Over the last two decades, there have been three deadly human outbreaks of coronaviruses (CoVs) caused by SARS-CoV, MERS-CoV, and SARS-CoV-2, which has caused the current COVID-19 global pandemic. All three deadly CoVs originated from bats and transmitted to humans via various intermediate animal reservoirs. It remains highly possible that other global COVID pandemics will emerge in the coming years caused by yet another spillover of a bat-derived SARS-like coronavirus (SL-CoV) into humans. Determining the Ag and the human B cells, CD4 1 and CD8 1 T cell epitope landscapes that are conserved among human and animal coronaviruses should inform in the development of future pan-coronavirus vaccines. In the current study, using several immunoinformatics and sequence alignment approaches, we identified several human B cell and CD4 1 and CD8 1 T cell epitopes that are highly conserved in 1) greater than 81,000 SARS-CoV-2 genome sequences identified in 190 countries on six continents; 2) six circulating CoVs that caused previous human outbreaks of the common cold; 3) nine SL-CoVs isolated from bats; 4) nine SL-CoV isolated from pangolins; 5) three SL-CoVs isolated from civet cats; and 6) four MERS strains isolated from camels. Furthermore, the identified epitopes: 1) recalled B cells and CD4 1 and CD8 1 T cells from both COVID-19 patients and healthy individuals who were never exposed to SARS-CoV-2, and 2) induced strong B cell and T cell responses in humanized HLA-DR1/HLA-A*02:01 double-transgenic mice. The findings pave the way to develop a preemptive multiepitope pancoronavirus vaccine to protect against past, current, and future outbreaks.
Human 3-methyladenine-DNA glycosylase (MPG protein) initiates base excision repair by severing the glycosylic bond of numerous damaged bases. In comparison, homologues of the Rad23 proteins (hHR23) and the hXPC protein are involved in the recognition of damaged bases in global genome repair, a subset of nucleotide excision repair. In this report, we show that the hHR23A and -B also interact with the MPG protein and can serve as accessory proteins for DNA damage recognition in base excision repair. Furthermore, the MPG⅐hHR23 protein complex elevates the rate of MPG protein-catalyzed excision from hypoxanthine-containing substrates. This increased excision rate is correlated with a greater binding affinity of the MPG proteinhHR23 protein complex for damaged DNA. These data suggest that the hHR23 proteins function as universal DNA damage recognition accessory proteins in both of these major excision repair pathways.
Integration of the human immunodeficiency virus (HIV‐1) DNA into the host genome is catalysed by a virus‐encoded protein integrase. Here, we report some of the structural and functional properties of two synthetic peptides: integrase‐(147–175)‐peptide reproducing the residues 147–175 (SQGVVESMNKELK159KIIGQVRDQAEHLKTAY) of the HIV‐1 integrase, and [Pro159] integrase‐(147–175)‐peptide where the lysine 159 is substituted for a proline. Circular dichroism revealed that both peptides are mostly under unordered conformation in aqueous solution, contrasting with the α‐helix exhibited by residues 147–175 in the protein crystal structure. In a weak α‐helix‐promoting environment, integrase‐(147–175)‐peptide self‐associated into stable coiled‐coil oligomers, while [Pro159] integrase‐(147–175)‐peptide did not. This property was further confirmed by cross‐linking experiments. In our in vitro experiments, only integrase‐(147–175)‐peptide was able to reduce the integration activity of the enzyme. We propose that the inhibitory activity shown by integrase‐(147–175)‐peptide is dependent on its ability to bind to its counterpart in integrase through a peptide‐protein coiled‐coil structure disturbing the catalytic properties of the enzyme.
Methylpurine-DNA glycosylases (MPG proteins, 3-methyladenine-DNA glycosylases) excise numerous damaged bases from DNA during the first step of base excision repair. The damaged bases removed by these proteins include those induced by both alkylating agents and/or oxidizing agents. The intrinsic kinetic parameters (k(cat) and K(m)) for the excision of hypoxanthine by the recombinant human MPG protein from a 39 bp oligodeoxyribonucleotide harboring a unique hypoxanthine were determined. Comparison with other reactions catalyzed by the human MPG protein suggests that the differences in specificity are primarily in product release and not binding. Analysis of MPG protein binding to the 39 bp oligodeoxyribonucleotide revealed that the apparent dissociation constant is of the same order of magnitude as the K(m) and that a 1:1 complex is formed. The MPG protein also forms a strong complex with the product of excision, an abasic site, as well as with a reduced abasic site. DNase I footprinting experiments with the MPG protein on an oligodeoxyribonucleotide with a unique hypoxanthine at a defined position indicate that the protein protects 11 bases on the strand with the hypoxanthine and 12 bases on the complementary strand. Competition experiments with different length, double-stranded, hypoxanthine-containing oligodeoxyribonucleotides show that the footprinted region is relatively small. Despite the small footprint, however, oligodeoxyribonucleotides comprising <15 bp with a hypoxanthine have a 10-fold reduced binding capacity compared with hypoxanthine-containing oligodeoxyribonucleotides >20 bp in length. These results provide a basis for other structural studies of the MPG protein with its targets.
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