L(1)trol and L(1)devl, Loci Affecting the Development of the Adult Central Nervous System in Drosophila Melanogaster

Adult optic lobes of Drosophila melanogaster are composed of neurons specific to the adult which develop postembryonically. The structure of the optic lobes and aspects of its development have been described, and a number of mutants that affect its development have been identified. The focus of every screen to date has been on disruption of adult structure or function. Although these loci were originally identified on the basis of viable mutants, some have proven capable of giving rise to lethal alleles. It seems reasonable to assume that mutants which strongly affect development of the imaginal-specific central nervous system may evidence abnormalities during the late larval or pupal stages when the adult central nervous system is undergoing final assembly and might show a lethal phase prior to eclosion (as is true for mutations at the previously defined l(1)ogre locus). We have carried out the first screen of autosomal and sex-linked late larval and pupal lethals to identify mutations that affect the development of the optic lobes. Our screen yielded nine mutants that could tentatively be grouped into three classes, depending on the neuroblast population affected and imaginal disc phenotypes. Two of these, including one that is allelic to l(1)zw1, were chosen for further analysis.     

Properties of Orange-Pupa-Inducing Factor (OPIF) in the swallowtail butterfly, Papilio xuthus L

Diapause pupae of the swallowtail butterfly Papilio xuthus L. exhibit diapause-green, orange and brownish-orange color polymorphism. Development of orange pupae involves a neuroendocrine factor inducing orange pupa (Orange-Pupa-Inducing Factor, OPIF), which is secreted from the head-thoracic region during late pharate pupal stages, in particular from the ganglia of short-day animals located posteriorly from the second thoracic ganglion2 (TG2). This report describes certain properties of OPIF using bioassays involving ligated abdomens of short-day pharate pupae. Localization of OPIF in the central nervous system of short-day larvae indicated that it was present predominantly in TG2, thoracic ganglion3 (TG3) and abdominal ganglion1 (AG1) complexes. OPIF activity in TG(2,3)-AG1 complexes was over two times higher than in the more posteriorely located ganglia. The developmental profile of OPIF in last instar short-day larvae revealed that OPIF activity in larval ganglia posterior to TG2 became gradually higher as larval growth proceeded, suggesting that OPIF might be accumulated in TG(2,3)-AG(1-7) complexes as larvae prepare for pupal molting. Furthermore, ligated abdomens of short-day larvae developed into pupae of an orange type when a 2% NaCl extract containing OPIF prepared from TG(2,3)-AG(1-7) complexes of long-day larvae was injected into ligated abdomens of short-day pharate pupae, indicating that OPIF is also present in long-day larvae. Additionally, a biochemical investigation using gel filtration chromatography showed that the molecular weight of OPIF was about 10 kDa.     

Developmental expression and tissue distribution of the lethal (2) giant larvae protein of Drosophila melanogaster

Recessive mutations in the Drosophila tumor gene lethal (2) giant larvae affect the growth and tissue specificity of determined cells in imaginal discs and presumptive optic centers of the brain. To analyse the function of the l (2) gl gene during development, we have raised monoclonal antibodies against the l (2) gl protein. These antibodies detect a 130-kd protein in wild-type tissue which is absent in homozygous mutant tissues. The protein is detected in increasing amounts up to mid-embryonic stages. Antibody binding to embryo sections and indirect immunofluorescence labeling indicate that the protein is localized at the cellular membranes or in the intercellular matrix of the embryonic cells. The primordia of all larval tissues are labeled in the embryo. Much less labeling is found in the neural primordia of the central nervous system, except that within the supraoesophageal ganglion the regions of the presumptive optic centers are distinctly labeled. Moreover, the axon bundles of the ventral cord are labeled in the embryo, apparently a reflection of the accumulation of cell membranes here. After embryogenesis the l (2) gl protein is found at a low level until the end of the 3rd larval instar, when it is preferentially seen in the brain and imaginal discs. The protein distribution in embryonic and larval tissues correlates with already known proliferation patterns, which could indicate that the l (2) gl protein is involved in proliferation arrest of cells.     

