Peter Overath

Hydrodynamic Flow-Mediated Protein Sorting on the Cell Surface of Trypanosomes

The unicellular parasite Trypanosoma brucei rapidly removes host-derived immunoglobulin (Ig) from its cell surface, which is dominated by a single type of glycosylphosphatidylinositol-anchored variant surface glycoprotein (VSG). We have determined the mechanism of antibody clearance and found that Ig-VSG immune complexes are passively sorted to the posterior cell pole, where they are endocytosed. The backward movement of immune complexes requires forward cellular motility but is independent of endocytosis and of actin function. We suggest that the hydrodynamic flow acting on swimming trypanosomes causes directional movement of Ig-VSG immune complexes in the plane of the plasma membrane, that is, immunoglobulins attached to VSG function as molecular sails. Protein sorting by hydrodynamic forces helps to protect trypanosomes against complement-mediated immune destruction in culture and possibly in infected mammals but likewise may be of functional significance at the surface of other cell types such as epithelial cells lining blood vessels.

Kinetics of endocytosis and recycling of the GPI-anchored variant surface glycoprotein in Trypanosoma brucei

The dense coat of glycosylphosphatidylinositol (GPI)-anchored variant surface glycoprotein (VSG) covering parasitic African trypanosomes is essential for survival in mammalian hosts. VSG is internalised and recycled exclusively via a specialised part of the plasma membrane, the flagellar pocket. Direct measurement of the kinetics of VSG endocytosis and recycling shows that the VSG cell-surface pool is turned over within 12 minutes. Correspondingly, the turnover of the intracellular pool (9±4% of total VSG) requires only 1 minute, and this is an exceptionally high rate considering that endocytosis and exocytosis are limited to only 5% of the cell surface area. Kinetic 3D co-localisation analysis using biotinylated VSG and a panel of compartmental markers provides consistent evidence for the itinerary of VSG through the cell: VSG is endocytosed in large clathrin-coated vesicles, which bud from the flagellar pocket membrane at a rate of 6-7 vesicles per second, and is then delivered to RAB5-positive early endosomes. From there, VSG is recycled to RAB11-positive recycling endosomes at two stages, either directly or via RAB7-positive, late endosomes. Small clathrin-coated vesicles carrying fluid-phase cargo and being depleted of VSG bud from early and recycling endosomes. These vesicles are postulated to deliver their content to late endosomes and/or the lysosome. The recycling endosomes give rise to RAB11-positive exocytic carriers that fuse with the flagellar pocket and thereby return VSG to the cell surface. VSG recycling provides an interesting model for studies on the cellular trafficking and sorting of GPI-anchored proteins.

Endocytosis and secretion in trypanosomatid parasites — Tumultuous traffic in a pocket

Trypanosomatids are flagellated protozoan parasites of invertebrates, vertebrates and plants. Some species, found in the subtropics and tropics, cause chronic diseases in humans and domestic animals. The surface of the trypanosomatid provides a shield against environmental challenges, ligands for interaction with host cells, as well as receptors and transporters for the uptake of nutrients. Communication between the parasite and its environment is confined to the flagellar pocket, an invagination of the plasma membrane around the base of the flagellum. In this review, the authors discuss endocytosis, secretion and membrane trafficking in Trypanosoma and Leishmania.

The molecular phylogeny of trypanosomes: evidence for an early divergence of the Salivaria.

Chronic infections with trypanosomes dwelling extracellularly in the blood and tissues of their hosts are observed in all vertebrate classes. We present here a molecular phylogenetic reconstruction of trypanosome evolution based on nucleotide sequences of small subunit rRNA genes. The evolutionary tree suggests an ancient split into one branch containing all Salivarian trypanosomes and a branch containing all non-Salivarian lineages. The latter branch splits into a clade containing bird, reptilian and Stercorarian trypanosomes infecting mammals and a clade with a branch of fish trypanosomes and a branch of reptilian/amphibian lineages. The branching order of the non-Salivarian trypanosomes supports host-parasite cospeciation scenarios, but also suggests host switches, e.g. between bird and reptilian trypanosomes. The tree is discussed in relation to the modes of adaptation that allow trypanosomes to infect immunocompetent vertebrates. Most importantly, the early divergence of the Salivarian lineages suggests that the presence of a dense proteinaceous surface coat that is subject to antigenic variation is a unique invention of this group of parasites.

Targeted integration into a rRNA locus results in uniform and high level expression of transgenes in Leishmania amastigotes.

This report describes the construction of a DNA cassette for integration into a genomic small sub-unit rRNA locus of Leishmania mexicana by homologous recombination. Reporter genes encoding beta-galactosidase or green fluorescent protein and the gene conferring hygromycin resistance were integrated downstream of a RNA polymerase I-driven rRNA promoter. To ensure high expression of the marker proteins in the intracellular, amastigote stage, transgene coding sequences were followed by the intergenic region of the L. mexicana cysteine proteinase B 2.8 gene which provides processing signals required for high level expression in this life-cycle stage. Integration of the DNA cassette was also efficiently obtained in L. major. We show that either beta-galactosidase or the green fluorescent protein were abundantly, stably and uniformly expressed in promastigotes and amastigotes of both Leishmania sp. The transgenic lines allow parasite detection at high sensitivity in the tissues of infected mice and will be useful to follow infections in macrophages in culture and in animal hosts.

