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369 tocEndocranial morphology of the extinct Antillean shrew Nesophontes (Lipotyphla: Nesophontidae) from natural and digital endocasts of Cuban taxa

Johanset Orihuela

Article number: 17.2.22A
https://doi.org/10.26879/369
Copyright Society for Vertebrate Paleontology, May 2014

Author biography
Plain-language and multi-lingual abstracts
PDF version

Submission: 6 January 2013. Acceptance: 25 March 2014

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ABSTRACT

This paper describes the endocranial morphology of the extinct genus of Antillean shrews Nesophontes, based on natural and digital endocranial casts extracted from Cuban species. The endocranial casts show developed olfactory lobes without accessory bulbs, an exposed tectum with visible superior colliculi, a large cerebellum and vermis, and a smooth neocortex. Body mass was estimated from skull size to be between 97 and 114 g, yielding encephalization quotients between 0.33 and 0.57. Endocranial casts of Nesophontes are morphologically similar to those of Solenodon more so than to other lipotyphlans such as Sorex, Blarina, Erinaceus, or the afroinsectivoran Tenrec. The morphological similarity to Solenodon, not only in endocranial structures but also in the rest of the skeleton suggests a behavioral analogy between the two genera. The marked superior colliculi, prominent olfactory lobes, and facial musculoskeletal anatomy suggest that Nesophontes was most likely nocturnal and fossorial, relying on hearing, smell, and tactility to forage. Future analysis of the appendicular skeleton can help determine if this genus was solely terrestrial or if it also exploited arboreal habitats. All these morphologies can help elucidate Nesophontes’s behavior, ecology, and the osteological variation that is observed in the genus.

Johanset Orihuela. Department of Earth and Environment (Geosciences), Florida International University, Miami, Florida 33199, USA, Paleonycteris@gmail.com

INTRODUCTION

Nesophontidae (Anthony, 1916) and Solenodontidae (Gill, 1872) are so far the only two families of insectivorans known from the Antilles, of which only solenodons remain extant. Nesophontes has been extinct since the late Holocene, but has left a rich fossil record in the Greater Antilles (Morgan and Wood, 1986; MacPhee et al., 1999; Whidden and Asher, 2001; Hutterer, 2005; Silva-Taboada et al., 2007). Most recent phylogenetic data suggests that Nesophontidae and Solenodontidae are sister taxa to a clade of Holartic insectivorans that predate the K/T event which include moles, hedgehogs, and shrews (Roca et al., 2004; Asher et al., 2005; Douady and Douzery, 2009). MacPhee and Grimaldi (1996) reported Nesophontes-size lipotyphlan remains from late Oligocene/early Miocene amber from the Dominican Republic, in the Greater Antilles, but its classification remains uncertain. These ancient mammals are important to the understanding of Antillean land mammal biogeography and to discussions about insectivoran evolution (MacFadden, 1980; Asher et al., 2003, 2005; MacPhee, 2005).

Endocranial casts are relevant in the study of mammalian brains, and the evolution of endocranial morphology (Radinsky, 1968; Kielan-Jaworowska, 1984; Macrini et al., 2007a and b; Rowe et al., 2011; Silcox et al., 2011; Orliac et al., 2012). Endocranial casts do not represent actual brains. Instead, endocasts are impressions of external brain structures such as vessels and meninges (Bauchot and Stephan, 1967; Kielan-Jaworowska and Lancaster, 2004). Nevertheless, endocranial casts provide a unique opportunity for paleobiologists and paleoneurologists to study casts of soft tissue structures that are rarely preserved during fossilization. Particularly, endocasts allow investigators to infer the function, evolution, and behavior of extinct animals (Edinger, 1949; Clark, 1959; Eisenberg, 1981; Stephan et al., 1991; Jerison, 2009). Natural and digital endocasts have provided fundamental evidence of the neuroanatomy and behavior of primitive lineages such as multituberculates and insectivore-grade mammals, among other taxa, as a key to understanding mammalian evolution (Kielan-Jaworowska, 1984, 2004; Thewissen and Gingerich, 1989; Macrini et al., 2007a; Rowe, 1996; Rowe et al., 2011).

