TURBINATES IN THERAPSIDS: EVIDENCE FOR LATE PERMIAN ORIGINS OF MAMMALIAN ENDOTHERMY

The structure and function of the nasal conchae of extant reptiles, birds, and mammals are reviewed, and the relationships to endothermy of the mammalian elements are examined. Reptilian conchae are relatively simple, recurved structures, which bear primarily sensory (olfactory) epithelium. Conversely, the conchae, or turbinates, of birds and mammals are considerably more extensive and complex, and bear, in addition, nonsensory (respiratory) epithelium. Of the mammalian turbinates, only the exclusively respiratory maxilloturbinal has a clear functional relationship with endothermy, as it reduces desiccation associated with rapid and continuous pulmonary ventilation. The other mammalian turbinates principally retain the primitive, olfactory function of the nasal conchae. The maxilloturbinates are the first reliable morphological indicator of endothermy that can be used in the fossil record. In fossil mammals and mammallike reptiles, the presence and function of turbinates are most readily revealed by the ridges by which they attach to the walls of the nasal cavity. Ridges for olfactory turbinals are located posterodorsally, away from the main flow of respiratory air, whereas those of the respiratory maxilloturbinals are situated in the anterolateral portion of the nasal passage, directly in the path of respired air. The maxilloturbinal is also characterized by its proximity to the opening of the nasolacrimal canal. Posterodorsal ridges, for olfactory turbinals, have long been recognized in many mammallike reptiles, including early forms such as pelycosaurs. However, ridges for respiratory turbinals have not been identified previously in this group. In this paper, the presence of anterolateral ridges, which most likely supported respiratory turbinals, is reported in the primitive therocephalian Glanosuchus and in several cynodonts. The presence of respiratory turbinals in these advanced mammallike reptiles suggests that the evolution of “mammalian” oxygen consumption rates may have begun as early as the Late Permian and developed in parallel in therocephalians and cynodonts. Full mammalian endothermy may have taken as much as 40 to 50 million yr to develop.     

A Quantitative Study of Olfactory, Non-Olfactory, and Vomeronasal Epithelia in the Nasal Fossa of the Bat Megaderma lyra

In complexity, the mammalian nasal fossa is unparalleled among vertebrates. Although total nasal epithelial surface areas (SA) have been reported for numerous mammals, detailed quantitative reports on individual structures exist for few mammals. Here, we examine mucosal distribution in the nasal fossa of the greater false vampire bat, Megaderma lyra (Megadermatidae, Chiropera). The SA of the left nasal fossa of one adult Megaderma was measured in serial histological sections; the development of the nasal fossa was assessed using three fetal specimens. The nasal fossa of Megaderma has seven ethmoturbinals and multiple smaller interturbinals between them, all bearing olfactory mucosa. Nearly half of the total olfactory SA of the nasal fossa lines these turbinals; the remainder lines recesses and parts of the medial (septal) and lateral walls of the nasal fossa. The maxilloturbinal is diminutive, and the nasoturbinal is absent. Volumetric measurements of the fetal and adult vomeronasal organ suggest age-related reduction. Thirty-five percent of the nasal fossa is lined with olfactory mucosa, within the range reported previously for chiropterans. In Megaderma the frontal recess contributes little to total nasal SA (2% of all olfactory SA). This represents a significant departure in morphology compared to other mammals, including some bats, in which the frontal recess is much larger. The significance of the emphasis in olfactory SA distribution to central or more peripheral (paranasal) spaces could be investigated using a large sample of phylogenetically diverse mammals, such as bats. This study emphasizes the need for more histological detail to further such studies.     

Olfactory metamorphosis in the coastal tailed frog Ascaphus truei (Amphibia,Anura, Leiopelmatidae)

