Eduardo R. Macagno

Coding of olfactory information: Topography of odorant receptor expression in the catfish olfactory epithelium

Discrimination among the vast array of odors requires that the brain discern which of the numerous odorant receptors have been activated. If individual olfactory neurons express only a subset of the odorant receptor repertoire, then the nature of a given odorant can be discerned by identifying which cells have been activated. We performed in situ hybridization experiments demonstrating that individual olfactory neurons express different complements of odorant receptors and are therefore functionally distinct. Thus, a topographic map, defining either the positions of specific neurons in the epithelium or the positions of their projections, may be employed to determine the quality of an olfactory stimulus. Neurons expressing specific receptors appear to be randomly distributed within the olfactory epithelium. These data are consistent with a model in which randomly dispersed olfactory neurons with common receptor specificities project to common glomeruli in the olfactory bulb.

UV photoreceptors in the compound eye of Daphnia magna (Crustacea, Branchiopoda). A fourth spectral class in single ommatidia.

SummaryThe spectral sensitivities of individually stimulated ommatidia in the compound eye of Daphnia magna were measured using a fast spectral scan voltage-clamp technique with extracellular recording. Chromatic adaptation was used to reveal the contributions of individual spectral classes of photoreceptors to the ommatidial sensitivity. Ommatidia in the dorsal and ventral regions of the compound eye were tested. Four spectral classes of photoreceptors were found in each ommatidium, among them a previously undetected class with peak sensitivity in the ultraviolet. The wavelengths of peak sensitivity were at 348, 434, 525, and 608 nm for the dorsal ommatidia. The three longer wavelength classes agreed well with those found previously by intracellular recording (Schehr 1984). Only small differences in wavelength and magnitude of peak sensitivity were found between the four classes in the dorsal versus ventral ommatidia.

Cellular interactions and pattern formation in the development of the visual system ofDaphnia magna (crustacea, branchiopoda): I. Interactions between embryonic retinular fibers and laminar neurons

Retinular cells in the Daphnia compound eye were deleted at specified developmental stages and in adults to test the hypothesis that growing retinular fibers trigger the differentiation of laminar neurons, thereby recruiting them as synaptic targets and organizing them into a particular structural pattern. Deletion of retinular neurons was accomplished by producing small lesions with either ultraviolet or laser microbeams. The effects of the lesions on the eye and optic ganglion were assayed quantitatively using computerized techniques for the three-dimensional reconstruction of biological structures from serial light or electron micrographs. The following results were obtained: (1) In animals with embryonic retinular lesions, the number of laminar neurons found in adults was reduced and was roughly proportional to the number of surviving retinular cells which sent fibers to the lamina. When retinular lesions were made in adults, however, no evidence of laminar cell loss was found. (2) A reduced number of higher-order neurons (medullary neurons) was found only in animals with very large embryonic retinular lesions. (3) When retinular cells were deleted before their fibers could grow into the lamina and contact immature target cells, the laminar cells deprived of these contacts failed to differentiate morphologically before degenerating at late embryonic stages. (4) In a number of cases, optic cartridges were formed with abnormal numbers of retinular fibers and laminar neurons. These observations support our hypothesis and increase our understanding of the role of cellular interactions in the development of the arthropod visual system.

Microbial Challenge Promotes the Regenerative Process of the Injured Central Nervous System of the Medicinal Leech by Inducing the Synthesis of Antimicrobial Peptides in Neurons and Microglia

