Abstracts
This study aimed to characterize the morphology of the vas deferens ofKinosteron scorpioides by macroscopic and microscopic analysis. Were used 20 adult male jurarás collected at regular intervals during the year and divided into four experimental groups in the rainy and dry seasons, being processed for light microscopy, scanning electron microscopy and transmission electron microscopy. Morphometry for tubular and luminal diameters and epithelial height were also performed. On rainy season, vas deferens presented pseudostratified epithelium with cylindrical cells, spermatozoids and milky fluid in the lumen, with cytoplasmic organelles and lipid vesicles. On dry season, epithelium was pseudostratified with cuboid cells, with cellular debris and no spermatozoids. There was significant variation (p<0,05) for morphometry of vas deferens, with lower values of tubular and luminal diameters on rainy season, and higher epithelial height on dry season.
Kinosternon; Reproduction; Vas deferens; Morphometry; Ultrastructural
Este estudo teve como objetivo caracterizar a morfologia dos ductos deferentes deKinosteron scorpioides por meio de análise macroscópica e microscópica. Foram utilizados 20 machos adultos, coletados em intervalos regulares durante o ano, os quais foram divididos em quatro grupos experimentais nas estações chuvosa e seca. Os ductos deferentes foram processados para análise por microscopia de luz, microscopia eletrônica de varredura e microscopia eletrônica de transmissão. Morfometria para diâmetros tubular e luminal e altura epitelial também foram realizadas. Na época das chuvas, o ducto deferente apresentou epitélio pseudoestratificado com células cilíndricas, espermatozoides e líquido leitoso no lúmen, além de com organelas citoplasmáticas e vesículas lipídicas. Na estação seca, o epitélio do ducto deferente foi do tipo pseudoestratificado com células cuboides e debris celulares, sendo que nenhum espermatozoide foi encontrado nesta estação. Houve variação significativa (p <0,05) para a morfometria dos ductos deferentes, com menores valores de diâmetros tubular e luminal na estação chuvosa, e maior altura do epitélio na estação seca.
Kinosternon; Reprodução; Ducto deferente; Morfometria; Ultraestrutural
Introduction
Brazil has 35 species of chelonians distributed in its various terrestrial and aquatic ecosystems, of which 28 species are freshwater, two are terrestrial (land turtles), and 5 are marine turtles (SBH, 2005). The family Kinosternidae is composed of semi-aquatic species of small to medium size, being distributed from Canada to South America (Erns & Barbour 1989). It is composed of 22 species subdivided in four genus: Kinosternon, Sternotherus, Staurotypus and Claudius. In the Brazilian Amazon it is possible to found only one species of this family, Kinosternon scorpioides, also known as scorpion mud turtle (Molina & Rocha 1996MOLINA, F.B. & ROCHA, M.B. 1996. Algumas observações sobre a biologia e manejo do muçuã. Aquacultura. 2: 25-26.).
The scorpion mud turtle is preferably an aquatic species, and inhabits both stagnant and flowing water, being also able to develop semi-aquatic behavior (Pritchard & Trebbau 1984PRITCHARD, P.C. & TREBBAU, P. 1984. The Turtles of Venezuela. Society the study of amphibians and reptiles. Ithaca, 403p.). It displays a shell with three evident keels, especially the median, which runs through the shell in the longitudinal direction (Vanzolini et al. 1980). It also has a strong jaw and a structure similar to a nail at the end of the body, like a scorpion's stinger, which termed scientifically this species.
Kinosternon scorpioides is well distributed in the coast of South America, including Colombia, the Guianas and Trinidad. In Brazil it is found in the states of Pará, Maranhão, north of Goias, Ceará, Rio Grande do Norte and Pernambuco (Pritchard & Trebbau 1984PRITCHARD, P.C. & TREBBAU, P. 1984. The Turtles of Venezuela. Society the study of amphibians and reptiles. Ithaca, 403p.). In Maranhao its presence is confirmed on the edge of rivers (Pereira 2007), and it is considered an important species, both economically and as a source of protein.
The male reproductive system consists on a pair of oval testes of variable size, between light yellow to golden yellow color, and being fixed by mesorchium and mesocolon; epididymis located along the dorsal part of medial surface of each testis, being very delicate, presented as very convoluted structures of whitish color; and the vas deferens, which are continuous to the epididymis and culminate in the region of the cloaca. The vas deferens in jurará are a pair of simple structures, with a convoluted path that extends from the epididymis (Viana 2013) to the cloaca, with the function of transporting and storing spermatozoids. The penis, in turn, is grooved, and composed by the root, body and gland, located in the ventral floor of the cloaca, in which it attaches via a retractor muscle, and is protected by the foreskin (Carvalho et al. 2010CARVALHO, R.C., SOUSA, A., SILVA, A.L.A. & PEREIRA, J.G. 2010. Anatomia dos órgãos genitais do muçuã Kinosternon scorpioides macho (Chelonia, Kinosternidae). Pes. Vet. Bras. 30: 289-294, doi: 10.1590/S0100-736X2010000400001.
https://doi.org/10.1590/S0100-736X201000...
