Correction
14 Aug 2014: The PLOS Neglected Tropical Diseases Staff (2014) Correction: Identification of Giardia lamblia DHHC Proteins and the Role of Protein S-palmitoylation in the Encystation Process. PLOS Neglected Tropical Diseases 8(8): e3157. https://doi.org/10.1371/journal.pntd.0003157 View correction
Figures
Abstract
Protein S-palmitoylation, a hydrophobic post-translational modification, is performed by protein acyltransferases that have a common DHHC Cys-rich domain (DHHC proteins), and provides a regulatory switch for protein membrane association. In this work, we analyzed the presence of DHHC proteins in the protozoa parasite Giardia lamblia and the function of the reversible S-palmitoylation of proteins during parasite differentiation into cyst. Two specific events were observed: encysting cells displayed a larger amount of palmitoylated proteins, and parasites treated with palmitoylation inhibitors produced a reduced number of mature cysts. With bioinformatics tools, we found nine DHHC proteins, potential protein acyltransferases, in the Giardia proteome. These proteins displayed a conserved structure when compared to different organisms and are distributed in different monophyletic clades. Although all Giardia DHHC proteins were found to be present in trophozoites and encysting cells, these proteins showed a different intracellular localization in trophozoites and seemed to be differently involved in the encystation process when they were overexpressed. dhhc transgenic parasites showed a different pattern of cyst wall protein expression and yielded different amounts of mature cysts when they were induced to encyst. Our findings disclosed some important issues regarding the role of DHHC proteins and palmitoylation during Giardia encystation.
Author Summary
Giardiasis is a major cause of non-viral/non-bacterial diarrheal disease worldwide and has been included within the WHO Neglected Disease Initiative since 2004. Infection begins with the ingestion of Giardia lamblia in cyst form, which, after exposure to gastric acid in the host stomach and proteases in the duodenum, gives rise to trophozoites. The inverse process is called encystation and begins when the trophozoites migrate to the lower part of the small intestine where they receive signals that trigger synthesis of the components of the cyst wall. The cyst form enables the parasite to survive in the environment, infect a new host and evade the immune response. In this work, we explored the role of protein S-palmitoylation, a unique reversible post-translational modification, during Giardia encystation, because de novo generation of endomembrane compartments, protein sorting and vesicle fusion occur in this process. Our findings may contribute to the design of therapeutic agents against this important human pathogen.
Citation: Merino MC, Zamponi N, Vranych CV, Touz MC, Rópolo AS (2014) Identification of Giardia lamblia DHHC Proteins and the Role of Protein S-palmitoylation in the Encystation Process. PLoS Negl Trop Dis 8(7): e2997. https://doi.org/10.1371/journal.pntd.0002997
Editor: Steven M. Singer, Georgetown University, United States of America
Received: November 15, 2013; Accepted: May 23, 2014; Published: July 24, 2014
Copyright: © 2014 Merino et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This research was supported by the Agencia Nacional para la Promoción de la Ciencia y Tecnología(FONCyT) PICT 2010 grant to MCT and PICT 2008 grant to ASR; and by CONICET and SECYT-UNC grants to ASR. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Introduction
The flagellated protozoan parasite Giardia lamblia is a major cause of non-viral/non-bacterial diarrheal disease worldwide. This parasite can cause asymptomatic colonization or acute or chronic diarrheal illness and malabsorption [1]. Infection begins with the ingestion of Giardia in its cyst form which, after exposure to gastric acid in the host stomach and proteases in the duodenum, gives rise to trophozoites. The inverse process is called encystation and begins when the trophozoites migrate to the lower part of the small intestine where they receive signals that trigger synthesis of the components of the cyst wall. The encystation process is tightly regulated but the exact mechanism that controls this process is still obscure. Expression of the three Cyst Wall Proteins (CWP) and the glycopolymer biosynthetic enzymes, is largely upregulated. In addition, several other proteins, whose roles in encystation are yet to be discovered, are upregulated at the transcriptional level [2], [3]. Various protein posttranslational modifications (PTM) have been implicated in the development of encystation, such as phosphorylation [4] and deacetylation [5], among others [6], [7], [8]. There is also some evidence of the role of PTM in gene regulation for the control of this process [9].
Protein S-palmitoylation (hereafter referred to as palmitoylation), the post-translational addition of palmitic acid (16∶0) to cysteine residues of proteins, is a PTM essential for proper membrane trafficking to defined intracellular membranes or membrane sub-domains, protein stability, protein turnover, and vesicle fusion [10], [11], [12]. Unlike the other lipid modifications, palmitoylation is potentially reversible, providing a regulatory switch for membrane association [13], [14]. Palmitoylation is catalyzed by a family of protein acyltransferases (PATs), which transfer a palmitoyl moiety derived from palmitoyl-CoA to a free thiol of a substrate protein to create a labile thioester linkage [15], [16]. The discovery of these enzymes came through studies in yeast that identified the PATs Erf2 and Akr1, which are active against Ras and casein kinase, respectively [17], [16]. These enzymes are polytopic integral membrane proteins which share the conserved Asp-His-His-Cys (DHHC) - cysteine-rich domain (CRD). The general membrane topology predictions indicate that the core structure of a PAT is four transmembrane domains (TMDs), with the N- and C- terminus in the cytoplasm [18]. The signature feature DHHC-CRD, which is indispensable for palmitoylating activity, is located in the cytoplasmic loop between the second and third TMDs [19]. There is a small group of PATs that display six TMDs with an extended N-terminal region encoding ankyrin repeats. The yeast PAT called Akr1 is a member of this group [16], [20]. All these findings were crucial in defining palmitoylation as an enzymatic process and led to subsequent identification of protein acyltransferases in many other organisms, such as mammals [21], [22], plants [23], and protozoan parasites like Toxoplasma gondii [24], [25], Plasmodium [26], [25], and Trypanosoma brucei [27].
There is scarce knowledge about palmitoylation in Giardia, but some findings indicate that this PTM may play an important role in pathogenesis. It was shown that α19-giardin, one of the major protein components of the Giardia cytoskeleton, can be both myristoylated and palmitoylated [28] and that the variant-specific surface proteins (VSPs) may be palmitoylated within their C-terminal domains [29], [30]. Later, Touz et al. determined the exact site of palmitoylation of the VSPs, characterized the enzyme responsible for this modification, and determined the participation of palmitoylation during antigenic variation [31], a process in which the trophozoite continuously changes its surface antigen coat [32]. Antigenic variation and encystation are two distinctive mechanisms of defense that the parasite has developed to survive in hostile environmental conditions during its life cycle, and it has been suggested that both are mechanistically related processes [33].
Accumulation of material in membrane vesicles followed by transport and vesicle fusion and secretion are some of the main events involved in Giardia encystation. Because palmitoylation has been reported to play a key role in these events in other cell types [12], [10], [34], [35], [36], it is likely that this PTM may also play a role in Giardia encystation. In this work, we address the question of whether PATs and palmitoylation itself are involved in Giardia encystation. We provide evidence about the role of palmitoylation in Giardia encystation biology by inhibiting this PTM with 2-bromopalmitate (2-BP) or 2-fluoropalmitate (2-FP). Using bioinformatics, we identified the potential PATs (hereafter called DHHC proteins) in the Giardia lamblia proteome and performed a phylogenetic analysis of these proteins. We evaluated the expression of the total collection of DHHC proteins in trophozoites and encysting parasites. Using dhhc transgenic Giardia parasites, we revealed the intracellular localization of DHHC proteins and their influence in CWP expression and cyst yield when parasites were induced to encyst. Our data suggest a role of palmitoylation and DHHC proteins in encystation, providing an insight into the impact of this PTM in Giardia survival.
Methods
Giardia lamblia culture, transfection, and differentiation
Trophozoites of the isolate WB, clone 1267 [37], were cultured in TYI-S-33 medium supplemented with 10% adult bovine serum and 0.5 mg ml−1 bovine bile (Sigma, St. Louis, MO) as described [38]. GL50806_40376 (High Cysteine Non-variant Cyst protein; HCNCp), GL50803_1908, GL50803_2116, GL50803_16928, and GL50803_8711 open reading frames (ORF) were amplified from genomic DNA. GL50806_40376 was cloned into the vector pTubV5-pac [39] to generate pHCNCp-V5 plasmid. GL50803_1908, GL50803_2116, GL50803_16928, and GL50803_8711 were each one cloned into the vector pTubHA-pac [39] to generate the pDHHC-HA plasmids. Trophozoites were transfected with the constructs by electroporation and selected by puromycin (Invivogen, San Diego, CA) as previously described [40], [41], [42]. Trophozoites transfected with empty pTubHA-pac or pTubV5-pac plasmids were used as control. Primer sequences used for DHHC proteins cloning are depicted in table S1. Encystation was induced by growing trophozoites for one culture cycle in TYI-S-33 medium without bile (pre-encystation). Bile-deficient medium was poured off along with unattached trophozoites and replaced with warmed encysting medium containing 0.45 mg ml−1 porcine bile (Sigma, St. Louis, MO) and 0.25 mg ml−1 lactic acid (Sigma, St. Louis, MO), pH 7.8, and incubated at 37°C for 48 h [43]. Total encysting cultures were harvested at 48 h by chilling and centrifugation, and subsequently used for palmitoylation assay, RNA extraction, western blot, immunofluorescence, or flow cytometry.
Palmitoylation assay
The assay followed the procedure described by Papanastasiou et al. and Corvi et al. [29], [44]. Briefly, 8×106 growing and encysting wild-type or dhhc transgenic parasites were washed, suspended in 1 ml of RPMI (Gibco, Invitrogen, Carlsbad, CA) containing 200 µCi of [9,10-3H(N)]-palmitic acid (Perkin-Elmer, MA), previously conjugated to BSA fatty acid free (1∶1, mol∶mol ratio), and incubated for 4 h at 37°C. The samples were then suspended on SDS–PAGE loading buffer without any reducing agent and loaded onto SDS-PAGE gel. The gel was then incubated for 30 min in ddH2O and for 30 min more in 1M sodium salicylate pH 6.5. The gel was then incubated with 3% glycerol, 10% acetic acid, and 40% methanol for 30 min, dried for 2 h at 80°C using a gel dryer machine, and exposed to autoradiographic film for a month. For hydroxylamine treatment, the gel was soaked in either 1 M NH2OH- NaOH pH 7.0 or 1 M Tris-HCl pH 7.0 (Control) for 48 h. Finally, the gel was incubated for 30 min in ddH2O and for 30 min more in 1M sodium salicylate pH 6.5, dried as described above, and exposed to autoradiographic film for a month.
