Mito-TIPTP Increases Mitochondrial Function by Repressing the Rubicon-p22phox Interaction in Colitis-Induced Mice

The run/cysteine-rich-domain-containing Beclin1-interacting autophagy protein (Rubicon) is essential for the regulation of nicotinamide adenine dinucleotide phosphate (NADPH) oxidase by interacting with p22phox to trigger the production of reactive oxygen species (ROS) in immune cells. In a previous study, we demonstrated that the interaction of Rubicon with p22phox increases cellular ROS levels. The correlation between Rubicon and mitochondrial ROS (mtROS) is poorly understood. Here, we report that Rubicon interacts with p22phox in the outer mitochondrial membrane in macrophages and patients with human ulcerative colitis. Upon lipopolysaccharide (LPS) activation, the binding of Rubicon to p22phox was elevated, and increased not only cellular ROS levels but also mtROS, with an impairment of mitochondrial complex III and mitochondrial biogenesis in macrophages. Furthermore, increased Rubicon decreases mitochondrial metabolic flux in macrophages. Mito-TIPTP, which is a p22phox inhibitor containing a mitochondrial translocation signal, enhances mitochondrial function by inhibiting the association between Rubicon and p22phox in LPS-primed bone-marrow-derived macrophages (BMDMs) treated with adenosine triphosphate (ATP) or dextran sulfate sodium (DSS). Remarkably, Mito-TIPTP exhibited a therapeutic effect by decreasing mtROS in DSS-induced acute or chronic colitis mouse models. Thus, our findings suggest that Mito-TIPTP is a potential therapeutic agent for colitis by inhibiting the interaction between Rubicon and p22phox to recover mitochondrial function.

Hedgehog-Interacting Protein is a multimodal antagonist of Hedgehog signalling

Hedgehog (HH) morphogen signalling, crucial for cell growth and tissue patterning in animals, is initiated by the binding of dually lipidated HH ligands to cell surface receptors. Hedgehog-Interacting Protein (HHIP), the only reported secreted inhibitor of Sonic Hedgehog (SHH) signalling, binds directly to SHH with high nanomolar affinity, sequestering SHH. Here, we report the structure of the HHIP N-terminal domain (HHIP-N) in complex with a glycosaminoglycan (GAG). HHIP-N displays a unique bipartite fold with a GAG-binding domain alongside a Cysteine Rich Domain (CRD). We show that HHIP-N is required to convey full HHIP inhibitory function, likely by interacting with the cholesterol moiety covalently linked to HH ligands, thereby preventing this SHH-attached cholesterol from binding to the HH receptor Patched (PTCH1). We also present the structure of the HHIP C-terminal domain in complex with the GAG heparin. Heparin can bind to both HHIP-N and HHIP-C, thereby inducing clustering at the cell surface and generating a high-avidity platform for SHH sequestration and inhibition. Our data suggest a multimodal mechanism, in which HHIP can bind two specific sites on the SHH morphogen, alongside multiple GAG interactions, to inhibit SHH signalling.

Isometric training improves fatigue resistance in dystrophin-deficient muscle

Eccentric contractions, in which the muscle is stretched during contraction, cause substantially greater damage than isometric (ISO) contractions, in which the length of the muscle does not change during contraction. Here, we tested the hypothesis that ISO training improves fatigue resistance in skeletal muscle from dystrophin-deficient mdx52 mice (15–22 wk old). ISO training (100 Hz stimulation frequency, 0.25-s contractions every 0.5 s, 6 sets of 60 contractions) was performed on the left plantar flexor muscles in vivo with supramaximal electrical stimulation every other day for 4 wk. Compared with the normal control muscle, resistance to fatigue was reduced in the nontrained muscle from mdx52 mice, which was accompanied by a reduction in citrate synthase activity and the LC3BII/I ratio and an increase in the phosphorylation levels of Akt Ser473 and the expression levels of p62. ISO training restored these alterations and markedly increased in vivo fatigue resistance and PGC-1α expression in mdx52 muscles. Moreover, an increased number of Evans Blue dye-positive fibers was significantly reduced by ISO training in mdx52 muscles. In contrast, ISO training did not restore a reduction in the amount of SH3 and cysteine-rich domain 3 in mdx muscles. Thus, our data suggest that mitochondrial function is impaired in dystrophin-deficient muscles, which is likely to be induced by the defective autophagy due to persistent activation of Akt. ISO training inhibits the aberrant activation of Akt presumably by up-regulating the PGC-1α expression, which results in improved mitochondrial function and thus fatigue resistance in dystrophin-deficient muscles.

Inhibition of SARS-CoV-2 spike protein palmitoylation reduces virus infectivity

Spike glycoproteins of almost all enveloped viruses are known to undergo post-translational attachment of palmitic acid moieties. The precise role of such palmitoylation of the spike protein in membrane fusion and infection is not completely understood. Here, we report that palmitoylation of the first five cysteine residues of the c-terminal cysteine-rich domain of the SARS-CoV-2 spike are indispensable for infection, and palmitoylation deficient spike mutants are defective in trimerization and subsequent membrane fusion. The DHHC9 palmitoyltransferase interacts with and palmitoylates the spike protein in the ER and Golgi, and knockdown of DHHC9 results in reduced fusion and infection of SARS-CoV-2. Two bis-piperazine backbone-based DHHC9 inhibitors inhibit SARS-CoV-2 spike protein palmitoylation and the resulting progeny virion particles released are defective in fusion and infection. This establishes these palmitoyltransferase inhibitors as potential new intervention strategies against SARS-CoV-2.