Proliferation pattern and early differentiation of the optic lobes in Drosophila melanogaster

Summary The larval and early pupal development of the optic lobes in Drosophila is described qualitatively and quantitatively using [³H]thymidine autoradiography on 2-m plastic sections. The optic lobes develop from 30–40 precursor cells present in each hemisphere of the freshly hatched larva. During the first and second larval instars, these cells develop to neuroblasts arranged in two epithelial optic anlagen. In the third larval instar and in the early pupa these neuroblasts generate the cells of the imaginal optic lobes at discrete proliferation zones, which can be correlated with individual visual neuropils.The different neuropils as well as the repetitive elements of each neuropil are generated in a defined temporal sequence. Cells of the medulla are the first to become postmitotic with the onset of the third larval instar, followed by cells of the lobula complex and finally of the lamina at about the middle of the third instar. The elements of each neuropil connected to the most posterior part of the retina are generated first, elements corresponding to the most anterior retina are generated last.The proliferation pattern of neuroblasts into ganglion mother cells and ganglion cells is likely to include equal as well as unequal divisions of neuroblasts, followed by one or two generations of ganglion mother cells. For the lamina the proliferation pattern and its temporal coordination with the differentiation of the retina are shown.     

Biochemical and cytoimmunological evidence for the control of Aedes aegypti larval trypsin with Aea-TMOF

Trypsin and chymotrypsin-like enzymes were detected in the gut of Aedes aegypti in the four larval instar and pupal developmental stages. Although overall the amount of trypsin synthesized in the larval gut was 2-fold higher than chymotrypsin, both enzymes are important in food digestion. Feeding Aea-Trypsin Modulating Oostatic Factor (TMOF) to Ae. aegypti and Culex quinquefasciatus larvae inhibited trypsin biosynthesis in the larval gut, stunted larval growth and development, and caused mortality. Aea-TMOF induced mortality in Ae. aegypti, Cx. quinquefasciatus, Culex nigripalpus, Anopheles quadrimaculatus, and Aedes taeniorhynchus larvae, indicating that many mosquito species have a TMOF-like hormone. The differences in potency of TMOF on different mosquito species suggest that analogues in other species are similar but may differ in amino acid sequence or are transported differently through the gut. Feeding of 29 different Aea-TMOF analogues to mosquito larvae indicated that full biological activity of the hormone is achieved with the tetrapeptide YDPA. Using cytoimmunochemical analysis, intrinsic TMOF was localized to ganglia of the central nervous system in larvae and male and female Ae. aegypti adults. The subesophageal, thoracic, and abdominal ganglia of both larval and adult mosquitoes contained immunoreactive cells. Immunoreactive cells were absent in the corpus cardiacum of newly molted 4th instar larvae but were found in late 4th instar larvae. In both males and females, the intrinsic neurosecretory cells of the corpus cardiacum were filled with densely stained immunoreactive material. These results indicate that TMOF-immunoreactive material is synthesized in sugar-fed male and female adults and larvae by the central nervous system cells.     

Neural development in an imaginal disc mutant of Drosophila melanogaster

The neural phenotype of an imaginal disc degenerate mutant l(1)d deg-3 was studied in histological sections. The mutant larvae showed severe abnormalities in the imaginal neural development. Gynandromorphs, which are composed of genetically mutant and nonmutant cells, were generated and analyzed as late larvae. The results of mosaic analysis were consistent with l(1)d deg-3 gene acting autonomously in the imaginal disc and imaginal neural cells. The optic lobe development patterns observed in the larval mosaics provided evidence for an eye disc-optic lobe interaction during the late third instar larval stage.     

