Oral ultrastructure and oral development of the misaligned undulating membrane mutant of Tetrahymena thermophila

The misaligned undulating membrane (mum) mutant of Tetrahymena thermophila is a non-conditional, single gene recessive mutation. The major effect of the mum mutation is the production of multiple undulating membrane (UM) fragments in the oral apparatus (OA). The ultrastructure of the UM fragments of mum OAs is identical to that of the single UM of wild-type OAs. Analysis of OA development at midbody using a combination of light microscopy of protargol-stained cells and SEM of demembranated whole cells showed that the phenotypic effect of the mum mutation first becomes evident during mid to late stage 4 and is fully manifested in early stage 5. The effect of the mutation involves a proliferation of excess basal bodies in the UM field. Subsequent events in the development of the mum OA from mid to late stage 5 are identical to those in wild-type OAs. This study suggests that the mum mutation establishes conditions that allow the production of multiple UMs and thus reveals that the UM field is competent for the complete and coordinated development of several adjacent UMs. This level of regional control is not clearly evident when a single UM is present. The comparison of development of wild-type and mum OAs required an extensive reanalysis of stages 4 and 5 of normal oral development. On the basis of current and previous observations, we propose a new and more subdivided staging system for oral development in Tetrahymena.     

Oral Assembly in Left-Handed Tetrahymena thermophila

We have investigated oral development in a non-genically derived left-handed (LH) form of Tetrahymena thermophila , in which the large-scale asymmetry of arrangement of cortical structures is reversed whereas the local asymmetry of ciliary architecture remains normal. Approximately 1/2 of the oral apparatuses (OAs) of LH cells develop in the form of superficial mirror-images of OAs of RH cells. In most of these OAs, membranelles are assembled from the cells'anterior to posterior. Nonetheless, the posterior ends of these membranelles undergo the basal body displacements that lead to a "sculptured" appearance, so that the membranelles of LH OAs become organized as rotational permutations of membranelles of normal RH OAs. Many of these membranelles re-orient to a normal orientation near the end of oral development. Membranelles and undulating membranes (UMs) may develop independently of each other, and formation of postciliary microtubules of UMs is separate from that of ribbed wall microtubules. In some cases, the entire OA develops and remains as a 180° rotational permutation of the normal, resembling the inverted OAs of mirror-image doublets and LH cells of Glaucoma scintillans described by Suhama [36, 37]. We present a model (Fig. 37) for these complex developmental outcomes. These developmental patterns resemble those described previously and less completely for "secondary" OAs of cells with mirror-image global patterns, including janus cells. The present study demonstrates that such alterations in oral development are not a direct outcome of genotypic changes.     

Oral assembly in left-handed Tetrahymena thermophila

We have investigated oral development in a non-genetically derived left-handed (LH) form of Tetrahymena thermophila, in which the large-scale asymmetry of arrangement of cortical structures is reversed whereas the local asymmetry of ciliary architecture remains normal. Approximately 1/2 of the oral apparatuses (OAs) of LH cells develop in the form of superficial mirror-images of OAs of RH cells. In most of these OAs, membranelles are assembled from the cells' anterior to posterior. Nonetheless, the posterior ends of these membranelles undergo the basal body displacements that lead to a "sculptured" appearance, so that the membranelles of LH OAs become organized as rotational permutations of membranelles of normal RH OAs. Many of these membranelles re-orient to a normal orientation near the end of oral development. Membranelles and undulating membranes (UMs) may develop independently of each other, and formation of postciliary microtubules of UMs is separate from that of ribbed wall microtubules. In some cases, the entire OA develops and remains as a 180 degrees rotational permutation of the normal, resembling the inverted OAs of mirror-image doublets and LH cells of Glaucoma scintillans described by Suhama. We present a model for these complex developmental outcomes. These developmental patterns resemble those described previously and less completely for "secondary" OAs of cells with mirror-image global patterns, including janus cells. The present study demonstrates that such alterations in oral development are not a direct outcome of genotypic changes.     

