Aspects of the biology of the plerocercoid of Grillotia erinaceus (van Beneden, 1858) (Cestoda: Trypanorhyncha) in haddock Melanogrammus aeglefinus (L.)

From one to thirty Grillotia erinaceus plerocercoids were found in 3714 of 8228 haddock Melanogrammus aeglefinus caught in the northern North Sea, to the north and west of Scotland and at Faroe. Plerocercoids were also found in 30 of 64 cod from Aberdeen Bay, and in 44 of 55 saithe from the Firth of Clyde. In haddock, most plerocercoids occurred encysted along the intestine, and their frequency fitted a negative binomial distribution. Incidence and intensity of infestation increased with host age and there was no host sex difference in incidence. Three maturity stages were recognized, the proportions of which were consistent between haddock length groups. No precipitin bands developed in gel diffusion tests using live plerocercoids and sera from infested and uninfested haddock. Attempts to transfer plerocercoids between haddock were unsuccessful. Speculations are made on the possible course of the life-cycle.     

Redescription of Diesingium lomentaceum (Diesing, 1850) (Cestoda: Trypanorhyncha)

Ardeirhynchus spiralis (Rudolphi, 1809) n. g., n. comb. (syns Echinorhynchus spiralis, Prosthorhynchus spiralis and Plagiorhynchus spiralis), a parasite of herons (Ciconiiformes: Ardeidae), is redescribed on the basis of the holotype from Ixobrychus minutus and specimens from Ardeola ralloides (new host record) in Bulgaria. A. spiralis is a member of the family Polymorphidae and not of the Plagiorhynchidae in which it was previously classified. Ardeirhynchus n. g. is distinguished from the most morphologically similar genus, Arhythmorhynchus Lühe, 1911, by the position of the male genital system, which occupies the posterior 1/8-1/6 part of the trunk, the distribution of hypodermal nuclei in groups in the anterior part and in lateral rows along the length of the posterior part of the trunk, a considerably shorter neck, minute trunk spines and a terminal genital pore.     

Morphological and quantitative aspects of nodule formation in hemolymph of the blowfly Chrysomya megacephala (Fabricius, 1794)

Insects manifest effective immune responses that include both cellular and humoral components. Morphological and quantitative aspects of cellular and humoral cooperation during nodule formation in Chrysomya megacephala hemolymph against Saccharomyces cerevisae yeast cells were demonstrated for the first time. The analyses were performed in non-injected larvae (NIL), saline-injected larvae (SIL) and yeast-injected larvae (YIL). The hemolymph of injected groups was collected 0.5, 1, 2, 4, 12, 24, 36, or 48-h post-injection. Morphological aspects of YIL nodulation were investigated using transmission electron microscopy (TEM). Quantitative analyses consisted of total (THC) and differential hemocyte counts (DHC) in all the groups and total yeast count (TYC) in YIL, which were performed in an improved Neubauer chamber. Nodule formation was initiated at approximately 2-h post-injection. Twelve hours after the injection, TEM revealed the presence of an amorphous membrane, at the same time that circulating hemocyte number decreased significantly contrasting the increase of yeast number. Our results showed the ability of C. megacephala hemolymph to perform humoral encapsulation when hemocyte population is insufficient to eliminate the microorganisms, warranting consideration in future investigations on the relative roles played by cellular and humoral elements of innate immunity of this calliphorid.     

Long-term changes in the prevalence of two helminth parasites (Cestoda: Trypanorhyncha) infecting marine fish

Changes in prevalence of the plerocerci of Grillotia angeli Dollfus, 1969 in mackerel, Scomber scombrus L., and of Lacistorhynchus sp. in herring, Clupea harengus L., were recorded over periods of eight years (1978–1985) and 11 years (1974–1984), respectively. Data were collected from 21 year classes of mackerel in an area to the south-west of Britain and Ireland and from seven year classes of herring in the eastern North Sea. Both sets of data showed sharp decreases in parasite prevalence from periods at relatively high levels to others at much lower levels. The changes in prevalence occurred at the same time in both host-parasite systems and coincided with the end of the hydrographic phenomenon known as the mid-70s salinity anomaly. Possible explanations for the changes which are discussed include changes in abundance of first intermediate and definitive hosts, variations in host year class strength, changes in hydrographic conditions and changes in host diet.     

