Top

Published in:

01-04-2016 | Original Article

Neural circuits underlying tongue movements for the prey-catching behavior in frog: distribution of primary afferent terminals on motoneurons supplying the tongue

Authors: Szilvia Kecskes, Clara Matesz, Botond Gaál, András Birinyi

Published in: Brain Structure and Function | Issue 3/2016

Abstract

The hypoglossal motor nucleus is one of the efferent components of the neural network underlying the tongue prehension behavior of Ranid frogs. Although the appropriate pattern of the motor activity is determined by motor pattern generators, sensory inputs can modify the ongoing motor execution. Combination of fluorescent tracers were applied to investigate whether there are direct contacts between the afferent fibers of the trigeminal, facial, vestibular, glossopharyngeal-vagal, hypoglossal, second cervical spinal nerves and the hypoglossal motoneurons. Using confocal laser scanning microscope, we detected different number of close contacts from various sensory fibers, which were distributed unequally between the motoneurons innervating the protractor, retractor and inner muscles of the tongue. Based on the highest number of contacts and their closest location to the perikaryon, the glossopharyngeal–vagal nerves can exert the strongest effect on hypoglossal motoneurons and in agreement with earlier physiological results, they influence the protraction of the tongue. The second largest number of close appositions was provided by the hypoglossal and second cervical spinal afferents and they were located mostly on the proximal and middle parts of the dendrites of retractor motoneurons. Due to their small number and distal location, the trigeminal and vestibular terminals seem to have minor effects on direct activation of the hypoglossal motoneurons. We concluded that direct contacts between primary afferent terminals and hypoglossal motoneurons provide one of the possible morphological substrates of very quick feedback and feedforward modulation of the motor program during various stages of prey-catching behavior.

Anderson CW (2001) Anatomical evidence for brainstem circuits mediating feeding motor programs in the leopard frog, Rana pipiens. Exp Brain Res 140:12–19CrossRefPubMed

Anderson CW, Nishikawa KC (1993) A prey-type dependent hypoglossal feedback system in the frog Rana pipiens. Brain Behav Evol 42:189–196CrossRefPubMed

Anderson CW, Nishikawa KC (1996) The roles of visual and proprioceptive information during motor program choice in frogs. J Comp Physiol A 179:753–762CrossRefPubMed

Anderson CW, Nishikawa KC (1997) The functional anatomy and evolution of hypoglossal afferents in the leopard frog, Rana pipiens. Brain Res 771:285–291 (pii: S0006-8993(97)00803-2)CrossRefPubMed

Anderson CW, Nishikawa KC, Keifer J (1998) Distribution of hypoglossal motor neurons innervating the prehensile tongue of the African pig-nosed frog, Hemisus marmoratum. Neurosci Lett 244:5–8 (pii: S0304-3940(98)00111-6)CrossRefPubMed

Antal M, Tornai I, Szekely G (1980) Longitudinal extent of dorsal root fibres in the spinal cord and brain stem of the frog. Neuroscience 5:1311–1322 (pii: 0306-4522(80)90203-1)CrossRefPubMed

Bacskai T, Veress G, Halasi G, Matesz C (2010) Crossing dendrites of the hypoglossal motoneurons: possible morphological substrate of coordinated and synchronized tongue movements of the frog, Rana esculenta. Brain Res 1313:89–96. doi:10.1016/j.brainres.2009.11.071 CrossRefPubMed

Bailey EF, Fregosi RF (2004) Coordination of intrinsic and extrinsic tongue muscles during spontaneous breathing in the rat. J Appl Physiol (1985) 96(2):440–449. doi:10.1152/japplphysiol.00733.2003 CrossRef

Bailey EF (2011) Activities of human genioglossus motor units. Respir Physiol Neurobiol 179(1):14–22. doi:10.1016/j.resp.2011.04.018 CrossRefPubMedPubMedCentral

