Structure and occurrence of cyphonautes larvae (bryozoa,ectoprocta)

We have studied larvae of the freshwater ctenostome Hislopia malayensis with scanning electron microscopy (SEM), confocal laser scanning microscopy (CLSM), and LM of serial sections. Some additional observations on larvae of M. membranacea using SEM and CLSM are also reported. The overall configuration of muscles, nerves, and cilia of the two larvae are identical. However, the larva of H. malayensis is much smaller than that of M. membranacea, which may explain most of the differences observed. Although all major nerves and muscle strands are present in H. malayensis, they are generally composed of fewer fibers. The H. malayensis larva lacks the anterior and posterior intervalve cilia. Its pyriform organ is unciliated with only a small central depression. The adhesive epithelium is not invaginated as an adhesive sac and lacks the large muscles interpreted as adhesive sac muscles in the M. membranacea larva. The velum carries two rows of ciliated cells, though the lower “row” consists of only one or two cells. Both rows of ciliated cells are innervated by nerves, which have not been detected in the M. membranacea larva. The ciliated ridge of H. malayensis lacks the frontal cilia. The planktotrophic cyphonautes larvae in a number of ctenostome clades and in the “basal” cheilostome clade Malacostega (and probably in the earliest cheilostomes) support the idea that the cyphonautes larva is the ancestral larval type of the Eurystomata. It may even represent the ancestral larval type of the bryozoans (= ectoprocts). J. Morphol. 271:1094‐1109, 2010. © 2010 Wiley‐Liss, Inc.     

Pathogenicity,reproduction and foraging behaviours of some entomopathogenic nematodes on a new turf pest,Dorcadion pseudopreissi (Coleoptera: Cerambycidae)

Entomopathogenic nematodes (EPNs) in the families Heterorhabditidae and Steinernematidae have considerable potential as biological control agents of soil-inhabiting insect pests. In the present study, the control potential of the EPNs Steinernema carpocapsae (TUR-S4), S. feltiae (Nemaplus), S. carpocapsae (Nemastar), S. feltiae (TUR-S3) and Heterorhabditis bacteriophora (Nematop) against a new longicorn pest, Dorcadion pseudopreissi Breuning, 1962 (Coleoptera: Cerambycidae), on turf was examined in laboratory studies. Pathogenicity tests were performed at the following doses: 50, 100 and 150 Dauer Juveniles (DJs)/larva at 25°C. Highest mortalities (75–92%) of the larvae were detected at the dose of 150 DJs/larva for all nematodes used. Reproduction capabilities of the used EPNs were examined at doses of 50, 75, 100 and 150 DJs/larva at 25°C. S. carpocapsae (TUR-S4) had the most invasions (32 DJs/larva) and reproduction (28042 DJs/larva) at the dose of 100 DJs, and the highest reproduction (per invaded DJ into a larva) was observed in H. bacteriophora (Nematop) (2402.85 DJs) at a dose of 50 DJs. The foraging behaviour of the nematodes in the presence of D. pseudopreissi and Galleria mellonella L. (Lepidoptera: Galleriidae) larvae was studied using a Petri dish filled with sand at 20°C. All of the used nematodes accumulated near the larvae section of both insect species (32–53% of recovered DJs) with a higher percentage of S. carpocapsae (TUR-S4) (53%) and H. bacteriophora (48%) (Nematop) moving towards larvae of D. pseudopreissi, than the S. feltiae strains.     

The Larva of Hydropsyche tabacarui Botosaneanu, 1960 (Trichoptera: Hydropsychidae), Including a Re-description of the Female

The larva of Hydropsyche tabacarui Botosaneanu, 1960 is described and compared with the morphologically very similar larva of H. tibialis McLachlan, 1884. Information for the identification of both species is given and some zoogeographical and ecological notes are presented. In addition, the female of H. tabacarui is re-described.     

An unusual macrourid larva (Gadiformes) from San Juan Island, Washington, USA

An unusual macrourid larva was collected in Friday Harbor, San Juan Island, Washington, USA. This specimen is remarkable in appearance having very long anterior dorsal- and pelvic-fin rays, with flattened distal ends free of the fin membrane, and a long, whiplike, heavily pigmented caudal filament. It is similar to smaller Coryphaenoides pectoralis larvae reported from the California Current region, and different from larger specimens of C. pectoralis from the northern North Pacific. Counts and other morphological similarities suggest that this larva should be tentatively assigned to genus Coryphaenoides.     

