Structural features associated with respiration in some intertidal Uropodina (Acarina: Mesostigmata)

The present study suggests that the peritremes of both Phaulodinychus repleta (Berlese) (Uropo-didae) and Thinozercon michaeli Halbert (Thinozerconidae) are incapable of forming peritreme plastrons in the same manner as the Gamasina or Phaulodinychus mitis (Leonardi) (Uropodidae) described in previous studies. However, it is proposed that extra-peritrematic plastrons may be formed by other structures, for example the pedofossae and legs in P. repleta and the coarse sculpturing on the dorsal surface of the peritrematic shield in T. michaeli , which may trap an airfilm during inundation.     

Physical gills in Elmidae (Coleoptera: Byrrhoidea): Structure and evolutionary pattern of plastron in Stenelmis and related genera

Many species within Elmidae (Coleoptera: Byrrhoidea) have plastrons composed of flattened setae. However, some genera display fine plastrons on the epicuticle, called plastron hairs. In Japanese elmids, members of the genera Stenelmis, Ordobrevia, Nomuraelmis and Leptelmis bear ventral plastron hairs. Based on a maximum likelihood tree including most Japanese genera within Elmidae, we found that these genera are monophyletic and that plastron hairs are a derived character in Elmidae. We also found that the genus Graphelmis bears jigsaw puzzle‐like plastron scales with plastron hair‐like projections, and is sister to the group with plastron hairs.     

A diffusion equation for tapered plastrons

An equation for the diffusion of oxygen along a plastron of uniform thickness was provided by Thorpe and Crisp in their classical work on plastrons. Since then it has been discovered that some plastrons are tapered, e.g. those of many spiracular gills, in which the thickness of the plastron becomes less as the distance from the spiracle increases. Here a differential equation is provided for calculating the efficiency of a uniformly tapered plastron. A series of curves is also given that show the efficiency of the tapered plastron as a function of the distance from the spiracle, thickness, and degree of taper. Using these curves the efficiency of the plastron can be estimated immediately without the necessity of solving the differential equations.     

The respiratory system of the femaleVarroa jacobsoni (Oudemans): its adaptations to a range of environmental conditions

The morphology of the respiratory system of the femaleVarroa jacobsoni (Oudemans, 1904) is described. The mobile, appendage-like, emergent peritreme may be raised to lie against the ventral integument or lowered between the third and fourth pair of legs. It is raised when the mite is submerged in the liquid food of the host's brood chamber, where respiration occurs via an external plastron, formed by an airfilm trapped between the rough cuticle of the ventral integument and the retracted legs. The peritreme is also raised when the mite is outside the hive in sub-saturated air, to reduce water vapour transpiration, and it is lowered in the carbon-dioxide-rich and water-saturated hive atmosphere, where it facilitates rapid removal of carbon dioxide. Thus gaseous exchange in the female mites may be adjusted by the position of the peritreme.Key to captions a ascending limb of peritrematic groove - c hollow (haemocoel) core of peritreme - d descending limb of peritrematic groove - e endocuticle - f flange of the inner stigmatic orifice - g peritrematic groove - i funnel of inner stigmatic orifice - k circum-spiracular pocket at base of peritreme - 1 peritrematic slit - m micropapillae - n fringe of marginal setae - o outer stigmatic orifice (=stigma) - p emergent peritreme - r rough integument at bases of leg coxae - s stigmatic atrium - t tracheal atrium - u outer lip of outr stigmatic orifice - v inner lip of outer stigmatic orifice - x tracheal trunks - z thick cuticle of peritrematic groove - 1,2,3,4 numbers of legs or leg coxae     

Plastron respiration in bugs and beetles

In the naucorid bug, Alphelocheirus, the plastron hairs are twice as thick and nearly twice as dense (ca. 4 × 10⁶/mm²) as they had been thought to be by previous workers. From experiments and calculations it seems clear that when the plastron is subjected to excess pressures it is wetted long before there is any question of the collapse of the hair pile itself. The plastron of Aphelocheirus is thus like the plastrons of other insects in that it is wetted long before the structures supporting the air film collapse.A plastron has been independently evolved in at least five subfamilies of the Naucoridae. A plastron is here recorded for the first time in bugs of the family Helotrephidae.It has been claimed that the plastron-bearing elmid beetles are unable to fly. Many, if not most, of these beetles fly after they emerge from their pupal cells. However, once they have begun to live under water they cease to be able to fly: the flight muscles degenerate, and this degeneration seems to be irreversible.The structure of the plastron scales of several kinds of weevils is described. The resistance of the plastron of the rice water weevil, Lissorhoptrus, to wetting at excess pressures is examined. An explanation is advanced to account for the fact that weevils and other plastron-bearing beetles that live in still waters can often swim whereas those, like elmids and dryopids, that live in running waters cannot swim.     