Brain-independent development in the moth Sesamia nonagrioides

The caterpillars of Sesamia nonagrioides developing under long-day (LD) photoperiod pupate in the 5th or 6th instar whereas under short day (SD) conditions they enter diapause and undergo several extra larval molts. The diapause is terminated within 1-3 instars upon transfer of SD larvae to the LD conditions. Brain removal from the 6th instar larvae promotes pupation followed by imaginal development; however, one third of the SD larvae and 12% of the LD larvae debrained at the start of the instar first undergo 1-2 larval molts. The incidence of larval molts is enhanced by the brain implants. Exclusively pupal molts occur in the LD larvae debrained late in the 6th instar. Decapitation elicits pupation in both LD and SD larvae, except for some of the 4th and 5th and rarely 6th instar that are induced to a fast larval molt. The pupation of decapitated larvae is reverted to a larval molt by application of a juvenile hormone (JH) agonist. No molts occur in abdomens isolated from the head and thorax prior to the wandering stage. Abdomens isolated later undergo a larval (SD insects) or a pupal (LD insects) molt. Taken together the data reveal that in S. nonagrioides (1) several larval molts followed by a pupal and imaginal molt can occur without brain; (2) an unknown head factor outside the brain is needed for the pupal-adult molt; (3) brain exerts both stimulatory and inhibitory effect on the corpora allata (CA); (4) larval molts induced in CA absence suggest considerable JH persistence.     

中华蜜蜂工蜂视叶胚后发育过程中的细胞凋亡

本研究通过形态解剖和原位末端标记法(TUNEL),对中华蜜蜂Apis cerana cerana视叶胚后发育过程中的细胞凋亡进行了研究,结果表明:视叶内的细胞程序性死亡开始出现在1龄幼虫末期,随后凋亡细胞数量逐渐增加;在视叶的胚后发育过程中,细胞凋亡经历了3个高峰期,即2龄幼虫、5龄幼虫和蛹发育的第2天;在视叶3个部分的发育中,视髓层中细胞凋亡的数量远远多于视小叶和视神经节层,而视神经节层最少,说明了细胞凋亡的数量和位置与各部分结构发育的时间以及神经投射有关。广泛的细胞凋亡是蜜蜂视叶发育过程中的一个显著特征。     

Control of pupal commitment in the imaginal disks of Precis coenia (Lepidoptera: Nymphalidae)

When final (5th) instar larvae of Precis coenia were treated with the juvenile hormone analog (JHA) methoprene, they underwent a supernumerary larval molt, except for certain regions of their imaginal disks, which deposited a normal pupal cuticle. Evidently those regions had already become irreversibly committed to pupal development at the time JHA was applied. By applying JHA at successively later times in the instar, the progression of pupal commitment could be studied. Pupal commitment in the proboscis, antenna, eye, leg and wing imaginal disks occurred in disk-specific patterns. In each imaginal disk there were distinct initiation sites where pupal commitment began during the first few hours of the final larval instar, and from which commitment spread across the remainder of the disk over a 2- to 3-day period. The initiation sites were not always located in homologous regions of the various disks. As a rule, pupal commitment also spread from imaginal disk tissue to surrounding epidermal tissue. The regions of pupal commitment in all disks except those of the wings, coincided with the regions of growth of the disk. Only portions of the disk that had undergone cell division and growth underwent pupal commitment. Shortening the growth period did not prevent pupal commitment in the wing imaginal disk, indicating that, in this disk at least, a normal number of cell divisions was not crucial in reprogramming of disk cells for pupal cuticle synthesis. The apparent growth spurt of imaginal disks that occurs during the last part of the final larval instar is merely the final stage of normal and constant exponential growth. Juvenile hormone (JH) and ecdysteroids appeared to play little role in the regulation of normal imaginal disk growth. Instead, growth of the disks may be under intrinsic control. Interestingly, even though endogenous fluctuation in JH titers do not affect imaginal disk growth, exogenous JHA proved able to inhibit both pupal commitment, cell movement, and growth of the disks during the last larval instar. This function of JH could be important under certain adverse conditions, such as when metamorphosis is delayed in favor of a supernumerary larval molt.     

atonal regulates neurite arborization but does not act as a proneural gene in the Drosophila brain

Drosophila atonal (ato) is the proneural gene of the chordotonal organs (CHOs) in the peripheral nervous system (PNS) and the larval and adult photoreceptor organs. Here, we show that ato is expressed at multiple stages during the development of a lineage of central brain neurons that innervate the optic lobes and are required for eclosion. A novel fate mapping approach shows that ato is expressed in the embryonic precursors of these neurons and that its expression is reactivated in third instar larvae (L3). In contrast to its function in the PNS, ato does not act as a proneural gene in the embryonic brain. Instead, ato performs a novel function, regulating arborization during larval and pupal development by interacting with Notch.     

