Fate of neuroblast progeny during postembryonic development of mushroom bodies in the house cricket,Acheta domesticus

Mushroom bodies represent the main sensory integrative center of the insect brain and probably play a major role in the adaptation of behavioral responses to the environment. Taking into account the continuous neurogenesis of cricket mushroom bodies, we investigated ontogenesis of this brain structure. Using BrdU labeling, we examined the fate of neuroblast progeny during the postembryonic development. Preimaginal Kenyon cells survived throughout larval and imaginal moults and persisted during adulthood. Our results indicate that the location of labelled Kenyon cells in the cortex of the adult cricket mainly depends upon the period when they were produced during development. The present data demonstrate that cricket mushroom bodies grow from the inside out and that, at any developmental stage, the center of the cortex contains the youngest Kenyon cells. This study also allowed us to observe the occurrence of quiescent neuroblasts. Kenyon cell death during postembryonic and adult life seems to be reduced. Although preimaginal Kenyon cells largely contribute to adult mushroom body structure, a permanent remodeling of the mushroom body occurs throughout the whole insect life due to the persistence of neurogenesis in the house cricket. Further studies are needed to understand the functional significance of these findings.     

Mcm3 replicative helicase mutation impairs neuroblast proliferation and memory in Drosophila

In the developing Drosophila brain, a small number of neural progenitor cells (neuroblasts) generate in a co‐ordinated manner a high variety of neuronal cells by integration of temporal, spatial and cell‐intrinsic information. In this study, we performed the molecular and phenotypic characterization of a structural brain mutant called small mushroom bodies (smu), which was isolated in a screen for mutants with altered brain structure. Focusing on the mushroom body neuroblast lineages we show that failure of neuroblasts to generate the normal number of mushroom body neurons (Kenyon cells) is the major cause of the smu phenotype. In particular, the premature loss of mushroom body neuroblasts caused a pronounced effect on the number of late‐born Kenyon cells. Neuroblasts showed no obvious defects in processes controlling asymmetric cell division, but generated less ganglion mother cells. Cloning of smu uncovered a single amino acid substitution in an evolutionarily conserved protein interaction domain of the Minichromosome maintenance 3 (Mcm3) protein. Mcm3 is part of the multimeric Cdc45/Mcm/GINS (CMG) complex, which functions as a helicase during DNA replication. We propose that at least in the case of mushroom body neuroblasts, timely replication is not only required for continuous proliferation but also for their survival. The absence of Kenyon cells in smu reduced learning and early phases of conditioned olfactory memory. Corresponding to the absence of late‐born Kenyon cells projecting to α′/β′ and α/β lobes, smu is profoundly defective in later phases of persistent memory.     

Developmental organization of the mushroom bodies of Thermobia domestica (Zygentoma, Lepismatidae): insights into mushroom body evolution from a basal insect

The mushroom bodies of the insect brain are sensory integration centers best studied for their role in learning and memory. Studies of mushroom body structure and development in neopteran insects have revealed conserved morphogenetic mechanisms. The sequential production of morphologically distinct intrinsic neuron (Kenyon cell) subpopulations by mushroom body neuroblasts and the integration of newborn neurons via a discrete ingrowth tract results in an age-based organization of modular subunits in the primary output neuropil of the mushroom bodies, the lobes. To determine whether these may represent ancestral characteristics, the present account assesses mushroom body organization and development in the basal wingless insect Thermobia domestica. In this insect, a single calyx supplied by the progeny of two neuroblast clusters, and three perpendicularly oriented lobes are readily identifiable. The lobes are subdivided into 15 globular subdivisions (Trauben). Lifelong neurogenesis is observed, with axons of newborn Kenyon cells entering the lobes via an ingrowth core. The Trauben do not appear progressively during development, indicating that they do not represent the ramifications of sequentially produced subpopulations of Kenyon cells. Instead, a single Kenyon cell population produces highly branched axons that supply all lobe subdivisions. This suggests that although the ground plan for neopteran mushroom bodies existed in early insects, the organization of modular subunits composed of separate Kenyon cell subpopulations is a later innovation. Similarities between the calyx of Thermobia and the highly derived fruit fly Drosophila melanogaster also suggest a correlation between calyx morphology and Kenyon cell number.     