Acyl-biotin exchange
Total cellular palmitoylated proteins from growing and encysting wild-type or transgenic (overexpressing HCNCp) parasites, were purified following the procedure described by Wan et al. [45]. Briefly, 5×107 trophozoites or 48 h encysting parasites were harvested and lysed with Lysis buffer (LB; 50 mM Tris-HCl pH 7.4, 5 mM EDTA, 150 mM NaCl) with 10 mM N-Ethylmaleimide (NEM; Thermo Scientific Pierce Rockford, IL) plus protease inhibitors. After sonication, 1.7% of Triton X-100 was added to each sample and incubated for 1 h at 4°C under shacking. The samples were then centrifuged at 500× g for 5 min at 4°C. The supernatant was collected in a new tube and solubilized proteins were precipitated with chloroform-methanol. Proteins were resolubilized in 4% SDS buffer (SB; 4% SDS, 50 mM Tris-HCl pH 7.4, 5 mM EDTA) with 10 mM NEM by incubating at 37°C under shacking. Each sample was then diluted with 3 vol of LB with 1 mM NEM, protease inhibitors, and 0.2% Triton X-100 and incubated overnight at 4°C under shacking. Proteins were then precipitated by three sequential chloroform-methanol extractions after which each sample was dissolved in SB and split into two equal fractions: one for neutral pH hydroxylamine treatment (hyd+) and the other for neutral pH Tris buffer treatment (hyd−). The hyd+ portion was diluted with 4 vol of hyd+ buffer (1M hydroxylamine pH 7.4, 150 mM NaCl, 1 mM HPDP-Biotin, 0.2% Triton X-100, protease inhibitors), and the hyd- portion with 4 vol of the hyd- buffer (50 mM Tris-HCl pH 7.4, 5 mM EDTA, 150 mM NaCl, 1 mM HPDP-Biotin (Thermo Scientific Pierce, Rockford, IL), 0.2% Triton-X-100, protease inhibitors) and incubated for 1 h at room temperature under shacking, followed by chloroform-methanol precipitation. The samples were then resuspended in SB at 37°C under shacking. Protein pellets were solubilized in LB containing 0.2% Triton X-100. Streptavidin-agarose (Thermo Scientific Pierce, Rockford, IL) was added at concentration of 25 µl beads ml−1 and the lysate and samples were incubated for 1 h at room temperature. Unbound proteins were removed by four sequential washes with LB containing 0.2% Triton X-100. Samples were finally eluted with 100 mM DTT containing 0.2% Triton X-100. Each eluate was then analyzed by Western blotting.
Inhibition of palmitoylation
Giardia trophozoites were cultured as described above. 2-bromopalmitate (2-BP) (Sigma-Aldrich, St. Louis, MO) or 2-fluoropalmitate (2-FP) (Cayman Chemical, Ann Arbor, MI) were added to the media for 48 h to reach a final concentration of 10, 20, 40, 50, 75 or 100 µM for 2-BP, and 100, 150 or 200 µM for 2-FP. The inhibitors were diluted in DMSO (Sigma-Aldrich, St. Louis, MO) following manufacturer indications. The parasites were then analyzed by staining them with Trypan blue to distinguish live from dead cells and by counting them in a Neubauer chamber. To perform a growth curve, parasites from three independent experiments were counted. Parasites were induced to encyst as described above. 2-BP or 2-FP were added with encysting media for 48 h to reach a final concentration of 10, 20 or 40 µM for 2-BP, and 100 µM for 2-FP. The inhibitors were diluted in DMSO as mentioned above. For immunofluorescence the parasites were subcultured onto 12 mm round glass coverslips (Glaswarenfabrik Karl Hecht, Sondhein, Germany) in 24-well culture plates for 1 h, fixed with 4% paraformaldehyde in PBS for 20 min at 4°C, washed twice in PBS and blocked with 10% normal goat serum (Invitrogen, Carlsbad, CA) in 0.1% Triton X-100 in PBS for 30 min at 37°C. The samples were then incubated with FITC labeled anti-CWP1 mAb (Waterborne Inc., New Orleans, LA) diluted 1∶250 in PBS containing 3% normal goat serum and 0.1% Triton X-100 for 1 h at 37°C or anti-CWP1 mAb and DAPI diluted in PBS (dilution 1∶500) (Sigma, St. Louis, MO). The coverslips were then mounted onto glass slides using FluorSave reagent (Calbiochem, La Jolla, CA). Fluorescence was visualized in a Zeiss Axiovert 200 microscope (Carl Zeiss, Jena, Germany). To quantify the percentage of encysting parasites, 55 cells from three separate experiments were counted and classified as encysting I, encysting II, or cyst according to the cell shape, membrane staining, and number and size of the encystation-specific vesicles. The average was taken in each of the three groups.
Dataset construction, multiple sequence alignment, and phylogenetic analyses
A proteome database was constructed gathering complete proteomes for 25 Metazoa (Amphimedon queenslandica (aqu), Anolis carolinensis (aca), Apis mellifera (apm), Bombyx mori (bmo), Caenorhabditis elegans (cae), Canis familiaris (cfa), Ciona intestinalis (cin), Danio rerio (dre), Daphnia pulex (dpu), Drosophila melanogaster (dme), Equus caballus (eqc), Felis catus (fca), Gallus gallus (gga), Gorilla gorilla (ggo), Homo sapiens (hsa), Ixodes scapularis (ixs), Mus musculus (mmu), Nematostella vectensis (nve), Ornithorhynchus anatinus (oan), Petromyzon marinus (pma), Pteropus vampyrus (pva), Rattus norvegicus (rno), Schistosoma mansoni (sma), Sus scrofa (ssc) and Xenopus tropicalis (xtr)), 18 Fungi (Aspergillus nidulans (and), Batrachochytrium dendrobatidis (bde), Botryotinia fuckeliana (bfu), Candida albicans (clb), Encephalitozoon cuniculi (ecu), Gibberella zeae (gze), Leptosphaeria maculans (lem), Nematocida sp (nsp), Neurospora crassa (ncr), Pichia pastoris (ppa), Puccinia graminis (pug), Saccharomyces cerevisiae (sce), Schizosaccharomyces pombe (szp), Sclerotinia sclerotiorum (scl), Tuber melanosporum (tme), Ustilago maydis (uma), Vittaforma corneae (vco) and Yarrowia lipolytica (yli)), 12 Plants (Arabidopsis thaliana (ath), Brachypodium distachyon (bdi), Glycine max (gmx), Medicago truncatula (met), Oryza sativa (osa), Physcomitrella patens (php), Populus trichocarpa (pot), Selaginella moellendorffii (smo), Solanum lycopersicum (sly), Solanum tuberosum (stu), Sorghum bicolor (sbi) and Vitis vinifera (vvi)), 1 Brown alga (Aureococcus anophagefferens (aan)), 1 Red alga (Cyanidioschyzon merolae (cym)), 3 Green algae (Ostreococcus taurii (ota), Chlamydomonas reinhardtii (chr) and Chlorella variabilis (chv)), and 24 Protists (Babesia bovis (bbo), Bigelowiella natans (bna), Chlamydomonas reinhardtii (chr), Chlorella sp (chl), Cryptosporidium parvum (cpv), Dictyostelium discoideum (ddi), Entamoeba histolytica (ehi), Giardia lamblia (gla), Guillardia theta (gth), Leishmania major (lma), Paramecium tetraurelia (pat), Perkinsus marinus (pem), Phaeodactylum tricornutum (pht), Phytophthora capsici (pcs), Phytophthora ramorum (pra), Plasmodium falciparum (pfa), Polysphondylium pallidum (pop), Tetrahymena thermophila (tet), Thalassiosira pseudonana (thp), Theileria parva (thp), Toxoplasma gondii (tgo), Trichomonas vaginalis (tva), Trypanosoma brucei (trb) and Trypanosoma cruzi (tcz)) from Ensembl, the Joint Genome Institute (JGI) and the NCBI databanks. zf-DHHC HMMer profile was obtained from Pfam [46], and used to search the proteomes database [47]. Incomplete sequences or those that did not start with the M residue were deleted from the dataset. Also, 90% similar amino acid sequences were clustered using CD-HIT web server with default settings, to reduce the redundancy of the set [48]. The final dataset contained 1034 amino acid sequences. Multiple sequence alignment of DHHC-CRD amino acid sequences was carried out using PROMALS3D online server with default settings [49]. Following manual curation using GeneDoc software [50], sequences lacking conservation in the regions of interest (i.e., DPG, DHHC-CRD and TTxE) were removed. Block Mapping and Gathering with Entropy (BMGE) [51] was used to select columns suitable for phylogenetic inference with the following settings: m = BLOSUM30, g = 0.2, b = 4.
Phylogenetic analysis was performed by Maximum Likelihood (ML) using PhyML [52] with approximate likelihood-ratio test (aLRT), in combination with the LG+G amino acid replacement matrix, which was determined by ProtTest to be the model of protein evolution which best fit the data [53]. Phylogenetic trees were generated and edited with Itol [54].
Semiquantitative Reverse Transcription Polymerase Chain Reaction (RT-PCR)
RNA from WB1267 trophozoites or 48 h encysting WB1267 was extracted and purified using TRIzol reagent (Invitrogen, Carlsbad, CA) and SV total RNA Isolation System (Promega, Madison, WI). Total RNA were reverse transcribed using Revertaid reverse transcriptase according to the manufacturer's specifications (Fermentas, Thermo Scientific, PA). DNA contamination was tested by performing PCR in a “-RT” control (a mock reverse transcription containing all the RT-PCR reagents, except the reverse transcriptase. For PCR, 30 cycles (30 s at 94°C, 30 s at 55°C and 1 min at 72°C) were used ending with a final extension of 10 min at 72°C. The expression of the Giardia glutamate dehydrogenase (gdh) gene was assayed for positive control. Aliquots (50 µl) of the RT-PCR reaction were size-separated on 1% agarose gel prestained with SYBR Safe (Invitrogen, Carlsbad, CA). Primers sequences used in RT-PCR are displayed in table S2. These assays were performed four times in duplicates.
