Visualization of the funis of Giardia lamblia by high-resolution field emission scanning electron microscopy--new insights

Giardia lamblia is a multiflagellar parasite and one of the earliest diverging eukaryotic cells. It possesses a cytoskeleton made of several microtubular structures-an adhesive disc, four pairs of flagella, median body, and funis. This protozoan displays different types of movements, including a lateral and dorso-ventral dislocation of its posterior region, which has not been completely elucidated. In the present study, high-resolution field emission scanning electron microscopy was used to analyze the funis structure of G. lamblia trophozoites. It was shown that the funis is made of short arrays of microtubules emanating from the axonemes of the caudal flagella, which are anchored to dense rods that run parallel to the posterior-lateral flagella. After emergence of the posterior-lateral flagella, funis microtubules are anchored to the epiplasm, a fibrous layer that underlies the portion of membrane that presents tail contractility. Based on these observations a model for the tail flexion of G. lamblia is proposed.     

Giardia lamblia: evaluation of the in vitro effects of nocodazole and colchicine on trophozoites

Giardia lamblia is the most commonly detected parasite in the intestinal tract of humans and other mammals causing giardiasis. Giardia presents several cytoskeletal structures with microtubules as major components such as the ventral adhesive disk, eight flagella axonemes, the median body and funis. Many drugs have already been tested as antigiardial agents, such as albendazole and mebendazole, which act by specifically inhibiting tubulin polymerization and hence microtubule assembly. In the present work, we used the microtubule inhibitors nocodazole and colchicine in order to investigate their direct and indirect effects on Giardia ultrastructure and attachment to the glass surface, respectively. Axenically grown G. lamblia trophozoites were treated with nocodazole or colchicine for different time intervals and analyzed by light and electron microscopy. It was observed that trophozoites became completely misshapen, detached from the glass surface and failed to complete cell division. The main alterations observed included disc fragmentation, presence of large vacuoles, and appearance of electrondense deposits made of tubulin. The cytokinesis was blocked, but not the karyokinesis, and membrane blebs were observed. These findings show that Giardia behavior and cytoskeleton are clearly affected by the commonly used microtubule targetting agents colchicine and nozodazole.     

水蕨精子发生过程中中心体蛋白和微管蛋白的免疫荧光定位

采用透射电镜技术和免疫荧光标记技术对水蕨精子发生的超微结构以及中心体蛋白和微管蛋白在精子发生过程中的动态表达进行了观察。研究发现：（1）生毛体分化早期周围有放射状微管分布,这与线粒体向生毛体的聚集有关。（2）免疫荧光观察表明,中心体蛋白仅定位于生毛体、基体和鞭毛带上,自生毛体至基体阶段呈现明亮的荧光标记,在核塑形、鞭毛形成至精子成熟阶段,中心体蛋白荧光标记随着鞭毛的发生而逐渐减弱,至游动精子阶段中心体蛋白荧光标记信号几乎消失。（3）微管蛋白早期荧光标记与中心体蛋白标记形相同,在生毛体、鞭毛带、基体等运动细胞器上呈现明亮荧光标记,但微管蛋白随着鞭毛的发生其荧光标记越来越强。从二者的时空表达特征可以推断,中心体蛋白主要是运动细胞器的组织者,而非这些运动细胞器的结构成分,其功能是参与或负责中心粒、基体和鞭毛的发生。     

