Structural insights into the targeting specificity of ubiquitin ligase for S. cerevisiae isocitrate lyase but not C. albicans isocitrate lyase.

In Saccharomyces cerevisiae, the glyoxylate cycle is controlled through the posttranslational regulation of its component enzymes, such as isocitrate lyase (ICL), which catalyzes the first unique step of the cycle. The ICL of S.cerevisiae (ScIcl1) is tagged for proteasomal degradation through ubiquitination by a multisubunit ubiquitin ligase (the glucose-induced degradation-deficient (GID) complex), whereas that of the pathogenic yeast Candida albicans (CaIcl1) escapes this process. However, the reason for the ubiquitin targeting specificity of the GID complex for ScIcl1 and not for CaIcl1 is unclear. To gain some insight into this, in this study, the crystal structures of apo ScIcl1 and CaIcl1 in complex with formate and the cryogenic electron microscopy structure of apo CaIcl1 were determined at a resolution of 2.3, 2.7, and 2.6 Å, respectively. A comparison of the various structures suggests that the orientation of N-terminal helix α1 in S.cerevisiae is likely key to repositioning of ubiquitination sites and contributes to the distinction found in C. albicans ubiquitin evasion mechanism. This finding gives us a better understanding of the molecular mechanism of ubiquitin-dependent ScIcl1 degradation and could serve as a theoretical basis for the research and development of anti-C. albicans drugs based on the concept of CaIcl1 ubiquitination.

Structural insight into the recognition of the linear ubiquitin assembly complex by Shigella E3 ligase IpaH1.4/2.5.

Pathogenic bacteria deliver virulence factors called effectors into host cells in order to facilitate infection. The Shigella effector proteins IpaH1.4 and IpaH2.5 are members of the 'novel E3 ligase' (NEL)-type bacterial E3 ligase family. These proteins ubiquitinate the linear ubiquitin assembly complex (LUBAC) to inhibit nuclear factor (NF)-κB activation and, concomitantly, the inflammatory response. However, the molecular mechanisms underlying the interaction and recognition between IpaH1.4 and IpaH2.5 and LUBAC are unclear. Here we present the crystal structures of the substrate-recognition domains of IpaH1.4 and IpaH2.5 at resolutions of 1.4 and 3.4 Å, respectively. The LUBAC-binding site on IpaH1.4 was predicted based on structural comparisons with the structures of other NEL-type E3s. Structural and biochemical data were collected and analysed to determine the specific residues of IpaH1.4 that are involved in interactions with LUBAC and influence NF-κB signaling. The new structural insight presented here demonstrates how bacterial pathogens target innate immune signaling pathways.