Unique Isospora-associated histologic lesions in white-rumped shama (Copsychus malabaricus)

Twenty-one white-rumped shamas (19 necropsied, 2 biopsied) (Copsychus malabaricus) housed at the San Diego Zoo between 1992 and 2020 were diagnosed with Isospora infection based on evaluation of histologic sections. Review of these cases revealed a consistent histologic lesion characterized by nodular aggregates of atypical epithelioid macrophages containing few intracytoplasmic protozoa, with or without lymphocytic infiltrates. Of the 19 necropsied cases, 16 (84%) had systemic lesions variably affecting the liver, spleen, gastrointestinal tract, lung, pancreas, connective tissues, or bone marrow, while all 21 diagnosed cases had skin involvement. The findings suggest that white-rumped shamas have a unique inflammatory response to isosporosis with a predilection for the skin. Skin may be a diagnostically sensitive sampling site for histologic diagnosis of Isospora in this species.


Nondomestic, Exotic, Wild and Zoo Animals-Brief Communication
White-rumped shamas (Copsychus malabaricus) are small, Southeast Asian passerine birds common in aviaries. Isospora (formerly Atoxoplasma) is a genus in the family Eimeriidae comprised of ubiquitous apicomplexan protozoan parasites of passerine birds, closely related to Eimeria. 4,14 The life cycle involves both sexual and asexual reproductive stages in the intestinal epithelium, producing unsporulated oocysts that are shed in the feces. In the environment, these sporulate to become infective to new hosts via ingestion. Some Isospora species have an additional asexual, replicative stage in circulating mononuclear cells. Many passerines have coevolved with their hostadapted Isospora species, and infections are typically subclinical and often diagnosed incidentally by fecal examination. 14 If stressed or exposed to a high parasite load, fledglings may develop a severe and frequently fatal clinical syndrome characterized by lethargy, ruffled feathers, and diarrhea. 2,7,9,11,15 This syndrome can be associated with severe gastrointestinal inflammation from sexual stages in the intestine, systemic inflammation from circulating replicative stages, or both. Several studies in black siskins (Carduelis atrata), canaries (Serinus canarius), Gouldian finches (Chloebia gouldiae), and song sparrows (Melospiza melodia) with this severe form of isosporosis describe a lymphocytic, lymphoproliferative, or lymphohistiocytic inflammatory response affecting multiple organs, particularly the small intestine, liver, spleen, kidney, and lung. 3,5,6,10,12 In 2 of these studies, merozoites were shown by immunohistochemistry to parasitize lymphocytes specifically. 3,5 In 1992, 3 female white-rumped shamas were imported from Hong Kong to the San Diego Zoo. On assessment, all 3 were diagnosed with subclinical Isospora by fecal examination and were released to the exhibit following treatment. Four fledglings hatched from one of these females died suddenly in 1996. At postmortem examination, all 4 were noted to have a unique, systemic histiocytic response and intracytoplasmic inclusions within mononuclear inflammatory cells that were suspicious for protozoal parasites. Skin, proventriculus, air sac, and aorta from 1 case (bird 1) were submitted to the Armed Forces Institute of Pathology (AFIP), and skin from a second case (bird 5) was submitted to the Davis branch of California Animal Health and Food Safety (CAHFS) for electron microscopy. Both laboratories identified the intrahistiocytic organisms as apicomplexan protozoa. Based on fecal examination, impression smears, histologic appearance, and electron microscopy interpretation, these organisms were determined to be consistent with Isospora.
To better characterize this atypical presentation of Isospora infection in white-rumped shamas, necropsy and biopsy records of white-rumped shamas housed at the San Diego Zoo between 1992 and 2020 were searched for cases that included the terms "Isospora" and "Atoxoplasma," as well as white-rumped shamas with unexplained deaths, evidence of histiocytic inflammation, or skin lesions. Inclusion criteria for this study were defined as the presence of organisms consistent with Isospora identified on histology or cytology at the time of initial case submission and by secondary review. Twenty-one cases met the inclusion criteria, 19 of which were diagnosed histologically at necropsy and 2 of which were diagnosed by biopsy only. Polymerase chain reaction (PCR), which was not available at the time initial cases were identified, was performed on archived frozen tissues from 7 birds (cases 6, 12, 14, 16, 18, 19, and 20). Tissues tested included lung (n = 2), intestine (n = 6), liver (n = 2), heart (n = 1), or skin (n = 1) (see Supplemental Material 1). An additional 2 cases had Isospora diagnosed at necropsy but did not have further diagnostics or histologic sections available for review; these cases were excluded from the study summaries but are referenced in Supplemental Table S1.
