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Veterinary Medicine International
Volume 2014 (2014), Article ID 358158, 5 pages
Gross and Morphometric Anatomy of the Male Reproductive System of Bats (Eidolon helvum)
1Department of Veterinary Anatomy, Faculty of Veterinary Medicine, Usmanu Danfodiyo University, P.M.B 2346, Sokoto, Nigeria
2Department of Theriogenology and Animal Production, Faculty of Veterinary Medicine, Usmanu Danfodiyo University, P.M.B 2346, Sokoto, Nigeria
3Department of Veterinary Parasitology and Entomology, Faculty of Veterinary Medicine, Usmanu Danfodiyo University, P.M.B 2346, Sokoto, Nigeria
Received 23 December 2013; Accepted 19 February 2014; Published 26 March 2014
Academic Editor: Kazim Sahin
Copyright © 2014 A. Danmaigoro et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
The present study aimed at examining the gross and morphometry of the reproductive tract of the male bats (Eidolon helvum). Thirty male bats (adults and juveniles ) were captured using net, weighed, aged using relative ossification of the wing bone, and dissected for gross examination. Morphologically, the mean body weight and forearm length in both adults and juveniles were g, cm and g, cm, respectively. The testicles were completely descended in adults with the penis projected cranially. The epididymides were found at the median border of the testis and continues as vas deferens. No significant differences were observed between right and left testicular weights in both adults and juveniles and also in lengths of different parts of the reproductive segments in both age groups assessed, respectively. This work has documented the gross anatomy of the male reproductive tract in bats. Ultrastructure and histochemistry are recommended for further insight into the reproductive biology.
Bats (Chiroptera) are among the most diverse and widely distributed groups of mammals and can be found in all continents except in Antarctica . There are around 1,150 species of bats. Bats are second to rodents in terms of numbers of genera and species, which represent nearly a quarter of all the species of mammals on earth with majority living in tropical and semitropical regions .
Bats are the only flying mammals and they have a wide range of feeding and roosting habits, social behaviours, and reproductive strategies . Their nocturnal habits and diversity in their biology not only make bats a fascinating group of animals to study but also a difficult one.
The diversity and abundance of bats are probably attributable to a number of features, such as their biology, that are unique and most of their life tracks do not conform to typical mammalian patterns . Eidolon helvum is commonly found in moist and dry tropical rain forest .
The gonads and excretory structures embryologically develop from the intermediate mesoderm of the hindgut, with the gonadal ridge being formed as the precursor to gonad development . The gonads arose as ridge-like thickening which in turn became thicker as the gonad differentiates to the primordial germ cells of the gonads .
The reproductive tract of male mammals usually consists of the testes and associated epididymis, vasa deferentia, accessory sex gland complex, urethra, and penis. The accessory sex gland complex consists of ampullary, prostate, urethra and Cowper's glands, and seminal vesicles . However not all glands are present in every mammalian order  and in the Chiroptera as revealed by Bernard  on Rhinolophus capensis.
In recent years, bats have been implicated in numerous emerging infectious diseases and are increasingly recognized as important reservoir hosts for viruses that can cross species barriers to infect humans and other domestic and wild mammals . Bats also have high ecological and economic importance due to their role in seed dispersal and serve as source of protein when taken as bush meat.
The gross anatomy of this system varies widely among different mammalian species . Thus, variations exist between species in terms of the position of their reproductive structures. Some works on the physiology, breeding, and pathology of reproductive organs of the female bats [12–16] have been reported in different countries including Nigeria. Good understanding of the reproductive biology particularly that of the male reproductive system is very vital. Although E. helvum is found widely distributed in Northwestern Nigeria, little is known about its male reproductive morphology. This work is aimed at studying the gross and morphometry of the male reproductive tract of the bat (Eidolon helvum).
2. Materials and Methods
2.1. Source of Bats
A total number of thirty (30) male bats were used for the study (adult and juvenile ). Bats were sourced from Zuru town, Kebbi State in Northwestern Nigeria. The capturing process involved the use of hand nets with extendable poles, during daytime at the roosts of the bats. The bats were held in plastic cages with leaves hung on the ceilings of the cages to provide roosts for the bats and transported to the laboratory.
