Under pressure: Effects of instrumentation methods on fur seal pelt function

Tracking marine mammals with electronic devices enables researchers to better understand animal movements and at-sea behavior. For pinnipeds, instruments are typically glued to the animal's hair, either directly to the pelage or via a fabric patch. These instruments are retrieved by cutting the pelage or cutting through the patch. The impact of these modifications to the pelage is presumed to be minimal and short-lived, but this has never been explicitly investigated. This study examined effects of instrument attachment on northern fur seal pelts. To assess thermal consequences of instrumentation, we determined thermal resistance of pelts in water for instruments glued directly to the pelage or with a neoprene base. For each attachment method, we measured the pelt unmodified, with instrument attached, and with instrument removed. Using a hyperbaric chamber, we measured the extent to which water could penetrate the pelt's air layer during diving. Removing the tag by cutting the pelage reduced thermal function of the pelt in water and allowed more air to escape under pressure. In contrast, a neoprene patch better maintained the insulation in water and reduced air loss under pressure. Our results suggest the use of neoprene may reduce negative consequences of instrumentation in fur seals.     

A structural investigation of the ovule in sugar beet, Beta vulgaris: Integuments and micropyle

The micropyle and the integuments of sugar beet (Beta vulgaris) ovules have been investigated by light and electron microscopy during differentiation and maturation of the ovule. The micropyle itself is formed by the inner integument which is surrounded by the outer integument at its base. The micropyle containts a fibrillar PAS+ substance and is often covered by a thin sheet or hymen. Both integuments are cuticle-covered thin sheets, each 2-few cell layers in thickness. In the outer integument an increase in starch accumulation occurs during ovule maturation and probably functions as nutrient storage for embryo development. The inner epidermis of the inner integument differentiates as the most conspicuous cell layer of the beet ovule. During growth and maturation of the ovule a system of small perinuclear vacuoles containing dense material increases steadily in these cells. At maturity this system fills up more than half of each cell and very dense material has accumulated in each vacuole. This vacuole content is highly refractive and contains tannins and/or polyphenols.     

哺乳动物毛被传热性能及其影响因素

毛被能够加强或减弱动物向周围环境的热量散失,毛被的形态结构和颜色是传热性能的决定因素,其传热过程往往是传导、对流和辐射3个过程的耦合。以往研究发现环境因子中,风可增加机体向环境中的散热速率,且散失量与风速正相关,且动物通过调节在风场中的姿态来适应不同风向。动物体与环境间的温差是影响散热速率的另一因素,不同环境中的动物通过改变毛被结构来适应温差变化。毛被含水率上升会引起导热和蒸发冷却作用加强,动物通过行为或毛被结构变化来调节毛被含水率。毛色决定毛被吸收和反射热辐射的能力。毛被传热性能直接把动物的生理特点与环境因子关联起来,这对揭示动物的适应、进化都具有重要意义。同时提出,毛被结构和传热性能的研究还有助于仿生学意义的挖掘。因此,今后应重点在毛被结构和物理性能、研究技术与方法以及毛被生物学和仿生学意义等方面开展研究。     

Development of the ovule and seed in Costus cuspidatus (N.E.Br.) Maas (Zingiberaceae), with special reference to the formation of the operculum

The ovule primordium of Costus is trizonate and both its integuments are dermally initiated. With other evidence, this strongly suggests that most, if not all, monocotyledons have dermally initiated integuments, indicating a derived status. The mature seed coat of Costus is completely formed by the outer integument and its principal mechanical layer is the endotesta.
The seed of Costus has an aril, an operculum and a micropylar collar. These structures, characteristic of zingiberalean seeds, are each initiated in a different, specific cell layer of the exostome. The aril is completely dermally initiated. The parenchymatic part of the operculum and the micropylar collar are of dual origin, namely dermal at me integumentary region and subdermal at the raphe.     

