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Revista da Sociedade Brasileira de Medicina Tropical

Print version ISSN 0037-8682On-line version ISSN 1678-9849

Rev. Soc. Bras. Med. Trop. vol.32 n.4 Uberaba July/Aug. 1999

http://dx.doi.org/10.1590/S0037-86821999000400002 

ARTIGO

Contribution to the histology of Biomphalaria glabrata

Contribuição à histologia da Biomphalaria glabrata

 

Queli Teixeira Lemos

 

 

Abstract A combination of histological techniques applied to the study of Biomphalaria glabrata yielded some interesting new data about the histology of this snail, a major intermediate host of Schistosoma mansoni in Brazil. Three kinds of pigments were identified: a dark pigment which bleached following oxidation with potassium permanganate; a lipofuchsin-like, diastase-resistant PAS-positive pigment and an iron-containing pigment, probably related to hemosiderin. Calcium was detected in small deposits within the connective tissue and forming a dense core inside the chitinous radular teeth. The presence of fibrils, staining with sirius-red and birefringence under polarized light strongly suggest primitive collagen tissue. The radular apparatus appeared as a storing site for glycogen, while abundant Alcian-blue positive material (proteoglycans) was extremely concentrated in the radular sac.
Key-words: Biomphalaria glabrata. Histology. Pigments

Resumo Uma combinação de várias técnicas histológicas permitiu alguns achados de interesse para a histologia da Biomphalaria glabrata, principal hospedeiro intermediário do Schistosoma mansoni no Brasil. Três tipos de pigmentos foram identificados: um pigmento escuro, que se descora após oxidação pelo permanganato de potássio; outro que é semelhante à lipofuscina, que se cora pelo PAS e é diastase- resistente, e um pigmento que contém ferro, provalvelmente, relacionado com a hemossiderina. O cálcio foi identificado em pequenos depósitos no interior do tecido conjuntivo e formando pequenos núcleos no interior dos dentes quitinosos da rádula. A presença de fibrilas coradas pelo sírius-vermelho, exibindo birrefrigência sob luz polarizada, sugere fortemente a presença de um tecido colágeno primitivo. O aparelho radular foi visto como um local de armazenamento do glicogênio, enquanto a presença de abundante material amorfo positivo para o azul de alciano (proteoglicano) apareceu em grande concentração no saco radular.
Palavras-chaves: Biomphalaria glabrata. Histologia. Pigmentos.

 

 

The histology of Biomphalaria glabrata is now well known. Besides the classical study of Pan9 there are several others3 4 7 10, concerning not only the optical microscopic appearance, but also ultrastructural and histochemical features. However, there remain some controversies about the true nature of the extracellular matrix, especially whether true collagen fibers are present in it. Also, there are some other aspects which seem little explored, such as those related to the nature and significance of pigments present in snails and the composition and histophysiology of the glandular and radular apparatus.

As an important step toward a program for a large study of experimental schistosomiasis, the need for a better understanding of B. glabrata histology was felt. In the present investigation normal, adult, laboratory raised specimens of B. glabrata were microscopically examined with the help of a battery of staining methods to attempt a contribution on some obscure and controversial issues.

 

MATERIAL AND METHODS

Adult B. glabrata from Feira de Santana, Bahia, Brazil, raised from eggs within aquarium at the Gonçalo Moniz Research Center (Fiocruz) Salvador, Bahia, Brazil and measuring approximately 12mm diameter, were anesthetized with menthol crystals in water during 40 minutes. After the shell was carefully broken, the soft parts of the mollusk were removed and immediately fixed either in Bouin's fluid added of acetic acid or in phosphate buffered 10% formalin. Fixation in Bouin lasted for six hours, the tissues being conserved in 70% alcohol thereafter. After paraffin embedding, the 5µm sections obtained were submitted to the following staining techniques: hematoxilyn and eosin, Masson's trichrome, Movat's pentachrome stain, periodic acid Schiff (PAS) either with and without previous diastase treatment, alcian blue, orcein for elastic fibers, Gomori's reticulum impregnation, Mayer's mucicarmin for mucin (with mouse intestinal mucosa as control), Van Kossa for calcium, Perls for iron, Woelckes for myelin and potassium permanganate for tissue breaching. Techniques were performed according to the instructions on the AFIP Manual12. Slides were also stained with the picro-sirius-red method, according to Junqueira et al5, and microscopically examined with or without polarized light.

