SDF-9, a protein tyrosine phosphatase-like molecule,regulates the L3/dauer developmental decision through hormonal signaling in C. elegans

The dauer larva of the nematode Caenorhabditis elegans is a good model system for investigating the regulation of developmental fates by environmental cues. Here we show that SDF-9, a protein tyrosine phosphatase-like molecule, is involved in the regulation of dauer larva formation. The dauer larva of sdf-9 mutants is different from a normal dauer larva but resembles the dauer-like larva of daf-9 and daf-12 dauer-constitutive mutants. Like these mutants, the dauer-constitutive phenotypes of sdf-9 mutants were greatly enhanced by cholesterol deprivation. Epistasis analyses, together with the relationship between sdf-9 mutations and daf-9 expression, suggested that SDF-9 increases the activity of DAF-9 or helps the execution of the DAF-9 function. SDF-9 was expressed in two head cells in which DAF-9 is expressed. By their position and by genetic mosaic experiments, we identified these cells as XXXL/R cells, which are known as embryonic hypodermal cells and whose function at later stages is unknown. Killing of the sdf-9-expressing cells in the wild-type first-stage larva induced formation of the dauer-like larva. Since this study on SDF-9 and former studies on DAF-9 showed that the functions of these proteins are related to those of steroids, XXXL/R cells seem to play a key role in the metabolism or function of a steroid hormone(s) that acts in dauer regulation.     

Systematics of Anopheles lanei Galvão and Amaral, a species of the subgenus Nyssorhynchus Blanchard (Diptera: Culicidae)

Anopheles (Nyssorhynchus) lanei Galv?o and Amaral is here redescribed using morphological characteristics of adult, male and female, fourth instar larva and pupa. The larva, pupa, and male genitalia are illustrated. Diagnostic morphological characters of adults, male genitalia, fourth instar larva and pupa are provided to distinguish An. lanei from other species of the Argyritarsis section. Species distribution data are based on the published literature records and bionomics data are based on both literature records and field data.     

Hatching and earliest larval stages of the priapulid worm Priapulus caudatus

Abstract. Here we describe the hatching and morphology of the earliest larval stages of the priapulid worm Priapulus caudatus for the first time. The hatching larva differs considerably from previously described larvae not only in its general body shape but also in its lack of a proper lorica including the typical lorica tubuli. Furthermore, no mouth opening or pharyngeal teeth have formed as yet, and the number and arrangement of scalids differ from that of later larvae. The hatching larva molts and emerges as the first lorica larva. This larva partially resembles earlier described lorica larvae, but there are a number of important differences; the first lorica larva is smaller, and the mouth opening as well as pharyngeal teeth are still yet to form. The second lorica larva is equipped with four rings of pharyngeal teeth; it shows striking similarity to the previously described larva of P. caudatus , i.e., the larva-type 2 , only differing in the scalid pattern. We conclude that the first two larval stages of P. caudatus have not been described previously. We suggest that discrepancies between the earliest lorica larvae described here and in earlier publications might depend on sub-speciation or ecophenotypic modification of larvae collected from different localities. Our findings highlight the importance of studying the development of non-model organisms such as priapulids under controlled laboratory conditions.     

The life history and larval morphology of Aperilampus (Hymenoptera: Chalcidoidea: Philomidinae), with a discussion of the phylogenetic affinities of the Philomidinae

Abstract. The host association and larval morphology of Aperilampus (Hymenoptera: Chalcidoidea: Philomidinae) are documented for the first time based on specimens collected during the excavation of ground-nesting bee nests in South Africa. Aperilampus varians Strand is a primary parasite of the pupa of Halictus (Seladonia) africanus Friese (Hymenoptera: Halictidae). The first and final-instar larvae are described and illustrated, and notes are provided on the behaviour of the first-instar larva. The first-instar larva is a planidium and synapomorphies are documented between the first-instar larva of Aperilampus and the planidia of Chrysolampinae, Perilampidae and Eucharitidae.     