This paper reports the endocranial morphology of Nesophontes through the analysis of natural and digital endocranial casts. Although Nesophontes is known from well-preserved cranial specimens, their endocranial casts remained unreported and their morphology unstudied. The cranial osteology of Nesophontes has often been described in combination with that of Solenodon, with the most extensive treatments being those of Anthony (1916, 1918), McDowell (1958), MacPhee (1981, 2005), and Wible (2008). Other researchers have analyzed different features of nesophontid cranial morphology through the study of fossil crania, but not from endocranial casts (e.g., Gould and Garwood, 1969; Silva-Taboada et al., 2007). Through the analysis of Nesophontes endocranial casts this research describes and illustrates their endocranial morphology for the first time. Additionally, this manuscript explains the sensorial and behavioral characteristics from Nesophontes’s neuromorphology, and compares it to that of Solenodon and other extant and extinct mammals. Such data provides basic information to evolutionary neurologists interested in mammalian or insectivoran neuroanatomy. Evolutionary signals and developmental drives (i.e., stages of brain evolution) lie outside the scope of this research. Nevertheless, the data presented here further enhance our knowledge and understanding of nesophontid systematics, paleoecology, and behavior.

MATERIALS AND METHODS

Locality

The specimens used in this study were extracted from a late Quaternary owl pellet deposit in Nesophontes Cave, Palenque Hill in northwestern Cuba. Specimens were excavated from a 50 cm x 50 cm x 50 cm test pit under the main doline (sinkhole). The association of the Nesophontes specimens with introduced rats ( Rattus sp.) suggests a late Holocene age for the deposit (MacPhee et al., 1999). The cave’s faunally-rich assemblage will be described elsewhere. All specimens are deposited in the National Museum of Natural History (MNHNCu), Havana, Cuba (uncataloged). The numbers referred to here are field numbers.

Methodology

s figure1This study is based on eight incomplete natural endocranial casts and four digital reconstructions from four nearly complete skulls (Figure 1, Figure 2, Figure 3, Figure 4, Figure 5, Figure 6, and Figure 7). The analyses included the Cuban species Nesophontes major and Nesophontes micrus. All measurements are given in Table 1.

Natural endocasts (Steinkerns) were extracted from two nearly complete adult skulls; one Nesophontes major (C181) and one Nesophontes micrus (C145) (Figure 1.1). The maturity of the specimens was assessed from tooth wear and cranial sutures (McDowell, 1958). The natural endocasts were extracted through partial destructive sampling of the braincase after the specimens were x-rayed (Figure 1.2-3). Skulls with cemented sediment inside the endocranial cavity were specially selected. The posterior portion of the braincase was then carefully removed and the natural endocasts carefully extracted. These endocasts were compared to brain images in scientific literature, plus the Comparative Brain Collection at www.brainmuseum.org and Digital Morphology Library (Digimoph: www.digimorph.org/) of the University of Texas at Austin. Detailed comparisons were made with several multituberculates, basal eutherians, and extinct insectivorans as a source or morphological comparison, and not for phylogenetic purposes. These included the species Eoryctes melanus, Vincelestes neuquenianus, Hyopsodus lepidus, the extant marsupials Monodelphis domestica and Marmosa murina, plus the extant lipotyphlans Solenodon paradoxus, Tenrec ecuadatus, Erinaceus europeaus, and Sorex sp. s figure2Cranial and natural endocranial casts linear measurements were taken with digital calipers. Brain percentage compositions and angle measurements procedures were adopted from Stephan and Andy (1982) and Macrini et al. (2006). Marsupials were included not as an ancient or “primitive” outgroup, but because of their endocranial similarities, and their value in the study of placental neuroanatomy (Ashwell, 2010). Because of known problems with insectivoran nomenclature and phylogeny (Asher and Helgen, 2010) some of the older classification systems (e.g., classification of “progressive insectivorans” using EQ values) have been included in the text to serve as comparisons with older literature and will be referred to as actual genera or species when appropriate.