 

RESULTS

The diverse staining methods utilized allowed for a good general review of the histology of B. glabrata. However, the present results concern only those aspects on which possible addition to present knowledge is presumed.

Pigments. Three types of pigments appeared prominent in the sections examined: a) a dark brown or black pigment was abundant along the basal portion of the superficial epithelial lining which cover the entire molluscan body. This pigment completely disappeared after treatment of the section with potassium permanganate (Figures 1 and 2); b) a yellowish granular pigment found in different tissues, but mainly in the connective tissue of the mantle collar, both extra and intracellularly. This pigment was PAS positive, diastase resistant and did not bleach following potassium permanganate treatment. The third type of pigment presented with a brownish hue and was iron-positive. It was the most abundant of the pigments found in the sections. A relatively abundant amount was seen within the tubular portion of the kidney and in the digestive glands (Figure 3). The ovotestis contained a large amount, especially within the ovule and spermatozoid heads. Iron-positive pigment was also present at the basal layer of the external epithelial covering, in focal areas, together with the dark melanin-like pigment above described.

 

 

 

 

 

 

Radular apparatus. The radular apparatus is composed of different structures, therefore presenting a complex histology. It includes the radular sac, the radula carrier, the radula itself and the protractor and retractor muscles. The radula carrier is formed by large, plump, vesicular cells with well defined external membrane, arranged side by side, sometimes interposed by smooth muscle cells. The latter is well visualized when stained in red by the Movat' s pentachromic method. The plump cells contain a large amount of glycogen (PAS positive, diastase removable) (Figure 4). The radular sac, where the radula takes origin, is actually a proteoglycan-rich structure, strongly alcian-blue positive. Its content of PAS-positive material is rather scanty. The radula is represented by a thick basement membrane on which a thick chitinous layer is implanted (Figure 5). This layer has a saw-like structure representative of teeth, in the center of each of them a condensed calcium-containing material is seen (Figure 6).

 

 

 

 

 

 

Digestive glands. These structures were remarkable for the presence of numerous secretory granules located within the high cubic and cylindrical epithelial cells making the tubular glands. The granules were more often located at the superior pole of the cells, varied in size and amount for a same gland and much more so in different individuals (Figure 7). They were PAS-positive and diastase resistant, strongly alcian blue-positive, but did not stain for mucin. Diffuse and focal PAS-staining, resistant to diastase digestion, was also observed in the cytoplasm of epithelial cells throughout the molluscan tissues, especially in the nidamental and albumen glands.

 

 

Extracellular matrix fibers. In areas with abundant connective tissue, such as the foot region, the mantle collar, esophagus and peri-esophageal region, numerous thin and long fibers were seen forming sometimes a cris-crossing pattern. Others fibers had a wavy appearance (some of them stained as elastic fibers by orcein), while others were thick, with variable degree of thickness and oriented in several directions. These thin and thick fibers took a strong red staining with sirius-red and appeared birefringent and with striated periodicity under polarizing light (Figure 8). The color hue varied from red to yellowish. Sometimes, especially at the foot region, fine fibrils forming an argirophilic network were also observed.

