Top

Published in:

01-11-2020 | Original Article

Volumetric analysis and morphological assessment of the ascending olfactory pathway in an elasmobranch and a teleost using diceCT

Authors: Victoria Camilieri-Asch, Jeremy A. Shaw, Kara E. Yopak, Lucille Chapuis, Julian C. Partridge, Shaun P. Collin

Published in: Brain Structure and Function | Issue 8/2020

Abstract

The size (volume or mass) of the olfactory bulbs in relation to the whole brain has been used as a neuroanatomical proxy for olfactory capability in a range of vertebrates, including fishes. Here, we use diffusible iodine-based contrast-enhanced computed tomography (diceCT) to test the value of this novel bioimaging technique for generating accurate measurements of the relative volume of the main olfactory brain areas (olfactory bulbs, peduncles, and telencephalon) and to describe the morphological organisation of the ascending olfactory pathway in model fish species from two taxa, the brownbanded bamboo shark Chiloscyllium punctatum and the common goldfish Carassius auratus. We also describe the arrangement of primary projections to the olfactory bulb and secondary projections to the telencephalon in both species. Our results identified substantially larger olfactory bulbs and telencephalon in C. punctatum compared to C. auratus (comprising approximately 5.2% vs. 1.8%, and 51.8% vs. 11.8% of the total brain volume, respectively), reflecting differences between taxa, but also possibly in the role of olfaction in the sensory ecology of these species. We identified segregated primary projections to the bulbs, associated with a compartmentalised olfactory bulb in C. punctatum, which supports previous findings in elasmobranch fishes. DiceCT imaging has been crucial for visualising differences in the morphological organisation of the olfactory system of both model species. We consider comparative neuroanatomical studies between representative species of both elasmobranch and teleost fish groups are fundamental to further our understanding of the evolution of the olfactory system in early vertebrates and the neural basis of olfactory abilities.

Available only for authorised users

Akhilesh K, Bineesh K, Gopalakrishnan A, Jena J, Basheer V, Pillai N (2014) Checklist of chondrichthyans in indian waters. J Mar Biol Assoc India 56:109–120

Atkinson CJ, Martin KJ, Fraser GJ, Collin SP (2016) Morphology and distribution of taste papillae and oral denticles in the developing oropharyngeal cavity of the bamboo shark. Chiloscyllium Punctatum Biol Open 5(1759):1769

Bauchot R, Platel R, Ridet J-M, Diagne M, Delfini C (1995) Encéphalisation et adaptations écobiologiques chez les chondrichtyens. Cybium 19:153–165

Bauchot R, Ridet J-M, Bauchot M-L (1989) The brain organization of butterflyfishes. Environ Biol Fishes 25:205

Beatty SJ, Allen MG, Whitty JM, Lymbery AJ, Keleher JJ, Tweedley JR, Ebner BC, Morgan DL (2017) First evidence of spawning migration by goldfish (Carassius auratus); implications for control of a globally invasive species. Ecol Freshw Fish 26:444–455

Bleckmann H, Hofmann MH (1999) Special senses. In: Hamlett W (ed) Sharks, skates, and rays: the biology of elasmobranch fishes. Johns Hopkins Univ Press, Baltimore, pp 300–328

Bock WJ, Shear CR (1972) A staining method for gross dissection of vertebrate muscles. Anatomischer Anzeiger 130:222–227PubMed

Brandstätter R, Kotrschal A (1990) Brain Growth Patterns in Four European Cyprinid Fish Species (Cyprinidae, Teleostei): Roach (Rutilus rutilus), Bream (Abramis brama), Common Carp (Cyprinus carpio) and Sabre Carp (Pelecus cultratus). Brain Behav Evol 35:195–211PubMed

Broglio C, Rodríguez F, Salas C (2003) Spatial cognition and its neural basis in teleost fishes. Fish Fish 4:247–255

Buschhüter D, Smitka M, Puschmann S, Gerber JC, Witt M, Abolmaali N, Hummel T (2008) Correlation between olfactory bulb volume and olfactory function. Neuroimage 42:498–502PubMed

Buytaert J, Goyens J, De Greef D, Aerts P, Dirckx J (2014) Volume shrinkage of bone, brain and muscle tissue in sample preparation for micro-CT and light sheet fluorescence microscopy (LSFM). Microsc Microanal 20:1208–1217PubMed

Camilieri-Asch V, Shaw JA, Mehnert A, Yopak KE, Partridge JC, Collin SP (2020) diceCT: a valuable technique to study the nervous system of fishes. Eneuro. https://doi.org/10.1523/ENEURO.0076-20.2020CrossRefPubMedPubMedCentral