Metamorphosis and adult development of the mushroom bodies of the red flour beetle, Tribolium castaneum

The insect mushroom bodies play important roles in a number of higher processing functions such as sensory integration, higher level olfactory processing, and spatial and associative learning and memory. These functions have been established through studies in a handful of tractable model systems, of which only the fruit fly Drosophila melanogaster has been readily amenable to genetic manipulations. The red flour beetle Tribolium castaneum has a sequenced genome and has been subject to the development of molecular tools for the ready manipulation of gene expression; however, little is known about the development and organization of the mushroom bodies of this insect. The present account bridges this gap by demonstrating that the organization of the Tribolium mushroom bodies is strikingly like that of the fruit fly, with the significant exception that the timeline of neurogenesis is shifted so that the last population of Kenyon cells is born entirely after adult eclosion. Tribolium Kenyon cells are generated by two large neuroblasts per hemisphere and segregate into an early-born delta lobe subpopulation followed by clear homologs of the Drosophila gamma, alpha'/beta' and alpha/beta lobe subpopulations, with the larval-born cohorts undergoing dendritic reorganization during metamorphosis. BrdU labeling and immunohistochemical staining also reveal that a proportion of individual Tribolium have variable numbers of mushroom body neuroblasts. If heritable, this variation represents a unique opportunity for further studies of the genetic control of brain region size through the control of neuroblast number and cell cycle dynamics.     

Mitogenic effects of 20‐hydroxyecdysone on neurogenesis in adult mushroom bodies of the cockroach,Diploptera punctata

The purpose of this study was to examine the mitogenic effects of 20‐hydroxyecdysone on neurogenesis in mushroom bodies of the adult cockroach, Diploptera punctata. The occurrence of neurogenesis was studied immunocytochemically after in vivo labeling with 5‐bromo‐2′‐deoxyuridine (BrdU). The number of BrdU‐labeled cells in the mushroom bodies was high shortly after adult ecdysis, then gradually decreased, and proliferation ceased on day 8. 20‐Hydroxyecdysone injection during the early adult stages significantly delayed the decrease in mitotic activity. Moreover, 20‐hydroxyecdysone injection during the late stage stimulated quiescent mushroom body neuroblasts to initiate their mitotic activity in a dose‐dependent manner. These results indicated that the mushroom body neuroblasts of this insect become quiescent in the maturing central nervous system, but retain the capacity for proliferation if exposed to appropriate environmental signals. We conclude that 20‐hydroxyecdysone has a mitogenic effect on neurogenesis in mushroom bodies of this insect. © 1999 John Wiley & Sons, Inc. J Neurobiol 39: 264–274, 1999     

Diversity in neuroblast number forming mushroom bodies of the higher dipterans (Insecta,Diptera, Brachycera Cyclorrhapha)

Neurogenesis in mushroom bodies is studied in 12 species of the higher dipterans. A significant difference in the number of neuroblasts forming mushroom bodies is found. In the majority of species studied, Kenyon cells are formed by four solitary neuroblasts. Among six calliphorid species, the number of neuroblasts increases up to 10–15 (mean 12.6) in each mushroom body in Calliphora vicina only. In young pupae of Muscina stabulans and M. livida, four polyneuroblastic prolipherative centers occur instead of solitary neuroblasts. These centers disintegrate later into numerous solitary neuroblasts. A hypothesis on the origin of the polyneuroblastic structure of mushroom bodies found in C. vicina and, earlier, in Musca domestica, is proposed.     

Mushroom Body Neuroblasts of the Lepidopteran Brain (Insecta: Lepidoptera)

A study of the brain of 47 species from 15 lepidopteran families has revealed that only one neuroblast corresponds to each calyx cup of the mushroom body and that mushroom body neuroblasts have been found in the imagoes of 13 out of 25 species caught in the field. It is considered that the proliferative centers consisting of several neuroblasts are not characteristic of lepidopteran mushroom bodies, whereras Kenyon cell neurogenesis in the imago appears to be a widespread phenomenon.     

中华蜜蜂蕈形体的发育

中华蜜蜂(Apis cerana cerana)的脑由前脑、中脑和后脑三部分构成,蕈形体位于前脑的背侧,是其重要的学习及其他复杂行为的整合中心。通过对中华蜜蜂工蜂的幼虫、蛹及成虫的蕈形体形态发育的观察研究,发现中华蜜蜂的蕈形体包含约1000个成神经细胞,它们最终形成了蕈形体的所有Kenyon细胞。这些成神经细胞来自于在新孵化的幼虫脑中已存在的四丛成神经细胞,每一丛细胞的数量不多于45个。蕈形体柄区的出现约在3龄幼虫,而α叶和β叶在5龄幼虫已可明显辨认。冠区出现较晚,大约在蛹期的第二天以后。由于社会性昆虫复杂的学习、记忆和认知需求,其蕈形体的体积和复杂程度都优于其他昆虫。     

Early development of the Drosophila mushroom bodies, brain centres for associative learning and memory

We have studied the formation of Drosophila mushroom bodies using enhancer detector techniques to visualize specific components of these complex intrinsic brain structures. During embryogenesis, neuronal proliferation begins in four mushroom body neuroblasts and the major axonal pathways of the mushroom bodies are pioneered. During larval development, neuronal proliferation continues and further axonal projections in the pedunculus and lobes are formed in a highly structured manner characterized by spatial heterogeneity of reporter gene expression. Enhancer detector analysis identifies many genomic locations that are specifically activated in mushroom body intrinsic neurons (Kenyon cells) during the transition from embryonic to postembryonic development and during metamorphosis.     

