Burrow plasticity in the deep-sea isopod Bathynomus doederleini (Crustacea: Isopoda: Cirolanidae)

We investigated whether the deep-sea isopod Bathynomus doederleini has the capacity to change burrow length in response to changes in environmental conditions. We observed burrowing behavior in individuals that were placed on substrates with either simple (ST) or complex (CT) surface topographies. Individuals in the ST group (N = 10) constructed seven burrows. The mean ratio of the burrow length to body length was 1.8. The individuals in the CT group (N = 10) constructed eight burrows with a mean ratio of burrow length to body length of 2.5. Thus the burrows were significantly longer in the CT group. In addition, the isopods in the CT group often incorporated a chamber in the mid-section of the burrow. Our results may be used to infer the determinants of burrow morphology and speculate about the lifestyle of this species in the deep sea.     

Reproduction in the Giant Isopod,Bathynomus giganteus

Summary

Aspects of the reproductive biology of the giant isopod, Bathynomus giganteus (Edwards) resemble those of other isopods. In females, the gonopores are located on the sternal midline of the eighth thoracic somite and the eggs are brooded in a marsupium. The reproductive tract of the males also resembles those of other isopods. The paired vasa deferentia open into two penes located on the sternal midline of the eighth thoracic somite. The vasa deferentia are formed of columnar epithelial cells with basal nuclei. The lumen is filled with seminal products consisting of aggregrates of spermatozoa surrounded by extracellular tubules. The sperm head consists of an acrosome and subacrosomal rod from which a pendant nucleus extends. The tails are composed of an amorphous core consisting of a dark band, two medium bands, two light bands followed by a dark band again. The tails are attached to the heads by a knob which is an extension of the core     

Intestinal microflora in the deep-sea isopodBathynomus giganteus

Observations with the scanning electron microscope showed that the deep-sea isopodBathynomus giganteus harbors a dense microflora within the digestive tract. The gut microflora is composed of a diversity of microorganisms, including an unusually large bacterial morphotype that predominates almost exclusively in the anterior end of the hindgut. The majority of these large bacteria measured 1.9 m×8.5 m and many reached a size of 2.0 m×10.0 m.     

Neural pathways to cardioaccelerator neurons in the isopod crustacean Bathynomus doederleini: Cholinergic activation by somatic movements

We investigated the excitatory and inhibitory input to cardioaccelerator (CA) and cardioinhibitor (CI) neurons located in the thoracic ganglia of the isopod crustacean Bathynomus doederleini by extracellular and intracellular recording. Electrical stimuli applied to the anterior and posterior connectives of single-ganglion preparations, containing either the 2nd or 3rd thoracic ganglion alone, and each of three paired ganglionic nerve roots produced excitatory postsynaptic potentials (EPSPs) in the cell body of a CA neuron. Artificial movements of appendages, such as the thoracic limbs and the swimmerets, also evoked EPSPs in the CA neuron. Electrical stimuli applied to the peripheral nerves running to appendages induced inhibitory postsynaptic potentials (IPSPs) in a CI neuron. Since artificial movements of the appendages caused decrease of CI impulse rate, these IPSPs in the CI neuron may be caused by mechanoproprioceptors in the appendages. Since tachycardia was accompanied by excitation of CA neurons and inhibition of CI neurons, activation of the mechanoproprioceptors may be responsible for tachycardia. EPSPs in CA neurons produced by stimulation of peripheral nerves were augumented by eserinization and blocked by curarization. The activation of CA neurons by ganglionic roots may be mediated by cholinergic processes ascending from mechanoproprioceptors.     

A push-pull set of elastic strand stretch receptor neurons for the swimmeret in an isopod Bathynomus doederleini

There coexist two types of neuronal terminal processes attaching to elastic strands at the socket of the swimmeret in Bathynomus doederleini. One of the processes, stretch receptor I is derived from the 1st nerve root of the abdominal ganglion. The other, stretch receptor II is derived from the 2nd nerve root of the ganglion. Both axons of stretch receptors are very thick (30-60 micro m) at sites before the terminal arborization. Cell bodies of the stretch receptors are located in the ganglion of their own segments. The neuronal cell body of the stretch receptor I is located at the anterior half of the hemiganglion ipsilateral to the periphery, and the neuronal cell body of the stretch receptor II at the posterior half of the hemiganglion contralateral to the periphery. Their signaling modalities in response to swimmeret movements were analyzed from intracellular recordings from the cell bodies. Stretch receptor I produced a sustained hyperpolarizing potential in response to protraction of the swimmeret. Stretch receptor II produced a sustained depolarizing potential in response to the protraction, and moreover, generated spike potentials on the rising phase of the depolarizing potential according to its height and steepness. Both the stretch receptors are a push-pull set of elastic strand stretch receptors for the angular position and velocity of swimmeret movements.     