Digital endocasts were reconstructed from x-ray computed tomography data (CT slices) acquired through the scanning of two nearly complete cranial specimens of Nesophontes micrus (C436, C437) and two of Nesophontes major (C133,C270). The specimens were scanned coronally with a General Electric Lightspeed scanner (VCT, 64 detectors), resulting in 120 images with a matrix size of 512². The techniques used were a 20 milliampere current (mA), 80 peak kilovolts (KvP), a slice thickness of 0.625 mm, plus a 0.312 mm image overlap in a 32 mm field of view. The scan data were then reconstructed with a General Electric ADW (4.3) Workstation using an “air-structure” algorithm.

s figure3Encephalization quotients (EQ) were calculated using Jerison (1973) equation: EQ=EV/0.12 (Wt) ⁰·⁶⁷and Eisenberg’s (1981) equation: EQ=EV/0.055(Wt) ⁰·⁷⁴, where EV = endocranial volume in ml (cm³) and Wt the body mass in grams (g). Calculated EQ values were based on a body mass range between 97 and 114 g (average 105.5), estimated from the formula: y = 3.68x - 3.83, where y = log10 (body mass in grams), and x = log10 (skull length in mm). This formula is based on the relationship between body mass and skull length documented in extant insectivore-grade mammals (Luo et al., 2001; Rowe et al., 2011). Skull lengths for Nesophontes micrus and N. major, plus other linear and volumetric features were measured (Table 1). Endocranial volumes and dimensions were measured directly from CT data with built-in measuring tools of the ADW software (Table 1). McFarlane (1999) provided a mass estimate for Nesophontes between 180 and 200 g. However, this estimate is based on correlations between the significantly larger Nesophontes edithae from Puerto Rico and chipmunk-sized rodents (e.g., Allen, 1942, Walker et al., 1975) and could be an overestimation.

The terminology for brain anatomy follows Butler and Hodos (2005), Rowe et al. (2011) and Orliac et al., (2012), and that for cranial osteological follows McDowell (1958), Wible (2008), and Macrini (2012). The use of Lipotyphla over Eulipotyphla follows the suggestions of Asher and Helgen (2010). A list of character states for Nesophontes is provided in the Appendix.

RESULTS

Forebrain: The Olfactory Lobes and Ethmoid-cribriform Region

s figure4The casts of the olfactory lobes (Ob) are large, well-developed, elongated anteroposteriorly, non-continuous, and oval in shape (Figure 2.1 and Figure 4.2). The olfactory lobe casts are less than one half the anteroposterior length of the neocortex, but constitute 20-25 % of the total endocranial volume. The sagittal or longitudinal sinus (sas) divides both lobe casts medially.

The olfactory lobe casts are divided anteriorly and anterodorsally by the crista galli and posterodorsally by an annular or circular fissure (fan) on the posterior frontal bone (Figure 1.2-3, Figure 2.1, and Figure 4.2). Small sections of the olfactory peduncle casts were observed in well-preserved natural casts (Figure 4.2) and implied in digital endocasts (Figure 5.1, Figure 6.1). Casts of olfactory nerve fibers were not observed in either natural or digital endocast. The olfactory lobes rest on a thick and inclined cribriform plate, rich in nasoturbinal and ethmoturbinal foramina (Figure 1.2-3, Figure 6, and Figure 8). Possible casts of olfactory extensions [onf] are visible superiorly and anteriorly on the olfactory lobes of digital renderings (Figure 5 and Figure 6). The dorsalmost might be a negative cast of the cribroethmoidal foramen (cef), which seems to be largest of the cribriform foramina in s figure5Nesophontes (Figure 8). The annular or circular fissure (fan), which separates the olfactory lobes from the neocortex, is apparently deep as it can be seen in radiographs, and digital and natural endocranial casts. The olfactory lobes are aligned to the rest of the brain, but with an endocranial flexure between 25 and 29 degrees. No evidence of accessory olfactory lobes were observed in Nesophontes casts.

Forebrain: Cerebrum

The cast of the neocortex (Ncx) is lissencephalic or smooth (poor gyrification). Only slight indications of sulci are visible on natural and digital cast specimens. These are superficial, and probable indications of the rhinal fissure (rhn) above the olfactory (= piriform) cortex (Ocx), and superiorly, behind the circular fissure (fan). The latter seems to be the sylvian fissure (Sf) (Figure 1.2, Figure 5, and Figure 6).