AN ANALYSIS OF CALIFORNIA SEA OTTER (ENHYDRA LUTRIS) PELAGE AND INTEGUMENT

The sea otter is associated with a cold, marine habitat, has no insulating fat layer, and relies on its fur layer for insulation. Soiled pelage provides inadequate insulation and can lead to hypothermia and death. Information on sea otter pelage, the surface and bound lipids found in the pelage, and histology of the integument is thus relevant to the development of rehabilitation and management techniques for sea otters soiled with oil. We present detailed data on the sea otter pelage and integument, including hair bundle density (737–2,465 bundles per cm²), hair density per bundle (19–91.1), total hair density (26,413–164,662 hairs per cm²), guardhair length (8.2–26.9 mm), underfur length (4.6–15.8 mm), guardhair diameter (44.0–106.0 μ), underfur diameter (7.6–11.9 μ), angle of hair with respect to the skin (61.9°- 84.3°) and structure of individual hairs as seen with a scanning electron microscope. The hydrocarbon squalene was found to be the major component of the lipids associated with the pelage. Various layers of skin from eight sites on a single animal are described histologically. With the exception of density of the hair coat, sea otter integument is similar to that of domestic carnivores.     

Functional Microanatomy of the Feather-Bearing Integument: Implications for the Evolution of Birds and Avian Flight

A selective regime favoring a streamlining of body contoursand surfaces is proposed as having been instrumental in drivingthe morphological and functional transformations of an unfeatheredreptilian integument into a feather-bearing avian one. Thishypothesis is consistent with a new, structurally and functionallycoherent analysis of the microanatomy of the avian feather-bearingintegument as a complex, integrated organ system that includesan intricate, hydraulic skeleto-muscular apparatus of the feathers,a dermo-subcutaneous muscle system of the integument, and asubcutaneous hydraulic skeletal system formed by fat bodies.Key elements of the evidence supporting the new hypothesis are(1) the presence of depressor feather muscles that are not neededas antagonists for the erector feather muscles, but can counteractexternal forces, such as air currents; (2) the fact that thehighly intricate feather-bearing integument represents a machineryto move feathers or to stabilize them against external forces;(3) the crucial role of the coat of feathers in streamliningthe body contours and surfaces of birds; (4) the aerodynamicrole of feathers as pressure and turbulence sensors and as controllabletemporary turbulators; and (5) the critical role that a streamlinedbody plays in avian flight and is likely to have played in theevolutionary transformations from ecologically and locomotorilyversatile quadrupedal reptiles to volant bipedal birds withoutpassing through parachuting or gliding stages. These transformationsare likely to have occurred more than once. The ancestral birdswere probably small, arboreal, hopping, and using flap-bounding,or intermittent bounding, flight.     

Push or Pull? The light‐weight architecture of the Daphnia pulex carapace is adapted to withstand tension,not compression

Daphnia (Crustacea, Cladocera) are well known for their ability to form morphological adaptations to defend against predators. In addition to spines and helmets, the carapace itself is a protective structure encapsulating the main body, but not the head. It is formed by a double layer of the integument interconnected by small pillars and hemolymphatic space in between. A second function of the carapace is respiration, which is performed through its proximal integument. The interconnecting pillars were previously described as providing higher mechanical stability against compressive forces. Following this hypothesis, we analyzed the carapace structure of D. pulex using histochemistry in combination with light and electron microscopy. We found the distal integument of the carapace to be significantly thicker than the proximal. The pillars appear fibrous with slim waists and broad, sometimes branched bases where they meet the integument layers. The fibrous structure and the slim‐waisted shape of the pillars indicate a high capacity for withstanding tensile rather than compressive forces. In conclusion they are more ligaments than pillars. Therefore, we measured the hemolymphatic gauge pressure in D. longicephala and indeed found the hemocoel to have a pressure above ambient. Our results offer a new mechanistic explanation of the high rigidity of the daphniid carapace, which is probably the result of a light‐weight construction consisting of two integuments bound together by ligaments and inflated by a hydrostatic hyper‐pressure in the hemocoel. J. Morphol. 277:1320–1328, 2016. © 2016 Wiley Periodicals, Inc.     