Following trauma, the CNS of the medicinal leech, unlike the mammalian CNS, has a strong capacity to regenerate neurites and synaptic connections that restore normal function. In this study, we show that this regenerative process is enhanced by a controlled bacterial infection, suggesting that induction of regeneration of normal CNS function may depend critically upon the coinitiation of an immune response. We explore the interaction between the activation of a neuroimmune response and the process of regeneration by assaying the potential roles of two newly characterized antimicrobial peptides. Our data provide evidence that microbial components differentially induce the transcription, by microglial cells, of both antimicrobial peptide genes, the products of which accumulate rapidly at sites in the CNS undergoing regeneration following axotomy. Using a preparation of leech CNS depleted of microglial cells, we also demonstrate the production of antimicrobial peptides by neurons. Interestingly, in addition to exerting antibacterial properties, both peptides act as promoters of the regenerative process of axotomized leech CNS. These data are the first to report the neuronal synthesis of antimicrobial peptides and their participation in the immune response and the regeneration of the CNS. Thus, the leech CNS appears as an excellent model for studying the implication of immune molecules in neural repair.

Innexins form two types of channels

Injury to the central nervous system triggers glial calcium waves in both vertebrates and invertebrates. In vertebrates the pannexin1 ATP‐release channel appears to provide for calcium wave initiation and propagation. The innexins, which form invertebrate gap junctions and have sequence similarity with the pannexins, are candidates to form non‐junctional membrane channels. Two leech innexins previously demonstrated in glia were expressed in frog oocytes. In addition to making gap junctions, innexins also formed non‐junctional membrane channels with properties similar to those of pannexons. In addition, carbenoxolone reversibly blocked the loss of carboxyfluorescein dye into the bath from the giant glial cells in the connectives of the leech nerve cord, which are known to express the innexins we assayed.

Morphological evidence that regenerating axons can fuse with severed axon segments

Regenerating axons of sensory neurons in the leech nerve cord usually reconnect with their normal targets by growing the entire distance from the site of lesion to the target. However, in less than 1% to nearly 10% of cases a rapid restoration of the normal arborization occurs when the regenerating axon connects with the severed distal segment of the same cell or another cell of the same modality. The passage of horseradish peroxidase (mol. wt approximately 40,000 daltons) from the regenerating axon selectively into the axon or cell with which it has connected indicates that the two have joined or fused, rather than become linked by an electrical synapse, as sometimes occurs for other neurons in the leech. These results support the conclusions, based largely on physiological data from regenerating motor axons in crayfish, that unusually rapid and complete regeneration can occur when a growing axon fuses with its severed distal segment.

Molecular MALDI imaging: an emerging technology for neuroscience studies.

Mass spectrometry (MS) has become an essential tool for the detection, identification, and characterization of the molecular components of biological processes, such as those responsible for the dynamic properties of the nervous system. Generally, the application of these powerful techniques requires the destruction of the specimen under study, but recent technological advances have made it possible to apply the matrix‐assisted laser desorption/ionization (MALDI) MS technique directly to tissue sections. The major advantage of direct MALDI analysis is that it enables the acquisition of local molecular expression profiles, while maintaining the topographic integrity of the tissue and avoiding time‐consuming extraction, purification, and separation steps, which have the potential for introducing artifacts. With automation and the ability to display complex spectral data using imaging software, it is now possible to create multiple 2D maps of selected biomolecules in register with tissue sections, a method now known as MALDI Imaging, or MSI (for Mass Spectrometry Imaging). This creates, for example, an opportunity to correlate functional states, determined a priori with live recording or imaging, with the corresponding molecular maps obtained at the time the tissue is frozen and analyzed with MSI. We review the increasing application of MALDI Imaging to the analysis of molecular distributions of proteins and peptides in nervous tissues of both vertebrates and invertebrates, focusing in particular on recent studies of neurodegenerative diseases and early efforts to implement assays of neuronal development.