Bailey EF, Jones CL, Reeder JC, Fuller DD, Fregosi RF (2001) Effect of pulmonary stretch receptor feedback and CO(2) on upper airway and respiratory pump muscle activity in the rat. J Physiol 532(Pt 2):525–534 (pii: PHY_11560)CrossRefPubMedPubMedCentral

Birinyi A, Szekely G, Csapo K, Matesz C (2004) Quantitative morphological analysis of the motoneurons innervating muscles involved in tongue movements of the frog Rana esculenta. J Comp Neurol 470:409–421. doi:10.1002/cne.20006 CrossRefPubMed

Corbacho F, Nishikawa KC, Weerasuriya A, Liaw JS, Arbib MA (2005a) Schema-based learning of adaptable and flexible prey- catching in anurans II. Learning after lesioning. Biol Cybern 93:410–425. doi:10.1007/s00422-005-0014-z CrossRefPubMed

Corbacho F, Nishikawa KC, Weerasuriya A, Liaw JS, Arbib MA (2005b) Schema-based learning of adaptable and flexible prey-catching in anurans I. The basic architecture. Biol Cybern 93:391–409. doi:10.1007/s00422-005-0013-0 CrossRefPubMed

Deak A, Bacskai T, Veress G, Matesz C (2009) Vestibular afferents to the motoneurons of glossopharyngeal and vagus nerves in the frog, Rana esculenta. Brain Res 1286:60–65. doi:10.1016/j.brainres.2009.06.048 CrossRefPubMed

Dean J (1980) Effect of thermal and chemical-components of bombardier beetle chemical defense—glossopharyngeal response in 2 species of toads (Bufo-Americanus, Bufo-Marinus). J Comp Physiol 135:51–59CrossRef

Dicke U, Roth G, Matsushima T (1998) Neural substrate for motor control of feeding in amphibians. Acta Anat (Basel) 163:127–143 (pii: 46492)CrossRef

Dutia MB (2010) Mechanisms of vestibular compensation: recent advances. Curr Opin Otolaryngol Head Neck Surg 18:420–424. doi:10.1097/MOO.0b013e32833de71f CrossRefPubMed

Elmund J, Bowman JP, Morgan RJ (1983) Vestibular influence on tongue activity. Exp Neurol 81:126–140 (pii: 0014-4886(83)90162-0)CrossRefPubMed

Ewert JP (1984) Tectal mechanism that underlies prey-catching and avoidance behavior in toads. In: Vanegas H (ed) Comparative neurology of the optic tectum. Plenum, New York, pp 247–416CrossRef

Ewert JP, Schurg-Pfeiffer E, Weerasuriya A (1984) Neurophysiological data regarding motor pattern generation in the medulla oblongata of toads. Naturwissenschaften 71:590–591CrossRefPubMed

Ewert JP, Buxbaum-Conradi H, Glagow M, Rottgen A, Schurg-Pfeiffer E, Schwippert WW (1999) Forebrain and midbrain structures involved in prey-catching behaviour of toads: stimulus-response mediating circuits and their modulating loops. Eur J Morphol 37:172–176CrossRefPubMed

Fanardjian VV, Sarkisian VS (1988) Synaptic mechanisms of interaction between Deiters’ nucleus and the nuclei of some cranial nerves. Neuroscience 24:135–142 (pii: 0306-4522(88)90318-1)CrossRefPubMed

Fregosi RF (2011) Respiratory related control of hypoglossal motoneurons–knowing what we do not know. Respir Physiol Neurobiol 179(1):43–47. doi:10.1016/j.resp.2011.06.023 CrossRefPubMedPubMedCentral

Fregosi RF, Fuller DD (1997) Respiratory-related control of extrinsic tongue muscle activity. Respir Physiol 110:295–306CrossRefPubMed

Gaupp E (1904) A. Ecker’s und R. Wiedersheim’s Anatomie des Frosches vol 3. Vieweg und Sohn, Braunschweig

Gray LA, O’Reilly JC, Nishikawa KC (1997) Evolution of forelimb movement patterns for prey manipulation in anurans. J Exp Zool 277:417–424. doi:10.1002/(SICI)1097-010X(19970415)277:6<417:AID-JEZ1>3.0.CO;2-R CrossRefPubMed