Endocytosis, membrane recycling and sorting of GPI‐anchored proteins: Trypanosoma brucei as a model system

In the flagellated protozoon Trypanosoma brucei, endo‐ and exocytosis are restricted to a small area of the plasma membrane, the flagellar pocket. All endosomal compartments and the single Golgi complex are located within the posterior part of the cell between the flagellar pocket and the nucleus. The use of reverse genetic tools, including RNA interference, in combination with quantitative 3D‐fluorescence and electron microscopic techniques has provided an insight into endosomal membrane traffic, which occurs at a very high rate and appears to exhibit a lower level of complexity than in mammalian cells. The flagellate is an excellent model system for studies on endocytosis, sorting and recycling of glycosylphosphatidylinositol‐anchored glycoproteins, because 107 molecules of the variant surface glycoprotein form a dense coat at the cells surface. Because the endocytic rate varies widely at different stages in the parasites life cycle, trypanosomes may be used for investigating developmental aspects of their endocytic system.

Amplification of the lactose carrier protein in Escherichia coli using a plasmid vector.

SummaryThe isolation and properties of a hybrid plasmid carrying the Y gene of the lac operon of Escherichia coli are described. The lactose carrier protein, coded for by the Y gene, is readily identified upon lac operon induction in strains carrying the plasmid. The protein comprises about 15% of the cytoplasmic membrane protein synthesized in the first generation after induction, compared with a wild type strain induced under the same conditions where lactose carrier protein comprises 1.4% of the cytoplasmic membrane protein.

Expression of lipophosphoglycan, high-molecular weight phosphoglycan and glycoprotein 63 in promastigotes and amastigotes of Leishmania mexicana.

The abundant surface glycoconjugate of Leishmania promastigotes, lipophosphoglycan (LPG), forms a blue-colored complex (lambda max = 649 nm) with the cationic dye Stains-all, which can be quantitated densitometrically on polyacrylamide gels of cell lysates. Promastigotes of Leishmania mexicana, Leishmania major and Leishmania donovani yield values of 1-3 x 10(6) LPG molecules cell-1. In amastigotes the LPG content is down-regulated below the detection limit (< 10(3) molecules cell-1) in L. mexicana and L. donovani, but remains significant in L. major (2 x 10(3) molecules cell-1). In the case of L. mexicana, these results are supported by immunological studies. Using several monoclonal and polyclonal antibodies, LPG is undetectable by immunoblotting in lysates of either amastigotes or infected macrophages and the amastigote surface is devoid of LPG as judged by immunofluorescence and immunoelectron microscopy. Immunoblotting experiments demonstrate that amastigotes synthesize hydrophilic high-molecular weight compounds which stain blue with Stains-all and cross-react with the monoclonal and polyvalent antibodies suggesting the presence of similar phosphoglycan structures as in LPG. The high-molecular weight phosphoglycan appears to be located in the lumen of the flagellar pocket of mouse lesion amastigotes and may be secreted from there into the lumen of the parasitophorous vacuole of parasitized macrophages. In L. mexicana promastigotes the surface protease gp63 is amphiphilic and comprises about 1% of the cellular proteins. In contrast, in amastigotes gp63-related proteins are predominantly hydrophilic; they amount to only about 0.1% of the cellular proteins and are mainly located in the lumen of the extended lysosomes (megasomes) characteristic for this species.

A transferrin-binding protein of Trypanosoma brucei is encoded by one of the genes in the variant surface glycoprotein gene expression site

A transferrin‐binding protein (TFBP) with an apparent molecular weight of 42 kd was purified from detergent‐soluble membrane proteins of bloodstream forms of Trypanosoma brucei. The protein is not expressed in the insect‐borne stage of the parasites life‐cycle. Purified TFBP can be converted from an amphiphilic to a hydrophilic form by cleavage with T.brucei glycosylphosphatidylinositol (GPI)‐specific phospholipase C, demonstrating that the C‐terminus is modified by a GPI‐membrane anchor. The TFBP is encoded by an expression‐site‐associated gene [ESAG 6 in the nomenclature of Pays et al. (1989) Cell, 57, 835–845] which is under the control of the promoter transcribing the expressed variant surface glycoprotein gene. The possible function of TFBP as a receptor for the uptake of transferrin in bloodstream forms is discussed.

Phospholipid exchange between bilayer membranes

The mode of interaction of aqueous dispersions of phospholipid vesicles is investigated. The vesicles (average diameter 950 A) are prepared from total lipid extracts of Escherichia coli composed of phosphatidylethanolamine, phosphatidylglycerol and cardiolipin. One type of vesicle contains trans-delta 9-octadecenoate, the other type trans-delta 9-hexadecenoate as predominant acyl chain component. The vesicles show order in equilibrium disorder transitions at transition temperatures, Tt = 42 degrees C and Tt = 29 degrees C, respectively. A mixture of these vesicles is incubated at 45 degrees C and lipid transfer is studied as a function of time using the phase transition as an indicator. The system reveals the following properties: Lipids are transferred between the two vesicle types giving rise to a vesicle population where both lipid components are homogeneously mixed. Lipid transfer is asymmetric, i.e. trans-delta 9-hexadecenoate-containing lipid molecules appear more rapidly in the trans-delta 9-octadecenoate-containing vesicles than vice versa. At a given molar ratio of the two types of vesicles the rate of lipid transfer is independent of the total vesicle concentration. It is concluded that lipid exchange through the water phase by way of single molecules or micelles is the mode of communication of these negatively charged lipid vesicles.