Molecular genetic analysis of the Klarsicht gene in Drosophila eye development /

Mosley-Bishop, Kathleen Laverne,

January 1998

Thesis (Ph. D.)--University of Texas at Austin, 1998. / Vita. Includes bibliographical references (leaves 109-114). Available also in a digital version from Dissertation Abstracts.

Calibration of an electronic compound eye image sensor /

Krishnasamy, Rubakumar.

January 2004

Thesis (M.Sc.)--York University, 2004. Graduate Programme in Computer Science. / Typescript. Includes bibliographical references (leaves 155-159). Also available on the Internet. MODE OF ACCESS via web browser by entering the following URL: http://gateway.proquest.com/openurl?url%5Fver=Z39.88-2004&res%5Fdat=xri:pqdiss &rft_val_fmt=info:ofi/fmt:kev:mtx:dissertation&rft_dat=xri:pqdiss:MR11828

The role of epsins in Drosophila eye development

Overstreet, Erin Camille

30 June 2010

The goal of my doctoral work is to understand how proteins involved in vesicle trafficking contribute to proper animal development. To understand aspects of this process, I studied how two vesicle trafficking proteins, Liquid facets(Lqf)/epsin1 and D-Epsin-Related, affect Drosophila eye development. I determined that Lqf, an endocytosis protein, together with Fat facets (Faf), a deubiquitinating enzyme, regulate the Notch and Delta signaling in the developing Drosophila eye. Notch signaling pathway is used in most developmental processes and is dependent on its ligand Delta. Faf deubiquitinates Lqf in the signaling cells, thereby increasing Lqf protein levels and also levels of Delta endocytosis. This event is necessary for Notch activation in neighboring cells. Lqf probably works in concert with the E3 ubiquitin ligase Neuralized (Neur), which ubiquitinates Delta. These conclusions are consistent with a relatively new model describing an obligate role for endocytosis in the signaling cells to effect activation in neighboring cells. To understand how Lqf functions mechanistically in this process, I performed a structure/function analysis of the Lqf protein. Lqf proteins with strategic deletions of certain functional domains were tested for their ability to function in vivo. The major result of these experiments is that the N-terminal ENTH domain of Lqf and a protein without the ENTH domain each retain significant activity. This suggests that Lqf has two functions: the ENTH domain function and the ENTH-less function. These data are in contrast with the most popular model suggesting that ENTH-less epsins are non-functional proteins. I present possible models for how ENTH-less epsins may retain function. The final part of my thesis focuses on D-Epsin-Related (D-Epsin-R) protein. I showed that D-Epsin-R is a Golgi protein, like its homologs. Surprisingly, D-Epsin-R ENTH domain is not required for function because an ENTH-less D-Epsin-R can substitute for endogenous D-Epsin-R. Also, D-Epsin-R has essential and probably specific developmental roles in the eye as D-Epsin-R mutants exhibit impaired cell growth. This work suggests that epsins are specific components of certain developmental pathways. / text

Drosophila melanogaster -- Development

Compound eye -- Growth -- Regulation

Coated vesicles

Proteins

Optical Flow in the Hexagonal Image Framework

Tsai, Yi-lun

02 September 2009

The optical flow has been one of the common approaches for image tracking. Its advantage is that no prior knowledge for image features is required. Since movement information can be obtained based on brightness data only, this method is suitable for tracking tasks of unknown objects. Besides, insects are always masters in chasing and catching preys in the natural world due to their unique compound eye structure. If the edge of the compound eye can be applied to tracking of moving objects, it is highly expected that the tracking performance will be greatly improved. Conventional images are built on a Cartesian reference system, which is quite different from the hexagonal framework for the compound eye of insects. This thesis explores the distinction of the hexagonal image framework by incorporating the hexagonal concept into the optical flow technology. Consequently, the reason behind why the compound eye is good at tracking moving objects can be revealed. According to simulation results for test images with different features, the hexagonal optical flow method appears to be superior to the traditional optical flow method in the Cartesian reference system.