2.2. Bat Identification
Species were identified at the Zoological Laboratory Unit, Department of Biological Sciences, Usmanu Danfodiyo University, Sokoto, Nigeria. The following features were used for identification of the species as described by . Males are usually larger than females and are bright orange in colour while females are usually yellowish in colour. The wings are long and tapered at the tip. The cheeks are also large and pouch-like. The neck and back displayed yellow colour, with the ventral side of the body being brown or grey. The head is large and pointed with white facial markings.
2.3. Age Estimation
Age estimation was achieved using relative ossification of the wing bones (4th metacarpal joint and phalanges) by transilluminating the wing of the bats using torchlight to visualize the cartilaginous zone of the long phalanges while the wing of the bat is being spread over a transparent solid plastic sheet lightened from below, so as to distinguish between juveniles and adults as described by .
Following anaesthesia using chloroform (Prolabo, May, and Baker, Nigeria), the bats were sacrificed by severing the jugular vein and then placed on dorsal recumbency and a midline incision was made, extending from the xiphoid cartilage to the pubic symphysis. The peritoneum was reflected and intestines were displaced to gain access to the reproductive tract as described by . Organs were examined in situ and exteriorized. Gross features of the reproductive tract were carefully examined and recorded. The length, width, circumference, and weight of the reproductive organs were measured using ruler, thread, and weighting balance (Shimadzu AW320, Germany), respectively. Photographs of the reproductive structures were taken using a digital camera (Canon, S1 S3, Tokyo, Japan, 7.5 megapixels).
2.5. Data Analysis
The data obtained were subjected to statistical analysis using InStat statistical package, version 3.05 (2000), in which descriptive statistic and Student -test were used to check the significant differences between the weights of the testes and length of the structures (testes, epididymides, vas deferens, and penis) with ages and paired structures, where the probability of <0.05 was considered to be significant.
The average body weights and mean forearm length of 235.31 ± 6.30 g and 12.14 ± 0.19 cm were obtained in the adult while 69.54 ± 7.68 g and 7.7 ± 0.29 cm were obtained in the juvenile bats as shown in Table 1.
Just like other species, the bats were found to have paired testes, epididymis, and vas deferens with penis as shown in Figures 1 and 2. The testes are paired and migratory and seen outside the abdominal cavity, between the skin and muscles near the crest of the pubis lateral to the base of the penis. The testes were completely descended into the scrotum in adult bats and were ovoid shaped and milky-white in colour (Figures 1 and 2). The testes were covered with skin and enclosed by strong stroma (tunica albuginea).
The epididymis was observed to be an elongated and convoluted tube that lies firmly attached laterally to the testis. It covers the superior pole of the testis and connects by a narrow corpus epididymis to a prominent cauda epididymis projecting from the distal border of the testis. Macroscopically, the three main segments, caput (head), corpus (body), and cauda (tail), were observed (Figure 3).
Qualitatively, the cauda epididymis was found more enlarged and highly coiled in the adult and was found to be in a straightened tubular-like form in the juvenile.
The vas deferens which is a continuation of the cauda epididymis is more straightened and tubular and was observed to be more muscular than the epididymis (Figure 4).
The penis was observed as a cylindrical organ suspended from the pubic arch. It is broader proximally but tapers distally and projected cranially. It takes origin as two crurawhich unite beneath the pubic symphysis near its cranial margin (Figure 4).
Table 2 shows the mean testicular weight and length of different parts of reproductive tract in both adult and juvenile bats with no significant difference between the right and left testicular weights and between their sizes (length, breath, and circumference) and also between right and left epididymes and vas deferens.
No significant difference was observed between the penile length of the adult and juvenile (Table 2).
The body mass obtained was in line with the findings of , who reported a range of mean body mass of 230–330 g in adult male. The length of the forearm as observed in this study does not differ in any way from the findings of  who obtained a mean length of forearm of 117 to 132.0 mm in adult male. The work in  reported that there is strong direct relationship between the reproductive status and body condition index and that the body condition index is very important for gonadal development.
