Antibodies to variable surface antigens induce antigenic variation in the intestinal parasite Giardia lamblia.

The genomes of most protozoa encode families of variant surface antigens. In some parasitic microorganisms, it has been demonstrated that mutually exclusive changes in the expression of these antigens allow parasites to evade the host's immune response. It is widely assumed that antigenic variation in protozoan parasites is accomplished by the spontaneous appearance within the population of cells expressing antigenic variants that escape antibody-mediated cytotoxicity. Here we show, both in vitro and in animal infections, that antibodies to Variant-specific Surface Proteins (VSPs) of the intestinal parasite Giardia lamblia are not cytotoxic, inducing instead VSP clustering into liquid-ordered phase membrane microdomains that trigger a massive release of microvesicles carrying the original VSP and switch in expression to different VSPs by a calcium-dependent mechanism. This novel mechanism of surface antigen clearance throughout its release into microvesicles coupled to the stochastic induction of new phenotypic variants not only changes current paradigms of antigenic switching but also provides a new framework for understanding the course of protozoan infections as a host/parasite adaptive process.

Comprehensive characterization of Cysteine-rich protein-coding genes of Giardia lamblia and their role during antigenic variation.

Giardia lamblia encodes several families of cysteine-rich proteins, including the Variant-specific Surface Proteins (VSPs) involved in the process of antigenic variation. Their characteristics, definition and relationships are still controversial. An exhaustive analysis of the Cys-rich families including organization, features, evolution and levels of expression was performed, by combining pattern searches and predictions with massive sequencing techniques. Thus, a new classification for Cys-rich proteins, genes and pseudogenes that better describes their involvement in Giardia's biology is presented. Moreover, three novel characteristics exclusive to the VSP genes, comprising an Initiator element/Kozak-like sequence, an extended polyadenylation signal and a unique pattern of mutually exclusive transcript accumulation are presented, as well as the finding that High Cysteine Membrane Proteins, upregulated under stress, may protect the parasite during VSP switching. These results allow better interpretation of previous reports providing the basis for further studies of the biology of this early-branching eukaryote.

Efficient oral vaccination by bioengineering virus-like particles with protozoan surface proteins.

Intestinal and free-living protozoa, such as Giardia lamblia, express a dense coat of variant-specific surface proteins (VSPs) on trophozoites that protects the parasite inside the host's intestine. Here we show that VSPs not only are resistant to proteolytic digestion and extreme pH and temperatures but also stimulate host innate immune responses in a TLR-4 dependent manner. We show that these properties can be exploited to both protect and adjuvant vaccine antigens for oral administration. Chimeric Virus-like Particles (VLPs) decorated with VSPs and expressing model surface antigens, such as influenza virus hemagglutinin (HA) and neuraminidase (NA), are protected from degradation and activate antigen presenting cells in vitro. Orally administered VSP-pseudotyped VLPs, but not plain VLPs, generate robust immune responses that protect mice from influenza infection and HA-expressing tumors. This versatile vaccine platform has the attributes to meet the ultimate challenge of generating safe, stable and efficient oral vaccines.

Cytokines, Antibodies, and Histopathological Profiles during Giardia Infection and Variant-Specific Surface Protein-Based Vaccination.

Giardiasis is one of the most common human intestinal diseases worldwide. Several experimental animal models have been used to evaluate Giardia infections, with gerbils (Meriones unguiculatus) being the most valuable model due to their high susceptibility to Giardia infection, abundant shedding of cysts, and pathophysiological alterations and signs of disease similar to those observed in humans. Here, we report cytokine and antibody profiles both during the course of Giardia infection in gerbils and after immunization with a novel oral vaccine comprising a mixture of purified variant-specific surface proteins (VSPs). Transcript levels of representative cytokines of different immune profiles as well as macro- and microtissue alterations were assessed in Peyer's patches, mesenteric lymph nodes, and spleens. During infection, cytokine responses showed a biphasic profile: an early induction of Th1 (gamma interferon [IFN-γ], interleukin-1ß [IL-1ß], IL-6, and tumor necrosis factor [TNF]), Th17 (IL-17), and Th2 (IL-4) cytokines, together with intestinal alterations typical of inflammation, followed by a shift toward a predominant Th2 (IL-5) response, likely associated with a counterregulatory mechanism. Conversely, immunization with an oral vaccine comprising the entire repertoire of VSPs specifically showed high levels of IL-17, IL-6, IL-4, and IL-5, without obvious signs of inflammation. Both immunized and infected animals developed local (intestinal secretory IgA [S-IgA]) and systemic (serum IgG) humoral immune responses against VSPs; however, only infected animals showed evident signs of giardiasis. This is the first comprehensive report of cytokine expression and anti-Giardia antibody production during infection and VSP vaccination in gerbils, a reliable model of the human disease.