THE FINE STRUCTURE OF GIARDIA MURIS

Giardia is a noninvasive intestinal zooflagellate. This electron microscope study demonstrates the fine structure of the trophozoite of Giardia muris in the lumen of the duodenum of the mouse as it appears after combined glutaraldehyde and acrolein fixation and osmium tetroxide postfixation. Giardia muris is of teardrop shape, rounded anteriorly, with a convex dorsal surface and a concave ventral one. The anterior two-thirds of the ventral surface is modified to form an adhesive disc. The adhesive disc is divided into 2 lobes whose medial surfaces form the median groove. The marginal grooves are the spaces between the lateral crests of the adhesive disc and a protruding portion of the peripheral cytoplasm. The organism has 2 nuclei, 1 dorsal to each lobe of the adhesive disc. Between the anterior poles of the nuclei, basal bodies give rise to 8 paired flagella. The median body, unique to Giardia, is situated between the posterior poles of the nuclei. The cytoplasm contains 300-A granules that resemble particulate glycogen, 150- to 200-A granules that resemble ribosomes, and fusiform clefts. The dorsal portion of the cell periphery is occupied by a linear array of flattened vacuoles, some of which contain clusters of dense particles. The ventrolateral cytoplasm is composed of regularly packed coarse and fine filaments which extend as a striated flange around the adhesive disc. The adhesive disc is composed of a layer of microtubules which are joined to the cytoplasm by regularly spaced fibrous ribbons. The plasma membrane covers the ventral and lateral surfaces of the disc. The median body consists of an oval aggregate of curved microtubules. Microtubules extend ventrally from the median body to lie alongside the caudal flagella. The intracytoplasmic portions of the caudal, lateral, and anterior flagella course considerable distances, accompanied by hollow filaments adjacent to their outer doublets. The intracytoplasmic portions of the anterior flagella are accompanied also by finely granular rodlike bodies. No structures identifiable as mitochondria, smooth endoplasmic reticulum, the Golgi complex, lysosomes, or axostyles are recognized.     

Tubulin diversity in trophozoites of<Emphasis Type="Italic"> Giardia lamblia</Emphasis>

Giardia lamblia is a diplomonad that parasitizes the small intestine of vertebrates. The trophozoite is multiflagellar and its cytoskeleton presents a complex organization of microtubular structures. One of these, the adhesive disk, consists of a microtubular spiral. The median body, whose function is not yet determined, is also composed by microtubules. The cell has eight flagella and two microtubule sheets, known as the funis. In this study we used several antibodies and immunofluorescence microscopy to help in the characterization of these structures. We observed that Giardia tubulin reacts with antibodies raised against very distinct immunogens. The antibodies used were against: (1) alpha-tubulin from chicken embryo brain, Trypanosoma brucei, sea urchin sperm, Paramecium, acetylated alpha-tubulin from Paramecium, and tyrosinated alpha-tubulin, (2) beta-tubulin from chicken embryo brain and Physarum polycephalum, and (3) an antibody with specificity to beta-tubulin having as immunogen the FtsZ bacterial protein. Each cytoskeletal structure of Giardia presented a distinct pattern of labeling by the several antibodies used. These data indicate that even being considered one of the most ancient of organisms, Giardia shares similarities (at least in relation to tubulin) with other organisms. They also open some questions about the organization and composition of its microtubular structures.     

Immunoelectron Microscopy of Giardia lamblia Cytoskeleton Using Antibody to Acetylated α-Tubulin

Giardia lamblia trophozoites contain acetylated α-tubulin but lack detectable levels of tyrosinolated α-tubulin, as demonstrated in immunoblots with monoclonal antibodies specific for these tubulin forms. By immunofluorescence microscopy, acetylated α-tubulin is localized in axonemes, median bodies and in the adhesive disk. Post-embeddment immunogold labeling of thin sections of cells was used to evaluate acetylation at the level of individual microtubules by electron microscopy. Cells were fixed with glutaraldehyde and embedded in the acrylic resin LR Gold. Results indicate all microtubules in adhesive disk, axonemes, basal bodies, funis and the median bodies contain acetylated α-tubulin. Unlike immunofluorescence labeling, all microtubules of the adhesive disk and the funis could be gold labeled. No nonspecific labeling of the cytoplasm or of structures other than microtubules was observed. Acetylated microtubules in G. lamblia do not appear to be a subset of microtubules and acetylation appears uniform along the entire length of individual microtubules. Acetylation and the tyrosinolation state of microtubules in Giardia are discussed in the context of microtubule stability and crosslinked features of the cytoskeleton.     