Relative quantitative Real Time-PCR (qRT-PCR)
RNA from WB1267 trophozoites, 48 h encysting WB1267 or dhhc transgenic 48 h encysting cells (GL50803_1908, GL50803_2116, GL50803_16928, GL50803_8711) was extracted and purified as described above. 2 µg of total RNA were reverse transcribed using Revertaid reverse transcriptase according to the manufacturer's specifications (Fermentas, Thermo Scientific, PA). DNA contamination was tested as described above. cDNA samples were stored at −80°C until use. Control samples were prepared as above using nuclease-free ddH2O in place of RNA. Primers for PCR were designed using Primer express 3.0 software (Applied Biosystems, Forster City, CA) and were synthesized by Invitrogen, Inc. (Carlsbad, CA). Amplification was performed in a final volume of 20 µl, containing 2 µl of each cDNA sample which were previously diluted 1∶1000 (for dhhc genes) or 1∶10000 (for cwp genes), and 10 µl of SYBR Green Master Mix (Applied Biosystems, Foster City, CA). qRT-PCR was performed in a StepOne thermal cycler (Applied Biosystems, Foster City, CA). The mRNA levels of the genes studied were normalized to the expression of the Giardia glutamate dehydrogenase (gdh) gene. The relative-quantitative RT-PCR conditions were: holding stage: 95°C for 10 min, cycling stage: 40 cycles at 95°C for 15 s, 60°C for 1 min and melt curve stage: 95°C for 15 s, 60°C for 1 min, and 95°C for 15 s. Expression data were determined by using the comparative ΔΔCt method [55]. Primer sequences used in qRT-PCR are displayed in table S3.
Western blot analysis
For Western Blot assays, parasite lysates or purified palmitoylated proteins were incubated with 2× Laemmli buffer, boiled for 10 min, and separated in 10% Bis-Tris gels using a Mini Protean II electrophoresis unit (Bio-Rad). Samples were transferred to nitrocellulose membranes (GE Healthcare Biosciences, Pittsburgh, PA), blocked with 5% skimmed milk and 0.1% Tween 20 in PBS, and later incubated with anti-HA mAb or anti-V5 mAb (Sigma, St. Louis, MO; dilution 1∶1000 or 1∶50 respectively) diluted in the same buffer for 1 h. The membrane was then washed, incubated with IDRye 800CW conjugated goat anti-mouse Ab (LI-COR, Lincoln, NE; dilution 1∶10000) for 1 h, and analyzed on the Odyssey scanner (LI-COR, Lincoln, NE). For the analysis of VSPs expression, blockage was performed with 5% skimmed milk and 0.1% Tween 20 in TBS, and then incubated with 5C1 anti-VSP1267 mAb diluted in the same buffer for 1 h. After washing and incubation with an enzyme-conjugated secondary antibody, proteins were visualized with the SuperSignal West Pico Chemiluminescent Substrate (Pierce, Thermo Fisher Scientific Inc., Rockford, IL, USA) and autoradiography. Controls included the omission of the primary antibody, the use of an unrelated antibody, or assays using non-transfected cells.
Immunofluorescence
For immunofluorescence assays (IFA), trophozoites or encysting cells cultured in growth medium or encysting medium, respectively, were harvested and washed two times with PBSm (1% growth medium in PBS, pH 7.4) and allowed to attach to multi-well slides in a humidified chamber at 37°C for 30 min. After fixation with 4% formaldehyde (Sigma, St. Louis, MO) in PBS for 40 min at room temperature, the cells were washed with PBS and blocked with 10% normal goat serum (Invitrogen, Carlsbad, CA) in 0.1% Triton X-100 in PBS for 30 min at 37°C. Cells were then incubated with the anti-HA mAb (Sigma, St. Louis, MO; dilution 1∶500) in PBS containing 3% normal goat serum and 0.1% Triton X-100 for 1 h at 37°C, followed by incubation with Alexa 546-conjugated goat anti-mouse (dilution 1∶500) secondary antibody at 37°C for 1 h. Encysting cells were also incubated with FITC-conjugated anti-CWP1 mAb (Waterborne Inc., New Orleans, LA; dilution 1∶250). Alternatively, cells were incubated with 9C3 anti-BiP mAb (marker for ER) [56] or 5D2 anti-AP2 mAb (marker for peripheral vacuoles) [57] in PBS containing 3% normal goat serum and 0.1% Triton X-100 for 1 h at 37°C, followed by incubation with Alexa 546-conjugated goat anti-mouse (dilution 1∶500) secondary antibody at 37°C for 1 h. Samples were then incubated with FITC-conjugated anti-HA mAb (Sigma, St. Louis, MO; dilution 1∶100). Preparations were stained with DAPI diluted in PBS (dilution 1∶500) (Sigma, St. Louis, MO). Finally, preparations were washed with PBS and mounted in Vectashield mounting medium (Vector Laboratories, Burlingame, CA). Fluorescence staining was visualized with a motorized FV1000 Olympus confocal microscope (Olympus UK Ltd, UK), using 63× or 100× oil immersion objectives (NA 1.32). The fluorochromes were excited using an argon laser at 488 nm and a helio-neon laser at 543 nm. Detector slits were configured to minimize any cross-talk between the channels. Differential interference contrast images were collected simultaneously with the fluorescence images, by the use of a transmitted light detector. Images were processed using Fiji software [58] and Adobe Photoshop 8.0 (Adobe Systems) software. The colocalization and deconvolution were also performed using Fiji.
Flow cytometry analysis
For the analysis of the amount of cyst yield in dhhc transgenic trophozoites by flow cytometry, the parasites were induced to encyst for 48 h. Trophozoites, encysting cells, and cysts were collected from confluent cultures. Parasites were pelleted by centrifugation at 1455 g for 15 min at 4°C, resuspended in cool sterile ddH2O and placed at 4°C overnight. Mature water-resistant cysts were then processed following the protocol for immunofluorescence (see above) without permeabilization. Briefly, parasites were washed two times with PBSm (1% growth medium in PBS, pH 7.4). After blockade with 10% normal goat serum, the parasites were labeled with anti-CWP1 mAb (Waterborne Inc, New Orleans, LA; dilution 1∶250) diluted in PBSm for 1 hour at 4°C. Cells were then washed twice in PBS and fixed with 4% formaldehyde (Sigma, St. Louis, MO) in PBS for 40 min at room temperature. Unlabeled samples were used to determine background fluorescence, and subsequently, fluorescently labeled cysts were analyzed in triplicate on a FACSCanto II flow cytometer (Becton & Dickinson, New Jersey, NY). All samples were analyzed in parallel by IFA to assess encystation efficiency.
Statistics
Results were analyzed for statistical significance (defined as p<0.05 and indicated by asterisks in figures) by performing unpaired, two-sided Student's t-test with GraphPad Prism 5 Data Analysis Software (GraphPad Software, Inc., La Jolla, CA). Mean and standard error of mean (SEM) values were calculated from at least three biologically and technically independent experiments.
Results and Discussion
Growing and encysting parasites displayed a different pattern of total palmitoylated proteins with HCNCp and VSPs being palmitoylated during growth and encystation
It has been shown that protein palmitoylation actively participates in cell differentiation in a variety of cells [59], [60], [61]. The analysis of the expression of palmitoylated proteins, using metabolic labeling with [3H] palmitic acid, showed that encysting Giardia parasites displayed a different pattern of total protein palmitoylation than growing parasites (Figure 1A, T-ET/hyd−). The results showed a band of ∼60 kDa in trophozoites that may correspond to the expressed VSPs [31] (Figure 1A, T/hyd−). However, when Giardia encysting cells were analyzed, the assay displayed a larger amount of palmitoylated proteins, as can be judged by the larger number of bands displayed compared to trophozoites (Figure 1A, ET/hyd−). When we performed neutral treatment with hydroxylamine, almost complete removal of the attached palmitates was observed in both growing and encysting parasites (Figure 1A, T-ET/hyd+). This confirms that palmitate is attached through a labile thioester linkage (S-palmitoylation) in Giardia, as has been observed in other cell types including parasites [62], being most common among palmitoylated proteins [63]. Protein S-palmitoylation reversibility makes it a flexible, rapid and precise way of protein activity regulation [64] which may be crucial in the encystation process. The fact that the amount of total S-palmitoylated proteins was higher in encysting cells compared to trophozoites suggested that this PTM may play an important role during Giardia differentiation. This observation is in accordance with previous reports showing an important role of protein S-palmitoylation in controlling several crucial processes in parasites such as invasion or motility [44]. During Giardia encystation, the cyst wall proteins (CWPs) are sorted, concentrated within encystation-specific vesicles (ESVs), and exported to the nascent cyst wall [65], [66], [67]. Thus, the larger amount of palmitoylated proteins observed in encysting parasites (Figure 1A, ET/hyd−) may be explained by this additional requirement of protein sorting and export during this stage. In addition to the CWP1, 2 and 3, another type of cyst wall protein has been identified, a High Cysteine Non-variant Cyst protein (HCNCp) [68]. HCNCp belongs to a large group of cysteine-rich, non-VSPs, Type I integral membrane proteins (HCMp) [68]. The palmitoylation prediction algorithm CSS-Palm 3.0 [69] strongly predicts that HCNCp is palmitoylated at cysteines 1602 (CSS-Palm score 6.57, high stringency cut-off 0.31) and 1603 (CSS-Palm score 4.99, high stringency cut-off 0.31), which are located in the transmembrane region and in the cytosolic tail respectively (HMMTOP, (http://www.enzim.hu/hmmtop/) [70], [71]). In order to find out whether HCNCp is palmitoylated or not, we performed the following approach: first, we expressed full length HCNCp as a fusion protein containing a C-terminal V5-tag and a tubulin promoter [39]. The expression of the ∼169 kDa HCNCp protein was equally observed in hcncp-V5 transgenic growing and encysting parasites, together with fragments of 21, 42 and 66 kDa already reported by Davids et al. [68] (Figure S1). Second, hcncp-V5 transgenic trophozoites (HCNCp T) and encysting (HCNCp ET) parasites were subjected to acyl biotin exchange (ABE) as described in Methods. Parallel plus- and minus-hydroxilamine (hyd) samples were analyzed by Western blotting using an anti-V5 mAb (Figure 1B). Only the samples that were treated with hydroxylamine had free cysteine residues able to be detected by biotin/streptavidin (see Methods). When we assayed HCNCp T purified samples, we observed three bands (169, 66 and 21 kDa) and a weak band of 42 KDa (Figure 1B, HCNCp T/hyd+). Also, the four bands (169, 66, 42, and 21 kDa) were observed for HCNCp ET purified sample compared to the control (hyd−), showing that not only the full length but also the smaller epitope-tagged fragments of the HCNCp protein were palmitoylated in encysting parasites (Figure 1B, HCNCp ET/hyd+). The presence of these four bands may account, at least in part, for the bands shown in figure 1A (Figure 1A, ET/hyd−). Although we showed that the constitutively expressed HCNCp can be palmitoylated during growth and encystation, it was clearly reported that HCNCp is almost exclusively expressed during encystation when its expression was analyzed at the mRNA and protein (expression under its own promoter) levels [68]. Altogether, these results suggest that HCNCp is likely important during encystation, while the machinery necessary for its palmitoylation remains unaltered during growth and differentiation. Despite the need of additional assays to accurately identify additional palmitoylation substrates, it seems that this PTM is more frequently founded in encysting cells compared to trophozoites. In parallel to HCNCp T and HCNCp ET samples, we also performed ABE in wild-type trophozoites and encysting parasites and analyzed the purified samples by Western blotting using anti-VSP1267 mAb (Figure 1C). The results showed the specific protein band of VSP1267 (MW ∼60 KDa), in both growing and encysting parasites, suggesting that this PTM may be important for VSP function during the entire Giardia life cycle.
