Host cell invasion by trypanosomes requires lysosomes and microtubule/kinesin-mediated transport

Invasion of mammalian cells by the protozoan parasite Trypanosoma cruzi occurs by an actin-independent mechanism distinct from phagocytosis. Clusters of host lysosomes are observed at the site of parasite attachment, and lysosomal markers are detected in the vacuolar membrane at early stages of the entry process. These observations led to the hypothesis that the trypanosomes recruit host lysosomes to their attachment site, and that lysosomal fusion serves as a source of membrane to form the parasitophorous vacuole. Here we directly demonstrate directional migration of lysosomes to the parasite entry site, using time-lapse video-enhanced microscopy of L6E9 myoblasts exposed to T. cruzi trypomastigotes. BSA-gold-loaded lysosomes moved towards the cell periphery, in the direction of the parasite attachment site, but only when their original position was less than 11-12 microns from the invasion site. Lysosomes more distant from the invasion area exhibited only the short multi-directional saltatory movements previously described for lysosomes, regardless of their proximity to the cell margins. Specific depletion of peripheral lysosomes was obtained by microinjection of NRK cells with antibodies against the cytoplasmic domain of lgp 120, a treatment that aggregated lysosomes in the perinuclear area and inhibited T. cruzi entry. The microtubule- binding drugs nocodazole, colchicine, vinblastine, and taxol also inhibited invasion, in both NRK and L6E9 cells. Furthermore, microinjection of antibodies to the heavy chain of kinesin blocked the acidification-induced, microtubule-dependent redistribution of lysosomes to the host cell periphery, and reduced trypomastigote entry. Our results therefore demonstrate that during T. cruzi invasion of host cells lysosomes are mobilized from the immediately surrounding area, and that availability of lysosomes at the cell periphery and microtubule/kinesin-mediated transport are requirements for parasite entry.     

Secretory lysosomes

Regulated secretion of stored secretory products is important in many cell types. In contrast to professional secretory cells, which store their secretory products in specialized secretory granules, some secretory cells store their secretory proteins in a dual-function organelle, called a secretory lysosome. Functionally, secretory lysosomes are unusual in that they serve both as a degradative and as a secretory compartment. Recent work shows that cells with secretory lysosomes use new sorting and secretory pathways. The importance of these organelles is highlighted by several genetic diseases, in which immune function and pigmentation--two processes that normally involve secretory lysosomes--are impaired.     

Distinct protein sorting and localization to premelanosomes, melanosomes, and lysosomes in pigmented melanocytic cells

Melanosomes and premelanosomes are lysosome-related organelles with a unique structure and cohort of resident proteins. We have positioned these organelles relative to endosomes and lysosomes in pigmented melanoma cells and melanocytes. Melanosome resident proteins Pmel17 and TRP1 localized to separate vesicular structures that were distinct from those enriched in lysosomal proteins. In immunogold-labeled ultrathin cryosections, Pmel17 was most enriched along the intralumenal striations of premelanosomes. Increased pigmentation was accompanied by a decrease in Pmel17 and by an increase in TRP1 in the limiting membrane. Both proteins were largely excluded from lysosomal compartments enriched in LAMP1 and cathepsin D. By kinetic analysis of fluid phase uptake and immunogold labeling, premelanosomal proteins segregated from endocytic markers within an unusual endosomal compartment. This compartment contained Pmel17, was accessed by BSA-gold after 15 min, was acidic, and displayed a cytoplasmic planar coat that contained clathrin. Our results indicate that premelanosomes and melanosomes represent a distinct lineage of organelles, separable from conventional endosomes and lysosomes within pigmented cells. Furthermore, they implicate an unusual clathrin-coated endosomal compartment as a site from which proteins destined for premelanosomes and lysosomes are sorted.     

