Burrowing shrimp of the infraorders Gebiidea and Axiidea (Crustacea: Decapoda)

This review is devoted to the different aspects of biology of burrowing shrimp of the infraorders Gebiidea and Axiidea (Crustacea: Decapoda). Information on their taxonomy, morphology and physiology, distribution, burrow architecture, and trophic mode is reviewed. The peculiarities of breeding and development, life history, and the role in the ecosystem of these infaunal species are analyzed. Special attention is given to the species that inhabit Peter the Great Bay of the Sea of Japan.     

The Morphology of the Mandibles in Zoea I Larvae of the Burrowing Shrimp Genera <Emphasis Type="Italic">Upogebia</Emphasis> (Gebiidea) and <Emphasis Type="Italic">Nihonotrypaea</Emphasis> (Axiidea)

The mandibles in the first zoeal stage of five species of the burrowing shrimp genera Upogebia (infraorder Gebiidea) and Nihonotrypaea (infraorder Axiidea) have been examined by scanning electron microscopy. The general shape of the mandibles in Upogebia zoeae is similar to that in Anomura larvae; in Nihonotrypaea, it is intermediate between the mandibles of anomuran and caridean shrimp larvae. The asymmetry of the mandibles, which is more pronounced in Nihonotrypaea, is confirmed. Species-specific features of the structure of the incisor process are found in three Upogebia species, while two Nihonotrypaea species almost do not differ in the mandible structure in their zoea I larvae. The morphological features of the mandibles indicate differences in the diet of Upogebia and Nihonotrypaea larvae. Under natural conditions, zoea I of the studied Nihonotrypaea species may feed on diatoms, which should be taken into account when rearing these decapod larvae in the laboratory.     

The seasonal dynamics and distribution of burrowing shrimp larvae of the infraorders Gebiidea and Axiidea in Amursky and Ussuriysky Bays,the Sea of Japan

The species composition, period of occurrence, density, and distribution of the larvae of burrowing shrimp of the infraorders Gebiidea and Axiidea in Amursky and Ussuriysky bays (Sea of Japan) were studied in May–October 2008. Larvae of eight species of this group were found in plankton samples. The period of occurrence of larvae in the bays was longest in Upogebia major and Nihonotrypaea petalura (4 and 3 months, respectively). Zoeae of the rest of the species occurred in the plankton for no more than 2 months, indicating a single larval hatching during the reproductive season. The average density of gebiidean and axiidean larvae was low and reached the highest values (4 ind./m³) in June in Amursky Bay and in July in Ussuriysky Bay; their contribution to the total density of decapod larvae was not above 18%. In general, larvae of the family Upogebiidae dominated in Amursky Bay and larvae of the Callianassidae were predominant in Ussuriysky Bay. The zoeae of U. major (up to 37 ind./m³) and Nihonotrypaea makarovi (up to 46 ind./m³) were most numerous. Larvae of the family Axiidae were recorded only in very low numbers in both bays.     

Partitioning and utilization of energy during the larval development of the xanthid crab, Rhithropanopeus harrisii (Gould)

An energy budget is constructed for the larval development of the crab Rhithropanopeus harrisii (Gould) fed nauplii of the brine shrimp Artemia salina (L.). Between the first zoeal instar and the megalopa, there is a 5.4-fold increase in caloric consumption and a 13.2-fold increase in dry weight. Weight specific energy content increases through the zoeal stages and drops at the megalopa. Rate of oxygen consumption increases steadily throughout development. Assimilation, gross growth, and net growth efficiencies increase steadily through zoeal development and drop at the megalopa. Calories put into tissue production exceed those expended via respiration in zoeal stages II–IV; the reverse is true in zoeal stage I and the megalopa.

A total energy budget has been calculated and the partitioning of energy is discussed in relation to other physiological studies on this species.     

Multiple motor patterns in the stomatogastric ganglion of the shrimp Penaeus japonicus

 Motor patterns of the cardiac sac, the gastric and the pyloric network in the stomatogastric nervous system of the shrimp Penaeus japonicus, the most primitive decapod species, were studied. Single neurons can switch from the gastric or the pyloric pattern to the cardiac sac pattern. Some of the pyloric neurons fire with the gastric pattern. All of the gastric neurons fire with the pyloric pattern, unlike those in reptantians. Proctolin activates and modulates the cardiac sac and the pyloric rhythm, and promotes reconfiguration of the networks. Neurons of the three networks have so many interconnections that they construct a multifunctional neural network like those in Cancer. This network may function in different configurations under the appropriate conditions. Several modes of interactions between the networks found in different reptantian species can apply to the penaeidean shrimp. Such interactions are general features of the stomatogastric nervous system in decapods. Phylogenetic differences among the decapod infraorders are seen in the number and orientation of muscles and the innervation pattern of muscles. The multifunctional networks have existed in the most primitive decapod species, and types of configurations of the networks would have evolved to produce a wide range of motor patterns as the foregut structure has become complex. Accepted: 26 October 1999     

