Characteristics and Trends in Median Arcuate Ligament Syndrome (MALS) Associated Visceral Artery Aneurysms: A Systematic Descriptive Review of the Literature.

Median Arcuate Ligament Syndrome (MALS) is associated with true aneurysms, mainly of both the pancreaticoduodenal artery (PDA) and gastroduodenal artery (GDA). Although rare, their potential for rupture and adverse clinical outcomes warrants analysis. Prior studies suggest high rupture rates even for smaller aneurysms under 2 cm in this setting.

Prostate MRI quality: clinical impact of the PI-QUAL score in prostate cancer diagnostic work-up.

Objective: To assess the reproducibility and impact of prostate imaging quality (PI-QUAL) scores in a clinical cohort undergoing prostate multiparametric MRI.

Methods: PI-QUAL scores were independently recorded by three radiologists (two senior, one junior). Readers also recorded whether MRI was sufficient to rule-in/out cancer and if repeat imaging was required.

Gβγ is a direct regulator of endogenous p101/p110γ and p84/p110γ PI3Kγ complexes in mouse neutrophils.

The PI3Kγ isoform is activated by Gi-coupled GPCRs in myeloid cells, but the extent to which the two endogenous complexes of PI3Kγ, p101/p110γ and p84/p110γ, receive direct regulation through Gβγ or indirect regulation through RAS and the sufficiency of those inputs is controversial or unclear. We generated mice with point mutations that prevent Gβγ binding to p110γ (RK552DD) or to p101 (VVKR777AAAA) and investigated the effects of these mutations in primary neutrophils and in mouse models of neutrophilic inflammation. Loss of Gβγ binding to p110γ substantially reduced the activation of both p101/p110γ and p84/p110γ in neutrophils by various GPCR agonists.

ATG13 dynamics in nonselective autophagy and mitophagy: insights from live imaging studies and mathematical modeling.

During macroautophagy/autophagy, the ULK complex nucleates autophagic precursors, which give rise to autophagosomes. We analyzed, by live imaging and mathematical modeling, the translocation of ATG13 (part of the ULK complex) to the autophagic puncta in starvation-induced autophagy and ivermectin-induced mitophagy. In nonselective autophagy, the intensity and duration of ATG13 translocation approximated a normal distribution, whereas wortmannin reduced this effect and shifted to a log-normal distribution.

Selective Autophagy of Mitochondria on a Ubiquitin-Endoplasmic-Reticulum Platform.

The dynamics and coordination between autophagy machinery and selective receptors during mitophagy are unknown. Also unknown is whether mitophagy depends on pre-existing membranes or is triggered on the surface of damaged mitochondria. Using a ubiquitin-dependent mitophagy inducer, the lactone ivermectin, we have combined genetic and imaging experiments to address these questions.

Correlative Live-Cell Imaging and Super-Resolution Microscopy of Autophagy.

Correlative live-cell imaging and super-resolution microscopy of autophagy was developed to combine the temporal resolution of time-lapse fluorescence microscopy with the spatial resolution of super-resolution microscopy. HEK293 cells that express recombinant proteins of interest fused to fluorescent tags are imaged live to capture the formation of autophagosomes, fixed on stage to "snap-freeze" these structures, stained with appropriate antibodies, relocated, and imaged at super resolution by direct stochastic optical reconstruction microscopy. This chapter provides an easy-to-follow protocol along with practical tips and background information to help set up and perform an experiment.

Autophagy initiation by ULK complex assembly on ER tubulovesicular regions marked by ATG9 vesicles.

Autophagosome formation requires sequential translocation of autophagy-specific proteins to membranes enriched in PI3P and connected to the ER. Preceding this, the earliest autophagy-specific structure forming de novo is a small punctum of the ULK1 complex. The provenance of this structure and its mode of formation are unknown.

Live-cell imaging for the assessment of the dynamics of autophagosome formation: focus on early steps.

Autophagy is a cytosolic degradative pathway, which through a series of complicated membrane rearrangements leads to the formation of a unique double membrane vesicle, the autophagosome. The use of fluorescent proteins has allowed visualizing the autophagosome formation in live cells and in real time, almost 40 years after electron microscopy studies observed these structures for the first time. In the last decade, live-cell imaging has been extensively used to study the dynamics of autophagosome formation in cultured mammalian cells.

Dynamics of autophagosome formation: a pulse and a sequence of waves.

Autophagosomes form in eukaryotic cells in response to starvation or to other stress conditions brought about by the unwanted presence in the cytosol of pathogens, damaged organelles or aggregated protein assemblies. The uniqueness of autophagosomes is that they form de novo and that they are the only double-membraned vesicles known in cells, having arisen from flat membrane sheets which have expanded and self-closed. The various steps describing their formation as well as most of the protein and lipid components involved have been identified.

Imaging autophagy.