Not all dytiscidae have poorly developed mushroom bodies: The enigma of Cybister lateralimarginalis

The majority of diving beetles studied has completely differentiated but poorly developed mushroom bodies. The Kenyon cells are not numerous, the calyces are small, and the pedunculi and lobes have a simple structure. New Kenyon cells are produced by few solitary neuroblasts. Cybister lateralimarginalis makes an amazing exception. Its mushroom bodies are strongly developed and comprise numerous Kenyon cells, large calyces, and a peduncular apparatus of a complicated structure. The Kenyon cells are produced in polyneuroblast proliferative centers. The grounds of such strong development of the mushroom body in Cybister remain unknown.     

Male-associated polypeptide (MAP) expression in different compartments of the reproductive system of the mussel Mytilus galloprovincialis: immunocytochemical and Western blot study

The dissociation and maintenance in culture of cells derived from the mushroom bodies of adult crickets (Acheta domesticus) are described. This primary culture was developed in order to investigate maturation and differentiation of mushroom-body cells including Kenyon cells, the major intrinsic interneurons of mushroom bodies, which have been shown to be involved in learning and memory in insects. Three distinct cell types were observed, all identified as neural cells on the basis of their size, morphology and immunocytochemical staining with horseradish peroxidase. These cells appear to correspond to the three cell types observed in vivo: Kenyon cells, ganglion mother cells and neuroblasts. Some cells showed neurite growth, usually with long unipolar processes, occasionally with either bipolar or, more rarely, multipolar processes. Neuronal cell bodies readily formed seals with patch pipettes, allowing stable, whole-cell, patch-clamp electrophysiological recordings. Depolarization of the cell under voltage-clamp resulted in at least two types of outwardly directed potassium currents: a delayed rectifier-type of current that was sensitive to tetraethylammonium, and a cadmium-sensitive current with rapid inactivation. Neither type of current was affected by quinidine, a blocker of potassium currents recorded from pupal honeybee Kenyon cells. Other ionic currents, which have yet to be characterized, were also observed. Received: 30 October 1996 / Accepted: 11 July 1997     

Mitogenic effects of 20-hydroxyecdysone on neurogenesis in adult mushroom bodies of the cockroach, Diploptera punctata

The purpose of this study was to examine the mitogenic effects of 20-hydroxyecdysone on neurogenesis in mushroom bodies of the adult cockroach, Diploptera punctata. The occurrence of neurogenesis was studied immunocytochemically after in vivo labeling with 5-bromo-2'-deoxyuridine (BrdU). The number of BrdU-labeled cells in the mushroom bodies was high shortly after adult ecdysis, then gradually decreased, and proliferation ceased on day 8. 20-Hydroxyecdysone injection during the early adult stages significantly delayed the decrease in mitotic activity. Moreover, 20-hydroxyecdysone injection during the late stage stimulated quiescent mushroom body neuroblasts to initiate their mitotic activity in a dose-dependent manner. These results indicated that the mushroom body neuroblasts of this insect become quiescent in the maturing central nervous system, but retain the capacity for proliferation if exposed to appropriate environmental signals. We conclude that 20-hydroxyecdysone has a mitogenic effect on neurogenesis in mushroom bodies of this insect.     

Evolution of insect mushroom bodies: old clues,new insights

The mushroom bodies are a morphologically diverse sensory integration and learning and memory center in the brains of various invertebrate species, of which those of insects are the best described. Insect mushroom bodies are composed of numerous tiny intrinsic neurons (Kenyon cells) that form calyces with their dendrites and a pedunculus and lobes with their axons. The identities of conserved Kenyon cell subpopulations and the correlations between morphological and functional specializations of the mushroom bodies are just beginning to be elucidated, providing insight into mechanisms of mushroom body evolution. Comparisons of mushroom body organization in different insect lineages reveal trends in the evolution of subcompartments correlated with the elaboration, reduction, acquisition or loss of Kenyon cell subpopulations. Furthermore, these changes often appear correlated with variation in type and strength of afferent input and in behavioral ecology. These and other features of mushroom body organization suggest a striking convergence with mammalian cortex, with Kenyon cell subpopulations displaying evolutionary modularity in a manner reminiscent of cortical areas.     