).
To our knowledge, this is the first study aimed to characterize the morphology of the vas deferens of Kinosteron scorpioides by macroscopic and microscopic analysis, contributing to describe the reproductive characteristics of this species and elucidate the spermatogenic cycle, strategies of sperm storage, and morphology of the reproductive tract.
Materials and methods
Were used 20 adult male Kinosternon scorpioides, from the capture ex-situ in the city of São Bento, state of Maranhão, Brazil, as authorized by IBAMA for the purpose of scientific activities with number 26136-1, and approval of the Ethics and Animal Research Committee of the Course of Veterinary Medicine (EAEC/UEMA), protocol number 011/2010.
The research was developed in the Laboratory of Veterinary Anatomy and Anatomopathology of the Course of Veterinary Medicine in the Center for Agricultural Sciences of State University of Maranhão - UEMA, Sao Luis - MA, and Laboratories of Light and Electron Microscopy, of the School of Veterinary Medicine and Animal Science of University of Sao Paulo - USP.
The animals were collected at regular intervals during the year and divided into four experimental groups in the rainy and dry seasons, the rainy season being understood by the collections of March/2011 and June/2011, and dry season being December/2010 September/2011.
The twenty animals were anesthetized with xylazine 2% (40mg/kg/IM) and ketamine hydrochloride 1% (60mg/kg/IM) and euthanized by administration of thiopental sodium 2.5% (60mg/kg/EV) by catheterization of the cervical venous sinus.
Subsequently, was held the opening of the coelomic cavity with steel handsaw, for the disarticulation of the bone bridge that connects the carapace and the plastron, and visualization and removal of the reproductive tract and isolation of the vas deferens, the processing being specific for each microscopy.
For light microscopy, the vas deferens were fixed in buffered formaldehyde 4% for about 24 hours for paraffin embedding. They were then dehydrated in increasing alcohol concentrations (70 ° - 100 °) and diaphanized in xylol, with an interval of switching between the solutions of 1 hour. After dehydration, the fragments were embedded in paraffin, sectioned at 4μm thickness, and stained with hematoxylin-eosin (HE), Masson's trichrome and periodic acid-Schiff - PAS, and examined under an optical microscope.
For scanning electron microscopy (SEM), the fragments were fixed in 2.5% glutaraldehyde, frozen for 72 hours and thereafter cryofracturated in liquid nitrogen, washed in 0.1 M phosphate buffer, post-fixed in osmium tetroxide 1% and dehydrated in series of alcohols (50 ° - 100 °). The samples were dried in a critical point apparatus Balzers CPD 020 using liquid CO2 and mounted on metal aluminum basis (stub), using carbon paste. Subsequently, were subjected to a metallic coating ("sputting") with gold in sputter device EMITECH K550, analyzed and photographed under a scanning electron microscope LEO 435VP.
For transmission electron microscopy (TEM), the fragments were fixed in 2.5% glutaraldehyde, washed in 0.1 M phosphate buffer and post-fixed in osmium tetroxide 1%. Subsequently, were dehydrated in series of increasing alcohols (50 ° - 100 °), propylene oxide and resin. The resin mixture was replaced by pure resin and placed in molds. The ultrathin sections were collected on copper screens and contrasted with uranyl acetate solution at 2% and 0.5% lead citrate. The samples were analyzed in transmission electron microscopy apparatus MORGANI 268d.
Images for morphometric studies were obtained using a binocular microscope Olympus BH-41 equipped with a digital camera for the photographic record. Histomorphometric analyses were performed with the aid of the program GIMP 2 to obtain the average height of the epithelium and the luminal and tubular diameters of the vas deferens, obtained with the use of micrometric ocular adapted to the microscope. Were made ten slides with three serial sections; the tubular sections have been made around the tubules in the base of epithelium, by the level of the the basal membrane, to obtain the total tubular diameter, and adjacent to the apical edge to obtain the luminal diameter, using a 10x objective. Similarly, a 40x objective was used for the measurement of the height of epithelium from its base to the apical edge.
Results
Vas deferens are continuous to the epididymis, presenting as a small structure, resembling a sinuous tube in its final portion, following lateral to ureters, and inserting on the dorsolateral wall of the cloaca, expanding in a shape of a small bulb.
In Kinosternon scorpioides, vas deferens observed by light microscopy presents as covered by pseudostratified cylindrical epithelium with secretory cells (Figure 1). Vas deferens also has a layer of dense connective tissue with the presence of blood vessels surrounded by muscle tissue. Inside the lumen are found spermatozoids and a milky fluid on the tubular center.