Camilieri-Asch V, Yopak KE, Rea A, Mitchell JD, Partridge JC, Collin SP (in press) Convergence of olfactory inputs within the central nervous system of a cartilaginous and a bony fish: an anatomical indicator for olfactory sensitivity. Brain Behav Evol. https://doi.org/10.1159/000510688

Caprio J (1978) Olfaction and taste in the channel catfish: an electrophysiological study of the responses to amino acids and derivatives. J Comp Physiol 123:357–371

Chapman BK, Chapman CA (2017) Small-scale elasmobranch husbandry and life support systems for research environments. In: Smith MFL (ed) the elasmobranch husbandry manual ii––recent advances in the care of sharks, rays and their relatives. Ohio Biological Survey, Columbus, p 403

Chapuis L (2017) The acoustic world of sharks. The University of Western Australia, Perth

Chin A, Tobin A, Simpfendorfer C, Heupel M (2012) Reef sharks and inshore habitats: patterns of occurrence and implications for vulnerability. Mar Ecol Prog Ser 460:115–125

Collin SP (2007) Nervous and sensory systems. Fish physiol 26:121–179

Collin SP (2012) The neuroecology of cartilaginous fishes: sensory strategies for survival. Brain Behav Evol 80:80–96PubMed

Collin SP, Kempster RM, Yopak KE (2015) How elasmobranchs sense their environment. Fish physiol 34:19–99

Culling CFA (1963) Handbook of Histopathological techniques, 2nd edn. butterworth and co canada ltd., Toronto

Daniel JF (1934) The special senses of Heptanchus maculatus. In: Daniel JF (ed) The elasmobranch fishes. Univ California Press, Berkeley, pp 268–295

Demski LS, Dulka JG (1984) Functional-anatomical studies on sperm release evoked by electrical stimulation of the olfactory tract in goldfish. Brain Res 291:241–247PubMed

Døving K (1986) Functional properties of the fish olfactory system. Prog Sensory Physiol 6:39–104

Døving K, Pinching A (1973) Selective degeneration of neurones in the olfactory bulb following prolonged odour exposure. Brain Res 52:115–129PubMed

Døving K, Selset R (1980) Behavior patterns in cod released by electrical stimulation of olfactory tract bundlets. Science 207:559–560PubMed

Døving KB, Selset R, Thommesen G (1980) Olfactory sensitivity to bile acids in salmonid fishes. Acta Physiol Scand 108:123–131PubMed

Dryer L, Graziadei P (1994a) Mitral cell dendrites: a comparative approach. Anat Embryol 189:91–106

Dryer L, Graziadei P (1993) A pilot study on morphological compartmentalization and heterogeneity in the elasmobranch olfactory bulb. Anat Embryol 188:41–51

Dryer L, Graziadei P (1994) Projections of the olfactory bulb in an elasmobranch fish, Sphyrna tiburo: segregation of inputs in the telencephalon. Anat Embryol 190:563–572

Dryer L, Graziadei P (1996) Synaptology of the olfactory bulb of an elasmobranch fish, Sphyrna tiburo. Anat Embryol 193:101–114

Ebbesson SO (1972) New insights into the organization of the shark brain. Comp Biochem Physiol A Physiol 42:121–129

Edinger L, Rand HW (1908) The relations of comparative anatomy to comparative psychology. J Comp Neurol Psychol 18:437–457

Eifert C, Farnworth M, Schulz-Mirbach T, Riesch R, Bierbach D, Klaus S, Wurster A, Tobler M, Streit B, Indy JR, Arias-Rodriguez L, Plath M (2015) Brain size variation in extremophile fish: local adaptation versus phenotypic plasticity. J Zool 295:143–153

Etnier DA, Starnes WC (1993) The fishes of Tennessee. Newfound Press, Knoxville

Evans HE (1952) The correlation of brain pattern and feeding habits in four species of cyprinid fishes. J Comp Neurol 97:133–142PubMed

Ferrando S, Amaroli A, Gallus L, Aicardi S, Di Blasi D, Christiansen JS, Vacchi M, Ghigliotti L (2019) Secondary folds contribute significantly to the total surface area in the olfactory organ of Chondrichthyes. Front Physiol 10:245PubMedPubMedCentral

Ferrando S, Gallus L, Ghigliotti L, Amaroli A, Abbas G, Vacchi M (2017a) Clarification of the terminology of the olfactory lamellae in chondrichthyes. Anat Rec 300:2039–2045