Hanamori T, Ishiko N (1981) Conduction-velocity of the 10th nerve-fibers innervating taste organs in the rostral and caudal tongue region in bullfrog. Chem Senses 6:175–187. doi:10.1093/chemse/6.3.175 CrossRef

Harwood DV, Anderson CW (2000) Evidence for the anatomical origins of hypoglossal afferents in the tongue of the leopard frog, Rana pipiens. Brain Res 862:288–291 (pii: S0006-8993(00)02146-6)CrossRefPubMed

Ishiwata Y, Ono T, Kuroda T, Nakamura Y (2000) Jaw-tongue reflex: afferents, central pathways, and synaptic potentials in hypoglossal motoneurons in the cat. J Dent Res 79:1626–1634CrossRefPubMed

Kecskes S, Matesz C, Birinyi A (2013) Termination of trigeminal primary afferents on glossopharyngeal-vagal motoneurons: possible neural networks underlying the swallowing phase and visceromotor responses of prey-catching behavior. Brain Res Bull 99:109–116. doi:10.1016/j.brainresbull.2013.09.006 CrossRefPubMed

Kogo N, Perry SF, Remmers JE (1994) Neural organization of the ventilatory activity in the frog, Rana catesbeiana. I J Neurobiol 25:1067–1079. doi:10.1002/neu.480250904 CrossRefPubMed

Kraklau DM (1991) Kinematics of prey capture and chewing in the lizard Agama-agama (Squamata, Agamidae). J Morphol 210:195–212. doi:10.1002/jmor.1052100208 CrossRef

Krammer EB, Rath T, Lischka MF (1979) Somatotopic organization of the hypoglossal nucleus: a HRP study in the rat. Brain Res 170:533–537 (pii: 0006-8993(79)90970-3)CrossRefPubMed

Kumai T (1981) Reflex response of the hypoglossal nerve induced by gustatory stimulation of the frog tongue. Brain Res 208:432–435 (pii: 0006-8993(81)90572-2)CrossRefPubMed

Llinás RR, Precht W, Capranica RR (1976) Frog neurobiology : a handbook. Springer, BerlinCrossRef

Luo P, Moritani M, Dessem D (2001) Jaw-muscle spindle afferent pathways to the trigeminal motor nucleus in the rat. J Comp Neurol 435:341–353CrossRefPubMed

Luo P, Zhang J, Yang R, Pendlebury W (2006) Neuronal circuitry and synaptic organization of trigeminal proprioceptive afferents mediating tongue movement and jaw-tongue coordination via hypoglossal premotor neurons. Eur J Neurosci 23:3269–3283. doi:10.1111/j.1460-9568.2006.04858.x CrossRefPubMed

Lysakowski A (1996) Synaptic organization of the crista ampullaris in vertebrates. Ann N Y Acad Sci 781:164–182CrossRefPubMed

Mameli O, Tolu E (1986) Vestibular ampullar modulation of hypoglossal neurons. Physiol Behav 37:773–775 (pii: 0031-9384(86)90183-6)CrossRefPubMed

Mameli O, Tolu E, Melis F, Caria MA (1988) Labyrinthine projection to the hypoglossal nucleus. Brain Res Bull 20:83–88 (pii: 0361-9230(88)90011-1)CrossRefPubMed

Mameli O, Melis F, De Riu PL (1994) Visual and vestibular projections to tongue motoneurons. Brain Res Bull 33:7–16 (pii: 0361-9230(94)90044-2)CrossRefPubMed

Mandal R, Anderson CW (2009) Anatomical organization of brainstem circuits mediating feeding motor programs in the marine toad, Bufo marinus. Brain Res 1298:99–110. doi:10.1016/j.brainres.2009.08.024 CrossRefPubMed

Mandal R, Anderson CW (2010) Identification of muscle spindles in the submentalis muscle of the marine toad, Bufo marinus and its potential proprioceptive capacity in jaw-tongue coordination. Anat Rec (Hoboken) 293:1568–1573. doi:10.1002/ar.21197 CrossRef