Selective mirror-image reversal of ciliary patterns inTetrahymena thermophila homozygous for ajanus mutation

Summary The development of the oral apparatus (OA) and of neighboring ciliary structures ofTetrahymena thermophila was analyzed in cells homozygous for ajanus (jan A) mutation plus a recessiveenhancer of janA (eja). Such cells frequently possess two OAs located on opposite sides of the cell, a primary (1°) OA previously reported to be normal, and a secondary (2°) OA previously reported to express a mirror-reversal of right-left asymmetry. This study confirms the reality of a reversal in the gross orientation of membranelles in most developing 2° OAs. It also shows that there is a reversal of asymmetry in the pattern of resorption of basal bodies of ciliary rows adjacent to the 2° OA, and in the arrangement of basal-body couplets making up the portion of the apical crown of the cell situated close to the 2° OA. However, the locations at which membranelles of the 2° OA become modified during late phases of oral development remain normal, so that membranelles of 2° OAs are superimposable on those of 1° OAs. In addition, the membranelles of 2° OAs frequently undergo a rotation during the final phases of oral development, so that even their spatial orientation becomes normal. This mixture of reversed and normal features can be accounted for by postulating a superimposition of a reversed largescale asymmetry on a normal local asymmetry of ciliary units. This postulate predicts that no single mutation can bring about a complete mirror-image reversal of ciliary patterns.1° OAs appear normal by light microscopy. However, detailed analysis of SEM, preparations of isolated 1° OAs indicate subtle abnormalities of basal body arrangement in some of these OAs.     

bcd: A mutation affecting the width of organelle domains in the cortex of Tetrahymena thermophila

Summary A single-gene recessive mutation, bcd (broadened cortical domains), of Tetrahymena thermophila is characterized by a variable broadening of the spatial domains within which cortical organelles, including both the contractile vacuole pores (CVP) and oral apparatus (OA), are formed. The phenotype is not temperature-sensitive. During the development of the organelles of the mutant prior to cell division, extra CVPs and extra oral primordia (OP) appear near ciliary rows adjacent to the rows at which these structures normally form. In the later stages of development, some, but not all, of these extra structures are resorbed, or in the case of the oral domain, multiple adjacent OPs may be completely or partially integrated into a single enlarged OA. When multiple OAs persist, one or more of these may display a reversed orientation reminiscent of those encountered in janus mutants. However, unlike janus, bcd cells do not express any sign of a mirror-image global organization.Our results can best be accounted for by postulating that the bcd mutation affects some common determinant of the widths of both CVP and OA domains. Studies are in progress which explore the relationship between this width-determining mechanism(s) and the mechanism(s) determining the location of cortical organelles around the cell circumference.     

Mutants of Tetrahymena thermophila with temperature sensitive food vacuole formation : II. Physiological and morphological studies

We studied 13 independently isolated, nitrosoguanidine-induced mutants of Tetrahymena thermophila having heat-sensitive capacity for food vacuole formation. Mutants belonging to the vacA complementation group have defects in the development of a new oral apparatus (OA) and not in phagocytosis per se; OAs formed at 30 °C are functional for at least three cell generations after transfer to 39 °C, while OAs formed at 39 °C are non-functional with regard to phagocytosis. Morphologically, the mutant OAs appear normal under light microscopy. One mutant forms a functional OA and normal contractile vacuole pores (CVP) at 22 °C, but after transfer to 30 °C these organelles disintegrate and vacuole-less cells swell without dividing. Finally, one mutant may be defective in phagocytosis; all daughters formed during the first three cell generations after transfer from 22 °C to 30 °C make food vacuoles, but at a rate which decreases with time. After 24 h at 30 °C food vacuole formation is practically stopped. With one exception, all mutants grow with wild-type generation times at temperatures restrictive for food vacuole formation in growth medium supplemented with high concentrations of iron, copper and folinic acid. The results indicate the feasibility of using a mutant approach to help dissect the developmental mechanisms responsible for the construction of the OA, and to determine the route of entry for compounds required for cell multiplication.     