The structure of the olfactory organ in larvae and adults of the basal anuran Ascaphus truei was examined using light micrography, electron micrography, and resin casts of the nasal cavity. The larval olfactory organ consists of nonsensory anterior and posterior nasal tubes connected to a large, main olfactory cavity containing olfactory epithelium; the vomeronasal organ is a ventrolateral diverticulum of this cavity. A small patch of olfactory epithelium (the “epithelial band”) also is present in the preoral buccal cavity, anterolateral to the choana. The main olfactory epithelium and epithelial band have both microvillar and ciliated receptor cells, and both microvillar and ciliated supporting cells. The epithelial band also contains secretory ciliated supporting cells. The vomeronasal epithelium contains only microvillar receptor cells. After metamorphosis, the adult olfactory organ is divided into the three typical anuran olfactory chambers: the principal, middle, and inferior cavities. The anterior part of the principal cavity contains a “larval type” epithelium that has both microvillar and ciliated receptor cells and both microvillar and ciliated supporting cells, whereas the posterior part is lined with an “adult‐type” epithelium that has only ciliated receptor cells and microvillar supporting cells. The middle cavity is nonsensory. The vomeronasal epithelium of the inferior cavity resembles that of larvae but is distinguished by a novel type of microvillar cell. The presence of two distinct types of olfactory epithelium in the principal cavity of adult A. truei is unique among previously described anuran olfactory organs. A comparative review suggests that the anterior olfactory epithelium is homologous with the “recessus olfactorius” of other anurans and with the accessory nasal cavity of pipids and functions to detect water‐borne odorants. J. Morphol. 2011. © 2011 Wiley Periodicals, Inc.     

An investigation of the population ecology of syntopic shrews inhabiting water-cress beds

The population ecology of the shrews Neomys fodiens, Sorex araneus and S. minutus living syntopically in an area of commercial water-cress beds was investigated by live-trapping over a two-year period. The shrew population comprised 52% 5. araneus , 31% N. fodiens and 17% S. minutus. Sorex araneus was the most numerous species in all seasons. Peak numbers of shrews occurred in summer with low numbers in the ensuing winter. Input of new individuals was high, especially of N. fodiens which exceeded 60% in most months. Survival in the study area never exceeded 8 months in N. fodiens and 11 months in S. araneus. Both species suffered approximately 50% mortality and emigration in the first two months of life. Apart from a few, more nomadic, shrews, N. fodiens and S. araneus seemed quite sedentary during trapping periods, moving a mean distance of 13.7 m and 17.2 m between successive captures, respectively. The relatively low numbers of recaptures of N. fodiens at successive trapping periods indicated nomadic behaviour. Both species were more active during darkness than during daylight, and were more active in spring and summer than in winter. High turnover of the shrew population was attributed to mortality and emigration. Emigration was possibly encouraged by competition for space, particularly for nesting sites.     

Cerebrosides and sulfocerebrosides in the brain of insectivorous mammals

Brain cerebrosides (C) and sulfocerebrosides (S) of Insectivora, which represent the most ancient and primitive order of placentary mammals, were first studied. The content of C and S is higher in hedgehogs (Erinaceus europaeus, E. auritus) and mole (Talpa europaea) brains as compared to shrew (Sorex araneus) brain. Hydroxy fatty acids predominate over normal fatty acids in C of all studied insectivora brains. The fatty acid content of C and S of the Insectivora brains is similar in being rich in palmitic, stearic and behenic normal acids and hydroxybehenic and hydroxylignocerinic acids. Hydroxy fatty acids of C and S are more saturated and they have a longer chain (sum C24-26 acids) than the normal acids. C and S of insectivora and primate brains are compared. The data may be of importance for the understanding of the biochemical evolution of the nervous system of mammals.     

The helminth fauna of the shrew genus Sorex (Insectivora: Soricidae) in the Kandalksha nature reserve

The helminth fauna of shrews (Sores araneus, S. caecutiens, S. minutus, S. minutissimus) from the Karelian coast and islands of the Kandalaksha nature reserve was studied. 18 helminth species belonging to 3 taxonomic groups, Trematoda (3), Cestoda (8), and Nematoda (7) were found. The main body of the helminth fauna of shrews is represented by the nematodes species Longistriata codrus, L. didas, and the cestode species Ditestolepis diaphana. Inhabiting of shrews in the insular localities leads to the decrease of the species diversity and the abundance of their helminths. The distribution ranges of the shrew parasites have been outlined more accurately.     

Water and fat contents of British shrews and their role in the seasonal changes in body weight

Water and fat contents of wild and captive Sorex araneus, S. minutus and Neomys fodiens were determined. The influence of sex, locality, body weight and age on water and fat contents of wild shrews are discussed. A seasonal cycle in both water and fat content of wild shrews is demonstrated. An investigation of captive shrews revealed fat contents to be considerably greater than in wild shrews. It is concluded that the seasonal differences in water and fat contents found in this study are of insufficient magnitude to account for the loss in body weight of wild shrews in winter or to be of any great survival value to them.     