Histology of vas deferens of scorpion mud turtle (Kinosternon scorpioides) in rainy and dry seasons. A: vas deferens on rainy season with presence of spermatozoids in the lumen (Spz), pseudostratfied cylindrical epithelium (Pcy) and milky fluid (*). B: Vas deferens on dry season wish spermatozoids on luminal edges (Spz), pseudostratified cuboid epithelium (Pcu) and pseudostratified cylindrical epithelium (Pcy), with presence of dense connective tissue (Dct). Hematoxylin-eosin staining.
Structural morphology of vas deferens of scorpion mud turtle on the rainy season was a pseudostratified epithelium with cylindrical cells, spermatozoids in the lumen and milky fluid characteristic of semen, while on dry season were observed modifications, presenting pseudostratified epithelium with cuboid cells, absence of spermatozoa in the lumen and cellular debris.
Scanning electron microscopy of vas deferens by cryofracture technique showed disposition of spermatozoid on tubular epithelium and arrangement of dense connective tissue along to a muscular layer close to the blood vessels. It is believed that these elevations favor storage of sperm in the region (Figure 2).
Fotomicrography of scanning electron microscopy (SEM) of vas deferens of scorpion mud turtle (Kinosternon scorpioides). A: vas deferens, with pseudostratified cylindrical epithelium and spermatozoids in lumen (Spz). B: vas deferens, with evidence of tubular lumen (ℓ ), dense connective tissue (Dct) and muscular layer(Ml).
Transmission electron microscopy on rainy season showed spermatozoids, cytoplasmic organelles (mitochondria), indicating high metabolic activity, and lipid vesicles responsible by nutrition of spermatozoid during storage. On dry season, ultrastructural findings were disorganized and sparse cytoplasm, with endoplasmic reticulum, indicating protein production, and few spermatozoids (Figure 3).
Fotomicrography of transmission electron microscopy (TEM) of vas deferens of scorpion mud turtle (Kinosternon scorpioides). A: vas deferens on dry season with disorganized cytoplasm, presenting endoplasmic reticulum (yellow arrow), vesicle (red circle) and spermatozoids (blue arrow). B: vas deferens on rainy season with spermatozoids (Spz), mitochondria (yellow arrow) and lipidic vesicles (red arrow).
There was significant variation (p<0,05) between seasons for morphometry of vas deferens. The tubular and luminal diameters had lower values on rainy season. However, epithelial height in dry season had higher averages (Table 1).
Discussion
Although in scorpion mud turtle the vas deferens expands in a shape of a small bulb, this feature was not observed for the same species by Carvalho et al. (2010)CARVALHO, R.C., SOUSA, A., SILVA, A.L.A. & PEREIRA, J.G. 2010. Anatomia dos órgãos genitais do muçuã Kinosternon scorpioides macho (Chelonia, Kinosternidae). Pes. Vet. Bras. 30: 289-294, doi: 10.1590/S0100-736X2010000400001.
https://doi.org/10.1590/S0100-736X201000...
, which does not report the expansion of vas deferens before its insertion on the cloaca. Chaves (2011)CHAVES, L.P.F.A. 2011. Orgãos genitais masculino e nível sérico de testosterona de jurará (kinosternon scorpioides, linnaeus, 1766) criado em cativeiro na região da baixada maranhense no estado do maranhão. Dissertação (Mestrado em Ciências Animal) - Universidade Estadual do Maranhão, São Luís, 92p., however, described the same characteristic, characterizing this expansion in bulb shape on vas deferens of scorpion mud turtle.
By light microscopy, in snakes (Bothrops jararaca andCrotalus durissus), epithelial cells showed microvilli which were not observed in scorpion mud turtle, even though similar secretion was observed by the epithelium (Almeida-Sousa 2005). Similarity was described on close species, such as the crocodile (Guerrero et al. 2004GUERRERO, M.S., CALDERON, L.M., PEREZ, R.G. and PINILLA, M.P.R. 2004. Morphology of the male reproductive duct system of Caiman crocodilus (Crocodylia, Alligatoridae). Ann. Anat. 186: 235-245, doi: 10.1016/S0940-9602(04)80009-8.
https://doi.org/10.1016/S0940-9602(04)80...
), and birds, particularly in the rooster (Tingari 2001). In the snakeSeminatrix pygaea of South Carolina, was observed arrangement of spermatozoids tangent to the epithelium, most being slightly separated from epithelium (Ssever 2004).