Fine structure of glial cells in the central nervous system of the tapeworm Grillotia erinaceus (Cestoda: Trypanorhyncha)

The problem of glial cells existing in parasitic and free living flatworms is correlated with organization of parenchyma in platyhelmintes. In the contrary to the widespread opinion that myelin-like envelopes and glial cells do not exist in the nervous system of parasitic flatworms, it has been shown by ultrastructural researches that Amphilina foliacea (Cestoda, Amphilinidea) has well developed glial cells and myelin-like envelopes in the ganglia and main cords, which include both glial cells and intercellular components. The aim of our research was to reveal and investigate in details structural components corresponding to the concept of the glial cell in the CNS of Grillotia erinaceus (Cestoda: Trypanorhyncha). Three types of glial cells have been found. The first type is the fibroblast-like glial cells; cells locate in the cerebral ganglion, contain in cytoplasm and extract out fibrillar matrix, form desmosomes and have supporting function. The glial cells of the second type form myeline-like envelope of the giant axons and bulbar nerves in scolex and have laminar cytoplasm. These cells are numerous and exceed in number the neurons bodies into the nerve. The glial cells of the third type form multilayer envelopes in the main nerve cords; extra cellular fibers and gap-junctions take place between the layers. There are contacts between the glial cells of the third type and excretory epithelium but specialized contacts with neurons have been not found. The existing of glial cells in free living and parasitic flatworms is discussed.     

Prochristianella spinulifera n. sp. (Cestoda: Trypanorhyncha) from Australian dasyatid and rhinobatid rays

Prochristianella spinulifera n. sp. (Cestoda: Trypanorhyncha: Eutetrarhynchidae) is described from the spiral valves of the rays Rhinobatos typus (Rhinobatidae) and Himantura fai (Dasyatidae) from Heron Island, Queensland, Australia. The new species is distinguished from all congeners by the deltoid microtriches covering the anterior 80% of the scolex and the presence of a dorsoventrally elongate genital atrium. The species occurred in the anteriormost section of the spiral valve of R. typus. The orientation of the armature of this and other congeners is such that principal rows of hooks begin on the bothridial surface of the tentacle and end on the antibothridial surface.     

Some aspects of the reproductive biology of Acanthopagrus spp. (Family: Sparidae)

Changes in the seasonal development of the gonads in Acanthopagrus latus and A. cuvieri over an annual reproductive cycle are described. There is one major spawning period from January to March. Hermaphrodite A. latus and A. cuvieri constituted 5.8% and 5.7% of the total sample respectively. The histological changes in the ovary, testis and ovo-testis in both species are described. Fecundity estimates for A. latus , 27.5–31.8 cm, ranged from 1 362 137 to 2 152 993, and estimates for A. cuvieri , 47.1–63.5 cm, ranged from 308 273 to 1 693 365.     

Two new species of Aporhynchus (Cestoda: Trypanorhyncha) from deep water lanternsharks (Squaliformes: Etmopteridae) in the Azores, Portugal

New collections of cestodes from the spiral intestines of the lanternsharks Etmopterus spinax and Etmopterus pusillus off the island of Faial, in the Azores, Atlantic Ocean, have yielded 2 new species of trypanorhynchs belonging to Aporhynchus. Both species share the distinctive lack of all elements of the rhyncheal system that are characteristic of this genus. The identity of Aporhynchus norvegicus is clarified to allow it to be distinguished from A. menezesi n. sp., which also parasitizes E. spinax. This new species differs conspicuously from its congeners in that its mature and gravid proglottids are wider than long, rather than longer than wide, and also in its lack of spinitriches on the scolex. Aporhynchus pickeringae n. sp., the new species from E. pusillus , differs from all of its congeners except A. norvegicus in that it is a relatively delicate worm with relatively fewer testes. It also possesses fewer proglottids and a wider pedunculus scolecis than does A. norvegicus. Sections through the scolex of A. menezesi n. sp. support use of the term bothriate, rather than difossate, in reference to the scolex configuration of some trypanorhynchs. A key to the 4 species of Aporhynchus is provided.     

A new genus and two new species of Aporhynchidae (Cestoda: Trypanorhyncha) from catsharks (Carcharhiniformes: Scyliorhinidae) off Taiwan