(A) Giardia trophozoites (T) or encysting trophozoites (ET) were labeled with [3H]-palmitic acid and loaded onto SDS-PAGE. The gel was treated with (hyd+) or without (hyd−) the thioester cleavage reagent hydroxylamine. Samples were then analyzed by autoradiography. (B) Western blotting performed on palmitoylated proteins purified by ABE from hcncp-V5 transgenic trophozoites (HCNCp T) or hcncp-V5 transgenic encysting trophozoites (HCNCp ET). (C) Western blotting performed on palmitoylated proteins purified by ABE from wild-type trophozoites (T) or encysting parasites (ET). The approximate sizes are indicated on the right in kDa.
Further analysis using ABE or click chemistry [72] assays, together with different methods for Mass spectrometry-based proteomics, including Multidimensional protein identification technology [45], will expand our knowledge about other palmitoylated proteins in Giardia, defining the palmitoyl proteome of this parasite and shedding light on the role of this PTM in its life cycle.
Inhibition of palmitoylation during Giardia encystation yielded a low number of cysts
The fact that Giardia encysting cells displayed a large amount of palmitoylated proteins prompted us to find out whether inhibition of protein palmitoylation would influence Giardia encystation. Several compounds have been reported to block protein palmitoylation [73]. The 2-bromopalmitate (2-BP) [74] and the 2-fluoropalmitate (2-FP) [73] inhibitors are non-metabolizable palmitate analogs that block palmitate incorporation into proteins using a still unclear mechanism. These two compounds have been widely used, act as broad inhibitors of palmitate incorporation and do not appear to selectively inhibit the palmitoylation of specific protein substrates. To test the effect of these inhibitors during encystation, Giardia wild-type trophozoites were induced to encyst together with the addition of either 2-BP or 2-FP. It has been reported that 2-BP is not well tolerated by in vitro cultured cells and causes cell death even after a brief exposure to 100 µM of 2-BP [75]. Thus, a growth curve was performed to determine the optimal concentrations that do not affect Giardia growth (10, 20 or 40 µM for 2-BP and 100 µM for 2-FP), observing that trophozoites died under concentrations higher than 50 µM of 2-BP or 150 µM of 2-FP (Figure 2A). After 48 h of encystation, treated or control parasites were harvested, permeabilized, stained with anti-CWP1 mAb and analyzed by fluorescence microscopy (Figure 2B). Wild-type encysting trophozoites were classified as encysting I (EI) (corresponding to 6 h of encystation [76]), encysting II (EII) (corresponding to 12 h of encystation [76]), and cysts (corresponding to 24–48 h of encystation [76]) (Figure 2B, upper panel), based on the following features: cell shape, membrane staining, and number and size of the ESVs. As shown in figure 2B (lower panel), there was a significant reduction in the amount of cysts when parasites were treated with 2-BP (20 µM or 40 µM) or 2-FP (100 µM).
(A) Growth curves displaying optimal concentrations of 2-BP (left panel) or 2-FP (right panel) that do not affect Giardia growth. Giardia trophozoites were cultured with different concentrations of 2-BP (10, 20, 40, 50, 75 or 100 µM), 2-FP (100, 150 or 200 µM), or DMSO (control) for 48 h. The parasites were then analyzed by staining them with Trypan blue to distinguish live from dead cells and by counting them in a Neubauer chamber. The graph displays the number (mean ± SEM) of parasites counted in three independent experiments. (B) Percentage of encysting parasites and cysts after inhibition of protein palmitoylation. Giardia trophozoites were induced to encyst and 2-BP (10, 20 or 40 µM), 2-FP (100 uM) or DMSO (Control) added to the encysting media. After 48 h, the encysting parasites were stained with anti-CWP1 mAb and analyzed by fluorescence microscopy. One representative cell of each encystation state (encysting I, encysting II, cyst) is shown in the upper panel. The graph in the lower panel represents the percentage (mean + SEM) of the cells counted in each state in three independent experiments. The asterisks indicate significant difference compared with the control (Student's t test: * p<0.05; **p<0.01; ***p<0.001). (C) Number of nuclei in encysting II parasites treated with palmitoylation inhibitors. Trophozoites were induced to encyst and 2-BP (20 or 40 µM), 2-FP (100 µM) or DMSO (Control) added to the encystation media as described above. After 48 h, the encysting parasites were stained with anti-CWP1 mAb and DAPI, and analyzed by fluorescence microscopy. One representative encysting II cell is shown. Scale bars = 5 µm.
The effect of 2-BP as a generic palmitoylation inhibitor has been reported in a wide variety of cells [77], [74], [78] including parasites like Toxoplasma gondii [62], although the concentrations used were much higher than the ones we used in this work. Interestingly, with 20 and 40 µM of 2-BP, there was an increase of the encysting II parasites compared to the control, reaching its highest levels when the concentration of 2-BP was 40 µM and resulting also in a diminution of encysting I cells (Figure 2B, lower panel). Thus, the decrease in the amount of cysts may be at the expense of the arrest of the cells at the encysting II stage of differentiation. In order to find out whether the treatment with palmitoylation inhibitors affect DNA replication, we analyzed the number of nuclei in the population of EII cells that were increased, observing no differences compared to the control (Figure 2C). Although a pleiotropic effect of 2-BP cannot be excluded, it is very likely that the observed decrease in cyst formation is associated with the inhibition of palmitoylation and the subsequent defect in ESVs docking and fusion, as was shown to be the case for other cells [79], [80].
Some results have suggested that palmitoylation in cells may occur nonenzymatically, i.e. spontaneous formation of thioester linkage in the presence of palmitoyl-CoA [81]. However, studies in yeast showed that DHHC protein family-mediated palmitoylation accounted for most of the palmitoylated proteins found in this organism [79]. Therefore, we decided to explore the Giardia proteome to study the presence of DHHC proteins in this parasite.
Bioinformatics revealed the presence of nine DHHC proteins in the Giardia proteome
PATs, the discovery of which has been crucial for the enzymology of palmitoylation, are a widespread evolutionary family of proteins [16], [82] ranging from eight in Saccharomyces cerevisiae [82], twelve in Trypanosoma brucei [27], eighteen in Toxoplasma gondii [25], twelve in Plasmodium [26], [25] to twenty-three members in humans [82]. To identify the complete set of Giardia putative PATs, we performed a HMMER search against the Giardia complete proteome using a DHHC PAT HMMer profile from Pfam (zf-DHHC). As shown in figure 3A, we found nine DHHC proteins in the Giardia proteome that displayed conserved sequences when compared to other organisms: i) the DHHC-CRD domain, ii) the two short motifs DPG (aspartate-proline-glycine) and iii) TTxE (threonine-threonine-any-glutamate) motif [20], [82]. One protein (gla_8711) contained a DHYC amino acid motif, instead of the canonical DHHC motif. However, this DHYC motif has been reported to be functional in the yeast PAT Akr1 [16].
(A) Multiple Sequence alignment of DHHC proteins shows conserved regions. The amino acid sequences of the total set of Giardia DHHC proteins, Erf2 (Yeast), ZDHHC4 (Human), and PF11_0167 (Plasmodium falciparum) were aligned using T-Coffee software [104]. The conserved DHHC-CRD domain and the DPG and TTxE motifs are indicated in bold. Positions exhibiting absolute identity are shown in pink, and high and lower amino acid similarities in green and yellow, respectively. (B) Schematic representation of the primary structure of Giardia DHHC proteins. The domains were searched using SMART (http://smart.embl-heidelberg.de) [105], [106]. Transmembrane domains were predicted using TMHMM (http://www.cbs.dtu.dk/services/TMHMM) [107] and TMPred (http://www.ch.embnet.org/software/TMPRED_form.html) with default settings. Signal peptides were predicted with signalP (http://www.cbs.dtu.dk/services/SignalP) [108].
We next analyzed the molecular identity of Giardia DHHC proteins with bioinformatics tools. In agreement with previous reports for other PATs [20], [18], [25], Giardia DHHC proteins were predicted to be polytopic membrane proteins, mainly harboring between three and six TMDs with the DHHC domain facing the cytosol (Figure 3B). There is a small group of DHHC proteins, including yeast DHHC protein Akr1, displaying the conserved 33 amino acid ankyrin repeats, which are frequently involved in protein-protein interactions [83]. By contrast, none of the Giardia DHHC proteins showed ankyrin repeats in their structure. Moreover, gla_8619 displayed a coiled coil structure and gla_96562 a signal peptide. As already described for other organisms [18], [25], Giardia DHHC proteins displayed a conserved structure, sharing domains and motifs that are present across all members of this enzyme family.