Autophagy is a membrane-trafficking pathway activated to deliver cytosolic material for degradation to lysosomes through a novel membrane compartment, the autophagosome. Fluorescence microscopy is the most common method used to visualize proteins inside cells, and it is widely used in the autophagy field. To distinguish it from the cellular background, the protein of interest (POI) is either fused with a genetically encoded fluorescent protein or stained with an antibody that is conjugated to an inorganic fluorescent compound.

Dynamic association of the ULK1 complex with omegasomes during autophagy induction.

Induction of autophagy requires the ULK1 protein kinase complex and the Vps34 lipid kinase complex. PtdIns3P synthesised by Vps34 accumulates in omegasomes, membrane extensions of the ER within which some autophagosomes form. The ULK1 complex is thought to target autophagosomes independently of PtdIns3P, and its functional relationship to omegasomes is unclear.

Live cell imaging of early autophagy events: omegasomes and beyond.

Autophagy is a cellular response triggered by the lack of nutrients, especially the absence of amino acids. Autophagy is defined by the formation of double membrane structures, called autophagosomes, that sequester cytoplasm, long-lived proteins and protein aggregates, defective organelles, and even viruses or bacteria. Autophagosomes eventually fuse with lysosomes leading to bulk degradation of their content, with the produced nutrients being recycled back to the cytoplasm.

Regulation of lipid droplet and membrane biogenesis by the acidic tail of the phosphatidate phosphatase Pah1p.

Lipins are evolutionarily conserved phosphatidate phosphatases that perform key functions in phospholipid, triglyceride, and membrane biogenesis. Translocation of lipins on membranes requires their dephosphorylation by the Nem1p-Spo7p transmembrane phosphatase complex through a poorly understood mechanism. Here we identify the carboxy-terminal acidic tail of the yeast lipin Pah1p as an important regulator of this step.

Phosphorylation of phosphatidate phosphatase regulates its membrane association and physiological functions in Saccharomyces cerevisiae: identification of SER(602), THR(723), AND SER(744) as the sites phosphorylated by CDC28 (CDK1)-encoded cyclin-dependent kinase.

The Saccharomyces cerevisiae PAH1-encoded phosphatidate phosphatase (PAP) catalyzes the penultimate step in the synthesis of triacylglycerol and plays a role in the transcriptional regulation of phospholipid synthesis genes. PAP is phosphorylated at multiple Ser and Thr residues and is dephosphorylated for in vivo function by the Nem1p-Spo7p protein phosphatase complex localized in the nuclear/endoplasmic reticulum membrane. In this work, we characterized seven previously identified phosphorylation sites of PAP that are within the Ser/Thr-Pro motif.

A phosphorylation-regulated amphipathic helix controls the membrane translocation and function of the yeast phosphatidate phosphatase.

Regulation of membrane lipid composition is crucial for many aspects of cell growth and development. Lipins, a novel family of phosphatidate (PA) phosphatases that generate diacylglycerol (DAG) from PA, are emerging as essential regulators of fat metabolism, adipogenesis, and organelle biogenesis. The mechanisms that govern lipin translocation onto membranes are largely unknown.

Building arks for tRNA: structure and function of the Arc1p family of non-catalytic tRNA-binding proteins.

Following the intricate architecture of the eukaryotic cell, protein synthesis involves formation of many macromolecular assemblies, some of which are composed by tRNA-aminoacylation enzymes. Protein-protein and protein-tRNA interactions in these complexes can be facilitated by non-catalytic tRNA-binding proteins. This review focuses on the dissection of the molecular, structural and functional properties of a particular family of such proteins: yeast Arc1p and its homologues in prokaryotes and higher eukaryotes.

Incorporation of the Arc1p tRNA-binding domain to the catalytic core of MetRS can functionally replace the yeast Arc1p-MetRS complex.

The catalytic core of methionyl-tRNA synthetase (MetRS) is conserved among all life kingdoms but, depending on species origin, is often linked to non-catalytic domains appended to its N- or C-terminus. These domains usually contribute to protein-protein or protein-tRNA interactions but their exact biological role and evolutionary purpose is poorly understood. Yeast MetRS contains an N-terminal appendix that mediates its interaction with the N-terminal part of Arc1p.

Molecular determinants of the yeast Arc1p-aminoacyl-tRNA synthetase complex assembly.

Eukaryotic aminoacyl-tRNA synthetases are usually organized into high-molecular-weight complexes, the structure and function of which are poorly understood. We have previously described a yeast complex containing two aminoacyl-tRNA synthetases, methionyl-tRNA synthetase and glutamyl-tRNA synthetase, and one noncatalytic protein, Arc1p, which can stimulate the catalytic efficiency of the two synthetases. To understand the complex assembly mechanism and its relevance to the function of its components, we have generated specific mutations in residues predicted by a recent structural model to be located at the interaction interfaces of the N-terminal domains of all three proteins.