Non-canonical autophagy drives alternative ATG8 conjugation to phosphatidylserine.

Autophagy is a fundamental catabolic process that uses a unique post-translational modification, the conjugation of ATG8 protein to phosphatidylethanolamine (PE). ATG8 lipidation also occurs during non-canonical autophagy, a parallel pathway involving conjugation of ATG8 to single membranes (CASM) at endolysosomal compartments, with key functions in immunity, vision, and neurobiology. It is widely assumed that CASM involves the same conjugation of ATG8 to PE, but this has not been formally tested. Here, we discover that all ATG8s can also undergo alternative lipidation to phosphatidylserine (PS) during CASM, induced pharmacologically, by LC3-associated phagocytosis or influenza A virus infection, in mammalian cells. Importantly, ATG8-PS and ATG8-PE adducts are differentially delipidated by the ATG4 family and bear different cellular dynamics, indicating significant molecular distinctions. These results provide important insights into autophagy signaling, revealing an alternative form of the hallmark ATG8 lipidation event. Furthermore, ATG8-PS provides a specific "molecular signature" for the non-canonical autophagy pathway.

WIPI2B links PtdIns3P to LC3 lipidation through binding ATG16L1.

WIPI proteins, phosphatidylinositol 3-phosphate (PtdIns3P) binding proteins with ß-propeller folds, are recruited to the omegasome following PtdIns3P production. The functions of the WIPI proteins in autophagosome formation are poorly understood. In a recent study, we reported that WIPI2B directly binds ATG16L1 and functions by recruiting the ATG12-ATG5-ATG16L1 complex to forming autophagosomes during starvation- or pathogen-induced autophagy. Our model of WIPI2 function provides an explanation for the PtdIns3P-dependent recruitment of the ATG12-ATG5-ATG16L1 complex during initiation of autophagy.

WIPI2b and Atg16L1: setting the stage for autophagosome formation.

The double-membraned autophagosome organelle is an integral part of autophagy, a process that recycles cellular components by non-selectively engulfing and delivering them to lysosomes where they are digested. Release of metabolites from this process is involved in cellular energy homoeostasis under basal conditions and during nutrient starvation. Selective engulfment of protein aggregates and dysfunctional organelles by autophagosomes also prevents disruption of cellular metabolism. Autophagosome formation in animals is crucially dependent on the unique conjugation of a group of ubiquitin-like proteins in the microtubule-associated proteins 1A/1B light chain 3 (LC3) family to the headgroup of phosphatidylethanolamine (PE) lipids. LC3 lipidation requires a cascade of ubiquitin-like ligase and conjugation enzymes. The present review describes recent progress and discovery of the direct interaction between the PtdIns3P effector WIPI2b and autophagy-related protein 16-like 1 (Atg16L1), a component of the LC3-conjugation complex. This interaction makes the link between endoplasmic reticulum (ER)-localized production of PtdIns3P, triggered by the autophagy regulatory network, and recruitment of the LC3-conjugation complex crucial for autophagosome formation.

WIPI2 links LC3 conjugation with PI3P, autophagosome formation, and pathogen clearance by recruiting Atg12-5-16L1.

Mammalian cell homeostasis during starvation depends on initiation of autophagy by endoplasmic reticulum-localized phosphatidylinositol 3-phosphate (PtdIns(3)P) synthesis. Formation of double-membrane autophagosomes that engulf cytosolic components requires the LC3-conjugating Atg12-5-16L1 complex. The molecular mechanisms of Atg12-5-16L1 recruitment and significance of PtdIns(3)P synthesis at autophagosome formation sites are unknown. By identifying interacting partners of WIPIs, WD-repeat PtdIns(3)P effector proteins, we found that Atg16L1 directly binds WIPI2b. Mutation experiments and ectopic localization of WIPI2b to plasma membrane show that WIPI2b is a PtdIns(3)P effector upstream of Atg16L1 and is required for LC3 conjugation and starvation-induced autophagy through recruitment of the Atg12-5-16L1 complex. Atg16L1 mutants, which do not bind WIPI2b but bind FIP200, cannot rescue starvation-induced autophagy in Atg16L1-deficient MEFs. WIPI2b is also required for autophagic clearance of pathogenic bacteria. WIPI2b binds the membrane surrounding Salmonella and recruits the Atg12-5-16L1 complex, initiating LC3 conjugation, autophagosomal membrane formation, and engulfment of Salmonella.

The structural basis of novel endosome anchoring activity of KIF16B kinesin.

KIF16B is a newly identified kinesin that regulates the intracellular motility of early endosomes. KIF16B is unique among kinesins in that its cargo binding is mediated primarily by the strong interaction of its PX domain with endosomal lipids. To elucidate the structural basis of this unique endosomal anchoring activity of KIF16B-PX, we determined the crystal structure of the PX domain and performed in vitro and cellular membrane binding measurements for KIF16B-PX and mutants. The most salient structural feature of KIF16B-PX is that two neighboring residues, L1248 and F1249, on the membrane-binding surface form a protruding hydrophobic stalk with a large solvent-accessible surface area. This unique structure, arising from the complementary stacking of the two side chains and the local conformation, allows strong hydrophobic membrane interactions and endosome tethering. The presence of similar hydrophobic pairs in the amino-acid sequences of other membrane-binding domains and proteins suggests that the same structural motif may be shared by other membrane-binding proteins, whose physiological functions depend on strong hydrophobic membrane interactions.

