Fine structure of the biogenesis of Giardia lamblia encystation secretory vesicles

Synthesis, transport, and assembly of the extracellular cyst wall is the hallmark of Giardia lamblia encystation. Much is known of the biochemical pathways and their regulation. However, from a cell biology point of view, the biogenesis of the encystation specific vesicles (ESVs) that transport cyst wall proteins to the periphery of the cell is poorly understood. Therefore, we exploited a number of complementary ultrastructural approaches to test the hypothesis that the formation of ESVs utilizes a novel regulated secretory pathway. We analyzed parasites at different stages of encystation in vitro by electron microscopy of thin sections, freeze fracture replicas, and three-dimensional reconstruction from serial sections of cells fixed for cytochemical localization of the endoplasmic reticulum (ER) marker, glucose 6-phosphatase. We also used a stereological approach to determine the area occupied by the ER, clefts, ESVs, and cyst wall. Taken together, our kinetic data suggest that some ER cisternae first dilate to form clefts, which enlarge into the ESVs. Living non-encysting and early-encysting trophozoites were labeled around the periphery of both nuclei with C(6)-NBD-ceramide. At 18-21 h, outward migration of some ESVs frequently caused protrusions at the periphery of encysting trophozoites. The presence of lysosome-like peripheral vesicles between the ESV and plasma membrane of the cell was confirmed using acridine orange, an acidic compartment marker. Our data suggest that G. lamblia has a novel secretory pathway in which certain functions of the ER and Golgi co-localize spatially and temporally. These studies will increase understanding of the evolutionary appearance of regulated secretory pathways for assembly of a primitive extracellular matrix in an early diverging eukaryote.     

Giardia lamblia: regulation of secretory vesicle formation and loss of ability to reattach during encystation in vitro

Encystation of Giardia lamblia is required for survival outside the host, as well as for initiation of new infections. Previously, we induced cultured G. lamblia trophozoites to encyst in vitro for the first time. During encystation, we observed the appearance of a new class of large secretory vesicle (encystation-specific vesicle; ESV) within which cyst antigens are concentrated and transported to the nascent wall. The present kinetic and physiologic studies now show that ESV are the earliest morphologic change observed in encystation. Expression of ESV, as well as subsequent encystation, are regulated by exposure to bile at the slightly alkaline pH which is typical of the human intestinal tract. ESV formation appears to be less stringently regulated than formation of water-resistant cysts because omission of either encystation stimuli or alkaline pH preferentially inhibits encystation. Since cysts do not attach, we asked when in encystation this physiologic transition occurs. We found that most encysting trophozoites remain attached until they begin to round up (greater than 24 hr). However, if they are made to detach, as early as 12 hr in encystation, well before they round up, they are defective in the ability to reattach. If trophozoites also become less able to reattach to the intestinal epithelium early in encystation in vivo, this would increase their exposure to lumenal encystation stimuli and promote encystation. These studies have provided new insights into the complex sequence of morphologic and physiologic alterations which occur during encystation of G. lamblia in vitro and their regulation by host intestinal factors.     

The single dynamin family protein in the primitive protozoan Giardia lamblia is essential for stage conversion and endocytic transport

Dynamins are universally conserved large guanosine triphosphatases, which function as mechanoenzymes in membrane scission. The primitive protozoan Giardia lamblia has a single dynamin-related protein (GlDRP) with an unusual domain structure. Giardia lacks a Golgi apparatus but generates transient Golgi-like delay compartments dubbed encystation-specific vesicles (ESVs), which serve to accumulate and mature cyst wall proteins during differentiation to infectious cyst forms. Here, we analyze the function of GlDRP during growth and encystation and demonstrate that it relocalizes from peripheral endosomal-lysosomal compartments to nascent ESVs. We show that GlDRP is necessary for secretion of the cyst wall material and ESV homeostasis. Expression of a dominant-negative GlDRP variant does not interfere with ESV formation but blocks cyst formation completely prior to regulated exocytosis. GlDRP colocalizes with clathrin at the cell periphery and is necessary for endocytosis of surface proteins to endosomal-lysosomal organelles in trophozoites. Electron microscopy and live cell imaging reveal gross morphological changes as well as functional impairment of the endocytic system in cells expressing the dominant-negative GlDRP. Thus, giardial DRP plays a key role in two distinct trafficking pathways and in organelle homeostasis, both essential functions for the proliferation of the parasite in the gut and its transmission to a new host.     

