INTRODUCTION
Fully aquatic teleost fishes typically respire through their gills, but there are exceptional cases where they can supplement deficient oxygen through the gastrointestinal surface (Grosell et al., 2010), swim bladder (Fernandes et al., 2012), branchial chamber (Sundin et al., 1999), labyrinthine organ (Zaccone et al., 2019), and skin (Glover et al., 2013). Among these types of respiration, the skin can provide 5~30% of the necessary oxygen within a fish’s body, and amphibious fishes can obtain more than 50% supplementary oxygen through the skin (Graham, 1997, 2011). Regarding cutaneous respiration, the skin as a type of epithelial tissue has revealed the following histological evidence: 1) intraepidermal blood capillaries, 2) rich vascularization within the dermis, 3) the presence of large cells, such as mucous cells, club cells, and swollen cells, and 4) reduced or absent scales(Glover et al., 2013).
The olfaction in teleost fishes plays a crucial role in triggering ecological habits and behavioral responses related to searching for food, feeding, social communication, mating, predator detection, and contamination detection in their habitat(Bone and Moore, 2008). For chemoreception, the olfactory organ has adapted to the physical environment of its habitat and unique ecological characteristics, resulting in a variety of positions, structures, and distributional patterns in the nostril, olfactory chamber, and accessory nasal sac, as well as the olfactory epithelium and olfactory receptor neurons by species (Kasumyan, 2004). Among these, the olfactory epithelium is typically a pseudostratified epithelial layer, including olfactory receptor neurons, supporting cells, basal cells, and mucous cells, without blood capillaries (Kasumyan, 2004). However, during histological studies on muddy fishes, intraepithelial vessels and vascularization were found in the olfactory epithelium of Monopterus albus that were indicative of aerial respiration.
The Asian swamp eel M. albus is widely distributed in East Asia including rivers in India, Indonesia, China, Japan, and South Korea flowing into the Western and Southern seas (Chae et al., 2019). M. albus prefers shallow water, such as muddy riverbeds, ponds, and rice fields, and has a high tolerance for drastic temperature changes and exposure to poor oxygen conditions during the dry season (Lefevre et al., 2016). This eel also has a respiratory behavior of exposing its snout above the water’s surface to intake air into its mouth (Liem, 1967). It has been reported that M. albus obtains supplementary oxygen from such behavior through the skin and buccal cavity (Liem, 1967; Damsgaard et al., 2014), and the amount of oxygen obtained is approximately three times more than it acquires underwater (Liem, 1967). The olfactory organ of M. albus also was assumed to have an additional respiratory function based on epithelial modification with intraepithelial blood capillaries (Beon et al., 2013; Glover et al., 2013). Therefore, we aimed to describe the new type of olfactory respiratory organ in M. albus based on histological findings of intraepithelial blood capillaries and dermal rich vascularization.
MATERIALS AND METHODS
1. Specimen preparation
For morphological and histological analysis, 10 adult M. albus(Fig. 2A) were caught in a rice field between May and June 2023 (35°53ʹ27ʺN, 127°07ʹ01ʺE, Jeonmi-dong, Jeonju-si, Jeonllabuk-do, South Korea, Fig. 1; Fig. 2C) using a scoop net(4×4 mm mesh size). The captured specimens were immediately anesthetized with 0.1% m-aminobenzoic acid ethyl ester methanesulfonate solution (MS222, Sigma-Aldrich, St Louis, MO, USA) in the field, and then six specimens were fixed in 10% neutral buffered formalin solution (pH 7.4) and the rest were fixed in 2.5% neutral glutaraldehyde solution (pH 7.4; EMS, USA). The collection was primarily conducted at night after observing the swamp eel exposing its snout above the water surface (Kim and Park, 2002; Fig. 2B). The experimental procedure for this study strictly followed the rules of the “Institutional Animal Care and Use Committee of Jeonbuk National University” (License Number: CBNU-2023-00060).
Fig. 1. The collection site (arrowhead) of Monopterus albus in Jeonmidong, Jeonju-si, Jeollabuk-do, South Korea.