Ferrando S, Gallus L, Ghigliotti L, Vacchi M, Amaroli A, Nielsen J, Christiansen J, Pisano E (2017b) Anatomy of the olfactory bulb in Greenland shark Somniosus microcephalus (Bloch and Schneider, 1801). J Appl Ichthyol 33:263–269

Ferrando S, Gambardella C, Ravera S, Bottero S, Ferrando T, Gallus L, Manno V, Salati AP, Ramoino P, Tagliafierro G (2009) Immunolocalization of G-protein alpha subunits in the olfactory system of the cartilaginous fish Scyliorhinus canicula. Neuroscience 292:1771–1779

Finger TE (1988) Organization of chemosensory systems within the brains of bony fishes. In: Atema J (ed) Sensory biology of aquatic animals. Springer, New York, pp 339–363

Friedrich RW, Korsching SI (1998) Chemotopic, combinatorial, and noncombinatorial odorant representations in the olfactory bulb revealed using a voltage-sensitive axon tracer. J Neurosci 18:9977–9988PubMedPubMedCentral

Gardiner JM, Hueter RE, Maruska KP, Sisneros JA, Casper BM, Mann DA, Demski LS (2012) Sensory physiology and behavior of elasmobranchs. In: Carrier JC, Musick JA, Heithaus MR (eds) Biology of sharks and their relatives, vol 1. CRC Press, Boca Raton, pp 349–401

Gardiner JM, Whitney NM, Hueter RE (2015) Smells like home: the role of olfactory cues in the homing behavior of blacktip sharks, Carcharhinus limbatus. Integr Comp Biol 55:495–506PubMed

Gemne G, Døving KB (1969) Ultrastructural properties of primary olfactory neurons in fish (Lota lota L.). Am J Anat 126:457–475PubMed

Gignac PM, Kley NJ (2014) Iodine-enhanced micro-CT imaging: methodological refinements for the study of the soft-tissue anatomy of post-embryonic vertebrates. J Exp Zool B Mol Dev Evol 322:166–176PubMed

Gignac PM, Kley NJ (2018) The utility of dicect imaging for high-throughput comparative neuroanatomical studies. Brain Behav Evol 91:180–190PubMed

Gignac PM, Kley NJ, Clarke JA, Colbert MW, Morhardt AC, Cerio D, Cost IN, Cox PG, Daza JD, Early CM, Echols MS, Henkelman RM, Herdina AN, Holliday CM, Li Z, Mahlow K, Merchant S, Muller J, Orsbon CP, Paluh DJ, Thies ML, Tsai HP, Witmer LM (2016) Diffusible iodine-based contrast-enhanced computed tomography (diceCT): an emerging tool for rapid, high-resolution, 3-D imaging of metazoan soft tissues. J Anat 228:889–909PubMedPubMedCentral

Gonzalez-Voyer A, Kolm N (2010) Sex, ecology and the brain: evolutionary correlates of brain structure volumes in Tanganyikan cichlids. PLoS ONE 5:e14355PubMedPubMedCentral

Gonzalez-Voyer A, Winberg S, Kolm N (2009) Brain structure evolution in a basal vertebrate clade: evidence from phylogenetic comparative analysis of cichlid fishes. BMC Evol Biol 9:238PubMedPubMedCentral

Hamdani E-H, Stabell OB, Alexander G, Døving KB (2000) Alarm reaction in the crucian carp is mediated by the medial bundle of the medial olfactory tract. Chem Senses 25:103–109PubMed

Hamdani EH, Alexander G, Døving KB (2001a) Projection of sensory neurons with microvilli to the lateral olfactory tract indicates their participation in feeding behaviour in crucian carp. Chem Senses 26:1139–1144PubMed

Hamdani EH, Døving KB (2002) The alarm reaction in crucian carp is mediated by olfactory neurons with long dendrites. Chem Senses 27:395–398

Hamdani EH, Døving KB (2003) Sensitivity and selectivity of neurons in the medial region of the olfactory bulb to skin extract from conspecifics in crucian carp, Carassius carassius. Chem Senses 28:181–189

Hamdani EH, Døving KB (2007) The functional organization of the fish olfactory system. Prog Neurobiol 82:80–86

Hamdani EH, Kasumyan A, Døving KB (2001b) Is feeding behaviour in crucian carp mediated by the lateral olfactory tract? Chem Senses 26:1133–1138PubMed

Hammock J (2005) Structure, function and context the impact of morphometry and ecology on olfactory sensitivity. Massachusetts Institute of Technology, Cambridge