Intracellular transport of a variant surface glycoprotein in Trypanosoma brucei

Trypanosome variant surface glycoproteins (VSGs) have a novel glycan-phosphatidylinositol membrane anchor, which is cleavable by a phosphatidylinositol-specific phospholipase C. A similar structure serves to anchor some membrane proteins in mammalian cells. Using kinetic and ultrastructural approaches, we have addressed the question of whether this structure directs the protein to the cell surface by a different pathway from the classical one described in other cell types for plasma membrane and secreted glycoproteins. By immunogold labeling on thin cryosections we were able to show that, intracellularly, VSG is associated with the rough endoplasmic reticulum, all Golgi cisternae, and tubulovesicular elements and flattened cisternae, which form a network in the area adjacent to the trans side of the Golgi apparatus. Our data suggest that, although the glycan-phosphatidylinositol anchor is added in the endoplasmic reticulum, VSG is nevertheless subsequently transported along the classical intracellular route for glycoproteins, and is delivered to the flagellar pocket, where it is integrated into the surface coat. Treatment of trypanosomes with 1 microM monensin had no effect on VSG transport, although dilation of the trans-Golgi stacks and lysosomes occurred immediately. Incubation of trypanosomes at 20 degrees C, a treatment that arrests intracellular transport from the trans-Golgi region to the cell surface in mammalian cells, caused the accumulation of VSG molecules in structures of the trans-Golgi network, and retarded the incorporation of newly synthesized VSG into the surface coat.     

Endocytosed transferrin in African trypanosomes is delivered to lysosomes and may not be recycled.

It has been shown in mammalian systems that the passage of transferrin-colloidal gold (Tf-Au) through the endocytic system is influenced by the size of the gold colloid (Neutra, M. R. et al., J. Histochem. Cytochem. 33, 1134-1144 (1985); Woods, J. W. et al., Eur. J. Cell Biol. 50, 132-143 (1989)). However, in both Trypanosoma brucei brucei and Trypanosoma congolense, widely varying sizes of Tf-Au (Tf-Au5 and Tf-Au15) have been shown to proceed to lysosomes (Webster, P., Eur. J. Cell Biol. 49, 295-302 (1989); Webster, P., D. Grab, J. Cell Biol. 106, 279-288 (1988)). Using an affinity-purified anti-bovine transferrin IgG we have demonstrated that, in both T. brucei and T. congolense, native transferrin, like Tf-Au, is found in the flagellar pocket, coated vesicles, tubular structures, and lysosome-like organelles where it appears to be concentrated. The presence of Tf in the lysosomes was confirmed in colocalization experiments using T. congolense, where native bovine transferrin colocalized with a trypanosome lysosomal marker, a cysteine protease. The data suggest that, unlike the situation in mammalian cells where most transferrin is recycled to the cell surface, in African trypanosomes transferrin is routed into lysosomes and may not, therefore, be recycled.     

Studies on the recycling of the transferrin receptor in Trypanosoma brucei using an inducible gene expression system.

Uptake of host transferrin in bloodstream forms of Trypanosoma brucei is mediated by a heterodimeric, glycosylphosphatidylinositol-anchored receptor. After endocytosis, transferrin is delivered to lysosomes where it is proteolytically degraded. Whether the heterodimeric transferrin receptor is returned to mediate several cycles in ligand uptake is undefined. By using an inducible gene expression system we provide evidence for recycling of the transferrin receptor in bloodstream forms of T. brucei. The metabolic half-life of the transferrin receptor in bloodstream-form trypanosomes is determined to be 7 h which is comparable to the half-lives of recycling receptors in mammalian cells. The cycling time of the trypanosomal transferrin receptor is calculated to be 11 min. By means of the half-life and the cycling time, we calculated that each receptor is recycled 60 times before being degraded on average.     

Coordination of cell cycle and cytokinesis in Trypanosoma brucei

In common with all eukaryotic cells, trypanosomes must coordinate a complex series of morphogenetic events both temporally and spatially during the cell cycle. The structural and molecular cues that synchronise these events in trypanosomes have started to be elucidated, and intriguingly although similarities to cell cycle events in other eukaryotes can be identified, trypanosomes have also evolved novel solutions to the common challenges faced by dividing eukaryotic cells. Although cellular morphology is clearly pivotal for successful progression through the trypanosome cell cycle, most cytological studies to date have focused exclusively on procyclic form trypanosomes. These studies provide an excellent framework for understanding cell cycle events in trypanosomes, however recent data indicates that profound differences might exist between different life cycle stages in relation to the regulation of cell cycle and cytokinesis.     