Specific histone modifications play critical roles in the control of encystation and antigenic variation in the early-branching eukaryote Giardia lamblia.

During evolution, parasitic microorganisms have faced the challenges of adapting to different environments to colonize a variety of hosts. Giardia lamblia, a common cause of intestinal disease, has developed fascinating strategies to adapt both outside and inside its host's intestine, such as trophozoite differentiation into cyst and the switching of its major surface antigens. How gene expression is regulated during these adaptive processes remains undefined. Giardia lacks some typical eukaryotic features, like canonical transcription factors, linker histone H1, and complex promoter regions; suggesting that post-transcriptional and translational control of gene expression is essential for parasite survival. However, epigenetic factors may also play critical roles at the transcriptional level. Here, we describe the most common post-translational histone modifications; characterize enzymes involved in these reactions, and analyze their association with the Giardia's differentiation processes. We present evidence that NAD+-dependent and NAD+-independent histone deacetylases regulate encystation; however, a unique NAD+-independent histone deacetylase modulate antigenic switching. The rates of acetylation of H4K8 and H4K16 are critical for encystation, whereas a decrease in acetylation of H4K8 and methylation of H3K9 occur preferentially during antigenic variation. These results show the complexity of the mechanisms regulating gene expression in this minimalistic protozoan parasite.

Vaccination of domestic animals with a novel oral vaccine prevents Giardia infections, alleviates signs of giardiasis and reduces transmission to humans.

Giardia lamblia is a human intestinal parasite and one of the most frequent enteric pathogen of companion animals. Clinical manifestations of giardiasis, such as diarrhoea, anorexia, weight loss and lethargy, have been associated with Giardia infections in both domestic and farm animals. A few anti-parasitic drugs are routinely used to treat giardiasis, but re-infections are common and drug-resistant strains have already been reported. Unfortunately, efficient vaccines against Giardia are not available. Giardia undergoes antigenic variation; through this mechanism, parasites can avoid the host's immune defenses, causing chronic infections and/or re-infections. Antigenic variation is characterised by a continuous switch in the expression of members of a homologous family of genes encoding surface antigens. In a previous report, we indicated that in Giardia, the mechanism responsible for the exchange of variant-specific surface proteins (VSPs) involves the RNA interference (RNAi) pathway. From a repertoire of ~200 VSP genes, only one is expressed on the surface of single trophozoites; however, RNAi machinery disruption generates trophozoites that express the complete VSP repertoire. We also demonstrated that gerbils orally immunised with VSPs isolated from these altered parasites showed high levels of protection. Here we tested this vaccine in cats and dogs, and found that it is highly efficient in preventing new infections and reducing chronic giardiasis in domestic animals both in experimental and natural infections. Remarkably, immunisation of dogs in a highly endemic area strongly decreased the percentage of infected children in the community, suggesting that this vaccine would block the zoonotic transmission of the disease.

