Type III protein-secretion machines are essential for the interactions of many pathogenic or symbiotic bacterial species with their respective eukaryotic hosts. The core component of these machines is the injectisome, a multiprotein complex that mediates the selection of substrates, their passage through the bacterial envelope, and ultimately their delivery into eukaryotic target cells. The injectisome is composed of a large cytoplasmic complex or sorting platform, a multiring base embedded in the bacterial envelope, and a needle-like filament that protrudes several nanometers from the bacterial surface and is capped at its distal end by the tip complex. A characteristic feature of these machines is that their activity is stimulated by contact with target host cells. The sensing of target cells, thought to be mediated by the distal tip of the needle filament, generates an activating signal that must be transduced to the secretion machine by the needle filament. Here, through a multidisciplinary approach, including solid-state NMR (SSNMR) and cryo electron microscopy (cryo-EM) analyses, we have identified critical residues of the needle filament protein of a
Salmonella
Typhimurium type III secretion system that are involved in the regulation of the activity of the secretion machine. We found that mutations in the needle filament protein result in various specific phenotypes associated with different steps in the type III secretion process. More specifically, these studies reveal an important role for a polymorphic helix of the needle filament protein and the residues that line the lumen of its central channel in the control of type III secretion.
The constitutive decay element (CDE) of tumor necrosis factor α (TNF-α) mRNA (Tnf) represents the prototype of a class of RNA motifs that mediate rapid degradation of mRNAs encoding regulators of the immune response and development. CDE-type RNAs are hairpin structures featuring a tri-nucleotide loop. The protein Roquin recognizes CDE-type stem loops and recruits the Ccr4-Caf1-Not deadenylase complex to the mRNA, thereby inducing its decay. Stem recognition does not involve nucleotide bases; however, there is a strong stem sequence requirement for functional CDEs. Here, we present the solution structures of the natural Tnf CDE and of a CDE mutant with impaired Roquin binding. We find that the two CDEs adopt unique and distinct structures in both the loop and the stem, which explains the ability of Roquin to recognize stem loops in a sequence-specific manner. Our findings result in a relaxed consensus motif for prediction of new CDE stem loops.
Ionizing radiation, free radicals, and reactive oxygen species produce hundreds of different DNA lesions. Clustered lesions are typical for ionizing radiation. They compromise the efficiency of the base excision repair (BER) pathway, and as a consequence, they are much more toxic and mutagenic than isolated lesions. Despite their biological relevance, e.g., in cancer radiotherapy and accidental exposure, they are not very well studied from a structural point of view, and while insights provided by structural studies contribute to the understanding of the repair process, only three nuclear magnetic resonance (NMR) studies of DNA containing clusters of lesions were reported. Herein, we report the first NMR solution structure of two DNAs containing a bistranded cluster with the 2'-deoxyribonolactone and 8-oxoguanine lesions. Both DNA duplexes feature a 2'-deoxyribonolactone site in the middle of the sequence of one strand and differ by the relative position of the 8-oxoguanine, staggered 3' or 5' side on the complementary strand at a three-nucleotide distance. Depending on its relative position, the repair of the 8-oxoguanine lesion by the base excision repair protein Fpg is either almost complete or inhibited. We found that the structures of the two DNAs containing a bistranded cluster of two lesions are similar and do not deviate very much from the standard B-form. As no obvious structural deformations were observed between the two duplexes, we concluded that the differences in Fpg activity are not due to differences in their global conformation.
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