Olaf Breidbach

Homologous Structures in the Nervous Systems of Arthropoda

Publisher Summary This chapter deals with the homologous structures in the nervous systems of Arthropoda. The Arthropoda constitute the phylum with the highest diversity of species in the animal kingdom. Originated in the Precambrium, this monophylum basically consists of two groups, the Chelicerata and the Mandibulata. The common ancestor of the arthropods has to be regarded as an annelid-like species, with an exoskeleton, serial homologous segments bearing a series of repetitively structured appendages, and possessing fused “head”-segments in the anterior region. Recent fossil evidence has debilitated an alternative view, the uniramian concept which regards the Arthropoda as a polyphylum. According to the concept of an arthropod monophylum, compartments of the nervous system reveal some of the synapomorphies of this phylum. The Onychophora represent a taxon which is regarded to have evolved convergently to the arthropod phylum. This chapter explores new evidences that suggest they are a sister-group of the Chelicerata. Peripatus has a brain with several similarities to neuropile regions in the spider brain, for example the “mushroom bodies” and the “central body”.

Structure and development of the larval central complex in a holometabolous insect, the beetle Tenebrio molitor

SummaryThe neuroarchitecture of the central complex, a prominent neuropil in the midbrain of the holometabolan, Tenebrio molitor, is described throughout larval development. The analysis is based on classical silver impregnations and on fate-mapping of identified neurons using antisera against serotonin and FMRF-amide. In T. molitor, the central body is present in the first larval instar, and is formed by side branches of contralaterally projecting neurons. Glial cells surround eight neuropil compartments in the first larval instar. These subdivisions in the organization of the fan-shaped body are maintained throughout development. Intrinsic interneurons are found from the 5th larval instar onwards. In the last larval stage, the central complex consists of the fan-shaped body, the protocerebral bridge, and the anlage of the ellipsoid body. The cellular architecture of the fan-shaped body of the last larval instar resembles the basic structural characteristics of the adult. Serotonin-immunoreactive neurons and FMRF-amide immunoreactive neurons in the midbrain of the first larval instar show the basic structural features of the respective imaginal cells. The structural organizations of larval and adult midbrain are compared.

Development of locustatachykinin immunopositive neurons in the central complex of the beetle Tenebrio molitor

Locustatachykinin‐immunoreactive (LomTK‐IR) interneurons were found to be associated with the central complex, a prominent neuropil region of the insect brain. The structures and development of this set of brain interneurons was studied from the embryo onward in the beetle Tenebrio molitor, showing individual neurons that persist from the late embryo to the adult stage. Their essential structural characteristics were already present in the late embryo, but distinct parts of their arborization patterns became newly formed throughout development. Using a combination of immunohistochemistry and single‐cell injection, we demonstrated minute structural changes, allowing a characterization of structural plasticity of identifiable, persistent, neuropeptidergic neurons throughout ontogenesis. Furthermore, this study has provided new information about basic principles of central brain neuroanatomy and the development of a distinct midbrain region of the insect brain, the central complex. The development of its basic connections, the connections between the fan‐shaped body and the protocerebral bridge, and the compartmentation of these neuropil regions were shown, using LomTK‐IR neurons as marker structures. These basic features of the central complex‐associated LomTK‐immunopositive neurons were formed in the embryonic brain, whereas in metamorphosis, reorganization of these persistent interneurons was restricted to the formation of a precisely defined projection of their side branches.

Serotonin-immunoreactive brain interneurons persist during metamorphosis of an insect: a developmental study of the brain of Tenebrio molitor L. (Coleoptera)

SummarySerotonin-immunoreactive neurons in the brain of Tenebrio molitor L. have been demonstrated and mapped throughout metamorphosis. Most serotonin-immunoreactive brain neurons persist throughout metamorphosis; their fate can be followed during development because of their characteristic cell body locations and arborization patterns. The detailed morphology of the persisting neurons, however, changes during metamorphosis, probably to accommodate architectural changes of the different brain centers. Serotonin-immunoreactivity in the optic lobes allows a subset of neurons that is newly differentiated during metamorphosis to be identified. Phylogenetic homology of serotonin-immunoreactive brain interneurons of different insect species is discussed. The serotonin-immunoreactive brain neurons comprise a phylogenetically conserved neuronal population. Serial homologous abdomino-thoracic and brain serotonin-immunoreactive neurons were characterized, allowing a comparison of some basic structural features of these neurons.

Crustacean cardioactive peptide-immunoreactive neurons in the ventral nerve cord and the brain of the meal beetle Tenebrio molitor during postembryonic development

SummaryBy use of an antiserum against the crustacean cardioactive peptide (CCAP) several types of bilaterally symmetrical neurons have been mapped quantitatively in the ventral nerve cord and in the brain of the meal beetle, Tenebrio molitor. The general architecture of these neurons was reconstructed from peroxidase-antiperoxidase-labelled whole-mount preparations. From the subesophageal to the seventh abdominal ganglia two types of neurons show a repetitive organization of contralateral projection patterns in each neuromere. The first type has few branches in the central neuropil and a distinct peripheral projection. The second type is characterized by an elaborate central branching pattern, which includes ascending and descending processes. Some of its peripheral branches were found to supply peripheral neurohemal areas. In the protocerebrum, 10 CCAP-immunoreactive neurons occur with projections into the superior median protocerebrum and the tritocerebrum. Immunopositive neurons were mapped in larval and various pupal stages, as well as in the adult. All types of identified neurons were found to persist throughout metamorphosis maintaining their essential structural and topological characteristics. The CCAP-immunoreactive neurons of T. molitor are compared with those described for the locust. Putative structural homologies of subsets of neurons in both species are discussed.