As observed from these studies, the bat reproductive tract has great similarity to that of other mammals. This finding is in agreement with report of , that gross structures of the reproductive organs in bat follows the normal mammalian pattern. Morphologically, the male reproductive tract is constituted by the testis, epididymis, vas deferens, and penis and this was also reported by .
In this study the shape and colouration of the testes were in agreement with the report of , in Cynopterus sphinx gangeticus bat, that the testes were ovoid in shape with creamy to milky-whitish colouration, whereas the location of the testis which is in the scrotum was contrary to that of , who reported that the testes of Cynopterus sphinx gangeticus were found in the abdominal region at the base of the urinary bladder while the scrotal sac or pouch is absent. This difference could result from genetic variation between species.
Our findings in this research are similar to the report of  in Taphozous hilli bat in which the testes were found in the scrotum connected by spermatic cord via the inguinal canal where they appeared to lie within nonpigmented fascial sac which extends from external inguinal ring. This finding is also contrary to the findings of  in Rhinolophus megaphyllus bat in which the testeslies are just external to the external inguinal ring. The testicular location or position has a significant effect on spermatogenesis in bats . In cases where the testes are intra-abdominal, spermatogenesis ceases entirely . All the variation in terms of the position and location of the testes seen could be attributed to the reproductive activity in adults. The work in  also suggested that the present scrotal sac serves to reduce testicular temperature to the level below that of the body temperature.
The division of epididymis into three regions, caput, corpus, and cauda regions, was similar to studies of  in male reproductive system of the bat and also in line with the findings of , that 3 and 4 segments were found in Eumops glaucinus and Molossus molossus bats respectively, namely, initial, caput, corpus, and cauda segments. But this division into segments could be attributed to species specificity. The shape of the cauda epididymis in the adult is more conspicuous than in juvenile and this is in line with the report of  who reported that the conspicuous nature of the cauda epididymis is a more appropriate indicator of sexual maturity than colour as reported by . These findings were similar to that of , who reported that cauda epididymis in young Plecotus auritus is small and inconspicuous compared to those in the adult male group.
The morphological presentation of the penis, which was observed to be cylindrical and directed cranially, agrees with , who reported that taxonomic variation exists in the posture of the penis which may be directed either cranially or caudally. It was, however, further stated that the morphological architecture is essentially the same in all species of bats.
Morphometry. The mean dimension of testes observed in this study was contrary to the findings of , who reported 20 by 18 mm in adult male bat. The change observed in testicular size agrees with the findings of [19, 30], who reported that maximum testicular size is associated with maximal spermatic activity in the adult bats. The increase in testicular mass and dimension as seen in these studies has a great influence and role to play in male spermatogenesis as reported by [31, 32]. The epididymal length in adult of this study was similar to the report of , who reported 2.5 cm as the epididymal length in adult Myotis capaccinii bat in Iran. The epididymal length plays a role in sperm cell storage and reducing sperm cell motility. Whereas the length of the vas deferens observed was contrary to the findings of  that recorded 20 cm in humans. This finding could be linked to the distance and location of the testis to the ampullary gland in humans.
The length (3.38 ± 0.18 cm) of the penis in this study was higher than the value obtained by  who recorded 1.2 cm in captive Desmodus rotundus bat.
In conclusion, this work is probably the first gross and morphometric studies on the male reproductive system of the bat (Eidolon helvum) in Nigeria and has established a baseline data for the different segments of the male reproductive tract of the bat. It is expected that the results will guide further researches on the reproductive systems of the male bats.
Seasonal variation could be looked at in respect to the environment of the location. It is recommended that the histochemical and ultrastructural studies of the male reproductive tract are recommended for further insight into the reproductive biology of the species.
Conflict of Interests
The authors declare that there is no conflict of interests regarding the publication of this paper.
This study was supported by the Department of Veterinary Anatomy, Faculty of Veterinary Medicine, Usmanu Danfodiyo University, Sokoto, Nigeria.
- K. Riede, “Global register of migratory species: from global region,” Final Report of R and D Projekt 808 05 081, Federal Agency of Nature Conservation, 2004.
