Functional morphological study of the choana in different bird species
The anatomical information about the structure of the choana is lacking in literature, and its role in the olfactory and feeding mechanism is still unknown
The present study discusses the adaptation of choana to cranial kinesis during feeding process in different bird species: kestrel, common moorhen, and hoopoe. Kestrel possesses a kinetic skull while the hoopoe and common moorhen have kinetic one; however, the common moorhen skull seems highly kinetic more than that of the hoopoe that properly effect on the choanal epithelium. The choana of kestrel and hoopoe are lined by pseudostratified ciliated columnar epithelium, while choana of common moorhen have transitional epithelium beside pseudostratified ciliated columnar epithelium. The choana epithelium of each bird species provides with simple alveolar glands and numerous goblet cells. In kestrel and hoopoe, the secretion products of choanal glands contain neutral and sulfated mucin, while in the common moorhen, these glands secret neutral and carboxylate mucopolysaccharides.
The choana of the three studied bird species apparents adaptation to the olfaction process but also affects the movement of skeletal elements of the skull during the feeding process
KeywordsChoana Cranial Kinesis Bird Feeding process
Birds have variation in the form and function of their feeding system which are amenable to comparative analysis because they represent modifications of the same basic structure of this apparatus among different species without a doubt that reflected the success of birds to survival and occupy a wide range of habitats. Many of the literature has studied the avian feeding system (Jackowiak & Godynicki, 2004; Mahmoud, Shawki, & Wahba, 2009; El-Bakary, 2011, 2012; Al-Zahaby & Elsheikh, 2014; Erdogan & Iwasaki, 2014; and Shah & Aziz, 2014; Gadel-Rab, Shawki, & Saber, 2017), but still the feeding mechanics and functional morphological information about most bird species remain poorly understood.
The roof of buccal cavity is considered as a part of feeding system and was given little attention in literature. It is interesting to state that only Shawki, Abdeen, and Mahmoud (2016) gave a clear description of the roof of buccal cavity of the kestrel and discussed its role in the feeding mechanism. Mahmoud, Gad-Rab, and Shawki (2017) pointed out the effect of different feeding behaviors on the lining epithelium of the roof of buccal cavity of two bird species.
The feeding and sensory systems are considered integrating systems and reflect a general historical trend of increasing cephalization in vertebrate evolution (Schwenk, 2000). The avian olfactory system consists of the choana which appears in birds and reptiles related to the incomplete secondary palate, through which the nasal and oral cavities communicate with each other (Kent & Carr, 2001). The anatomical information about the structure of the choana is lacking in literature, and its role in the olfactory and feeding mechanism is still unknown.
Thus, the present study gives attention to the functional morphological structure of the choana in three different bird species to exhibit the adaptation of the choana to the feeding process.
The selected bird species are kestrel, hoopoe, and common moorhen that belong to different avian’s orders: Falconiformes, Bucerotiformes, and Gruiformes, respectively, each of them have own feeding behavior.
The specimens of three bird species in the present study were collected from Abou-Rawash area of Egypt and brought alive to the comparative anatomy of vertebrate lab. The specimens were anesthetized by ether then dissected under wild stereomicroscope to separate the head from the rest of the body. Some specimens were carefully investigated by wild stereomicroscope to clarify the anatomical features of roof of mouth; the skull the was prepared; and then photos were photographed by using a digital camera. Some specimens were fixed in 10% neutral formalin for 3 days and prepared to paraffin embedding. Tissues were sectioned at 7 μm and stained with Hematoxylin and Eosin, Masson’s trichrome, Bromophenol blue, PAS and PAS-Alcian blue (Bancroft & Stevens, 1996).
Dorsally, the vomer bone is located between the anterior portion of palatine and extends posteriorly to fuse with the parasphenoid bone. In the kestrel, the vomer bone has club shape with rounded head which fuse anteriorly with maxillopalatine process (MP), and extends posteriorly as rod-shape to fuse with the parasphenoid bone (Fig. 8). Meanwhile, in the common moorhen, the vomer bone initiates as narrow unpaired bone, then forks posteriorly towards the parasphenoid bone (Figs. 6 and 7), whereas in the hoopoe, the vomer bone is absent and replaced by a longitudinal ribbon of collagenous connective tissue which extends posteriorly cross the ventromedial surface of the parasphenoid bone (Fig. 9).
Posteriorly, the palatine bone broads to form the pars lateralis which contains the ventral fossa. This fossa appears deeper in the common moorhen than that of the kestrel, while in the hoopoe, it appears shallow (Figs. 7, 8, and 9). The pars lateralis possesses medial and ventral crest which enclose the choana fossa between them. The choana fossa is narrow and shallow in the kestrel, broad and slightly deep in the common moorhen, and narrow and deep in the hoopoe (Figs. 7, 8, and 9).
Moreover, the kestrel and common moorhen have paired medial crest (Figs. 7 and 8) that is absent in the case of hoopoe and replaced by fibrous connective tissue (Fig. 9). The ventral crest that forms the lateral wall of the choana protrudes ventrally in the kestrel and the common moorhen more than in the hoopoe.
The simple alveolar gland and goblet cells are distributed within the lining epithelium of the choana of all species analyzed. In the common moorhen, compound-branched alveolar glands were observed embedding dorso-medially within the epithelium of the chaona (Fig. 13a).