Nuevos métodos para el diagnóstico microbiológico de la amebiasis y de otros protozoarios intestinales / New methods for the microbiological diagnosis of amebiasis and other intestinal protozoa

La Organización Mundial de la Salud (OMS) ubica a las enfermedades diarreicas en segundo lugar como causa de morbi-mortalidad de niños en países en vías de desarrollo, siendo las infecciones por protozoarios intestinales proporcionalmente una causa trascendente en dichas regiones. La mayoría de estos parásitos se transmiten por vía fecal-oral o por contacto interpersonal y exhiben ciclosde vida que, en general se desarrollan en dos estadios: el trofozoíto que coloniza el intestino y el quiste que es excretado con las heces y cuya rígida pared protectora, le confiere resistencia en el ambiente, permitiendo de este modo la propagación de la enfermedad. Entamoeba histolytica es uno de los agentes infecciosos de mayor distribución mundial, y es aproximadamente la causa de 100.000 muertes por año, siendo responsable de uno de los problemas de salud más serios en países en vías de desarrollo. Se reconocen al menos ocho amebas que podrían colonizar el intestino del hombre: E. histolytica, E. dispar, E. moshkovskii, E. coli, E. hartmanni, E. polecki, Iodamoeba butschlii y Endolimax nana. Aunque sólo E. histolytica es considerada como el agente etiológico de la Amebiosis. Su presentación clínica va desde la colonización asintomática, la disentería amebiana, hasta la propagación extraintestinal, originando abscesos en diversos órganos y tejidos. Por este motivo, la correcta identificación de E. histolytica en heces y tejidos y diferenciándola de otras amebas comensales y de otros protozoarios representa un desafío en la práctica médica, a que de ello dependerá el tratamiento y el pronóstico de laenfermedad.

Abstract: The World Health Organization (WHO) includes diarrhea a the second leading cause of morbidity and mortality of children in developing countries. Among these causes, infections by intestinal protozoan parasites represent an important percentage in any place of the world. Most of these parasites are transmitted by the fecal-oral route or by inter personal contact and exhibit simple life cycles, consisting in the disease-causing, proliferating trophozoites and the dormant, resistant cyst responsible for the transmission of the infection among susceptible hosts. Entamoeba histolytica is one of the most frequent of those parasites, causing about 100.000 deaths per year in developing countries, being one of the major health problems in areas where basic sanitation practices are inefficient. At least eight species of Entamoeba have been reported to infect the human large intestine: E. histolytica, E. dispar, E. moshkovskii, E. coli, E. hartmanni, E. polecki, odamoeba butschlii and Endolimax nana, although E. histolytica is the only one considered to cause pathology in humans. Clinical manifestation of this infection varies from asymptomatic infection to dysentery and extraintestinal invasion, producing abscesses in many tissues. Therefore, the correct identification of E. histolytica in stool and tissue samples and its differential diagnostic is an important challenge in parasitology because treatment and prognosis depend of the valid identification of this parasite.The health issue of protozoan intestinal infections, both in developed and developing parts of the world, is of such importance that it is clearly necessary the development of novel, better, cheap, and faster diagnostic methods. The incorporation of new approaches and technology to the efficient and sensitive detection of these infections is significantly relevant.

Nuevos métodos para el diagnóstico microbiológico de la amebiasis y de otros protozoarios intestinales / New methods for the microbiological diagnosis of amebiasis and other intestinal protozoa

La Organización Mundial de la Salud (OMS) ubica a las enfermedades diarreicas en segundo lugar como causa de morbi-mortalidad de niños en países en vías de desarrollo, siendo las infecciones por protozoarios intestinales proporcionalmente una causa trascendente en dichas regiones. La mayoría de estos parásitos se transmiten por vía fecal-oral o por contacto interpersonal y exhiben ciclosde vida que, en general se desarrollan en dos estadios: el trofozoíto que coloniza el intestino y el quiste que es excretado con las heces y cuya rígida pared protectora, le confiere resistencia en el ambiente, permitiendo de este modo la propagación de la enfermedad. Entamoeba histolytica es uno de los agentes infecciosos de mayor distribución mundial, y es aproximadamente la causa de 100.000 muertes por año, siendo responsable de uno de los problemas de salud más serios en países en vías de desarrollo. Se reconocen al menos ocho amebas que podrían colonizar el intestino del hombre: E. histolytica, E. dispar, E. moshkovskii, E. coli, E. hartmanni, E. polecki, Iodamoeba butschlii y Endolimax nana. Aunque sólo E. histolytica es considerada como el agente etiológico de la Amebiosis. Su presentación clínica va desde la colonización asintomática, la disentería amebiana, hasta la propagación extraintestinal, originando abscesos en diversos órganos y tejidos. Por este motivo, la correcta identificación de E. histolytica en heces y tejidos y diferenciándola de otras amebas comensales y de otros protozoarios representa un desafío en la práctica médica, a que de ello dependerá el tratamiento y el pronóstico de laenfermedad.(AU)