The median body of Giardia lamblia: an ultrastructural study

Giardia lamblia is an intestinal parasite of several mammals. The most striking feature of Giardia is the presence of a complex and unique cytoskeleton, and among its components the median body (MB) is the least defined microtubular structure. In the present study, we used a technique that allowed the removal of the plasma membrane and observation of cytoskeletal structures by both routine scanning electron microscopy (SEM) and field emission high resolution SEM. This technique permitted new observations such as details and insights of the median bodies, not previously described or controversial in the literature. Light microscopy after Panotic staining, immunofluorescence microscopy using several antibodies, and thin sections were also used to better characterized the Giardia MB. The new observations concerning the median bodies were : (1) they are not one or two structures, but varied in number, shape and position ; (2) they were found in mitotic and interphasic trophozoites, in disagreement with previous works ; (3) they were present in about 80 % of the cells, and not in 50 % of the cells, as previously described ; (4) they could be connected either to the plasma membrane, to the adhesive disc, and caudal flagella, and thus they are not completely free in the cells, as published before ; (5) they can protrude the cell surface ; (6) their microtubules react with several anti-tubulin and -beta giardin antibodies. These observations add new data on the scarce literature and to this largely understudied cell structure.     

Expression of tubulin polyglycylation in Giardia lamblia

By means of immunofluorescence, immunoelectron microscopy and immunoblotting, we show that polyglycylation, a posttranslational modification of tubulin widely spread among eukaryotes, is present in the diplomonad, Giardia lamblia, a putative ancestral cell possessing a highly developed microtubular cytoskeleton. This modification was recently discovered in the ciliated protist, Paramecium, and was not found in the Euglenozoa, a lineage considered as ancient. We used two monoclonal antibodies (mAbs), TAP 952 and AXO 49, specifically recognizing mono- and polyglycylated tubulin isoforms, to detect this modification in Giardia extracts and to localize it in the different classes of microtubules within the cell. The alpha- and beta-tubulin subunits were recognized by the two mAbs, indicating that both tubulin subunits are glycylated, in agreement with lately reported mass spectrometry results. Noticeably, Giardia tubulin was much more reactive with AXO 49 than with TAP 952. In situ, AXO 49 intensely labeled the microtubules present in the four pairs of flagella and the median body, and lightly decorated the microtubules from the adhesive disc. In contrast, TAP 952 intensely labeled only the microtubules of the median body. The results indicate a differential expression of glycylated isoforms within various microtubular structures of Giardia lamblia. They also suggest that the complete set of enzymes required for polyglycylation is expressed in very divergent eukaryotes.     

Differential localization and functional specialization of centrin analogs in the parasitic ciliate <Emphasis Type="Italic">Trichodina pediculus</Emphasis>

Trichodinids are ciliated protozoans that reversibly attach to the tegument of marine and freshwater host-organisms via an adhesive disc. In this study, we have used permeabilized cell models of Trichodina pediculus to examine the distribution of centrins, a Ca²⁺-binding protein associated with centrioles and/or contractile filamentous structures in a large number of protists. The previous finding that filamentous material of the adhesive disc comprised a 23-kDa centrin analog suggested that this protein might be a disc-specific isoform. This possibility was explored through immunolabeling methods using two distinct antibodies, anti-ecto-endoplasmic boundary (EEB) and anti-Hscen2 previously shown to react respectively with centrin-based filament networks and with centrioles. Immunofluorescence microscopy showed that anti-EEB reacts with filamentous material of the disc but not with basal bodies. Conversely, anti-Hscen2 cross-reacted with basal bodies but failed to label any type of structure occurring in the disc area. More detailed data on localization of this protein was obtained by immunoelectron microscopy showing gold particles deposits in the lumen of basal bodies. The different patterns revealed by this immunochemical approach suggest that the two protein antigens concerned by this study are distinct centrin isoforms that presumably perform organelle-specific function in the ciliate T. pediculus.     

Centrin association with the flagellar apparatus in spores ofPhytophthora cinnamomi

Summary Antibodies raised against the calcium-binding protein centrin, were used to identify and localise centrin containing structures in the flagellar apparatus of zoospores and cysts of the oomycetePhytophthora cinnamomi. Immunoblotting of extracts from zoospores indicates that theP. cinnamomi centrin homologue is a 20 kDa protein. Immunofluorescence microscopy with anti-centrin antibodies reveals labelling in the flagella, the basal body connector and co-localisation along the microtubular R1 root (formerly called AR3) that runs from the right side of the basal body of the anterior flagellum into the anterior of the zoospore close to the ventral surface. The centrin (R1^cen) and tubulin components of the R1 root split into four loops on the right hand side of the ventral groove and rejoin along the left hand side of the groove. The R1 root continues down the left hand side of the zoospore past the basal bodies and parallel to the R4 root. We propose that at least inP. cinnamomi there is no R2 root. Immunogold labelling confirms that centrin is a component of the basal body connector complex. When the zoospores become spherical during encystment, the R1^cen pivots by approximately 90 ° with respect to the nucleus.     