The cast of the neocortex is ovoid and divided by a shallow superior sagittal sinus. The casts of the hemispheres are elongated anteroposteriorly, narrower anteriorly, and wider posteriorly, at the level of the olfactory cortex (Ocx). The cerebral hemispheres are well defined.

s figure6A marked orbitotemporal groove (otg) cast is visible on most natural endocasts (Figure 2), but not on digital renderings (Figure 5 and Figure 6). Such a structure is often defined as a sinus canal or meningeal vessel, and is visible on the endocranial face of the squamosal bone (Thewissen and Gingerich, 1989; Silcox et al., 2011). This feature is a probable marker of the rhinal fissure, delimiting between the paleo and neocortex (Rowe, 1996; Silcox et al., 2011). The transverse sinus seems deeper and wider than the sagittal sinus. Traces of the sagittal and transverse sinuses meet just before the tectum (Figure 2 and Figure 4).

Diencephalon

The digital renderings show a hypophyseal fossa (hyf) and sphenoid tracts with optic nerves in the anterior-inferior region that can represent the optic chiasm (Och). The sphenoid tracts seem to be divided anteriorly by the alisphenoid, and are separate from the optic foramina (Figure 5). The olfactory cortex cast and the sphenorbital region are visible, but were not well delimited on natural or digital endocasts (Figure 9 and Figure 10).

s figure7Midbrain: Tectum

The midbrain shows marked superior colliculi casts posterior to the confluence of the transverse sinus (Figure 2.1-2, Figure 4.1 and 4.3). The midbrain seems to have been exposed with very little or no space between cerebrum and cerebellum. The tectum seems to be continuous superiorly and through between the cerebrum and cerebellum, unlike Solenodon or Tenrec, in which the tectum is exposed, but separated from both cerebrum and cerebellum (Figure 9, Figure 10, Figure 11, Figure 12; see Discussion).

Casts of colliculi appear posterior to the confluence of the transverse and sagittal sinuses at the same level. Colliculi are not visible on all natural specimens, and are also not visible on the digital endocasts. The variation in presence or absence of colliculi casts seems to be an artifact of preservation, and indicates the low resolution of both the natural and digital endocasts in which they are not evident. However, they are suggested by the presence of impressions inside the osseous roof of the braincase (Figure 9). However, on the digital renderings, there is indication of only one set of colliculi, which most probably represents superior colliculi. Presumably, inferior colliculi were present in the living animal, as in all extant mammals, but not visible on the endocasts (Macrini pers. comm., 2012). There was no osseous tentorium in any of the specimens studied.

s figure8Hindbrain: Cerebellum

The cast of the cerebellum is large and as wide as the neocortex. The vermis’s cast is thick, wide, and lies slightly higher than the rest of the cerebellum (Figure 2 and Figure 4). Folia or fissures are not visible on either natural or digital casts of the cerebellum. There are two prominent casts of lateral lobes (=cerebellar hemispheres), and paraflocculi. The casts of the paraflocculi are ovoid, much smaller than the cerebellar lobe and project laterally (Figure 2 and Figure 4).

Endocasts extracted from Nesophontes micrus and Nesophontes major crania seem to be slightly different morphologically. The endocranial casts of N. major (C181) show a narrower cerebrum and cerebellum than those of N. micrus (C145). The tectum is wider and more conspicuous in N. micrus than in N. major (Figure 9). The cerebrum and the vermis are wider and rounder in N. micrus (C145). The colliculi impressions on the braincase are deeper and slightly more separated in N. major than in N. micrus . The confluence of the transverse sinus appears to be deeper and wider in N. major . Differences are visible in the x-ray images and inner molds of their braincase (Figure 1.3 and Figure 9).

s figure9Measurements and EQ Values

The volume of all endocasts was estimated between 0.76 and 1.23 ml, which suggest a brain mass of nearly, or slightly heavier than 1 g (≈ 1 g/cm³). Encephalization quotients calculated from Eisenberg’s (1981) equation (EQ³) ranged between 0.33 and 0.57 (n=4; mean=0.46) for both species. The EQ estimates calculated with Jerison’s (1973) formula (EQ²) are slightly smaller with values between 0.21 and 0.36 (n=4; mean=0.29) (Table 1) and Figure 12 (Appendix). Of these, and despite the overlap, Nesophontes major seem to have larger EQ scores, probably due to their larger brain mass and volume.