Abstract: The World Health Organization (WHO) includes diarrhea a the second leading cause of morbidity and mortality of children in developing countries. Among these causes, infections by intestinal protozoan parasites represent an important percentage in any place of the world. Most of these parasites are transmitted by the fecal-oral route or by inter personal contact and exhibit simple life cycles, consisting in the disease-causing, proliferating trophozoites and the dormant, resistant cyst responsible for the transmission of the infection among susceptible hosts. Entamoeba histolytica is one of the most frequent of those parasites, causing about 100.000 deaths per year in developing countries, being one of the major health problems in areas where basic sanitation practices are inefficient. At least eight species of Entamoeba have been reported to infect the human large intestine: E. histolytica, E. dispar, E. moshkovskii, E. coli, E. hartmanni, E. polecki, odamoeba butschlii and Endolimax nana, although E. histolytica is the only one considered to cause pathology in humans. Clinical manifestation of this infection varies from asymptomatic infection to dysentery and extraintestinal invasion, producing abscesses in many tissues. Therefore, the correct identification of E. histolytica in stool and tissue samples and its differential diagnostic is an important challenge in parasitology because treatment and prognosis depend of the valid identification of this parasite.The health issue of protozoan intestinal infections, both in developed and developing parts of the world, is of such importance that it is clearly necessary the development of novel, better, cheap, and faster diagnostic methods. The incorporation of new approaches and technology to the efficient and sensitive detection of these infections is significantly relevant.(AU)

Disruption of antigenic variation is crucial for effective parasite vaccine.

Giardia lamblia is a human intestinal pathogen. Like many protozoan microorganisms, Giardia undergoes antigenic variation, a mechanism assumed to allow parasites to evade the host's immune response, producing chronic and/or recurrent infections. Recently, we found that the mechanism controlling variant-specific surface protein (VSP) switching in Giardia involves components of the RNA interference machinery and that disruption of this pathway generates trophozoites simultaneously expressing many VSPs. Here we use these altered trophozoites to determine the role of antigenic variation in a gerbil model of giardiasis. Our results show that either primary infection with trophozoites simultaneously expressing many VSPs or immunization with purified VSPs from the transgenic cells protects gerbils from subsequent Giardia infections. These results constitute, to our knowledge, the first experimental evidence that antigenic variation is essential for parasite survival within hosts and that artificial disruption of this mechanism might be useful in generating vaccines against major pathogens that show similar behavior.

ORF-C4 from the early branching eukaryote Giardia lamblia displays characteristics of alpha-crystallin small heat-shock proteins.

Giardia lamblia is a medically important protozoan parasite with a basal position in the eukaryotic lineage and is an interesting model to explain the evolution of biochemical events in eukaryotic cells. G. lamblia trophozoites undergo significant changes in order to survive outside the intestine of their host by differentiating into infective cysts. In the present study, we characterize the previously identified Orf-C4 (G. lamblia open reading frame C4) gene, which is considered to be specific to G. lamblia. It encodes a 22 kDa protein that assembles into high-molecular-mass complexes during the entire life cycle of the parasite. ORF-C4 localizes to the cytoplasm of trophozoites and cysts, and forms large spherical aggregates when overexpressed. ORF-C4 overexpression and down-regulation do not affect trophozoite viability; however, differentiation into cysts is slightly delayed when the expression of ORF-C4 is down-regulated. In addition, ORF-C4 protein expression is modified under specific stress-inducing conditions. Neither orthologous proteins nor conserved domains are found in databases by conventional sequence analysis of the predicted protein. However, ORF-C4 contains a region which is similar structurally to the alpha-crystallin domain of sHsps (small heat-shock proteins). In the present study, we show the potential role of ORF-C4 as a small chaperone which is involved in the response to stress (including encystation) in G. lamblia.