- Bat Conservation International, “Bat facts and Amazing Trivia,” Beaufortia, vol. 40, pp. 111–177, 1997.
- R. M. R. Barclay and L. D. Harder, “Life histories of bats: life in the slow lane,” in Bat Ecology University of Chicago Press, T. H. Kunz and M. B. Fenton, Eds., pp. 209–253, Chicago, Ill, USA, 2003.
- S. P. Mickleburgh, A. M. Hutson, and P. A. Racey, Old World Fruit Bats: An Action plan for Their Conservation, IUCN, Gland, Switzerland, 1992.
- C. Tilmann and B. Capel, “Mesonephric cell migration induces testis cord formation and Sertoli cell differentiation in the mammalian gonad,” Development, vol. 126, no. 13, pp. 2883–2890, 1999.
- M. N. Drew and A. de Lahunta, “Derivative of intermediate mesoderm: reproductive organs,” in The Embryology of Domestic Animals Developmental Mechanism and Malformations, pp. 322–341, Williams and Wilkins, 1985.
- P. H. Krutzsch, “Male reproductive patterns in nonhibernating bats,” Journal of Reproduction and Fertility, vol. 56, no. 1, pp. 333–344, 1979.
- B. P. Setchell, The Mammalian Testis, Cornell University Press, Ithaca, NY, USA, 1978.
- R. T. F. Bernard, “Seasonal changes in plasma testosterone concentrations and Leydig cell and accessory gland activity in the Cape horseshoe bat (Rhinolophus capensis),” Journal of Reproduction and Fertility, vol. 78, no. 2, pp. 413–422, 1986.
- C. H. Calisher, J. E. Childs, H. E. Field, K. V. Holmes, and T. Schountz, “Bats: important reservoir hosts of emerging viruses,” Clinical Microbiology Reviews, vol. 19, no. 3, pp. 531–545, 2006.
- A. A. Thomson and P. C. Marker, “Branching morphogenesis in the prostate gland and seminal vesicles,” Differentiation, vol. 74, no. 7, pp. 382–392, 2006.
- E. E. Okon, “Functional anatomy of the alimentary canal in the Fruit Bat, Eidolon helvum, and the insect bat, Tadarida nigeriae,” Acta Zoologica, vol. 58, no. 2, pp. 83–93, 1977.
- F. Mutere, “Eidolon helvum,” in Proceedings of the 5th International Bat Research Conference, D. Wilson Gardner, Ed., pp. 145–150, Texas Press, Lubbock, Tex, USA, 1980.
- P. D. Heideman, K. P. Bhatnagar, F. K. Hilton, and F. H. Bronson, “Melatonin rhythms and pineal structure in a tropical bat, Anoura geoffroyi, that does not use photoperiod to regulate seasonal reproduction,” Journal of Pineal Research, vol. 20, no. 2, pp. 90–97, 1996.
- A. O. Samson, A. A. Olusola, A. O. David et al., “Histological investigation of the pregnant and non-pregnant uterine limbs of the frugivorous bat (Eidolon helvum),” International Journal of Integrative Biology, vol. 3, no. 3, 2008.
- A. O. Samson, A. A. Olusola, A. O. David et al., “Partial septate uterus and tubal implantation: a normal phenomena in the Eidolon helvum,” Scientific Research and Essay, vol. 4, no. 1, pp. 13–17, 2008.
- S. Mickleburgh, A. M. Hutson, W. Bergmans, J. Fahr, and P. A. Racey, “Eidolon helvum. In: IUCN, 2011,” IUCN Red List of Threatened Species, Version 2011. 2. HYPERLINK, 2008, http://www.iucnredlist.org.
- M. Sharifi, “Postnatal growth in Myotis blythii (Chiroptera, Vespertilionidae),” Mammalia, vol. 68, no. 4, pp. 283–289, 2004.
- A. W. Gustafson, “Male reproductive patterns in hibernating bats,” Journal of Reproduction and Fertility, vol. 56, no. 1, pp. 317–333, 1979.