Unusual lysosomes in aortic smooth muscle cells: presence in living and rapidly frozen cells

Unusual tubular structures have been observed in rat aortic smooth muscle cells (SMC) grown in culture. These tubular structures have several characteristics that strongly suggest that they are lysosomes: they are bounded by a single membrane bilayer, contain densely staining material, and acid phosphatase activity. Furthermore, these structures are present in living cells, as demonstrated by their ability to accumulate the membrane-impermeable fluorescent dye lucifer yellow CH. In ultrastructural preparations they are best seen in samples that are cryofixed by rapid freezing and then freeze-substituted in osmium-acetone solutions. Conventional chemical fixation did not appear to preserve these structures to as great an extent as did rapid freezing. Comparison of SMC in vitro to the same cells in situ revealed differences in lysosome number as well as morphological appearance. Thus, the culturing of rat SMC leads to the formation of unusual tubular lysosomes whose ultrastructural appearance is particularly sensitive to the methods employed for examination.     

Stage-specific differences in cell cycle control in Trypanosoma brucei revealed by RNA interference of a mitotic cyclin

African trypanosomes have a tightly coordinated cell cycle to effect efficient segregation of their single organelles, the nucleus, flagellum, and kinetoplast. To investigate cell cycle control in trypanosomes, a mitotic cyclin gene (CYC6) has been identified in Trypanosoma brucei. We show that CYC6 forms an active kinase complex with CRK3, the trypanosome CDK1 homologue, in vivo. Using RNA interference, we demonstrate that absence of CYC6 mRNA results in a mitotic block and growth arrest in both the insect procyclic and mammalian bloodstream forms. In the procyclic form, CYC6 RNA interference generates anucleate cells with a single kinetoplast, whereas in bloodstream form trypanosomes, cells with one nucleus and multiple kinetoplasts are observed. Fluorescence-activated cell sorting analysis shows that bloodstream but not procyclic trypanosomes are able to reinitiate nuclear S phase in the absence of mitosis. Taken together, these data show that procyclic trypanosomes can undergo cytokinesis without completion of mitosis, whereas a mitotic block in bloodstream form trypanosomes inhibits cytokinesis but not kinetoplast replication and segregation nor an additional round of nuclear DNA synthesis. This indicates that there are fundamental differences in cell cycle controls between life cycle forms of T. brucei and that key cell cycle checkpoints present in higher eukaryotes are absent from trypanosomes.     

De novo sphingolipid synthesis is essential for viability, but not for transport of glycosylphosphatidylinositol-anchored proteins, in African trypanosomes

De novo sphingolipid synthesis is required for the exit of glycosylphosphatidylinositol (GPI)-anchored membrane proteins from the endoplasmic reticulum in yeast. Using a pharmacological approach, we test the generality of this phenomenon by analyzing the transport of GPI-anchored cargo in widely divergent eukaryotic systems represented by African trypanosomes and HeLa cells. Myriocin, which blocks the first step of sphingolipid synthesis (serine + palmitate --> 3-ketodihydrosphingosine), inhibited the growth of cultured bloodstream parasites, and growth was rescued with exogenous 3-ketodihydrosphingosine. Myriocin also blocked metabolic incorporation of [3H]serine into base-resistant sphingolipids. Biochemical analyses indicate that the radiolabeled lipids are not sphingomyelin or inositol phosphorylceramide, suggesting that bloodstream trypanosomes synthesize novel sphingolipids. Inhibition of de novo sphingolipid synthesis with myriocin had no adverse effect on either general secretory trafficking or GPI-dependent trafficking in trypanosomes, and similar results were obtained with HeLa cells. A mild effect on endocytosis was seen for bloodstream trypanosomes after prolonged incubation with myriocin. These results indicate that de novo synthesis of sphingolipids is not a general requirement for secretory trafficking in eukaryotic cells. However, in contrast to the closely related kinetoplastid Leishmania major, de novo sphingolipid synthesis is essential for the viability of bloodstream-stage African trypanosomes.     

Don't bother to knock--the cell invasion strategy of Trypanosoma cruzi

The protozoan parasite Trypanosoma cruzi is responsible for Chagas disease, a serious debilitating disease that affects millions of people in Latin America. Trypomastigotes, the infective forms, are capable of invading and replicating in different cell types. The invasion process involves a gradual recruitment and fusion of host cell lysosomes at the parasite entry site, and is regulated by intracellular free Ca2+ transients triggered by trypomastigotes in host cells. This unusual, Ca2+-dependent lysosome exocytosis pathway was recently shown to be involved in the mechanism by which mammalian cells repair lesions on their plasma membrane.     

A novel DNA nucleotide in Trypanosoma brucei only present in the mammalian phase of the life-cycle.