The larval morphology and systematics of the leaf-beetles <Emphasis Type="Italic">Altica deserticola</Emphasis> and <Emphasis Type="Italic">Altica engstroemi</Emphasis> (Coleoptera,Chrysomelidae)

The elder-instar larva of Altica deserticola is described for the first time, and the last-instar larva of A. engstroemi is re-described. The diagnostic characters are included. The former species develops on Glycyrrhiza, and the latter one, on Filipendula ulmaria. Some questions on the general morphology of the larvae of Altica are discussed.     

Effect of parasitism byAscogaster reticulatus [Hym.: Braconidae] on growth of the host,Adoxophyes sp. [Lep.: Tortricidae]

The developmental interaction between the egg/larval parasitoid,Ascogaster reticulatus Watanabe (Hymenoptera: Braconidae) and its host,Adoxophyes sp. (Lepidoptera: Tortricidae) was examined. Prior to the egress of a final-instar parasitoid larva from the 4^th-instar host larva, host weight decreased by 22% from the maximum weight. The final body weight of a host larva was 27% of the maximum weight of a healthy 5^th-instar host. Food consumption was significantly reduced in both 3^rd-and 4^th-instar parasitized larvae compared with healthy ones. In the 4^th instar, a parasitized larva consumed 28% less artificial diet and produced less frass than a healthy larva. The growth rate of the endoparasitoid larvae greatly increased after their host's molt to the 4^th instar. Parasitoid larval volume increased 40 fold in the 4^th-instar host.      

Larval morphometry of the Japanese flounder,Paralichthys olivaceus

The larval development of the Japanese flounder,Paralichthys olivaceus, was surveyed using two types of morphometric analyses, modified allometry and polar coordinate analysis by principal component analysis (PCA). In the former, centroid size was used as a growth index instead of total length (TL), such enabling the determination of more detailed changes in each character than ordinary allometry based upon TL. Polar coordinate analysis disclosed two remarkable inflexions during the larval development ofP. olivaceus. Postlarvae ofP. olivaceus were found to undergo four developmental phases. From the point of view of metamorphosis, the phases were named drifting larva, premetamorphic larva, metamorphic larva and postmetamorphic larva, respectively. These phases were also tested by other characters related to flounder metamorphosis.     

Le filet-piège de la larve de Plectrocnemia conspersa (Trichopteres,Polycentropodidae)

Summary The catching-net of P. conspersa larva was studies with particular reference to: structure, building, larval activity inside it and its function in prey catching.The microscopic and macroscopic structure of this catching-net is similar to that Neureclipsis larvae, with an open-ended tunnel and two funnel shaped openings, but its shape is less regular.The building of this net lasts about four to six hours. After a wandering period, the larva first builds the open-ended tunnel and the two openings.Most of the time, the larva lives inside the open-ended tunnel, but it can also crawl into the entrances. Its activity does seem to be related to a diel periodicity.During the catching process, the chief function of the net is detection, after which the prey is taken in the same way as in a spider's web.     

Taxonomic notes on Neophylax koizumii (Iwata 1927) (Trichoptera, Uenoidae) from Japan

We re-examined the type series material of Apatania koizumii Iwata and designated a lectotype and a paralectotype. We transferred Apatania koizumii to the genus Neophylax based on the morphological characters of the larvae. We redescribed the larva of Neophylax koizumii and its case and provided some ecological notes and the geographical distribution. We also examined the larvae used to describe Neophylax sp. NA (sensu Tanida 1985) and found that those belonged to Neophylax koizumii. On the other hand, the larva of Neophylax sp. NA designated by Akagi (1962) is clearly different from that of Neophylax koizumii in characters of the ventral sclerites on the meta-thorax and abdominal segment I. Received: September 6, 1999 / Accepted: February 20, 2000     

Larval development in <Emphasis Type="Italic">Guancha arnesenae</Emphasis> (Porifera,Calcispongiae, Calcinea)

Larval development and follicle structure of a representative of the Calcinea (Calcispongiae) Guancha arnesenae from the White Sea have been studied for the first time at the ultrastructural level. The follicle in G. arnesenae has an unusual structure: it consists of trapezoid cells rich in phagosomes and a surrounding dense collagen layer. Follicular cells differentiate from choanocytes. Cleavage results in formation of a hollow, equal, non-polarized coeloblastula. Larval morphogenesis occurs by means of direct hollow blastula formation without any individual cell or cell layer movements. The coeloblastula (calciblastula) larva of G. arnesenae is completely ciliated. The larva also contains rare non-ciliated cells: vacuolar cells, bottle-shaped cells and free cells in a central cavity. The basal ciliary apparatus of larval cells includes the basal body, an accessory centriole oriented perpendicularly to it, the basal foot, and two cross-striated rootlets. A bundle of microtubules emerges from the side of the basal body, opposite to the basal foot, running parallel to the outer surface. All bundles of cells are parallel to each other and oriented towards the posterior larval pole, forming a transverse cytoskeletal system. Specialized intercellular junctions in the apical regions of all ciliated cells are revealed for the first time in a Calcispongiae larva. The central larval cavity contains symbiotic bacteria, which are included inside the embryo at the blastula stage.     