Fiber capillarization relative to mitochondrial volume in diaphragm of shrew.

The objective was to examine fiber capillarization in relation to fiber mitochondrial volume in the highly aerobic diaphragm of the shrew, the smallest mammal. The diaphragms of four common shrews [Sorex araneus; body mass, 8.2 +/- 1.3 (SE) g] and four lesser shrews (Sorex minutus, 2.6 +/- 0.1 g) were perfusion fixed in situ, processed for electron microscopy, and analyzed by morphometry. Capillary length per fiber volume was extremely high, at values of 8,008 +/- 1,054 and 12,332 +/- 625 mm(-2) in S. araneus and S. minutus, respectively (P = 0.012), with no difference in capillary geometry between the two species. Fiber mitochondrial volume density was 28.5 +/- 2.3% (S. araneus) and 36.5 +/- 1.4% (S. minutus; P = 0.025), yielding capillary length per milliliter mitochondria values (S. araneus, 27.8 +/- 1.5 km; S. minutus, 33.9 +/- 2.2 km; P = 0.06) as high as in the flight muscle of the hummingbird and small bats. The size of the capillary-fiber interface (i.e., capillary surface per fiber surface ratio) per fiber mitochondrial volume in shrew diaphragm was also as high as in bird and bat flight muscles, and it was about two times greater than in rat hindlimb muscle. Thus, whereas fiber capillary and mitochondrial volume densities decreased with increased body mass in S. araneus compared with S. minutus Soricinae shrews, fiber capillarization per milliliter mitochondria in both species was much higher than previously reported for shrew diaphragm, and it matched that of the intensely aerobic flight muscles of birds and mammals.     

Cases of coat colour anomalies in the common shrew, Sorex araneus L

Coat colour anomalies in the common shrew, Sorex araneus L., in the geographical range of this species, including Poland, are extremely rare. This study describes atypically coloured common shrews. Light colouration of the coat is a result of lack ofpigment in the entire hair or hair fragments. It appears that atypically coloured shrews occur more often in isolated populations whose gene transfer with neighboring populations is limited.     

Histological description of seminiferous epithelium and cycle length of spermatogenesis in the water shrew Neomys fodiens (Mammalia: Soricidae)

Recently, we examined the spermatogenesis cycle length in two shrews species, Sorex araneus characterized by a very high metabolic rate and a polyandric mating system (sperm competition) resulting in a short cycle and Crocidura russula characterized by a much lower metabolic rate and a monogamous mating system showing a longer cycle. In this study, we investigated the spermatogenesis cycle in Neomys fodiens showing an intermediate metabolic rate. We described the stages of seminiferous epithelium according to the spermatid morphology method and we calculated the cycle length of spermatogenesis using incorporation of 5-bromodeoxyuridine into DNA of the germ cells. Twelve males were injected intraperitoneally with 5-bromodeoxyuridine, and the testes were collected. For cycle length determination, we applied a recently developed statistical method. The calculated cycle length is 8.69 days and the total duration of spermatogenesis based on 4.5 cycles is approximately 39.1 days, intermediate between the duration of spermatogenesis of S. araneus (37.6 days) and C. russula (54.5 days) and therefore congruent with both the metabolic rate hypothesis and the sperm competition hypothesis. Relative testes size of 1.4% of body mass indicates a promiscuous mating system.     

Habitat occurrence and prey distribution of a multi-species community of shrews in the Siberian taiga

The habitat occurrence and invertebrate prey distribution of nine species of shrew in the mid-taiga of central Siberia were investigated. Species richness ranged from 4–9 shrews per habitat. Sorex araneus and S. caecutiens were numerically dominant in all seven habitats (44 and 36% of the total catch, respectively) while Sorex minutus, S. tundrensis, S. isodon , and S. roboratus each constituted 4–6% and Sorex minutissimus, S. daphaenodon , and Neomys fodiens were rare (< 1% each). There was no overall correlation between abundance of shrews and invertebrate prey, but flood-plain habitats supported the greatest abundance and species richness of shrews, and high density and biomass of prey. Oligochaete-eating shrews were twice as numerous here as in other habitats, coincident with high abundance of oligochaetes. The large, earthworm-feeding Sorex roboratus occurred only here. The more acid, typical taiga habitats had lower adundance and species richness of shrews. They had the lowest density and biomass of prey, particularly oligochaetes, and far fewer oligochaete-eating shrews. The relative paucity of shrews in bush-meadow habitats, despite abundant prey, implied that habitat structure influences shrew distribution. Differential numbers of certain species in the presence or absence of larger congeners also suggested that interspecific competitive effects influence habitat selection by shrews. The high species richness of shrews here in the mid-taiga may be accounted for by the heterogeneous nature of the constituent habitats which provide niches for small and large species of shrew with a range of feeding habits.     