The names used in this paper, GiardiaDB, NCBI, and UniProt accession numbers for Giardia DHHC proteins are indicated in table 1.
Phylogenetic analysis of Giardia DHHC proteins
In order to elucidate the phylogenetic relationship among the PATs and to infer the evolutionary history of Giardia DHHC proteins, we retrieved 1034 DHHC-CRD protein sequences from 84 completely sequenced eukaryotic genomes, including the Giardia lamblia genome (Assemblage A, isolate WB), by means of the DHHC PAT HMMer profile from Pfam (zf-DHHC). A Multiple Sequence Alignment was constructed with PROMALS3D [49], and Block Mapping and Gathering with Entropy (BMGE) [51] was used to select columns suitable for Maximum Likelihood (ML) phylogenetic inference. Maximum likelihood phylogenetic trees were calculated using PhyML [52], and Branch support was evaluated by approximate likelihood-ratio test (aLRT) [84]. The resultant phylogenetic tree can be divided in six monophyletic clades (MC), three of which together contain almost 90% of all sequences (MC D, E and F). Four MC have Giardia DHHC proteins: MC A and D contain one DHHC sequence each, while MC E and F contain five and two Giardia sequences respectively (Figure 4A and figures S2, S3, S4, S5). Without any further consideration than the topology of the tree and the early divergent phylogenetic status of Giardia, it can be argued that the Most Recent Common Ancestor of Giardia and the rest of the eukaryotic lineage (MRCA) had a minimum of four and a maximum of six groups of PATs. However, of the two Giardia-lacking MC one is almost entirely composed of Plant paralogues (MC C). Moreover, many MC contain subclades composed mostly or even only by Plant paralogues, suggesting that gene duplication have largely taken place in this group. All these can be seen as an indication of functional diversification among Plants, which also constitutes a plausible evolutionary mechanism for the origin of the MC C.
(A) Phylogenetic relationships between DHHC proteins from Giardia and several other species. Phylogenetic tree of DHHC proteins inferred from ML analyses is depicted in the left panel. Symbols correspond to aLRT values >0.7. Sequence taxonomic identity is displayed with colors (outer circle around the tree), as shown in the upper right panel. MCs are labeled as A, B, C, D, E and F. Giardia DHHC proteins are colored in red and indicated in black in the inner circle around the tree. Each Giardia DHHC protein position in the tree (MC) is indicated in the table (lower right panel). (B) Trichomonas duplicated DHHC sequences accumulate mutations. Giardia DHHC proteins are indicated in light blue, and Trichomonas DHHC proteins in yellow. Variations in the HC, C, and DHHC portions of the DHHC-CRD domain were mapped in the tree using a green-to-black-to-red color code. Full conservation is depicted in light green, while lack of conservation is shown in red. A clade of highly mutated Trichomonas sequences is displayed in red.
If we hypothesize that all DHHC sequences evolve from 4 PATs groups in the MRCA, we should be able to explain, in a parsimonious way, the MC lacking Giardia sequences as examples of evolutionary innovation. As we mentioned before, this is suitable in the case of the MC C, but not for the MC B (the other Giardia sequences-lacking MC). This is because MC B is composed of sequences from a greater variety of organisms compared to MC C, making the possibility of a common functional diversification very unlikely. Nevertheless, it is possible for the MC B to be the result of reductive evolution, meaning that Giardia lost sequences during its adaptation to a parasitic lifestyle, since the more stable environment provided by the host can cause relaxation or loss of selective constraints.
We tested gene loss across DHHC-CRD protein family by examining the heavily duplicated genomes of Trichomonas vaginalis, given that duplicated genes are most likely to be released from functional constraints (Figure 4B). For this, we retrieved all DHHC sequences from Trichomonas (http://trichdb.org/trichdb/) using the same pipeline described above, except that this time no sequences were excluded from the posterior analysis. Variations in the HC, C and DHHC portions of the DHHC-CRD domain were extracted from the MSA, and mapped onto a phylogenetic tree. Contrary to what is found in Plants, there is a substantial presence of poorly conserved sequences among Trichomonas genome that cluster together in the tree. Moreover, we found a strong correlation between the degree of conservation in the HC, C and DHHC portions of the DHHC-CRD domain within each sequence.
Altogether, our findings suggest that the MRCA had five groups of DHHC sequences from which the other sequences eventually evolved by functional diversification, and that Giardia lost at least one representative sequence presumably during its adaptation to a parasitic lifestyle.
We also determined the orthology relationships between sequences from different assemblages. For this, we retrieved DHHC sequences from Giardia isolates WB, GS and P15 (Assemblages A, B and E, respectively; http://giardiadb.org/giardiadb/), following the pipeline described above. As expected, every DHHC sequence in the isolate WB has a highly similar ortholog in the other isolates, which cluster together in the tree (Figure 5). Only one WB sequence, EAA36893, escapes this pattern, but this probably constitutes a case of defective annotation in isolates GS and P15.
Phylogenetic tree of Giardia DHHC sequences from the three isolates inferred from ML analyses is depicted. Each isolate is indicated with a different color.
DHHC proteins were expressed in trophozoites and encysting cells
Semi-quantitative RT-PCR indicated that all the dhhc genes were expressed in trophozoites and in encysting parasites (Figure S6). This prompted us to explore further the expression levels of these genes in growing and encysting parasites by performing qRT-PCR analysis of mRNA expression from these cells. As shown in figure 6, many of the dhhc transcripts were present at relatively constant levels, but gla_8619, gla_1908, and EAA36893 were downregulated in encysting parasites while gla_2116 was upregulated in 48 h encysting cells. Considering that Giardia contains minimal systems, either as a result of reductive processes associated with a parasitic lifestyle, as a reflection of basic evolutionary characteristics, or both [85], [86], the fact that the nine dhhc genes found by bioinformatics were expressed in vegetative and encysting parasites suggests that protein palmitoylation and the PATs themselves may be playing a key role during the entire life cycle of this parasite.
Expression of gla_8619, gla_1908, gla_8711, EAA36893, gla_9529, gla_16928, gla_6733, gla_96562, gla_2116 transcripts from 48 h encysting parasites (white bars) relative to the expression in growing parasites (black bars). The data are the means and SEM of three separate experiments, and each experiment was carried out in triplicate. The qRT-PCR analysis of dhhc genes was performed as described in Methods. The asterisks indicate that there was significant difference compared with growing parasites (Student's t test: * p<0.05; **p<0.01; ***p<0.001).
We next sought to characterize four of the nine DHHC proteins that are expressed in Giardia based on their expression profile. We chose two that are expressed at similar levels in growing and encysting parasites (gla_8711 and gla_16928), one that is downregulated during encystation (gla_1908), and one that is upregulated in encysting parasites (gla_2116).
DHHC proteins gla_1908, gla_2116, gla_16928, gla_8711 displayed a different intracellular localization
To further analyze these DHHC proteins, we expressed full-length gla_1908, gla_2116, gla_16928 and gla_8711 as fusion DHHC proteins containing C-terminal HA-tag [39] and evaluated their protein expression profiles by Western blotting using an anti-HA mAb (Figure 7). Analysis by semi-quantitative RT-PCR indicated that the overexpression of these fusion proteins was 2 to 3-times higher in transgenic cells, as reported for protein expression using a similar vector [9]. Immunofluorescence assays showed that HA-tagged gla_1908, gla_2116, and gla_16928 partially co-localized with BiP in the endoplasmic reticulum (ER) or around the nuclei of transgenic trophozoites (Figure 8, trophozoite). Our results confirmed the localization of gla_16928 already shown by Touz et al. [31]. Analysis of intracellular localization of yeast and mammalian DHHC proteins revealed that the majority of these localize to the ER and Golgi [20], [87]. However, there are a few exceptions, including human DHHC5 protein [87] and Giardia DHHC protein (EAA36893) [31], which localize to the plasma membrane. Also, we found that gla_8711 partially co-localized with the adaptor protein AP-2 [57] at the lysosomal-like peripheral vacuoles (PVs) as well as in plasma membrane and flagella (Figure 8, trophozoite). Ongoing experiments intended to knock-down this protein may reveal its importance during the Giardia life cycle.
Western blotting performed on total protein extracts from dhhc-ha transgenic trophozoites. Expected sizes are indicated in brackets. Relative molecular weights of protein standards (kDa) are indicated on the left.
Subcellular localization of gla_1908-HA (A), gla_2116-HA (B), gla_16928-HA (C), or gla_8711-HA (D) in trophozoites or encysting parasites. For trophozoites, gla_1908-HA, gla_2116-HA or gla_16928-HA were stained with anti-BiP (ER) mAb, anti-HA mAb and DAPI; gla_8711-HA was stained with anti-AP2 (PVs) mAb, anti-HA mAb and DAPI. For encysting parasites, after 48 h of encystation dhhc-ha transgenic parasites were stained with anti-HA mAb, anti-CWP1 mAb and DAPI. The cells were analyzed by fluorescence microscopy. One representative cell from each stage is shown. Yellow areas in trophozoites indicate co-localization between DHHC-HA and ER (gla_1908-HA, gla_2116-HA or gla_16928-HA), or between DHHC-HA and PVs (gla_8711-HA). Yellow areas in encysting parasites indicate co-localization between DHHC-HA and CWP1. The inset in C (gla_16928 transgenic encysting II parasites) corresponds to the zoomed area indicated by the lined box. Scale bars = 5 µm.