Fig. 2. The photograph of Monopterus albus (A), its breathing behavior with the aerial exposure of snout (B), and its habitat (C). The bar indicates 10 cm.
2. Microscopic investigation
To determine the anatomy of the olfactory organ, the external morphology was observed under a stereo microscope (Stemi DV4, Carl Zeiss, Germany). Skin tissue was dissected using surgical blades(stainless No. 10 and 11, Japan) to expose the internal structure, and filmed with a digital camera (TG-3, Olympus, Japan). To confirm the cytological characteristics and structure of the olfactory epithelium, the tissue sections were fixed for 24 hours and were dehydrated in ascending concentrations of alcohol (50%, 60%, 70%, 80%, 90%, 100%) for 1 hour each. Then, the sections were cleared in xylene for 1 hour. The paraffin blocks (Paraplast, Oxford) were five micrometer-sectioned using a microtome (Leica RM 2255, Leica, Germany), and stained with Harri’s hematoxylin-eosin (H&E) for general structure and with Masson’s trichrome (Masson, 1929) to differentiate the epithelium and connective tissue. Additional special staining was performed using nuclear fast red-Alcian blue pH 1.0 and 2.5 solutions(Yamabayashi, 1987) to highlight the mucous cells’ specificity. In order to examine the surface features of the olfactory epithelium in the olfactory chamber, the tissues were pre-fixed in 2.5% glutaraldehyde solution, post-fixed in 1% osmium tetroxide solution with phosphate buffer(pH 7.4), dehydrated in ascending alcohol series (60%, 70%, 80%, 90%, 95%, 100%, tert-butanol), and frozen at 4℃ for 24 hours. The tissues were dried using a t-BuOH freeze dryer(VFD-21S, Vacuum Device Co. Ltd., Ibaragi, Japan), coated with osmium tetroxide using a plasma coater(HPC-1SW, Vaccum Device Inc., Tokyo, Japan), and finally photographed with a scanning electron microscope (SUPRA40VP, Carl Zeiss, Germany).
RESULTS
1. Anatomy
The paired olfactory organ of M. albus on each dorsal side of the snout externally displayed two openings(anterior nostril at the anterior tip of the snout and posterior nostril above the eyes)(Fig. 3). Both nostrils were non-protruding openings parallel to the skin surface and the distance between them was 5.57~7.10 mm on average. The interior structure consisted of a pipe-like chamber and two sacs (lower and upper accessory nasal sacs) at the posterior end of the chamber (Fig. 3). No rosette structure was found within the olfactory chamber.
Fig. 3. Anatomical structure (left photograph, external view; right, internal view) of the olfactory organ of Monopterus albus. AN, anterior nostril; LNS, lower accessory nasal sac; OC, olfactory chamber; PN, posterior nostril; UNS, upper accessory nasal sac.
2. Histology
The epithelium of the olfactory chamber was classified into the sensory epithelium of the pseudostratified layer and the non-sensory epithelium of the stratified squamous epithelium (Fig. 4A and B). In addition, there was an unidentified organ that developed from the epithelial side toward the inner lumen (Fig. 4A and B).
Fig. 4. Histological characteristics of the olfactory canal (OC) of Monopterus albus, stained with Harri’s hematoxylin and eosin (A, C), Masson’s trichrome (B, D, E), and nuclear fast red-alcian blue pH 2.5 solution (F). A and B, the olfactory epithelium consisting of three large parts, sensory epithelium (SE), non-sensory epithelium (NSE), and unidentified organ (UO) and surrounded by the connective tissue (CT); C and D, the SE having olfactory receptor neurons(ORN), supporting cells(SC), basal cells(BC), lymphatic cells(LC), pigment cells(PC), and interepithelial blood capillary (yellow asterisk); E and F, the NSE consisting of stratified epithelial cells(SEC) and mucous cells(arrowhead). Bars indicate 20 μm in C, 50 μm in D~F, 200 μm in A, B, respiectively.