Hansen A, Rolen SH, Anderson K, Morita Y, Caprio J, Finger TE (2003) Correlation between olfactory receptor cell type and function in the channel catfish. J Neurosci 23:9328–9339PubMedPubMedCentral

Hansen A, Zeiske E (1998) The peripheral olfactory organ of the zebrafish, Danio rerio: an ultrastructural study. Chem Senses 23:39–48PubMed

Hansen A, Zielinski BS (2005) Diversity in the olfactory epithelium of bony fishes: development, lamellar arrangement, sensory neuron cell types and transduction components. J Neurocytol 34:183–208PubMed

Hansen A, Zippel HP, Sorensen PW, Caprio J (1999) Ultrastructure of the olfactory epithelium in intact, axotomized, and bulbectomized goldfish, Carassius auratus. Microsc Res Tech 45:325–338PubMed

Hara T (1982) Chemoreception in fishes. Elsevier, Amsterdam

Hara T (1992a) Fish Chemoreception. Chapman and Hall, London

Hara T (1992b) Overview and introduction Fish chemoreception. Springer, Dordrecht, pp 1–12

Hara T, Zhang C (1998) Topographic bulbar projections and dual neural pathways of the primary olfactory neurons in salmonid fishes. Neuroscience 82:301–313PubMed

Hara TJ (1975) Olfaction in fish. Prog Neurobiol 5:271–335PubMed

Hara TJ (1994) The diversity of chemical stimulation in fish olfaction and gustation. Rev Fish Biol Fisheries 4:1–35

Hara TJ, Zhang C (1996) Spatial projections to the olfactory bulb of functionally distinct and randomly distributed primary neurons in salmonid fishes. Neurosci Res 26:65–74PubMed

Harahush B, Fischer A, Collin S (2007) Captive breeding and embryonic development of Chiloscyllium punctatum Muller & Henle, 1838 (Elasmobranchii: Hemiscyllidae). J Fish Biol 71:1007–1022

Haug H (1986) History of neuromorphometry. J Neurosci Methods 18:1–17PubMed

Heimel P, Swiadek NV, Slezak P, Kerbl M, Schneider C, Nurnberger S, Redl H, Teuschl AH, Hercher D (2019) Iodine-enhanced micro-ct imaging of soft tissue on the example of peripheral nerve regeneration. Contrast Media Mol Imaging 2019:7483745PubMedPubMedCentral

Hofmann MH, Northcutt RG (2012) Forebrain organization in elasmobranchs. Brain Behav Evol 80:142–151PubMed

Huber R, Rylander MK (1992) Brain morphology and turbidity preference in Notropis and related genera (Cyprinidae, Teleostei). Environ Biol Fishes 33:153–165

Huber R, van Staaden MJ, Kaufman LS, Liem KF (1997) Microhabitat use, trophic patterns, and the evolution of brain structure in African cichlids. Brain Behav Evol 50:167–182PubMed

Hueter RE, Mann DA, Maruska KP, Sisneros JA, Demski LS (2004) Sensory biology of elasmobranchs. In: Carrier JC, Musick JA, Heithaus MR (eds) Biology of sharks and their relatives. CRC Press, Boca Raton, pp 325–368

Jacobs LF (2012) From chemotaxis to the cognitive map: the function of olfaction. Proc Natl Acad Sci 109:10693–10700PubMedPubMedCentral

Jerison H (1973) Brain, behavior and the evolution of mind. In: Jerison HJ (ed) Evolution of the Brain and Intelligence. Acad Press, New York, p 17

Kajiura SM, Forni JB, Summers AP (2005) Olfactory morphology of carcharhinid and sphyrnid sharks: does the cephalofoil confer a sensory advantage? J Morphol 264:253–263PubMed

Kasumyan AO (2004) The olfactory system in fish: structure, function, and role in behavior. J Ichthyol 44:180–223

Kerckhofs G, Stegen S, van Gastel N, Sap A, Falgayrac G, Penel G, Durand M, Luyten FP, Geris L, Vandamme K (2018) Simultaneous three-dimensional visualization of mineralized and soft skeletal tissues by a novel microCT contrast agent with polyoxometalate structure. Biomaterials 159:1–12PubMed

Kleerekoper H (1969) Olfaction in fishes. Indiana University Press, Bloomington

Kolm N, Gonzales-Voyer A, Brelin D, Winberg S (2009) Evidence for small scale variation in the vertebrate brain: mating strategy and sex affect brain size and structure in wild brown trout (Salmo trutta). J Evol Biol 22:2524–2531PubMed