Hexagonal image

Compound eye

Optical flow

Visual servo

Post-embryonic growth and fine-structural organization of arthropod photoreceptors:a study involving selected species of insects and crustaceans

Keskinen, E. (Essi)

24 November 2004

Abstract Arthropod photoreceptors are versatile sense organs. Any investigation of these organs has to consider that their structure and functional limitations at the moment of fixation depend on many factors: species, sex, developmental and nutritional state of the animal, time of day and ambient light. The microscopic image of an arthropod photoreceptor is always a sample frozen in time and space. Quite often publications on arthropod photoreceptors only provide the name of the species studied, but nothing beyond that. At least the developmental status of the study animals ought to be noted, possibly even the sex and body size. Forty publications on insect and 54 on crustacean photoreceptors were checked for the information that was given about the investigated animals: Out of these papers 40% provide only information on the name of the studied species and nothing else. The aim of this thesis, thus, was to investigate, to what extent the developmental state and the sex of the animal as well as the ambient light conditions affect the structure of the eye of a given species. Five species of arthropods were chosen: (a) the semi-terrestrial isopod Ligia exotica and two aquatic Branchiuran fishlice, Argulus foliaceus and A. coregoni, to represent the Crustacea, and (b) the stick insect Carausius morosus and the spittle bug Philaenus spumarius, both terrestrial, to represent the Insecta. The addition of new ommatidia was studied in a paper on L. exotica, which also dealt with the site of newly added ommatidia. It was found that all of these species had two sessile, large compound eyes firmly positioned on their heads (but fishlouse compound eyes were bathed in haemocoelic liquid). In all species, the compound eye was found to be of the apposition type. The gross structural organization of the ommatidia stayed approximately the same during the whole post-embryonic development. Lateral ocelli of the A. coregoni nauplius eye changed from elongated to spherical between the metanauplius and the 8th stage pre-adult. The sex of the specimens was not found to affect the structure of the eye. In all species, it turned out that the larger the animal and hence the eye, the better its sensitivity. The addition of new ommatidia in the L. exotica compound eye was concluded to take place in the anterior and ventral marginal areas of the eye.

Compound eye

crustaceans

insects

nauplius eye

post-embryonic development

Processos celulares no desenvolvimento do olho composto de Apis mellifera / Celular processes during compound eye development of Apis mellifera

