Coordinated flagellar and ciliary beating in the protozoon Tritrichomonas foetus

Costain 1 (ARM19800.1) - The first identified protein of the costa of the pathogenic protozoan Tritrichomonas foetus

Protists members of the Trichomonadidae and Tritrichomonadidae families include agents of trichomoniasis that constitute important parasitic diseases in humans and in animals of veterinary interest. One of the characteristic features of these eukaryotic microorganisms is that they contain a fibrous structure known as the costa as an important cytoskeleton structure, that differs in several aspects from other cytoskeleton structures found in eukaryotic cells. Previous proteomic analysis of an enriched costa fraction revealed the presence of several hypothetical proteins. Here we describe the localization of one of the most prevalent protein found in this previously made proteomic assay to confirm its presence in the costa of Tritrichomonas foetus. A peptide sequence of the hypothetical protein ARM19800.1 was selected for the production of specific polyclonal antibodies and its specificity was confirmed by Western Blotting using an enriched costa fraction. Next, the specific localization of the selected protein was evaluated by immunofluorescence and electron microscopy immunocytochemistry. Our observations clearly showed that the ARM 19800.1 protein is indeed localized in the costa and displays an almost periodic labeling pattern. Since this is the first protein identified in the costa, it was designated as costain 1. A better understanding of a structure as peculiar as the costa is of great biological and evolutionary importance due to the fact that it contains unique proteins, it may represent a possible chemotherapy target and it may correspond to antigens of interest in immunodiagnosis and/or vaccine development.

Trichomonas vaginalis Motility Is Blocked by Drug-Free Thermosensitive Hydrogel

Trichomonas vaginalis motility in biological fluids plays a prominent, but understudied, role in parasite infectivity. In this study, the ability of a thermosensitive hydrogel (pluronic F127) to physically immobilize T. vaginalis was investigated. Blocking parasite motility could prevent its attachment to the mucosa, thus reducing the acquisition of the infection. The trajectory of individual parasites was monitored by multiple particle tracking. Mean square displacement, diffusivity, and velocity were calculated from x, y coordinates during time. Major results are that T. vaginalis exhibited different types of trajectories in a diluted solution composed of lactate buffer similar to "run-and-tumble" motion reported for flagellated bacteria. The fastest T. vaginalis specimen moves with a velocity of 19 μm/s. Observation of T. vaginalis movements showed that the cell body remains rigid during swimming and that the propulsive forces necessary to generate the movement are the result of flagellar beating. Parasite motility was partially slowed down using hydroxyethylcellulose hydrogel, used as a reference for the development of vaginal microbicides, while 100% of T. vaginalis were immobile in F127 hydrogel. Once completed by biological investigations on mice, this report suggests using drug-free formulation composed of F127 as a new strategy to prevent T. vaginalis attachment to the mucosa. The concept will be extended to other flagellated organisms where the motility is driven by cilia and flagella.

Unlocking the secrets of multi-flagellated propulsion: drawing insights from Tritrichomonas foetus

In this work, a high-speed imaging platform and a resistive force theory (RFT) based model were applied to investigate multi-flagellated propulsion, using Tritrichomonas foetus as an example. We discovered that T. foetus has distinct flagellar beating motions for linear swimming and turning, similar to the 'run and tumble' strategies observed in bacteria and Chlamydomonas. Quantitative analysis of the motion of each flagellum was achieved by determining the average flagella beat motion for both linear swimming and turning, and using the velocity of the flagella as inputs into the RFT model. The experimental approach was used to calculate the curvature along the length of the flagella throughout each stroke. It was found that the curvatures of the anterior flagella do not decrease monotonically along their lengths, confirming the ciliary waveform of these flagella. Further, the stiffness of the flagella was experimentally measured using nanoindentation, allowing for calculation of the flexural rigidity of T. foetus's flagella, 1.55×10(-21) N m(2). Finally, using the RFT model, it was discovered that the propulsive force of T. foetus was similar to that of sperm and Chlamydomonas, indicating that multi-flagellated propulsion does not necessarily contribute to greater thrust generation, and may have evolved for greater manoeuvrability or sensing. The results from this study have demonstrated the highly coordinated nature of multi-flagellated propulsion and have provided significant insights into the biology of T. foetus.