A review of the North American genus Epimartyria (Lepidoptera, Micropterigidae) with a discussion of the larval plastron

The indigenous North American micropterigid genus Epimartyria Walsingham,1898 is revised. Three species are recognized, including Epimartyria auricrinella Walsingham, 1898 which occurs widely over much of the northeastern United States and Canada, a new species, Epimartyria bimaculella Davis & Landry from northwestern United States and Canada, and Epimartyria pardella (Walsingham, 1880) from northern California to northern Oregon. The larva of Epimartyria auricrinella is described in detail, supplemented with illustrations of the external structure of the larval integument. The larval plastron is described and illustrated for Epimartyria, and this is compared with the plastrons of Neomicropteryx Issiki, 1931 and Micropterix Hübner, 1825. COI barcode sequences show that the three species are genetically distinct, congruent with morphological differences. Marked haplotype divergence within some Epimartyria auricrinella populations appears to be unrelated to morphology, geography or phenology.     

Plastron respiration in marine intertidal oribatid mites (Acari,Fortuyniidae and Selenoribatidae)

Plastron respiration was investigated in the fortuyniid Alismobates inexpectatus, Fortuynia atlantica and the selenoribatid Carinozetes bermudensis. All these taxa inhabit intertidal zones of subtropical and tropical coasts and are exposed to tidal flooding. The utilization of plastron mechanisms enables these species to respire under water. Cerotegumental structures consisting of micropapillae and pillars bearing an outer sheet provide extensive areas where air is retained supplying the tracheal system with oxygen. A. inexpectatus and F. atlantica possess a dorsal and ventral plastron connected laterally by cuticular channels of the van der Hammen’s organ, whereas the specific configuration of these channels varies between the genera. The plastron of Carinozetes species spans the whole body except for all movable parts as legs and genital and anal valves. Plastron structures in juveniles of the families Fortuyniidae and Selenoribatidae were investigated for the first time in detail. Air-retaining cerotegument is also present in immatures of these taxa but is concentrated along lateral and ventral folds where series of pores lead into supposed tracheal organs. In juveniles of A. inexpectatus and F. atlantica, these organs are tubes with a length of approximately 3–15 μm, and in Carinozetes immatures, these organs are short saccules (0.5–1 μm).     

Aquatic respiration as a potential survival mechanism of Brephidium pseudofea (Lepidoptera: Lycaenidae) larvae to intertidal environments

The eastern pygmy blue, Brephidium pseudofea (Morrison) (Lepidoptera: Lycaenidae: Polyommatinae), inhabits intertidal environments that are periodically flooded. The immature stages are subject to salt or brackish water inundation during this time and therefore must endure many stressors, including respiratory limitation and salt exposure. Our goal was to investigate possible mechanisms used by the larval stages of B. pseudofea to endure periodic tidal inundation by using physiological and morphological analyses in comparison with several species of terrestrial lepidopteran larvae. A review of tidal charts showed that the immature stages of B. pseudofea would be prone to complete inundation two to five times per month during the summer months (May to August) and partial submersion for up to 20 d per month during the rest of the year. Larvae of several terrestrial lepidopteran species studied consumed oxygen under water for a limited period, but B. pseudofea demonstrated substantially higher oxygen consumption. Light microscopy of B. pseudofea larvae revealed small air pockets in and around the spiracles when submerged in tap water; these air pockets disappeared when exposed to detergent solution. The resulting air pockets may function as a diffusion layer for oxygen to be absorbed from the surrounding water or may act in conjunction with trans-cuticular gas exchange to meet the larva's respiratory needs. Morphological examination by scanning electron microscopy showed that B. psudofea larvae have distinctively small, clavate setae that appear insufficient to effectively support a functional plastron.     

Surviving floods: leaf gas films improve O2 and CO2 exchange, root aeration, and growth of completely submerged rice

When completely submerged, the leaves of some species retain a surface gas film. Leaf gas films on submerged plants have recently been termed 'plant plastrons', analogous with the plastrons of aquatic insects. In aquatic insects, surface gas layers (i.e. plastrons) enlarge the gas–water interface to promote O₂ uptake when under water; however, the function of leaf gas films has rarely been considered. The present study demonstrates that gas films on leaves of completely submerged rice facilitate entry of O₂ from floodwaters when in darkness and CO₂ entry when in light. O₂ microprofiles showed that the improved gas exchange was not caused by differences in diffusive boundary layers adjacent to submerged leaves with or without gas films; instead, reduced resistance to gas exchange was probably due to the enlarged water–gas interface (cf. aquatic insects). When gas films were removed artificially, underwater net photosynthesis declined to only 20% of the rate with gas films present, such that, after 7 days of complete submergence, tissue sugar levels declined, and both shoot and root growth were reduced. Internal aeration of roots in anoxic medium, when shoots were in aerobic floodwater in darkness or when in light, was improved considerably when leaf gas films were present. Thus, leaf gas films contribute to the submergence tolerance of rice, in addition to those traits already recognized, such as the shoot-elongation response, aerenchyma and metabolic adjustments to O₂ deficiency and oxidative stress.     

