Michael R. Mowatt

DEVELOPMENTALLY REGULATED EXPRESSION OF A GIARDIA LAMBLIA CYST WALL PROTEIN GENE

The protozoan Giardia lamblia is an obligate parasite of the mammalian small intestine. We studied the expression of a gene that encodes a protein component of the cyst wall, a complex structure assembled during the differentiation of trophozoites to cysts and which is critical to survival of the parasite outside its mammalian host. Transcripts from the cyst wall protein gene increase more than 100‐fold during encystation, reaching a maximum between 5 and 24 hours after induction. Cyst wall protein expression also increases dramatically during encystation, and, prior to its incorporation into the nascent cyst wall, the protein is contained within the encystation‐specific vesicles of encysting trophozoites. The sequence of the cloned gene predicts an acidic, leucine‐rich polypeptide of Mr, 26000 that contains 5.3 tandemly arranged copies of a degenerate 24‐amino‐acid repeat. A hydrophobic amino‐terminal peptide probably serves as the initial signal that targets this protein to a secretory pathway involving vesicular localization during encystation and, ultimately, secretion to form the cyst wall.

Characterization of a Giardia lamblia variant-specific surface protein (VSP) gene from isolate GS/M and estimation of the VSP gene repertoire size

Giardia lamblia undergoes surface antigenic variation. The variant-specific surface proteins (VSPs) of isolate WB are cysteine-rich, can vary dramatically in size, contain Cys-X-X-Cys motifs, and are differentially expressed. GS/M(H7) is a Giardia clone from a different isolate which expresses a VSP epitope not found in WB. The VSP gene encoding this epitope was selected by differential hybridization using radiolabeled cDNA from H7 and variant sibling trophozoite lines from the same isolate that express other VSPs. The VSPH7 gene probe detects an 1800 nucleotide transcript abundant in H7 but undetectable in variant siblings. Primer extension directly from RNA was used to complete the gene sequence which predicted a protein with a molecular weight of 56,832. The protein showed many of the characteristics of 2 previously sequenced WB VSPs including many Cys-X-X-Cys tetrapeptides and a conserved carboxy-terminal region. Genomic Southern analysis indicated the presence of 2 distinct VSPH7 genes in H7. An oligonucleotide from the conserved region was used in combination with one specific for the VSPH7 gene to estimate the VSP repertoire size at between 133 and 151. VSPs, even from isolates expressing unique epitopes, constitute a family of related proteins.

INCREASED EXPRESSION OF THE MOLECULAR CHAPERONE BIP/GRP78 DURING THE DIFFERENTIATION OF A PRIMITIVE EUKARYOTE

Summary— Giardia lamblia, a major cause of intestinal disease worldwide, is a parasitic protozoan that represents the earliest branch of the eukaryotic lineage. Trophozoites, which possess two nuclei but lack mitochondria, peroxisomes and a typical Golgi apparatus, colonize the small intestine of the vertebrate host where they may differentiate into infective cysts. Encystation is a regulated process characterized by the biosynthesis, secretion and formation of a protective extracellular cyst wall. In previous studies, we demonstrated the biogenesis of the Golgi apparatus during encystation and identified two leucine‐rich proteins (CWPs), which localize within encystation‐specific secretory granules before their incorporation into the cyst wall. Here, we used immunological, biochemical and molecular biological approaches to analyze the expression of BiP/GRP78, an endoplasmic reticulum (ER)‐resident chaperone, during the Giardia life cycle. A monoclonal antibody specific for Giardia BiP permitted the visualization of the ER of this protozoan and showed that BiP expression increased simultaneously with the increased expression of CWPs during encystation. However, in contrast to the 140‐fold increase in levels of CWP transcripts, the steady‐state level of BiP mRNA did not increase during encystation. Furthermore, potent inducers of BiP expression in higher eukaryotic cells, including agents that perturb the ER environment, did not affect BiP expression in Giardia. These results, when considered together with the profound changes that occur in the secretory pathway during Giardia encystation, indicate an important role for this molecular chaperone during the differentiation of this primitive eukaryote.

Isoprenylation of proteins in the protozoan Giardia lamblia.

We report the ability of Giardia lamblia to modify several of its cellular proteins by isoprenylation. Trophozoites cultured in the presence of [3H]mevalonate synthesized radiolabeled proteins of approx. 50 and 21-26 kDa. Chemical analysis indicated that farnesyl and geranylgeranyl isoprenoids comprised the majority of the radiolabel covalently associated with trophozoite proteins. In addition, antibodies to human p21ras immunoprecipitated mevalonate-labelled species of approx. 21 kDa. Inhibitors of several enzymatic steps of the mevalonate pathway dramatically affected Giardia metabolism. Protein isoprenylation and cell growth were blocked by compactin and mevinolin, competitive inhibitors of HMG-CoA reductase, the rate-limiting enzyme in isoprenoid biosynthesis. In the presence of these inhibitors, Giardia growth was restored by the addition of mevalonate to the culture medium. In contrast, cell growth was blocked irreversibly by inhibitors of subsequent steps in the protein isoprenylation pathway. Trophozoite growth inhibition by limonene, perillic acid, perillyl alcohol and N-acetyl-S-farnesyl-L-cysteine was not reversed after the addition of mevalonate, dolichol, ubiquinone or cholesterol to the medium. These observations constitute the first description of protein isoprenylation in any protozoan and indicate that this post-translational modification is an important step in the regulation of the growth of this primitive eukaryote.