Immunocytochemical localization of an allatotropin in developmental stages of Heliothis virescens and Apis mellifera

Juvenile hormone biosynthesis by the corpora allata is regulated by stimulatory neuropeptides called allatotropins and inhibitory neuropeptides called allatostatins. This study localized Manduca sexta allatotropin-like material in developmental stages of the noctuid moth Heliothis virescens and the honeybee Apis mellifera. Immunocytochemical methods using both fluorescence-tagged antibodies and enzyme-coupled antibodies were used to stain the central nervous tissue of both species. H. virescens contains M. sexta allatotropin (Manse-AT)-like material consistently throughout larval development. The distribution patterns of Manse-AT immunoreactive cell bodies in the CNS persisted from one larval instar to the next. It will be discussed how larval Manse-AT distribution patterns differed from those in adults. The total number of AT-containing cells in brain and subesophageal ganglion gradually increased during larval development, whereas in the thoracic and abdominal ganglia, the number of AT-containing neurons remained constant. In the honeybee A. mellifera, Manse-AT immunoreactive cells were only found in a few brains from late last instar larvae (prepupae). Manse-AT-like material was present in a group of 6-8 cells in the pars intercerebralis. However, we did not find any Manse-AT-like material in brains of early last instar larvae, whose corpora allata (CA) are more sensitive to in vitro stimulation by Manse-AT than prepupal CA.     

Postembryonic development of serotonin-immunoreactive neurons in the central nervous system of the blowfly,Calliphora erythrocephala

Summary The postembryonic development of serotonin-immunoreactive (5-HTi) neurons was studied in the optic lobe of the blowfly. In the adult fly there are 24 5-HTi neurons invading each optic lobe. The perikarya of two of these neurons are situated in the dorso-caudal part of the protocerebrum (LBO-5HT neurons; large bilateral optic lobe 5-HTi neurons). The cell bodies of the remaining 22 neurons are located anteriorly at the medial base of the medulla (2 innervating the lobula, LO-5HT neurons; and 20 neurons innervating the medulla, ME-5HT neurons). The two central neurons (LBO-5HT neurons) are derived from metamorphosing larval neurons, while the ME- and LO-5HT neurons are imaginai optic lobe neurons differentiating during pupal development.The 5-HTi neurons of the optic lobe seem to have different ancestors. The LBO-5HT neurons are probably derived from segmental protocerebral neuroblasts, whereas the ME-and LO-5HT neurons are most likely derived from the inner optic anlage. The first 5-HTi fibers to reach the imaginal optic lobes are seen in the late third instar larva and are derived from the LBO-5HT neurons. The first ME- and LO-5HT neurons become immunoreactive at 24 h (10%) pupal development. At about 96 h (40%) of pupal development all the 5-HTi neurons of the optic lobes have differentiated and attained their basic adult morphology. The further development mainly entails increase in volume of arborizations and number of finer processes. The differentiation and outgrowth of 5-HTi processes follows that of, e.g., columnar neurons in the optic lobe neuropils. Hence, 5-HTi processes invade neuropil relatively late in the differentiation of the optic lobe.     