How the mirror-image pattern specified by a janus mutation of Tetrahymena thermophila comes to expression

The initial changes of cell-surface organization that occurred as the recessive janAl (janus) mutation of Tetrahymena thermophila first became expressed were elucidated in a special mating scheme in which old macronuclei homozygous for janA⁺ were synchronously replaced by new macronuclei homozygous for janAl. During this period of onset of expression, the number, regularity, and asymmetry of the ciliary rows remained unchanged. New normal (primary) oral apparatuses (OAs) continued to be formed posterior to old OAs, as in normal cells. At about four fissions after conjugation, abnormal (secondary) OAs with a partial reversal of asymmetry began to appear nearly opposite to the primary OAs, close to but not at the eventual circumferential position of janAl secondary OAs. The array of contractile vacuole pores (CVPs), normally located adjacent to two ciliary rows centered near 22% of the cell circumference to the righ of the primary oral meridian, underwent a two-step transformation: first, the number of adjacent ciliary rows bearing CVPs increased to 3, 4, and sometimes 5, then “skipped” rows appeared within this broadened CVP-arc to split the single set of CVPs into two separated subsets. The CVP transformations occurred gradually and progressively. They began prior to the expression of secondary OAs but accelerated as secondary OAs appeared. As the CVP are became broader, its midpoint shifted somewhat to the right, away from the primary oral meridian, but ended up close to halfway between the primary and secondary oral meridians. The data provide a better fit to an intercalation model than to an alternative double gradient model, suggesting that the janAl mutation alters the large-scale organization of positional values by preventing the expression of a subset of these values and thus provoking reverse-intercalation of the remainder.     

Development of the Ciliary Pattern of the Oral Apparatus of Tetrahymena thermophila1

ABSTRACT. The sequence of formation and ciliation of basal bodies and the subsequent organization of compound ciliary structures of the oral apparatus of Tetrahymena thermophila was reanalyzed with the aid of scanning electron microscopy of cells in which the epiplasmic layer was exposed, as well as by light microscopy of protargol-impregnated specimens. This combination of methods allowed the delineation of numerous steps in the patterning of the oral ciliature, some of which have received little or no previous attention. Highlights include: the initial formation of “strings” of nonciliated new basal bodies in juxtaposition to relatively few basal bodies of the stomatogenic kinety; generation of basal body pairs, roughly oriented along the anteroposterior axis of the cell, that later align side-by-side to assemble promembranelles; condensation and reorientation of promembranelles simultaneous with addition of a third row of basal bodies anterior to the original two rows; production of a very short fourth row of basal bodies at the anterior right end of each developing membranelle; generation of the outer basal body row of the undulating membrane (UM) after alignment of the inner row, with transient ciliation of the inner row preceding permanent ciliation of the outer row; limited basal body resorption at the ends of membranelles; and sculpturing of the right ends of membranelles by a movement of basal bodies associated with formation of the ribbed wall adjacent to the UM. In the old anterior oral apparatus a repetition of the processes of generation of a new outer UM row and sculpturing of right ends of membranelles takes place in synchrony with the corresponding events in the oral primordium, following prior shedding of the old outer UM row and loss of the sculptured pattern in association with temporary regression of the ribbed wall micro-tubules. Oral development is complex, with different processes involved in the assembly of the membranelles and the UM, and with a sequence of distinct events involved in the generation of each of these structures. Speaking comparatively, membranelle development follows the same pathway in many, perhaps all, ciliates in which these structures or their homologues develop from a common stomatogenic field.     