扬子鳄鼻腔上皮光学显微镜及扫描电镜观察

本文通过光镜和扫描电镜研究了爬行动物扬子鳄鼻腔上皮的组织学。结果表明:其嗅觉上皮的组成细胞类型与两栖类、鸟类和哺乳类基本相似,但嗅细胞纤毛形状则有所不同;扬子鳄与两栖类、鸟类嗅纤毛相似,呈丝状,而哺乳类嗅觉纤毛则呈棍棒状;据外,扬子鳄鼻腔不同部位可发现不同类型嗅纤毛,鸟兽则无此现象,扬子鳄嗅觉上皮的分布仅局限于鼻腔中部前甲区和鼻甲区狭小范围,而兽类嗅觉上皮一般分布较广;扬子鳄呼吸上皮下未见兽类具有的混合型粘液腺,也未见兽类用以温暖空气的静脉丛,这和扬子鳄属外温动物而兽类为恒温动物密切相关。     

The occurrence of Centrorhynchus (Acanthocephala) in shrews (Sorex araneus and Sorex minutus) in the United Kingdom

Encysted acanthocephalans belonging to the genus Centrorhynchus were found in the body cavities of Sorex araneus (common shrew) and Sorex minutus (pygmy shrew) from Boxworth, Cambridgeshire, U.K. Fifty percent of the male S. araneus and 67% of the male S. minutus examined were found to be infected, with the mean intensity (+/-SD) being 54.3 +/- 91.3 and 14.7 +/- 18.4, respectively. The species of Centrorhynchus in the shrews may be Centrorhynchus aluconis, which is distributed widely in tawny owls, Strix aluco, in the United Kingdom. Shrews appear to serve as paratenic hosts for C. aluconis.     

Population dynamics of shrews on small islands accord with the equilibrium model

Three of the six species of shrew in Finland, Sorex araneus, S. caecutiens, and S. minutus , are common on the mainland and widespread on islands in lakes. The islands range from 0.01 to 500 ha in area, and from 10 to 3000 m in isolation (distance from the mainland). The species-area relationship, the lack of importance of habitat diversity, the increasing frequency of unoccupied small islands with isolation, and direct observations of small populations, all suggest that populations on small islands have a high extinction rate. Demographic stochasticity is the main cause of extinctions in the superior competitor, S. araneus , which occurs consistently on islands greater than 2 ha. The small species, S. caecutiens and S. minutus , are more sensitive to environmental stochasticity than is S. araneus , and are inferior to it in interspecific competition; these factors probably contribute to the absence of the small species from many islands tens of hectares in area. Frequent colonization of islands less than 500 m from the mainland is indicated by large numbers of shrews trapped from tiny islets where breeding is not possible, by increasing epigenetic divergence of island populations with isolation, and by observations of dispersal to and colonization of islands. Dispersal ability decreases with decreasing individual size, which may partly explain the absence of the small shrews from many relatively large islands. The shrew populations persist in a dynamic equilibrium on the islands. Epigenetic morphological variation is a useful tool in ecological studies of island populations.     

A novel population of neuronal cells expressing the olfactory marker protein (OMP) in the anterior/dorsal region of the nasal cavity

The olfactory marker protein (OMP) is expressed in mature chemosensory neurons in the nasal neuroepithelium. Here, we report the identification of a novel population of OMP-expressing neurons located bilaterally in the anterior/dorsal region of each nasal cavity at the septum. These cells are clearly separated from the regio olfactoria, harboring the olfactory sensory neurons. During mouse development, the arrangement of the anterior OMP-cells undergoes considerable change. They appear at about stage E13 and are localized in the nasal epithelium during early stages; by epithelial budding, ganglion-shaped clusters are formed in the mesenchyme during the perinatal phase, and a filiform layer directly underneath the nasal epithelium is established in adults. The anterior OMP-cells extend long axonal processes which form bundles and project towards the brain. The data suggest that the newly discovered group of OMP-cells in the anterior region of the nasal cavity may serve a distinct sensory function.     

