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1	Targeting and function of CAH1 : Characterization of a novel protein pathway to the plant cell chloroplast / Transport och funktion av CAH1 : Karakterisering av en ny transportväg för proteiner till växtcellens kloroplast Burén, Stefan January 2010 (has links) The chloroplast is the organelle within a plant cell where photosynthesis takes place. This organelle originates from a cyanobacterium that was engulfed by a eukaryotic cell. During the transition from endosymbiont to organelle most of the cyanobacterial genes were transferred to the nuclear genome of the host cell, resulting in a chloroplast with a much reduced genome that requires massive import of gene products (proteins) back to the organelle. The majority of these proteins are translated in the cytosol as pre-proteins containing targeting information that directs them to a translocon complex in the chloroplast envelope, the Toc-Tic system, through which these proteins are transported. We have identified a protein in the model plant Arabidopsis thaliana, CAH1, that is trafficked via the endomembrane system (ER/Golgi apparatus) to the chloroplast instead of using the Toc-Tic machinery. This transport is partly mediated by canonical vesicle trafficking elements involved in ER to Golgi transport, such as Sar1 and RabD GTPases. Analysis of point mutated variants of CAH1 showed that both N-linked glycans and an intra-molecular disulphide bridge are required for correct folding, trafficking and function of the protein. Since chloroplasts lack N-glycosylation machinery, we propose that a route for chloroplast proteins that require endomembrane-specific post-translational modifications for their functionality exists as a complement to the Toc-Tic system. We also show that mutant plants with disrupted CAH1 gene expression have reduced rates of CO2 uptake and accumulate lower amounts of starch compared to wild-type plants, indicating an important function of the CAH1 protein for the photosynthetic capacity of Arabidopsis. Further study of CAH1 will not only be important to reveal its role in photosynthesis, but characterization of this novel protein pathway to the chloroplast can also shed light on how the plant cell evolved and clarify the purpose of keeping several chloroplast import pathways working in parallel. In addition, knowledge about this pathway could increase the opportunities for using plants as bio-factories for production of recombinant glycoproteins, which make up the vast majority of the bio-pharmaceutical molecules. / Kloroplasten är den organell i växtcellen där fotosyntesen sker. Denna organell härstammar från en cyanobakterie som togs upp av en eukaryot cell. Under omvandlingen från endosymbiont till organell har de flesta av den ursprungliga cyanobakteriens gener flyttats över till växtcellens eget kärngenom, vilket resulterat i en kloroplast som endast kan producera ett fåtal av de proteiner den behöver och som istället kräver att en mängd genprodukter (proteiner) transporteras tillbaka till organellen. De flesta av dessa proteiner syntetiseras i cytosolen som polypeptider innehållande en speciell signal för kloroplasten, och tranporteras över kloroplastens dubbelmembran (envelop) med hjälp av ett specifikt importsystem (Toc-Tic). Vi har identifierat ett protein i modellväxten Arabidopsis thaliana (CAH1) som istället för att använda Toc-Tic tranporteras via det endomembrana systemet (ER/Golgi). Transporten sker delvis med hjälp av faktorer involverade i normal vesikeltransport, t.ex. Sar1 och RabD GTPaser (mellan ER och Golgi). Genom att uttycka och analysera punktmuterade varianter av CAH1 har vi kunnat visa att både sockergrupper kopplade till proteinet, samt en intern svavelbrygga, är nödvändiga för korrekt veckning, transport och funktion av proteinet. Då kloroplasten saknar eget maskineri för att koppla sådana sockergrupper till proteiner så föreslår vi att anledningen till att denna rutt existerar, som ett komplement till Toc-Tic, är för att proteiner beroende av denna typ av modifiering ska kunna finnas i kloroplasten. Vi visar också att muterade växter som inte kan uttrycka genen som kodar för CAH1 uppvisar lägre upptag av CO2, samt ackumulerar mindre stärkelse än vildtypplantor, vilket antyder att CAH1 har en viktig funktion för den fotosyntetiska förmågan hos Arabidopsis. För att kunna fastställa den exakta funktionen för CAH1 kommer ytterliga studier att vara nödvändiga. En fördjupad karaktärisering av transportvägen som CAH1 följer till kloroplasten kan dessutom ge kunskap om hur växtcellen uppkom, samt besvara varför flera importvägar arbetar till synes parallellt med varandra. Kunskap om denna transportväg kan även bidra med användbar information i försöken att nyttja växter till att uttrycka rekombinanta N-glykosylerade proteiner, t. ex. antikroppar och vacciner. Arabidopsis chloroplast endomembrane system CAH1 protein targeting N-glycosylation Molecular biology Molekylärbiologi
