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Cutaneous Chlorellosis in a Gazelle (Gazella dorcas)

Abstract

Cutaneous chlorellosis in a gazelle caused a chronic granulomatous inflammation in the subcutaneous tissue of the carpus. The diagnosis was based on the intense green color of the lesion and the presence of organisms identified as algae of the order Chlorellales. According to morphologic and ultrastructural features, the genus Bracteacoccus is most likely.

Key words: Bracteacoccus; Chlorella; dorcas gazelle; histopathology; skin; ultrastructure.

Compared with mycoses, algal infections are rare in mammals and human beings.^6,10,12 The infection manifests as cutaneous lesions or systemic disease. In animals, infections have been described in cattle,¹⁴ sheep,^2,8,16 a dromedary,⁹ and probably a beaver.¹⁵

The Chlorellales is an order of chlorophyll-containing coccal green algae. The various genera of the Chlorellales must be differentiated from the genus Prototheca. Prototheceae are unicellular, achlorophyllous organisms belonging to the same phylogenetic group as green algae of the genus Chlorella.¹³ Unlike Prototheca, members of the genus Chlorella contain abundant periodic acid–Schiff (PAS)-positive cytoplasmic granules, which represent starch and chloroplasts.^1,4,7,11

The infected gazelle belonged to a flock of seven animals kept in an enclosure of gravel and scarce vegetation that was completely surrounded by a fence of wire netting and without a moat. The 10-year-old female gazelle suffered an injury, presumably caused by wire, in the left carpal region. The animal was immobilized, and a firm green lump approximately 4 cm in diameter, which was thought to be an abscess, was removed surgically. The wound was dressed and treated locally and systemically with antibiotics. Two days later, healing of the wound appeared to be progressing. Local treatment was repeated by antibiotic spray without immobilization. Seven months later, a mass 2 cm in diameter recurred in the same location and grew to 4 cm in diameter within 3 weeks. Because the gazelle was pregnant, it was not treated. Four months later, after the animal gave birth, the mass, now a suspected neoplasm, was removed surgically and submitted for histologic examination. The animal did well after surgery. However, 19 months after the first excision the lesion recurred again at the site of the operation, and the gazelle was euthanatized.

The specimen submitted for examination consisted of an ovoid mass approximately 4 cm in maximum diameter and covered by hairy skin. The cut surface was of a striking yellow-green color. It was well demarcated from the surrounding subcutaneous tissue by a capsule of fibrous tissue and had a lobular, almost cystic appearance due to fibrous strands within (Fig. 1).

View larger version (145K): [in this window] [in a new window]   Fig. 1. Forelimb; dorcas gazelle. Cutaneous mass has an ulcerated surface (above). The cut surface has a lobulated appearance (below) and a yellow-green color. Fig. 2. Cutaneous mass; dorcas gazelle. Granulomatous inflammation showing abundant algal cells surrounded by fibroplastic strand (FP) and lymphoplasmacytic infiltrates (LP). Methacrylate, Giemsa. Fig. 3. Cutaneous mass; dorcas gazelle. Single cells of coccal green alga with autospore formation (asterisks), which is a characteristic feature of the order Chlorellales. Methacrylate, Giemsa. Fig. 4. Cutaneous mass; dorcas gazelle. The algal cells contain abundant PAS-positive material (asterisk = autospore formation). Methacrylate, PAS.

The mass consisted mainly of granulomatous inflammatory tissue. Between broad strands of fibrous tissue, there were large accumulations of macrophages, many of them ghost cells within areas of necrosis. A myriad of spheric to slightly ovoid organisms, identified as algae apparently were the cause of this tissue reaction (Fig. 2). Fibroplasia of variable degree was also present. Lymphoplasmacellular infiltration and multinucleated giant cells were scarce. The algal cells were 10–45 µm in diameter and obviously represented different developmental stages (Fig. 3). In HE-stained sections, two main types could be distinguished: small cells with thin cell walls and cytoplasmic basophilic granules that stain strongly by PAS (Fig. 4) and large cells with thick cell walls that were translucent with a slightly eosinophilic (cloudy) center.

Numerous organisms could not clearly be identified as belonging to the two main types described above. They were considered transitional stages. A few algal cells were in the process of cell division. In necrotic areas, dystrophic calcification was seen. Corresponding to the gross finding in the HE-stained paraffin-embedded sections (± 6 µm thick), a green color of some cells could be seen that was not clearly visible in methacrylate embedded Giemsa-stained sections (± 1 µm).

Only formalin-fixed material was used for transmission electron microscopic examination (Figs. 5–7). In cross section, single cells were more or less spherical with diameters of approximately 20 µm. Frequently, clusters of cells within a common cell wall were observed, representing typical autospores (Fig. 6), which are flagellum-free endospores that form within the cell wall of the mother cell. Because of the coccosiphonal organization (unicellular, multinucleated), cross sections of large algal cells exhibited up to seven randomly distributed nuclear profiles. The cell wall varied in thickness from 1 to 2 µm, with irregular local thickenings. Typically, a distinct coating (= sporopollenin layer) with a thickness of approximately 200 nm was visible as an electron-dense layer. Most of the cytoplasmic area was occupied by typical lipid bodies 1 µm in diameter with an electron-translucent homogeneous matrix and a half-unit membrane as a boundary. In addition, larger osmiophilic globules (diameter ca. 1.5 µm) were observed. These globules may represent a second population of lipid bodies with a different lipid composition. Chloroplasts were numerous; within one cross section about 25 rather small chloroplasts (1–2 µm) could be seen (Fig. 5). Thylakoid stacks, part of the internal membrane system of chloroplasts, were made up of three to five thylakoids. Plastoglobules (small plastidal lipid bodies) with diameters of 50–75 nm and starch grains were frequently observed (Fig. 7). Pyrenoides, definded as protein-rich globular structures involved in starch accumulation, were absent.