Nutrition of Glossina morsitans: metabolism of U-14C glucose during pregnancy.

A Glossina morsitans female can synthesize alanine, aspartic acid, cystine, glutamic acid, glycine, proline, and serine, and also lipids, from d-[U-¹⁴C] glucose during pregnancy and utilize these products for nourishment of the growing intra-uterine larva. The third instar larva shortly after formation of the puparium can also synthesize these nutrients from glucose and is thus similar to the adult female fly in this respect. It is possible that some glucose taken up by the larva via the maternal uterine glands is converted to the above nutrients. Although the specific nutritional requirements of the growing larva are largely provided by its female parent, the larva has active synthetic systems for the regulation and maintenance of its inherent metabolic steady state. This is reflected in the synthesis of large amounts of glutamic acid in the larva whereas in the adult the emphasis appears to be on the synthesis of proline.Most of the injected glucose and its synthetic products are utilized to provide energy for biosynthetic activity. Uric acid is the main nitrogenous end product of catabolism of non-essential amino acids. A small proportion of such amino acids and glucose are also excreted.Embryonic development which lasts for about 4 days following ovulation is sustained by nutrients within the egg. Following eclosion, the first instar larva begins to feed upon uterine gland secretions. This instar lasts for about 1 day. Ecdysis to the second instar, which lasts for 1 to 2 days, is associated with a three- to fourfold increase in the rate of nutrient uptake. Most rapid feeding begins when the third instar develops. These results are discussed in terms of larval growth in relation to feeding by the adult female parent.     

Further Ultrastructural Studies on the Encapsulated Larva of Kronborgia isopodicola (Platyhelminthes,Fecampiidae), with Particular Reference to Nuclei

During development of the encapsulated Kronborgia isopodicola larva, nuclei of the body tissues and differentiating eyes undergo a continuous condensation, the progression of which is described. The brain is composed of a central neuropil and an outer layer of nerve cell perikarya. Neurosecretory cells are located at the sides of the brain. Some neurosecretory cell extensions are interposed between the cerebral neuropil and nerve cell perikarya; others overlie the photoreceptor cell processes of the eyes. The advanced encapsulated larva possesses a frontal complex, consisting of modified epidermis, secretory cells, gland ducts and nerve cell processes. The advanced larva is transparent and diminished in size, advantages possibly due in part to the extraordinary process of comprehensive nuclear condensation during ontogeny. The larva has a uniform epidermal ciliation and, while sharing certain features with trochophore larvae, is not of the trochophore type.     

Larval morphology of the Nemertean Carcinonemertes epialti (Nemertea: Hoplonemertea)

The morphology of the newly hatched larva of Carcinonemertes epialti Coe has been examined by light and electron microscopy. The newly hatched larva is covered with cilia and measures about 110 μm in length. Four types of epidermal cells are recognizable: (1) Multiciliated cells, (2) vacuolated cells, (3) mucous cells, and (4) “knob cells”. The knob cells protrude from the posterior end of the larva and contain granules and bundles of microfilaments. The gut is incomplete and is located ventral to the bipartite proboscis. A bilobed brain and two subepidermal ocelli are found in the anterior end of the larva. The anterior and posterior cirri are composed of long, tightly appressed cilia that arise from an invagination of the epidermis at each end of the larva. The anterior cirrus is surrounded by two types of glandular cells. It is proposed that the knob cells have a role in larval attachment, combining the functions of the adhesive cells and anchor cells described in the duo-gland system of turbellarians. The cirri are believed to be larval sensory structures that function in substrate selection. Histological and ultrastructural observations suggest that the larvae of Carcinonemertes are relatively long lived and develop into juveniles without a drastic metamorphosis.     