Structural morphology was also closed to that observed in snakes, presenting lots of spermatozoa in the lumen of vas deferens in rainy season, indicating copulation period, when it is used as a storage organ; and decrease of spermatozoa in the lumen on dry season, indicating a postmating stage (Rojas et al. 2013ROJAS, C.A., BARROS, V.A., ALMEIDA-SANTOS, S.M. 2013. The Reproductive Cycle of the Male Sleep Snake Sibynomorphus mikanii (Schlegel, 1837) From Southeastern Brazil. J. Morphol. 274: 215-288, doi: 10.1002/jmor.20099.
https://doi.org/10.1002/jmor.20099...
). However, in rat snakes, although vas deferens is also the main sperm storage organ, spermatozoa is present in large numbers throughout all the year, except in July (Gang et al. 2011).
Scanning electron morphology in snakes reported vas deferens as being an organ of spermatozoids storage (Almeida-Sousa 2005),. In this study of scorpion mud turtle, it is believed that vas deferens is also adapted for storage, due to its structural characteristics such as absence of cilia or stereocilia in the cells. On crocodiles (Caiman crocodilus), non-ciliated cells were also found, indicating storage function of vas deferens in another species of reptiles (Guerrero et al. 2004GUERRERO, M.S., CALDERON, L.M., PEREZ, R.G. and PINILLA, M.P.R. 2004. Morphology of the male reproductive duct system of Caiman crocodilus (Crocodylia, Alligatoridae). Ann. Anat. 186: 235-245, doi: 10.1016/S0940-9602(04)80009-8.
https://doi.org/10.1016/S0940-9602(04)80...
).
Transmission electron microscopy also presented lipid vesicles in snakes on the rainy season, which are responsible for nutrition of spermatozoids (Rojas 2013). On dry season, the visualization of spermatozoa in the lumen demonstrates that the organ is in reproductive activity. On domestic quails, was reported that vas deferens showed little annual variability, with a significant increase in tubular caliber, intraluminal storage of spermatozoids and occurence of mitochondria, lysomes, endoplasic reticulum and variable vesicles in the cytoplasm of principal cells. These ultrastructural features of principal cells seems to be indicative of the occurence of active processes of endocytosis, and degenerative characteristics were observed at the supranuclear cytoplasm of epididimary P cells on autumn (Orsi et al. 2007ORSI, A.M., DOMENICONI, F.R., SIMõES, K., STEFANINI, A.M. & BARALDI-ARTONI, S.M. 2007. Variabilidade sazonal no ducto epididimário de codorna doméstica: observações morfológicas. Pesq. Vet. Bras. 27: 495-500, doi: 10.1590/S0100-736X2007001200005.
https://doi.org/10.1590/S0100-736X200700...
). On crocodiles, endoplasmic reticulum was also abundant, indicating protein production, despite of absence of visible secretory material (Guerrero et al. 2004GUERRERO, M.S., CALDERON, L.M., PEREZ, R.G. and PINILLA, M.P.R. 2004. Morphology of the male reproductive duct system of Caiman crocodilus (Crocodylia, Alligatoridae). Ann. Anat. 186: 235-245, doi: 10.1016/S0940-9602(04)80009-8.
https://doi.org/10.1016/S0940-9602(04)80...
).
By morphometry, the decrease of tubular and luminal diameters, along with increase of epithelial heighs on rainy season, are correlated to seasonal variations in synchrony with the spermatogenic and epididymal cycles. In the same sense, was described in snakes (Cerastes vipera and Psammophis sibilans), a larger diameter and short epithelial linings during reproductive season as a result of elongation of stored spermatozoids (Sivan et al. 2012SIVAN, J., KAM, M., HADAD, S., DEGEN, A.A., ROZENBOIM, I. & ROSENSTRAUCH, A. 2012. Reproductive cycle of free-living male Saharan sand vipers, Cerastes vipera(Viperidae) in the Negev desert, Israel. Gen. Comp. Endocrinol. 179: 241-247, doi: 10.1016/j.ygcen.2012.08.021.
https://doi.org/10.1016/j.ygcen.2012.08....
, AMER et al. 1978).
We conclude that vas deferens is the main sperm storage organ on the scorpion mud turtle, presenting a large number of spermatozoids in reproductive season, and morphological findings that represent an adaptation to its function. However, on dry season, the storage was smaller, indicating that organ is in reproductive activity, but production of spermatozoids is reduced in comparison to the rainy season. Further studies on hormonal levels and quality of spermatozoids are suggested, in order to refine the knowledge on the reproductive biology of Kinosternon scorpioides.
Acknowledgments
The authors would like to thank the State University of Maranhão (UEMA), the National Program of Academic Cooperation (Procad I-CAPES/UEMA/USP Amazon) and the Foundation for Research Support of the State of Maranhão (FAPEMA) for funding current research.
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Publication Dates
-
Publication in this collection
Sept 2014
History
-
Received
05 Nov 2013 -
Accepted
10 July 2014