The sensory epithelium at the ventral wall of the olfactory chamber consisted of olfactory receptor neurons (ORNs), supporting cells (SCs), basal cells (BCs), lymphatic cells (LCs), and blood capillaries (Fig. 4C and D). The ORNs were bipolar cells composed of dendrites that extended to the surface, axons connecting to the basement membrane, and a long oval-shaped nucleus. The nucleus appeared as a dark purple color in the H&E and Masson’s trichrome stainings. The SCs had more round-shaped nuclei than those of the ORNs and they were lighter purple in the H&E and Masson’s trichrome stainings. They were situated among the ORNs in the sensory epithelium. The BCs were distributed in the bottom of the sensory epithelium and had the lightest purple nuclei and pale pink cytoplasm in the H&E and Masson’s trichrome stainings. The LCs were circular cells distributed in the middle and lower layers of the sensory epithelium. They were the smallest in size compared to the other epithelial cells and showed the darkest purple color in the H&E staining. The intraepithelial blood capillaries were scattered in the middle and lower layers of the sensory epithelium and contained one to three blood cells(Fig. 4C and D). More abundant dermal vascularization was observed in the connective tissue just below the bottom of the sensory epithelium and among the pigment cells and dermal collagen fibers than in intraepithelial vessels(Fig. 4C and D).
The non-sensory epithelium at the dorsal wall of the olfactory chamber consisted of stratified epithelial cells(SEC) and mucous cells (MC) (Fig. 4E and F). The SECs were polygonal cells exhibiting nuclei with a purple color in the Masson’s trichrome and a weak pink color in the nuclear fast red staining, and they contained wide cytoplasm. The MCs had nuclei located at the cell bottom and the cytoplasm stained in a blue color with nuclear fast red-Alcian blue with a pH of 2.5. However, they did not exhibit reactivity in Masson’s trichrome staining.
Under scanning electron microscopy, the surface of the sensory epithelium indicated numerous cilia from ORNs, SCs, and mucous mass(Fig. 5A), and a fingerprint-like pattern was observed on the surface of the non-sensory epithelium(Fig. 5B).
Fig. 5. Scanning electron micrographs showing the surface structure of the sensory (A) and non-sensory epithelium (B) of the olfactory organ of Monopterus albus. Bars indicate 5 μm, respectively.
DISCUSSION
In teleost fishes, the anatomy and histology of the olfactory organ is known to be closely related to their ecological habits and the physical conditions in their habitat. Most underwater teleost fishes have an oval olfactory chamber with a rosette structure but no accessory sac (Zeiske et al., 1992). However, the olfactory organs of amphibious fishes that inhabit mudflats, paddy fields, ponds, and similar environments with frequent exposure to air possess only one lacrymal accessory nasal sac, such as in Periophthalmus modestus (Kim et al., 2019) and P. barbarus (Kuciel, 2013), or the two ethmoidal and lacrymal accessory nasal sacs, such as in Boleophthalmus pectinirostris (Kim and Park, 2020), Odontamblyopus lacepedii(Kim et al., 2018), Scartelaos histophorus(Kuciel et al., 2013), and Parapocryptes rictuosus(Kuciel et al., 2013). In addition, they are characterized by tubular anterior nostrils, olfactory chambers with a pipe-like form, and the absence of a rosette structure. In this study, M. albus also displayed pipe-like olfactory chambers lacking a rosette structure and two sacs (lower and upper accessory nasal sacs). In general, the olfactory activity of amphibious fishes in stagnant or shallow water conditions tends to be highly dependent on the structure of the olfactory chambers and the nasal sacs’ pumping mechanisms(Kuciel, 2013). Kim et al. (2019) opined that P. modestus on wet mudflats with extremely shallow water move their heads’ skeletons and straw-like olfactory chambers to facilitate the inflow of water into the internal olfactory organ and such olfactory activity is relevant to the “sniffing” of the mudskipper. Therefore, the pipe-like olfactory chamber and two accessory nasal sacs of M. albus could be considered structural adaptations that play an important role in allowing external water to be drawn into the olfactory cavity, particularly in stagnant water environment, such as rice fields, ponds, swamps, and rivers. Moreover, although M. albus and most amphibious species share similar habitat environments with stagnant water, the nostril morphology of M. albus differs from these species(a closed hole parallel to the skin surface vs. an open hole with ascending tubular form) (Belanger et al., 2003; Ma and Wang, 2010; Kim and Park, 2016). This seems to be a morphological adaptation to different ecological habits rather than the habitat differences of M. albus. Meanwhile, the unidentified organ inside the olfactory chamber is considered to be a unique structure not previously reported in other fish taxa. Therefore, it was suggested that further anatomical and histological analysis is needed to confirm its detailed function.