The overexpression of the DHHC proteins disclosed a differential involvement during encystation
The hallmark of encystation in Giardia is the synthesis of CWP1, CWP2, and CWP3 [88]. These proteins are expressed and concentrated within the ESVs before they are targeted to the cyst wall [89], [6], [90]. To address the influence of the overexpression of these HA-tagged DHHC proteins during encystation, dhhc-ha transgenic trophozoites were induced to encyst in vitro. The localization of DHHC-HA proteins as well as CWP1 expression, intracellular localization, and vesicle formation were addressed by IFA. To examine in detail the results obtained, we decided to analyze each dhhc-ha transgenic cell following the protocol described above, in which the cells were classified as encysting I, encysting II, and early cyst. We observed that gla_1908 (Figure 8A), gla_2116 (Figure 8B), and gla_8711 (Figure 8D) transgenic parasites displayed normal encystation. It was noteworthy that gla_16928 (Figure 8C) had enlarged ESVs, with co-localization between gla_16928-HA and CWP1 observed in those vesicles (Figure 8C, inset). Additionally, it was noted that gla_16928 early cysts had a larger size and an abnormal shape compared with wild-type cells (not shown) and other transgenic early cysts.
When CWP expression was analyzed in dhhc transgenic parasites by qRT-PCR, we observed that, except for gla_2116 transgenic cells, which displayed similar levels or even moderate decrease in the mRNA expression of CWPs compared to the control, the other dhhc-ha transgenic parasites showed increased expression of CWP1, CWP2, and CWP3 (Figure 9A). Several transcription factors have been described as involved in the regulation of cwp gene transcription [91], [92], [93], [94], [95], [96], [97]. However, the mechanisms underlying transcription control in this parasite have not been completely elucidated. It has always been assumed that the mobilization mechanism for transcription factors in many organisms is based on proteolytic processing [98], [99], [100], [101]. Nevertheless, there is a group of lipid-modified transcription factors whose mobilization mechanism to the nucleus is not based on proteolytic processing but on reversible palmitoylation [102]. If that were the case for the transcription factors involved in Giardia encystation, DHHC proteins would be palmitoylating different transcriptions factors that, in turn, may regulate CWP expression. It would be interesting to explore the molecular architecture of Giardia transcription factors to find out whether palmitoylation is involved in regulating their shuttling between the cytoplasm and the nuclei.
(A) qRT-PCR analysis of cwp1, cwp2, and cwp3 transcripts expression in dhhc transgenic parasites after 48 h of encystation (white bars), relative to the expression in wild-type encysting cells (control) (black bars). The data are the means and SEM of three separate experiments, and each experiment was carried out in triplicate. (B) Percentage of water-resistant cysts in dhhc transgenic parasites determined by flow cytometry after 48 h of encystation. The results are presented as the percentage (mean ± SEM) of cysts in three independent experiments. The asterisks indicate that there was significant difference compared with the control (Student's t test: * p<0.05; **p<0.01; ***p<0.001).
Analyzing the amount of water-resistant cysts, we observed that gla_1908 and gla_8711 transgenic cells yielded a significantly higher amount of cysts than the control (Figure 9B). In contrast, gla_2116 transgenic cells, while displaying an apparently normal encystation process (Figure 8B) and CWP expression (Figure 9A), produced a reduced number of mature cysts (Figure 9B). A likely explanation is that gla_2116 may be involved in the palmitoylation of a protein in charge of turning encystation-specific genes off and ending the encystation process. In the case of gla_16928 transgenic parasites, these cells produced a low percentage of cysts (Figure 9B) although the CWP expression was increased (Figure 9A). These findings, in addition to the large ESVs seen in figure 8C (encysting II) and the large size of early cysts (Figure 8C, early cyst), may be explained by a high rate of synthesis of CWPs in gla_16928 transgenic parasites, which may exceed the mechanisms of vesicle discharge regulation, leading to the formation of immature non-water-resistant cysts. Further experiments using knock-down strategies are needed to completely address the role of each DHHC protein in the encystation process. Table 2 summarizes the main features of the Giardia DHHC proteins analyzed in this work.
The different localization of DHHC-HA proteins in trophozoites and the differential effect of DHHC overexpression in encystation prompted us to evaluate the palmitoylation pattern in the dhhc transgenic parasites (Figure 10). gla_1908, gla_2116, gla_16928, and gla_8711 transgenic trophozoites or encysting parasites displayed a similar global protein palmitoylation pattern compared to wild type (Figure 1A). Mass spectrometry-based proteomics analyses will be necessary to accurately identify any differences in the palmitoylation substrates among the dhhc transgenic parasites.
Giardia trophozoites (T) or encysting trophozoites (ET) were labeled with [3H]-palmitic acid and loaded onto SDS-PAGE. Samples were then analyzed by autoradiography. The approximate sizes are indicated on the right in kDa.
Conclusion
This work presents a detailed analysis of Giardia lamblia DHHC protein structure and phylogeny and reveals a possible role of palmitoylation in Giardia encystation. Our data, suggesting the presence of DHHC proteins in growing and encysting parasites, reinforced the idea that this PTM has conserved and important functions in cell-signaling, protein-sorting and protein-export throughout evolution. Without being able to assign a specific substrate candidate to each Giardia DHHC proteins, we showed that overexpression of these enzymes had consequences on CWP expression and on the amount of cysts produced. Proteomic analysis of Giardia palmitoyl proteome would be a great contribution to elucidating the mechanisms by which palmitoylation participates in encystation biology. Finally, the suggested role of palmitoylation in Giardia encystation, a key event that enables the parasite to survive in the environment, infect a new host and evade the immune response [1], [103], could open new ways to intervene in the process of Giardia infection.
Supporting Information
Figure S1.
Expression of HCNCp-V5 in Giardia growing and encysting parasites. Western blotting performed on total protein extracts from hcncp-V5 transgenic trophozoites (T) or hcncp-V5 transgenic encysting trophozoites (ET). Expected size is indicated in brackets. Relative molecular weights of protein standards (kDa) are indicated on the left.
https://doi.org/10.1371/journal.pntd.0002997.s001
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Figure S2.
The zoomed subclade containing gla_8619, gla_6733, gla_1908, and gla_8711 (A) or EAA36893 (B) from the phylogenetic tree presented in figure 4. Sequence taxonomic identity is displayed with colors as described in figure 4.
https://doi.org/10.1371/journal.pntd.0002997.s002
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Figure S3.
The zoomed subclade containing gla_9529 from the phylogenetic tree presented in figure 4. Sequence taxonomic identity is displayed with colors as described in figure 4.
https://doi.org/10.1371/journal.pntd.0002997.s003
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Figure S4.
The zoomed subclade containing gla_16928 (A) or gla_96562 (B) from the phylogenetic tree presented in figure 4. Sequence taxonomic identity is displayed with colors as described in figure 4.
https://doi.org/10.1371/journal.pntd.0002997.s004
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Figure S5.
The zoomed subclade containing gla_2116 from the phylogenetic tree presented in figure 4. Sequence taxonomic identity is displayed with colors as described in figure 4.
https://doi.org/10.1371/journal.pntd.0002997.s005
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Figure S6.
Differential expressions of Giardia dhhc genes in trophozoites and encysting parasites by semiquantitative RT-PCR. Expression of gla_8619, gla_1908, gla_8711, EAA36893, gla_9529, gla_16928, gla_6733, gla_96562, gla_2116 transcripts from growing parasites (upper panel) and 48 h encysting parasites (lower panel). Expression of glutamate dehydrogenase (gdh) mRNA fragment was tested as positive control. Expected sizes are indicated in brackets. Relative molecular weights of standards (bp) are indicated on the left.
https://doi.org/10.1371/journal.pntd.0002997.s006
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Table S1.
Oligonucleotide primers used for Giardia DHHC cloning.
https://doi.org/10.1371/journal.pntd.0002997.s007
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Table S2.
Oligonucleotide primers used for semiquantitative RT-PCR.
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Table S3.
Oligonucleotide primers used for qRT-PCR.
https://doi.org/10.1371/journal.pntd.0002997.s009
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Acknowledgments
We thank Dr Maria M. Corvi (IIB-INTECH, National Council for Sciences and Technology (CONICET)-Universidad Nacional de San Martin), and Sabrina Chumpen and Dr Javier Valdez-Taubas (CIQUIBIC-CONICET-Universidad Nacional de Cordoba) for their helpful advice on palmitoylation assay and acyl-biotin exchange. We are also grateful to Constanza Feliziani, Carla Cisternas and Florencia Dadam (IMMF-CONICET) for useful technical assistance on qRT-PCR assays.
Author Contributions
Conceived and designed the experiments: MCM ASR. Performed the experiments: MCM NZ CVV. Analyzed the data: MCM NZ CVV MCT ASR. Contributed reagents/materials/analysis tools: MCM MCT ASR. Wrote the paper: MCM ASR.
References
- 1. Adam RD (2001) Biology of Giardia lamblia. Clin Microbiol Rev 14: 447–475.
- 2. Birkeland SR, Preheim SP, Davids BJ, Cipriano MJ, Palm D, et al. (2010) Transcriptome analyses of the Giardia lamblia life cycle. Mol Biochem Parasitol 174: 62–65.
- 3. Morf L, Spycher C, Rehrauer H, Fournier CA, Morrison HG, et al. (2010) The transcriptional response to encystation stimuli in Giardia lamblia is restricted to a small set of genes. Eukaryot Cell 9: 1566–1576.
- 4. Slavin I, Saura A, Carranza PG, Touz MC, Nores MJ, et al. (2002) Dephosphorylation of cyst wall proteins by a secreted lysosomal acid phosphatase is essential for excystation of Giardia lamblia. Mol Biochem Parasitol 122: 95–98.
- 5. Sonda S, Morf L, Bottova I, Baetschmann H, Rehrauer H, et al. (2010) Epigenetic mechanisms regulate stage differentiation in the minimized protozoan Giardia lamblia. Mol Microbiol 76: 48–67.
- 6. Reiner DS, McCaffery JM, Gillin FD (2001) Reversible interruption of Giardia lamblia cyst wall protein transport in a novel regulated secretory pathway. Cell Microbiol England 459–472.
- 7. Touz MC, Nores MJ, Slavin I, Carmona C, Conrad JT, et al. (2002) The activity of a developmentally regulated cysteine proteinase is required for cyst wall formation in the primitive eukaryote Giardia lamblia. J Biol Chem United States 8474–8481.
- 8. Davids BJ, Mehta K, Fesus L, McCaffery JM, Gillin FD (2004) Dependence of Giardia lamblia encystation on novel transglutaminase activity. Mol Biochem Parasitol 136: 173–180.