Marco Antonio, David Santos

30 May 2008

Os processos que regem o desenvolvimento dos olhos compostos em insetos têm sido amplamente estudados em Drosophila melanogaster onde estes se originam a partir de discos imaginais. Pouco se sabe, porém, sobre o desenvolvimento do lóbulo óptico e da retina em outros insetos que, na sua grande maioria, não possuem discos imaginais de olhos separados do sistema nervoso central. Neste sentido, a análise comparada do desenvolvimento dos olhos de Apis mellifera pode contribuir não somente para aspectos evo-devo entre as grandes famílias dos insetos holometábolos, quanto pode elucidar questões de plasticidade de desenvolvimento pois os olhos compostos apresentam fortes características sexo e casta-específicas. Com o objetivo primário de elucidar os padrões de divisão e diferenciação celular durante o desenvolvimento do olho em A. mellifera realizamos análises histológicas e de imunomarcação durante o desenvolvimento pós-embrionário, juntamente com análise de expressão do gene roughest em tempo real. Para imunomarcação utilizamos o anticorpo anti-fosfo-histona H3 fosforilada que marca células em fase M do ciclo celular. Foram analisadas larvas operárias entre o terceiro instar larval (L3) até pupas de olho branco, rosa e marrom, com foco sobre o quinto instar larval que fica subdividida em fase de alimentação e crescimento (L5F), fases de tecelagem de casulo (L5S) e prepupa (PP). O desenvolvimento do lóbulo óptico em Apis mellifera ocorre por dobramento neuroepitelial, a partir de um centro de diferenciação, seqüencialmente gerando as camadas neurais do lóbulo óptico (lóbula, medula e lâmina). A lâmina (última a surgir) 6 apresentou-se com desenvolvimento mais lento e em duas fases antes da metamorfose: a primeira fase é o seu surgimento no começo do quinto instar larval acompanhando o primeiro pico de expressão de roughest e a segunda fase ocorre durante a tecelagem de casulo com o desenvolvimento do córtex acompanhando o segundo pico de expressão de roughest. Ainda durante o segundo pico de expressão de roughest os rabdômeros da retina começam a ficar visíveis, assim como os feixes axonais. Estes porém estarão completamente formados somente após a metamorfose.. O desenvolvimento completo da lâmina, lóbula e medula e da retina ocorre somente após a metamorfose. Durante a fase pupal as estruturas do lóbulo óptico estão prontas, porém na retina observa-se ainda gradual pigmentação, encurtamento dos feixes axonais e alongamento dos rabdômeros até atingirem o seu comprimento final logo antes da emergência. / The processes that drive compound eye development in insects have been broadly studied in Drosophila melanogaster in which they arise from imaginal discs. Little is known about optic lobe and retina development in other insects, most of which do not have imaginal eye discs attached to the nervous system. For this reason, a comparative analysis of eye development in the honey bee, Apis mellifera, not only contributes to evo-devo aspects comparing the major families of holometabolous insects, but also may elucidate questions about developmental plasticity because the compound eyes of the honeybee show strong sex and caste-specific differences. Since our primary objective was to elucidate the pattern of cellular differentiation and division during eye development we performed histological and immunolabelling analyses during the postembrionic stages of development, concomitant with a realtime analysis of roughest gene expression. For the immunolabelling experiments we used an anti-phospho-histone H3 antibody that labels cells in M phase. We analyzed eye development in worker larvae starting with the third instar until white, pink and browneyed pupae, paying special attention to the fifth instar which was subdivided into feeding phase (L5F), cocoon spinning phase (L5S) and prepupae (PP). Optic Lobe development in Apis mellifera occurs by neuroepithelial folding initiating from a differentiation center, in the larval brain. This center sequentially produces the neural layers of the optic lobe (medulla, lobula and lamina). Development of the lamina, which is the last layer to be formed, takes more time and happens in two steps before metamorphosis. The first step is emergence at the beginning of the fifth larval instar coinciding with the first peak of roughest gene expression. The second step 8 occurs during the cocoon spinning phase and is marked by its inner differentiation, again accompanied by a second peak of roughest expression. During this second peak of roughest expression the rabdomers in the retina become visible. These, however, cplete thir development only during the pupal stage. The development of the lamina, lobula and medulla is not complete until after metamorphosis, even though these optic lobe structures are structurally defined already at the beginning of the pupal phase. Retinal development in this phase is marked by gradual pigmentation, axonal bundle shortening and rabdomer elongation, which reach their final size just prior to emergence of the bees from their brood cells.

Apis mellifera

Apis mellifera

compound eye

lóbulo óptico

olho composto

optic lobe

retina

retina

roughest

roughest

Rhabdomerorganisation und –morphogenese im Komplexauge von Drosophila / Rhabdomere organization and morphogenesis in the compound eye of Drosophila

