Targeting of the yeast Sna3p and Sna4p to the endosomal pathway depends on their interaction with ubiquitin ligase Rsp5p

Pokrzywa, Wojciech

12 March 2009

Sna3p and Sna4p are small proteins of unknown function possessing two transmembrane domains and belong to a small family of conserved proteins present in plant and fungi. The budding yeast has four SNA proteins (Sna1–4) that have different localizations in the cell. Sna3p is targeted to the vacuolar lumen by the multivesicular body pathway. Two observations marked Sna3p as a multivesicular body cargo that is sorted in an ubiquitin-independent manner. First, Sna3p-GFP is still correctly transported to internal multivesicular body vesicles under conditions of ubiquitin depletion, which impairs multivesicular body sorting of certain other cargoes. Second, a mutant form of Sna3p-GFP lacking the only potential positions for ubiquitylation is still correctly targeted to the vacuolar lumen. It has thus been postulated that ubiquitylation marks, but not all, membrane proteins for sorting into the interior of the vacuole. In this study we present a further characterization of the Golgi to vacuole trafficking of Sna3p together with its ubiquitylation status. We observed that Sna3p physically interacts with the E3 ligase Rsp5p and that this interaction is essential for sorting of Sna3p to the endosomal pathway. Sna3p is ubiquitylated on its Lys125 residue by Rsp5p and modified by Lys 63-linked ubiquitin chains. In contrast to the conclusions from prior reports, we demonstrated that, as noticed for most other multivesicular body cargoes, Sna3p ubiquitylation is required for its multivesicular body sorting. Sna4p is localized to the vacuolar membrane and interior. Sna4p contains an acidic di-leucine motif, that could be a sorting signal specific for AP-3 dependent pathway directing Sna4p to the vacuolar membrane. In apm3∆ cells, where µ subunit of the AP-3 complex is deleted, Sna4p is missorted to the vacuolar interior. Strikingly, this localization is different from localization of markers of AP-3 dependent pathway. This dissimilarity indicates that Sna4p possesses an additional characteristic, absent in other AP-3 cargoes, driving it to the vacuolar interior. In this study we have shown that the acidic di-leucine motif is indeed the sorting signal of Sna4p to the vacuolar membrane through the AP-3 dependent pathway, and that a part of Sna4p is targeted to the vacuole lumen via the multivesicular body pathway. The ability to enter multivesicular bodies is linked to the c-terminal PPPY sequence of Sna4p. Sna4p interacts with Rsp5p via this PY motif, resulting in Sna4p ubiquitylation on its lysine 128 and incorporation into the multivesicular bodies. Thus, Sna4p possesses two functional sorting signals which allow it to use two different pathways directing the protein to the vacuole.

Rsp5p

Ubiquitin ligase

Ubiquitin

Sna3p

Sna4p

Multivesicular body

AP-3 adaptor

Understanding the plant ESCRT machinery and its role in tombusvirus-induced mitochondrial multivesicular body biogenesis

Richardson, Lynn

13 September 2012

Carnation Italian ringspot virus (CIRV) is a positive-strand RNA virus that assembles its membrane-bound replication complexes at mitochondria in plant cells. This process is accompanied by extensive inward invagination of the mitochondrial outer membrane, leading to the formation of cytosol-filled spherules, wherein viral RNA synthesis occurs. The mechanism by which CIRV is able to induce spherule formation is unknown, however growing evidence suggests that the host-cell ESCRT (Endosomal Sorting Complex Required for Transport) machinery – a multi-protein complex normally involved in late endosome maturation – may be involved. ESCRT consists of ~30 soluble proteins that form sub-complexes assembled at the late endosomal surface, and function in multivesicular body (MVB) biogenesis. While ESCRT is relatively well characterized in yeasts and mammals, comparably little is known about ESCRT in plants. Hence, as an initial step towards understanding the potential role of ESCRT in CIRV replication, we examined the protein-protein interaction network, subcellular localization, and gene expression profiles of the Arabidopsis thaliana ESCRT components. Overall, the results from these studies suggest that ESCRT organization and function is relatively well conserved in plants compared to other eukaryotes. We also observed that ESCRT is important for CIRV replication, as expression of dominant-negative versions of several key ESCRT components reduced CIRV replication efficiency in plant cells. Moreover, the Arabidopsis ESCRT-I component, Vps23A is recruited from late endosomes to mitochondria in plant cells expressing the CIRV replicase protein, p36, and recruitment of Vps23A was shown to be mediated by sequences located at the N terminus of p36. It was also shown that recruitment of Vp23A to mitochondria by p36 does not require the Ubiquitin E2 Variant domain of Vps23A, which is in contrast to recruitment of ESCRT by retroviruses during viral budding in mammalian cells. Taken together, these results support the hypothesis that CIRV recruits ESCRT by a novel mechanism in order to carry out its replication, a finding that may lend important insight to aspects of normal ESCRT function in plants.

plant cell biology

ESCRT

multivesicular body biogenesis

tombusvirus

plus-strand RNA virus

Characterization of peroxisomal multivesicular body morphology and the role of host-cell and viral components in their biogenesis in plant and yeast cells

Gibson, Kimberley

21 December 2009

Peroxisome biogenesis is complex, involving a diverse array of intracellular pathways and mechanisms that mediate their biogenesis and cellular functions. Relevant to our understanding of peroxisome biogenesis is the utilization of peroxisomal membranes for viral genome replication as observed in plant cells infected by several members of the Tombusviridae family of positive-strand RNA viruses. Tomato Bushy Stunt Virus (TBSV), for instance, usurps an array of host factors that facilitate the transformation of peroxisomes into peroxisomal multivesicular bodies (pMVB) the sites of viral RNA replication. In this study, pMVB topology and biogenesis was investigated using transmission electron and epifluorescence microscopy of tobacco and wildtype or mutant budding yeast that were transformed with TBSV replicase proteins and a defective interfering viral RNA. Overall, the results suggest that host-virus interactions specifically associated with Endosomal Sorting Complex Required for Transport (ESCRT) and lipid metabolism are involved in TBSV replication and pMVB biogenesis.

