DNA polymerase β using molecular modeling

   https://doi.org/10.1371/journal.pone.0318614  

   Srivastava, Amit; Idriss, Haitham; Das, Gobind; Abedrabbo, Sufian; Shamsir, Mohd Sahir; Homouz, Dirar (March 2025, PLOS ONE)

   Selvaraj, Chandrabose (Ed.)

   DNA polymerase β, a member of the X-family of DNA polymerases, undergoes complex regulations both in vitro and in vivo through various posttranslational modifications, including phosphorylation and methylation. The impact of these modifications varies depending on the specific amino acid undergoing alterations. In vitro, methylation of DNA polymerase β with the enzyme protein arginine methyltransferase 6 (PRMT6) at R83 and R152 enhances polymerase activity by improving DNA binding and processivity. Although these studies have shown that methylation improves DNA binding, the underlying mechanism of enhancement of polymerase activity in terms of structure and dynamics remains poorly understood. To address this gap, we modeled the methylated enzyme/DNA complex and conducted a microsecond-long simulation in the presence of Mg ions. Our results revealed significant structural changes induced by methylating both R83 and R152 sites in the enzyme. Specifically, these changes caused the DNA fragment to move closer to the C- and N-subdomains, forming additional hydrogen bonds. Furthermore, the cross-correlation map demonstrated that methylation enhanced long-range correlations within the domains/subdomains of DNA polymerase β, along with an increase in the linear mutual information value between the domains/subdomains and DNA fragments. The graph connectivity network also illustrated that methylation modulates the information pathway and identifies residues exhibiting long-distance coupling with the methylated sites. Our results provide an atomic-level understanding of the structural transition induced by methylation, shedding light on the mechanisms underlying the methylation-induced enhancement of activity in DNA polymerase β. 

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