RASopathy Mutations Demonstrate the Critical Function of the Cysteine-rich Domain in Maintaining BRAF in an Autoinhibited State

BRAF is frequently mutated in human cancer and the RASopathy syndromes, with RASopathy mutations often observed in the cysteine-rich domain (CRD). Although the CRD is known for roles in phosphatidylserine (PS) binding, the RAS-RAF interaction, and RAF autoinhibition, how these differing activities impact BRAF function in normal and disease states is not well-characterized. Here, we analyze a panel of BRAF-CRD mutations and find that they can be classified into three groups based on their ability to relieve autoinhibition and/or enhance PS binding, with relief of autoinhibition being the predominant factor determining mutation severity. Comparison of the BRAF and CRAF CRDs further reveals that the BRAF-CRD is a stronger mediator of both autoinhibition and PS binding. Moreover, given the increased catalytic activity of BRAF versus CRAF, our findings indicate a more critical role for CRD-mediated autoinhibition in BRAF regulation, consistent with the high frequency of mutations that disrupt this function in the RASopathies.

The amyloid precursor protein is a conserved Wnt receptor

The Amyloid Precursor Protein (APP) and its homologues are transmembrane proteins required for various aspects of neuronal development and activity, whose molecular function is unknown. Specifically, it is unclear whether APP acts as a receptor, and if so what its ligand(s) may be. We show that APP binds the Wnt ligands Wnt3a and Wnt5a and that this binding regulates APP protein levels. Wnt3a binding promotes full-length APP (flAPP) recycling and stability. In contrast, Wnt5a promotes APP targeting to lysosomal compartments and reduces flAPP levels. A conserved Cysteine-Rich Domain (CRD) in the extracellular portion of APP is required for Wnt binding, and deletion of the CRD abrogates the effects of Wnts on flAPP levels and trafficking. Finally, loss of APP results in increased axonal and reduced dendritic growth of mouse embryonic primary cortical neurons. This phenotype can be cell-autonomously rescued by full length, but not CRD-deleted, APP and regulated by Wnt ligands in a CRD-dependent manner.

Structure and function of the ROR2 cysteine-rich domain in vertebrate noncanonical WNT5A signaling

The receptor tyrosine kinase ROR2 mediates noncanonical WNT5A signaling to orchestrate tissue morphogenetic processes, and dysfunction of the pathway causes Robinow syndrome, Brachydactyly B and metastatic diseases. The domain(s) and mechanisms required for ROR2 function, however, remain unclear. We solved the crystal structure of the extracellular cysteine rich (CRD) and Kringle (Kr) domains of ROR2 and found that, unlike other CRDs, the ROR2 CRD lacks the signature hydrophobic pocket that binds lipids/lipid-modified proteins, such as WNTs, suggesting a novel mechanism of receptor action. Functionally, we showed that the ROR2 CRD, but not other domains, is required and minimally sufficient to promote WNT5A signaling, and Robinow mutations in the CRD and the adjacent Kr alter ROR2 function. Moreover, we demonstrated that the activity of the ROR2 CRD requires Frizzled receptors. Thus, ROR2 acts via its CRD to potentiate the function of a receptor supercomplex that includes Frizzleds to transduce WNT5A signals.

Frizzled BRET sensors based on bioorthogonal labeling of unnatural amino acids reveal WNT-induced dynamics of the cysteine-rich domain.

Frizzleds (FZD1-10) comprise a class of G protein-coupled receptors containing an extracellular cysteine-rich domain (CRD) that binds lipoglycoproteins of the Wingless/Int-1 family (WNTs). Despite the prominent role of the WNT/FZD system in health and disease, our understanding of how WNT binding to the FZD CRD is translated into receptor activation and transmembrane signaling remains limited. Current hypotheses dispute the roles for conformational dynamics and the involvement of the linker domain connecting the CRD with the seven-helical transmembrane core of FZD. To clarify the mechanism of WNT binding to FZD and to elucidate how WNT/FZD complexes achieve signaling pathway specificity, we devised conformational FZD-CRD biosensors based on bioluminescence-resonance-energy-transfer (BRET). Using FZD engineered with N-terminal nanoluciferase and fluorescently-labeled unnatural amino acids in the linker domain and extracellular loop 3, we show that WNT-3A and WNT-5A induce similar CRD conformational rearrangements despite promoting distinct downstream signaling pathways, and that CRD dynamics are not required for WNT/β-catenin signaling. Thus, the novel FZD-CRD biosensors we report provide insights into the stepwise binding, activation and signaling processes in FZDs. The sensor design is broadly applicable to explore fundamental events in signal transduction mediated by other membrane receptors.