Morphology of the first zoeal stage of the commensal southwestern Atlantic crab Austinixa aidae (Righi 1967) (Brachyura: Pinnotheridae), hatched in the laboratory

The first zoeal stage of the endemic southern Atlantic pinnotherid crab Austinixa aidae is described and illustrated based on laboratory-hatched material from ovigerous females collected from the upper burrows of the thalassinidean shrimp Callichirus major at Ubatuba, São Paulo, Brazil. The zoeae of Austinixa species can be distinguished from other pinnotherids and especially from zoeae of the closely related species of Pinnixa by the telson structure.     

The survival and development of the shrimp Crangon crangon (L.), reared in the laboratory under non-circadian light-dark cycles

The shrimp, Crangon crangon (L.), has been reared from hatching to the late juvenile phase, under a circadian (LD 12 : 12) and two non-circadian (LD 8 : 8 and LD random) light-dark cycles. During the zoeal phase, survival in the non-circadian regimes was markedly lower than in the control circadian treatments. This effect supports the hypothesis that the entraining influence of daily environmental cycles is important in coordinating the various physiological processes within the animal. There was no evidence, however, that growth and morphological development were affected in the non-circadian regimes.     

Identification of different types of serotonin-like immunoreactive olfactory interneurons in four infraorders of decapod crustaceans

Summary An antiserum raised against serotonin (5HT) was applied to the brains of representatives of four different infraorders of decapod crustaceans, and revealed two morphological classes of olfactory interneurons. They were classified by the position and size of their cell bodies, and by their connection pattern. One class consisted of giant olfactory interneurons and the other of globuli cells. They were regarded as input and intrinsic interneurons, respectively, because of their morphology. The two classes displayed a similar pattern in two of the infraorders, whereas only one class appeared in the other two infraorders.     

Phylogenetic position,systematic status,and divergence time of the Procarididea (Crustacea: Decapoda)

Bracken, H. D., De Grave, S., Toon, A., Felder, D. L. & Crandall, K. A. (2009). Phylogenetic position, systematic status, and divergence time of the Procarididea (Crustacea: Decapoda). —Zoologica Scripta, 39, 198–212. Ever since discovery of the anchialine shrimp, Procaris ascensionis Chace & Manning 1972 , there has been debate as to its systematic position in relationship to other shrimp‐like decapods. Several morphological characters have suggested a close affinity among Procarididae, Dendrobranchiata and Stenopodidea, whereas other physical features unite Procarididae with Caridea. Few molecular studies have examined the phylogenetic position of procaridid shrimp due to limited available material for genetic analyses. Those studies show procaridids as sister to carideans but lack sufficient taxon and locus sampling to validate the relationship. Here, we present a molecular phylogeny of selected individuals across decapod infraorders and superfamilies to clarify the phylogenetic position of procaridid shrimp. One mitochondrial (16S) and three nuclear genes (18S, 28S, H3) have been chosen to elucidate relationships. We used Bayesian molecular dating methods implemented in multidivtime to estimate and compare the divergence times among procaridids and other lineages. Findings secure the placement of the procaridids as a sister clade to carideans. Results provide evidence for the recognition of procaridids as a separate infraorder (Procarididea Felgenhauer & Abele 1983 ) within the Decapoda on the basis of molecular and morphological data.     

The zoeal development of Platymaia wyvillethomsoni Miers, 1886 (Crustacea: Decapoda: Majoidea: Inachidae) described from laboratory reared material

The spider crab Platymaia wyvillethomsoni was reared in the laboratory, from hatching to the megalopal stage at 20°C. The larval development comprises two zoeal stages and a megalopa. The zoeal stages are described for the first time and compared with those of the four known species of the family Inachidae from the northern Pacific. The zoeal characters (carapace spines, antenna, mouthpart appendages, pleon and telson fork) of P. wyvillethomsoni are significantly different from those of two Achaeus species from northern Pacific and other inachid genera (Inachus and Macropodia) from the Atlantic. Therefore, this species should not be placed in the family Inachidae based on zoeal morphology. A provisional key for the identification of known zoeae of the family from the northern Pacific is provided.     