Participation of the adhesive disc during karyokinesis in Giardia lamblia

Evidence is presented for a potential involvement of the adhesive disc on the nucleus division in Giardia lamblia. The trophozoite mitotic nucleus was studied by transmission electron microscopy, freeze-fracture, freeze-substitution and also by immunofluorescence microscopy using anti-tubulin antibodies specific to spindle microtubules and Panotic staining. Prior to cell division the nucleus elongated and a displaced disc fragment, established contact with the nucleus. A progressive nucleus indentation was coincident with the concomitant presence of a disc fragment at the constricted region. One nucleus each time progressively divided until the karyokinesis was finished and two daughter-nuclei were observed. After the first karyokinesis a second karyokinesis takes place following the same procedure. When Giardia gets the four nuclei, cytokinesis occurs. Duplicated basal bodies were seen in between the first and the second karyokinesis. Immunofluorescence microscopy, using a panel of anti-tubulin antibodies, and electron microscopy of cells processed using microtubule stabilizer buffers, or cells fast-frozen and freeze-substituted, did not reveal the presence of a typical spindle. We propose that Giardia lamblia presents an uncommon mitotic behavior where the adhesive disc, a microtubular structure, seems to participate in the karyokinesis process.     

Localization of gamma-tubulin in interphase and mitotic cells of a unicellular eukaryote, Giardia intestinalis

Giardia intestinalis, a bi-nucleated amitochondrial flagellate, possesses a complex cytoskeleton based on several microtubular systems (flagella, adhesive disk, median body, funis, mitotic spindles). MTOCs of the individual systems have not been fully defined. By using monoclonal antibodies against a conserved synthetic peptide from the C-terminus of human gamma-tubulin we investigated occurrence and distribution of gamma-tubulin in interphase and mitotic Giardia cells. On the immunoblots of Giardia cytoskeletal extracts the antibodies bound to a single polypeptide of approximately 50 kDa. Immunostaining of the interphase cell demonstrated gamma-tubulin as four bright spots at the basis of four out of eight flagella. Gamma-tubulin label was associated with perikinetosomal areas of the ventral and posterolateral pairs of flagella which are formed de novo during cell division. Basal body regions of the anterolateral and caudal pairs of flagella which persist during the division and are integrated into the flagellar systems of the daughter cells did not show gamma-tubulin staining. At early mitosis, gamma-tubulin spots disappeared reappearing again at late mitosis in accord with reorientation of parent flagella and reorganization of flagellar apparatus during cell division. The antibody-detectable gamma-tubulin epitope was absent at the poles of both mitotic spindles. Albendazole-treated Giardia, in which spindle assembly was completely inhibited, showed the same gamma-tubulin staining pattern thus confirming that the fluorescent label is exclusively located in the basal body regions. Our results point to a role of gamma-tubulin in nucleation of microtubules of newly formed flagella and indicate unusual mitotic spindle assembly. Moreover, the demonstration of gamma-tubulin in Giardia shows ubiquity of this protein through the evolutionary history of eukaryotes.     

Centrin scaffold in Chlamydomonas reinhardtii revealed by immunoelectron microscopy

In the flagellate green alga Chlamydomonas reinhardtii the Ca(2+)-binding EF-hand protein centrin is encoded by a single-copy gene. Previous studies have localized the protein to four distinct structures in the flagellar apparatus: the nucleus-basal body connector, the distal connecting fiber, the flagellar transitional region, and the axoneme. To explain the disjunctive distribution of centrin, the interaction of centrin with as yet unknown specific centrin-binding proteins has been implied. Here, we demonstrate using serial section postembedding immunoelectron microscopy of isolated cytoskeletons that centrin is located in additional structures (transitional fibers and basal body lumen) and that the centrin-containing structures of the basal apparatus are likely part of a continuous filamentous scaffold that extends from the nucleus to the flagellar bases. In addition, we show that centrin is located in the distal lumen of the basal body in a rotationally asymmetric structure, the V-shaped filament system. This novel centrin-containing structure has also been detected near the distal end of the probasal bodies. Taken together, these results suggest a role for a rotationally asymmetric centrin "seed" in the growth and development of the centrin scaffold following replication of the basal apparatus.     