The olfactory epithelium of teleost fishes has multiple cells that play diverse functions, such as chemical reception of olfactory neurons, cilia possession of supporting cells for mucus spreading, progenitors of olfactory neurons in basal cells, and mucus secretion for olfactory cell protection against infective pathogens or harmful substances (Hara, 1994). However, the respiratory function in the olfactory epithelium has not been reported in fish thus far, including all evolutionary stages of fish groups beyond the Agnatha (jawless fish) (Fernandes, 2016). Therefore, the development of blood capillaries within the sensory epithelium and the rich dermal vascularization of the M. albus olfactory organ was considered to be a meaningful modification in this study. It also could be considered strong histological evidence supporting its respiratory function (Beon et al., 2013). In the view of skin histology, the presence of intraepidermal blood capillaries and abundant dermal vascularization have been described as significant modifications that prove cutaneous respiration in fishes, such as P. modestus(Park et al., 2000), P. magnuspinnatus(Park et al., 2006), Rhinogobius brunneus (Kim et al., 2022), P. cantonensis (Yokoya and Tamura, 1992), Pseudobagrus brevicorpus(Park and Kim, 2007), Liobagrus mediadiposalis (Park et al., 2003), and Tridentiger obscurus (Suzuki and Hiraki, 1991), that can survive in adverse environments with extremely low oxygen levels or limited water, and occasionally prolonged exposure to air. Based on such histological references, the olfactory organ of M. albus is suggested to have an additional respiratory function along with the buccal cavity, which it uses by protruding its snout above the water’s surface when submerged.
Furthermore, we confirmed that the sensory epithelium of the olfactory organ of M. albus contained ORNs, SCs, BCs, and LCs, which are fundamentally essential to the cellular composition found in the sensory epithelium of teleost fishes for detecting chemical odorants in the surrounding environment (Hara, 1994). In addition, the components of the mucous cells in the non-sensory epithelium were characterized by negativity on nuclear fast red-Alcian blue staining at a pH of 1.0, but positivity at a pH of 2.5. These results imply that acidic mucopolysaccharides containing carboxyl groups are the major constituents within the cytoplasm(Lev and Spicer, 1964).
ACKNOWLEDGMENTS
This work was supported by the research grant from Jeonju National University of Education in 2023.
참고문헌
- Belanger, R.M., C.M. Smith, L.D. Corkum and B.S. Zielinski. 2003. Morphology and histochemistry of the peripheral olfactory organ in the round goby, Neogobius melanostomus(Teleostei: Gobiidae). J. Morphol., 257: 62-71. https://doi.org/10.1002/jmor.10106.
- Beon, M.S., M.K. Oh, Y.J. Lee, C.H. Kim and J.Y. Park. 2013. A comparative study on vascularization and the structure of the epidermis of an amphibious mudskipper fish, Scartelaos gigas (Gobiidae, Teleostei), on different parts of the body and the appendages. J. Appl. Ichthyol., 29: 410-415. https://doi.org/10.1111/jai.12038.
- Bone, Q. and R. Moore. 2008. Biology of fishes. Taylor & Francis Group, New York, NY, USA.
- Chae, B.S., H.B. Song, J.Y. Park, K.H. Cho, I.S. Kim and S.J. Cho. 2019. A field guide to the freshwater fishes of Korea. LG Evergreen Foundation, Korea, 355pp.