Discussion

s figure10This study supports that the endocranial morphology of Nesophontes resembles that of placental, insectivore-grade mammals, especially the lipotyphlans. Within this clade, it is most morphologically similar to Solenodon despite their different molar morphology (Figure 12). Unfortunately, because endocranial casts of juvenile specimens were not available, developmental variation was not studied.

The olfactory lobes seem continuous in the digital endocasts, but are markedly separated by the circular fissure in natural endocasts and lateral radiographs (Figure 1.1, 1.3, and Figure  4.2). Casts of olfactory nerve fibers are visible only on digital casts and could be negative renderings of the cribroethmoidal foramen (cef) (Figure 6). Such an intricate system of cribriform foramina is reminiscent of Solenodon as illustrated in Wible (2008, figure 23).

s figure11The neocortex of Nesophontes is ovoid and nearly lissencephalic in both the natural and digital endocasts. There are faint indications of sylvian and rhinal fissures (Figure 2.2, Figure 5, and Figure 6). Gyrencephalic brains of mammals, such as apes, are known to produce lissencephalic endocasts due to the covering of thick meninges (Clark, 1959; Macrini et al., 2007a). Presently, gyrification is correlated with brain mass and size (Pillay and Manger, 2007). The low gyrification seen in endocranial casts of Nesophontes is plausibly an artifact of its small brain size and mass (Martin, 1981; Pillay and Manger, 2007).

The traces of the rhinal fissure in Nesophontes separates the neocortex from the olfactory cortex very low and laterally as in Solenodon, but not as superiorly as in Erinaceus or Tenrec (Figure 12) (Leche, 1907; Allen, 1910; Stephan and Andy, 1982). The orbitotemporal groove seen on natural and digital endocasts (Figure 2, Figure 3, and Figure 5) marks the location of the rhinal fissure and suggests that the olfactory cortex was lower in the neocortex than the extant lipotyphlan Sorex, Blarina, and Scalopus. Overall, it resembles the extent observed in Solenodon and Condylura (Stephan and Andy, 1982).

s figure12Exposed colliculi are reported for most tenrecids and ericnaceids (Clark, 1932; Stephan et al., 1991; Orliac et al., 2012). In the afroinsectivoran Tenrec, and the lipotyphlans Ericaceus, Sorex, and Condylura, the tectum is not superiorly continuous with the cerebellum. Instead, it arises, exposed, from under the neocortex (telencephalon) to join the cerebellum. There is a small gap between the telencephalon and the cerebellum in three mentioned species, where the tectum is nearly totally exposed, and thus visible (Stephan and Andy, 1982; Macrini et al., 2007 b; Figure 9 and Figure 10). Conversely, the tectum in Nesophontes is not as exposed as in Solenodon, Erinaceus, or Tenrec (Figure 10, Figure 11, and Figure 12). Natural endocasts suggest a slight and shallow gap between Nesophontes’s telencephalon and cerebellum (Figure 2 and Figure 4.3), in which the tectum is not completely exposed. In the endocranial casts of Nesophontes only one set of colliculi casts are visible (Figure 10 and Figure 11). These were presumably present, but hidden under the telencephalon or cerebellum, or poorly preserved in the endocranial casts studied. The state of Nesophontes resembles that of Solenodon paradoxus as shown in Allen (1910) and Stephen and Andy (1982) in which the tectum is exposed superiorly, but one set of colliculi are covered by the neocortex.

The endocranial casts of Nesophontes resembles that of the extinct condylarth Hyopsodus and the palaeoryctid Eoryctes in being nearly superiorly continuous, and having partially or totally exposed colliculi (Figure 10 and Figure 11). The gap between the tectum and cerebellum was not wide enough to expose all sets of colliculi in Nesophontes . This state, as observed in Nesophontes endocasts, is intermediate with that present in Tenrec (totally exposed) and Microgale or Sorex (totally hidden) (Figure 11 and Figure 12). In Tenrec, there is a wide gap between the posterior part of the cerebral hemispheres and the cerebellum from which the midbrain appears, exposing the tectum (Figure 12). In Microgale, however, there is no gap between the neocortex and the cerebellum. This feature seems hidden in Sorex, Blarina, and Scalopus (Figure 12).

