ABSTRACT
The insect microsporidian Anncaliia algerae was first described in 2004 as a cause of fatal myositis in an immunosuppressed person from Pennsylvania, USA. Two cases were subsequently reported, and we detail 2 additional cases, including the only nonfatal case. We reviewed all 5 case histories with respect to clinical characteristics, diagnosis, and management and summarized organism life cycle and epidemiology. Before infection, all case-patients were using immunosuppressive medications for rheumatoid arthritis or solid-organ transplantation. Four of the 5 case-patients were from Australia. All diagnoses were confirmed by skeletal muscle biopsy; however, peripheral nerves and other tissues may be infected. The surviving patient received albendazole and had a reduction of immunosuppressive medications and measures to prevent complications. Although insects are the natural hosts for A. algerae, human contact with water contaminated by spores may be a mode of transmission. A. algerae has emerged as a cause of myositis, particularly in coastal Australia.
Subject(s)
Apansporoblastina/physiology , Arthritis, Rheumatoid/immunology , Immunocompromised Host , Microsporidiosis/pathology , Muscle, Skeletal/pathology , Myositis/pathology , Aged , Apansporoblastina/pathogenicity , Arthritis, Rheumatoid/drug therapy , Australia , Fatal Outcome , Humans , Immunosuppressive Agents/adverse effects , Life Cycle Stages , Male , Microsporidiosis/drug therapy , Microsporidiosis/microbiology , Muscle, Skeletal/microbiology , Myositis/drug therapy , Myositis/microbiology , Organ TransplantationABSTRACT
The presence of a new microsporidium is believed to be responsible for an emaciative syndrome observed in farmed gilthead sea bream (Sparus aurata) from different facilities along the Spanish coast. Infected fish were approximately half the average weight and significant mortality was attributed to the condition in some facilities. Clinical signs included anorexia, cachexia and pale internal organs. The microsporidium was found mainly in the intestinal mucosa and occasionally in the submucosa. Morphological, histopathological, ultrastructural and molecular phylogenetic studies were conducted to characterise this organism. This microsporidium undergoes intranuclear development in rodlet cells and enterocytes, and cytoplasmic development mainly in enterocytes and macrophages. The nucleus-infecting plasmodium contains several diplokarya and displays polysporous development which occurs without an interfacial envelope. In the host cell cytoplasm, the parasite develops within a membrane-bound matrix. In both infection locations, the polar tube precursors appear as disks, first with lucent centres, then as fully dense disks as they fuse to form the polar filament, all before division of the plasmodium into sporoblasts. Up to 16 intranuclear spores result from the sporogonic development of a single plasmodium, whereas more than 40 spores result from several asynchronous reproductive cycles in the cytoplasmic infection. Fixed spores are ellipsoidal and diplokaryotic, with five to six coils of an isofilar polar filament in a single row. ssrDNA-based molecular phylogenetic inference places this parasite as a sister clade to crustacean-infecting species of the Enterocytozoonidae and closer to Enterocytozoon bieneusi than to other fish-infecting microsporidians presenting intranuclear development, i.e. Nucleospora, Paranucleospora and Desmozoon. Our studies result in the erection of a new species, Enterospora nucleophila, within the family Enterocytozoonidae, and the description of this family is amended accordingly to accommodate the features of known species assigned to it. Severe histopathological damage occurs in intense infections and this microsporidian is considered a serious emerging threat in sea bream production.
Subject(s)
Apansporoblastina/classification , Apansporoblastina/pathogenicity , Fish Diseases/microbiology , Microsporidiosis/veterinary , Sea Bream/microbiology , Animals , Apansporoblastina/genetics , Cell Nucleus/microbiology , Cell Nucleus/ultrastructure , Cytoplasm/microbiology , Cytoplasm/ultrastructure , DNA, Fungal/genetics , DNA, Fungal/isolation & purification , Fish Diseases/pathology , Host-Pathogen Interactions , Intestinal Mucosa/microbiology , Intestinal Mucosa/pathology , Microscopy, Electron, Transmission , Microsporidiosis/microbiology , Microsporidiosis/pathology , Molecular Sequence Data , PhylogenyABSTRACT
Anncaliia algerae is an aquatic microsporidium that most commonly infects mosquitoes but can be grown on the rabbit kidney cell line, RK-13. Spores were purified from RK-13 cultures and added to cell lines from warm water fish and from an insect. The cell lines were GFSK-S1 and GFB3C-W1 from goldfish skin and brain respectively, ZEB2J from zebrafish embryos, FHMT-W1 from fathead minnow testis, and Sf9 from ovaries of a fall armyworm moth. All cultures were maintained at 27°C. Infection was judged to have taken place by the appearance of sporonts and/or spores in cells and occurred in all cell lines. Spores were also isolated from ZEB2J cultures and used to successfully infect new cultures of ZEB2J, RK-13 and Sf9. These results suggest that cells of a wide range of vertebrates support A. algerae growth in vitro and fish cells can produce spores infectious to cells of mammals, fish, and insects.