New collections of cestodes from the spiral intestines of catsharks (Carcharhiniformes: Scyliorhinidae) off Taiwan have led to the discovery of a new genus and 2 new species of trypanorhynchs. These taxa are relatively unique among trypanorhynchs in their lack of all elements of the rhyncheal apparatus. The new genus, Nakayacestus n. gen., is considered to belong with Aporhynchus in the Aporhynchidae. In addition to lacking the rhyncheal apparatus, these 2 genera share circum-medullary vitelline follicles, post-ovarian testes, and complex terminal genitalia consisting of accessory, external, and internal seminal vesicles. The 2 genera differ conspicuously in spinithrix configuration; whereas both species of Nakayacestus n. gen. bear scolex spinitriches that are bifid, trifid, or pectinate, species of Aporhynchus either lack scolex spinitriches entirely or possess spathulate spinitriches. The configuration of the bothria of the 2 genera also differ conspicuously. Whereas the bothria of Aporhynchus are sessile and generally do not extend beyond the lateral margins of the cephalic peduncle, those of Nakayacestus bear only a tenuous connection with the scolex proper, being conspicuously free both anteriorly and posteriorly and extending conspicuously beyond the cephalic peduncle. Futhermore, the boundary between the scolex and the strobila of members of the new genus is clearly delineated, whereas this distinction is ill-defined in species of Aporhynchus. Nakayacestus takahashii n. sp., the type of the new genus, was collected from the Broadmouth catshark, Apristurus macrostomus, and differs from Nakayacestus tanyderus n. sp., collected from the Blacktip sawtail catshark, Galeus sauteri, in being shorter, bearing a longer pedunculus scolecis, an ovary that is more posterior in the proglottid, and fewer post-ovarian testes. Furthermore, the 2 new species differ conspicuously from one another in the configuration of their scolex spinitriches.     

Some aspects of the biology and population dynamics of Nasonia vitripennis (Walker) (Hymenoptera: Pteromalidae)

Some aspects of the biology and population dynamics of the chalcid Nasonia vitripennis (Walker) are described.The reproduction capacity and the influence of size and age of the females have been studied, using Calliphora erythrocephala Meig. as the host. The females lay a maximum number of about 30 eggs into one host puparium. Fully parasitized puparia are recognized by females as such. This seems to be the major factor in the determination of the area searched for hosts.Changes in sex ratio of the offspring, in relation to the age and the density of the females are described. Also an influence of the age of the females on the number of offspring entering diapause is reported.

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Zusammenfassung Die beschriebenen Experimente zeigen, dass die Eiproduktion von Nasonia vitripennis in grossem Ausmasse durch das Alter des Muttertieres bedingt ist. Insbesondere während der ersten 4 Tage nach dem Schlüpfen steigt die Produktion schnell von sehr wenig bis zu etwa 100 Eiern pro Tag an (Wirt: Calliphora erythrocephala Meig.). Diese Produktion bleibt einige Tage konstant und nimmt dann langsam ab. Obwohl die individuelle Produktion sehr variabel ist, konnte eine positive Korrelation zwischen der Grösse des Tieres und der Anzahl seiner Nachkommen nachgewiesen werden.Wenn ein Teil der vorhandenen Wirte durch Austrocknen unbrauchbar geworden ist, tritt eine Reduktion der Eiablage auf. Diese Reduktion ist nicht eine Folge von Zeitmangel (verursacht durch das Inspizieren unbrauchbare Wirte), sondern entsteht durch die beschränkte Eiablage-Möglichkeit in einen Wirt. Die Weibchen passen ihre Eiablage der Anzahl der verfügbaren Wirte an. Im Mittel werden die wirte mit nicht mehr als rund 30 Eiern belegt. Eine Reduktion der Nachkommenschaft durch Futterkonkurrenz zwischen den Larven findet nicht statt.Ein Einfluss des Alters der Weibchen auf das Verhältnis der Geschlechter ihrer Nachkommen wird nachgewiesen. Das gefundene Verhältnis (10–15% Männchen) entspricht nicht dem Mechanismus, der von King (1961) für die Berfruchtung vorgeschlagen wird.Durch Mangel an Wirten wird die Anzahl abzulegender Eier reduziert. Eiresorption und damit Steigerung des Anteils der Männchen in der Nachkommenschaft ist die Folge; die ersten Resorptionsstadien werden bei der Eiablage nicht befruchtet, wodurch Männchen entstehen. Die Dichte der Wirte hat also einen Einfluss auf das Geschlechtsverhältnis.Ein dritter Einfluss des Alters der Weibchen besteht in einer Zunahme des Prozentsatzes von Diapauselarven. Bei älteren Weibchen wird eine rasche Änderung von normaler Nachkommenschaft in eine fast nur Diapauselarven umfassende nachgewiesen. Diese Änderung ist nicht die Folge von Futtermangel oder Abkühlung.Die Suchaktivität des Parasiten wird zum grössten Teil durch die Wirtsdichte bedingt. Nasonia-Weibchen bleiben in der Nähe eines Wirtes, bis dieser fast vollständig ausgenutzt ist. Die Weibchen können parasitierte und nichtparasitierte Wirte voneinander unterscheiden und nehmen bei ihrer Suche den ersten freien Wirt an, den sie finden. Dadurch wird die Grösse ihres Wandergebietes durch die Populationsdichte des Wirtes bedingt. Eine zwangsläufige Regulation der Dichte von Wirt und Parasit ist damit aber nicht ausgeschlossen.