The skull of Morganucodon

Morganucodon is a triconodont (atherian) mammal from the Lower Jurassic. Two species are described: M. oehleri from China and M. watsoni from Wales. The skull in M. walsoni is 26 mm long; M. oehleri is slightly larger. The dentition is differentiated functionally into incisors, canines, premolars and molars. The pineal foramen is closed. The prefrontals, postfrontals and postorbitals are lost. Septomaxilla, quadratojugal, tabular and pterygoid flanges are retained. The bony external nares are unpaired. The nasal cavity had the mammalian complement of turbinals. The posterior palate has ridges and troughs similar to those in tritylodonts, triconodonts and multituberculates. The alisphenoid ascending process is narrow and is not in contact with the anterior lamina of the petrosal, lying lateral to it. There is a cavum epiptericum, as in late therapsids. The anterior lamina forms the lateral braincase wall, perforated by the foramina pseudovale and pseudorotundum. There is a squamosal-dentary articulation, but the reptilian jaw joint is retained. The ear resembles that in later therapsids, with the tympanum in the lower jaw. The small quadrate was moveable, buttressed medially be a large stapes. Sound conduction from the tympanum was via articular, quadrate and stapes. The systematic position of Morganucodon is discussed.     

The occurrence of the Pigmy shrew Sorex minutus on moorland, and the implications for its presence in Ireland

Throughout most of its range in western Europe, the Pigmy shrew Sorex minutus is sympatricwith the Common shrew Sorex araneus but greatly outnumbered by it. This makes it difficult to explain the presence of the Pigmy shrew, in the absence of its congener, in Ireland. A limited pitfall trapping exercise in England has shown that in moorland on deep peat, the Pigmy shrew may in fact outnumber the Common shrew. Reference to the literature on the ecology of the two shrews shows that this result is readily explained by existing knowledge of their diet; earthworms are a major prey for Common shrews and are absent from waterlogged, acidic, peats. Further, evidence on the nature of the possible land bridge from Scotland to Ireland suggests that it was at best low-lying, and probably partly flooded. By analogy with moorland, such a land bridge might have been suitable for Pigmy shrews but not for Common shrews.     

The taming of the shrew milk teeth

SUMMARY A characteristic feature of mammalian dentition is the evolutionary reduction of tooth number and replacement. Because mice do not replace teeth, here we used Sorex araneus , the common shrew, as a model to investigate the loss of tooth replacement. Historically, shrews have been reported to initiate the development of several, milk or deciduous teeth but these soon become rudimentary and only the replacement teeth erupt. Shrews thus offer a living example of a derived mammalian pattern where the deciduous tooth development is being suppressed. Based on histological and gene expression analyses of serial sections, we suggest that S. araneus has discernible tooth replacement only in the premolar 4 (P4) position. Both generations of teeth express Shh in the enamel knot and in the inner enamel epithelium. Nevertheless, the deciduous P4 (dP4) is reduced in size during embryogenesis and is eventually lost without becoming functional. Analysis of growth shows that P4 replaces the dP4 in a "double-wedge" pattern indicative of competitive replacement where the suppression of the deciduous tooth coincides with the initiation of its replacement. Because activator–inhibitor mechanisms have been implicated in adjacent mouse molars and in transgenic mice with continuous tooth budding, we suggest that evolutionary suppression of deciduous teeth may involve early activation of replacement teeth, which in turn begin to suppress their deciduous predecessors.     

Sex chromosome aneuploidy in wild small mammals

We describe four examples of the XO condition in wild mammals. One XO house mouse (Mus musculus domesticus) was caught in nature and subsequently gave birth to three litters in captivity, confirming for wild mice the fertility observed for XO laboratory mice. Two other XO house mice were produced from laboratory crosses of wild-caught mice. An immature XO common shrew (Sorex araneus) was caught in nature; this appears to be the first XO recorded in the order Insectivora. We collected data from researchers studying chromosome variation in house mice and common shrews and found an overall incidence of 0.22% sex chromosome aneuploidy in 4608 mice and 0.05% in 6625 shrews. The discrepancy related to a much higher frequency of XO's in mice than shrews. Single XXY and XYY shrews and an XXX mouse have been recorded in nature.