Mitogenomic analysis of decapod crustacean phylogeny corroborates traditional views on their relationships

Phylogenetic relationships within decapod crustaceans are highly controversial. Even recent analyses based on molecular datasets have shown largely contradictory results. Previous studies using mitochondrial genomes are promising but suffer from a poor and unbalanced taxon sampling. To fill these gaps we sequenced the (nearly) complete mitochondrial genomes of 13 decapod species: Stenopus hispidus, Polycheles typhlops, Panulirus versicolor, Scyllarides latus, Enoplometopus occidentalis, Homarus gammarus, Procambarus fallax f. virginalis, Upogebia major, Neaxius acanthus, Calocaris macandreae, Corallianassa coutierei, Cryptolithodes sitchensis, Neopetrolisthes maculatus, and add that of Dromia personata. Our new data allow for comprehensive analyses of decapod phylogeny using the mitochondrial genomes of 50 species covering all major taxa of the Decapoda. Five species of Stomatopoda and one species of Euphausiacea serve as outgroups. Most of our analyses using Maximum Likelihood (ML) and Bayesian inference (BI) of nucleotide and amino acid datasets revealed congruent topologies for higher level decapod relationships: (((((((Anomala, Brachyura), Thalassinida: Gebiidea), Thalassinida: Axiidea), (Astacidea, Polychelida), Achelata), Stenopodidea), Caridea), Dendrobranchiata). This result corroborates several traditional morphological views and adds new perspectives. In particular, the position of Polychelida is surprising. Nevertheless, some problems can be identified. In a minority of analyses the basal branching of Reptantia is not fully resolved, Thalassinida are monophyletic; Polychelida are the sister group to Achelata, and Stenopodidea are resolved as sister group to Caridea. Despite this and although some nodal supports are low in our phylogenetic trees, we think that the largely stable topology of the trees regardless of different types of analyses suggests that mitochondrial genomes show good potential to resolve the relationship within Decapoda.     

Studies on the larval development of northeastern Atlantic and Mediterranean Procellanidae (Decapoda,Anomura). I — Redescription of the larval stages ofPorcellana platycheles (Pennant, 1777) reared under laboratory conditions

The complete larval development is described forPorcellana platycheles (Pennant) reared under laboratory conditions. The development consists of two zoeal stages and one megalopa. At 20°C and 35‰ salinity, the megalopa appeared 17–18 days after hatching. Survival was 56% from hatching to the megalopa stage. The morphological features of the zoeal and megalopa stages ofP. platycheles are compared with those of other species ofPorcellana, and a key of the known zoeal stages of the genus is given.     

The evolutionary significance of heterochrony in the abbreviated zoeal development of pilumnine crabs (Crustacea: Brachyura: Xanthoidea)

The zoeal development of Pilumnus hirtellus (Linnaeus, 1761) is redescribed and the four stages are compared with the abbreviated development of Actumnus setifer (de Haan, 1835) with three stages, and Pilumnus sluiteri De Man, 1892 with two stages. A number of characters are not affected by abbreviated zoeal development and do not change during successive stage moults. Of these, some traits remain conservative at higher taxonomic level, whereas others varied between closely related pilumnid taxa, but neither provided phylogenetic information within the three pilumnines studied. However, abbreviated zoeal development affected 23 pilumnine characters that change with successive stage moults. Their timing of appearance and rate of development occur at different stages relative to the homologous process in an ancestral sequence with more zoeas, and can be attributed to three heterochronic mechanisms; postdisplacement, predisplacement and acceleration. These processes collectively appear to provide the predominant mechanism underlying the evolution of oligomerization within pilumnine zoeas.  © 2005 The Linnean Society of London, Zoological Journal of the Linnean Society , 2005, 143 , 417–446.     

Cytogenetics of the true bug infraorder Cimicomorpha (Hemiptera, Heteroptera): a review

The Cimicomorpha is one of the largest and highly diversified infraorders of the Heteroptera. This group is also highly diversified cytogenetically and demonstrates a number of unusual cytogenetic characters such as holokinetic chromosomes; m-chromosomes; multiple sex chromosome systems; post-reduction of sex chromosomes in meiosis; variation in the presence/absence of chiasmata in spermatogenesis; different types of achiasmate meiosis. We present here a review of essential cytogenetic characters of the Cimicomorpha and outline the chief objectives and goals of future investigations in the field.     