Tectum exposure of the midbrain is correlated with a slight neocortical extension, and secondary sensory specialization as documented in bats (Edinger, 1964; Orliac et al., 2012). Yet, this exposure usually leaves faint, if any, marks on the braincase (Orliac et al., 2012). However, there are slight collicular imprints inside of the Nesophontes braincase (Figure 9). The slight differences noted between N. micrus and N. major endocranial casts lie especially in the neocortex and tectum. The neocortex of N. micrus is slightly wider, with more visible sylvian and rhinal fissures, plus orbitotemporal groove (otg). The confluence of the transverse sinus is less angled, deeper, and wider in N. micrus . The superior colliculi seem more pronounced in N. micrus (Figure 9). Unfortunately, there is not enough evidence now to support that these differences are of interspecific value considering the high level of intraespecific variation in Nesophontes (Figure 7) (Silva-Taboada et al., 2007 and literature cited therein).

Cerebellar hemispheres or lateral lobes, vermis and paraflocculus are all visible in the endocranial casts of Nesophontes as in other placentals (Macrini et al., 2007 b; Rowe et al., 2011). Widening of the cerebellar hemispheres, and distinction between its parts in Nesophontes ’s casts, resemble Solenodon and tenrecids in general. The casts of the vermis are not round and centrally located such as that of the stem therian Vincelestes, but are elevated and medially located like those of Solenodon, Erinaceus, and Sorex (Figure 12) (Stephan and Andy, 1982; Macrini et al., 2007 b). Unfortunately, casts of the paraflocculi were not all complete, but indications on natural and digital casts suggest that these were round structures, projecting postero-laterally and low in the cerebellum (Figure 2.1, Figure 4.1, and Figure 5.1). Future study on the ear structure of Nesophontes can shed light on the relationship between the paraflocculi and the semicircular canal within the inner ear.

Characters such as enlargement and widening of the cerebellum with marked cerebellar parts are considered derived conditions in ancestral therians (Kielan-Jaworowska et al., 2004; Rowe et al., 2011). The neocortex covering of the midbrain tectum is apparent in many different lineages of extant mammals; such dorsal exposure of the tectum is considered a likely condition of ancestral or early mammals (Kielan-Jaworowska et al., 2004; Macrini et al., 2007 b).

For comparative purposes with older methodology and literature, encephalization quotients (EQ) of insectivoran-grade mammals are compared to that of Nesophontes . These “progressive insectivorans” are said to be progressive because of larger brains, and higher EQ estimates related to specialized behavior seen in fossorial and semiaquatic adaptations (Stephan and Andy, 1982). The EQ estimates for both N. micrus and N. major lie below those for the “evolved insectivorans” of Bauchot and Stephan (1967), and are intermediate to the “progressive insectivores” of Stephan and Andy (1982), and most of the crown mammals in Rowe et al. (2011). The “progressive insectivores” of Stephan and Andy (1982) included the following taxa: Desmana, Talpa, and the semiaquatic Potomogale, whereas Solenodon, Oryzorictes, and Microgale were considered “slightly progressive” or intermediate between groups. Nesophontes EQ values lie within the range of the extant Solenodon paradoxus, Erinaceus spp ., plus the marsupials Monodelphis and Didelphis . Their range is also comparable to the extinct multituberculate Kryptobaatar, Chulsanbaatar, and the also extinct primitive eutherian Asioryctes, but is larger than the stem therian Vincelestes and the primitive eutherian Kennalestes (Kielan-Jaworowska et al., 2004; Rowe et al., 2011).