Kotrschal A, Deacon AE, Magurran AE, Kolm N (2017) Predation pressure shapes brain anatomy in the wild. Evol Ecol 31:619–633PubMedPubMedCentral

Kotrschal K, Junger H (1988) Patterns of brain morphology in mid-European Cyprinidae (Pisces, Teleostei): a quantitative histological study. J Hirnforsch 29:341–352PubMed

Kotrschal K, Palzenberger M (1992) Neuroecology of cyprinids: comparative, quantitative histology reveals diverse brain patterns. In: Wieser W, Schiemer F, Goldschmidt A, Kotrschal K (eds) Environmental biology of European cyprinids. Springer, New York, pp 135–152

Kotrschal K, Van Staaden M, Huber R (1998) Fish brains: evolution and environmental relationships. Rev Fish Biol Fisheries 8:373–408

Kottelat M (2007) and Freyhof, Jr. Publications Kottelat, Handbook of European freshwater fishes

Laberge F, Hara TJ (2001) Neurobiology of fish olfaction: a review. Brain Res Rev 36:46–59PubMed

Lanford PJ, Platt C, Popper AN (2000) Structure and function in the saccule of the goldfish (Carassius auratus): a model of diversity in the non-amniote ear. Hear Res 143:1–13PubMed

Last PR, Stevens JD (2009) Sharks and rays of Australia. CSIRO, Hobart

Li Z, Clarke JA, Ketcham RA, Colbert MW, Yan F (2015) An investigation of the efficacy and mechanism of contrast-enhanced X-ray computed tomography utilizing iodine for large specimens through experimental and simulation approaches. BMC Physiol 15:5PubMedPubMedCentral

Lisney T, Collin S (2006) Brain morphology in large pelagic fishes: a comparison between sharks and teleosts. J Fish Biol 68(532):554

Lisney TJ, Bennett MB, Collin SP (2007) Volumetric analysis of sensory brain areas indicates ontogenetic shifts in the relative importance of sensory systems in elasmobranchs. Raffles B Zool. 14(7):15

Lisney TJ, Yopak KE, Camilieri-Asch V, Collin SP (2017) Ontogenetic shifts in brain organization in the bluespotted stingray Neotrygon kuhlii (Chondrichthyes: Dasyatidae). Brain Behav Evol. 89(68):83

Lisney TJ, Yopak KE, Montgomery JC, Collin SP (2008) Variation in brain organization and cerebellar foliation in chondrichthyans: batoids. Brain Behav Evol. 72(262):282

Mackay-Sim A, Royet J-P (2006) Structure and function of the olfactory system. Olfaction brain. 353:3–27

Marshall N (1967) The olfactory organs of bathypelagic fishes. Paper presented at the Symposia of the Zoological Society, London

Marshall NB (1971) Explorations in the life of fishes. Harvard University Press, Cambridge

Meng Q, Yin M (1981) A study of the olfactory organ of the sharks. Trans Chin Ichthyol Soc 2:1–24

Meredith TL, Caprio J, Kajiura SM (2012) Sensitivity and specificity of the olfactory epithelia of two elasmobranch species to bile salts. J Exp Biol 215:2660–2667PubMed

Meredith TL, Kajiura SM (2010) Olfactory morphology and physiology of elasmobranchs. J Exp Biol 213:3449–3456PubMed

Meredith TL, Kajiura SM, Hansen A (2013) The somatotopic organization of the olfactory bulb in elasmobranchs. J Morphol 274:447–455PubMed

Metscher BD (2009) MicroCT for developmental biology: a versatile tool for high-contrast 3D imaging at histological resolutions. Dev Dyn 238:632–640PubMed

Mingcheng MQY (1981) A study on the olfactory organ of skates, rays and chimaeras. J Fish China. 3(25):27

Montgomery JC, Sutherland KBW (1997) Sensory development of the Antarctic silverfish Pleuragramma antarcticum: a test for the ontogenetic shift hypothesis. Polar Biol 18:112–115

Morell P, Quarles RH (1999) Characteristic composition of myelin. In: Siegel GJ, Agranoff BW, Albers RW (eds) Basic neurochemistry molecular, cellular and medical aspects. Lippincott, Philadelphia

Mori K, Nagao H, Yoshihara Y (1999) The olfactory bulb: coding and processing of odor molecule information. Science 286:711–715PubMed

Morita Y, Finger TE (1998) Differential projections of ciliated and microvillous olfactory receptor cells in the catfish, Ictalurus punctatus. J Comp Neurol 398:539–550PubMed

