Microsporidia are currently considered emerging pathogens responsible for life-threatening infections in organ transplant recipients. Here, we describe the first cases of intestinal microsporidiosis by Enterocytozoon bieneusi genotype D in two non-HIV-infected renal transplant recipients from Spain. Previously reported cases of microsporidiosis in organ transplant recipients have also been reviewed, highlighting the necessity of considering organ transplant recipients a risk group for microsporidiosis. A systematic search for these parasites is recommended in cases of persistent diarrhea and in the differential diagnosis of other syndromes, such as chronic fever of unknown etiology.
Polymorphism and recombination for rDNA in the putatively asexual microsporidian Nosema ceranae, a pathogen of honeybees
Nosema ceranae is currently one of the major pathogens of honeybees, related to the worldwide colony losses phenomenon. The genotyping of strains based on ribosomal DNA (rDNA) can be misleading if the repeated units are not identical. The analysis of cloned rDNA fragments containing the intergenic spacer (IGS) and part of the rDNA small-subunit (SSU) gene, from N. ceranae isolates from different European and Central Asia populations, revealed a high diversity of sequences. The variability involved single-nucleotide polymorphisms and insertion/deletions, resulting in 79 different haplotypes. Two sequences from the same isolate could be as different as any pair of sequences from different samples; in contrast, identical haplotypes were also found in very different geographical origins. Consequently, haplotypes cannot be organized in a consistent phylogenetic tree, clearly indicating that rDNA is not a reliable marker for the differentiation of N. ceranae strains. The results indicate that recombination between different sequences may produce new variants, which is quite surprising in microsporidia, usually considered to have an asexual mode of reproduction. The diversity of sequences and their geographical distribution indicate that haplotypes of different lineages may occasionally be present in a same cell and undergo homologue recombination, therefore suggesting a sexual haplo-diploid cycle.
Several studies have demonstrated that the soil of public parks presents an important source of infection which has a significant impact on public health. Children are the main group affected by accidentally ingestion of contaminated soil. This study was performed in order to identify the presence of zoonotic parasites in dog and cat faecal and soil samples from public parks of Madrid, Spain. Six hundred twenty-five and seventy-nine soil and faecal samples (presumably from dogs and cats) respectively were collected from 67 parks. Intestinal parasites were identified in 27 parks (40.3%), which were contamined with Giardia sp. (19.4%), microsporidia (19.4%), Toxocara spp. (16.4%), Cryptosporidium sp. (6%), Entamoeba histolytica (3%) and Ancylostomidae (3%). Combinations of two or more intestinal parasites were found in 11 parks, and it was common to find Giardia and microsporidia together in samples. Intestinal parasites were detected in 18% (112/625) of soil samples. The most frequent parasite species found in the examined soil samples were Toxocara spp. (16.4%), followed by Giardia sp. (4.5%) and Strongyloides sp. larvae (3%). The zoonotic parasites found in the 79 faecal samples were Giardia sp. (17.7%), Cryptosporidium sp. (9%), E. histolytica (2.5%), Trichuris vulpis (1.3%), Toxascaris leonina (1.3%) and microsporidia spores (28%). Microsporidia characterization by amplification of DNA confirmed 10 samples as positive, eight for E. bieneusi and two for E. hellem by PCR. The role of those parasites in the environment are discussed.