The functional morphology of the respiratory system of the Holothyrida (= Tetrastigmata) Acari: Anactinotrichida

The respiratory system of Holothyrus coccinella Gervais (Holothyridae) and Allothyrus australasiae (Womersley) (Allothyridae) were examined. The stigma-peritreme complex is connected to tracheae and ventilated by indirect muscles. The peritreme provides an alternative route for the entry of air into the tracheal system, should a stigma be occluded by debris and retards water vapour transpiration, the mechanisms of which are compared in the two species.     

Assessing the morphological and physiological adaptations of the parasitoid wasp Echthrodesis lamorali for survival in an intertidal environment

As a result of a variety of chemical, environmental, mechanical and physiological difficulties, insects that spend their entire life spans in the marine or intertidal region are relatively rare. The present study assesses whether morphological and physiological adaptations have evolved in a maritime parasitoid wasp species Echthrodesis lamorali Masner, 1968 (Hymenoptera: Platygastridae, Scelioninae), in response to environmental pressures on its respiratory functioning. Scanning electron and light microscopy of whole and sectioned specimens show the presence of structure‐retaining taenidia in the tracheal tubes, although there is an absence of other major adaptations associated with the trachea or spiracles. Histological sectioning reveals the presence of unusual sacs in the female metasoma whose role is unknown, although they are hypothesized to most likely be linked to ovipositor control. Respirometry experiments illustrate the formation of a plastron when submerged, with the longevity of the wasps being increased by quiescence. The critical thermal range of E. lamorali is shown to be large: from ?1.1 °C ± 0.16 to 45.7 °C ± 0.26 (mean ± SE). Behavioural and physiological adaptations in E. lamorali appear to have evolved in response to exposure to the heterogeneous environmental conditions experienced within the intertidal zone.     

Plastron respiration in adult beetles of the suborder Myxophaga

The kind of physical gill known as a plastron is a gas film of constant volume and an extensive water-air interface. Such films are held by hydrofuge structures, and they resist wetting at the hydrostatic pressures to which they are normally subjected in nature. In well-aerated water a plastron enables the insect to be immersed indefinitely. A plastron is here recorded for the first time in adult beetles of the suborder Myxophaga. In both known genera of the family Torridincolidae a plastron is present on the abdomen. In Ptyopteryx of Brazil the plastron forms a diffraction grating that is responsible for the iridescence oi the abdomen. The structure of the plastron of Torridincola of Rhodesia is like that of some other beetles, and it is not iridescent. Among adult beetles plastron respiration has been independently evolved in at least eight quite different groups, and within some of these groups it has been evolved on more than one occasion.     

Respiratory Adaptations in Intertidal Fish

SYNOPSIS: Intertidal rockpools provide a challenging environmentfor rockpool fish with rapid changes taking place in many environmentalparameters over a tidal cycle. Intertidal fish exhibit a numberof behavioural adaptations such as the avoidance of hypoxicsituations or remaining inactive during aerial "stranding."Other species are, however, well adapted to breathe air andexhibit morphological adaptations such as smaller gill areas,specialized buccopharyngeal epithelia and a proliferation ofcutaneous blood vessels in the skin. Oxygen consumption in rockpoolfish is comparable to non-intertidal fish and responds in asimilar manner to temperature changes. The ability to regulateoxygen consumption down to oxygen tensions below 40 Torr is,however, marked in rockpool species. Aerial and aquatic ratesof respiration are similar in those species which are able tobreathe air and the respiratory quotient normally remains between0.7 and 0.9. A number of intertidal fish are well adapted forcutaneous respiration, satisfying over half of their oxygenand carbon dioxide exchange through the skin. Ventilatory responsesto increased temperature, hyperoxia and hypoxia are similarto those of other fish but cardiac responses may differ in thatno change in heart rate is seen under hypoxia or hyperoxia.Ventilatory and cardiac responses to aerial respiration arewell adapted in some species maintaining ventilation and perfusionduring aerial exposure. A marked Bohr effect, low temperaturesensitivity and a temperature dependent Haldane effect havebeen measured in the haemoglobolin of some intertidal fish.These properties may assist oxygen transport and carbon dioxideexchange during cyclical changes in environmental parameterswithin an intertidal rockpool.     

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.     