Witte, Jeannine

January 2009

Sehzellen von Insekten sind epitheliale Zellen mit einer charakteristischen, hochpolaren Morphologie und Organisation. Die molekularen Komponenten der Sehkaskade befinden sich im Rhabdomer, einem Saum dicht gepackter Mikrovilli entlang der Sehzelle. Bereits in den 70er Jahren des letzten Jahrhunderts wurde beschrieben, dass die Mikrovilli entlang einer Sehzelle eine unterschiedliche Ausrichtung besitzen, oder in anderen Worten, die Rhabdomere entlang der Sehzell-Längsachse verdreht sind. So sind in den Sehzellen R1-R6 bei dipteren Fliegen (Calliphora, Drosophila) die Mikrovilli im distalen und proximalen Bereich eines Rhabdomers etwa rechtwinkelig zueinander angeordnet. Dieses Phänomen wird in der Fachliteratur als rhabdomere twisting bezeichnet und reduziert die Empfindlichkeit für polarisiertes Licht. Es wurde für das Drosophila-Auge gezeigt, dass diese strukturelle Asymmetrie der Sehzellen mit einer molekularen Asymmetrie in der Verteilung phosphotyrosinierter Proteine an die Stielmembran (einem nicht-mikrovillären Bereich der apikalen Plasmamembran) einhergeht. Zudem wurde gezeigt, dass die immuncytochemische Markierung mit anti-Phosphotyrosin (anti-PY) als lichtmikroskopischer Marker für das rhabdomere twisting verwendet werden kann. Bisher wurde hauptsächlich die physiologische Bedeutung der Rhabdomerverdrehung untersucht. Es ist wenig über die entwicklungs- und zellbiologischen Grundlagen bekannt. Ziel der vorliegenden Arbeit war es, die Identität der phosphotyrosinierten Proteine an der Stielmembran zu klären und ihre funktionelle Bedeutung für die Entwicklung des rhabdomere twisting zu analysieren. Zudem sollte untersucht werden, welchen Einfluss die inneren Sehzellen R7 und R8 auf die Verdrehung der Rhabdomere von R1-R6 haben. Für die zwei Proteinkinasen Rolled (ERK) und Basket (JNK) vom Typ der Mitogen-aktivierten Proteinkinasen (MAPK) konnte ich zeigen, dass sie in ihrer aktivierten (= phosphorylierten) Form (pERK bzw. pJNK) eine asymmetrische Verteilung an der Stielmembran aufweisen vergleichbar der Markierung mit anti-PY. Weiterhin wurde diese asymmetrische Verteilung von pERK und pJNK ebenso wie die von PY erst kurz vor Schlupf der Fliegen (bei ca. 90% pupaler Entwicklung) etabliert. Durch Präinkubationsexperimente mit anti-PY wurde die Markierung mit anti-pERK bzw. anti-pJNK unterbunden. Diese Ergebnisse sprechen dafür, dass pERK und pJNK zu den Proteinen gehören, die von anti-PY an der Stielmembran erkannt werden. Da es sich bei ERK und JNK um Kinasen handelt, ist es naheliegend, dass diese an der Entwicklung des rhabdomere twisting beteiligt sein könnten. Diese Hypothese wurde durch die Analyse von hypermorphen (rl SEM)und hypomorphen (rl 1/rl 10a) Rolled-Mutanten überprüft. In der rl SEM-Mutante mit erhöhter Aktivität der Proteinkinase erfolgte die asymmetrische Positionierung von pERK an der Stielmembran sowie die Mikrovillikippung schon zu einem früheren Zeitpunkt in der pupalen Entwicklung. Im adulten Auge war die anti-PY-Markierung im distalen Bereich der Sehzellen intensiver sowie der Kippwinkel vergrößert. In der rl 1/rl 10a-Mutanten mit reduzierter Kinaseaktivität waren die anti-PY-Markierung und der Kippwinkel im proximalen Bereich der Sehzellen verringert. Die Proteinkinase ERK hat somit einen Einfluss auf die zeitliche Etablierung des rhabdomere twisting wie auch auf dessen Ausprägung im Adulttier. Die Rhabdomerverdrehung sowie die Änderung im anti-PY-Markierungsmuster erfolgen an den Sehzellen R1-R6 relativ abrupt auf halber Ommatidienlänge, dort wo das Rhabdomer von R7 endet und das von R8 beginnt. Es stellte sich deshalb die Frage, ob die Rhabdomerverdrehung an R1-R6 durch die Sehzelle R7 und/oder R8 beeinflusst wird. Um dieser Frage nachzugehen wurden Mutanten analysiert, denen die R7- oder die R8-Photorezeptoren bzw. R7 und R8 fehlten. Das wichtigste Ergebnis dieser Untersuchungen war, dass bei Fehlen von R8 die Rhabdomerverdrehung bei R1-R6 nach keinen erkennbaren Regeln erfolgt. R8 ist somit Voraussetzung für die Etablierung der Rhabdomerverdrehung in R1-R6. Folgendes Modell wurde auf Grundlage dieses und