Active and passive mechanisms drive secretory granule biogenesis during differentiation of the intestinal parasite Giardia lamblia

The parasitic protozoan Giardia lamblia undergoes important changes to survive outside the intestine of its host by differentiating into infective cysts. During encystation, three cyst wall proteins (CWPs) are specifically expressed and concentrated within encystation-specific secretory vesicles (ESVs). ESVs are electron-dense secretory granules that transport CWPs before exocytosis and extracellular polymerization into a rigid cyst wall. Because secretory granules form at the trans-Golgi in higher eukaryotes and because Giardia lacks an identifiable Golgi apparatus, the aim of this work was to investigate the molecular basis of secretory granule formation in Giardia by examining the role of CWPs in this process. Although CWP1, CWP2, and CWP3 are structurally similar in their 26-kDa leucine-rich overlapping region, CWP2 is distinguished by the presence of a 13-kDa C-terminal basic extension. In non-encysting trophozoites, expression of different CWP chimeras showed that the CWP2 basic extension is necessary for biogenesis of ESVs, which occurs in a compartment derived from the endoplasmic reticulum. Nevertheless, the CWP2 basic extension per se is insufficient to trigger ESV formation, indicating that other domains in CWPs are also required. We found that CWP2 is a key regulator of ESV formation by acting as an aggregation factor for CWP1 and CWP3 through interactions mediated by its conserved region. CWP2 also acts as a ligand for sorting via its C-terminal basic extension. These findings show that granule biogenesis requires complex interactions among granule components and membrane receptors.     

Export of cyst wall material and Golgi organelle neogenesis in Giardia lamblia depend on endoplasmic reticulum exit sites

Giardia lamblia parasitism accounts for the majority of cases of parasitic diarrheal disease, making this flagellated eukaryote the most successful intestinal parasite worldwide. This organism has undergone secondary reduction/elimination of entire organelle systems such as mitochondria and Golgi. However, trophozoite to cyst differentiation (encystation) requires neogenesis of Golgi‐like secretory organelles named encystation‐specific vesicles (ESVs), which traffic, modify and partition cyst wall proteins produced exclusively during encystation. In this work we ask whether neogenesis of Golgi‐related ESVs during G. lamblia differentiation, similarly to Golgi biogenesis in more complex eukaryotes, requires the maintenance of distinct COPII‐associated endoplasmic reticulum (ER) subdomains in the form of ER exit sites (ERES) and whether ERES are also present in non‐differentiating trophozoites. To address this question, we identified conserved COPII components in G. lamblia cells and determined their localization, quantity and dynamics at distinct ERES domains in vegetative and differentiating trophozoites. Analogous to ERES and Golgi biogenesis, these domains were closely associated to early stages ofnewly generated ESV. Ectopic expression of non‐functional Sar1 GTPase variants caused ERES collapse and, consequently, ESV ablation, leading to impaired parasite differentiation. Thus, our data show how ERES domains remain conserved in G. lamblia despite elimination of steady‐state Golgi. Furthermore, the fundamental eukaryotic principle of ERES to Golgi/Golgi‐like compartment correspondence holds true in differentiating Giardia presenting streamlined machinery for secretory organelle biogenesis and protein trafficking. However, in the Golgi‐less trophozoites ERES exist as stable ER subdomains, likely as the sole sorting centres for secretory traffic.     

A Lipoprotein-Cholesterol-Albumin Serum Substitute Stimulates Giardia lamblia Encystation Vesicle Formation

ABSTRACT. We found previously that the A6 clone of Giardia lamblia strain WB that did not encyst in vitro was blocked at an early stage in differentiation, as it did not form encystation secretory vesicles (ESV) efficiently or express cyst antigens, in comparison with the related clone C6. We now report that A6 formed ESV normally in the suckling mouse model. Therefore, we asked whether our serum-containing encystation media might lack a stimulus or component or contain an inhibitor of ESV formation to which A6 was especially sensitive. We found that replacing bovine serum with a lipoprotein-cholesterol solution and bovine serum albumin (LPC) in pre-encystation and encystation media increased ESV formation by both A6 and C6. The % of A6 cells with ESV increased from 8% in BS medium to 48% in LPC medium, compared with 64% and 98% for C6. Similarly, the average number of ESV/positive cell increased from 1.5 in BS medium to 7.7 in LPC medium for A6, and from 13.3 to 19.7 for C6. Moreover, in LPC encystation media, A6 expressed the cyst wall epitope recognized by monoclonal GCSA-1. Although formation of water-resistant cysts by A6 was increased >60 fold in LPC media, the numbers of cysts remained only ∼3–15% that of C6. This suggests that LPC may primarily affect early events in encystation and that A6 may require additional factors later in encystation.     

