John T. Conrad

Frequency of variant antigens in Giardia lamblia

Giardia lamblia undergoes antigenic variation. The rate of antigenic variation and the size of the variant antigen repertoire were estimated in clones of Giardia lamblia which reexpresses surface variant antigens that are characteristics of its parent. Calculations were based on determinations of the number of trophozoites expressing defined or nondefined epitopes as well as the total number of trophozoites in newly established clones. The rate of appearance of variant antigens containing defined epitopes was expressed as the number of generations until the first trophozoite expressing a defined epitope appeared. In clones of isolate WB, tested because their major surface variant antigens were largely nondefined, variants expressing epitopes recognized by Mabs 6E7 or 3F6 appeared after approximately 12 generations. Variants expressing epitopes recognized by Mab 5C1 appeared at about 13 generations, significantly greater than for the other epitopes. The rate of antigenic variation was studied in another isolate, GS/M, whose surface epitope repertoire differs from that of isolate WB. A single epitope recognized by Mab G10/4 was tested. Trophozoites reexpressing this epitope first appeared after about 6.5 generations, significantly less than in WB. Therefore, the single epitope studied in isolate GS/M is reexpressed much more frequently than those of WB. In isolate WB, the epitopes recognized by Mab 6E7 and 3F6 tended to appear at the same time. The median number of variant antigens in WB was estimated to lie between 20.5 and 184.

Arginine deiminase has multiple regulatory roles in the biology of Giardia lamblia.

The protozoan parasite Giardia lamblia uses arginine deiminase (ADI) to produce energy from free L-arginine under anaerobic conditions. In this work, we demonstrate that, in addition to its known role as a metabolic enzyme, it also functions as a peptidylarginine deiminase, converting protein-bound arginine into citrulline. G. lamblia ADI specifically binds to and citrullinates the arginine in the conserved CRGKA tail of variant-specific surface proteins (VSPs), affecting both antigenic switching and antibody-mediated cell death. During encystation, ADI translocates from the cytoplasm to the nuclei and appears to play a regulatory role in the expression of encystation-specific genes. ADI is also sumoylated, which might modulate its activity. Our findings reveal a dual role played by ADI and define novel regulatory pathways used by Giardia for survival.

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.

Variant specific epitopes of Giardia lamblia

Giardia lamblia undergoes surface antigenic variation. The capability of different isolates to express certain epitopes on the surfaces of trophozoites from different isolates and clones was determined using 4 surface-reacting monoclonal antibodies (mAbs) to variants derived from WB or WB-like Giardia (mAbs 6E7, 5C1, and 3F6) and GS/M (mAb G10/4). Of 28 isolates, 11 possessed trophozoites reactive with mAbs 6E7, 5C1 and 3F6, 6 with mAb 3F6, 2 with Mab G10/4, 1 with mAb 6E7, and 8 showed no reactivity as determined by direct or indirect immunofluorescence. Newly established clones from different isolates generated small numbers of reactive trophozoites similar to their parents. Only one epitope was found on any single trophozoite. Southern blots hybridized to a probe encoding for the epitope recognized by mAb 6E7 revealed that the inability to express the antigen in most isolates was due to lack of the gene. Analysis of the surface antigens of mAb 6E7 reactive clones from 3 isolates revealed that mAb 6E7 reacted with surface antigens of different molecular masses.

Biological Selection of Variant-Specific Surface Proteins in Giavdia lamblia

Immune evasion is frequently cited as the main reason for antigenic variation in pathogenic microorganisms. To better understand the role of switching of variant-specific surface proteins (VSPs) in Giardia lamblia-host interactions, antigenic variation during infections of mice and gerbils was examined, using clones that predominantly expressed unique VSPs. As expected, VSPs were selected against during infections of immunocompetent hosts. In contrast, in immunodeficient hosts, some VSPs were selected for and others were selected against. These diverse patterns of selection demonstrate that there are host-VSP interactions that exert both positive and negative selective pressures on parasites, independent of the adaptive immune response. Furthermore, selection was dependent on both the particular VSP and the host. Thus, the large number of VSP genes in G. lamblia may allow the parasite to infect multiple different hosts, and antigenic variation could be a mechanism to expand the parasites host range.

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.

Localization of Midgut-Specific Protein Antigens from Aedes aegypti (Diptera: Culicidae) Using Monoclonal Antibodies

Abstract Most insect transmitted pathogens interact with the midgut of their vectors for infection and, in some cases, development. Therefore, molecules associated with the midgut epithelium in direct contact with pathogens may be potential targets of infection-blocking measures. Here, we identify midgut-specific protein antigens from Aedes aegypti (L.) using monoclonal antibodies. Sixty-four monoclonal antibodies were generated with reactivity to the mosquito midgut, five of which are reported in this article. Three monoclonal antibodies identified protein antigens localized at the midgut epithelial surface (the brush border) and the peritrophic membrane. In addition, two monoclonal antibodies recognized mosquito nucleus-specific proteins by immunofluorescence microscopy. Because potential target antigens for blocking transmission of pathogens most likely are located at the interface of mosquito-pathogen interactions, these monoclonal antibodies could provide valuable tools for studying midgut-specific proteins and interactions of the mosquito midgut with pathogens.