In vitro excystation of Giardia from humans: a scanning electron microscopy study

The in vitro excystation of Giardia lamblia on cysts isolated from human feces was studied. After purification by sucrose gradient, cysts were incubated in a pepsin-acid solution, then placed in a modified HSP3 medium where excystation occurred within a few minutes. The excystation procedure was studied by continuous observations by light microscopy and sequential observations by scanning electron microscopy (SEM). The in vitro excystation was stopped at timed intervals during incubation by addition of a large amount of 1% glutaraldehyde. The excystation process began by the cyst wall opening at one pole. Flagella protruded rapidly, the parasite emerged progressively from the cyst envelope, posterior end first, the empty cyst collapsed and shrank. Although flagella emerging from the organism were distinguishable, the cell body had not yet shown all the morphological features of the G. lamblia trophozoite. A radical rearrangement of the organism occurred gradually: initially oval in shape, the parasite became round, then elongated, flattened, and underwent cytokinesis. The daughter trophozoites acquired their typical morphological features: the shape, the adhesive disc with the C-shaped structure distinctly visible on the ventral surface, and the definite placement of the flagella. These observations obtained on G. lamblia by SEM were comparable to those obtained with G. muris.     

Giardia lamblia aurora kinase: a regulator of mitosis in a binucleate parasite

Giardia lamblia is a major cause of diarrhoeal disease worldwide. Since it has no known toxin, the ability of trophozoites to colonise the human small intestine is required for its pathogenesis. Mitosis in this protozoan parasite is a unique challenge because its two equivalent nuclei and complex cytoskeleton must be duplicated and segregated accurately. Giardial mitosis is a complex and rapid event that is poorly understood at the cellular and molecular levels. Higher eukaryotes have one to three members of the highly conserved Ser/Thr aurora kinase (AK) family that regulate key aspects of mitosis and cytokinesis. Giardia has a single AK orthologue (gAK) with 61% similarity to human AK A. In addition to the conserved active site residues, activation loop and destruction-box motifs characteristic of AKs, gAK contains a unique insert near the active site region. We epitope-tagged gAK at its C-terminus and expressed it under its own promoter. During interphase, gAK localises exclusively to the nuclei, but is not phosphorylated as shown by lack of staining with an antibody specific to phosphorylated AK A (pAK). In contrast, during mitosis pAK localises to the basal bodies/centrosomes and co-localises with tubulin to the spindle. During specific stages of mitosis, giardial pAK also localised dynamically to cytoskeletal structures unique to Giardia: the paraflagellar dense rods of the anterior flagella and the median body, whose functions are unknown, as well as to the parent attachment disc. Two AK inhibitors significantly decreased giardial growth and increased the numbers of cells arrested in cytokinesis. These inhibitors appeared to increase microtubule nucleation and cell-ploidy. Our data show that gAK is phosphorylated in mitosis and suggest that it plays an important role in the Giardia cell cycle. The pleiotropic localisation of AK suggests that it may co-ordinate the reorganisation and segregation of tubulin-containing structures in mitosis. We believe this is the first report of a signalling protein regulating cell division in Giardia.     

Mining the Giardia genome and proteome for conserved and unique basal body proteins

Giardia lamblia is a flagellated protozoan parasite and a major cause of diarrhoea in humans. Its microtubular cytoskeleton mediates trophozoite motility, attachment and cytokinesis, and is characterised by an attachment disk and eight flagella that are each nucleated in a basal body. To date, only 10 giardial basal body proteins have been identified, including universal signalling proteins that are important for regulating mitosis or differentiation. In this study, we have exploited bioinformatics and proteomic approaches to identify new Giardia basal body proteins and confocal microscopy to confirm their localisation in interphase trophozoites. This approach identified 75 homologs of conserved basal body proteins in the genome including 65 not previously known to be associated with Giardia basal bodies. Thirteen proteins were confirmed to co-localise with centrin to the Giardia basal bodies. We also demonstrate that most basal body proteins localise to additional cytoskeletal structures in interphase trophozoites. This might help to explain the roles of the four pairs of flagella and Giardia-specific organelles in motility and differentiation. A deeper understanding of the composition of the Giardia basal bodies will contribute insights into the complex signalling pathways that regulate its unique cytoskeleton and the biological divergence of these conserved organelles.     