Modeling and analysis of propulsion in the multiflagellated micoorganism Giardia lamblia

The goal of this work was to analyze the propulsion of multiflagellated microorganisms, and to draw insight to the underlying physics and biology of the movement. Giardia lamblia was chosen as the model organism due to its unique ability to mechanically attach to various surfaces, its rapid movement, and its fine control over steering and navigation. In this work, a mechanics model was utilized to study the mechanics and propulsive contribution of the ventral and anterior flagella in Giardia. It was discovered that energy is supplied mainly at the proximal portion of these flagella, supporting the hypothesis that a decreasing adenosine triphosphate (ATP) gradient along the length of the flagella would not affect the motion observed. Similarly, the elasticity of the flagella allows the energy input at the proximal portion to be transferred to the distal portion, where the majority of thrust is generated. Specifically, we found that the ventral flagella are the driving force for planar propulsion and turning, while the anterior flagella are used for steering and control.

The caudal complex of Giardia lamblia and its relation to motility

This paper presents a detailed study of the caudal complex of Giardia lamblia and its relation to movements observed in this region. The caudal complex of Giardia, composed of axonemes from the caudal flagella plus associated microtubular sheets, was investigated by light, electron microscopy, and 3D reconstruction tools. By the use of video-microscopy and digital image processing techniques, we were able to visualize in detail the caudal movements. A non-ionic detergent, Triton X-100, was used to isolate the complex that was afterwards analyzed by video-microscopy and transmission electron microscopy (TEM). We showed for the first time, using video-microscopy, that the intracellular portion of the caudal flagella axonemes presented motility, even after the disrupture of the cell membrane, contrasting with the caudal flagella themselves, that do not show active beating pattern. To check if actin filaments play a role in the above described movements, as previously supposed, we incubated the cells with jasplakinolide, a drug that induces the disruption of actin filaments in living cells. The experiments demonstrated that the drug did not affect the caudal motility. The analysis of the caudal complex by transmission electron microscopy (TEM) revealed that, even after the exposure to higher detergent concentrations, the connections between their components remained intact. The information obtained by TEM and 3D reconstruction tools showed that the region between both nuclei marks the intracellular end of the caudal complex, which proceeds toward the caudal portion of the cell following its longitudinal axis, where the axonemes emerge as the caudal flagella. The results obtained from video-microscopy assays of the isolated beating complex together with the 3D reconstruction data indicated that the internal portion of the caudal flagella is the force-generator of the movements in this region.

Trichomonads under Microscopy

Trichomonads are flagellate protists, and among them Trichomonas vaginalis and Tritrichomonas foetus are the most studied because they are parasites of the urogenital tract of humans and cattle, respectively. Microscopy provides new insights into the cell biology and morphology of these parasites, and thus allows better understanding of the main aspects of their physiology. Here, we review the ultrastructure of T. foetus and T. vaginalis, stressing the participation of the axostyle in the process of cell division and showing that the pseudocyst may be a new form in the trichomonad cell cycle and not simply a degenerative form. Other organelles, such as the Golgi and hydrogenosomes, are also reviewed. The virus present in trichomonads is discussed.

Pseudocysts in Trichomonads – New Insights

Tritrichomonas foetus and Trichomonas vaginalis, parasitic protists of the urogenital tract, display a trophozoite and a pseudocyst stage. The ultrastructure of the trophozoite was compared with the pseudocyst form. The latter appears under unfavorable environmental conditions when the flagella are internalized, and a true cell wall is not formed. Although some authors consider this form as a degenerate stage, the cell behaves as a resistant form. Pseudocysts were found in natural culture conditions and also under induction by hydroxyurea or cycles of cooling and warming cultures. They were studied by light and scanning and transmission electron microscopy, using immunofluorescence and videomicroscopy. This report presents evidence that the trichomonad pseudocysts appear under stress conditions and that they are competent to divide. Pseudocysts differ from trophozoites in that: (1) the flagella are located in endocytic vacuoles and remain beating; (2) the axostyle and the costa are not depolymerized but present a curved shape; (3) the axostyle does not exhibit staining with antitubulin antibodies when the mitotic spindle is observed; (4) the mitotic process occurs within pseudocysts but differs from that described for trophozoites; (5) a nuclear canal is formed connecting the two spindle poles; and (6) the process is reversible if the cells are transferred to fresh medium.