Identification and characterization of a novel secretory granule calcium-binding protein from the early branching eukaryote Giardia lamblia

Giardia lamblia is a flagellate protozoan that infects humans and other mammals and the most frequently isolated intestinal parasite worldwide. Giardia trophozoites undergo essential biological changes to survive outside the intestine of their host by differentiating into infective cysts. Cyst formation, or encystation, is considered one of the most primitive adaptive responses developed by eukaryotes early in evolution and crucial for the transmission of the parasite among susceptible hosts. During this process, proteins that will assemble into the extracellular cyst wall (CWP1 and CWP2) are transported to the cell surface within encystation-specific secretory vesicles (ESVs) by a developmentally regulated secretory pathway. Cyst wall proteins (CWPs) are maintained as a dense material inside the ESVs, but after exocytosis, they form the fibrillar matrix of the cyst wall. Little is known about the molecular mechanisms involved in granule biogenesis and discharge in Giardia, as well as the assembly of the extracellular wall. In this work, we provide evidences that a novel 54-kDa protein that exclusively localizes to the ESVs is induced during encystation similar to CWPs, proteolytically processed during granule maturation, and able to bind calcium in vitro. The gene encoding this molecule predicts a novel protein (called gGSP for G. lamblia Granule-specific Protein) without homology to any other protein reported in public databases. Nevertheless, it possesses characteristics of calcium-sequestering molecules of higher eukaryotes. Inhibition of gGSP expression abolishes cyst wall formation, suggesting that this secretory granule protein regulates Ca(2+)-dependent degranulation of ESVs during cyst wall formation.     

Giardia lamblia: identification and characterization of Rab and GDI proteins in a genome survey of the ER to Golgi endomembrane system

To investigate the complexity of the endomembrane transport system in the early diverging eukaryote, Giardia lamblia, we characterized homologues of the GTP-binding proteins, Rab1 and Rab2, involved in regulating vesicular trafficking between the endoplasmic reticulum and Golgi in higher eukaryotes, and GDI, which plays a key role in the cycling of Rab proteins. G. lamblia Rab1, 2.1, and GDI sequences largely resemble yeast and mammalian homologues, are transcribed as 0.66-, 0.62-, and 1.4-kb messages, respectively, and are expressed during growth and encystation. Western analyses detected an abundant Rab/GDI complex at approximately 80 kDa, and free GDI (60 kDa) in both trophozoites and encysting cells. Immunoelectron microscopy with antibody to Rab1 localized Rab with ER, encystation secretory vesicles, and lysosome-like peripheral vesicles. GDI associated with these structures, and with small vesicles found throughout the cytoplasm, consistent with GDI's key role in Rab cycling between organelles within the cell.     

Mining the Giardia lamblia genome for new cyst wall proteins

The Giardia lamblia cyst wall (CW), which is required for survival outside the host and infection, is a primitive extracellular matrix. Because of the importance of the CW, we queried the Giardia Genome Project Database with the coding sequences of the only two known CW proteins, which are cysteine-rich and contain leucine-rich repeats (LRRs). We identified five new LRR-containing proteins, of which only one (CWP3) is up-regulated during encystation and incorporated into the cyst wall. Sequence comparison with CWP1 and -2 revealed conservation within the LRRs and the 44-amino-acid N-flanking region, although CWP3 is more divergent. Interestingly, all 14 cysteine residues of CWP3 are positionally conserved with CWP1 and -2. During encystation, C-terminal epitope-tagged CWP3 was transported to the wall of water-resistant cysts via the novel regulated secretory pathway in encystation-secretory vesicles (ESVs). Deletion analysis revealed that the four LRRs are each essential to target CWP3 to the ESVs and cyst wall. In a deletion of the most C-terminal region, fewer ESVs were stained in encysting cells, and there was no staining in cysts. In contrast, deletion of the 44 amino acids between the signal sequence and the LRRs or the region just C-terminal to the LRRs only decreased the number of cells with CWP3 targeting to ESVs and cyst wall by approximately 50%. Our studies indicate that virtually every portion of the CWP3 protein is needed for efficient targeting to the regulated secretory pathway and incorporation into the cyst wall. Further, these data demonstrate the power of genomics in combination with rigorous functional analyses to verify annotation.     