Latent phenoloxidase activity and N-terminal amino acid sequence of hemocyanin from Bathynomus giganteus,a primitive crustacean

N-terminal amino acid sequences for the two hemocyanin subunits from the deep-sea crustacean Bathynomus giganteus have been determined by Edman degradation, providing the first sequence information for a hemocyanin from an isopod. In addition, purified hemocyanin from B. giganteus exhibited phenoloxidase activity in the presence of sodium dodecyl sulfate. Although a natural activator has not yet been identified, a preliminary study of the enzyme indicated a K(m) of 5mM for dopamine and an initial rate of 0.1 micromol per min per mg protein, values consistent with a significant role for this enzyme in the innate immune system of B. giganteus. Moreover, after separation of hemolymph by alkaline polyacrylamide gel electrophoresis, the only detectable phenoloxidase activity coincided with the two hemocyanin subunits. The hemocyanin of this primitive crustacean may fulfill dual functions, both as oxygen carrier and as the phenoloxidase crucial for host defense.     

Neural mechanisms governing distribution of cardiac output in an isopod crustacean,Bathynomus doederleini: reflexes controlling the cardioarterial valves

In Bathynomus doederleini all of the cardioarterial valves located at the origin of the lateral arteries are dilated by impulses of lateral cardiac nerves. Tactile stimuli applied to sensillar setae depress impulse activities of the 1st and 5th lateral cardiac nerves. The 1st lateral cardiac nerve controls the valve of the lateral artery which runs to the walking-legs and viscera. The 5th lateral cardiac nerve controls the valve of the lateral artery which runs to the swimmeret muscles. The response indicates that tactile receptor reflexes bring about decreased haemolymph flow to the organs. Augmented swimmeret movements were always accompanied by an increased firing rate in the 5th lateral cardiac nerve. Artificial full protraction of swimmerets simultaneously induced excitation of the 5th lateral cardiac nerve and inhibition of the 1st lateral cardiac nerve. The excitation corresponds to an increase in haemolymph flow to the swimmerets, and the inhibition a decrease in haemolymph flow to walking-legs and viscera. Three kinds of mechanoproprioceptors which were activated by swimmeret movements were found. Two of the mechanoproprioceptors are located at the base of the basipodite. The other mechanoproprioceptor supplies processes to a nerve to the retractor muscles. Activation of three kinds of mechanoproprioceptors, induced by artificial swimmeret protraction, triggered lateral cardiac nerve reflex responses.Abbreviations LA lateral artery - LCN lateral cardiac nerve - RMN nerve to retractor muscles - StR stretch receptor     

The first complete mitogenome of the South China deep‐sea giant isopod Bathynomus sp. (Crustacea: Isopoda: Cirolanidae) allows insights into the early mitogenomic evolution of isopods

In this study, the complete mitochondrial (mt) genome sequence of the South China deep‐sea giant isopod Bathynomus sp. was determined, and this study is the first to explore in detail the mt genome of a deep‐sea member of the order Isopoda. This species belongs to the genus Bathynomus, the members of which are saprophagous residents of the deep‐sea benthic environment; based on their large size, Bathynomus is included in the “supergiant group” of isopods. The mt genome of Bathynomus sp. is 14,965 bp in length and consists of 13 protein‐coding genes, two ribosomal RNA genes, only 18 transfer RNA genes, and a noncoding control region 362 bp in length, which is the smallest control region discovered in Isopoda to date. Although the overall genome organization is typical for metazoans, the mt genome of Bathynomus sp. shows a number of derived characters, such as an inversion of 10 genes when compared to the pancrustacean ground pattern. Rearrangements in some genes (e.g., cob, trnT, nad5, and trnF) are shared by nearly all isopod mt genomes analyzed thus far, and when compared to the putative isopod ground pattern, five rearrangements were found in Bathynomus sp. Two tRNAs exhibit modified secondary structures: The TΨC arm is absent from trnQ, and trnC lacks the DHU. Within the class Malacostraca, trnC arm loss is only found in other isopods. Phylogenetic analysis revealed that Bathynomus sp. (Cymothoida) and Sphaeroma serratum (Sphaeromatidea) form a single clade, although it is unclear whether Cymothoida is monophyletic or paraphyletic. Moreover, the evolutionary rate of Bathynomus sp. (dN/dS [nonsynonymous mutational rate/synonymous mutational rate] = 0.0705) is the slowest measured to date among Cymothoida, which may be associated with its relatively constant deep‐sea environment. Overall, our results may provide useful information for understanding the evolution of deep‐sea Isopoda species.     

The evolution of the giant deer, Megaloceros giganteus (Blumenbach)

The giant deer, Megaloceros giganteus , is best known from its fossil occurrences in Ireland around 11 000 years ago, but has a history across Europe and Western Asia spanning 300 000–400 000 years. This paper reports a biometric study of variation and evolution in the giant deer through its history. Most early populations were as large in body size as the Irish sample, but some were distincdy smaller and others had markedly shorter limbs. Thickened skull and mandibular bones, especially marked in males, are constant throughout die species' history. Some earlier populations had anders which were relatively smaller, more upright and differing in other details from the celebrated Irish specimens. Observed variation in body and antler form is discussed in terms of changing palaeoenvironments. Interpretation of the fighting or display roles of M. giganteus antlers needs to take account of their differing forms through time.     