赤松毛虫消长规律生命表分析

赤松毛虫消长规律生命表分析慕宗昭倪玉乐,孙家江（山东省林业厅,济南２５００１４）（山东省文登市林业局,２６４４００）ＬｉｆｅＴａｂｌｅＡｎａｌｙｓｉｓｏｆＤｅｎｄｒｏｌｉｍｕｓｓｐｅｃｔａｂｉｌｉｓＧｒｏｗｔｈａｎｄＤｅｃｌｉｎｅＰａｔｔｅｒｎｓ．￥...     

The forkhead gene FH1 is involved in evolutionary modification of the ascidian tadpole larva.

The forkhead gene FH1 encodes a HNF-3beta protein required for gastrulation and development of chordate features in the ascidian tadpole larva. Although most ascidian species develop via a tadpole larva, the conventional larva has regressed into an anural (tailless) larva in some species. Molgula oculata (the tailed species) exhibits a tadpole larva with chordate features (a dorsal neural sensory organ or otolith, a notochord, striated muscle cells, and a tail), whereas its sister species Molgula occulta (the tailless species) has evolved an anural larva, which has lost these features. Here we examine the role of FH1 in modifying the larval body plan in the tailless species. We also examine FH1 function in tailless speciesxtailed species hybrids, in which the otolith, notochord, and tail are restored. The FH1 gene is expressed primarily in the presumptive endoderm and notochord cells during gastrulation, neurulation, and larval axis formation in both species and hybrids. In the tailless species, FH1 expression is down-regulated after neurulation in concert with arrested otolith, notochord, and tail development. The FH1 expression pattern characteristic of the tailed species is restored in hybrid embryos prior to the development of chordate larval features. Antisense oligodeoxynucleotides (ODNs) shown previously to disrupt FH1 function were used to compare the developmental roles of this gene in both species and hybrids. As described previously, antisense FH1 ODNs inhibited endoderm invagination during gastrulation, notochord extension, and larval tail formation in the tailed species. Antisense FH1 ODNs also affected gastrulation in the tailless species, although the effects were less severe than in the tailed species, and an anural larva was formed. In hybrid embryos, antisense FH1 ODNs blocked restoration of the otolith, notochord, and tail, reverting the larva back to the anural state. The results suggest that changes in FH1 expression are involved in re-organizing the tadpole larva during the evolution of anural development.     

Larval development in the Homoscleromorpha (Porifera, Demospongiae)

Abstract. Embryonic development from coeloblastula to fully developed larva was investigated in 8 Mediterranean homoscleromorph species: Oscarella lobularis, O. tuberculata, O. microlobata, O. imperialis, Plakina trilopha, P. jani, Corticium candelabrum , and Pseudocorticium jarrei. Morphogenesis of the larva is similar in all these species; however, cell proliferation is more active in species of Oscarella than in Plakina and C. candelabrum. The result of cell division is a wrinkled, flagellated larva, called a cinctoblastula. It is composed of a columnar epithelium of polarized, monoflagellated cells among which are scattered a few non-flagellated ovoid cells. The central cavity always contains symbiotic bacteria. Maternal cells are also present in O. lobularis, O. imperialis , and P. jarrei. In the fully developed larva, cell shape and dimensions are constant for each species. The cells of the anterior pole have large vacuoles with heterogeneous material; those of the postero-lateral zone have an intranuclear paracrystalline inclusion; and the flagellated cells of the posterior pole have large osmiophilic inclusions. Intercellular junctions join the apical parts of the cells, beneath which are other specialized cell junctions. A basement membrane underlying the flagellated cells lines the larval cavity. This is the first observation of a basement membrane in a poriferan larva. The basal apparatus of flagellated cells is characterized by an accessory centriole located exactly beneath the basal body. The single basal rootlet is cross striated. The presence of a basement membrane and a true epithelium in the larva of Homoscleromorpha—unique among poriferan clades and shared with Eumetazoa—suggests that Demospongiae could be paraphyletic.     

