The Campaign to End U.S. War-Making in Yemen: Strategies of Congressional Advocacy, 2015–2020

Civil society groups and a handful of lawmakers have pursued a robust campaign to end U.S. support for the Saudi-led war in Yemen in Congress. By framing the conflict as a war of Saudi aggression and pulling legislative levers that enabled them to force floor votes, advocates turned a niche issue into one that galvanized majorities in Congress and generated significant media coverage. Even when vetoes blocked their ability to enact binding war powers and arms transfer legislation, advocates nevertheless exerted political pressure that gave the president and the Saudi-led coalition alike impetus to moderate the war effort. This case suggests both the potential and limits of pursuing antiwar advocacy through Congress

Constriction Rate Modulation Can Drive Cell Size Control and Homeostasis in C. crescentus

Summary: Rod-shaped bacteria typically grow first via sporadic and dispersed elongation along their lateral walls and then via a combination of zonal elongation and constriction at the division site to form the poles of daughter cells. Although constriction comprises up to half of the cell cycle, its impact on cell size control and homeostasis has rarely been considered. To reveal the roles of cell elongation and constriction in bacterial size regulation during cell division, we captured the shape dynamics of Caulobacter crescentus with time-lapse structured illumination microscopy and used molecular markers as cell-cycle landmarks. We perturbed the constriction rate using a hyperconstriction mutant or fosfomycin ([(2R,3S)-3-methyloxiran-2-yl]phosphonic acid) inhibition. We report that the constriction rate contributes to both size control and homeostasis, by determining elongation during constriction and by compensating for variation in pre-constriction elongation on a single-cell basis. : Microbiology; Microbial Physiology; Microbial Cell Structure Subject Areas: Microbiology, Microbial Physiology, Microbial Cell Structur

CdiA Effectors Use Modular Receptor-Binding Domains To Recognize Target Bacteria

Contact-dependent growth inhibition (CDI) systems encode CdiA effectors, which bind to specific receptors on neighboring bacteria and deliver C-terminal toxin domains to suppress target cell growth. Two classes of CdiA effectors that bind distinct cell surface receptors have been identified, but the molecular basis of receptor specificity is not understood. Alignment of BamA-specific CdiAEC93 from Escherichia coli EC93 and OmpC-specific CdiA(EC536) from E. coli 536 suggests that the receptor-binding domain resides within a central region that varies between the two effectors. In support of this hypothesis, we find that CdiA(EC93) fragments containing residues Arg1358 to Phe1646 bind specifically to purified BamA. Moreover, chimeric CdiA(EC93) that carries the corresponding sequence from CdiA(EC536) is endowed with OmpC-binding activity, demonstrating that this region dictates receptor specificity. A survey of E. coli CdiA proteins reveals two additional effector classes, which presumably recognize distinct receptors. Using a genetic approach, we identify the outer membrane nucleoside transporter Tsx as the receptor for a third class of CdiA effectors. Thus, CDI systems exploit multiple outer membrane proteins to identify and engage target cells. These results underscore the modularity of CdiA proteins and suggest that novel effectors can be constructed through genetic recombination to interchange different receptor-binding domains and toxic payloads. IMPORTANCE CdiB/CdiA two-partner secretion proteins mediate interbacterial competition through the delivery of polymorphic toxin domains. This process, known as contact-dependent growth inhibition (CDI), requires stable interactions between the CdiA effector protein and specific receptors on the surface of target bacteria. Here, we localize the receptor-binding domain to the central region of E. coli CdiA. Receptor-binding domains vary between CdiA proteins, and E. coli strains collectively encode at least four distinct effector classes. Further, we show that receptor specificity can be altered by exchanging receptor-binding regions, demonstrating the modularity of this domain. We propose that novel CdiA effectors are naturally generated through genetic recombination to interchange different receptor-binding domains and toxin payloads