First Detection and Genotyping of Human-Associated Microsporidia in Pigeons from Urban Parks
Microsporidia are ubiquitous opportunistic parasites in nature infecting all animal phyla, and the zoonotic potential of this parasitosis is under discussion. Fecal samples from 124 pigeons from seven parks of Murcia (Spain) were analyzed. Thirty-six of them (29.0%) showed structures compatible with microsporidia spores by staining methods. The DNA isolated from 26 fecal samples (20.9%) of microsporidia-positive pigeons was amplified with specific primers for the four most frequent human microsporidia. Twelve pigeons were positive for only Enterocytozoon bieneusi (9.7%), 5 for Encephalitozoon intestinalis (4%), and one for Encephalitozoon hellem (0.8%). Coinfections were detected in eight additional pigeons: E. bieneusi and E. hellem were detected in six animals (4.8%); E. bieneusi was associated with E. intestinalis in one case (0.8%); and E. hellem and E. intestinalis coexisted in one pigeon. No positive samples for Encephalitozoon cuniculi were detected. The internally transcribed spacer genotype could be completed for one E. hellem-positive pigeon; the result was identical to the genotype A1 previously characterized in an E. hellem Spanish strain of human origin. To our knowledge, this is the first time that human-related microsporidia have been identified in urban park pigeons. Moreover, we can conclude that there is no barrier to microsporidia transmission between park pigeons and humans for E. intestinalis and E. hellem. This study is of environmental and sanitary interest, because children and elderly people constitute the main visitors of parks and they are populations at risk for microsporidiosis. It should also contribute to the better design of appropriate prophylactic measures for populations at risk for opportunistic infections.Microsporidia are intracellular obligate parasites mainly considered as opportunistic pathogens (58), ubiquitous in nature, infecting all animal phyla (6, 59). Although initially associated with AIDS patients, they are being detected in increasing numbers in immunocompetent patients and thus are gaining attention as emerging pathogens (25,33,35,53,56). The phylum Microsporidia contains over 144 genera and 1,200 species (59). The number of genera implicated in human microsporidiosis has increased at the same rate as the improvements in diagnostic techniques, and the interest in this group of parasites has grown accordingly. To date, eight genera are recognized as human pathogens: Nosema, Vittaforma, Pleistophora, Encephalitozoon, Enterocytozoon, Brachiola, Trachipleistophora, and Microsporidium. Among these, Enterocytozoon bieneusi is the species of microsporidia that most frequently causes infection in humans, followed by Encephalitozoon intestinalis, Encephalitozoon hellem, and Encephalitozoon cuniculi.
Microsporidia are ubiquitous parasites infecting all animal phyla and we present evidence that supports their zoonotic potential. Fecal samples taken from domestic (cats and dogs), farm (pigs, rabbits and ostriches) and wild animals (foxes) from different provinces of Spain were evaluated for microsporidia infection by light microscopy and PCR. After Microsporidia species identification, E. bieneusi genotypes were additionally studied by sequence analysis of the ITS region. Eighty-five samples out of 159 exhibited structures that were compatible with microsporidia spores by Webeŕs stain with 37 of them being confirmed by PCR. Microsporidia species identified included E. bieneusi, E. intestinalis and A. algerae. We report the first diagnosis of E. intestinalis and E. bieneusi in ostriches and A. algerae in pigs. We also provide new information on the molecular characterization of E. bieneusi isolates both in rabbits and ostriches. All of the E. bieneusi genotypes identified belonged to the zoonotic group of genotypes (Group I) including genotypes A (dogs), I (pigs), D (rabbits and foxes) and type IV (ostriches). Our results demonstrate that microsporidia are present in domestic, farm and wild animals in Spain, corroborating their potential role as a source of human infection and environmental contamination.
Intestinal Microsporidiosis Due toEnterocytozoon bieneusiin Elderly Human Immunodeficiency Virus–Negative Patients from Vigo, Spain
We report what is, to our knowledge, the first study in which microsporidial infection was detected in elderly human immunodeficiency virus (HIV)--negative patients. Of the 60 elderly patients studied, 47 had diarrhea. Intestinal microsporidiosis due to Enterocytozoon bieneusi was diagnosed in 8 patients (17.02%) by use of Weber's chromotrope-based stain and polymerase chain reaction with species-specific primers. The mean age of these 8 patients was 75 years; 7 had chronic diarrhea and 1 had nonchronic diarrhea. Six of the patients with chronic diarrhea had no other pathogens isolated. In our opinion, elderly patients, because of their special immunological characteristics, should be considered a group at risk for the acquisition of intestinal microsporidiosis.