Infection of adult migratory river shrimps,Macrobrachium ohione,by the branchial bopyrid isopod Probopyrus pandalicola

Abstract. Macrobrachium ohione is a migratory (amphidromous) river shrimp (Decapoda, Caridea) that may be parasitized by the branchial parasite Probopyrus pandalicola (Isopoda, Bopyridae). The parasite disrupts gonadal maturation and spawning in female shrimps, resulting in the total loss of reproduction. Shrimps are usually infected by bopyrid parasites during the late zoeal or early postlarval stages; in this study, we investigated the apparent parasite infection of adult shrimps. We analyzed the relationships between parasite body size (total length) and host shrimp body size (carapace length) to test the hypothesis that parasite infection of adult shrimps occurs during the shrimps' reproductive migrations. The results presented here indicate that infection of adult shrimps is common in M. ohione in the Atchafalaya and Mississippi Rivers, Louisiana, USA. In the two upriver sites sampled, Butte La Rose (BLR) and River Bend (RB), parasite size was not associated with host body size. In these locations, many parasitized adult M. ohione were infected with immature P. pandalicola (40.3% in BLR and 51.2% in RB), indicating that the shrimps were adults at the time of infection. A possible explanation is that when female shrimps enter the estuary to hatch larvae, they molt and spawn another brood. The smaller male shrimps that accompany the females downstream are also assumed to molt and continue growth. The intermediate host of the parasite is an estuarine copepod, and thus the parasite cryptoniscus larva that infects the host shrimp is primarily estuarine as well. Newly molted shrimps have soft cuticles, which may facilitate their infection by parasite cryptonisci. Our conclusion is that most infections of adult shrimps occur during their migration into estuarine waters, the primary habitat of infective parasite larvae, and that host vulnerability is probably increased following host ecdysis.     

Distribution of decapod larvae in the surface layer of an isolated equatorial oceanic archipelago: the cases of benthic Grapsus grapsus (Brachyura: Grapsidae) and pelagic Sergestes edwardsi (Dendrobranchiata: Sergestidae)

Two different decapod larval assemblages inhabit the marine environment of Saint Paul’s Rocks, differentiating the inlet from the surrounding oceanic waters. Larvae of the crab Grapsus grapsus and of the holopelagic shrimp Sergestes edwardsi are abundant in superficial waters of the archipelago and have previously been shown to be good indicators of the inlet and adjacent oceanic waters, respectively. We investigated the horizontal, diel and temporal distribution of these species at Saint Paul’s Rocks. Horizontal surface hauls were conducted from 2003 to 2005, in the inlet and at four increasing distances from the archipelago, in the morning and at night, using a 200-μm mesh net. Larvae of G. grapsus were identified in samples from all expeditions and abundance was found significantly higher at night in the inlet site. Only larvae in the first zoeal stage were found in samples, highlighting the importance of the area for this species reproduction. On the contrary, the distribution of larvae of S. edwardsi was typical of a holopelagic species, which are permanent residents of the water column and spawn in oceanic areas, indicating that the islands are of little influence to them.     

A comparative study of zoeal morphology in the genus Liocarcinus (Crustacea: Brachyura: Portunidae)

The zoeal morphology of Liocarcinus arcuatus, L. corrugatus and L. depurator is described from laboratory reared material and the larvae of L. holsatus, L. puber, L. pusillus and L. marmoreus are reexamined from specimens deposited in the BM (NH). No single meristic character was found that would adequately separate the seven described species of Liocarcinus. Characters that may facilitate separation of later zoeal stages only are listed.     

Occurrence of additional Zoea-VI larvae in the mud crab, Scylla paramamosain (Estampador), reared in the laboratory

Mud crabs, Scylla spp. , are commercially important in many Indo-Pacific countries. The larval development of mud crabs has been reported previously as five zoeal and one megalopal stages. This paper reports larval rearing experiments that revealed variability in larval developmental stages in the mud crab Scylla paramamosain, one of four mud crab species. In addition to normal five zoeal stages, an alternative pathway of developing through six zoeal stages was observed for the crab. There were evidences suggested that the appearance of the additional Zoea-VI larvae was associated with unfavourable dietary conditions, including poor quality of diet, inadequate quantity of dietary supply and a period of starvation for newly hatched larvae. Based on exuviae and larval specimens, the morphology of the additional Zoea-VI larvae was described.     

Decapod Crustacea from the International Indian Ocean Expedition: the larval development of Heterocarpus (Caridea)

The larval species Atlantocaris gigas Ortmann is shown to be conspecific with Heterocarpus ensifer A. Milne Edwards, while Procletes biangulatus Bate is the larva of Heterocarpus levicarina (Bate). Each species passes through 13–15 zoeal stages and 3–4 megalopal stages. The later zoeal stages are large, have a long toothed rostrum, a carinated carapace and dorsal abdominal spines. The carinae on the carapace are retained in the adult; the rostrum becomes shortened and the abdominal spines modified at metamorphosis. Larval characters support the retention of Heterocarpus in the Pandalidae.
New information on the distribution of both species is included.