2	Evolutionary history of clathrin-mediated endocytosis and the eisosome Cibrario, Luigi January 2011 (has links) Endocytosis is both an ancient and a diverse feature of the eukaryotic cell. Studying how it evolved can provide insight into the nature of the last common eukaryotic ancestor, and the diversification of eukaryotes into the known extant lineages. In this thesis, I present two studies on the evolution of endocytosis. In the first part of the thesis I report results from a large-scale, phylogenetic and comparative genomic study of clathrin-mediated endocytosis (CME). The CME pathway has been studied to a great level of detail in yeast to mammal model organisms. Several protein families have now been identified as part of the complex set of protein-protein and protein-lipid interactions which mediate endocytosis. To investigate how such complexity evolved, first, I defined the modular nature of the CME interactome (CME-I) by literature review, and then I carried out a systematic phylogenetic and protein domain architecture analysis of the proteins involved. These data were used to construct a model of the evolution of the CME-I network, and to map the expansion of the network's complexity to the eukaryotic tree of life. In the second part of the thesis, I present results from evolutionary and functional studies of the eisosome, a protein complex which has been proposed to regulate the spatial distribution of endocytosis in S. cerevisiae. The phylogeny of eisosomes components Pil1 and Lsp1 reported here, suggests that eisosomes are likely to have originated at the base of the fungi, and then diversified significantly via multiple gene duplications. I thus studied the localisation and function of Pil1 and Lsp1 homologues in Magnaporthe oryzae to investigate the role of eisosomes in filamentous fungi. Results suggests that eisosomes are linked with septal formation and integrity in M. oryzae, and that the septal specific Pil2 paralogue was lost in budding yeasts. Together, the data presented in this thesis describe the evolutionary history of a complex biological system, but also highlights the problem of asymmetry in the understanding of endocytic diversity in the eukaryotes. 571.6
3	Connecting Systemic RNAi to the Endomembrane System in Caenorhabditis elegans Holmgren, Benjamin T. January 2017 (has links) RNA interference (RNAi) is a gene regulation mechanism conserved among eukaryotes. To silence gene expression, RNAi relies on a short single-stranded guide RNA to steer the RNA-induced Silencing Complex (RISC) to mRNAs with guide strand-complementary sequences. RNAi is a highly membrane-associated process. The RISC complex is likely loaded at the rough Endoplasmic Reticulum, where it can bind to and degrade mRNAs. Components of the RISC complex also colocalize to late endosomes, and the efficiency of RNAi-mediated silencing is affected by changes in late endosome to lysosome fusion. RNAi can be systemic and inherited, effecting gene silencing in distal tissues and in the offspring. In this thesis, the model organism Caenorhabditis elegans was used to identify and characterize factors connecting systemic and inherited RNAi to the endomembrane system. We identify two SNARE proteins, SEC-22 and SYX-6, that both act as negative regulators of RNAi. SNAREs are necessary for vesicle fusion. Both SEC-22 and SYX-6 localize to late endosomes, and both interact with systemic RNAi protein SID-5 in a yeast two-hybrid (Y2H) screen. We find that in addition to its function in systemic RNAi, SID-5 is required for proper maturation of late endosomes. Furthermore, we identify the putative RNA-binding protein C12D8.1 as a novel regulator of RNAi inheritance. Mutant C12D8.1 animals will have enhanced inheritance of RNAi silencing, which negatively affects the ability of the progeny to silence new targets using RNAi. Finally, we describe a novel, object-based method for estimating significance in colocalization studies. This method helped us describe and quantify spatial relations between fluorophore-labeled proteins in situations where such analyses would otherwise be impossible. In conclusion, the work presented here further elucidates the connection between cellular RNAi, the endomembrane system, and the outside world. Systemic RNAi RNAi inheritance Endomembrane system Late endosome SID-5 SEC-22 SYX-6 C12D8.1 RNA Biological Sciences Biologiska vetenskaper
4	Analýza lokalizace endomembránových markerů v kortikální vrstvě rostlinných buněk a jejich interakce s komplexem Arp2/3 / Analysis of endomembrane markers in the cortical cytoplasm and their co-localization with Arp2/3 complex Jelínková, Barbora January 2021 (has links) ARP2/3 is an evolutionarily conserved heteroheptameric protein complex. Its main activity lies in the nucleation of dendritic actin filaments that are involved in membrane remodeling. ARP2/3 takes part in plasma membrane remodeling and the formation of cytoplasmic protrusions that serve in the amoeboid motion of mammalian cells and some protists and plays role in exocytosis and endocytosis of animal and yeast cells. The main objective of this work was to find a connection between the ARP2/3 complex and the regulation of the plant endomembrane system. Using TIRF microscopy we visualized the localization of the ARP2/3 complex in the cortical layer of plant cells and compared it to the localization of several endomembrane markers from the Rab family and an exocytotic marker Exo84b. In the vicinity of the plasma membrane, the ARP2/3 complex subunits localized to dynamic dots very similar to the localization of Exo84b protein. Colocalization analysis showed that a small portion of Exo84b marker and ARP2/3 complex signals colocalize and this result was seconded by the biochemical approach of coimmunoprecipitation. Key words: ARP2/3, endomembrane system, cortical layer, RabA1g, RabC1, RaD2a, Exo84b
5	Cellular Mechanisms of Gravitropism in ARG1 (Altered Response to Gravity) Mutants of <i>Arabidopsis Thaliana</i> Kumar, Neela Shiva 12 August 2008 (has links) No description available. Botany actin cytoskeleton Arabidopsis columella cells electron microscopy endodermis endomembrane system gravitropism gravity perception immunocytochemical plastid movement signal transduction statocytes
6	Cellular mechanisms of gravitropism in ARG1 (altered response to gravity) mutants of Arabidopsis thaliana Kumar, Neela Shiva. January 2008 (has links) Thesis (Ph. D.)--Miami University, Dept. of Botany, 2008. / Title from second page of PDF document. Includes bibliographical references.

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