Histological structure of tripartite mushroom bodies in ground beetles (Insecta, Coleoptera: Carabidae)

Contrary to members of the suborder Polyphaga, ground beetles have been found to possess tripartite mushroom bodies, which are poorly developed in members of basal taxa and maximally elaborated in evolutionarily advanced groups. Nevertheless, they do not reach the developmental stage, which has been previously found in particular families of beetles. It has been pointed out that a new formation of the Kenyon cells occurs during at least the first months of adult life, and inactive neuroblasts are found even in one-year-old beetles. It has been suggested that there is a relation between the Kenyon cell number and development of the centers of Kenyon cell new-formation.     

20-Hydroxyecdysone inhibits the mitotic activity of neuronal precursors in the developing mushroom bodies of the honeybee,Apis mellifera

The mushroom bodies (MBs) within the brain of the honeybee, Apis mellifera, are prominent paired neuropil structures consisting of a lateral and a median subunit. The intrinsic MB neurons (Kenyon cells) of each of these subunits are generated in four distinct proliferation centers, each associated with a calyx. Previous BrdU studies revealed that neurogenesis of Kenyon cells starts at the first larval stage (L1) by symmetrical cell division of Kenyon precursor cells, and ceases abruptly at a midpupal stage (P5). In the present work, we confirmed these results using the antiphospho histone H3 mitosis marker to label mitotically active cells in a cell culture system, in histological sections, and in whole-mount brain preparations. To elucidate whether the steroid hormone ecdysone plays a role in the termination of Kenyon cell neurogenesis, we manipulated the hormone titer by injecting 20-hydroxyecdysone (20E) into animals of those pupal stages (P0/1, P3, P4) in which neurogenesis of Kenyon cells was still extensive. The effects of 20E were evaluated by determining the number of mitotically active cells in confocal microscopic images of squash preparations of the MB proliferation centers. In all pupal stages studied, 20E caused a reduction of mitotic activity, indicating its involvement in the cessation of Kenyon cell neurogenesis.     

Understanding the regulation and function of adult neurogenesis: contribution from an insect model, the house cricket

Since the discovery of adult neurogenesis, a major issue is the role of newborn neurons and the function-dependent regulation of adult neurogenesis. We decided to use an animal model with a relatively simple brain to address these questions. In the adult cricket brain as in mammals, new neurons are produced throughout life. This neurogenesis occurs in the main integrative centers of the insect brain, the mushroom bodies (MBs), where the neuroblasts responsible for their formation persist after the imaginal molt. The rate of production of new neurons is controlled not only by internal cues such as morphogenetic hormones but also by external environmental cues. Adult crickets reared in an enriched sensory environment experienced an increase in neuroblast proliferation as compared with crickets reared in an impoverished environment. In addition, unilateral sensory deprivation led to reduced neurogenesis in the MB ipsilateral to the lesion. In search of a functional role for the new cells, we specifically ablated MB neuroblasts in young adults using brain-focused gamma ray irradiation. We developed a learning paradigm adapted to the cricket, which we call the "escape paradigm." Using this operant associative learning test, we showed that crickets lacking neurogenesis exhibited delayed learning and reduced memory retention of the task when olfactory cues were used. Our results suggest that environmental cues are able to influence adult neurogenesis and that, in turn, newly generated neurons participate in olfactory integration, optimizing learning abilities of the animal, and thus its adaptation to its environment. Nevertheless, odor learning in adult insects cannot always be attributed to newly born neurons because neurogenesis is completed earlier in development in many insect species. In addition, many of the irradiated crickets performed significantly better than chance on the operant learning task.     

Novel Middle-Type Kenyon Cells in the Honeybee Brain Revealed by Area-Preferential Gene Expression Analysis