Oral Apparatus Structure in the Carnivorous Macrostomal Form of Tetrahymena vorax

The structure of the oral apparatus in the carnivorous macrostomal form of Tetrahymena vorax has been investigated using serial thin sections and preparations of isolated oral apparatuses. The cilia of the oral apparatus are organized into an undulating membrane that borders the right and part of the posterior margin of the buccal cavity and three membranelles that project from plateaus on the anterior surface. Each membranelle consists of one short row and two longer rows of hexagonally packed kinetosomes. The organization of the microtubules of the oral ribs is identical to that in the T. vorax microstomal cell type. However, the first oral rib originates near the first kinetosome at the anterior end of the undulating membrane. The fine filamentous reticulum that underlies part of the oral ribs in the macrostomal cell type is not striated, unlike the reticulum in the microstomal form. A band of filaments similar to the fine filamentous reticulum extends around the anterior margin of the large cytostomal opening that occupies most of the posterior part of the oral cavity. The single row of microtubules along the left side of the oral cavity and cytostome also has filaments associated with it. A major difference between the microstomal and macrostomal forms in the structure of the oral apparatus is in the oral connectives. The macrostomal cell type contains only a single cross-connective that joins the three membranelles and the anterior portion of the undulating membrane. The posterior or peripheral connective between the posterior ends of membranelles one and two and the posterior end of the undulating membrane is absent.     

Participation of the Undulating Membrane in the Formation of Oral Replacement Primordia in Tetrahymena pyriformis*

SYNOPSIS. Cells of T. pyriformis GL-C, transferred from a complete axenic medium to a medium lacking amino acids, cease dividing after several hours, and instead begin to undergo oral replacement. This process can be synchronized by a single long 33.8 C treatment. Oral replacement was also observed during stationary phase of normal culture growth in cells of strain GL-C and WH-6 (syngen 1). In strain GL-C the oral replacement primordium is initiated by the appearance of a small number of kinetosomes adjacent to the anterior end of kinety 1, just posterior to the undulating membrane (UM). The UM then loses its cilia and becomes disorganized, and is thus converted into a field of kinetosomes which is broadest near its posterior end. This UM-derived field then becomes joined with the much smaller field which had appeared earlier near the anterior end of kinety 1. As a consequence, the right margin of the UM-derived field becomes continuous with the anterior end of kinety 1, and thus comes to appear as an anterior extension of this kinety. The membranelles and UM of the new oral area differentiate within this composite field. While this is going on, the membranelles of the old oral area are progressively resorbed; these old membranelles always remain spatially separate from the oral replacement primordium. In strain WH-6, the stomatogenic field initially formed adjacent to kinety 1 is substantial, and the role of the UM kinetosomes in stomatogenesis is less obvious than in strain GL-C. The posterior portion of the UM probably contributes to the oral replacement primordium, while the anterior portion is resorbed. In this strain small supernumerary primordia are occasionally seen adjacent to the portion of kinety 2 which is nearest to the posterior region of the UM. It is suggested that the junction between the posterior portion of the UM and the neighboring cortex can serve as an inductive zone for initiation of stomatogenesis, the UM itself having a varying capacity for direct provision of kinetosomes for the stomatogenic field. The flexibility of the stomatogenic site in T. pyriformis is discussed in relation to the apparent restriction of potentialities in peniculine ciliates such as Paramecium.     

How the mirror-image pattern specified by a janus mutation of Tetrahymena thermophila comes to expression

The initial changes of cell-surface organization that occurred as the recessive janA1 (janus) mutation of Tetrahymena thermophila first became expressed were elucidated in a special mating scheme in which old macronuclei homozygous for janA+ were synchronously replaced by new macronuclei homozygous for janA1. During this period of onset of expression, the number, regularity, and asymmetry of the ciliary rows remained unchanged. New normal (primary) oral apparatuses (OAs) continued to be formed posterior to old OAs, as in normal cells. At about four fissions after conjugation, abnormal (secondary) OAs with a partial reversal of asymmetry began to appear nearly opposite to the primary OAs, close to but not at the eventual circumferential position of janA1 secondary OAs. The array of contractile vacuole pores (CVPs), normally located adjacent to two ciliary rows centered near 22% of the cell circumference to the right of the primary oral meridian, underwent a two-step transformation: first, the number of adjacent ciliary rows bearing CVPs increased to 3, 4, and sometimes 5, then "skipped" rows appeared within this broadened CVP-arc to split the single set of CVPs into two separated subsets. The CVP transformations occurred gradually and progressively. They began prior to the expression of secondary OAs but accelerated as secondary OAs appeared. As the CVP arc became broader, its midpoint shifted somewhat to the right, away from the primary oral meridian, but ended up close to halfway between the primary and secondary oral meridians. The data provide a better fit to an intercalation model than to an alternative double-gradient model, suggesting that the janA1 mutation alters the large-scale organization of positional values by preventing the expression of a subset of these values and thus provoking reverse-intercalation of the remainder.     