 

 

DISCUSSION

The results presented above were selected as the most representative obtained in the present study. There is some reluctance to identify or even compare findings in invertebrate histology with those of superior animals. That attitude is of course correct, since differences do exist between them. However, from a practical point of view it is interesting to stress similarities rather than differences. For instance, the pigments found in B. glabrata are morphologically and chemically very similar to the main pigments found in vertebrates, including man. The so-called melanin-like pigment so abundant in B. glabrata, behaves as their human counterpart, undergoing complete bleaching after being peroxidized by potassium permanganate. The two other pigments are similar to lipofuscin and hemosiderin, respectively. There is an iron-containing pigment present in hemolymph1 2 8. In the tissues the iron-containing pigment may represent iron storage. On the other hand, Its prominent presence in the tubular portion of the kidney may be related to excretion of excess pigment. it is also abundant in the ovo-testis and related structures11.

The radula carrier appears as an important site of storage for glycogen, while the radicular sac is rich in proteoglycan, which is in keeping with its function as both cushion and support for the radula. The suggestion that the serrilhated part of the radula represents primitive teeth is supported by the present demonstration of a calcium nucleus within each one of them.

The findings showing variation in size, density and number of PAS-positive diastase-resistant granules in the glandular epithelium seen in different parts of the same gland and, better still, in glands from different specimens indicate that the activity in these glands pass through functioning cycles and is far from uniform. Probably there occur waves of functional activity along the glandular epithelial line. The exact nature of the granules has not been determined, but present findings are consistent with the presence of a complex glycoprotein content. However no evidence of mucin could be demonstrated, nor the presence of caliciform cells.

Fibers with staining characteristics of collagen have been demonstrated in several locations, usually accompanied by a few orcein-positive elastic fibers and an occasional net of argirophilic reticular fibrils. The observation of refringent fibers when sirius-red stained sections are viewed under polarizing light is considered to be diagnostic of collagen fibers5 6. This is important to register because the encapsulating or granulomatous lesions seen around disintegrating S. mansoni sporocysts usually present concentric collagen-like fibers that do not take the sirius-red staining and show no refringence13. After seen such lesions on optical microscope preparations one may doubt whether true collagen fibers are formed in B. glabrata at all. Actually these fibers around the encapsulating lesions (granulomas) are formed by cytoplasm prolongation from numerous amebocytes, as can be seen under the electron microscope7. It rests to be demonstrated whether stromal reaction in B. glabrata is characterized by the production of fibrosis, with neoformation of collagen fibers. The behavior of the extracellular matrix in B. glabrata is indeed a point of considerable interest in comparative pathology and needs further study.

 

ACKNOWLEDGEMENT

Thanks are due to Dr. Zilton A. Andrade for orientation and support.

 

REFERENCES

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10. Pan, Chia-Tung. Some biochemical and immunological aspects of host-parasite relationships: Generalized and focal tissue responses in the snail Australorbis glabratus, infected with Schistosoma mansoni. Annals New York Academy Science 113:475-485, 1963.         [ Links ]

11. Paraense WL. The sites of cross and self-fertilization in planorbid snails. Revista Brasileira de Biologia. 36:535-539, 1976.         [ Links ]

12. Prophet EB, Mills B, Arrington JB, Sobin LH. Laboratory Methods in Histotechnology. Armed Forces Institute of Pathology, Washington. 1992.         [ Links ]

13. Souza CP, Cunha RC, Andrade ZA. Development of Schistosoma mansoni in Biomphalaria tenagophila, Biomphalaria straminea and Biomphalaria glabrata. Revista do Instituto de Medicina Tropical de São Paulo 37:201-206, 1995.         [ Links ]

 

 

Laboratório de Patologia Experimental, Centro de Pesquisas Gonçalo Moniz / FIOCRUZ. Rua Valdemar Falcão/ 121, 40925-001 Salvador, BA, Brasil.
Address to: Drª Queli Teixeira Lemos. Centro de Pesquisas Gonçalo Moniz (FIOCRUZ). Rua Valdemar Falcão 121, Brotas, 40295-001 Salvador, BA, Brasil, Tel: 55 71 356-8787, Fax: 55 71 356-4292.
Recebido para publicação em 3/4/98.

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