David M. Edwards scite author profile

Mitochondrial DNA (mtDNA) and plastid DNA (ptDNA) encode vital bioenergetic apparatus, and mutations in these organelle DNA (oDNA) molecules can be devastating. In the germline of several animals, a genetic “bottleneck” increases cell-to-cell variance in mtDNA heteroplasmy, allowing purifying selection to act to maintain low proportions of mutant mtDNA. However, most eukaryotes do not sequester a germline early in development, and even the animal bottleneck remains poorly understood. How then do eukaryotic organelles avoid Muller’s ratchet—the gradual buildup of deleterious oDNA mutations? Here, we construct a comprehensive and predictive genetic model, quantitatively describing how different mechanisms segregate and decrease oDNA damage across eukaryotes. We apply this comprehensive theory to characterise the animal bottleneck with recent single-cell observations in diverse mouse models. Further, we show that gene conversion is a particularly powerful mechanism to increase beneficial cell-to-cell variance without depleting oDNA copy number, explaining the benefit of observed oDNA recombination in diverse organisms which do not sequester animal-like germlines (for example, sponges, corals, fungi, and plants). Genomic, transcriptomic, and structural datasets across eukaryotes support this mechanism for generating beneficial variance without a germline bottleneck. This framework explains puzzling oDNA differences across taxa, suggesting how Muller’s ratchet is avoided in different eukaryotes.

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Cowpox Virus Inhibits the Transporter Associated with Antigen Processing to Evade T Cell Recognition

Alzhanova

Edwards

Hammarlund

et al. 2009

Cell Host & Microbe

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SUMMARY Cowpox virus is considered ancestral to orthopoxviridae since CPXV encodes the most extensive array of putative immunomodulators that likely contribute to its wide host range including zoonotic infections in humans. Unlike vaccinia virus, CPXV prevents stimulation of CD8+ T cells and this correlated with retention of MHC-I in the endoplasmic reticulum by CPXV203. However, deletion of CPXV203 did not restore MHC-I transport or T cell stimulation. Here, we demonstrate that the type II transmembrane protein, CPXV012, additionally interferes with MHC-I/peptide complex formation by inhibiting peptide translocation by TAP. CPXV012 thus represents the first non-herpesvial TAP inhibitor. Importantly, human and mouse MHC-I transport and T cell stimulation was restored upon deletion of both CPXV012 and CPXV203 suggesting that these unrelated proteins independently mediate T cell evasion in multiple hosts. Interestingly, CPXV012 is a truncated version of a putative NK cell ligand indicating that poxviral gene fragments can encode new unexpected functions.

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T Cell Inactivation by Poxviral B22 Family Proteins Increases Viral Virulence

et al. 2014

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Infections with monkeypox, cowpox and weaponized variola virus remain a threat to the increasingly unvaccinated human population, but little is known about their mechanisms of virulence and immune evasion. We now demonstrate that B22 proteins, encoded by the largest genes of these viruses, render human T cells unresponsive to stimulation of the T cell receptor by MHC-dependent antigen presentation or by MHC-independent stimulation. In contrast, stimuli that bypass TCR-signaling are not inhibited. In a non-human primate model of monkeypox, virus lacking the B22R homologue (MPXVΔ197) caused only mild disease with lower viremia and cutaneous pox lesions compared to wild type MPXV which caused high viremia, morbidity and mortality. Since MPXVΔ197-infected animals displayed accelerated T cell responses and less T cell dysregulation than MPXV US2003, we conclude that B22 family proteins cause viral virulence by suppressing T cell control of viral dissemination.

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Recombinant HLA-DP2 Binds Beryllium and Tolerizes Beryllium-Specific Pathogenic CD4+ T Cells

Fontenot

Keizer

McCleskey

et al. 2006

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Chronic beryllium disease is a lung disorder caused by beryllium exposure in the workplace and is characterized by granulomatous inflammation and the accumulation of beryllium-specific, HLA-DP2-restricted CD4+ T lymphocytes in the lung that proliferate and secrete Th1-type cytokines. To characterize the interaction among HLA-DP2, beryllium, and CD4+ T cells, we constructed rHLA-DP2 and rHLA-DP4 molecules consisting of the α-1 and β-1 domains of the HLA-DP molecules genetically linked into single polypeptide chains. Peptide binding to rHLA-DP2 and rHLA-DP4 was consistent with previously published peptide-binding motifs for these MHC class II molecules, with peptide binding dominated by aromatic residues in the P1 pocket. 9Be nuclear magnetic resonance spectroscopy showed that beryllium binds to the HLA-DP2-derived molecule, with no binding to the HLA-DP4 molecule that differs from DP2 by four amino acid residues. Using beryllium-specific CD4+ T cell lines derived from the lungs of chronic beryllium disease patients, beryllium presentation to those cells was independent of Ag processing because fixed APCs were capable of presenting BeSO4 and inducing T cell proliferation. Exposure of beryllium-specific CD4+ T cells to BeSO4-pulsed, plate-bound rHLA-DP2 molecules induced IFN-γ secretion. In addition, pretreatment of beryllium-specific CD4+ T cells with BeSO4-pulsed, plate-bound HLA-DP2 blocked proliferation and IL-2 secretion upon re-exposure to beryllium presented by APCs. Thus, the rHLA-DP2 molecules described herein provide a template for engineering variants that retain the ability to tolerize pathogenic CD4+ T cells, but do so in the absence of the beryllium Ag.

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David M. Edwards

Avoiding organelle mutational meltdown across eukaryotes with or without a germline bottleneck

Cowpox Virus Inhibits the Transporter Associated with Antigen Processing to Evade T Cell Recognition

T Cell Inactivation by Poxviral B22 Family Proteins Increases Viral Virulence

Recombinant HLA-DP2 Binds Beryllium and Tolerizes Beryllium-Specific Pathogenic CD4+ T Cells

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