Histologically, Isospora infection was characterized by multiple nodular to coalescing aggregates of epithelioid macrophages within multiple tissues including liver, spleen, gastrointestinal tract, skin, lung, pancreas, connective tissues, and bone marrow (Figs. 1-6). Macrophages were prominent and characterized by abundant, pale, finely granular eosinophilic cytoplasm that frequently contained between 1 and 3 round-to-ovoid, poorly distinguishable merozoites (Fig. 7). Merozoites measured approximately 2-4 µm in diameter, with a basophilic nucleus and a faint, clear, perinuclear halo. Ziehl-Neelsen acidfast stains were performed on 2 biopsies and 1 necropsy to rule out Mycobacterium sp. and were negative. Histiocytic     aggregates were occasionally surrounded by lymphocytic cuffs, most prominently within the liver and spleen; however, lymphocytes were not consistently present. A grading scheme was developed to characterize the spectrum of Isosporainduced inflammation in the most consistently collected and most widely affected tissues, including liver, spleen, gastrointestinal tract, and skin (Supplemental Tables S3-S5). Isosporaassociated lesions in the liver and spleen were graded into 4 categories based on the percentage of affected parenchyma, including severe (>60%), moderate (60%-30%), mild (10%-29%), and minimal (<10% or individual irregular histiocytes with intracytoplasmic protozoa). Sections of gastrointestinal tract were evaluated at 200× magnification and were graded into 3 categories from severe to mild based on numbers of macrophage aggregates within the field of view. Severe cases were defined as >5 aggregates per 200× field, moderate as 3-5 per 200× field, and mild as <3 per 200× field or individual, scattered histiocytes with intracytoplasmic protozoa. Skin lesions were qualitatively characterized as severe, moderate, mild, or minimal based on the degree to which nodules of affected macrophages coalesced and effaced the tissue structure. In all organs, the most severe lesion determined the final grade assignment.
Gastrointestinal tract inflammation was typically granulomatous and composed of multiple aggregates of atypical, merozoite-filled macrophages within the serosa or lamina propria. Sexually replicative stages within enterocytes were only identified in 2 cases. Lack of available frozen tissues prevented molecular confirmation of these gametocytes as Isospora related to the systemic lesions. Lesions in either feathered or nonfeathered skin were identified in all 21 cases and were the only histologic evidence of Isospora infection in 5 cases. Inflammation within the skin was often extensive despite absent, minimal, or mild lesions within the remaining tissues. In 12 necropsy cases with available liver and lung impression smears, clear intramonocytic inclusions with nuclear indentation, consistent with Isospora, were identified in 10 cases. Poor cell preservation was a common complicating factor.
Outbreaks of isosporosis in young captive passerines are well-recognized and are suspected to coincide with periods of high stress, immunosuppression, or overcrowding that lead to high environmental parasite burdens, and thus high infectious doses when exposed upon fledging. 1,3,[5][6][7]10,12,13 There is limited and largely species-specific documentation of gross and histopathologic lesions associated with Isospora infection. 3,5,6,10,12 In previously reported studies, there has been relative agreement on the typical gross and histologic findings, which include intestinal thickening, splenomegaly, and hepatomegaly or hepatopathy, and a primary lymphocytic to lymphohistiocytic response. The gastrointestinal tract has been the primary target organ in most of these previous cases, with intense and often transmural lymphocytic to lymphoproliferative infiltrates and smaller numbers of merozoite-containing lymphocytic cells in the spleen and liver. 3,5,6,10 One report also found intraendothelial merozoites in green-winged saltators (Saltator similis). 8 In our study, we observed that white-rumped shamas appear to have a unique, macrophage-dominant response associated with isosporosis. Lymphocytes were present in most but not all cases. Merozoites were reliably identified within macrophages and were not found in lymphocytes or any other cell. Inflammation targeted multiple organs with varying frequency, including the intestine, liver, and spleen. The skin was consistently affected in all examined cases, which has not been described in other passerines, and may prove a diagnostic site for both antemortem and postmortem detection of Isospora infection in this species. The shift in composition of Isospora-related inflammation in white-rumped shamas from lymphocytic to histiocytic may reflect a species-specific immune response to the parasite or may stem from antigens intrinsic to the infective Isospora species. Notably, only 2 birds in this study (both fledglings) had identifiable sexual stages of the organism in intestinal epithelium. Previous work suggests that these gametocytes likely represent the same organism as systemic merozoites. 14 While the lack of gametocytes in most cases may be attributable to sampling error due to the segmental nature of intestinal Isospora infection, it is also possible that the species of Isospora affecting this population of white-rumped shamas represents a nonhost-adapted strain, with exposure more commonly leading to systemic but nonpatent infection. Further studies examining the genetic and morphologic diversity of Isospora, host response, and cross-species infectivity are needed to better understand the pathogenesis of this parasite in both host-adapted and non-hostadapted infections.