Moreover, in kestrel and hoopoe, the choanal glands showed moderate reaction with mercuric bromophenol blue (Fig. 14d, f) indicating the presence of protein secretory materials, while in the common moorhen, the choanal glands gives slightly react with mercuric bromophenol blue (Fig. 14e).
The kestrel, common moorhen, and hoopoe are three different bird species with different feeding behaviors: kestrel is prey–predator bird which possesses hard curved beaks to cut their prey while the hoopoe and common moorhen are probing birds that catch their prey by different strategies. Shawki and Ismail (2006) and Mahmoud et al. (2009) mentioned the functional morphological structure of the lingual apparatus of the common moorhen and kestrel respectively and confirmed that these bird species mainly rely on their lingual apparatus in feeding process, while the hoopoe depends on the jaw apparatus in manipulating their prey than its tongue (Gadel-Rab, Shawki, & Saber, 2012) which agree with those mentioned by Rawal (1968) who concluded that the long arms of hoopoe’s bill confer greater advantage in thrusting the bill into soil.
The cranial kinesis is an important character of the feeding behavior of birds (Bout & Zweers, 2001). The kestrel, hoopoe, and common moorhen are prokinetic birds like most bird species, in which the bending zone is situated at the nasal-frontal hinge that allows the movement of the upper jaw up/down relative to the skull.
Mahmoud, Shawki, and Abdeen (2017) clarified that there is no flexible zone appearing at the nasal-frontal hinge in the kestrel’s skull. In the hoopoe, this hinge is movable that confirmed practically during the skull preparation; also in the common moorhen, the upper jaw can depress downward relative to skull. The movement of the upper jaw (depression) occurs as resulting of the contraction of pterygoid muscle complex of each bird species. The pterygoid muscles are originated from the palatine bone “pars lateralis” and insert on the lower jaw “posterior portion of the mandible”. The contraction of this muscle pulls the palatine bone backward, thereby depressing the upper jaw, as well as, adducting the mandible by elevating the anterior portion of mandible that leads to closing the beak. Physically, the naso-frontal hinge determines the ability of the gliding movement of the palatine bone beside its shape and position. The skull of kestrel have immovable naso-frontal hinge; this leads to the mechanical force which is produced during the contraction of the pterygoid muscle closing the mandible quickly to produce a strong bit force; this result agree with those mentioned by Mahmoud et al. (2017).
Meanwhile, in hoopoe and the common moorhen, the movable naso-frontal hinge gives flexibility for depression of the upper jaw by pulling the palatine bone during the contraction of the pterygoid muscle. During depression of upper jaw in the common moorhen, the force transferred to curve the anterior portion of the palatine bone “maxillary process of the palatine bone”. This force enables bird to widen the choana. Morphologically, widening of choana may lead to increase air-flow that drain to the buccal cavity during closing of the mouth after catching prey or may be related to the uptake of large food items. In the hoopoe, the anatomical structure of the palatine bone maxillary process of the palatine bone is none allowable to change the diameter of choana. In fact, the hoopoe catches small insects and worms in no need to change the diameter of choana like that of kestrel which feeds on small items cutting before by their beak.
However, the morphological analysis of choana of these bird species suggests that the ability of movement of upper jaw relative to skull (cranial kinesis) affects the type of epithelium that lining the choana. The choana of kestrel and hoopoe is lined by pseudostratified ciliated columnar epithelium. This type of epithelium usually placed within the nasal passages of birds (Bang & Wenzel, 1995) and some part of respiratory system of other animals (Junqueira & Carneiro, 1980) formed the mucosa of the olfactory and respiratory tracts. The presence of pseudostratified ciliated columnar epithelium within the choana in all studied bird species may help in increasing the efficiency of smell in these bird species. In addition, in the common moorhen, there is another type of epithelium beside the pseudostratified ciliated columnar epithelium, transitional epithelium type which lining the dorso-medial surface of choana. This surface of choana is more exposed to the mechanical forces during the movement of upper jaw explaining the presence of this type of epithelium in this region. The transitional epithelium has stretching ability during exposure to any pressure, if it is external (food items) or internal (mechanical performance of the feeding apparatus) pressure.
Moreover, the epithelium of choana in the three studied bird species provides with simple alveolar glands and numerous goblet cells which lack in most bird species (Bang & Wenzel, 1995). In kestrel and hoopoe, the secretion products of glands contain neutral and sulfated mucin, while in the common moorhen, secretion is neutral and carboxylate mucopolysaccarides. The natural secretion of choanal gland of these bird species confirms that these glands have no role in the digestion of food items. Moreover, these birds feed on meat; thereby, the digestion process occurs by secretion of preventriculus portion of the alimentary tract of the bird (McLelland, 1979), so their secretions of choanal gland in these bird species may help in lubrication of ingested food for ease of swelling process and provide an effective barrier against enzymatic acidic elements in contact with the buccal mucosal surface. In addition, we suggested that the choanal glands may share in detection the odoriferous molecules through dissolving in it as an olfactory stimulus.
The choana of the three studied bird species apparents adaptation to the olfaction process but also affects the movement of skeletal elements of the skull during the feeding process. We suggest that the different epithelium which appears within the choana and the natural of their gland secretions may be specialized for different functions. Thus, it is clear that we still have much to know about the structure and function of the choana in birds.
I would like to express our thanks to the microscopical unit in Zoology Dept., Faculty of Science, Assiut University, for their help in specimen preparations.
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FM, AG, and NS designed and performed this work. All authors read and approved the final manuscript.
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