Video-microscopy observations of fast dynamic processes in the protozoon Giardia lamblia

Video-microscopy in combination with digital image processing was used to analyze dynamic processes associated to the life cycle of Giardia lamblia trophozoites. These parasites swim and attach to the epithelial cells, producing the disease known as Giardiasis. Giardia is a multiflagellar cell, presenting 4 pairs of flagella. With the use of analogue and digital tools, we observed that in cells attached to glass slides only 2 of the 4 pairs present active beating (wave propagation). The frequency observed was 17-18 Hz to the anterior and 8-11 Hz to the ventral flagella. These data resulted from several hours of recording using both analogue video and high-speed digital camera. The caudal pair did not show active beating patterns and the same holds true for the posterior one. In this latter pair, oscillations were observed, but they were always associated to the transit of the wave produced by the ventral pair. The analysis performed with free moving cells showed that during its forward dislocation, Giardia lamblia presented either a lateral rocking or a complete rotational (tumbling) movement around its longitudinal axis. A dislocation of the caudal region of the cell both in the lateral and dorso-ventral direction was observed. This movement was completely independent from the flagellar beating and it is likely to be produced by a microtubular complex located in the caudal portion of the cell. The adhesion process of Giardia lamblia was also followed by video-microscopy and the data showed that the ventral disk had an active participation in this process.

Laser ablation reveals regulation of ciliary activity by serotonergic neurons in molluscan embryos

Early in embryonic development, the pond snail Helisoma trivolvis exhibits a rotational behavior that is generated by beating of cilia in the dorsolateral and pedal bands. Although previous anatomical and pharmacological studies provided indirect evidence that a pair of serotonergic neurons, Embryonic Neurons C1 (ENC1s), is involved in regulating embryonic rotation, direct evidence linking ENC1 to ciliary function is still lacking. In the present study, we used laser microbeams to perturb ENC1 in vivo while monitoring ciliary activity in identified ciliary bands. A laser treatment protocol to specifically ablate ENC1 without damaging the surrounding cells was established. Unilateral laser treatment of ENC1 caused transient increases in the activity of the pedal and ipsidorsolateral cilia, lasting 30-50 min. In contrast, activity of cilia that were not anatomically associated with ENC1 was unaffected by laser treatment. Mianserin, an effective serotonin antagonist in Helisoma ciliated cells, decreased the overall CBF of pedal and dorsolateral cilia by reducing the occurrence of spontaneous CBF surges in these cilia. Finally, the cilioexcitatory action of ENC1 laser treatment was mimicked by serotonin and reduced in the presence of mianserin. These results suggest that laser treatment provokes a release of serotonin from ENC1, resulting in a prolonged elevation of activity in the target ciliary cells. We conclude that, in addition to their previously established role in regulating neurodevelopment, ENC1s also function as serotonergic motor neurons to regulate ciliary activity, and therefore the rotational behavior of early embryos.

Free movement of Tritrichomonas foetus in a liquid medium: a video-microscopy study

The present paper describes in detail the complex movement of the protozoon Tritrichomonas foetus. By the use of analogue and digital video techniques, we were able to analyze frame by frame the beatings of the anterior flagella and discuss their role in the movement of the cell. We also measured the productive displacement of the cell during one flagellar beating cycle. The obtained data were digitally improved and compared to analogue quantifications. It is shown that during 1 s of recorded movement, T. foetus performs 4 complete anterior flagella beating cycles (with active-like and recovery-like beatings). In each cycle the cell swims +/- 6.5 microns forwards, after the recovery of +/- 1.5 microns of receded movement. These observations led us to conclude that the estimated average speed of T. foetus is 25 microns/s, and that all flagella participate in the cell movement. The recurrent flagellum continuously contribute to the forward movement of the protozoon. The cell also performs rotational movements. The obtained results led us to suggest a model for the movement of T.foetus.