Sequencing and characterization of an Echinococcus multilocularis DNA probe and its use in the polymerase chain reaction

The nucleotide sequence of the cloned Echinococcus multilocularis DNA probe pAL1 was determined in order to simplify and improve the sensitivity of a diagnostic assay through the application of the polymerase chain reaction (PCR). The insert-specific oligonucleotides BG1 and BG2 define a 2.6-kb fragment in the genomic DNA of E. multilocularis, while BG1 and BG3 define a 0.3 kb fragment. A PCR study including 14 independent E. multilocularis isolates in addition to Echinococcus granulosus. Echinococcus vogeli, Taenia spp. and other cestodes revealed that the 2.6-kb fragment was amplified from genomic DNA of all E. multilocularis isolates tested (originating from Switzerland, Alaska, Canada, France, Germany and Japan), but from genomic DNA of none of the other cestode species. PCR with BG1 and BG2 furthermore uniquely resulted in the synthesis of a 0.55-kb fragment specific for Taenia saginata and a 0.6-kb fragment specific for T. taeniaeformis. In contrast to the species specificity of the 2.6-kb BG1/BG2 product, the 0.3 kb (BG1/BG3) product demonstrated genus specificity: the 0.3-kb product was amplified from genomic DNA of all E. multilocularis, E. granulosus and E. vogeli isolates tested, but from genomic DNA of none of the other cestode species. The diagnostic sensitivity of PCR using both primer sets was determined to be 50 pg parasite DNA, suggesting the practical utility of this simple assay in demonstrating parasite DNA in specimens from a variety of sources. At the basic level, the pAL1-derived oligonucleotides may also prove useful in assessing strain variation, RFLPs or other manifestations of genetic variation in E. multilocularis.

Identification and characterization of a Giardia lamblia group-specific gene

Giardia lamblia consist of heterogeneous isolates that can be divided into at least three groups. Differential screening of a cDNA library with isolate-specific antisera identified a gene which is expressed and found only in Group 3 isolates. This gene, GLORF-C4, is 597 bp in length and predicts a deduced protein of 198 amino acids that is characterized by a polyserine motif. Giardia can also be grouped by their ability to express certain variant-specific surface proteins (VSPs), expression of which is restricted among groups. In Southern blots, probes specific to two VSPs were used to characterize isolates. Failure to detect VSP genes correlated with inability to express the same VSP. Analysis of isolates with these new probes complements and confirms the groupings previously suggested using other criteria. These genetic differences should allow differentiation of isolates and permit the application of basic epidemiological techniques to determine the manner of spread and the presence of animal reservoirs.

Lipid Requirements and Lipid Uptake by Giardia lamblia Trophozoites in Culture

To better understand the lipid requirements of Giardia lamblia trophozoites and the mechanisms of lipid uptake, we supplemented serum‐free TYI‐S‐33 medium with lipids incorporated into different lipid carriers. We found that serum lipoproteins, β‐cyclodextrins, and bile salts are able to supply cholesterol and phospholipids to Giardia and to support the multiplication of the parasite in vitro. The growth rates obtained with different lipoproteins or bile salts and lipid mixtures were similar to that in standard culture medium containing serum. Pulse labelling experiments using fluorescent lipid analogs demonstrated that Giardia can take up lipids from lipoproteins, β‐cyclodextrins, or bile salt micelles, but with different kinetics, and that bile salts greatly facilitated lipid transfer from lipoproteins and cyclodextrins to the parasite surface. The binding of different radioiodinated lipoprotein classes to the trophozoite surface, inhibition of lipoprotein interiorization at 4°C or by cytochalasin D, and incorporation studies using fluorescent LDL suggested that a small component of lipid uptake by trophozoites was likely due to endocytosis of lipoproteins.

Giardia lamblia: Identification and Characterization of a Variant-Specific Surface Protein Gene Family

ABSTRACT. Giardia lamblia trophozoites undergo antigenic variation by modulating the expression of variant‐specific surface proteins (VSP), which are encoded by a number of small multigene families. We characterized the genomic copy of the VSP gene expressed by the cloned trophozoite line H7, derived from the isolate GS/M, in addition to a related, but nonexpressed, family member. The coding regions of the two genes encode closely related polypeptides (86% identity). However, differences in the coding region of these genes reside solely in an 873 bp segment. Only four differences were found between the 5’flanking sequences (465 bp). The proximal 205 base pairs downstream from the coding regions were identical, but thereafter the sequences diverged (37% identity over the next 391 bp). Mapping studies indicated that no other VSP gene was located within 4 kb pairs of the expressed H7 VSP gene, and transcripts from the nonexpressed gene were detected in neither GS/H7 nor heterogeneous trophozoites populations derived from this cloned line. Any mechanisms responsible for the differential expression of VSP genes must reconcile the near identity of DNA sequences that flank the coding regions of expressed and nonexpressed VSP genes.

The Molecular Mechanisms of Giardia Encystation

The protozoan parasite Giardia lamblia is transmitted as an environmentally resistant cyst. The encystation process is attracting attention not only from the viewpoint of disease transmission, but also as a model for differentiation. Here, Hugo Luján, Michael Mowatt and Theodore Nash discuss molecular events underlying this process, including the induction of expression and transport of cyst wall proteins and the induction of Golgi-like activity. They also propose that the signal for encystation derives from cholesterol deprivation in the lower small intestine.