Moult of the giant petrels Macronectes halli and M. giganteus at South Georgia

Moult scores were collected from colour-ringed individuals of known reproductive status of the two species of giant petrel, Macronectes halli and M. giganteus , at Bird Island, South Georgia between 1978–81.
Both species showed a substantial overlap between breeding and wing-moult, unlike most other Southern Ocean seabirds. Males started moult before females and both sexes of M. giganteus moulted at an earlier stage of the breeding cycle than M. halli , which breeds six weeks earlier than its congener.
Changes in moult rate during the breeding season are documented for both species, with Id. halli showing a rapid increase as the chick nears fledging. Male M. giganteus show a notably different pattern to the other three species-sex groups, starting moult much earlier (at egg-laying), with greater individual synchrony and usually suspending primary moult throughout the main chick growth period, whereas only two male M. halli and no females of either species suspended moult. Differences in pattern, timing and rate of moult are interpreted in terms of availability of food resources and the competing energy demands of other activities, especially chick-rearing.
Completion of primary moult could not be observed in the field but was estimated using data frcsm non-breeding birds and failed breeders; the latter started a rapid moult almost immediately they failed. In both sexes of both species moult is probably concluded at least by early winter.
The general pattern of moult in giant petrels at Bird Island is contrasted with that of other populations and species of Southern Ocean seabirds. It is suggested that the unusually extensive overlap between breeding and moult in giant petrels is a consequence of the very abundant and easily available summer food supplies (especially carrion) and the much diminished winter resources, favouring a completion of moult by the beginning of the winter.     

Skeleton of the giant deer Megaloceros giganteus giganteus (Blumenbach, 1803) (Mammalia,Artiodactyla) from the Irtysh Region near Pavlodar

An almost complete skeleton of the giant deer Megaloceros giganteus giganteus (Blumenbach, 1803) from the Dzhambul locality on the Irtysh River (Pavlodar Region, Kazakhstan) is described. About 80% of bones are intact, including the skull with well-preserved antlers. At present, the skeleton is mounted in the Pavlodar Local History Regional Museum. Comparative analysis of giant deer skulls varying in age from the southeastern West Siberian Plain has revealed stable characters distinguishing Middle and Late Neopleistocene specimens. These characteristics are considered to be of subspecies rank, allowing the identification of Megaloceros giganteus ruffi Nehring and Megaloceros giganteus giganteus (Blumenbach.) Changes in absolute and relative dimensions of the dentition and facial skull length are most indicative with reference to evolution.     

Stable isotopes document the trophic structure of a deep-sea cephalopod assemblage including giant octopod and giant squid

Although deep-sea cephalopods are key marine organims, their feeding ecology remains essentially unknown. Here, we report for the first time the trophic structure of an assemblage of these animals (19 species) by measuring the isotopic signature of wings of their lower beaks, which accumulated in stomachs of stranded sperm whales. Overall, the species encompassed a narrow range in δ¹³C values (1.7‰), indicating that they lived in closely related and overlapping habitats. δ¹³C values can be interpreted in terms of distribution with the more ¹³C-depleted species (e.g. Stigmatoteuthis arcturi, Vampyroteuthis infernalis) having a more pelagic habitat than the more ¹³C-enriched, bathyal species (e.g. Todarodes sagittatus and the giant squid Architeuthis dux). The cephalopods sampled had δ¹⁵N values ranging 4.6‰, which is consistent with the species spanning approximately 1.5 trophic levels. Neither the giant octopod (Haliphron atlanticus) nor the giant squid reached the highest trophic position. Species δ¹⁵N was independent of body size, with large squids having both the highest (Taningia danae) and lowest (Lepidoteuthis grimaldii) δ¹⁵N values. Their trophic position indicates that some species share the top of the food web, together with other megacarnivores such as the sperm whale.     

Direct observations of the association between a deep-sea fish and a giant scyphomedusa

This is a report of evidence of a close symbiotic relationship between the scyphomedusa, Stygiomedusa gigantea and the fish, Thalassobathia pelagica. Images from remotely operated vehicles (ROV) were obtained of the fish swimming on and around the large scyphomedusa. This is the first ever documented symbiosis between an Ophidiform fish and a medusa.     

Direct observations of the association between a deep-sea fish and a giant scyphomedusa

This is a report of evidence of a close symbiotic relationship between the scyphomedusa, Stygiomedusa gigantea and the fish, Thalassobathia pelagica. Images from remotely operated vehicles (ROV) were obtained of the fish swimming on and around the large scyphomedusa. This is the first ever documented symbiosis between an Ophidiform fish and a medusa.