Cytoarchitecture of the superior olivary complex of three neotropical species of bats (Noctilio leporinus, Phyllostomus hastatus and Carollia perspicillata) with different foraging behavior

Gibbons, I.; Sundaram, Venkatesan; Adogwa, Andrew; Odekunle, A

doi:10.1590/1519-6984.210489

Cited by 3 publications

(7 citation statements)

References 28 publications

(38 reference statements)

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“…The MNTB appeared large in size, extending medially to the raphe and penetrated by most of the fibres of passage in all the bats studied. The auditory nuclei are relatively larger in echolocating animals like the marmoset (Prado Reis and Abrantes Erhart, 1979), dolphins (Thomas et al, 2004;DeLong et al, 2007) and bats (Zook and Casseday, 1982;Gibbons et al, 2013aGibbons et al, , b, 2019Adogwa et al, 2014;Gibbons et al, 2019) than the human and non-human primates (Neuweiler and Covey, 2000) which is similar in the present study. The very well developed MNTB in N. leporinus (1160 ± 124 μm in length) indicated that this bat heavily depends on the echolocation than the two other bats studied.…”

Section: Discussionsupporting

confidence: 84%

“…Since the different bats forage different environment, it is assumed that different foraging strategies reflect on morphology of the MNTB, an important nucleus in sound localization pathway. Though few studies were done on comparative cytoarchitecture of the various auditory nuclei of echolocating bats with different foraging strategies (Gibbons et al, 2013a(Gibbons et al, , b, 2019Adogwa et al, 2014), the MNTB was not studied.…”

Section: Introductionmentioning

confidence: 99%

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Cytoarchitecture of the medial nucleus of trapezoid body of three neotropical species of bats (Noctilio leporinus, Phyllostomus hastatus, and Carollia perspicillata) with different foraging behavior

et al. 2021

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The present study was taken to test the hypothesis that the medial nucleus of the trapezoid body (MNTB) of echolocating neotropical bats with different foraging behavior will exhibit morphological variations in relative size, degree of complexity and spatial distribution. The brains were collected from six male adult bats of each species: Noctilio leporinus (fish-eating), Phyllostomus hastatus (carnivorous/ omnivorous) and Carollia perspicillata (fruit-eating) and were double-embedded and transverse serial sections were cut and stained with cresyl fast violet. The results showed that the MNTB is well developed in all the bats in general and the mean length of the MNTB was 1160 ± 124 µm in N. leporinus, 400 ± 59 µm in P. hastatus and 320 ± 25µm in C. perspicillata. The body and brain weight do not reflect proportionately on the size of the MNTB in the present study. The hearing frequency spectrum did not covary with the size of the MNTB among the bats studied. The MNTB is clearly demarcated from the ventral nucleus of the trapezoid body (VNTB) only in P. hastatus. The MNTB comprised mainly three types of cells in all three bats: dense-staining multipolar cells (12.5 µm and 25.0 µm diameter); light-staining multipolar cells measuring (12.5 µm and 25.0 µm diameter) and light-staining round cells (5.0 µm diameter). The large sized MNTB was observed in N. leporinus, which suggests that it relies heavily on echolocation whereas P. hastatus and C. perspicillata use echolocation as well but also rely on hearing, smell and vision.

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Section: Discussionsupporting

confidence: 84%

Section: Introductionmentioning

confidence: 99%

Cytoarchitecture of the medial nucleus of trapezoid body of three neotropical species of bats (Noctilio leporinus, Phyllostomus hastatus, and Carollia perspicillata) with different foraging behavior

et al. 2021

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“…However, these bats possess a well‐developed MSO that is homolog to the MSO in non‐echolocating mammals with some differences in connectivity pattern and function in acoustic contrasting (Casseday & Pollak, 1988; Grothe et al, 1994; Pollak & Casseday, 1988). Anatomical differences in the SOC among echolocating bat species are thought to be linked to differences in feeding strategy and echolocation strategies (Gibbons et al, 2019; Zook & Casseday, 1982).…”

Section: Discussionmentioning

confidence: 99%

“…The size of the LSO was proposed to be correlated to the hearing range exploited by an animal (Moore, 2000; Schwartz, 1992). Generally, LSO and MNTB are well developed in mammals with good high frequency hearing and are especially prominent in echolocating bats and odontocetes (Gibbons et al, 2019; Grothe et al, 2010). The volume of the LSO in D. delphis (average 150 mm 3 ) is the largest for any mammal measured so far and could reflect the dolphins' adaptation to high frequencies.…”