Antigenic variation in Giardia lamblia is regulated by RNA interference.

Giardia lamblia (also called Giardia intestinalis) is one of the most common intestinal parasites of humans. To evade the host's immune response, Giardia undergoes antigenic variation-a process that allows the parasite to develop chronic and recurrent infections. From a repertoire of approximately 190 variant-specific surface protein (VSP)-coding genes, Giardia expresses only one VSP on the surface of each parasite at a particular time, but spontaneously switches to a different VSP by unknown mechanisms. Here we show that regulation of VSP expression involves a system comprising RNA-dependent RNA polymerase, Dicer and Argonaute, known components of the RNA interference machinery. Clones expressing a single surface antigen efficiently transcribe several VSP genes but only accumulate transcripts encoding the VSP to be expressed. Detection of antisense RNAs corresponding to the silenced VSP genes and small RNAs from the silenced but not for the expressed vsp implicate the RNA interference pathway in antigenic variation. Remarkably, silencing of Dicer and RNA-dependent RNA polymerase leads to a change from single to multiple VSP expression in individual parasites.

Identification of variant-specific surface proteins in Giardia muris trophozoites.

Giardia lamblia undergoes antigenic variation, a process that might allow the parasite to evade the host's immune response and adapt to different environments. Here we show that Giardia muris, a related species that naturally infects rodents, possesses multiple variant-specific surface proteins (VSPs) and expresses VSPs on its surface, suggesting that it undergoes antigenic variation similar to that of G. lamblia.

A unique mechanism of nuclear division in Giardia lamblia involves components of the ventral disk and the nuclear envelope.

The fine structure of the binucleate, parasitic protist Giardia lamblia during interphase and divisional stages was studied by serial thin sectioning and three-dimensional reconstructions. The earlier sign of nuclear division is the development of a few peripheral areas of densely packed chromatin directly attached to the inner nuclear envelope. An intracytoplasmic sheet of ventral disk components grows from the cell periphery towards one of the nuclei, apparently constricting this nucleus, which becomes located at a ventral bulge. After the basal bodies become duplicated, a full nuclear division occurs in trophozoites, giving two pairs of parent-daughter nuclei. This full division occurs in a dorsal-ventral direction, with the resulting nuclear pairs located at the sides of the two sets of basal bodies. A new ventral disk is formed from the disk-derived sheets in the cell harboring the four nuclei. Cytokinesis is polymorphic, but at early stages is dorsal-to-dorsal. Encysting trophozoites show the development of Golgi cisternae stacks and dense, specific secretory granules. 3-D reconstructions show that cysts contain a single pair of incompletely strangled nuclei. The dividing Giardia lacks a typical, microtubular spindle either inside or outside the nuclei. The nuclear envelope seems to be the only structure involved in the final division of the parent-daughter nuclei.

A unique mechanism of nuclear division in Giardia lamblia involves components of the ventral disk and the nuclear envelope.

The fine structure of the binucleate, parasitic protist Giardia lamblia during interphase and divisional stages was studied by serial thin sectioning and three-dimensional reconstructions. The earlier sign of nuclear division is the development of a few peripheral areas of densely packed chromatin directly attached to the inner nuclear envelope. An intracytoplasmic sheet of ventral disk components grows from the cell periphery towards one of the nuclei, apparently constricting this nucleus, which becomes located at a ventral bulge. After the basal bodies become duplicated, a full nuclear division occurs in trophozoites, giving two pairs of parent-daughter nuclei. This full division occurs in a dorsal-ventral direction, with the resulting nuclear pairs located at the sides of the two sets of basal bodies. A new ventral disk is formed from the disk-derived sheets in the cell harboring the four nuclei. Cytokinesis is polymorphic, but at early stages is dorsal-to-dorsal. Encysting trophozoites show the development of Golgi cisternae stacks and dense, specific secretory granules. 3-D reconstructions show that cysts contain a single pair of incompletely strangled nuclei. The dividing Giardia lacks a typical, microtubular spindle either inside or outside the nuclei. The nuclear envelope seems to be the only structure involved in the final division of the parent-daughter nuclei.