MITOSIS IN DUNALIELLA BIOCULATA (CHLOROPHYTA): CENTRIN BUT NOT BASAL BODIES ARE AT THE SPINDLE POLES

Centrin, a 20 kDa calmodulin-like protein, is located in various basal body-associated fibers in protists. We used indirect immunofluorescence of isolated cytoskeletons or methanol-fixed cells to analyze the distribution of centrin during mitosis of the biflagellate green alga Dunaliella bioculata (Butcher). The distance between the nucleus and the basal apparatus decreased in late interphase, presumably caused by the contraction of the two centrin-containing nucleus–basal body connectors (NBBCs). During prophase, centrin accumulated on the new basal bodies as shown by postembedding immunogold labeling of serial thin sections. The new basal bodies were in close contact with plaque-like structures on the nuclear envelope. In mitotic cells, basal body pairs were separated and positioned at a considerable distance from the poles of the mitotic spindle. At this stage, we observed four separated centrin dots, two associated with the pairs of basal bodies and two located at the spindle poles as shown by double immunofluorescence, including anti-tubulin staining. The latter signals corresponded to an accumulation of centrin between the plasma membrane and the nuclei, indicating that centrin could be involved in mitotic movements of the nuclei. In telophase, centrin was observed along the nuclear surface and one new NBBC developed in each cell half. Our results demonstrate that centrin is present at the acentriolar spindle poles of Dunaliella independently from its localization in the basal apparatus.     

Ultrastructure of Lamblia duodenalis. I. Body Surface, Sucking Disc and Median Bodies

SYNOPSIS. The body surface, sucking disc and median bodies of Lamblia duodenalis have been studied on ultrathin sections in the electron microscope. The body is covered by a pellicle, displaying a striated structure in the area of the sucking disc. The striation is due to 150 Å thick dense ridges which are spaced in distances of 200–400 Å. The ridges are formed by the internal pellicular membrane and have a triangular cross section with a very dense apex. They are arranged concentrically and run parallel to the surface of the sucking disc lobes. Anteriad to the nuclei in the median line a space is free of ridges. The margin of the sucker is elevated above the body forming a sharp crest of the ridged pellicle.
This crest is the inner wall of a marginal groove delimiting the sucker from the body. The outer margin is circumscribed by a fold in the body tapering to the posterior end. A ventral groove containing the two ventral flagella lies in the median line. The movement of the ventral flagella pushes the medium through the marginal and ventral grooves thus producing vacuum in the sucker area.
The median bodies are composed of numerous 150 Å thick tubular fibrils. They differ in their ultrastructure from the parabasal apparatus in other flagellates and have nothing in common with the kinetoplasts. Their functional significance awaits elucidation.     

Localization of centrins in the hypotrich ciliate Paraurostyla weissei

Centrins are ubiquitous cytoskeletal proteins that are generally associated with the centrosome and form large cytoskeletal networks in protists. To obtain more data on the respective role of different centrin proteins, we studied their distribution and behavior in one ciliate species, Paraurostyla weissei, using specific antibodies. In this species, only two major proteins of 21 and 24 kDa corresponding to centrins, were identified by 1D and 2D electrophoresis. Immunofluorescence analysis showed that these two proteins displayed non-overlapping localization in the interphase cell and during morphogenesis. Both centrin proteins localize on the fibrous network linking the oral basal bodies in the interphase cell and in the form of marginal dots, which correspond to the proximal ends of the striated rootlets; the 21 kDa centrin was also detected within the basal bodies, whereas the 24 kDa centrin allowed identifying new structures, the frontal dashes. During morphogenesis, the 21 kDa centrin locates at the basal bodies, while the 24 kDa centrin is detected along the striated rootlets and in close association with the basal bodies pairs. These data are discussed in terms of the potential roles of the two centrins in different cellular functions.