View larger version (170K): [in this window] [in a new window]   Fig. 5. Transmission electron micrograph. Cutaneous mass; dorcas gazelle. Coccal green algal cell contains numerous chloroplasts (Ch) and lipid bodies (LB). A second type of lipid body–like osmiophilic globules (OG) is visible. The cell wall (CW) is rather thick and covered by a prominent sporopollenin layer (SP) (N = nuclei). Uranyl acetate, lead citrate. Fig. 6. Transmission electron micrograph. Cutaneous mass; dorcas gazelle. Algal cells show autospore formation. Fig. 7. Transmission electron micrograph. Cutaneous mass; dorcas gazelle. Algal cells have chloroplasts (Ch) with small starch grains (S) and plastoglobules (arrows) (CW = cell wall; LB = lipid bodies).

Because most species of this genus are aerophytic or terrestrial, a secondary infection of the skin with a member of this algal genus is not unlikely. In addition, a member of this genus would be able to survive in tissues under these deficient conditions. Chlorellosis in animals might be caused by different species of the order Chlorellales. Ultrastructural investigation of granulomatous enteritis in a camel⁹ revealed much smaller green algal cells (5–11 µm in diameter) with a single nucleus, which obviously belong to another genus.

The mode of infection remains unclear. Probably an unobserved small wound facilitated the primary infection with bacteria and secondary infection with spores of the facultative pathogenic alga. A primary bacterial infection might have caused a purulent inflammation, providing conditions for the alga to multiply in the subcutaneous tissues and cause the granulomatous inflammation.

Acknowledgments

We thank Dr. Julia von Maltzan for providing the clinical data.

References

1. Chandler FW, Kaplan W, Callaway CS: Differentiation between Prototheca and morphologically similar green algae in tissue. Arch Pathol Lab Med 102:353-356, 1978[Medline]
2. Cordy DR: Chlorellosis in a lamb. Vet Pathol 10:171-176, 1973[Medline]
3. Ettl H, Gärtner G: Syllabus der Boden-, Luft- und Flechtenalgen [Syllabus of Algae in Soil, Air and Lichens]. pp 371-373, 465-471, Gustav Fischer Verlag, Stuttgart, Germany 1995
4. Gibbs SP: The comparative ultrastructure of the algal chloroplast. Ann NY Acad Sci 175:454-473, 1970
5. Hoek van den CH, Jahns HM, Mann DG: Algen [Algae]. pp 229-266, Georg Thieme Verlag, Stuttgart, Germany 1993
6. Jones JW, McFadden HW, Chandler FW, Kaplan W, Connor DH: Green algal infection in a human. Am J Clin Pathol 80:102-107, 1983[Medline]
7. Kaplan W: Protothecosis and infections caused by morphologically similar green algae. In: Proceedings of the Fourth International Conference on the Mycoses, Scientific Publication 356, pp 218-232, PAHO, Washington, DC 1978
8. Kaplan W, Chandler FW, Choudary C, Ramachandran PK: Disseminated unicellular green algal infection in two sheep in India. Am J Trop Med Hyg 32:405-411, 1983
9. Le Net JL, Fadl Ahmed M, Saint-Martin G, Masson MT, Montois C, Longeart L: Granulomatous enteritis in a dromedary (Camelus dromedarius) due to green algal infection. Vet Pathol 30:370-373, 1993[Medline]
10. Modly CE, Burnett JW: Cutaneous algal infections: protothecosis and chlorellosis. Cutis 44:23-24, 1989[Medline]
11. Nadakavaren MJ, McCracken DA: An ultrastructural survey of the genus Prototheca with special reference to plastids. Mycopathologia 61:117-119, 1977[CrossRef]
12. Nelson AM, Neafie RC, Connor DH: Cutaneous protothecosis and chlorellosis, extraordinary, "aquatic-borne" algal infections. Clin Dermatol 5:76-87, 1987[Medline]
13. Ramsy E, Chandler FW, Connor DH: Protothecosis. In: Pathology of Infectious Diseases, ed. Conner DH, Chandler FW, Schwartz DA, Manz HJ, Lack EE. pp 1067-1072, Appleton & Lange, Stamford, CT 1997
14. Rogers RJ, Connole MD, Norton J, Thomas A, Ladds PW, Dickson J: Lymphadenitis of cattle due to infection with green algae. J Comp Pathol 90:1-9, 1980[CrossRef][Medline]
15. Sileo L, Palmer NC: Probable cutaneous protothecosis in a beaver. J Wildl Dis 9:320-322, 1973[Abstract/Free Full Text]
16. Zakia AM, Osheik AA, Halima MO: Ovine chlorellosis in the Sudan. Vet Rec 125:625-626, 1989[Medline]

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