The filaments supporting ciliary primordia and fission furrow in the hypotrich ciliateParaurostyla weissei, revealed by the monoclonal antibody 12G9: Studies on wild-type and ciliary hypertrophy mutant

Summary The unique monoclonal antibody FXXXIX 12G9 obtained againstTetrahymena cortices was used to label cytoskeletal structures related to basal body proliferation inParaurostyla weissei. The antibody binds to an amorphous material interconnecting basal bodies in compound ciliary structures: dorsal units, cirri and membranelles in interfission cells, and filamentous structures supporting the primordia of ciliary structures and fission line in dividing cells. The antibody visualized meridional filaments preceding proliferation of new basal bodies in the oral primordium and structures accompanying all developing ciliary primordia. It congregated in differentiating new procirri and membranelles, whereas another population of transient meridional structures accompanied the final distribution of new structures. A meridional filament connecting transverse cirri with the oral apparatus, marking the future stomatogenic meridian, persisted in both division products until completion of cell elongation. The fission line was found to originate from an anterior extension of the pre-oral filament toward the parental oral structures. It then encircled the cell's midbody demarcating the boundary between daughter cells; two additional circumferential structures bordering the anterior and posterior ends of differentiating division products participate in formation of the new poles. They disappear after separation of daughter cells and completion of resorption of parental ciliature. In the enhanced multi-left-marginal mutant expressing gross hyperduplication of basal bodies, the location of the 12G9 antigen corresponded to that in wild-type cells. The sequence of formation of meridional filaments in the mutant was found to be altered. The filaments in the left lateral domain preceded the formation of the preoral filament, yet the temporal pattern of basal body assembly was not modified. The fission line, as in wild-type cells, originated in connection with the oral primordium. We conclude that the nucleation of the filamentous structures bearing the 12G9 antigen and the basal body assembly occur by independent mechanisms reading the same cell cycle signals. We suggest that the 12G9-antigen-bearing protein might be similar to septins: involved in signaling the position of the oral primordium and the fission line and functioning in establishing and maintaining the asymmetric cortical domain characteristics.Abbrevations AZM zone of adorai membranelles - bb basal bodies - CC caudal cirri - FC frontal cirri - Fmf frontal meridional filament - FTV the primordia of fronto-ventro-transverse cirri - LD, RD dorsal rows of bristle units - LM, RM left or right marginal cirral row - OA oral apparatus - OP primordium of the adoral membranelles - pLM, pRM primordium of the left or right marginal cirri - pLD, pRD primordia of the left or right dorsal bristle rows - pUM primordium of the undulating membranes - TC transverse cirri - UM undulating membranes - VC ventral cirral rows     

Critical Phases of Oral Primordium Development in Tetrahymena pyriformis GL-C: An Analysis Employing Low Temperature Treatment