Evidence for the neural crest origin of turtle plastron bones

Summary: The migrating cranial neural crest cells of birds, fish, and mammals have been shown to form the membranous bones of the cranium and face. These findings have been extrapolated to suggest that all the dermal bones of the vertebrate exoskeleton are derived from the neural crest ectomesenchyme. However, only one group of extant animals, the Chelonians, has an extensive bony exoskeleton in the trunk. We have previously shown that the autapomorphic carapacial and plastron bones of the turtle shell arise from dermal intramembranous ossification. Here, we show that the bones of the plastron stain positively for HNK‐1 and PDGFRα and are therefore most likely of neural crest origin. This extends the hypothesis of the neural crest origin of the exoskeleton to include the turtle plastron. genesis 31:111–117, 2001. © 2001 Wiley‐Liss, Inc.     

Underwater survival in the dog tick Dermacentor variabilis (Acari:Ixodidae)

Ticks are blood-feeding arthropods known for their long survivability off the host. Although ticks are terrestrial, they can survive extended periods of time submerged underwater. A plastron is an alternative respiration system that can absorb oxygen from water via a thin layer of air trapped by hydrophobic hairs or other cuticular projections. The complex spiracular plate of ticks has been postulated to serve as a plastron but that function has not been verified. This study provides evidence of plastron respiration in the American dog tick, Dermacentor variabilis, and for the first time confirmed the existence of plastron respiration in Ixodidae. Longer survival rates in oxygenated water indicate that underwater respiration requires oxygen. Wetting the spiracular plate with alcohol debilitates any potential plastron function and lowers the survival rate. Survival underwater may also be enhanced by metabolic depression and possibly anaerobic respiration. This study describes the first example of plastron respiration in the Ixodidae.     

Submersion respiration in small diving beetles (Dytiscidae)

Some small diving beetles can survive submerged through weeks and months, because they can extract oxygen, dissolved in the water, through respiratory pores in their integument. An air flux from the outside to the inside through the respiratory pores has been demonstrated. All diving beetles capable of such pore respiration are small, but not all small diving beetles have pore respiration. With increasing size, more and more of the surface must be covered by respiratory pores to meet the increasing demand of oxygen. In running water species the pore-respiration mode is regarded as an adaptation to life in current exposed substrates, thus they avoid the risk of being swept away during frequent surface visits. In stagnant water species the pore respiration mode reduces the risk of falling victim to pelagic predators. The submersion tolerant species can switch to surface respiration, e.g. during low oxygen content. The pore respiratory mechanism is believed to be a specialised plastron. The oxygen flux through the scattered, small respiratory pore area may be enhanced by a functional thinning of the boundary layer.     

Stimulation of hydrocarbon biosynthesis by ecdysterone in the flesh fly Sarcophaga bullata.

Ecdysterone has been shown to stimulate hydrocarbon biosynthesis in Sarcophaga bullata at pupariation. When post-feeding larva were treated with ³H-acetate 10·5 hr after hormone administration, a 1·3 times greater quantity of ³H-acetate was incorporated into hydrocarbon in the ecdysterone injected insects than controls. A similar experiment with a 24 hr delay of ³H-acetate administration following hormone treatment resulted in 3·3 times greater incorporation into hydrocarbon of treated animals.Isolated integuments synthesize hydrocarbon from acetate better than internal tissues, and the integuments of ecdysterone-treated insects incorporate acetate into hydrocarbon 9·8 times better than integuments of control insects. This indicates that cuticular hydrocarbon biosynthesis not only occurs in the integument, but that a locus of regulation is present in the integument.     

Gametophytes,embryogeny and pericarp ofMicrostylis wallichii lindl. (Orchidaceae)

The anther wall is 4-layered thick. Its development is of the Monocotyledonous type. Simultaneous cytokinesis results in decussate, isobilateral, linear and tetrahedral tetrads. At anthesis, the microspores are 2-celled. The mature ovules are anatropous, bitegmic and tenuinucellate. Both the integuments are dermal in origin and 2-layered. The inner integument alone forms the micropyle. Development of the female gametophyte is of the Monosporic type. Double fertilization occurs but the primary endosperm nucleus degenerates without any division. Development of embryo corresponds to the variation of the Onagrad type. The mature embryo lacks differentiation. The seeds are minute and non-endospermic. The seed coat is formed entirely by the outer layer of outer integument. There are three sterile and three fertile valves in the ovary. In the prefertilization stages valves consist of parenchymatous cells. After fertilization, the sterile valves become sclerenchymatous whereas the fertile valves remain parenchymatous.     