Notes on the New Zealand antlion,Weeleus acutus (Neuroptera)

Abstract

The New Zealand antlion, Weeleus acutus (Walker), is redescribed and its relationships are discussed. Notes on the larva are given.     

Early Stages and Biology of Melitaea robertsi Butler, 1880 (Lepidoptera,Nymphalidae)

The external morphology of the egg (including the chorion), the last instar larva, and the pupa of Melitaea robertsi Butler, 1880 from East Iran is described; data on the host plant of the species are given.

     

New diagnosis for genus Austrothaumalea,and redescription of A. neozealandica (Diptera: Thaumaleidae)

Abstract

A new diagnosis of Austrothaumalea Tonnoir is given. The male and female of A. neozealandica are redescribed, and the larva and pupa are described for the first time.     

Insecticidal and feeding deterrent activities of essential oils in the cabbage looper,Trichoplusia ni (Lepidoptera: Noctuidae)

Ten essential oils were tested against the cabbage looper, Trichoplusia ni larvae for contact, residual and fumigant toxicities and feeding deterrent effects. Against third instar T. ni, Syzygium aromaticum (LD₅₀ = 47.8 μg/larva), Thymus vulgaris (LD₅₀ = 52.0 μg/larva) (the two positive controls) and Cinnamomum glanduliferum (LD₅₀ = 76.0 μg/larva) were the most toxic via topical application. Litsea pungens (LD₅₀ = 87.1 μg/larva), Ilex purpurea (LD₅₀ = 94.0 μg/larva), Cinnamomum cassia (LD₅₀ = 101.5 μg/larva) and Litsea cubeba (LD₅₀ = 112.4 μg/larva) oils were equitoxic. Thymus vulgaris (LC₅₀ = 4.8 mg/ml) and S. aromaticum (LC₅₀ = 6.0 mg/ml) oils were the most toxic in residual bioassays. Cymbopogon citratus (LC₅₀ = 7.7 mg/ml) and C. cassia (LC₅₀ = 8.5 mg/ml) oils were equitoxic followed by Cymbopogon nardus (LC₅₀ = 10.1 mg/ml) in this bioassay. The remaining five oils showed little or no residual effects. In a fumigation bioassay, L. cubeba (LC₅₀ = 16.5 μl/l) and I. purpurea (LC₅₀ = 22.2 μl/l) oils were the most toxic. Cinnamomum glanduliferum (LC₅₀ = 29.7 μl/l) and Sabina vulgaris (LC₅₀ = 31.2 μl/l) oils were equitoxic. Interestingly, S. aromaticum did not exhibit any fumigant toxicity. Cymbopogon citratus, C. nardus and C. cassia strongly deterred feeding by third instar T. ni (DC₅₀s = 26.9, 33.8 and 39.6 μg/cm², respectively) in a leaf disc choice bioassay. The different responses of T. ni larvae to the oils in different bioassays suggest that these essential oils exhibit different modes of action. Based on their comparable efficacy with essential oils already used as active ingredients in many commercial insecticides (i.e. clove oil and thyme oil), some of these essential oils may have potential as botanical insecticides against T. ni.     

Predation of the apefly,Spalgis epius (Lepidoptera: Lycaenidae) on citrus mealybug,Planococcus citri (Hemiptera: Pseudococcidae)