- 9. Touz MC, Ropolo AS, Rivero MR, Vranych CV, Conrad JT, et al. (2008) Arginine deiminase has multiple regulatory roles in the biology of Giardia lamblia. J Cell Sci England 2930–2938.
- 10. Linder ME, Deschenes RJ (2007) Palmitoylation: policing protein stability and traffic. Nat Rev Mol Cell Biol England 74–84.
- 11. Fukata Y, Fukata M (2010) Protein palmitoylation in neuronal development and synaptic plasticity. Nat Rev Neurosci England 161–175.
- 12. Greaves J, Chamberlain LH (2007) Palmitoylation-dependent protein sorting. J Cell Biol United States 249–254.
- 13. Magee AI, Gutierrez L, McKay IA, Marshall CJ, Hall A (1987) Dynamic fatty acylation of p21N-ras. EMBO J 6: 3353–3357.
- 14. Rocks O, Peyker A, Kahms M, Verveer PJ, Koerner C, et al. (2005) An acylation cycle regulates localization and activity of palmitoylated Ras isoforms. Science United States 1746–1752.
- 15. Bartels DJ, Mitchell DA, Dong X, Deschenes RJ (1999) Erf2, a novel gene product that affects the localization and palmitoylation of Ras2 in Saccharomyces cerevisiae. Mol Cell Biol 19: 6775–6787.
- 16. Roth AF, Feng Y, Chen L, Davis NG (2002) The yeast DHHC cysteine-rich domain protein Akr1p is a palmitoyl transferase. J Cell Biol United States 23–28.
- 17. Lobo S, Greentree WK, Linder ME, Deschenes RJ (2002) Identification of a Ras palmitoyltransferase in Saccharomyces cerevisiae. J Biol Chem United States 41268–41273.
- 18. Linder ME, Jennings BC (2013) Mechanism and function of DHHC S-acyltransferases. Biochem Soc Trans England 29–34.
- 19. Mitchell DA, Mitchell G, Ling Y, Budde C, Deschenes RJ (2010) Mutational analysis of Saccharomyces cerevisiae Erf2 reveals a two-step reaction mechanism for protein palmitoylation by DHHC enzymes. J Biol Chem United States 38104–38114.
- 20. Politis EG, Roth AF, Davis NG (2005) Transmembrane topology of the protein palmitoyl transferase Akr1. J Biol Chem United States 10156–10163.
- 21. Fukata M, Fukata Y, Adesnik H, Nicoll RA, Bredt DS (2004) Identification of PSD-95 palmitoylating enzymes. Neuron United States 987–996.
- 22. Greaves J, Chamberlain LH (2011) DHHC palmitoyl transferases: substrate interactions and (patho)physiology. Trends Biochem Sci England 245–253.
- 23. Batistic O (2012) Genomics and localization of the Arabidopsis DHHC-cysteine-rich domain S-acyltransferase protein family. Plant Physiol United States 1597–1612.
- 24. Beck JR, Fung C, Straub KW, Coppens I, Vashisht AA, et al. (2013) A Toxoplasma palmitoyl acyl transferase and the palmitoylated Armadillo Repeat protein TgARO govern apical rhoptry tethering and reveal a critical role for the rhoptries in host cell invasion but not egress. PLoS Pathog United States e1003162.
- 25. Frenal K, Tay CL, Mueller C, Bushell ES, Jia Y, et al. (2013) Global analysis of apicomplexan protein S-acyl transferases reveals an enzyme essential for invasion. Traffic 14: 895–911.
- 26. Jones ML, Tay CL, Rayner JC (2012) Getting stuck in: protein palmitoylation in Plasmodium. Trends Parasitol 28: 496–503.
- 27. Emmer BT, Souther C, Toriello KM, Olson CL, Epting CL, et al. (2009) Identification of a palmitoyl acyltransferase required for protein sorting to the flagellar membrane. J Cell Sci England 867–874.
- 28. Saric M, Vahrmann A, Niebur D, Kluempers V, Hehl AB, et al. (2009) Dual acylation accounts for the localization of {alpha}19-giardin in the ventral flagellum pair of Giardia lamblia. Eukaryot Cell United States 1567–1574.
- 29. Papanastasiou P, McConville MJ, Ralton J, Kohler P (1997) The variant-specific surface protein of Giardia, VSP4A1, is a glycosylated and palmitoylated protein. Biochem J 322(Pt 1): 49–56.
- 30. Hiltpold A, Frey M, Hulsmeier A, Kohler P (2000) Glycosylation and palmitoylation are common modifications of giardia variant surface proteins. Mol Biochem Parasitol Netherlands 61–65.
- 31. Touz MC, Conrad JT, Nash TE (2005) A novel palmitoyl acyl transferase controls surface protein palmitoylation and cytotoxicity in Giardia lamblia. Mol Microbiol England 999–1011.
- 32. Nash TE, Mowatt MR (1992) Identification and characterization of a Giardia lamblia group-specific gene. Exp Parasitol 75: 369–378.
- 33. Carranza PG, Feltes G, Ropolo A, Quintana SM, Touz MC, et al. (2002) Simultaneous expression of different variant-specific surface proteins in single Giardia lamblia trophozoites during encystation. Infect Immun 70: 5265–5268.
- 34. Greaves J, Prescott GR, Gorleku OA, Chamberlain LH (2009) The fat controller: roles of palmitoylation in intracellular protein trafficking and targeting to membrane microdomains (Review). Mol Membr Biol 26: 67–79.
- 35. Salaun C, Greaves J, Chamberlain LH (2010) The intracellular dynamic of protein palmitoylation. J Cell Biol 191: 1229–1238.
- 36. Aicart-Ramos C, Valero RA, Rodriguez-Crespo I (2011) Protein palmitoylation and subcellular trafficking. Biochim Biophys Acta 1808: 2981–2994.
- 37. Nash TE, Aggarwal A, Adam RD, Conrad JT, Merritt JW Jr (1988) Antigenic variation in Giardia lamblia. J Immunol 141: 636–641.
- 38. Keister DB (1983) Axenic culture of Giardia lamblia in TYI-S-33 medium supplemented with bile. Trans R Soc Trop Med Hyg 77: 487–488.
- 39. Touz MC, Lujan HD, Hayes SF, Nash TE (2003) Sorting of encystation-specific cysteine protease to lysosome-like peripheral vacuoles in Giardia lamblia requires a conserved tyrosine-based motif. J Biol Chem United States 6420–6426.
- 40. Yee J, Nash TE (1995) Transient transfection and expression of firefly luciferase in Giardia lamblia. Proc Natl Acad Sci U S A 92: 5615–5619.
- 41. Singer SM, Yee J, Nash TE (1998) Episomal and integrated maintenance of foreign DNA in Giardia lamblia. Mol Biochem Parasitol Netherlands 59–69.
- 42. Elmendorf HG, Singer SM, Pierce J, Cowan J, Nash TE (2001) Initiator and upstream elements in the alpha2-tubulin promoter of Giardia lamblia. Mol Biochem Parasitol Netherlands 157–169.
- 43. Boucher SE, Gillin FD (1990) Excystation of in vitro-derived Giardia lamblia cysts. Infect Immun 58: 3516–3522.
- 44. Corvi MM, Soltys CL, Berthiaume LG (2001) Regulation of mitochondrial carbamoyl-phosphate synthetase 1 activity by active site fatty acylation. J Biol Chem United States 45704–45712.
- 45. Wan J, Roth AF, Bailey AO, Davis NG (2007) Palmitoylated proteins: purification and identification. Nat Protoc England 1573–1584.
- 46. Punta M, Coggill PC, Eberhardt RY, Mistry J, Tate J, et al. (2012) The Pfam protein families database. Nucleic Acids Res England D290–301.
- 47. Finn RD, Clements J, Eddy SR (2011) HMMER web server: interactive sequence similarity searching. Nucleic Acids Res England W29–37.
- 48. Huang Y, Niu B, Gao Y, Fu L, Li W (2010) CD-HIT Suite: a web server for clustering and comparing biological sequences. Bioinformatics England 680–682.
- 49. Pei J, Tang M, Grishin NV (2008) PROMALS3D web server for accurate multiple protein sequence and structure alignments. Nucleic Acids Res England W30–34.
- 50. Nicholas KB, Nicholas HB Jr, Deerfield DW II (1997) GeneDoc: Analysis and Visualization of Genetic Variation. EMBNEWNEWS 4: 14.
- 51. Criscuolo A, Gribaldo S (2010) BMGE (Block Mapping and Gathering with Entropy): a new software for selection of phylogenetic informative regions from multiple sequence alignments. BMC Evol Biol England 210.
- 52. Guindon S, Dufayard JF, Lefort V, Anisimova M, Hordijk W, et al. (2010) New algorithms and methods to estimate maximum-likelihood phylogenies: assessing the performance of PhyML 3.0. Syst Biol England 307–321.
- 53. Abascal F, Zardoya R, Posada D (2005) ProtTest: selection of best-fit models of protein evolution. Bioinformatics England 2104–2105.
- 54. Letunic I, Bork P (2011) Interactive Tree Of Life v2: online annotation and display of phylogenetic trees made easy. Nucleic Acids Res England W475–478.
- 55. Livak KJ, Schmittgen TD (2001) Analysis of relative gene expression data using real-time quantitative PCR and the 2(-Delta Delta C(T)) Method. Methods United States 402–408.
- 56. Lujan HD, Mowatt MR, Conrad JT, Nash TE (1996) Increased expression of the molecular chaperone BiP/GRP78 during the differentiation of a primitive eukaryote. Biol Cell 86: 11–18.
- 57. Rivero MR, Vranych CV, Bisbal M, Maletto BA, Ropolo AS, et al. (2010) Adaptor protein 2 regulates receptor-mediated endocytosis and cyst formation in Giardia lamblia. Biochem J 428: 33–45.
- 58. Schindelin J, Arganda-Carreras I, Frise E, Kaynig V, Longair M, et al. (2012) Fiji: an open-source platform for biological-image analysis. Nat Methods United States 676–682.
- 59. Leong WF, Zhou T, Lim GL, Li B (2009) Protein palmitoylation regulates osteoblast differentiation through BMP-induced osterix expression. PLoS One 4: e4135.