Adaptation to the sky: Defining the feather with integument fossils from mesozoic China and experimental evidence from molecular laboratories

In this special issue on the Evo-Devo of amniote integuments, Alibardi has discussed the adaptation of the integument to the land. Here we will discuss the adaptation to the sky. We first review a series of fossil discoveries representing intermediate forms of feathers or feather-like appendages from dinosaurs and Mesozoic birds from the Jehol Biota of China. We then discuss the molecular and developmental biological experiments using chicken integuments as the model. Feather forms can be modulated using retrovirus mediated gene mis-expression that mimics those found in nature today and in the evolutionary past. The molecular conversions among different types of integument appendages (feather, scale, tooth) are discussed. From this evidence, we recognize that not all organisms with feathers are birds, and that not all skin appendages with hierarchical branches are feathers. We develop a set of criteria for true avian feathers: 1) possessing actively proliferating cells in the proximal follicle for proximo-distal growth mode; 2) forming hierarchical branches of rachis, barbs, and barbules, with barbs formed by differential cell death and bilaterally or radially symmetric; 3) having a follicle structure, with mesenchyme core during development; 4) when mature, consisting of epithelia without mesenchyme core and with two sides of the vane facing the previous basal and supra-basal layers, respectively; and 5) having stem cells and dermal papilla in the follicle and hence the ability to molt and regenerate. A model of feather evolution from feather bud --> barbs --> barbules --> rachis is presented, which is opposite to the old view of scale plate --> rachis --> barbs --> barbules (Regal, '75; Q Rev Biol 50:35).     

长豇豆种皮和种脐的发育

长豇豆的胚珠具内外两层珠被,内珠被在种子发育早期退化消失,种皮仅由外珠被发育而成。外珠被的外表皮细胞径向伸长,外壁和经向壁增厚,形成约占成熟种皮厚度一半的栅栏层;亚表皮细胞发育为骨状石细胞层。第三层细胞类似于亚表皮层但细胞壁增厚不明显,其内方的多层薄壁细胞形成海绵组织。种脐具两层栅栏细胞,外栅栏层及其以外部分由珠柄组织发育而成管胞群。本文还对脐缝和管胞群的作用以及豆科种子的吸水机制进行了讨论。     

Integument initiation and testa development in some Cruciferae

This study has shown for the first time that the middle layer (or layers) of the outer integument is (are) of subdermal derivation in at least some taxa of the Cruciferae. The outer integument is initiated in the Cruciferae in three different ways, viz. subdermally (Brassica, Sinapis) , partly subdermally and partly dermally (Lunaria) , or completely dermally (Capsella). These differences in initiation are reflected in the structure of the mature testa. The inner integument is completely of dermal derivation and originally two cell-layers thick, but may become more than two-layered during the ovule and seed maturation by periclinal divisions of the inner cell layer. The consequences of the ontogeny of the integuments for the terminology and interpretation of the mature testa is discussed.     

Sound reception of marine mammales depending on parameters and sound-conducting tracks

Underwater audiograms of a northern fur seal, a Caspic seal and a dolphin aphalina were measured under conditions of full or partial (the head above the water) submergence of animals using the method of instrumental conditioned reflexes with food reinforcement. The possibility and peculiarities of sound conduction through the body of marine mammals were investigated by isolating the auricle from the medium of sound spreading (under conditions of partial submergence). By the same technique, the hearing thresholds of Caspic seal were measured in the presence of broad- and narrow-band noises with different central frequencies depending on the medium (underwater or in air) the signal and the noise masker were presented and on the sound-conducting ways (under conditions of full or partial submergence of animals). It was found that aerial and underwater sound-conducting canals of the Caspic seal were functionally connected with each other. The level of hearing masking in the Caspic seal is determined by the tracts of signal and noise conduction, by the differences in sensitivity to the signal and masker, and by their spectral structure. Apparently, the tissues of the seal body considerably change the amplitude-frequency characteristics of the sound.     

