Karyn McFadden scite author profile

Epstein-Barr virus (EBV) is an oncogenic herpesvirus that has been causally linked to the development of B-cell and epithelial malignancies. Early after infection, EBV induces a transient period of hyperproliferation that is suppressed by the activation of the DNA damage response and a G1/S-phase growth arrest. This growth arrest prevents long-term outgrowth of the majority of infected cells. We developed a method to isolate and characterize infected cells that arrest after this early burst of proliferation and integrated gene expression and metabolic profiling to gain a better understanding of the pathways that attenuate immortalization. We found that the arrested cells have a reduced level of mitochondrial respiration and a decrease in the expression of genes involved in the TCA cycle and oxidative phosphorylation. Indeed, the growth arrest in early infected cells could be rescued by supplementing the TCA cycle. Arrested cells were characterized by an increase in the expression of p53 pathway gene targets, including sestrins leading to activation of AMPK, a reduction in mTOR signaling, and, consequently, elevated autophagy that was important for cell survival. Autophagy was also critical to maintain early hyperproliferation during metabolic stress. Finally, in assessing the metabolic changes from early infection to long-term outgrowth, we found concomitant increases in glucose import and surface glucose transporter 1 (GLUT1) levels, leading to elevated glycolysis, oxidative phosphorylation, and suppression of basal autophagy. Our study demonstrates that oncogene-induced senescence triggered by a combination of metabolic and genotoxic stress acts as an intrinsic barrier to EBV-mediated transformation.Epstein-Barr virus | oncogene-induced senescence | autophagy | B cell | metabolism

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The Active Core in a Triazole Peptide Dual‐Site Antagonist of HIV‐1 gp120

Umashankara

et al. 2010

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In an effort to identify broadly active inhibitors of HIV-1 entry into host cells, we had previously reported a family of dodecamer triazole-peptide conjugates with nanomolar affinity for viral ichaiken@drexelmed NIH-PA Author ManuscriptNIH-PA Author Manuscript NIH-PA Author Manuscript surface protein gp120. This class of peptides exhibits potent antiviral activity and the capacity to simultaneously inhibit interaction of viral envelope protein with both CD4 and co-receptor. In the current investigation, we used minimization of structural complexity of the lead triazole inhibitor HNG-156 (peptide 1) in order to explore the limits of the pharmacophore that enables dual antagonism and to improve opportunities for peptidomimetic design. Truncations of both carboxyl-and amino-terminal residues of the initial 12 amino acid residues of peptide 1 were found to have minimal effect on both affinity and antiviral activity. In contrast, the central triazole Pro-Trp cluster at residues 6 and 7 with ferrocenyl-triazole-Pro (Ftp) was found to be critical for bioactivity. Amino terminal residues distal to the central triazole Pro-Trp sequence tolerated decreasing degrees of side chain variation upon approaching the central cluster. A peptide fragment containing residues 3-7 (Asn-Asn-Ile-Ftp-Trp) exhibited substantial direct binding affinity, antiviral potency, dual receptor site antagonism and induction of gp120 structuring, all properties defining the functional signature of the parent compound 1. This active core contains a stereochemically specific hydrophobic triazole-Pro-Trp cluster, with a short N-terminal peptide extension providing groups for potential main chain and side chain hydrogen binding. The results of this work argue that the pharmacophore for dual antagonism is structurally limited, enhancing the potential to develop minimized peptidomimetic HIV-1 entry inhibitors that simultaneously suppress binding of envelope protein to both of its host cell receptors. The results also argue that the target epitope on gp120 is relatively small, pointing to a localized allosteric inhibition site in the HIV-1 envelope that could be targeted for small-molecule inhibitor discovery.

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Interactions of peptide triazole thiols with Env gp120 induce irreversible breakdown and inactivation of HIV-1 virions

et al. 2013

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BackgroundWe examined the underlying mechanism of action of the peptide triazole thiol, KR13 that has been shown previously to specifically bind gp120, block cell receptor site interactions and potently inhibit HIV-1 infectivity.ResultsKR13, the sulfhydryl blocked KR13b and its parent non-sulfhydryl peptide triazole, HNG156, induced gp120 shedding but only KR13 induced p24 capsid protein release. The resulting virion post virolysis had an altered morphology, contained no gp120, but retained gp41 that bound to neutralizing gp41 antibodies. Remarkably, HIV-1 p24 release by KR13 was inhibited by enfuvirtide, which blocks formation of the gp41 6-helix bundle during membrane fusion, while no inhibition of p24 release occurred for enfuvirtide-resistant virus. KR13 thus appears to induce structural changes in gp41 normally associated with membrane fusion and cell entry. The HIV-1 p24 release induced by KR13 was observed in several clades of HIV-1 as well as in fully infectious HIV-1 virions.ConclusionsThe antiviral activity of KR13 and its ability to inactivate virions prior to target cell engagement suggest that peptide triazole thiols could be highly effective in inhibiting HIV transmission across mucosal barriers and provide a novel probe to understand biochemical signals within envelope that are involved in membrane fusion.

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Cell‐Free HIV‐1 Virucidal Action by Modified Peptide Triazole Inhibitors of Env gp120

et al. 2011

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Rapid single B cell antibody discovery using nanopens and structured light

Winters

McFadden

Bergen

et al. 2019

mAbs

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Accelerated development of monoclonal antibody (mAb) tool reagents is an essential requirement for the successful advancement of therapeutic antibodies in today's fast-paced and competitive drug development marketplace. Here, we describe a direct, flexible, and rapid nanofluidic optoelectronic single B lymphocyte antibody screening technique (NanOBlast) applied to the generation of antiidiotypic reagent antibodies. Selectively enriched, antigen-experienced murine antibody secreting cells (ASCs) were harvested from spleen and lymph nodes. Subsequently, secreted mAbs from individually isolated, single ASCs were screened directly using a novel, integrated, high-content culture, and assay platform capable of manipulating living cells within microfluidic chip nanopens using structured light. Single-cell polymerase chain reaction-based molecular recovery on select anti-idiotypic ASCs followed by recombinant IgG expression and enzyme-linked immunosorbent assay (ELISA) characterization resulted in the recovery and identification of a diverse and high-affinity panel of anti-idiotypic reagent mAbs. Combinatorial ELISA screening identified both capture and detection mAbs, and enabled the development of a sensitive and highly specific ligand binding assay capable of quantifying free therapeutic IgG molecules directly from human patient serum, thereby facilitating important drug development decision-making. The ASC import, screening, and export discovery workflow on the chip was completed within 5 h, while the overall discovery workflow from immunization to recombinantly expressed IgG was completed in under 60 days.

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Karyn McFadden

Metabolic stress is a barrier to Epstein–Barr virus-mediated B-cell immortalization

The Active Core in a Triazole Peptide Dual‐Site Antagonist of HIV‐1 gp120

Interactions of peptide triazole thiols with Env gp120 induce irreversible breakdown and inactivation of HIV-1 virions

Cell‐Free HIV‐1 Virucidal Action by Modified Peptide Triazole Inhibitors of Env gp120

Rapid single B cell antibody discovery using nanopens and structured light

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