- S. L. De Frees and D. E. Wilson, “Eidolon helvum,” Mammalian Species, vol. 312, pp. 1–5, 1988.
- J. R. Speakman and P. A. Racey, “The energetics of pregnancy and lactation in the brown long-eared bat, Plecotus auritus,” in Recent Advances in the Study of Bats, M. B. Fenton, P. A. Racey, and J. M. V. Rayner, Eds., pp. 367–393, Cambridge University Press, Cambridge, UK, 1986.
- P. H. Krutzsch, “Anatomy, physiology and cyclicity of the male reproductive tract,” in Reproductive Biology of Bats, E. G. Crichton and P. H. Krutzsch, Eds., pp. 91–155, Academic Press, London, UK, 1979.
- S. A. Vamburkar, “The male genital tract of the Indian megachiropteran bat Cynopterus sphinx gangeticus Anderson,” Proceedings of the Zoological Society, vol. 130, pp. 57–77, 1957.
- D. J. Kitchener, “Bats,” in The Australian Museum Complete Book of Australian Mammals, R. Strahan, Ed., pp. 335–347, Angus and Robertson Publishers, London, UK, 1983.
- P. H. Krutzsch, R. A. Young, and E. G. Crichton, “Observations on the reproductive biology and anatomy of Rhinolophus megaphyllus (Chiroptera: Rhinolophidae) in eastern Australia,” Australian Journal of Zoology, vol. 40, pp. 533–549, 1992.
- R. B. Mateus, F. S. Bruno, J. L. Fábio, R. T. Sebastião, and M. V. Eliana, “Morphological and morphometric characteristics of the epididymis in the Neotropical bats Eumops glaucinus and Molossus molossus (Chiroptera: Molossidae),” Chiroptera Neotropical, vol. 16, no. 2, pp. 769–779, 20101992.
- T. Kokurewicz and J. Bartmanska, “Early sexual maturity in male Daubenton's bats Myotis daubentoni (Kuhl, 1891) (Chiroptera: Vespertilionidae), the observations and histological studies on the genitalia,” Myotis, vol. 30, pp. 95–108, 1992.
- A. C. Entwistle, P. A. Racey, and J. R. Speakman, “The reproductive cycle and determination of sexual maturity in male brown long-eared bats, Plecotus auritus (Chiroptera: Vespertilionidae),” Journal of Zoology, vol. 244, no. 1, pp. 63–70, 1998.
- C. Jones, “The bats of Rio Muni, West Africa,” Journal of Mammalogy, vol. 52, no. 1, pp. 121–140, 1971.
- D. J. Hosken, M. A. Blackberry, T. B. Stewart, and A. F. Stucki, “The male reproductive cycle of three species of Australian vespertilionid bat,” Journal of Zoology, vol. 245, no. 3, pp. 261–270, 1998.
- M. Gemendio and E. R. S. Rodlan, “Sperm competition influences sperm size in mammals,” Proceedings of the Royal Society B: Biological Sciences, vol. 243, pp. 181–185, 1993.
- P. Stockley, M. J. G. Gage, G. A. Parker, and A. P. Moller, “Female reproductive biology and the coevolution of ejaculate characteristics in fish,” Proceedings of the Royal Society B: Biological Sciences, vol. 263, no. 1369, pp. 451–458, 1996.
- V. Akmali, M. Sharifi, R. S. Esmaeili, and R. Ghorbani, “Evidence of sperm storage in Myotis capaccinii (Chiroptera: Vespertilionidae) in western Iran,” Journal of Veterinary Research, vol. 63, no. 2, pp. 47–61, 2008.
- “Anatomy, vasculature, and innervation of the male reproductive tract,” in Knobil and Neill's Physiology of Reproduction, J. D. Neill, Ed., pp. 771–808, Elsevier Press, New York, NY, USA, 2006.
- A. M. Orsi, C. A. Vicentini, S. M. Dias, S. C. Michelin, and M. J. Viotto, “Histochemical and structural characteristics of the testis of the vampire bat (Desmodus rotundus rotundus, Geoffrey, 1810),” Revista Brasileira de Biologia, vol. 50, no. 1, pp. 221–228, 1990.