- Damsgaard, C., I. Findorf, S. Helbo, Y. Kocagoz, R. Buchanan, R.E. Weber, A. Fago, M. Bayley and T. Wang. 2014. High blood oxygen affinity in the air-breathing swamp eel Monopterus albus. Comp. Biochem. Physiol. A Mol. Integr. Physiol., 178: 102-108. https://doi.org/10.1016/j.cbpa.2014.08.001.
- Fernandes, M.N., A.L. da Cruz, O.T.F. da Costa and S.F. Perry. 2012. Morphometric partitioning of the respiratory surface area and diffusion capacity of the gills and swim bladder in juvenile Amazonian air-breathing fish, Arapaima gigas. Micron, 43:961-970. https://doi.org/10.1016/j.micron.2012.03.018.
- Fernandes, M.N. 2016. Fish respiration and environment. CRC Press.
- Glover, C.N., C. Bucking and C.M. Wood. 2013. The skin of fish as a transport epithelium: a review. J. Comp. Physiol. B, 183: 877-891. https://doi.org/10.1007/s00360-013-0761-4.
- Graham, J.B. 1997. Air-breathing fishes: Evolution, diversity, and adaptation. Academic Press, San Diego, 299pp.
- Graham, J.B. 2011. Air-respiratory adaptations for air-breathing fishes, In: Farrell, A., J.J. Jr Cech, J.G. Richards and E.D. Stevens(eds.), Encyclopedia of Fish Physiology: Energetics, Interactions with the Environment, Lifestyles, and Applications, 3: 1861-1874.
- Grosell, M., A.P. Farrell and C.J. Brauner. 2010. Fish Physiology: The Multifunctional Gut of Fish. Academic Press.
- Hara, T.J. 1994. Olfaction and gustation in fish: an overview. Acta physiol. Scand., 152: 207-217. https://doi.org/10.1111/j.1748-1716.1994.tb09800.x.
- Kasumyan, A.O. 2004. The olfactory system in fish: structure, function, and role in behavior. J. Ichthyol., 44: S180.
- Kim, H.T. and J.Y. Park. 2016. The anatomy and histoarchitecture of the olfactory organ in the Korean flat-headed goby Luciogobius guttatus(Pisces; Gobiidae). Appl. Microsc., 46: 51-57. https://doi.org/10.9729/AM.2016.46.1.51
- Kim, H.T. and J.Y. Park. 2020. Microscopic research on the olfactory organ of the blue spotted mudskipper Boleophthalmus pectinirostris, compared to a related sympatric mudskipper. Ocean Sci. J., 55: 563-572. https://doi.org/10.1007/s12601-020-0042-6.
- Kim, H.T., S.W. Yun and J.Y. Park. 2019. Anatomy, histology, and histochemistry of the olfactory organ of the Korean shuttles mudskipper Periophthalmus modestus. J. Morphol., 280: 1485-1491. https://doi.org/10.1002/jmor.21044.
- Kim, H.T., S.W. Yun and J.Y. Park. 2022. Histological studies on the skin of a freshwater goby Rhinogobius brunneus (Gobiidae) related to cutaneous respiration. J. Ichthyol., 62: 495-502. https://doi.org/10.1134/S0032945222030067.
- Kim, H.T., Y.J. Lee and J.Y. Park. 2018. Functional anatomy and histology of the olfactory organ in Korean eel goby, Odontamblyopus lacepedii(Pisces: Gobiidae). Appl. Microsc., 48: 11-16. https://doi.org/10.9729/AM.2018.48.1.11
- Kuciel, M. 2013. The mechanism of olfactory organ ventilation in Periophthalmus barbarus(Gobiidae, Oxudercinae). Zoomorphology, 132: 81-85. https://doi.org/10.1007/s00435-012-0167-y.
- Kuciel, M., K. Zuwala and U. Satapoomin. 2013. Comparative morphology (SEM) of the peripheral olfactory organ in the Oxudercinae subfamily (Gobiidae, Perciformes). Zool. Anz., 252: 424-430. https://doi.org/10.1016/j.jcz.2013.03.002.