A new type of loriciferan larva (Shira larva) from the deep sea of Shatsky Rise,Pacific Ocean

Loricifera is a phylum of minute animals that live exclusively in marine sediments. A total of 33 species have been described so far in this phylum; however, several more are already known from preliminary observations. Loriciferans are characterised by a complex life cycle, which involves a succession of several adult and larval stages. Here, we describe a new type of loriciferan larval stage: the Shira larva. The gross morphology of this larva is generally similar to that of the most prominent larval type of Loricifera, the so-called Higgins larva. However, the Shira larva possesses a number of unique features, namely (1) a single pair of anteroventral setae is present in the most anterior region of the abdomen, (2) the bases of the anteroventral setae are very large and swollen, (3) the thorax and abdomen are thinner than the introvert and (4) the abdominal region is divided into five sub-regions. Accordingly, we described the new species, Tenuiloricus shirayamai gen. nov. et sp. nov. (incertae sedis). The new findings are discussed from a comparative perspective with the Higgins larva as well as with the fossil of a putative loriciferan larval stage from the Middle Cambrian.     

Stage-dependent strategies of host invasion in the egg-larval parasitoid Chelonus inanitus

Chelonus inanitus (Braconidae) is a solitary egg-larval parasitoid which lays its eggs into eggs of Spodoptera littoralis (Noctuidae); the parasitoid larva then develops in the haemocoel of the host larva. Host embryonic development lasts approx. 3.5 days while parasitoid embryonic development lasts approx. 16 h. All stages of host eggs can be successfully parasitized, and we show here that either the parasitoid larva or the wasp assures that the larva eventually is located in the host's haemocoel. (1) When freshly laid eggs, up to almost 1-day-old, are parasitized, the parasitoid hatches while still in the yolk and enters the host either after waiting or immediately through the dorsal opening. (2) When 1-2-day-old eggs are parasitized, the host embryo has accomplished final dorsal closure and is covered by an embryonic cuticle when the parasitoid hatches; in this case the parasitoid larva bores with its moving abdominal tip into the host. (3) When 2.5-3.5-day-old eggs are parasitized, the wasp oviposits directly into the haemocoel of the host embryo; from day 2 to 2.5 the embryo is still very small and the wasps, after probing, often restrain from oviposition for a few hours.     

大蜂螨对一些气味物质的趋性

狄斯瓦螨Varroa destructor Anderson & Trueman是意大利蜜蜂Apis mellifera Spinola的主要外寄生螨。雌成螨在幼虫巢房封盖前不久侵入幼虫巢房,并开始繁殖为害。从雌成螨在一个很短的时间内进入蜜蜂幼虫巢房,以及雄蜂幼虫巢房蜂螨的寄生率明显高于工蜂幼虫巢房的现象,表明蜜蜂幼虫体表一些信息素(semiochemicals)可能起着重要的引诱作用。作者对与大蜂螨相关的19种气味物质进行筛选,并对封盖前工蜂幼虫和雄蜂幼虫表皮挥发物进行气谱及气-质联谱测定。结果表明:雄蜂6龄幼虫对大蜂螨的引诱作用显著高于丁香水等10种气味物质。工蜂和雄蜂末龄幼虫体表挥发物的共有组份是9-二十三烯(C23H46),但它在雄蜂幼虫中所占的比例要明显高于工蜂幼虫。工蜂幼虫的特有主要组分是十八烷(C18H38)和9-甲基十九烷(C19H40);而雄蜂幼虫的特有主要组分是二十五烷(C25H52)和二十三烷(C23H48)。     

黑紫蛱蝶生物学特性的研究

黑紫蛱蝶Sasainia funebris(Leech)一年发生1代,11月份以四龄幼虫在寄主植物枝条上越冬．翌年4月越冬幼虫眠起．6月化蛹,7月中旬为成虫羽化盛期。各虫态历期：卵6．5—7天,幼虫共6龄,计300天左右,蛹12—13天,成虫10—13天。同时,还记述了该蝶各虫态的形态特征、生活习性和天敌情况等。     

Surface structures and sense organs of the cypris larva of Balanus balanoides as seen by scanning and transmission electron microscopy.