Section: Discussionmentioning

confidence: 99%

“…These nuclei are surrounded by the medial nucleus of the trapezoid body (MNTB), and several periolivary cell groups (Heffner & Masterton, 1990; Moore & Moore, 1971; Schwartz, 1992; Stotler, 1953; Strominger & Hurwitz, 1976). LSO and MSO are present in most mammals, however they vary in morphology and most prominently in size, depending on the hearing ability of the species (Gibbons et al, 2019; Irving & Harrison, 1967; Schwartz, 1992). Mammals with good high‐frequency hearing (e.g., mice, rats, and echolocating bats) usually possess a well‐developed LSO and MNTB (Glendenning & Masterton, 1983; Harrison & Irving, 1966; Hofmann, 1908; Irving & Harrison, 1967; Moore & Moore, 1971).…”

Section: Introductionmentioning

confidence: 99%

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Morphology and unbiased stereology of the lateral superior olive in the short‐beaked common dolphin, Delphinus delphis (Cetacea, Delphinidae)

Nieder

Rosene

Mortazavi

et al. 2022

Journal of Morphology

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In all mammals, the superior olivary complex (SOC) comprises a group of auditory brainstem nuclei that are important for sound localization. Its principal nuclei, the lateral superior olive (LSO) and the medial superior olive (MSO) process interaural time and intensity differences, which are the main cues for sound localization in the horizontal plane. Toothed whales (odontocetes) rely heavily on hearing and echolocation for foraging, orientation, and communication and localize sound with great acuity. The investigation of the SOC in odontocetes provides insight into adaptations to underwater hearing and echolocation. However, quantitative anatomical data for odontocetes are currently lacking. We quantified the volume, total neuron number, and neuron density of the LSO of six common dolphins (Delphinus delphis) using the Cavalieri principle and the unbiased stereology optical fractionator. Our results show that the LSO in D. delphis has a volume of 150 + (SD = 27) mm3, which is on average 69 (SEM = 19) times larger than the LSO in human, or 37 (SEM = 11) times larger than the human LSO and MSO combined. The LSO of D. delphis contains 20,876 ± (SD = 3300) neurons. In comparison, data reported for the human brainstem indicate the LSO has only about ¼ that number but about the same number for the LSO and MSO combined (21,100). LSO neurons range from 21 to 25 μm (minor axis) and from 44 to 61 μm (major axis) in transverse sections. The LSO neuron packing density is 1080 ± (SD = 204) neurons/mm3, roughly half of the LSO neuron density in human. SMI‐32‐immunohistochemistry was used to visualize projection neurons in the LSO and revealed the presence of principal, marginal, and multipolar neurons in transverse sections. The distinct morphology of the LSO likely reflects the common dolphin's superb sensitivity to ultra‐high frequencies and ability to detect and analyze sounds and their location as part of its underwater spatial localization and echolocation tasks.

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Structural arrangement of auditory brainstem nuclei in the bats Phyllostomus discolor and Carollia perspicillata

Pätz

Console-Meyer

Felmy

2022

J of Comparative Neurology

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The structure of the mammalian auditory brainstem is evolutionarily highly plastic, and distinct nuclei arrange in a species-dependent manner. Such anatomical variability is present in the superior olivary complex (SOC) and the nuclei of the lateral lemniscus (LL). Due to the structure-function relationship in the auditory brainstem, the identification of individual nuclei supports the understanding of sound processing. Here, we comparatively describe the nucleus arrangement and the expression of functional markers in the auditory brainstem of the two bat species Phyllostomus discolor and Carollia perspicillata. Using immunofluorescent labeling, we describe the arrangement and identity of the SOC and LL nuclei based on the expression of synaptic markers (vesicular glutamate transporter 1 and glycine transporter 2), calcium-binding proteins, as well as the voltage-gated ion channel subunits Kv1.1 and HCN1. The distribution of excitatory and inhibitory synaptic labeling appears similar between both species and matches with that of other mammals. The detection of calcium-binding proteins indicates species-dependent differences and deviations from other mammals. Kv1.1 and HCN1 show largely the same expression pattern in both species, which diverges from other mammals, indicating functional adaptations in the cellular physiology of bat neurons.

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Cytoarchitecture of the superior olivary complex of three neotropical species of bats (Noctilio leporinus, Phyllostomus hastatus and Carollia perspicillata) with different foraging behavior

Cited by 3 publications

References 28 publications

Cytoarchitecture of the medial nucleus of trapezoid body of three neotropical species of bats (Noctilio leporinus, Phyllostomus hastatus, and Carollia perspicillata) with different foraging behavior

Cytoarchitecture of the medial nucleus of trapezoid body of three neotropical species of bats (Noctilio leporinus, Phyllostomus hastatus, and Carollia perspicillata) with different foraging behavior

Morphology and unbiased stereology of the lateral superior olive in the short‐beaked common dolphin, Delphinus delphis (Cetacea, Delphinidae)

Structural arrangement of auditory brainstem nuclei in the bats Phyllostomus discolor and Carollia perspicillata

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