Mateika JH, Millrood DL, Kim J, Rodriguez HP, Samara GJ (1999) Response of human tongue protrudor and retractors to hypoxia and hypercapnia. Am J Respir Crit Care Med 160:1976–1982. doi:10.1164/ajrccm.160.6.9903001 CrossRefPubMed

Matesz C (1979) Central projection of the VIIIth cranial nerve in the frog. Neuroscience 4:2061–2071 (pii: 0306-4522(79)90078-2)CrossRefPubMed

Matesz C (1994) Synaptic relations of the trigeminal motoneurons in a frog (Rana esculenta). Eur J Morphol 32:117–121PubMed

Matesz C, Szekely G (1977) The dorsomedial nuclear group of cranial nerves in the frog. Acta Biol Acad Sci Hung 28:461–474PubMed

Matesz C, Szekely G (1978) The motor column and sensory projections of the branchial cranial nerves in the frog. J Comp Neurol 178:157–176. doi:10.1002/cne.901780109 CrossRefPubMed

Matesz C, Szekely G (1996) Organization of the ambiguus nucleus in the frog (Rana esculenta). J Comp Neurol 371:258–269. doi:10.1002/(SICI)1096-9861(19960722)371:2<258:AID-CNE6>3.0.CO;2-1 CrossRefPubMed

Matesz C, Schmidt I, Szabo L, Birinyi A, Szekely G (1999) Organization of the motor centres for the innervation of different muscles of the tongue: a neuromorphological study in the frog. Eur J Morphol 37:190–194CrossRefPubMed

Matesz C, Kulik A, Bacskai T (2002) Ascending and descending projections of the lateral vestibular nucleus in the frog Rana esculenta. J Comp Neurol 444:115–128. doi:10.1002/cne.10137 CrossRefPubMed

Matesz C, Kovalecz G, Veress G, Deak A, Racz E, Bacskai T (2008) Vestibulotrigeminal pathways in the frog, Rana esculenta. Brain Res Bull 75:371–374. doi:10.1016/j.brainresbull.2007.10.049 CrossRefPubMed

Matesz K, Kecskes S, Bacskai T, Racz E, Birinyi A (2014) Brainstem circuits underlying the prey-catching behavior of the frog. Brain Behav Evol 83:104–111. doi:10.1159/000357751 PubMed

Matsushima TA, Satou M, Ueda K (1986) Glossopharyngeal and tectal influences on tongue-muscle motoneurons in the Japanese toad. Brain Res 365:198–203CrossRefPubMed

Matsushima T, Satou M, Ueda K (1987) Direct contacts between glossopharyngeal afferent terminals and hypoglossal motoneurons revealed by double labeling with cobaltic-lysine and horseradish peroxidase in the Japanese toad. Neurosci Lett 80:241–245CrossRefPubMed

Montuelle SJ, Herrel A, Libourel PA, Reveret L, Bels VL (2009) Locomotor-feeding coupling during prey capture in a lizard (Gerrhosaurus major): effects of prehension mode. J Exp Biol 212:768–777. doi:10.1242/jeb.026617 CrossRefPubMed

Morimoto T, Takebe H, Sakan I, Kawamura Y (1978) Reflex activation of extrinsic tongue muscles by jaw closing muscle proprioceptors. Jpn J Physiol 28:461–471CrossRefPubMed

Morimoto T, Inoue T, Masuda Y, Nagashima T (1989) Sensory components facilitating jaw-closing muscle activities in the rabbit. Exp Brain Res 76:424–440CrossRefPubMed

Munoz A, Munoz M, Gonzalez A, ten Donkelaar HJ (1997) Spinal ascending pathways in amphibians: cells of origin and main targets. J Comp Neurol 378:205–228. doi:10.1002/(SICI)1096-9861(19970210)378:2<205:AID-CNE5>3.0.CO;2-7 CrossRefPubMed