- 60. Zhang MM, Wu PY, Kelly FD, Nurse P, Hang HC (2013) Quantitative control of protein S-palmitoylation regulates meiotic entry in fission yeast. PLoS Biol United States e1001597.
- 61. Jones ML, Collins MO, Goulding D, Choudhary JS, Rayner JC (2012) Analysis of protein palmitoylation reveals a pervasive role in Plasmodium development and pathogenesis. Cell Host Microbe United States 246–258.
- 62. De Napoli MG, de Miguel N, Lebrun M, Moreno SN, Angel SO, et al. (2013) N-terminal palmitoylation is required for Toxoplasma gondii HSP20 inner membrane complex localization. Biochim Biophys Acta 1833: 1329–1337.
- 63. Tsutsumi R, Fukata Y, Fukata M (2008) Discovery of protein-palmitoylating enzymes. Pflugers Arch 456: 1199–1206.
- 64. Dunphy JT, Linder ME (1998) Signalling functions of protein palmitoylation. Biochim Biophys Acta 1436: 245–261.
- 65. Reiner DS, McCaffery M, Gillin FD (1990) Sorting of cyst wall proteins to a regulated secretory pathway during differentiation of the primitive eukaryote, Giardia lamblia. Eur J Cell Biol 53: 142–153.
- 66. Lujan HD, Marotta A, Mowatt MR, Sciaky N, Lippincott-Schwartz J, et al. (1995) Developmental induction of Golgi structure and function in the primitive eukaryote Giardia lamblia. J Biol Chem 270: 4612–4618.
- 67. Hehl AB, Marti M, Kohler P (2000) Stage-specific expression and targeting of cyst wall protein-green fluorescent protein chimeras in Giardia. Mol Biol Cell 11: 1789–1800.
- 68. Davids BJ, Reiner DS, Birkeland SR, Preheim SP, Cipriano MJ, et al. (2006) A new family of giardial cysteine-rich non-VSP protein genes and a novel cyst protein. PLoS One 1: e44.
- 69. Ren J, Wen L, Gao X, Jin C, Xue Y, et al. (2008) CSS-Palm 2.0: an updated software for palmitoylation sites prediction. Protein Eng Des Sel England 639–644.
- 70. Tusnady GE, Simon I (1998) Principles governing amino acid composition of integral membrane proteins: application to topology prediction. J Mol Biol 283: 489–506.
- 71. Tusnady GE, Simon I (2001) The HMMTOP transmembrane topology prediction server. Bioinformatics 17: 849–850.
- 72. Martin BR, Cravatt BF (2009) Large-scale profiling of protein palmitoylation in mammalian cells. Nat Methods United States 135–138.
- 73. DeJesus G, Bizzozero OA (2002) Effect of 2-fluoropalmitate, cerulenin and tunicamycin on the palmitoylation and intracellular translocation of myelin proteolipid protein. Neurochem Res 27: 1669–1675.
- 74. Jennings BC, Nadolski MJ, Ling Y, Baker MB, Harrison ML, et al. (2009) 2-Bromopalmitate and 2-(2-hydroxy-5-nitro-benzylidene)-benzo[b]thiophen-3-one inhibit DHHC-mediated palmitoylation in vitro. J Lipid Res United States 233–242.
- 75. Planey SL (2013) Discovery of Selective and Potent Inhibitors of Palmitoylation.
- 76. Faso C, Bischof S, Hehl AB (2013) The proteome landscape of Giardia lamblia encystation. PLoS One 8: e83207.
- 77. Webb Y, Hermida-Matsumoto L, Resh MD (2000) Inhibition of protein palmitoylation, raft localization, and T cell signaling by 2-bromopalmitate and polyunsaturated fatty acids. J Biol Chem 275: 261–270.
- 78. Resh MD (2006) Use of analogs and inhibitors to study the functional significance of protein palmitoylation. Methods United States 191–197.
- 79. Roth AF, Wan J, Bailey AO, Sun B, Kuchar JA, et al. (2006) Global analysis of protein palmitoylation in yeast. Cell United States 1003–1013.
- 80. He Y, Linder ME (2009) Differential palmitoylation of the endosomal SNAREs syntaxin 7 and syntaxin 8. J Lipid Res United States 398–404.
- 81. Duncan JA, Gilman AG (1996) Autoacylation of G protein alpha subunits. J Biol Chem 271: 23594–23600.
- 82. Mitchell DA, Vasudevan A, Linder ME, Deschenes RJ (2006) Protein palmitoylation by a family of DHHC protein S-acyltransferases. J Lipid Res United States 1118–1127.
- 83. Smotrys JE, Linder ME (2004) Palmitoylation of intracellular signaling proteins: regulation and function. Annu Rev Biochem 73: 559–587.
- 84. Anisimova M, Gascuel O (2006) Approximate likelihood-ratio test for branches: A fast, accurate, and powerful alternative. Syst Biol England 539–552.
- 85. Lloyd D, Harris JC (2002) Giardia: highly evolved parasite or early branching eukaryote? Trends Microbiol England 122–127.
- 86. Morrison HG, McArthur AG, Gillin FD, Aley SB, Adam RD, et al. (2007) Genomic minimalism in the early diverging intestinal parasite Giardia lamblia. Science United States 1921–1926.
- 87. Ohno Y, Kihara A, Sano T, Igarashi Y (2006) Intracellular localization and tissue-specific distribution of human and yeast DHHC cysteine-rich domain-containing proteins. Biochim Biophys Acta Netherlands 474–483.
- 88. Gillin FD, Reiner DS, McCaffery JM (1996) Cell biology of the primitive eukaryote Giardia lamblia. Annu Rev Microbiol 50: 679–705.
- 89. Gottig N, Elias EV, Quiroga R, Nores MJ, Solari AJ, et al. (2006) Active and passive mechanisms drive secretory granule biogenesis during differentiation of the intestinal parasite Giardia lamblia. J Biol Chem United States 18156–18166.
- 90. Sun CH, McCaffery JM, Reiner DS, Gillin FD (2003) Mining the Giardia lamblia genome for new cyst wall proteins. J Biol Chem United States 21701–21708.
- 91. Wang CH, Su LH, Sun CH (2007) A novel ARID/Bright-like protein involved in transcriptional activation of cyst wall protein 1 gene in Giardia lamblia. J Biol Chem United States 8905–8914.
- 92. Huang YC, Su LH, Lee GA, Chiu PW, Cho CC, et al. (2008) Regulation of cyst wall protein promoters by Myb2 in Giardia lamblia. J Biol Chem United States 31021–31029.
- 93. Su LH, Pan YJ, Huang YC, Cho CC, Chen CW, et al. (2011) A novel E2F-like protein involved in transcriptional activation of cyst wall protein genes in Giardia lamblia. J Biol Chem United States 34101–34120.
- 94. Chuang SF, Su LH, Cho CC, Pan YJ, Sun CH (2012) Functional redundancy of two Pax-like proteins in transcriptional activation of cyst wall protein genes in Giardia lamblia. PLoS One United States e30614.
- 95. Pan YJ, Cho CC, Kao YY, Sun CH (2009) A novel WRKY-like protein involved in transcriptional activation of cyst wall protein genes in Giardia lamblia. J Biol Chem United States 17975–17988.
- 96. Worgall TS, Davis-Hayman SR, Magana MM, Oelkers PM, Zapata F, et al. (2004) Sterol and fatty acid regulatory pathways in a Giardia lamblia-derived promoter: evidence for SREBP as an ancient transcription factor. J Lipid Res United States 981–988.
- 97. Sun CH, Su LH, Gillin FD (2006) Novel plant-GARP-like transcription factors in Giardia lamblia. Mol Biochem Parasitol Netherlands 45–57.
- 98. Brown MS, Ye J, Rawson RB, Goldstein JL (2000) Regulated intramembrane proteolysis: a control mechanism conserved from bacteria to humans. Cell United States 391–398.
- 99. Hoppe T, Matuschewski K, Rape M, Schlenker S, Ulrich HD, et al. (2000) Activation of a membrane-bound transcription factor by regulated ubiquitin/proteasome-dependent processing. Cell United States 577–586.
- 100. Ebinu JO, Yankner BA (2002) A RIP tide in neuronal signal transduction. Neuron United States 499–502.
- 101. Stoven S, Silverman N, Junell A, Hedengren-Olcott M, Erturk D, et al. (2003) Caspase-mediated processing of the Drosophila NF-kappaB factor Relish. Proc Natl Acad Sci U S A United States 5991–5996.
- 102. Eisenhaber B, Sammer M, Lua WH, Benetka W, Liew LL, et al. (2011) Nuclear import of a lipid-modified transcription factor: mobilization of NFAT5 isoform a by osmotic stress. Cell Cycle United States 3897–3911.
- 103. Lauwaet T, Davids BJ, Reiner DS, Gillin FD (2007) Encystation of Giardia lamblia: a model for other parasites. Curr Opin Microbiol England 554–559.
- 104. Notredame C, Higgins DG, Heringa J (2000) T-Coffee: A novel method for fast and accurate multiple sequence alignment. J Mol Biol 302: 205–217.
- 105. Letunic I, Doerks T, Bork P (2012) SMART 7: recent updates to the protein domain annotation resource. Nucleic Acids Res England D302–305.
- 106. Schultz J, Milpetz F, Bork P, Ponting CP (1998) SMART, a simple modular architecture research tool: identification of signaling domains. Proc Natl Acad Sci U S A 95: 5857–5864.
- 107. Krogh A, Larsson B, von Heijne G, Sonnhammer EL (2001) Predicting transmembrane protein topology with a hidden Markov model: application to complete genomes. J Mol Biol England 567–580.
- 108. Petersen TN, Brunak S, von Heijne G, Nielsen H (2011) SignalP 4.0: discriminating signal peptides from transmembrane regions. Nat Methods United States 785–786.
- 109. Aurrecoechea C, Brestelli J, Brunk BP, Carlton JM, Dommer J, et al. (2009) GiardiaDB and TrichDB: integrated genomic resources for the eukaryotic protist pathogens Giardia lamblia and Trichomonas vaginalis. Nucleic Acids Res England D526–530.