RNAi of the receptor tyrosine phosphatase HmLAR2 in a single cell of an intact leech embryo leads to growth-cone collapse

Receptor protein tyrosine phosphatases (RPTPs) are important for growth-cone migration [1-5], but their specific roles have yet to be defined. Previously, we showed that the growth cones of the Comb cell, an embryonic cell in the leech, express high levels of an RPTP called HmLAR2 [6,7]. Here, we report the use of RNA interference (RNAi) to block expression of HmLAR2 in individual Comb cells in the developing embryo. HmLAR2 mRNA levels were reduced in the soma, processes and growth cones of Comb cells injected with double-stranded RNA (dsRNA) for HmLAR2, but no decrease was detected when control dsRNAs were injected. Consistent with this observation, the level of phosphotyrosine increased significantly in the growth cones of Comb cells injected with HmLAR2 dsRNA. Within 24 hours, the growth cones of treated cells showed a distinct collapsed phenotype, with sharp reductions in lamellipodial surface area and in numbers of filopodia. These experiments indicate a key role for LAR-like RPTPs in maintaining the integrity of the growth cone.

Construction of a medicinal leech transcriptome database and its application to the identification of leech homologs of neural and innate immune genes

BackgroundThe medicinal leech, Hirudo medicinalis, is an important model system for the study of nervous system structure, function, development, regeneration and repair. It is also a unique species in being presently approved for use in medical procedures, such as clearing of pooled blood following certain surgical procedures. It is a current, and potentially also future, source of medically useful molecular factors, such as anticoagulants and antibacterial peptides, which may have evolved as a result of its parasitizing large mammals, including humans. Despite the broad focus of research on this system, little has been done at the genomic or transcriptomic levels and there is a paucity of openly available sequence data. To begin to address this problem, we constructed whole embryo and adult central nervous system (CNS) EST libraries and created a clustered sequence database of the Hirudo transcriptome that is available to the scientific community.ResultsA total of ~133,000 EST clones from two directionally-cloned cDNA libraries, one constructed from mRNA derived from whole embryos at several developmental stages and the other from adult CNS cords, were sequenced in one or both directions by three different groups: Genoscope (French National Sequencing Center), the University of Iowa Sequencing Facility and the DOE Joint Genome Institute. These were assembled using the phrap software package into 31,232 unique contigs and singletons, with an average length of 827 nt. The assembled transcripts were then translated in all six frames and compared to proteins in NCBIs non-redundant (NR) and to the Gene Ontology (GO) protein sequence databases, resulting in 15,565 matches to 11,236 proteins in NR and 13,935 matches to 8,073 proteins in GO. Searching the database for transcripts of genes homologous to those thought to be involved in the innate immune responses of vertebrates and other invertebrates yielded a set of nearly one hundred evolutionarily conserved sequences, representing all known pathways involved in these important functions.ConclusionsThe sequences obtained for Hirudo transcripts represent the first major database of genes expressed in this important model system. Comparison of translated open reading frames (ORFs) with the other openly available leech datasets, the genome and transcriptome of Helobdella robusta, shows an average identity at the amino acid level of 58% in matched sequences. Interestingly, comparison with other available Lophotrochozoans shows similar high levels of amino acid identity, where sequences match, for example, 64% with Capitella capitata (a polychaete) and 56% with Aplysia californica (a mollusk), as well as 58% with Schistosoma mansoni (a platyhelminth). Phylogenetic comparisons of putative Hirudo innate immune response genes present within the Hirudo transcriptome database herein described show a strong resemblance to the corresponding mammalian genes, indicating that this important physiological response may have older origins than what has been previously proposed.

Modulation of the pattern of axonal projections of a leech motor neuron by ablation or transplantation of its target

The sixth segmental ganglion in the ventral nerve cord of the leech H. medicinalis contains a bilateral pair of rostral penile evertor motor neurons (RPEs) that in the adult innervate the male genitalia. During embryogenesis, the RPEs extend numerous extraganglionic projections. Only two of these innervate the target and are normally retained in the adult, while the others retract. Early, but not late, removal of the male genitalia results in the indefinite retention and continued growth of projections that would normally retract. Any of these projections can innervate targets transplanted to ectopic locations. We conclude that an RPE motor neuron requires a signal, provided by its interaction with the target organ during a critical period, in order to stop extending axons, stabilize those axons that contact the target, and retract those that do not.