Nakachi T, Ishiko N (1986) Gustatory signal processing in the glossopharyngeo-hypoglossal reflex arc of the frog. Jpn J Physiol 36:189–208CrossRefPubMed

Nishikawa KC (1999) Neuromuscular control of prey capture in frogs. Philos Trans R Soc Lond B Biol Sci 354:941–954. doi:10.1098/rstb.1999.0445 CrossRefPubMedPubMedCentral

Nishikawa KC (2000) Feeding in frogs. In: Schwenk K (ed) Feeding: form, function and evolution in tetrapod vertebrates. Academic Press, San Diego, pp 117–144CrossRef

Nishikawa KC, Gans C (1992) The role of hypoglossal sensory feedback during feeding in the marine toad, Bufo marinus. J Exp Zool 264:245–252. doi:10.1002/jez.1402640303 CrossRefPubMed

Nishikawa KC, Gans C (1996) Mechanisms of tongue protraction and narial closure in the marine toad Bufo marinus. J Exp Biol 199:2511–2529PubMed

Nishikawa KC, Roth G, Dicke U (1991) Motor neurons and motor columns of the anterior spinal cord of salamanders: posthatching development and phylogenetic distribution. Brain Behav Evol 37:368–382CrossRefPubMed

Nishikawa KC, Anderson CW, Deban SM, O’Reilly JC (1992) The evolution of neural circuits controlling feeding behavior in frogs. Brain Behav Evol 40:125–140CrossRefPubMed

Oka Y, Takeuchi H, Satou M, Ueda K (1987) Cobaltic lysine study of the morphology and distribution of the cranial nerve efferent neurons (motoneurons and preganglionic parasympathetic neurons) and rostral spinal motoneurons in the Japanese toad. J Comp Neurol 259:400–423. doi:10.1002/cne.902590308 CrossRefPubMed

Olabi B, Bergquist F, Dutia MB (2009) Rebalancing the commissural system: mechanisms of vestibular compensation. J Vestib Res 19:201–207. doi:10.3233/VES-2009-0367 PubMed

Opdam R, Kemali M, Nieuwenhuys R (1976) Topological analysis of the brain stem of the frogs Rana esculenta and Rana catesbeiana. J Comp Neurol 165:307–332. doi:10.1002/cne.901650304 CrossRefPubMed

Racz E, Bacskai T, Szabo G, Szekely G, Matesz C (2008) Organization of last-order premotor interneurons related to the protraction of tongue in the frog, Rana esculenta. Brain Res 1187:111–115. doi:10.1016/j.brainres.2007.10.067 CrossRefPubMed

Rossiter CD, Yates BJ (1996) Vestibular influences on hypoglossal nerve activity in the cat. Neurosci Lett 211:25–28 (pii: 0304394096127105)CrossRefPubMed

Sato T, Nishishita K, Okada Y, Toda K (2012) Efferent fibers innervate gustatory and mechanosensitive afferent fibers in frog fungiform papillae. Chem Senses 37:315–324. doi:10.1093/chemse/bjr096 CrossRefPubMed

Sauerland EK, Mitchell SP (1970) Electromyographic activity of the human Genioglossus muscle in response to respiration and to positional changes of the head. Bull Los Angeles Neurol Soc 35:69–73PubMed

Sokoloff AJ (1991) Musculotopic organization of the hypoglossal nucleus in the grass frog, Rana pipiens. J Comp Neurol 308:505–512. doi:10.1002/cne.903080402 CrossRefPubMed

Stensaas LJ, Stensaas SS (1971) Light and electron microscopy of motoneurons and neuropile in the amphibian spinal cord. Brain Res 31:67–84 (pii: 0006-8993(71)90634-2)CrossRefPubMed

Stuesse SL, Fish SE (1984) Projections to the cardioinhibitory region of the nucleus ambiguus of rat. J Comp Neurol 229:271–278. doi:10.1002/cne.902290211 CrossRefPubMed

Stuesse SL, Cruce WL, Powell KS (1983) Afferent and efferent components of the hypoglossal nerve in the grass frog, Rana pipiens. J Comp Neurol 217:432–439. doi:10.1002/cne.902170407 CrossRefPubMed