National Health and Medical Research Council (2013) Australian code of practice for the care and use of animals for scientific purposes, 8th edn. National Health and Medical Research Council, Canberra. http://www.nhmrc.gov.au/_files_nhmrc/publications/attachments/ea28_code_care_use_animals_130728.pdf. Accessed 23 June 2015

Nieuwenhuys R (1966) Comparative anatomy of olfactory centres and tracts. Prog Brain Res 23:1–64

Nieuwenhuys R, Kremers J, van Huijzen C (1977) The brain of the crossopterygian fish Latimeria chalumnae: a survey of its gross structure. Anat Embryol 151:157–169

Nikonov AA, Caprio J (2001) Electrophysiological evidence for a chemotopy of biologically relevant odors in the olfactory bulb of the channel catfish. J Neurophysiol 86:1869–1876PubMed

Northcutt RG (1977) Elasmobranch central nervous system organization and its possible evolutionary significance. Am Zool 17:411–429

Northcutt RG (1978) Brain organization in the cartilaginous fishes. In: Hodgson ES, Mathewson RF (eds) Sensory biology of sharks, skates, and rays Washington DC. Office of Naval Research, Dept of the Navy, pp 117–193

Nosal AP, Chao Y, Farrara JD, Chai F, Hastings PA (2016) Olfaction contributes to pelagic navigation in a coastal shark. PLoS ONE 11:e0143758PubMedPubMedCentral

Panhuber H, Laing D, Willcox M, Eagleson G, Pittman E (1985) The distribution of the size and number of mitral cells in the olfactory bulb of the rat. J Anat 140:297PubMedPubMedCentral

Pollen AA, Dobberfuhl AP, Scace J, Igulu MM, Renn SC, Shumway CA, Hofmann HA (2007) Environmental complexity and social organization sculpt the brain in Lake Tanganyikan cichlid fish. Brain Behav Evol 70:21–39PubMed

Popesku JT, Martyniuk CJ, Mennigen J, Xiong H, Zhang D, Xia X, Cossins AR, Trudeau VL (2008) The goldfish (Carassius auratus) as a model for neuroendocrine signaling. Mol Cell Endocrinol 293:43–56PubMed

Portavella M, Vargas JP (2005) Emotional and spatial learning in goldfish is dependent on different telencephalic pallial systems. Eur J Neurosci 21:2800–2806PubMed

Puzdrowski RL (1989) Peripheral distribution and central projections of the lateral-line nerves in goldfish, Carasius auratus (Part 2 of 2). Brain Behav Evol 34:121–131

Quinn TP (2018) The behavior and ecology of Pacific salmon and trout. University of Washington Press, Seattle

R Core Team (2019) R: a language and environment for statistical computing. https://www.r-project.org/. Accessed 1 Mar 2019

Ridet J, Bauchot R (1990) Quantitative analysis of the teleost brain: evolutionary and adaptive features of encephalization. II. Primary brain subdivisions. J Hirnforsch 31:433–458PubMed

Rooker JR, Secor DH, De Metrio G, Schloesser R, Block BA, Neilson JD (2008) Natal homing and connectivity in Atlantic bluefin tuna populations. Science 322:742–744PubMed

Rupp B, Reichert H, Wullimann MF (1996) The zebrafish brain: a neuroanatomical comparison with the goldfish. Anat Embryol 194:187–203

Ryan LA, Hemmi JM, Collin SP, Hart NS (2017) Electrophysiological measures of temporal resolution, contrast sensitivity and spatial resolving power in sharks. J Comp Physiol A 203:197–210

Sakka L, Coll G, Chazal J (2011) Anatomy and physiology of cerebrospinal fluid. Eur Ann Otorhinolaryngol Head Neck Dis 128:309–316PubMed

Salas C, Broglio C, Rodríguez F (2003) Evolution of forebrain and spatial cognition in vertebrates: conservation across diversity. Brain Behav Evol 62:72–82PubMed

Schluessel V, Bennett MB, Bleckmann H, Blomberg S, Collin SP (2008) Morphometric and ultrastructural comparison of the olfactory system in elasmobranchs: the significance of structure–function relationships based on phylogeny and ecology. J Morphol. 269(1365):1386

Schnitzlein H (1964) Correlation of habit and structure in the fish brain. Am Zool 4:21–32PubMed

Schwarze S, Bleckmann H, Schluessel V (2013) Avoidance conditioning in bamboo sharks (Chiloscyllium griseum and C. punctatum): behavioral and neuroanatomical aspects. J Comp Physiol A 199:843–856