The existence of an unusual form of DNA modification in the bloodstream form of the African trypanosome Trypanosoma brucei has been inferred from partial resistance to cleavage of nuclear DNA with PstI and PvuII (Bernards et al, 1984; Pays et al, 1984). This putative modification is correlated with the shut-off of telomeric Variant-specific Surface Glycoprotein (VSG) gene expression sites (ESs). The modification only affects inactive VSG genes with a telomeric location, and it is absent in procyclic (insect form) trypanosomes in which no VSG is made at all. Previous attempts to detect unusual nucleosides in T.brucei DNA were unsuccessful, but we now report the detection of two unusual nucleotides, called pdJ and pdV, in T.brucei DNA, using the 32P-postlabeling technique. Nucleotide pdV was present in both bloodstream form and procyclic T.brucei DNA and co-migrated in two different two-dimensional thin layer chromatography (2D-TLC) systems with hydroxymethyldeoxyuridine 5'-monophosphate (pHOMedU). In contrast, nucleotide pdJ was exclusively present in bloodstream form trypanosomal DNA. Levels of pdJ were higher in DNA enriched for telomeric sequences than in total genomic DNA and pdJ was also detected in other Kinetoplastida species exhibiting antigenic variation. Postlabeling and 2D-TLC analyses showed base J to be different from the known eukaryotic unusual DNA bases 5-methylcytosine, N6-methyladenine and hydroxymethyluracil, and also from (glucosylated) hydroxymethylcytosine, uracil, alpha-putrescinylthymine, 5-dihydroxypentyluracil and N6-carbamoylmethyladenine. We conclude that pdJ is a novel eukaryotic DNA nucleotide and that it is probably responsible for the partial resistance to cleavage by PvuII and PstI of inactive telomeric VSG genes. It may therefore be involved in the regulation of ES activity in bloodstream form trypanosomes.     

The receptosome: an intermediate organelle of receptor mediated endocytosis in cultured fibroblasts

Receptor-mediated endocytosis of specific ligands is mediated through clustering of receptor-ligand complexes in coated pits on the cell surface. Following this clustering event, the ligand is internalized into a noncoated intracellular vesicle, the receptosome, which selectively avoids fusion with lysosomes and moves toward the Golgi region of the cell by saltatory motion. Using alpha 2-macroglobulin as the ligand and electron microscopic cytochemical methods, we have shown the unusual appearance of this previously undescribed organelle and have followed the labeled ligand in these vesicles in the cytoplasm. To accomplish this, cells were incubated with immunolabeled alpha 2-macroglobulin at 4C under conditions where ligand-receptor complexes cluster into coated pits on the cell surface. Formation of the receptosome occurs between 2 and 5 min after raising the temperature of cells to 37C. These labeled receptosomes were seen to associate with many small vesicular elements in the cytoplasm, and were often found near the Golgi or GERL region after 15 min. Between 15 and 30 min a significant transfer of labeled ligand occurred from the receptosomal population to a population of small uniform lysosomes. By 60 min, all of the label was contained in these small lysosomes. Immunocytochemical studies showed that the receptosomes were not associated with clathrin, actin, myosin or tubulin. This unique, short-lived, specialized organelle selectively delivers the products of receptor-mediated endocytosis to intracellular sites.     

Kinetoplast DNA minicircles: High-copy-number mitochondrial plasmids

The kinetoplast DNA of trypanosomes is a highly unusual network of catenated DNA circles of two kinds: maxicircles, the equivalent of conventional mitochondrial DNA, and minicircles, high-copy-number mitochondrial plasmids with no known function. Kinetoplast minicircles share many features with bacterial plasmids and represent a novel model system for the study of the mechanisms and regulation of DNA replication in eukaryotic organisms.     

Two patients walk into a clinic...a genomics perspective on the future of schizophrenia

Background

Cytolytic cells of the immune system destroy pathogen-infected cells by polarised exocytosis of secretory lysosomes containing the pore-forming protein perforin. Precise delivery of this lethal hit is essential to ensuring that only the target cell is destroyed. In cytotoxic T lymphocytes (CTLs), this is accomplished by an unusual movement of the centrosome to contact the plasma membrane at the centre of the immunological synapse formed between killer and target cells. Secretory lysosomes are directed towards the centrosome along microtubules and delivered precisely to the point of target cell recognition within the immunological synapse, identified by the centrosome. We asked whether this mechanism of directing secretory lysosome release is unique to CTL or whether natural killer (NK) and invariant NKT (iNKT) cytolytic cells of the innate immune system use a similar mechanism to focus perforin-bearing lysosome release.