Various features of the settlement stage larva (cyprid) of the barnacle, Balanus balanoides (L.), were studied using scanning and transmission electron microscopy. The cuticle of the valves is pitted and in section has a characteristic ultrastructure. Small sensory setae protrode from the surface of this cuticle and are probably mechanoreceptors able to sense water movement around the larva. Each of the pair of caudla appendages which protrude from between the larval valves posteriorly, is made up of several sensory setae. These appendages are able to sense settlement surface topography. Certain other features of the larva are alos described and their roles discussed; such features include the frontal filaments, antennules and thoracic limbs.     

红毛羽毛蚜蝇幼期生物学特性的初步研究

通过红毛羽毛蚜蝇Pararctophila oberthueri Herve室内饲养,对红毛羽毛蚜蝇幼期形态特征及生物学特性进行观察和研究。结果表明：在自然条件下,幼期每世代历期为25～30天,卵的孵化时间为2.52天,幼虫期为18．25天,蛹的羽化时间8．45天,幼期历期的长短受食物及温度影响。     

How does Trichinella spiralis make itself at home?

The nurse cell-parasite complex of Trichinella spiralis is unlike anything else in Nature. It is derived from a normal portion of striated skeletal muscle cell and develops in a matter of 15 to 20 days after the larva invades that cell type. What are the molecular mechanisms at work that result in this unique relationship? Here, Dickson Despommier presents a hypothesis to account for its formation, in which secreted tyvelosylated proteins of the larva play a central role. These proteins are always present in the intracellular niche of the larva from Day 7 after infection and may be responsible for redirecting host genomic expression, leading to nurse cell formation.     

条背萤幼虫水生适应性形态与游泳行为研究

研究了条背萤Luciolasubstriata幼虫的形态特征及其对游泳行为的适应。形态及扫描电镜观察发现,条背萤幼虫存在二态现象。1～2龄幼虫虫体扁平,多毛。有7对呼吸鳃,分别位于腹部第1～7节。3～6龄幼虫虫体扁平呈船形,无呼吸鳃,靠气管呼吸。二者均具有扁平桨状的足、燕尾状尾节及位于尾节末端的圆柱形粘附器官。条背萤幼虫游动时身体腹面朝上,呈仰泳姿态,足向后划水。3～6龄幼虫仰泳时足共有8种摆动姿势。幼虫仰泳时足摆动1个周期所需时间为(0.611±0.16)s。腹部末端可上下左右摆动,当幼虫向前游动时,尾部上下摆动1个周期所需时间为(1.795±0.44)s。幼虫的游泳速度为(0.85±0.16)mh。仰泳中的幼虫改变方向时,头部和尾部同时向身体的一侧弯曲,当头部与尾部呈近90°时,幼虫用力将尾部伸直,此时水产生一个反作用力继续推动幼虫转向,幼虫转向的范围为0～90°。条背萤2种类型幼虫呼吸系统的不同决定着幼虫外部形态的差异及游泳行为的不同,而导致这种呼吸系统、形态及运动行为不同的原因很可能是条背萤对环境的适应性进化。     

Larval cells of sponge Halisarca dujardini (Demospongiae, Halisarcida). I. Separation of the cells and their aggregation properties

The majority of Demospongia members have a parenchymula larva, whose inner cells are similar to definite sponge cells. There are some contradictory opinions about the structure of larva in the marine sponge Halisarca dujardini: some authors deny the presence of inner cells, while other investigators consider this larva as a real parenchymula. We defined the larval cell types by cell separation in the percoll gradient and analysed their morphology and behaviour. The results showed the existence of 6 cell types in the parenchymula larva of H. dujardini, including 2 types of external flagellated cells. Each cell category differs in its morphology and aggregation ability.