Noah Beltrami scite author profile

cWe previously associated a missense mutation of the tc0668 gene of serial in vitro-passaged Chlamydia muridarum, a murine model of human urogenital C. trachomatis, with severely attenuated disease development in the upper genital tract of female mice. Since these mutants also contained a TC0237 Q117E missense mutation that enhances their in vitro infectivity, an effort was made here to isolate and characterize a tc0668 single mutant to determine its individual contribution to urogenital pathogenicity. Detailed genetic analysis of C. muridarum passages revealed a truncated variant with a G216* nonsense mutation of the 408-amino-acid TC0668 protein that does not produce a detectable product. Intracellular growth and infectivity of C. muridarum in vitro remain unaffected in the absence of TC0668. Intravaginal inoculation of the TC0668 null mutant into C3H/HeJ mice results in a typical course of lower genital tract infection but, unlike a pathogenic isogenic control, is unable to elicit significant chronic inflammation of the oviduct and fails to induce hydrosalpinx. Thus, TC0668 is demonstrated as an important chromosome-encoded urogenital pathogenicity factor of C. muridarum and the first with these characteristics to be discovered for a Chlamydia pathogen. Chlamydia muridarum is a Gram-negative obligate intracellular pathogen that was isolated from a steady-state respiratory infection of laboratory mice in the early 1940s (1, 2). Like other chlamydial organisms, C. muridarum has a biphasic life cycle that alternates between infectious elementary body (EB) and replicating reticulate body (RB) morphologies. The genome of C. muridarum is reductively evolved, containing a 1.07-Mb circular chromosome and single 7.5-kb extrachromosomal plasmid (3). In that C. muridarum and other chlamydial pathogens have fewer than 1,000 genes and ϳ900 encoded proteins, roughly half the number encoded by environmental chlamydial organisms that parasitize simple single-celled eukaryotes (4), it is not known which of the many cryptic genetic factors allow them to thrive within and harm complex vertebrates.In the laboratory, C. muridarum is used as a model of urogenital disease resulting from sexually transmitted Chlamydia trachomatis in women. The basic biology and genomes of these two pathogens are highly conserved. The urogenital biovar of C. trachomatis is responsible for the most reported cases of bacterial infection in the United States (5) and is a pervasive global health problem (6). In women, ascending infection from the lower to upper genital tracts, separated by the cervical barrier, can lead to loss of the ciliated epithelium and irreversible fibrotic remodeling of the fallopian tubes after primary infection is resolved (7). If left untreated, often because of asymptomatic infection (8), afflicted women can experience severe chronic sequelae, such as tubal blockage, hydrosalpinx, spontaneous abortion, ectopic pregnancy, and tubal factor infertility (9, 10). Genital inoculation of female mice with C. muridarum results in analo...

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DNA Strand Displacement Driven by Host–Guest Interactions

Kankanamalage

Tran

Beltrami

et al. 2022

J. Am. Chem. Soc.

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Base-pair-driven toehold-mediated strand displacement (BP-TMSD) is a fundamental concept employed for constructing DNA machines and networks with a gamut of applications�from theranostics to computational devices. To broaden the toolbox of dynamic DNA chemistry, herein, we introduce a synthetic surrogate termed host−guest-driven toeholdmediated strand displacement (HG-TMSD) that utilizes bioorthogonal, cucurbit[7]uril (CB[7]) interactions with guest-linked input sequences. Since control of the strand-displacement process is salient, we demonstrate how HG-TMSD can be finely modulated via changes to the structure of the input sequence (including synthetic guest head-group and/or linker length). Further, for a given input sequence, competing small-molecule guests can serve as effective regulators (with fine and coarse control) of HG-TMSD. To show integration into functional devices, we have incorporated HG-TMSD into machines that control enzyme activity and layered reactions that detect specific microRNA.

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Structure/Function Analysis of Truncated Amino-Terminal ACE2 Peptide Analogs That Bind to SARS-CoV-2 Spike Glycoprotein

et al. 2022

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The global burden of the SARS-CoV-2 pandemic is thought to result from a high viral transmission rate. Here, we consider mechanisms that influence host cell–virus binding between the SARS-CoV-2 spike glycoprotein (SPG) and the human angiotensin-converting enzyme 2 (ACE2) with a series of peptides designed to mimic key ACE2 hot spots through adopting a helical conformation analogous to the N-terminal α1 helix of ACE2, the region experimentally shown to bind to the SARS-CoV-2 receptor-binding domain (RBD). The approach examines putative structure/function relations by assessing SPG binding affinity with surface plasmon resonance (SPR). A cyclic peptide (c[KFNHEAEDLFEKLM]) was characterized in an α-helical conformation with micromolar affinity (KD = 500 µM) to the SPG. Thus, stabilizing the helical structure of the 14-mer through cyclization improves binding to SPG by an order of magnitude. In addition, end-group peptide analog modifications and residue substitutions mediate SPG binding, with net charge playing an apparent role. Therefore, we surveyed reported viral variants, and a correlation of increased positive charge with increased virulence lends support to the hypothesis that charge is relevant to enhanced viral fusion. Overall, the structure/function relationship informs the importance of conformation and charge for virus-binding analog design.

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Noah Beltrami

The Chromosome-Encoded Hypothetical Protein TC0668 Is an Upper Genital Tract Pathogenicity Factor of Chlamydia muridarum

DNA Strand Displacement Driven by Host–Guest Interactions

Structure/Function Analysis of Truncated Amino-Terminal ACE2 Peptide Analogs That Bind to SARS-CoV-2 Spike Glycoprotein

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