Results

NK cells were conjugated with B-cell targets lacking major histocompatibility complex class I 721.221 cells, and iNKT cells were conjugated with glycolipid-pulsed CD1-bearing targets, then prepared for thin-section electron microscopy. High-resolution electron micrographs of the immunological synapse formed between NK and iNKT cytolytic cells with their targets revealed that in both NK and iNKT cells, the centrioles could be found associated (or 'docked') with the plasma membrane within the immunological synapse. Secretory clefts were visible within the synapses formed by both NK and iNKT cells, and secretory lysosomes were polarised along microtubules leading towards the docked centrosome. The Golgi apparatus and recycling endosomes were also polarised towards the centrosome at the plasma membrane within the synapse.

Conclusions

These results reveal that, like CTLs of the adaptive immune system, the centrosomes of NK and iNKT cells (cytolytic cells of the innate immune system) direct secretory lysosomes to the immunological synapse. Morphologically, the overall structure of the immunological synapses formed by NK and iNKT cells are very similar to those formed by CTLs, with both exocytic and endocytic organelles polarised towards the centrosome at the plasma membrane, which forms a focal point for exocytosis and endocytosis within the immunological synapse. We conclude that centrosomal polarisation provides a rapid, responsive and precise mechanism for secretory lysosome delivery to the immunological synapse in CTLs, NK cells and iNKT cells.     

Trypanosome hydrolases and the blood-brain barrier

African trypanosomes cross the blood-brain barrier, but how they do so remains an area of speculation. We propose that proteases, such as the trypanopains and oligopeptidases that are released by trypanosomes, could mediate in this process. The trypanosomes also possess cell-surface-associated acid phosphatases that could play a role in invasion similar to that in advancing cancer cells. Such enzymes, perhaps acting in concert, have the potential to cause tissue degradation and ease the passage of the trypanosomes through various tissues in the host, including the blood-brain barrier.     

Flow Loading Induces Oscillatory Trajectories in a Bloodstream Parasite

The dynamics of isolated microswimmers are studied in bounded flow using the African trypanosome, a unicellular parasite, as the model organism. With the help of a microfluidics platform, cells are subjected to flow and found to follow an oscillatory path that is well fit by a sine wave. The frequency and amplitudes of the oscillatory trajectories are dependent on the flow velocity and cell orientation. When traveling in such a manner, trypanosomes orient upstream while downstream-facing cells tumble within the same streamline. A comparison with immotile trypanosomes demonstrates that self-propulsion is essential to the trajectories of trypanosomes even at flow velocities up to ～40 times higher than their own swimming speed. These studies reveal important swimming dynamics that may be generally pertinent to the transport of microswimmers in flow and may be relevant to microbial pathogenesis.     

Depletion of GIM5 causes cellular fragility,a decreased glycosome number,and reduced levels of ether-linked phospholipids in trypanosomes

Microbody division in mammalian cells, trypanosomes, and yeast depends on the PEX11 microbody membrane proteins. The function of PEX11 is not understood, and the suggestion that it affects microbody (peroxisome) numbers in mammals and yeast, because it plays a role in beta-oxidation of fatty acids, is controversial. PEX11 and two PEX11-related proteins, GIM5A and GIM5B, are the predominant membrane proteins of the microbodies (glycosomes) of Trypanosoma brucei. The compartmentation of glycosomal enzymes is essential in trypanosomes. Deletion of the GIM5A gene from the form of the parasite that lives in the mammalian blood has no effect on trypanosome growth, but depletion of GIM5B on a gim5a null background causes death. We show here that procyclic trypanosomes, adapted for life in the Tsetse fly vector, survive without GIM5A and with very low levels of GIM5B. The depleted cells have fewer glycosomes than usual and are osmotically fragile, which is a novel observation for a microbody defect. Thus trypanosomes require both GIM5B and PEX11 for the maintenance of normal glycosome numbers. Procyclic cells lacking GIM5A, like mouse cells partially defective in PEX11, have fewer ether-linked phospholipids, even when GIM5B levels are not reduced. Metabolite measurements on GIM5A/B-depleted bloodstream form trypanosomes suggested a change in the flux through the glycolytic pathway. We conclude that PEX11 family proteins play important roles in determining microbody membrane structure, with secondary effects on a subset of microbody metabolic pathways.