High-Level Resistance of Nosema ceranae , a Parasite of the Honeybee, to Temperature and Desiccation
Resistance of Nosema ceranae to different exposure conditions has been evaluated by using Sytox green and DAPI (4,6-diamidino-2-phenylindole) to test spore viability. High thermotolerance at 60 and 35°C and resistance to desiccation were observed. However, a significant decrease in viability after freezing and a rapid degeneration of spores maintained at 4°C were also detected.Two Nosema species have been related to pathology in the honeybee: Nosema apis (18) a parasite of Apis mellifera, the western honeybee, and Nosema ceranae (4), a parasite of Apis cerana, the eastern honeybee. Currently, however, N. ceranae is considered an emergent and important parasite of Apis mellifera (4).Over the last few years, an increase in infections by this microsporidian has been detected in several European countries, together with an increase in honeybee colony deaths and a consequent decrease in the production of honey (9). However, it is not clear if N. ceranae infection may be the only factor related to this disorder, since this pathogen has also been found in healthy colonies (14). In Spain, Higes et al. (7,9) have demonstrated the presence of this parasite in honeybee samples from colonies with clear signs of population depletion, relating the colony collapse disorder to N. ceranae. The presence of this microsporidian is not exclusive to Europe, since it has also been described in bee samples collected about a decade ago in the United States (3).The pathology produced by N. ceranae in A. mellifera bees may be higher than that produced by N. apis, showing a rapid autoinfective capacity of the spores to spread the infection among epithelial cells, producing high mortality (6). On the other hand, reduced longevity of caged N. ceranae-infected worker bees compared to bees infected by N. apis has also been found (15).To date, continuous cultures of N. ceranae are not available and there is no effective treatment. For this reason, it is important to study the effects of different exposure conditions, such as time, temperature, and desiccation, on the viability of spores kept in the laboratory for use in the search for new treatments and for development of culture protocols. In addition, as different levels of thermotolerance in the environment and different epidemiological patterns have been described for these microsporidia, available data on resistance of N. apis spores cannot be extrapolated to N. ceranae.Spores. Spores from N. apis and N. ceranae were provided by the experimental apiary of the Regional Apicultural Center in Marchamalo, Spain. Recently collected spores were purified as described previously (8). The spore concentration was determined by counting with a hematocytometer chamber. Two stocks of N. ceranae spores were used (S1 and S2). All studies were carried out at a concentration of 5 ϫ 10 5 spores/ml. The Nosema species was determined by multiplex PCR, which amplifies the 16S rRNA locus (12).Spore treatments. The effects of time, temperature, and desiccation on viability were measured at different points. All ...
African swine fever virus (ASFV) is able to inhibit TNF-α-induced gene expression through the synthesis of A238L protein. This was shown by the use of deletion mutants lacking the A238L gene from the Vero cell-adapted Ba71V ASFV strain and from the virulent isolate E70. To further analyze the molecular mechanism by which the viral gene controls TNF-α, we have used Jurkat cells stably transfected with the viral gene to identify the TNF-α regulatory elements involved in the induction of the gene after stimulation with PMA and calcium ionophore. We have thus identified the cAMP-responsive element and κ3 sites on the TNF-α promoter as the responsible of the gene activation, and demonstrate that A238L inhibits TNF-α expression through these DNA binding sites. This inhibition was partially reverted by overexpression of the transcriptional factors NF-AT, NF-κB, and c-Jun. Furthermore, we present evidence that A238L inhibits the activation of TNF-α by modulating NF-κB, NF-AT, and c-Jun trans activation through a mechanism that involves CREB binding protein/p300 function, because overexpression of these transcriptional coactivators recovers TNF-α promoter activity. In addition, we show that A238L is a nuclear protein that binds to the cyclic AMP-responsive element/κ3 complex, thus displacing the CREB binding protein/p300 coactivators. Taken together, these results establish a novel mechanism in the control of TNF-α gene expression by a viral protein that could represent an efficient strategy used by ASFV to evade the innate immune response.
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