escrt

plant virus

host-viral interaction

host-virus interaction

pMVB

peroxisomal multivesicular body

peroxisomes

peroxisome biogenesis

tbsv

tomato bushy stunt virus

Mechanisms of Multivesicular Body Biogenesis and Exosome Release / Biogenese multivesikulärer Endosomen und Mechanismen der Exosomenfreizetzung

Hsu, Chieh

08 February 2010

No description available.

570 Biowissenschaften, Biologie

Mathematics and Computer Science

Exosom

Multivesikuläres Endosom

PLP

Oligodendrozyt

Ceramide

ESCRT

Rab GTPase

Rab35

Endosom

exosome

multivesicular body

PLP

oligodendrocyte

ceramide

ESCRT

Rab GTPase

Rab35

endosome

42.15 Zellbiologie

WH Cytologie

Histologie

Zellbiologie

Zellkultur

Zytologie

Alzheimer’s Disease Pathology as a Clue to Pathogenesis

Funk, Kristen E.

16 August 2012

No description available.

Biochemistry

Biomedical Research

Neurosciences

Alzheimer&8217

s Disease

Autophagy

Confocal Microscopy

Endosome

Granulovacuolar Degeneration

Mass Spectrometry

Lysine Methylation

Lysosome

Multivesicular Body

Neurofibrillary Tangle

Pathology

Post-Translational Modification

Tau

Caractérisation cellulaire et fonctionnelle de l’autophagie : interactions avec la voie de maturation endosomale chez Caenorhabditis elegans / Functional and cellular analysis of autophagy : interactions with the endosomal maturation pathway in Caenorhabditis elegans

Djeddi, Abderazak

05 January 2011

L’autophagie est une voie catabolique durant laquelle des constituants cytoplasmiques sont engloutis dans des vésicules à double membrane nommées autophagosomes. Elle sert à éliminer les protéines mal repliées ou les agrégats protéiques, à détruire les organites défectueux comme les mitochondries, le réticulum endoplasmique et les peroxysomes mais aussi des pathogènes intracellulaires. Le matériel séquestré dans les autophagosomes est ensuite envoyé, pour dégradation, vers le lysosome. La dégradation du matériel séquestré génère des nucléotides, des acides aminés et des acides gras qui seront recyclés en vue de la synthèse de macromolécules et de la génération d’ATP.Dans cette étude nous explorons l’aspect cellulaire et fonctionnel de la voie de l’autophagie chez Caenorhabditis elegans. Nous montrons que le génome du nématode contient deux homologues du gène autophagique de levure Atg8. Ces homologues codent pour les protéines LGG-1 et LGG-2 qui sont des protéines des membranes des autophagosomes. Ces protéines agissent de façon synergique dans les processus physiologiques impliquant l’autophagie, en l’occurrence, la longévité et la formation des larves dauer.Nous montrons également que l’autophagie est impliquée dans le maintien de l’homéostasie cellulaire chez les mutants ESCRT. Les complexes ESCRT sont impliqués dans l’adressage des protéines ubiquitinées vers les corps multi vésiculaires pour les dégrader. Les mutants ESCRT se caractérisent par des altérations cellulaires et développementales. Nos résultats indiquent que l’inactivation des ESCRT cause une augmentation du flux autophagique. L’inactivation de l’autophagie dans ces mutants exacerbe les défauts cellulaires alors que son induction protège de la dégradation. / Macroautophgagy is a catabolic process involved in the clearance of cellular components in the lysosome when cells face starvation conditions. This eukaryotic process requires the formation of double membrane vesicles named autophagosomes. Autophagy is implicated in the elimination of misfolded proteins, protein aggregates and long-lived or damaged organelles such as mitochondria, endoplasmic reticulum and peroxysomes. It is alos required for the clearance of intracellular pathogens. The material enclosed inside autophagososmes in degraded in the lysosome: nucleotides, amino-acids and fatty-acids are generated and reused for neosynthesis of macromolecules and ATP.In the present study, we are exploring the cellular and functional aspects of the autophagic pathway in Caenorhabditis elegans. We show that the genome of the worm contain two homologues of the Yeast autophagic gene, Atg8. These homlogues encode for two proteins namely, LGG-1 and LGG-2, which localize to the autophagosomal membranes. We have shown that this two proteins act synergistically in dauer formation and longevity.We have also shown that autophagy play an important role in maintaining cell homeostasis in endosomal maturation mutans. These latter mutants show defects in the ESCRT coplexes (Endosomal Sorting Complex Required for Transport). ESCRT complexes are required the recycling of cell surface receptors and for the sorting of ubiquitinated prtoteins into the multivesicular bodies. Mutations in the ESCRTs cause cellular et developmental defects. In our study, we show that autophagy is induced in these mutants and play a beneficial role in correcting cellular defects.

Autophagie

Lgg-1

Lgg-2

Longevité

Dauer

Corps multivésiculaire

Vps

Lysosome

Voie endosomale

Caenorhabditis elegans

Autophagy

Lgg-1

Lgg-2

Longevity

Dauer

Multivesicular body

Vps

Lysosome

Endosomal pathway

Caenorhabditis elegans