kurtz, a novel nonvisual arrestin, is an essential neural gene in Drosophila

The kurtz gene encodes a novel nonvisual arrestin. krz is located at the most-distal end of the chromosome 3R, the third gene in from the telomere. krz is expressed throughout development. During early embryogenesis, krz is expressed ubiquitously and later is localized to the central nervous system, maxillary cirri, and antennal sensory organs. In late third instar larvae, krz message is detected in the fat bodies, the ventral portion of the thoracic-abdominal ganglia, the deuterocerebrum, the eye-antennal imaginal disc, and the wing imaginal disc. The krz(1) mutation contains a P-element insertion within the only intron of this gene and results in a severe reduction of function. Mutations in krz have a broad lethal phase extending from late embryogenesis to the third larval instar. The fat bodies of krz(1) larva precociously dissociate during the midthird instar. krz(1) is a type 1 melanotic tumor gene; the fat body is the primary site of melanotic tumor formation during the third instar. We have functionally rescued these phenotypes with both genomic and cDNA transgenes. Importantly, the expression of a full-length krz cDNA within the CNS rescues the krz(1) lethality. These experiments establish the krz nonvisual arrestin as an essential neural gene in Drosophila.     

Developmental Changes in Biogenic Amine Levels in the Central Nervous System and the Haemolymph of the Eastern Death's Head Hawk Moth,Acherontia styx (Lepidoptera: Sphingidae)

In an effort to understand the role of biogenic amines in insect development, changes in the levels of octopamine (OA), dopamine (DA), epinephrine (E), norepinephrine (NE), and serotonin (5-HT) in the brain, the optic lobes and the haemolymph of different developmental stages of Acherontia styx were analyzed using HPLC with electrochemical detector. In the brain, OA was the most abundant monoamine. DA, OA, and E levels in larvae peaked around the wandering stage (W). A dramatic increase in DA, 5-HT, and E levels was observed in the brain of the adult as compared to the pupal stage. NE, however, was not detected in the brain of most stages of the insect, except in the brain of 20-day-old pupae and adults. A 3-fold increase in OA levels was observed in the optic lobes of the adult as compared to late pupal stage. No changes were observed for E, DA, and 5-HT. NE was not detected in the optic lobes. In the haemolymph of 5^th instar larvae, OA was also the most abundant amine. Both DA and OA peaked prior to the onset of the W stage. In contrast, E and NE concentrations decreased with development of the 5^th instar larvae. 5-HT was not detected in the haemolymph. Finally, different profiles for amine levels were observed for the two forms of the 5^th instar larvae (green vs brown). These results are interpreted in the light of the role of biogenic amines and their relation to development in the nervous system of lepidopteran insects.     

Pyrokinin/PBAN-like peptides in the central nervous system of Drosophila melanogaster

The pyrokinin/pheromone biosynthesis activating neuropeptide (PBAN) family of peptides found in insects is characterized by a 5-amino-acid C-terminal sequence, FXPRLamide. The pentapeptide is the active core required for diverse physiological functions, including stimulation of pheromone biosynthesis in female moths, stimulation of muscle contraction, induction of embryonic diapause in Bombyx mori, and stimulation of melanization in some larval moths. Recently, this family of peptides has been implicated in accelerating the formation of the puparium in a dipteran. Using bioassay and immunocytochemical techniques, we demonstrate the presence of pyrokinin/PBAN-like peptides in the central nervous system of Drosophila melanogaster. Pheromonotropic activity was shown in the moths Helicoverpa zeaand Helicoverpa armigera by using dissected larval nervous systems and adult heads and bodies of D. melanogaster. Polyclonal antisera against the C-terminal ending of PBAN revealed the location of cell bodies and axons in the central nervous systems of larval and adult flies. Immunoreactive material was detected in at least three groups of neurons in the subesophageal ganglion of 3rd instar larvae, pupae, and adults. The ring gland of both larvae and adults contained immunoreactivity. Adult brain-subesophageal ganglion complex possessed additional neurons. The fused ventral ganglia of both larvae and adults contained three pairs of neurons that sent their axons to a neurohemal organ connected to the abdominal nervous system. These results indicate that the D. melanogasternervous system contains pyrokinin/PBAN-like peptides and that these peptides could be released into the hemolymph.     