Smeets W (1998) Cartilaginous fishes The central nervous system of vertebrates. Springer, Berlin, pp 551–654

Smeets WJ (1983) The secondary olfactory connections in two chondrichthians, the shark Scyliorhinus canicula and the ray Raja clavata. J Comp Neurol 218:334–344PubMed

Smeets WJ, Nieuwenhuys R, Roberts BL (2012) The central nervous system of cartilaginous fishes structure and functional correlations. Springer, Berlin

Sorensen PW, Hara TJ, Stacey NE (1987) Extreme olfactory sensitivity of mature and gonadally-regressed goldfish to a potent steroidal pheromone, 17α, 20β-dihydroxy-4-pregnen-3-one. J Comp Physiol A 160:305–313

Stacey N, Kyle AL (1983) Effects of olfactory tract lesions on sexual and feeding behavior in the goldfish. Physiol Behav 30:621–628PubMed

Striedter GF (2005) Principles of brain evolution. Sinauer Associates, Sunderland

Takami S, Luer CA, Graziadei P (1994) Microscopic structure of the olfactory organ of the clearnose skate. Raja eglanteria. Anatomy and embryology. 190:211–230PubMed

Theisen B, Zeiske E, Breucker H (1986) Functional morphology of the olfactory organs in the spiny dogfish (Squalus acanthias L.) and the small-spotted catshark (Scyliorhinus canicula (L.)). Acta Zoologica 67:73–86

Theisen B, Zeiske E, Silver W, Marui T, Caprio J (1991) Morphological and physiological studies on the olfactory organ of the striped eel catfish, Plotosus lineatus. Mar Biol 110:127–135

Theiss SM, Hart NS, Collin SP (2009) Morphological indicators of olfactory capability in wobbegong sharks (Orectolobidae, Elasmobranchii). Brain Behav Evol. 73(91):101

Timm LL, Fish FE (2012) A comparative morphological study of head shape and olfactory cavities of sharks inhabiting benthic and coastal/pelagic environments. J Exp Mar Biol Ecol 414:75–84

Tricas TC, Kajiura SM, Summers AP (2009) Response of the hammerhead shark olfactory epithelium to amino acid stimuli. J Comp Physiol A 195:947–954

Ullmann JF, Cowin G, Collin SP (2010a) Magnetic resonance microscopy of the barramundi (Lates calcarifer) brain. J Morphol. 271(1446):1456

Ullmann JF, Cowin G, Collin SP (2010b) Quantitative assessment of brain volumes in fish: comparison of methodologies. Brain Behav Evol 76(261):270

Uylings H, Van Eden C, Hofman M (1986) Morphometry of size/volume variables and comparison of their bivariate relations in the nervous system under different conditions. J Neurosci Methods 18:19–37PubMed

van Staaden MJ, Huber P, Kaufman LS, Liem KF (1994) Brain and body size, general patterns, and evolutionary trends. Zoology 98:165–178

Vickerton P, Jarvis J, Jeffery N (2013) Concentration-dependent specimen shrinkage in iodine-enhanced microCT. J Anat 223:185–193PubMedPubMedCentral

Wagner H-J (2001a) Brain areas in abyssal demersal fishes. Brain Behav Evol 57:301–316PubMed

Wagner H-J (2001b) Sensory brain areas in mesopelagic fishes. Brain Behav Evol 57:117–133PubMed

Wagner H-J (2002) Sensory brain areas in three families of deep-sea fish (slickheads, eels and grenadiers): comparison of mesopelagic and demersal species. Mar Biol 141:807

Wagner HJ (2003) Volumetric analysis of brain areas indicates a shift in sensory orientation during development in the deep-sea grenadier Coryphaenoides armatus. Mar Biol 142:791–797

Weil A (1928) A rapid method for staining myelin sheaths. Archives of Neurology & Psychiatry 20:392–393

Weltzien F-A, Höglund E, Hamdani EH, Døving KB (2003) Does the lateral bundle of the medial olfactory tract mediate reproductive behavior in male crucian carp? Chem Senses 28:293–300PubMed

Wenzel BM, Meisami E (1987) Number, size, and density of mitral cells in the olfactory bulbs of the northern fulmar and rock dove. Ann N Y Acad Sci 510:700–702

Westerman RA, Wilson JAF (1968) The fine structure of the olfactory tract in the teleost Carassius carassius L. Zeitschrift für Zellforschung 91:186–199

White W, Potter I (2004) Habitat partitioning among four elasmobranch species in nearshore, shallow waters of a subtropical embayment in Western Australia. Mar Biol 145:1023–1032