Especial Comparison with Solenodon

Except for their difference in size and dentition, the brain and facial anatomy of Nesophontes is similar to that of tenrecids, and even more so to Solenodon (Figure 11). This similarity extends to cranial rostral musculature and its osseous morphology (Anthony, 1918; McDowell, 1958; Asher, 2001). These similarities seem to suggest Nesophontes and Solenodon are ecomorphs. The faciomaxillary morphology of Nesophontes is similar to that of Solenodon in having similar muscular arrangements, cranial osteology, and grooved anterior dentition. In Nesophontes, the maxillary canines are grooved. In Solenodon, the second inferior incisor (i2) is grooved for venom delivery (Gundlach, 1877; McDowell, 1958; Silva-Taboada et al., 2007; Ligabue-Braun et al., 2012). The similar characteristics include pronounced faciomaxillary musculature scars for the levator labii, levator labii, and erector vibrissarum on the superior-lateral aspects of the maxilla (Allen, 1910; MacDowell, 1958; Wible, 2008). Other characters, such as the absence of accessory bulbs on olfactory lobes and the presence of prootic canal seem to be unique states in Solenodon and Nesophontes in comparison to other lipotyphlans (Stephan and Andy, 1982; Wible, 2008). Casts of the olfactory lobes in Nesophontes do not show presence of accessory olfactory lobes, as also not reported for Solenodon (Stephan and Andy, 1982: 540). In addition, Nesophontes has a double prootic canal (canalis prooticus), whereas Solenodon has a single canal (Wible, 2008). Prootic canals are not reported from other placental mammals, but have been widely reported in Cenozoic mammaliaforms (Wible, 2008).

Behavioral and Ecologic Inferences

By considering the marked similarities of the nesophontid endocranium with those of Solenodon and the Tenrec it is possible to deduce its sensitivity to auditory and olfactory stimuli. Barton and colleagues (1995) showed that nocturnal species tended to have larger olfactory structures than diurnal species; fossorial species had smaller optic nerves than those of non-fossorial adaptations. They did not find optic nerve size exclusive of either nocturnal or diurnal adaptation. The marked development of the olfactory lobes and superior colliculi in Nesophontes suggests that it lived in habitats where olfaction and acoustic capabilities were crucial (Scalia and Winons, 1975; Catania, 2005). Nesophontes was probably nocturnal, as indicated by its abundance in owl pellet remains (Silva-Taboada et al., 2007) and fossorial as suggested by its minute optic nerve foramen (0.27-0.58 mm, n= 8) (Barton et al., 1995), plus well-developed auditory and tactile systems as in other mammals adapted to nocturnal environments (Jerison, 1973; Scalia and Winons, 1975; Kielan-Jaworowska et al., 2004; Catania, 2005). The presence of superior colliculi suggests that the vision of Nesophontes was probably not as poor as in other lipotyphlans (e.g., Sorex ) (May, 2005). Instead, it implies that Nesophontes depended on inputs from the retina and from head- eye movements such as seen in the gazing, foraging, and defensive behavior of Solenodon and Tenrec described by Eisenberg and Gould (1966) and Stephen and Andy (1982). Nesophontes probably had a long, mobile nasal snout with movable vibrissae or whiskers for foraging and the detection of prey similar to that of Solenodon, Hemicentetes and Tenrec, (True, 1886; Beddard, 1901; Allen, 1910; McDowell, 1958; Eisenberg and Gould, 1966; Wible, 2008). Altogether, most of these characteristics suggest that Nesophontes was most likely nocturnal, terrestrial, and probably a very specialized fossorial insectivoran. Moreover, the scars for the levator labii and erector vibrissarum in the maxilla of Nesophontes, as in Solenodon (Allen, 1910; Jolicoeur et al., 1984; Sánchez-Villagra and Asher, 2002; Catania, 2005), suggest the use of vibrissae and mobile snouts in similar foraging and defensive behavior.

With the available endocasts it is not possible to infer whether Nesophontes used echolocation as reported for many lipotyphlans (Eisenberg and Gould, 1966; Orliac et al., 2012). Pathway connections between superior colliculi and optic layers have been supported by Lee and Hall (1995). The relationship of visual-motor guidance involved in eye/head movement and the development of superior colliculi has been compared to those of fructiverous megabats, monkeys, and in echolocating mammals such as microbats and several shrews (Valentine et al., 2002; Silcox et al., 2011; Orliac et al., 2012). Alternatively, the trace of these structures on the endocasts of Nesophontes indicates poor development of its cerebral hemispheres (Kielan-Jaworowska et al., 2004; May, 2005), but not vision directly.

Study Limitations

The study presented here is limited by several factors, but most especially by preservation. The detail of the natural endocasts in this case depended on taphonomic processes, such as the fragmentation of the fossil crania, and the extent to which the braincase filled with sediment during burial. Complete compaction and hardening of finer clay inside the braincase would have resulted in better casts. Most of the natural endocranial casts studied were incomplete.

