Eyespot Assembly and Positioning in Chlamydomonas reinhardtii

Boyd, Joseph Samuel

January 2011

The eyespot of the biflagellate unicellular green alga Chlamydomonas reinhardtii is a complex organelle that facilitates directional responses of the cell to environmental light stimuli. The eyespot, which assembles de novo after every cell division and retains a distinctive association with the microtubule cytoskeleton, comprises an elliptical patch of rhodopsin photoreceptors in the plasma membrane and stacks of carotenoid-rich pigment granule arrays in the chloroplast and serves as a model for understanding how organelles are formed and placed asymmetrically in the cell. This study describes the roles of several factors in the assembly and positioning of the eyespot. Two loci, EYE2 and EYE3, define factors involved in the formation and organization of the eyespot pigment granule arrays. Whereas EYE3, a serine/threonine kinase of the ABC1 family, localizes to pigment granules, EYE2 localization corresponds to an area of the chloroplast envelope in the eyespot. These proteins play interdependent roles: EYE2 and the ChR1 photoreceptor co-position in the absence of pigment granules, and the pigment granules are required to maintain the shape and integrity of the EYE2/ChR1 patch. The miniature-eyespot locus MIN2 affects eyespot size and likely regulates the amount of material available for eyespot assembly. The MLT2 locus regulates eyespot size, number, and asymmetry. A novel locus, PEY1, modulates the position of the eyespot on the anterior-posterior axis by affecting microtubule rootlet length. A working model is developed wherein rootlet microtubule-directed photoreceptor localization establishes connections in the chloroplast envelope with EYE2, which directs the site for pigment granule array assembly, and MLT2 is proposed to negatively regulate the levels of eyespot proteins.

Chlamydomonas

eyespot

microtubule rootlet

organelle biogenesis

The Rhizoplast (Flagellar Rootlet) of Naegleria

Simpson, Peter

10 1900

<p> The rhizoplast (flagellar rootlet) of the amebaflagellate Naegleria gruberi has been studied in sectioned cells and in the isolated state. Since the organelle arises, as do the other components of the flagellar apparatus, through a de novo assembly, and possibly a de novo synthesis during the ameba-to-flagellate transformation, the characterization of the rhizoplast's nature may be of importance in the study of a differentiation process in a eukaryotic cell. </p> <p> Structurally, the organelle is a periodically-banded, longitudinally fibrous structure arising in the basal body area of the cell and tapering towards its end in the cytoplasm adjacent to the nucleus. The attachment of the organelle to the basal bodies is mediated through the interbasal body connector and the rhizoplast-associated microtubules. Attachment to the nucleus is unlikely as it has never been unequivocally demonstrated in electron-microscope studies. </p> <p> Rhizoplasts exhibit a distinct periodicity composed of alternating electron-opaque and electron-transparent bands. Variations in the width of both bands has been observed and is discussed in terms of the possible role of the organelle as an anchor and stapilizing structure for the flagellar complex, with contractility and elasticity being discussed as possible mechanisms of this variation. </p> <p> An isolation and partial purification of the rhizoplast has been achieved and is described with reference to its possible use as a tool in the biochemical analysis of the rhizoplast. An aggregation phenomenon of dissolved rhizoplast material by divalent cations has been observed and is discussed, keeping in mind the similar phenomena exhibited by the contractile proteins paramyosin and tropomyosino Collagen, which exhibits a reaggregation from solution, is discussed and tentatively discarded as a possibility for rhizoplast material due to its tendency towards solubilization rather than reaggregation in solutions containing divalent cations. </p> / Thesis / Master of Science (MSc)

Rhizoplast

Flagellar Rootlet

ameboflagellate

Naegleria gruberi

Meckelin Functions in the Guided Movement and Orientation of Basal Bodies Prior to Duplication in Paramecium tetraurelia

Picariello, Tyler August

01 January 2015

Ciliopathies are a group of disorders that arise from ciliary dysfunction. Meckelin (MKS3 or TMEM67) is a conserved transmembrane protein found at the transition zone of ciliated cells. In humans MKS3 is one of 3 genes linked to the ciliopathy Meckel Syndrome. This disease is characterized by occipital meningioencephalocoele, polycystic kidneys, fibrotic changes to the liver, postnatal polydactyly and situs inversus. Paramecium tetraurelia is a single celled ciliated eukaryote. Its surface is organized of a meshwork of cortical units that run the length of the cell. At the center of the cortical units are either one or two basal bodies. In two basal body units only the posterior basal body is ciliated. From the ciliated basal body, three rootlets project in stereotypical orientations: the post-ciliary rootlet projects posteriorly, the transverse microtubule projects toward the adjacent basal body row and the striated rootlet projects anteriorly. Both the post-ciliary rootlet and transverse microtubule are microtubule-based structures. The striated rootlet is composed of multiple subunits that are predicted to have conserved segmented coiled coil domains known as SF-Assemblin domains. In Picariello at al., 2014, we showed that MKS3 is present in the transition zone of Paramecium tetraurelia and that RNAi for MKS3 leads to global ciliary loss. Additionally, RNAi for MKS3 results in the disorganization of the basal body rows. Within the areas of disorganization, the basal bodies along with their striated rootlets, post-ciliary rootlets and transverse microtubules are rotated away from their expected orientation. Interestingly, the post-ciliary rootlet and transverse microtubule are still attached at the expected angles relative to each other within the areas of disorganization. Initial GST pull-down experiments using the coiled coil domain of MKS3 suggest a potential interaction between MKS3 and the striated rootlet family members KdC1 and KdB2. To test potential interactions between MKS3 and the striated rootlet we identified 27 potential striated rootlet family members in Paramecium. Full-length sequences for 13 of these genes were marked at their N-terminus with a 3x FLAG sequence. Components with a conserved SF-Assemblin domain were distributed uniformly within the striated rootlet. Components lacking the SF-Assemblin domain were found in various cellular locations, but not within the striated rootlet. GST pull-down experiments utilizing the MKS3 C-terminus as bait were performed using cells expressing the FLAG-tagged striated rootlet family members. Unfortunately a clear interaction between MKS3 and the striated rootlet remains elusive. The organized nature of the surface of Paramecium has allowed us to identify a previously unrealized function for MKS3. Our immunofluorescence data suggest that MKS3 functions outside the transition zone to maintain basal body row organization by potentially contributing to a link between the basal body and the striated rootlet. Without the link, the migrating basal bodies are free to rotate and project their rootlets in the wrong directions. Although the nature of the link remains elusive, the identification of disorganized basal body rows upon MKS3 reduction suggests that, in addition to ciliary dysfunction, basal body polarity defects may contribute to the development of MKS.

Basal bodies

Cytoskeleton

Meckelin

striated rootlet

Biology

Genetics and Genomics