Wickham H, Chang W, Henry L, Pedersen TL, Takahashi K, Wilke C, Woo K, RStudio (2018) Create elegant data visualisations using the grammar of graphics CRAN. https://ggplot2.tidyverse.org/, https://github.com/tidyverse/ggplot2. Accessed 2 Dec 2018

Wong MD, Spring S, Henkelman RM (2013) Structural stabilization of tissue for embryo phenotyping using micro-CT with iodine staining. PLoS ONE 8:e84321PubMedPubMedCentral

Wright BL, Lai JT, Sinclair AJ (2012) Cerebrospinal fluid and lumbar puncture: a practical review. J Neurol 259:1530–1545PubMed

Yamamoto M (1982) Comparative morphology of the peripheral olfactory organ in teleosts. In: Hara TJ (ed) Chemoreception in fishes. Elsevier, Amsterdam, pp 39–59

Yopak KE (2012) Neuroecology of cartilaginous fishes: the functional implications of brain scaling. J Fish Biol 80:1968–2023PubMed

Yopak KE, Carrier JC, Summers AP (2018) Imaging Technologies in the Field and Laboratory. In: Carrier JC, Heithaus MR (eds) CA Simpfendorfer Shark Research Emerging Technologies and Applications for the Field and Laboratory. CRC Press, Boca Raton

Yopak KE, Frank LR (2009) Brain size and brain organization of the whale shark, Rhincodon typus, using magnetic resonance imaging. Brain Behav Evol 74:121–142PubMed

Yopak KE, Lisney TJ (2012) Allometric scaling of the optic tectum in cartilaginous fishes. Brain Behav Evol 80:108–126PubMed

Yopak KE, Lisney TJ, Collin SP (2015) Not all sharks are “swimming noses”: variation in olfactory bulb size in cartilaginous fishes. Brain Struct Func. 220(1127):1143

Yopak KE, Lisney TJ, Collin SP, Montgomery JC (2007) Variation in brain organization and cerebellar foliation in chondrichthyans: sharks and holocephalans. Brain Behav Evol. 69(280):300

Yopak KE, Lisney TJ, Darlington RB, Collin SP, Montgomery JC, Finlay BL (2010) A conserved pattern of brain scaling from sharks to primates. Proc Natl Acad Sci 107:12946–12951PubMedPubMedCentral

Yopak KE, McMeans BC, Mull CG, Feindel KW, Kovacs KM, Lydersen C, Fisk AT, Collin SP (2019) Comparative brain morphology of the greenland and pacific sleeper sharks and its functional implications. Sci Rep 9:10022PubMedPubMedCentral

Zeiske E, Theisen B, Breucker H (1992) Structure, development, and evolutionary aspects of the peripheral olfactory system. Fish Chemoreception. 6:13–39

Zelenitsky DK, Therrien F, Ridgely RC, McGee AR, Witmer LM (2011) Evolution of olfaction in non-avian theropod dinosaurs and birds. Royal Biol Sci 278:3625–3634

Zupanc GK (2001) Adult neurogenesis and neuronal regeneration in the central nervous system of teleost fish. Brain Behav Evol 58:250–275PubMed

Title: Volumetric analysis and morphological assessment of the ascending olfactory pathway in an elasmobranch and a teleost using diceCT
Authors: Victoria Camilieri-Asch
Jeremy A. Shaw
Kara E. Yopak
Lucille Chapuis
Julian C. Partridge
Shaun P. Collin
Publication date: 01-11-2020
Publisher: Springer Berlin Heidelberg
Published in: Brain Structure and Function / Issue 8/2020
Print ISSN: 1863-2653
Electronic ISSN: 1863-2661
DOI: https://doi.org/10.1007/s00429-020-02127-1

At a glance: The STEP trials

Springer Medicine

Volumetric analysis and morphological assessment of the ascending olfactory pathway in an elasmobranch and a teleost using diceCT

Abstract

At a glance: The STEP trials

Springer Medicine

Abstract

Please log in to get access to this content

Other articles of this Issue 8/2020

Abnormal dynamic resting-state brain network organization in auditory verbal hallucination

Non-classical behavior of the default mode network regions during an information processing task

Dissociable fronto-striatal functional networks predict choice impulsivity

Does size matter? The relationship between predictive power of single-subject morphometric networks to spatial scale and edge weight

Brain connections derived from diffusion MRI tractography can be highly anatomically accurate—if we know where white matter pathways start, where they end, and where they do not go

The role of the l-IPS in the comprehension of reversible and irreversible sentences: an rTMS study