weiterer Ergebnisse erarbeitet: Im dritten Larvenstadium rekrutiert R8 die Sehzellpaare R2/R5, R3/R4 und R1/R6. Dabei werden R1-R6 durch den Kontakt zu R8 „polarisiert“. Abschließend wird R7 durch R8 rekrutiert. Dies führt zu einer Fixierung der Polarität von R1-R6 durch R7. Die Ausführung der Mikrovillikippung anhand der festgelegten Polarität erfolgt in der späten Puppenphase. Die Proteinkinase ERK ist an diesem letzten Morphogeneseprozess beteiligt. / Visual cells of insects are epithelial cells with a characteristic morphology and organization. The molecular components of the signalling cascade are arranged in the rhabdomere, an array of densely packed microvilli along the side of the cell body. Already in the 70s of the last century it was described that microvilli point in different directions in various segments of the rhabdomere. Thus, in Dipteran flies (Calliphora, Drosophila) microvilli in the distal part of visual cells R1-R6 are nearly perpendicular to the microvilli in the proximal portion. This phenomenon is termed rhabdomere twisting and decreases the sensitivity of visual cells to polarized light. For Drosophila, structural asymmetry was shown to correlate with molecular asymmetry in the distribution of phosphotyrosinated proteins to the stalk (a non-microvillar region of the apical plasma membrane). Furthermore, this asymmetric distribution of antiphosphotyrosine (anti-PY) provides a light microscopic marker for rhabdomere twisting. So far little is known about the developmental and cell biological basis of rhabdomere twisting. Purpose of the present study was to identify the phosphotyrosinated proteins at the stalk und to analyse their functional relevance for the development of rhabdomere twisting. Moreover, influence of the inner visual cells R7 and R8 on rhabdomere twisting should be examined. Two protein kinases of the MAPK-type, Rolled (ERK) and Basket (JNK), show for their activated (= phosphorylated) forms (pERK and pJNK respectively) an asymmetric distribution to the stalk comparable to labelling with anti-PY. In addition, this asymmetric distribution of pERK, pJNK and also PY is established shortly before eclosion of the fly. Preincubation experiments with anti-PY abolished labelling with anti-pERK and anti-pJNK respectively. These results indicate that pERK and pJNK belong to the proteins on the stalk recognized by anti-PY. ERK and JNK are kinases and therefore are likely to be involved in the development of rhabdomere twisting. To test this hypothesis I analysed hypermorph (rl SEM) and hypomorph (rl 1/rl 10a) rolled mutants. In rl SEM mutants with increased kinase activity asymmetric positioning of pERK to the stalk and tilting of microvilli occurred earlier during pupal development. In the adult eye anti-PY labelling was more intensive in the distal part of the visual cells, and congruently the microvillar tilt angle was increased. In rl 1/rl 10a mutants with reduced kinase activity anti-PY labelling and microvillar tilt angle were reduced in the proximal part of visual cells. Hence, protein kinase ERK has an influence on developmental establishment of rhabdomere twisting and its specification in the adult eye. In R1-R6 rhabdomere twisting as well as changes in anti-PY labelling pattern take place within a narrow range halfway along the rhabdomere where the rhabdomere of R7 ceases and that of R8 begins. So the question arises whether rhabdomere twisting of R1-R6 is influenced by R7 and/or R8. To answer that question I analysed mutants that lack R7 or R8 or both visual cells. Most importantly absence of R8 leads to a disorganized rhabdomere twisting in R1-R6. Consequently R8 seems to be required for the establishment of rhabdomere twisting in R1-R6. Following working model was developed: in the third larval instar R8 recruits pairs of visual cells R2/R5, R3/R4 and R1/R6. In that process R1-R6 become „polarised“ by the contact to R8. Finally R7 is recruited by R8. That fixes polarity of R1-R6 by R7. The active tilting of the microvilli on the basis of the given polarity is carried out in late pupal development with the help of protein kinase ERK.