Evidence for the morphological constraint hypothesis and optimal offspring size theory in the Mexican mud turtle (Kinosternon integrum)

Optimal offspring size theory states that natural selection should balance reproductive output by optimizing between offspring size and offspring number. If a species has evolved an optimal offspring size, the fitness of larger females should be increased by simply producing more offspring of an optimum size. In contrast, when offspring size is not optimized, the morphological constraint hypothesis may apply, and in this case, maternal fitness is increased by producing the greatest number of the largest offspring that mothers are physically capable of producing. We used a log-log allometric regression approach on clutch size, egg size, and body size data to test the application of optimal offspring size theory and the morphological constraint hypothesis in the Mexican mud turtle (Kinosternon integrum) in southern Mexico. Our results indicate that this turtle seems to follow the morphological constraint hypothesis when all data are analyzed together, but when data are divided between small (< 140 mm plastron length) and large females (> 140 mm plastron length), optimal offspring (egg) size theory was supported only in large females, while the morphological constraint hypothesis was supported in small females. Our results thus indicate that K. integrum females may increase their fitness in two different, size-dependent ways as they grow from size at sexual maturity to maximum body size.     

Effects of Intertidal Elevation on the Rockpool Ichthyofaunas of Temperate Australia

A quantitative assessment of the effects of intertidal elevation on rockpool ichthyofaunas was investigated at four locations in southeastern New South Wales, Australia. Rockpools supported high diversity and abundance of fishes mainly comprising the families Clinidae, Blennidae, Tripterygiidae, Gobiidae, Gobiesocidae and Girellidae, which are mostly permanent residents. Mean numbers of species and individuals did not differ among low, medium and high rockpools. In contrast, species composition differed among intertidal rockpool heights with pools mainly being dominated by transient and opportunist species in lower intertidal, opportunists and permanent residents in the mid intertidal, and mainly permanent residents in the high intertidal. Distribution patterns appeared to be related to the morphological and/or physiological adaptations of species to the increasingly harsh and variable environmental conditions with increasing intertidal elevation. Residential status of each species may be used as a proxy for intertidal vertical distribution although some exceptions exist, namely Girella elevata, which may posses behavioural adaptations to cope with harsh environmental conditions.     

Preferred temperature of intertidal ectotherms: Broad patterns and methodological approaches

Preferred temperature (Tpref) has been measured in over 100 species of aquatic and 300 species of terrestrial ectotherms as a metric for assessing behavioural thermoregulation in variable environments and, as such, has been linked to ecological processes ranging from individual behaviour to population and community dynamics. Due to the asymmetric shape of performance curves, Tpref is typically lower than the optimal temperature (Topt, where physiological performance is at its peak), and the degree of this mismatch increases with variability in Tb. Intertidal ectotherms experience huge variability in Tb on a daily basis and therefore provide a good system to test whether the relationship between Tpref and variation in Tb holds in more extreme environments. A review of the literature, however, only revealed comparisons between Tpref and Topt for five intertidal species and measurements of Tpref for 23 species. An analysis of this limited literature for intertidal ectotherms showed a positive relationship between acclimation temperature and Tpref. There was, however, great variation in the methodologies employed to make these assessments. Factors contributing to behavioural thermoregulation in intertidal ectotherms including small body size; low mobility; interactions among individuals; endogenous clocks; metabolic effects; thermal sensitivity; sampling of the thermal environment and recent acclimation history were considered to varying degrees when measuring Tpref, confounding comparisons between species. The methodologies used to measure Tpref in intertidal ectotherms were reviewed in light of each of these factors, and methodologies proposed to standardize approaches. Given the theoretical predictions about the relationships between Tpref and variability in Tb, the spatial and temporal thermal variability experienced by intertidal ectotherms provides numerous opportunities to test these expectations if assessed in a standardized manner, and can potentially provide insights into the value of behavioural thermoregulation in the more thermally variable environments predicted to occur in the near future.     

Fine structure of the eggs of blowflies Aldrichina grahami and Chrysomya pacifica (Diptera: Calliphoridae)

We report here the fine structure of the eggs of blowflies Aldrichina grahami (Aldrich) and Chrysomya pacifica Kurahashi. For A. grahami, the plastron is wide and extends to almost the entire length of the eggs. The plastron near the micropyle is truncated. The polygonal patterns of chorionic sculpture bear a distinct swollen boundary. Regarding C. pacifica, the plastron is narrow and extends to almost the entire length of the eggs. The plastron near the micropyle bifurcates to a Y-shape, but the arms of the 'Y' are short. Information presented herein allows some distinctive features to differentiate among eggs of blowfly species.     

MICROPAPILLAE IN SEA URCHIN EGGS*

Sea urchin eggs fixed in a glutaraldehyde-calcium chloride mixture have “micropapillae” with a dense content. If these structures are real, they are likely to be sites where a fusion with the spermatozoon can take place. It is possible however that they represent some kind of preparation artefact without a structural counterpart in the living state.