Ultraviolet wavelength dependence of photomorphological and photosynthetic responses in Brassica napus and Arabidopsis thaliana.

Among the photomorphological responses in plants induced by ultraviolet-B radiation (UVB; 290 nm-320 nm) are leaf asymmetry, leaf thickening and cotyledon curling. We constructed an action spectrum of cotyledon curling in light-grown Brassica napus to characterize the UVB photoreceptor that initiates this response. Cotyledon curling was also characterized in Arabidopsis thaliana. Peak efficiency for this response occurred between 285 and 290 nm. Additionally, UVB-induced changes in epidermal cells from A. thaliana cotyledons were assessed because they are the likely site of UVB photoreception that leads to curling. Investigation of cellular structure, chlorophyll a fluorescence and chlorophyll concentration indicated that cotyledon curling is not concomitant with gross cellular damage or inhibition of photosynthesis, which only occurred in response to wavelengths <280 nm. Many UVB effects are apparently an indirect consequence of UVB radiation, dependent on UVB-mediated increases in reactive oxygen species (ROS) that either act as a signal in the UVB transduction pathway or cause oxidative damage. The cotyledon curling response was impeded by ascorbate and cystine, ROS scavengers and was promoted by H(2)O(2), a ROS. We suggest that following absorption by a UVB chromophore, ROS are generated via photosensitization, ultimately leading to cotyledon curling.

PB1 domain-mediated heterodimerization in NADPH oxidase and signaling complexes of atypical protein kinase C with Par6 and p62.

Maximal activation of NADPH oxidase requires formation of a complex between the p40(phox) and p67(phox) subunits via association of their PB1 domains. We have determined the crystal structure of the p40(phox)/p67(phox) PB1 heterodimer, which reveals that both domains have a beta grasp topology and that they bind in a front-to-back arrangement through conserved electrostatic interactions between an acidic OPCA motif on p40(phox) and basic residues in p67(phox). The structure enabled us to identify residues critical for heterodimerization among other members of the PB1 domain family, including the atypical protein kinase C zeta (PKC zeta) and its partners Par6 and p62 (ZIP, sequestosome). Both Par6 and p62 use their basic "back" to interact with the OPCA motif on the "front" of the PKC zeta. Besides heterodimeric interactions, some PB1 domains, like the p62 PB1, can make homotypic front-to-back arrays.

Peptide blockade of HIFalpha degradation modulates cellular metabolism and angiogenesis.

Hypoxia-inducible factor-1 (HIF) is a transcription factor central to oxygen homeostasis. It is regulated via its alpha isoforms. In normoxia they are ubiquitinated by the von Hippel-Lindau E3 ligase complex and destroyed by the proteasome, thereby preventing the formation of an active transcriptional complex. Oxygen-dependent enzymatic hydroxylation of either of two critical prolyl residues in each HIFalpha chain has recently been identified as the modification necessary for targeting by the von Hippel-Lindau E3 ligase complex. Here we demonstrate that polypeptides bearing either of these prolyl residues interfere with the degradative pathway, resulting in stabilization of endogenous HIFalpha chains and consequent up-regulation of HIF target genes. Similar peptides in which the prolyl residues are mutated are inactive. Induction of peptide expression in cell cultures affects physiologically important functions such as glucose transport and leads cocultured endothelial cells to form tubules. Coupling of these HIFalpha sequences to the HIV tat translocation domain allows delivery of recombinant peptide to cells with resultant induction of HIF-dependent genes. Injection of tat-HIF polypeptides in a murine sponge angiogenesis assay causes a markedly accelerated local angiogenic response and induction of glucose transporter-1 gene expression. These results demonstrate the feasibility of using these polypeptides to enhance HIF activity, opening additional therapeutic avenues for ischemic diseases.

Structural basis for the recognition of hydroxyproline in HIF-1 alpha by pVHL.

Hypoxia-inducible factor-1 (HIF-1) is a transcriptional complex that controls cellular and systemic homeostatic responses to oxygen availability. HIF-1 alpha is the oxygen-regulated subunit of HIF-1, an alpha beta heterodimeric complex. HIF-1 alpha is stable in hypoxia, but in the presence of oxygen it is targeted for proteasomal degradation by the ubiquitination complex pVHL, the protein of the von Hippel Lindau (VHL) tumour suppressor gene and a component of an E3 ubiquitin ligase complex. Capture of HIF-1 alpha by pVHL is regulated by hydroxylation of specific prolyl residues in two functionally independent regions of HIF-1 alpha. The crystal structure of a hydroxylated HIF-1 alpha peptide bound to VCB (pVHL, elongins C and B) and solution binding assays reveal a single, conserved hydroxyproline-binding pocket in pVHL. Optimized hydrogen bonding to the buried hydroxyprolyl group confers precise discrimination between hydroxylated and unmodified prolyl residues. This mechanism provides a new focus for development of therapeutic agents to modulate cellular responses to hypoxia.