The study of the digital endocasts reported here is also limited by their relatively low resolution, a result of equipment selection and the small size and density of Nesophontes crania. Specimens were scanned and reconstructed from data acquired with a multidetector CT (MDCT) designed for humans, and not from micro-computed tomography (micro-CT). Micro-CT would allow for the rendering of higher resolution casts due to their acquisition of thinner slices (Abel et al., 2012). Additional scanning with such better technology is already part of a future study to understand the morphological variation of the genus. The volume rendering of Nesophontes endocasts are based on an “air-structure” algorithm designed to visualize air-filled cavities, which allows only for the reconstruction of negative impressions inside the braincase, and can help approximate the original brain structures (Abel et al., 2012). The absence of a feature on these endocasts cannot be considered as indication of the nonexistence of such a feature. All scanned specimens are included in Figure 7 for further comparison.

Nevertheless, despite the limitations, studies have shown that the digital and natural endocranial casts give a fairly accurate approximation of brain morphology (Edinger, 1949; Macrini et al., 2007b; Abel et al., 2012). The measurements and morphology recorded from Nesophontes ’s digital endocasts are congruent with those observed in the natural endocasts. Together, the two types of endocasts provide an unreported approximation of Nesophontes endocranial characteristics that are comparable to other extinct and extant taxa (Macrini et al., 2007a; Jerison, 2009; Abel et al., 2012) (Figure 7, Figure 11, and Figure 12).

Conclusions

The endocranial morphology of Nesophontes spp. reported here allows for a generalized inference of their ecology, behavior, diversity, and evolution. Additionally, it adds data to the developing corpus of evidence on mammalian brain evolution in extant and extinct forms (see cited literature in Bauchot and Stephan, 1967; Macrini et al., 2007a; Jerison, 2009; Rowe et al., 2011).

Brain characters observed in the natural and digital endocranial casts of Nesophontes suggested that this taxon was probably as specialized as the lipotyphlan Solenodon, with well-developed olfactory, auditory, and tactile senses that are most likely associated to nocturnal habits. Nesophontes was most likely terrestrial and fossorial. Like Solenodon and Tenrec, it had a sensible mobile snout (proboscis) used as tactile and olfactory to sense its environment. However, with the present data, it is not possible to deduce whether Nesophontes used echolocation, like it has been documented for Solenodon and other insectivoran-grade mammals (Eisenberg and Gould, 1966; Orliac et al., 2012).

The endocranial morphology of Nesophontes is most similar to that of other lipotyphlans, especially Solenodon, rather than erinaceids, soricids, and talpids (Figure 12). Encephalization quotients and general brain characteristics superficially support its phylogenetic association to basal insectivoran-grade mammals and lipotyphlans. Foremost, the morphological similarities of Nesophontes to species that are considered “primitive” within the clade such as Solenodon and ericnaceids incipiently support its position among other basal Holartic insectivorans, where Nesophontes seems to be a sister taxon of a Solenodon -talpid-soricid clade (Robles et al., 2004; Asher et al., 2005; Douady and Douzery, 2009).

The future availability of better preserved natural endocasts and the scanning of the remaining Antillean taxa can help confirm these initial conclusions about nesophontid brain morphology and derived characteristics. Furthermore, such data can help detect interspecific differences between all other Antillean Nesophontes and help resolve the slight differences detected between the natural and digital endocasts. Such data can help reconstruct the relationship of Nesophontidae to other mammals, especially to other extinct insectivorans, and their evolution in the Antilles.

ACKNOWLEDGEMENTS

I am greatly indebted to my friend and colleague A. Tejedor for all his guidance with Nesophontes during the past decade. I thank T.E. Macrini from St. Mary’s University (San Antonio, Texas) and R. Asher from the American Museum of Natural History, New York (AMNH) for providing necessary literature and for guidance and superb comments. Thanks are due to R. Viera, C. Santana, and L.P. Orozco for field logistics and support. I also thank fellow CT technologists W. Gilmour, R.V. Rodriguez, and K. Davis for their guidance during the scanning and reconstruction processes. Foremost, I thank T.E. Macrini, L.S. Collins (Florida International University), T. Castaño, J. Álvarez Licourt, and several anonymous referees for reviewing multiple versions of this article and providing useful suggestions.

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