Organelle proteomics reveals cargo maturation mechanisms associated with Golgi-like encystation vesicles in the early-diverged protozoan Giardia lamblia

During encystation Giardia trophozoites secrete a fibrillar extracellular matrix of glycans and cyst wall proteins on the cell surface. The cyst wall material is accumulated in encystation-specific vesicles (ESVs), specialized Golgi-like compartments generated de novo, after export from the endoplasmic reticulum (ER) and before secretion. These large post-ER vesicles neither have the morphological characteristics of Golgi cisternae nor sorting functions, but may represent an evolutionary early form of the Golgi-like maturation compartment. Because little is known about the genesis and maturation of ESVs, we used a limited proteomics approach to discover novel proteins that are specific for developing ESVs or associated peripherally with these organelles. Unexpectedly, we identified cytoplasmic and luminal factors of the ER quality control system on two-dimensional electrophoresis gels, i.e. several proteasome subunits and HSP70-BiP. We show that BiP is exported to ESVs and retrieved via its C-terminal KDEL signal from ESVs. In contrast, cytoplasmic proteasome complexes undergo a developmentally regulated re-localization to ESVs during encystation. This suggests that maturation of bulk exported cyst wall material in the Golgi-like ESVs involves both continuous activity of ER-associated quality control mechanisms and retrograde Golgi to ER transport.     

The secretory apparatus of an ancient eukaryote: protein sorting to separate export pathways occurs before formation of transient Golgi-like compartments

Transmission of the protozoan parasite Giardia intestinalis to vertebrate hosts presupposes the encapsulation of trophozoites into an environmentally resistant and infectious cyst form. We have previously shown that cyst wall proteins were faithfully sorted to large encystation-specific vesicles (ESVs), despite the absence of a recognizable Golgi apparatus. Here, we demonstrate that sorting to a second constitutively active pathway transporting variant-specific surface proteins (VSPs) to the surface depended on the cytoplasmic VSP tail. Moreover, pulsed endoplasmic reticulum (ER) export of chimeric reporters containing functional signals for both pathways showed that protein sorting was done at or very soon after export from the ER. Correspondingly, we found that a limited number of novel transitional ER-like structures together with small transport intermediates were generated during encystation. Colocalization of transitional ER regions and early ESVs with coat protein (COP) II and of maturing ESVs with COPI and clathrin strongly suggested that ESVs form by fusion of ER-derived vesicles and subsequently undergo maturation by retrograde transport. Together, the data supported the hypothesis that in Giardia, a primordial secretory apparatus is in operation by which proteins are sorted in the early secretory pathway, and the developmentally induced ESVs carry out at least some Golgi functions.     

Organelles of protein transport in Giardia lamblia

Giardia occupies a unique evolutionary position since it is considered to belong to the earliest known lineage to diverge from the eukaryotic line of descent. Although organelles of protein transport are thought to have evolved with the nuclear membrane, G. lamblia is reported to have no Golgi apparatus. Therefore, Frances Gillin, David Reiner and Michael McCaffery have investigated how it exports glycoproteins to the cyst wall during encystation and whether a Golgi might become evident during an active secretory phase. They have found both functional and morphological evidence of a Golgi in Giardia and have shown that trophozoites are capable of sophisticated protein recognition, sorting and trafficking. These studies suggest that membranous organelles of protein transport appeared early in the evolution of the eukaryotic cell.     

Glucosylceramide Transferase Activity Is Critical for Encystation and Viable Cyst Production by an Intestinal Protozoan,Giardia lamblia

The production of viable cysts by Giardia is essential for its survival in the environment and for spreading the infection via contaminated food and water. The hallmark of cyst production (also known as encystation) is the biogenesis of encystation-specific vesicles (ESVs) that transport cyst wall proteins to the plasma membrane of the trophozoite before laying down the protective cyst wall. However, the molecules that regulate ESV biogenesis and maintain cyst viability have never before been identified. Here, we report that giardial glucosylceramide transferase-1 (gGlcT1), an enzyme of sphingolipid biosynthesis, plays a key role in ESV biogenesis and maintaining cyst viability. We find that overexpression of this enzyme induced the formation of aggregated/enlarged ESVs and generated clustered cysts with reduced viability. The silencing of gGlcT1 synthesis by antisense morpholino oligonucleotide abolished ESV production and generated mostly nonviable cysts. Interestingly, when gGlcT1-overexpressed Giardia was transfected with anti-gGlcT1 morpholino, the enzyme activity, vesicle biogenesis, and cyst viability returned to normal, suggesting that the regulated expression of gGlcT1 is important for encystation and viable cyst production. Furthermore, the overexpression of gGlcT1 increased the influx of membrane lipids and fatty acids without altering the fluidity of plasma membranes, indicating that the expression of gGlcT1 activity is linked to lipid internalization and maintaining the overall lipid balance in this parasite. Taken together, our results suggest that gGlcT1 is a key player of ESV biogenesis and cyst viability and therefore could be targeted for developing new anti-giardial therapies.     