Szekely G, Matesz C (1993) The efferent system of cranial nerve nuclei: a comparative neuromorphological study. Adv Anat Embryol Cell Biol 128:1–92CrossRefPubMed

Takei K, Oka Y, Satou M, Ueda K (1987) Distribution of motoneurons involved in the prey-catching behavior in the Japanese toad, Bufo japonicus. Brain Res 410:395–400 (pii: 0006-8993(87)90346-5)CrossRefPubMed

Tolu E, Caria MA, Simula ME, Lacana P (1994) Muscle spindle and periodontal trigeminal afferents modulate the hypoglossal motoneuronal activity. Arch Ital Biol 132:93–104PubMed

Uemura-Sumi M, Mizuno N, Nomura S, Iwahori N, Takeuchi Y, Matsushima R (1981) Topographical representation of the hypoglossal nerve branches and tongue muscles in the hypoglossal nucleus of macaque monkeys. Neurosci Lett 22:31–35 (pii: 0304-3940(81)90280-9)CrossRefPubMed

Valdez CM, Nishikawa KC (1997) Sensory modulation and behavioral choice during feeding in the Australian frog, Cyclorana novaehollandiae. J Comp Physiol A 180:187–202CrossRefPubMed

Weerasuriya A (1989) In search of the motor pattern generator for snapping in toads. In: Ewert J-P, Arbib MA (eds) Visuomotor coordination: amphibians, comparisons, models, and robots. Plenum, New York

Wolff JB, Lee MJ, Anderson CW (2004) Contribution of the submentalis muscle to feeding mechanics in the leopard frog, Rana pipiens. J Exp Zool A Comp Exp Biol 301:666–673. doi:10.1002/jez.a.55 CrossRefPubMed

Wouterlood FG, van Haeften T, Blijleven N, Perez-Templado P, Perez-Templado H (2002) Double-label confocal laser-scanning microscopy, image restoration, and real-time three-dimensional reconstruction to study axons in the central nervous system and their contacts with target neurons. Appl Immunohistochem Mol Morphol 10:85–95PubMed

Wouterlood FG, Bockers T, Witter MP (2003) Synaptic contacts between identified neurons visualized in the confocal laser scanning microscope. Neuroanatomical tracing combined with immunofluorescence detection of post-synaptic density proteins and target neuron-markers. J Neurosci Methods 128:129–142 (pii: S0165027003001717)CrossRefPubMed

Title: Neural circuits underlying tongue movements for the prey-catching behavior in frog: distribution of primary afferent terminals on motoneurons supplying the tongue
Authors: Szilvia Kecskes
Clara Matesz
Botond Gaál
András Birinyi
Publication date: 01-04-2016
Publisher: Springer Berlin Heidelberg
Published in: Brain Structure and Function / Issue 3/2016
Print ISSN: 1863-2653
Electronic ISSN: 1863-2661
DOI: https://doi.org/10.1007/s00429-014-0988-1

At a glance: The STEP trials

Springer Medicine

Neural circuits underlying tongue movements for the prey-catching behavior in frog: distribution of primary afferent terminals on motoneurons supplying the tongue

Abstract

At a glance: The STEP trials

Springer Medicine

Abstract

Please log in to get access to this content

Other articles of this Issue 3/2016

Congenital blindness affects diencephalic but not mesencephalic structures in the human brain

Voluntary exercise induces neurogenesis in the hypothalamus and ependymal lining of the third ventricle

Optogenetic inhibition of cortical afferents in the nucleus accumbens simultaneously prevents cue-induced transient synaptic potentiation and cocaine-seeking behavior

Erratum to: Anosmin-1 over-expression regulates oligodendrocyte precursor cell proliferation, migration and myelin sheath thickness

Endocannabinoid CB1 receptor-mediated rises in Ca2+ and depolarization-induced suppression of inhibition within the laterodorsal tegmental nucleus

Mesencephalic origin of the rostral Substantia nigra pars reticulata