Komplexauge

Drosophila

Rhabdomerverdrehung

MAPK

compound eye

Drosophila

rhabdomere twisting

MAP kinase

Life sciences

Determining roles of the SUN domain proteins klaroid and Dspag4 in Drosophila development

Kracklauer, Martin, 1971-

18 September 2012

In eukaryotes, the process of nuclear migration is critical in fusion of haploid pronuclei after fertilization, in separation of daughter nuclei during mitosis, and in nuclear positioning in interphase cells. Experiments in several organisms have identified the basic protein requirements for nuclear migration and positioning: molecular motors that provide motive force; the cytoskeleton along which motors move nuclei, or to which the nuclei are anchored; and proteins of the outer and inner nuclear envelopes. These nuclear membrane proteins interact with the motors, the nuclear lamina and each other to effect nuclear migration and positioning. Proteins containing a SUN domain, which were first characterized in S. pombe Sad1 and C. elegans UNC-84, are inner nuclear envelope linkers of the nucleus to the cytoskeleton. In fungi, C. elegans, D. discoideum and vertebrates, these proteins are required not only for nuclear positioning, but also for maintaining the connection of the nucleus to the MTOC, for centrosomal duplication, for homologous pairing of chromosomes in meiosis, for distribution of nuclear pore complexes and for connecting the centrosome to chromatin to ensure genomic stability. The D. melanogaster genome has two genes, CG18584 and CG6589, which encode SUN domain proteins. The specific aims of my dissertation research were to generate null mutants in these genes, to characterize their null phenotypes, and to analyze where the genes are expressed. CG18584 = klaroid mutants are grossly normal, but adult eyes are mildly rough due to a defect in nuclear positioning that occurs during larval eye development. Klaroid protein is perinuclear in every cell of the eye, and functions by localizing the MTOC connector Klarsicht to the outer nuclear envelope. CG6589 = dspag4 null mutants are male sterile. In mature sperm, Dspag4 protein localizes rostrally to the sperm centriole. In the absence of Dspag4, most steps of gametogenesis occur normally, however, prior to the final steps of sperm maturation, the sperm nucleus dissociates from its centriole. Klaroid and Dspag4 thus have cellular roles typical for SUN domain proteins, and Dspag4 is unique in that its function is to attach nuclei to centrioles exclusively in maturing spermatids in the male germline. / text

Drosophila melanogaster--Genetic aspects

Drosophila melanogaster--Development

Compound eye--Growth

Proteins

A Drosophila Winged-helix nude (Whn)-like transcription factor with essential functions throughout development

Sugimura, Isamu, Adachi-Yamada, Takashi, Nishi, Yoshimi, Nishida, Yasuyoshi

06 1900

No description available.

Forkhead

HNF-3

development

nude gene

CNS

PNS

compound eye

dorsal closure

Processos celulares no desenvolvimento do olho composto de Apis mellifera / Celular processes during compound eye development of Apis mellifera