The fate of persisting thoracic neurons during metamorphosis of the meal beetle Tenebrio molitor (Insecta= Coleoptera)

SummaryA set of motor neurons and interneurons in the thoracic nervous system of the meal beetle Tenebrio molitor L. is described that persist during metamorphosis. The motor neurons under discussion innervate the thoracic ventral longitudinal muscles and were identified by retrograde transport of intramuscularly injected horseradish peroxidase. Persisting motor neurons exhibit a complex repetitive pattern that changes only slightly during development. Additionally, the characterization of serotonin-immunoreactive neurons defines a complex set of interneurons that also persist throughout development. The fate of these identified neurons is outlined in detail with special reference to variations in their dendritic arborizations. All motor and interneurons are affected by a similar change in their shape during development. The larval neurons lack the contralateral arborization that is found in the adult beetle and is already distinguishable in the prepupa. Essentially only quantitative changes of the neuronal shape were observed during the pupal instar. No pupa-specific degeneration of certain axo-dendritic structures of these neurons was found. Removal of descending interneurons by sectioning the promesothoracic connectives causes specific degeneration of the dendritic tree of an identified serotonin-immunoreactive interneuron.

Comparative aspects of the chelicerate nervous systems

Main features of the neuroanatomical organization of recent Chelicerata are described. Thereby, it is possible to characterize a general scheme of the chelicerate brain that includes neuropil regions as the “central body” and the “corpora pedunculata”. Application of immunohistochemistry allows a description of identified neurons associated with these neuropil regions. Such neurons have been characterized as being homologous in different arachnid species. The chapter discusses whether these neurons form part of a ground plan of the arachnid brain.

Brain dysmaturity index for automatic detection of high-risk infants

The definition of an electroencephalographic (EEG)-based brain dysmaturity index that could allow automatic detection of neonates who deviate from expected ontogenetic patterns is proposed. The investigation was performed in a group of 94 term and preterm infants (28-112 weeks postconceptional age). For each neonate, one continuous two-channel EEG of 1-6 hours was recorded. The cluster analysis of different age groups was performed with a self-referential neural network. The network performed a nonlinear discriminant analysis; the synaptic strength of input nodes indicates the relevance of an individual EEG feature. The most relevant EEG features are given by the average amplitude in the delta and theta bands and by the relative amplitudes of beta-1/theta and beta-1/delta, respectively. The correlation between the frequency shifts and the postconceptional age agreed with measures of brain dysmaturity in healthy preterm neonates. Thus the presented trend in early EEG development demonstrates that it is possible to establish clinically relevant age dysmaturity scores.

Proctolin-immunoreactive neurons persist during metamorphosis of an insect: A developmental study of the ventral nerve cord of Tenebrio molitor(Coleoptera)

SummaryProctolin-immunoreactive neurons in all neuromers of the ventral nerve cord of Tenebrio molitor L. have been quantitatively demonstrated and mapped throughout metamorphosis. Each neuromer contains an anterior and a posterior group of neurons with light and dark staining properties as revealed by peroxidase-antiperoxidase labeling. Serial homologous subsets of dark staining neurons with central and peripheral projections have been identified and found to persist during morphogenetic changes from the larva to the adult. Most neurons maintain their topological and structural characteristics throughout metamorphosis. The identified proctolin-immunoreactive neurons exhibit structures similar to those described in other insect species; some may correspond known motoneurons.

Constancy and variation of the serotonin-like immunoreactive neurons in the metamorphosing ventral nerve cord of the meal beetle, Tenebrio molitor L. (Coleoptera : Tenebrionidae)

Serotonin-like immunoreactive neurons were mapped in the larval, prepupal, pupal, and adult ventral nerve cord (VNC) of the beetle, Tenebrio molitor L. (Coleoptera: Tenebrionidae). The alterations of the shape of these neurons during metamorphosis were analysed. The stage-specific interindividual variability of the examined serotonin-like immunoreactive neurons is low. Serotonin-like immunoreactive neurons of the abdominal and thoracic ganglia behave differently during metamorphosis. Only in thoracic ganglia was an obvious change in the pattern of serotonin-like immunoreactive neurons observed. The shape of the dendritic trees of serotonin-like immunoreactive neurons varies in thoracic., but not in abdominal ganglia. During postlarval development, new emerging neurons that react with the anti-serotonin antibody are found only in the thoracic ganglia. Serotonin-like immunoreactive neurons are serially homologous in the larval ventral nerve cord. The basic organization of the serotonin-like immunoreactive neurons is maintained up to the adult stage. Some aspects of the metamorphosis of the nervous system are discussed with respect to the transformation of the set of immunoreactive neurons from larval to adult stage. The results are compared to those obtained in the study of serotonin-immunoreactive neurons in cockroaches, dipterans and locusts.