The mushroom bodies (a higher center) of the honeybee (Apis mellifera L) brain were considered to comprise three types of intrinsic neurons, including large- and small-type Kenyon cells that have distinct gene expression profiles. Although previous neural activity mapping using the immediate early gene kakusei suggested that small-type Kenyon cells are mainly active in forager brains, the precise Kenyon cell types that are active in the forager brain remain to be elucidated. We searched for novel gene(s) that are expressed in an area-preferential manner in the honeybee brain. By identifying and analyzing expression of a gene that we termed mKast (middle-type Kenyon cell-preferential arrestin-related protein), we discovered novel ‘middle-type Kenyon cells’ that are sandwiched between large- and small-type Kenyon cells and have a gene expression profile almost complementary to those of large– and small-type Kenyon cells. Expression analysis of kakusei revealed that both small-type Kenyon cells and some middle-type Kenyon cells are active in the forager brains, suggesting their possible involvement in information processing during the foraging flight. mKast expression began after the differentiation of small- and large-type Kenyon cells during metamorphosis, suggesting that middle-type Kenyon cells differentiate by modifying some characteristics of large– and/or small-type Kenyon cells. Interestingly, CaMKII and mKast, marker genes for large– and middle-type Kenyon cells, respectively, were preferentially expressed in a distinct set of optic lobe (a visual center) neurons. Our findings suggested that it is not simply the Kenyon cell-preferential gene expression profiles, rather, a ‘clustering’ of neurons with similar gene expression profiles as particular Kenyon cell types that characterize the honeybee mushroom body structure.     

Proliferation pattern of postembryonic neuroblasts in the brain of Drosophila melanogaster.

The spatio-temporal proliferation pattern of postembryonic neuroblasts in the central brain region of the supra-esophageal ganglion of Drosophila melanogaster was studied by labeling DNA replicating cells with 5-bromo-2'-deoxyuridine (BrdU). There are five proliferating neuroblasts per hemisphere in larvae just after hatching: one in the ventro-lateral, and the other four in the postero-dorsal region of the brain. Dividing neuroblasts increase during the late first-late second instar larval stages, reaching a plateau of about 85 neuroblasts per hemisphere. Most neuroblasts cease dividing 20-30 hr after puparium formation (APF), while only four in the postero-dorsal region continue making progenies until 85-90 hr APF. The four distinct neuroblasts proliferating in the early larval and late pupal stages are identical; they lie in the cortex above the calyces of the mushroom bodies (corpora pedunculata), proliferating over a period twice as long as that for the other neuroblasts. Their daughter neurons project into the mushroom body neuropile, and hence are likely to be the Kenyon cells. The cell-cycle period of the four neuroblasts (named mushroom body neuroblasts: MBNbs) is rather constant (1.1-1.5 hr) during the mid larval-early pupal stages and is longer before and after that. The total number of the MBNb progenies made throughout the embryonic and postembryonic development was estimated to be 800-1200 per hemisphere.     

Development and evolution of the insect mushroom bodies: towards the understanding of conserved developmental mechanisms in a higher brain center

The insect mushroom bodies are prominent higher order neuropils consisting of thousands of approximately parallel projecting intrinsic neurons arising from the minute basophilic perikarya of globuli cells. Early studies described these structures as centers for intelligence and other higher functions; at present, the mushroom bodies are regarded as important models for the neural basis of learning and memory. The insect mushroom bodies share a similar general morphology, and the same basic sequence of developmental events is observed across a wide range of insect taxa. Globuli cell progenitors arise in the embryo and proliferate throughout the greater part of juvenile development. Discrete morphological and functional subpopulations of globuli cells (or Kenyon cells, as they are called in insects) are sequentially produced at distinct periods of development. Kenyon cell somata are arranged by age around the center of proliferation, as are their processes in the mushroom body neuropil. Other aspects of mushroom body development are more variable from species to species, such as the origin of specific Kenyon cell populations and neuropil substructures, as well as the timing and pace of the general developmental sequence.     

Influence of environmental stimulation on neurogenesis in the adult insect brain

Mushroom bodies are the main integrative structures of insect brain. They receive sensory information from the eyes, the palps, and the antennae. In the house cricket, Acheta domesticus, a cluster of mushroom body neuroblasts keeps producing new interneurons during an insect's life span. The aim of the present work is to study the impact of environmental stimuli on mushroom body neurogenesis during adulthood. Crickets were reared either in an enriched environment, where they received complex environmental and congeneric stimulations or isolated in small cages and deprived of most visual, auditory, and olfactory stimuli. They then were injected with a S-phase marker, 5-bromo, 2'-deoxyuridine (BrdU) and sacrificed at different periods of their life. Neurogenesis and cell survival were estimated by counting the number of BrdU-labeled cells in the mushroom bodies. Environmentally enriched crickets were found to have an increased number of newborn cells in their mushroom bodies compared with crickets housed in cages with an impoverished environment. This effect of external factors on neurogenesis seems to be limited to the beginning of imaginal life. Furthermore, no cell loss could be detected among the newborn neurons in either environmental situation, suggesting that cell survival was not affected by the quality of the environment. Considering vertebrate studies which showed that enriched environment increases hippocampal cell survival and improves animal performances in spatial learning tests, we suggest that the increased number of interneurons produced in an integrative brain structure after exposure to enriched environment could contribute to adaptive behavioral performances in adult insects.