SYNOPSIS. The effects of temperatures of 12–18 C on cell division and oral primordium development were investigated in cultures of synchronized Tetrahymena pyriformis GL-C. If exposures to 12 or 15 C were initiated prior to a “transition point,” long delays of cell division were generated. After this transition point, cell division could no longer be substantially delayed by exposure to low temperature. The time of the transition point was somewhat earlier with 15 C than with 12 C treatments. At temperatures higher than 15 C long delays of cell division were not generated regardless of time of treatment. The effects of low temperature on oral morphogenesis were strongly dependent on the stage which was affected. (i) The further development of cells initially in the “anarchic field” stage (stage 1) was immediately blocked at both 12 and 15 C. (ii) Cells initially in the stages of incipient membranelle differentiation (stages 2 and 3) continued to develop at both 12 and 15 C, and formed oral primordia in which all 3 membranelles were clearly differentiated (stage 4). The subsequent progress of these stage 4 primordia depended on the temperature: at 12 C virtually all were resorbed (and cell division was blocked); at 15 C only about 1/3 were resorbed, while the remaining 2/3 completed their development (with the concomitant completion of cell division). (iii) Cells initially in intermediate stages of membranelle differentiation (early stage 4) developed to some extent at 12 C, and then underwent resorpton of oral primordia and blockage of cell division; at 15 C such cells completed their development and division normally. (iv) Cells in which the membranelles and undulating membrane were complete or nearly so (stage 5 and very late stage 4) at the time of the beginning of the cold treatment subsequently finished their development and went thru cell division, even at temperatures as low as 5 C. These results indicate that in addition to a “stabilization point” which occurs shortly before the completion of membranelle development, there is an earlier change in the primordium at the time of the onset of membranelle development, which renders development much less sensitive to direct interference by low temperature.     

Heat-sensitive development of the phagocytotic organelle in a Tetrahymena mutant

A laboratory-induced mutant with heat-sensitive development of the phagocytotic organelle has been isolated in Tetrahymena pyriformis, syngen 1; the mutant cells form food vacuoles at 30 °C, but not after incubation at 37 °C. Mutant cells transferred to 37 °C undergo a maximum of 3–5 doublings, but a sizeable fraction remains viable for several days. Results of temperature shift-up experiments reveal that an oral apparatus (OA) constructed at 30 °C remains functional at 37 °C, while one constructed at 37 °C is non-functional with regard to phagocytosis. Preliminary cytological observations reveal severe structural abnormalities of the OA. Thus the mutant appears to be primarily affected in the morphogenesis of the OA. The phenotypic effect of the mutation is reversible by a temperature shiftdown. Changes in phenotype caused by temperature shifts in either direction can occur even in stationary or starved cultures. Cell division is not required for the resumption of phagocytosis after a temperature shiftdown. Null-formers obtained at the first doubling after a temperature shift-up can divide at least once more, indicating that a functional OA is not required for cell division at any stage of the cell cycle. Mutants defective in phagocytosis may prove useful in gaining deeper understanding of this mechanism and its relationship to other cellular processes.     

Mass spectrometry-based quantification and spatial localization of small organic acid exudates in plant roots under phosphorus deficiency and aluminum toxicity

Low-molecular-weight organic acid (OA) extrusion by plant roots is critical for plant nutrition, tolerance to cations toxicity, and plant–microbe interactions. Therefore, methodologies for the rapid and precise quantification of OAs are necessary to be incorporated in the analysis of roots and their exudates. The spatial location of root exudates is also important to understand the molecular mechanisms directing OA production and release into the rhizosphere. Here, we report the development of two complementary methodologies for OA determination, which were employed to evaluate the effect of inorganic ortho-phosphate (Pi) deficiency and aluminum toxicity on OA excretion by Arabidopsis roots. OA exudation by roots is considered a core response to different types of abiotic stress and for the interaction of roots with soil microbes, and for decades has been a target trait to produce plant varieties with increased capacities of Pi uptake and Al tolerance. Using targeted ultra-performance liquid chromatography coupled with high-resolution tandem mass spectrometry (UPLC-HRMS/MS), we achieved the quantification of six OAs in root exudates at sub-micromolar detection limits with an analysis time of less than 5 min per sample. We also employed targeted (MS/MS) matrix-assisted laser desorption/ionization (MALDI) mass spectrometry imaging (MSI) to detect the spatial location of citric and malic acid with high specificity in roots and exudates. Using these methods, we studied OA exudation in response to Al toxicity and Pi deficiency in Arabidopsis seedlings overexpressing genes involved in OA excretion. Finally, we show the transferability of the MALDI-MSI method by analyzing OA excretion in Marchantia polymorpha gemmalings subjected to Pi deficiency.     