David Santos Marco Antonio

30 May 2008

Os processos que regem o desenvolvimento dos olhos compostos em insetos têm sido amplamente estudados em Drosophila melanogaster onde estes se originam a partir de discos imaginais. Pouco se sabe, porém, sobre o desenvolvimento do lóbulo óptico e da retina em outros insetos que, na sua grande maioria, não possuem discos imaginais de olhos separados do sistema nervoso central. Neste sentido, a análise comparada do desenvolvimento dos olhos de Apis mellifera pode contribuir não somente para aspectos evo-devo entre as grandes famílias dos insetos holometábolos, quanto pode elucidar questões de plasticidade de desenvolvimento pois os olhos compostos apresentam fortes características sexo e casta-específicas. Com o objetivo primário de elucidar os padrões de divisão e diferenciação celular durante o desenvolvimento do olho em A. mellifera realizamos análises histológicas e de imunomarcação durante o desenvolvimento pós-embrionário, juntamente com análise de expressão do gene roughest em tempo real. Para imunomarcação utilizamos o anticorpo anti-fosfo-histona H3 fosforilada que marca células em fase M do ciclo celular. Foram analisadas larvas operárias entre o terceiro instar larval (L3) até pupas de olho branco, rosa e marrom, com foco sobre o quinto instar larval que fica subdividida em fase de alimentação e crescimento (L5F), fases de tecelagem de casulo (L5S) e prepupa (PP). O desenvolvimento do lóbulo óptico em Apis mellifera ocorre por dobramento neuroepitelial, a partir de um centro de diferenciação, seqüencialmente gerando as camadas neurais do lóbulo óptico (lóbula, medula e lâmina). A lâmina (última a surgir) 6 apresentou-se com desenvolvimento mais lento e em duas fases antes da metamorfose: a primeira fase é o seu surgimento no começo do quinto instar larval acompanhando o primeiro pico de expressão de roughest e a segunda fase ocorre durante a tecelagem de casulo com o desenvolvimento do córtex acompanhando o segundo pico de expressão de roughest. Ainda durante o segundo pico de expressão de roughest os rabdômeros da retina começam a ficar visíveis, assim como os feixes axonais. Estes porém estarão completamente formados somente após a metamorfose.. O desenvolvimento completo da lâmina, lóbula e medula e da retina ocorre somente após a metamorfose. Durante a fase pupal as estruturas do lóbulo óptico estão prontas, porém na retina observa-se ainda gradual pigmentação, encurtamento dos feixes axonais e alongamento dos rabdômeros até atingirem o seu comprimento final logo antes da emergência. / The processes that drive compound eye development in insects have been broadly studied in Drosophila melanogaster in which they arise from imaginal discs. Little is known about optic lobe and retina development in other insects, most of which do not have imaginal eye discs attached to the nervous system. For this reason, a comparative analysis of eye development in the honey bee, Apis mellifera, not only contributes to evo-devo aspects comparing the major families of holometabolous insects, but also may elucidate questions about developmental plasticity because the compound eyes of the honeybee show strong sex and caste-specific differences. Since our primary objective was to elucidate the pattern of cellular differentiation and division during eye development we performed histological and immunolabelling analyses during the postembrionic stages of development, concomitant with a realtime analysis of roughest gene expression. For the immunolabelling experiments we used an anti-phospho-histone H3 antibody that labels cells in M phase. We analyzed eye development in worker larvae starting with the third instar until white, pink and browneyed pupae, paying special attention to the fifth instar which was subdivided into feeding phase (L5F), cocoon spinning phase (L5S) and prepupae (PP). Optic Lobe development in Apis mellifera occurs by neuroepithelial folding initiating from a differentiation center, in the larval brain. This center sequentially produces the neural layers of the optic lobe (medulla, lobula and lamina). Development of the lamina, which is the last layer to be formed, takes more time and happens in two steps before metamorphosis. The first step is emergence at the beginning of the fifth larval instar coinciding with the first peak of roughest gene expression. The second step 8 occurs during the cocoon spinning phase and is marked by its inner differentiation, again accompanied by a second peak of roughest expression. During this second peak of roughest expression the rabdomers in the retina become visible. These, however, cplete thir development only during the pupal stage. The development of the lamina, lobula and medulla is not complete until after metamorphosis, even though these optic lobe structures are structurally defined already at the beginning of the pupal phase. Retinal development in this phase is marked by gradual pigmentation, axonal bundle shortening and rabdomer elongation, which reach their final size just prior to emergence of the bees from their brood cells.

Apis mellifera

lóbulo óptico

olho composto

retina

roughest

Apis mellifera

compound eye

optic lobe

retina

roughest