The outer integument and funicular outgrowth complex in the ovule of<Emphasis Type="Italic"> Magnolia grandiflora</Emphasis> (Magnoliaceae)

The development of the outer integument and funicular outgrowth in the ovule of Magnolia grandiflora was examined by microtomy and scanning electron microscopy to reveal the morphology and evolution of the outer integument, a novel angiosperm structure. Early in development the outer integument is semiannular, decurrent to the lateral sides of the funiculus, and extends downwards beyond the funicular outgrowth that forms in the gap of the outer integument, and is transverse to the funiculus. The outer integument then overgrows the funicular outgrowth perpendicularly to the funiculus to form a micropyle together. The hood-shaped outer integument and the funicular outgrowth compose an envelope complex, and the interpretation of a single cupular outer integument is not supported. This envelope complex may differ from the cupular outer integument of other angiosperms, e.g., Nymphaeaceae, suggesting independent origin of apparently cupular outer integuments and hood-shaped outer integuments. Anatropous curving is due mainly to differential growth of the chalaza. The bistomic micropyle of Magnoliaceae seems to represent a derived character state, compared to an endostomic micropyle. T. Yamada is a research fellow of the Japan Society for the Promotion of Science.     

Evo-Devo of amniote integuments and appendages

Integuments form the boundary between an organism and the environment. The evolution of novel developmental mechanisms in integuments and appendages allows animals to live in diverse ecological environments. Here we focus on amniotes. The major achievement for reptile skin is an adaptation to the land with the formation of a successful barrier. The stratum corneum enables this barrier to prevent water loss from the skin and allowed amphibian / reptile ancestors to go onto the land. Overlapping scales and production of beta-keratins provide strong protection. Epidermal invagination led to the formation of avian feather and mammalian hair follicles in the dermis. Both adopted a proximal - distal growth mode which maintains endothermy. Feathers form hierarchical branches which produce the vane that makes flight possible. Recent discoveries of feathered dinosaurs in China inspire new thinking on the origin of feathers. In the laboratory, epithelial - mesenchymal recombinations and molecular mis-expressions were carried out to test the plasticity of epithelial organ formation. We review the work on the transformation of scales into feathers, conversion between barbs and rachis and the production of "chicken teeth". In mammals, tilting the balance of the BMP pathway in K14 noggin transgenic mice alters the number, size and phenotypes of different ectodermal organs, making investigators rethink the distinction between morpho-regulation and pathological changes. Models on the evolution of feathers and hairs from reptile integuments are discussed. A hypothetical Evo-Devo space where diverse integument appendages can be placed according to complex phenotypes and novel developmental mechanisms is presented.     

Differences in the activity and distribution of peroxidases from three different portions of germinating Brassica oleracea seeds

Peroxidase (POD, EC 1.11.1.7) activity, cellular localization and isozyme patterns were investigated in the seed integument, cotyledon and embryo axis of Brassica oleracea cv. Cappuccio during pregermination and seedling growth. Seeds started to germinate after 24 h of imbibition. POD activity was localized in the pigmented layer of the integument and in procambial strands of the cotyledon and embryo axis in the first 24 h of imbibition. It was localized in the integumental cells of palisade, pigmented and aleurone layers and in epidermal, meristematic, procambial cells and xylem elements of the root and hypocotyl after 48 h of imbibition. POD activity increased during germination and early seedling growth: in the integument, it reached a maximum value after 72 h of imbibition, in the embryo axis and cotyledons, it increased up to 144 h of imbibition. The increase in peroxidase activity was accompanied by the appearance of new isozymes correlated with the development of seedling tissues. The isozyme profile was characterized by nine peroxidases: isoperoxidase of 50 kDa peculiar to integuments, that of 150 kDa to cotyledons and that of 82 kDa to the embryo axis. During pregerminative phase isozymes of 84 kDa were detected in the integument and cotyledons, of 48.5 kDa in the embryo axis. After germination, peroxidase activity and the complexity of the isozyme pattern increased, suggesting that they play a relevant role after rupture of the integument.