The AMP-dependent kinase pathway is upregulated in BAP1 mutant uveal melanoma

Metastatic uveal melanoma (UM) responds poorly to targeted therapies and immune checkpoint inhibitors. Loss of BRCA1-associated protein 1 (BAP1) via inactivating mutations in the BAP1 gene is associated with UM progression. Thus, molecular alterations caused by BAP1 dysfunction may be novel therapeutic targets for metastatic UM. Here, we found that phosphorylation of AMP-dependent kinase (AMPK) was elevated in BAP1-altered (or mutant) compared to BAP1-unaltered (or wild-type [WT]) UM tumors. As a readout of AMPK pathway activation, phosphorylation of an AMPK downstream effector, acetyl-CoA-carboxylase (ACC), was also elevated. BAP1 re-expression in BAP1-null UM cell lines decreased phospho-AMPK (pAMPK) and phospho-ACC (pACC) levels. AMPK phosphorylation is mediated by calcium/calmodulin dependent protein kinase kinase 2 (CaMKK2) and potentially liver kinase B1 (LKB1) in BAP1 mutant UM cells. Knockdown of AMPKα1/2 reduced the viability of BAP1 mutant UM cells, indicating a survival function of AMPK in BAP1 mutant UM. Our data suggest that the AMPK pathway is an important mechanism mediating the survival of BAP1 mutant UM. Targeting the AMPK pathway may be a novel therapeutic strategy for metastatic UM.     

Mirror-imaged doublets of Tetmemena pustulata: implications for the development of left-right asymmetry

Ciliated protozoa possess cellular axes reflected in the arrangement of their ciliature. Upon transverse fission, daughter cells develop an identical ciliary pattern, ensuring perpetuation of the cellular phenotype. Experimentally manipulated cells can be induced to form atypical phenotypes, capable of intraclonal propagation and regeneration after encystment. One such phenotype in the ciliate Tetmemena pustulata (formerly Stylonychia pustulata) is the mirror-imaged doublet. These cells possess two distinct sets of ciliature, juxtaposed on the surfaces in mirror image symmetry, with a common anterior-posterior axis. We have examined whether individual ciliary components of Tetmemena mirror-image doublets are mirror imaged. Ultrastructural analysis indicates that despite global mirror imaging of the ciliature, detailed organization of the membranelles is reversed in the mirror-image oral apparatus (OA), such that the ciliary effective stroke propels food away from the OA. Assembly of compound ciliary structures of both OAs starts out identically, but as the structures associated with the mirror-image OA continue to form, the new set of membranelles undergoes a 180° planar rotation on the ventral surface relative to the same structures in the typical OA. The overall symmetry of the OA thus appears to be separable from the more localized assembly of individual basal bodies. True mirror imagery of the membranelles would require new enantiomorphic forms of the individual ciliary components, particularly the basal bodies, which is never observed. These observations suggest a mechanistic hypothesis with implications for the development of left-right asymmetry not only in ciliates, but perhaps also in development of left-right asymmetry in general.     

Uveal melanoma driver mutations in GNAQ/11 yield numerous changes in melanocyte biology

Uveal melanoma (UM) is the most common primary intraocular cancer and has a high incidence of metastasis, which lacks any effective treatment. Here, we present zebrafish models of UM, which are driven by melanocyte‐specific expression of activating GNAQ or GNA11 alleles, GNAQ/11^Q209L, the predominant initiating mutations for human UM. When combined with mutant tp53, GNAQ/11^Q209L transgenics develop various melanocytic tumors, including UM, with near complete penetrance. These tumors display nuclear YAP localization and thus phenocopy human UM. We show that GNAQ/11^Q209L expression induces profound melanocyte defects independent of tp53 mutation, which are apparent within 3 days of development. First, increases in melanocyte number, melanin content, and subcellular melanin distribution result in hyperpigmentation. Additionally, altered melanocyte migration, survival properties, and evasion of normal boundary cues lead to aberrant melanocyte localization and stripe patterning. Collectively, these data show that GNAQ/11^Q209L is sufficient to induce numerous protumorigenic changes within melanocytes.