Postembryonic changes in the optic primordia and optic bud in the flesh fly Sarcophaga ruficornis fabr. (Diptera: Sarcophagidae)

Differentiation of the optic lobe anlagen begin in the brain of second instar. Each is an elongated disc of cortical cells placed on the dorsolateral border of each protocerebrum. In the late second instar the disc elongates and its two ends bend inwards which gradually separate from the central region, thus giving three imaginal discs. The protocerebral neuropile extends into these discs and medulla interna and externa are formed. The rudiments of compound eyes (cephalic complex) appear in the early laid larva. These are attached with the brain and pharyngeal wall separately. The posterior portion of cephalic complex (optic bud), after establishing a nervous association with the central optic lobe anlage (lamina ganglionaris), forms the compound eye. Ech optic bud is attached to the brain by a non-nervous stalk. The epiblast cells of the optic bud do not migrate into the brain and the lamina is formed by the proliferation of the central imaginal disc. The reorientation of the optic lobe anlagen starts in the late third instar and the medulla interna divides into two unequal lobes. In 2 day pupa the nerve fibres from the lamina travel into the optic stalk and the optic nerve is formed. The epiblast cells of the optic bud differentiate to form a peripheral epithelial layer which becomes pigmented and gets apposed to the lateral boundary of the brain. The central epiblast cells of the optic bud form several ommatidia. The optic nerve degenerates gradually and various components of the compound eye are formed by the epiblast cells. Chiasm internum is present but chiasm externum is absent.     

Analysis of molting and metamorphosis in the ecdysteroid-deficient mutant L(3)3DTS of Drosophila melanogaster

The dominant temperature-sensitive mutation L(3)3^DTS (DTS-3) in Drosophila melanogaster causes lethality of heterozygotes during the third larval instar at the restrictive temperature (29°C). Temperature-shift experiments revealed two distinct temperature-sensitive periods, with lethal phases during the third larval instar (which may persist for 4 weeks) and during the late pupal stage. At 29°C mutant imaginal discs are unable to evert in situ, but did evert normally if cultured in the presence of exogenous ecdysterone or when implanted into wild-type larval hosts. The only morphologically abnormal tissue present in the lethal larvae is the ring gland, the prothoracic gland being greatly hypertrophied in third instar DTS-3 larvae. Injection of a single wild-type ring gland rescued these mutant larvae, indicating that the mutant gland is functionally, as well as morphologically, abnormal. Finally, the mutant larvae were shown to have less than 10% of the wild-type ecdysteroid levels. These results are all consistent with a proposed lesion in ecdysteroid hormone production in DTS-3 larvae. A comparison with the phenotypes of other “ecdysone-less” mutants is presented.     

Temporal occurrence of the pupal melanization reducing factor during development of the butterfly, Inachis io

Abstract. . In prepupae of Inachis io L. (Lepidoptera: Nymphalidae), a pupal melanization reducing factor (PMRF) which controls morphological colour adaptation (Bückmann & Maisch, 1987) is located in the brain, suboesophageal ganglion, thoracic ganglia, and all abdominal ganglia and their closely associated neurohaemal organs (Stamecker et al , 1994)
In animals adapted to a yellow background, PMRF content decreased in all these ganglia complexes during the prepupal stage which may be due to a release of the hormone at the critical period of the melanization reducing effect. The release of PMRF apparently occurs in a slow, but continuous, manner and may be superimposed by an incessant PMRF production at the same time recognizable by reincreasing melanization scores towards the end of prepupal and beginning of pupal stage. Therefore PMRF content in ganglia were not completely exhausted. When animals were kept on a black background, such a decline of PMRF content did not occur in both posterior ganglia complexes, whereas values from brain-suboesophageal ganglion complexes were too variable.
The target cells seem to be sensitive to PMRF treatment over a wide time range of nearly 20 h from the early stage of spinning a silk mat to 13-h-old prepupae for the melanization reducing effect.
PMRF activity was also detected in first-instar larvae and in the nervous system of third-instar larvae as well as in pupae which had completed their pigmentation. Furthermore, all three parts of the adult body still contained PMRF. Possibly PMRF may have functions in larval and adult stages in addition to its effect on morphological colour adaptation.