The citrus mealybug, Planococcus citri (Risso) (Hemiptera: Pseudococcidae) is a serious pest of economically important crops worldwide. The apefly, Spalgis epius (Westwood) (Lepidoptera: Lycaenidae) is a potential predator of various species of mealybugs. Earlier investigation on its daily preying capacity and preference for prey stages on P. citri is incomplete. Hence, a study was conducted to find out the daily prey consumption ability and preference for prey stages by different larval instars of S. epius reared on P. citri in the laboratory. Through the 8-day developmental period with four larval instars, the daily prey consumption of S. epius increased from the first to the seventh day and decreased on the eighth day prior to the prepupal stage. Generally, there was a significant difference in the prey consumption on different days. When the prey stages were offered separately, the first to fourth instar larva of S. epius consumed, respectively, a mean of 199.6, 722.6, 1908.8, and 4625.6 eggs or 21.5, 77.0, 168.5, and 670.5 nymphs or 3.2, 7.2, 16.0, and 35.1 adults of P. citri. When an S. epius larva was fed on P. citri eggs, nymphs and adults separately, it consumed a mean of 7456.7 eggs, 937.6 nymphs, or 62.3 adults during its entire development. When the prey stages were offered all together, a single S. epius larva consumed 2618.4 eggs, 170.4 nymphs, and 39.7 adults of P. citri throughout its entire development. The study revealed that S. epius is a voracious predator of P. citri and thus could be utilized as a major biological control agent.     

Midgut proteinase activities of three keratinolytic larvae,Hofmannophila pseudospretella,Tineola bisselliella,and Anthrenocerus australis,and the effect of proteinase inhibitors on proteolysis

The midgut proteinase activities were characterized from the keratinolytic larvae of two lepidopterans, Hofmannophila pseudospretella (Stainton) (Oecophoridae) and Tineola bisselliella (Hummel) (Tineidae), and one coleopteran, Anthrenocerus australis (Hope) (Dermestidae). The major endopeptidase activities, characterized using specific enzyme inhibitors, were serine proteinases with hydrolytic activity against N-benzoyl-DL-arginine-p-nitroanilide and against N-succinyl-L-alanyl-L-alanyl-L-prolyl-L-leucine-p-nitroanilide. No significant levels of metalloendopeptidase or cysteine endopeptidase activities were detected. Aminopeptidase activity was present in all larvae. The enzyme levels and properties of the two moth larvae were similar to each other and to those of phytophagous lepidopteran larvae but different from those of the beetle larva. Whereas only a limited number of serine proteinase inhibitors inhibited the midgut proteolysis of the lepidopteran larvae, most inhibitors inhibited the midgut proteolysis of the beetle larva. © 1994 Wiley-Liss, Inc.     

Lecithotrophic development and metamorphosis in the Indo-West Pacific brittle star Ophiomastix venosa (Echinodermata: Ophiuroidea)

Summary

The larval development of the ophiocomid ophiuroid Ophiomastix venosais described using SEM. The gastrula transforms into a uniformly ciliated early larva which progressively changes into a lecithotrophic late premetamorphic larva with a continuous bilateral ciliated band. This stage is short-lived and equivalent to a highly reduced ophiopluteus. Comparisons between O. venosa and other ophiuroid species whose development has been investigated suggest that, whatever the developmental mode (lecithotrophic or planktotrophic), a pluteus stage always occurs in ophiuroids with planktonic development. Two metamorphic stages were identified, the late metamorphic larva differing from the early one by the closure of the larval mouth. The appearance of the permanent mouth marks the end of the metamorphosis. The postlarva still possesses remnants of larval features. The transformation of the reduced ophiopluteus into a barrel-shaped metamorphic larva with transverse ciliated bands, a vitellaria larva, is followed. The possible occurrence of a unique type of metamorphic larva in non-brooding ophiuroids is discussed. Verification of this, however, needs further SEM investigations on metamorphic larva from species having “regular” planktotrophic development.     

The larva of Rhyacophila loxias Schmid, 1970 (Trichoptera: Rhyacophilidae) with notes on its ecology

The larva of Rhyacophila loxias Schmid, 1970 is re-described. The diagnostic features of the species are listed and illustrated, and some information on the ecology and distribution of R. loxias is included.     

Ultrastructural study of metamorphosis in the freshwater bryozoan Plumatella fungosa (Bryozoa,Phylactolaemata)

Summary

At metamorphosis the attachment of the Plumatella larva to the substrate is effected by secretions from glandular cells in the apical plate, the leading pole during swimming. The larval mantle folds back and slides down towards the substrate. By ciliary activity an adhesive secretion is spread over the metamorphosing larva and the attachment area. Two polypides appear through the larval terminal opening. The mantle fold, together with gland cells, nerve cells, sensory cells, and muscle cells from the larva form a nutritive cell mass. Reduction of this nutritive cell mass is accomplished by autolysis and phagocytosis. An invaginated area of the nutritive cell mass is provided with a dense layer of microvilli, which seem to have an absorbtive function. The nutritive cell mass consisting of transitory larval tissues provides a significant source of nutrient for the developing polypide buds.