Stage-specific expression and targeting of cyst wall protein-green fluorescent protein chimeras in Giardia

In preparation for being shed into the environment as infectious cysts, trophozoites of Giardia spp. synthesize and deposit large amounts of extracellular matrix into a resistant extracellular cyst wall. Functional aspects of this developmentally regulated process were investigated by expressing a series of chimeric cyst wall protein 1 (CWP1)-green fluorescent protein (GFP) reporter proteins. It was demonstrated that a short 110 bp 5' flanking region of the CWP1 gene harbors all necessary cis-DNA elements for strictly encystation-specific expression of a reporter during in vitro encystation, whereas sequences in the 3' flanking region are involved in modulation of steady-state levels of its mRNA during encystation. Encysting Giardia expressing CWP1-GFP chimeras showed formation and maturation of labeled dense granule-like vesicles and subsequent incorporation of GFP-tagged protein into the cyst wall, dependent on which domains of CWP1 were included. The N-terminal domain of CWP1 was required for targeting GFP to regulated compartments of the secretory apparatus, whereas a central domain containing leucine-rich repeats mediated association of the chimera with the extracellular cyst wall. We show that analysis of protein transport using GFP-tagged molecules is feasible in an anaerobic organism and provides a useful tool for investigating the organization of primitive eukaryotic vesicular transport.     

Sorting of progeny coronavirus from condensed secretory proteins at the exit from the trans-Golgi network of AtT20 cells

Murine hepatitis virus (strain A59), (MHV-A59) is a coronavirus that buds into pre-Golgi compartments and then exploits the exocytic pathway of the host cell to reach the exterior. The fibroblastic cells in which replication of this virus is usually studied have only a constitutive exocytic pathway that the virus uses. MHV-A59 also infects, albeit inefficiently, AtT20 cells, murine pituitary tumor cells with a regulated as well as a constitutive exocytic pathway. Here we examine AtT20 cells at early times after the infection, when the Golgi apparatus retains its morphological and biochemical integrity. We observe that progeny coronavirus and secretory protein destined for the secretory granules of the regulated exocytic pathway traverse the same Golgi stacks and accumulate in the trans-Golgi network. Their pathways diverge at this site, the condensed secretory proteins including the ACTH going to the secretory granules and the coronavirus to post-Golgi transport vesicles devoid of ACTH. On very rare occasions there is missorting such that aggregates of condensed secretory proteins and viruses occur together in post-Golgi vesicles. We conclude that the constitutive and regulated exocytic pathways, identified respectively by the progeny virions and the secretory protein ACTH, diverge at the exit from the trans-Golgi network.     

Multiple pathways of exocytosis, endocytosis, and membrane recycling: validation of a Golgi route

A number of pathways for intracellular membrane traffic have been detected in various cell types. The major established routes are: 1) the lysosomal pathway, which is the major route utilized in phagocytic and cultured cells; 2) the transcellular route, which represents the major type of traffic in nonfenestrated, capillary endothelial cells and which also appears to be the preferred route for the transport of immunoglobulins (intact) across cells; 3) the exocytosis pathway, utilized in secretory cells for discharge of secretory products, and which is also believed to be used for delivery of intrinsic membrane glycoproteins; 4) the plasmalemma to Golgi route, also highly developed in secretory cells, which is believed to be utilized for the recycling of secretory granule membranes; and 5) the biosynthetic pathways for transport of secretory products, lysosomal enzymes, and membrane proteins from the endoplasmic reticulum to the Golgi complex and for transport of lysosomal enzymes from the Golgi complex to lysosomes. It has become clear that cells repeatedly reutilize or recycle the membranes used in these various transport operations. Clathrin-coated vesicles have been found to be involved in transport along all these routes, which suggests that there are multiple populations of coated vesicles with different transport functions in every cell. It has become clear that the Golgi complex is the site where the membrane and product traffic converges and is sorted and directed to its correct destinations. The validation of a transport route from the cell surface to the Golgi complex raises the possibility that bound ligands and membrane constituents could be modified or repaired in transit during recycling through the Golgi complex, which is a biosynthetic compartment.