- Lefevre, S., I. Findorf, M. Bayley, D.T.T. Huong and T. Wang. 2016. Increased temperature tolerance of the air-breathing Asian swamp eel Monopterus albus after high-temperature acclimation is not explained by improved cardiorespiratory performance. J. Fish Biol., 88: 418-432. https://doi.org/10.1111/jfb.12696.
- Lev, R. and S.S. Spicer. 1964. Specific staining of sulphate groups with alcian blue at low pH. J. Histochem. Cytochem., 12: 309-309. https://doi.org/10.1177/12.4.30.
- Liem, K.F. 1967. Functional morphology of the integumentary, respiratory, and digestive systems of the synbranchoid fish Monopterus albus. Copeia, 1967: 375-388. https://doi.org/10.2307/1442128
- Ma, A. and X.A. Wang. 2010. Functional morphology of the olfactory organ of the tongue sole, Cynoglossus semilaevis. Chinese J. Oceanol. Limnol., 28: 209-217. https://doi.org/10.1007/s00343-010-9006-5.
- Masson, P. 1929. Some histological methods: trichrome stainings and their preliminary technique. J. Tech. Methods, 12: 75-90.
- Park, J.Y. and C.H. Kim. 2007. Habitats and air uptake based on analysis of skin structure of two Korean bullheads, Pseudobagrus brevicorpus and P. koreanus(Pisces; Bagridae). Integ. Biosci., 11: 155-160. https://doi.org/10.1080/17386357.2007.9647329.
- Park, J.Y., I.S. Kim and S.Y. Kim. 2000. Histology of skin of the amphibious esh, Periophthalmus modestus. Korean J. Biol. Sci., 4: 315-318. https://doi.org/10.1080/12265071.2000.9647562
- Park, J.Y., I.S. Kim and S.Y. Kim. 2003. Structure and histochemistry of the skin of a torrent catfish, Liobagrus mediadiposalis. Environ. Biol. Fish., 66: 3-8. https://doi.org/10.1023/A:1023298520696.
- Park, J.Y., I.S. Kim and Y.J. Lee. 2006. A study on the vascularization and structure of the epidermis of the air-breathing mudskipper, Periophthalmus magnuspinnatus (Gobiidae, Teleostei), along different parts of the body. J. Appl. Ichthyol., 22: 62-67. https://doi.org/10.1111/j.1439-0426.2006.00696.x.
- Sundin, L.I., S.G. Reid, A.L. Kalinin, F.T. Rantin and W.K. Milsom. 1999. Cardiovascular and respiratory reflexes: The tropical fish, traira (Hoplias malabaricus) O2 chemoresponses. Respir. Physiol., 116: 181-199. https://doi.org/10.1016/S0034-5687(99)00041-9.
- Suzuki, N. and M. Hiraki. 1991. Intraepithelial blood capillaries in fish species, Rep. Kanagawa Nat. Preserv. Soc., 10: 1-11.
- Yamabayashi, S. 1987. Periodic acid-Schiff-Alcian Blue: A method for the differential staining of glycoproteins. Histochem. J., 19: 565-571. https://doi.org/10.1007/BF01687364
- Yokoya, S. and O.S. Tamura. 1992. Fine structure of the skin of the amphibious fishes, Boleophthalmus pectinirostris and Periophthalmus cantonensis, with special reference to the location of blood vessels. J. Morphol., 214: 287-297. https://doi.org/10.1002/jmor.1052140305
- Zaccone, G., J. Maina, A. Germana, G. Montalbano, G. Capillo, L. Aragona, M.J. Kuciel, E.R. Lauriano and J.M. Icardo. 2019. First demonstration of the neuroepithelial cells and their chemical code in the accessory respiratory organ and the gill of the sharptooth catfish, Clarias gariepinus: A preliminary study. Acta Zool., 100: 160-166. https://doi.org/10.1111/azo.12242.
- Zeiske, E., B. Theisen and H. Breucker. 1992. Structure, development, and evolutionary aspects of the peripheral olfactory system. In: Fish chemoreception. Dordrecht: Springer Netherlands, pp. 13-39.