Project description:Kidney plasma membranes of Aplysia californica were shown to contain an endopeptidase activity which cleaved [Leu]enkephalin (Tyr-Gly-Gly-Phe-Leu) and [Leu]enkephalinamide (Tyr-Gly-Gly-Phe-Leu-NH2) at the Gly3-Phe4 bond, as determined by reverse-phase h.p.l.c. analysis of metabolites. The optimal pH was shown to be 6.5. The bivalent cation chelating agent, 1,10-phenanthroline protected [Leu]enkephalin from degradation, suggesting that this enzyme is a metallopeptidase. The degradation of [Leu]enkephalin was also abolished by the neutral endopeptidase-24.11 inhibitors RB104 (2-[(3-iodo-4-hydroxyl)-phenylmethyl]-4-N-[3-(hydroxyamino-3-oxo-1- phenylmethyl)-propyl]amino-4-oxobutanoic acid), HABCO-Gly [(3-hydroxy-aminocarbonyl-2-benzyl-1-oxypropyl)glycine], phosphoramidon and thiorphan, with IC50 values of 1 nM, 1 microM, 20 microM and 30 microM respectively. By contrast, the angiotensin-converting enzyme inhibitor captopril and the serine proteinase inhibitor phenylmethanesulphonyl fluoride were without effect. Phase separation experiments using Triton X-114 showed that about 64% of the neutral endopeptidase activity in the Aplysia kidney membrane corresponds to an integral membrane protein. A specific radioiodinated inhibitor ([125I]RB104) was shown to bind the Aplysia endopeptidase with high affinity; the KD and Bmax. values were 21 +/- 5 pM and 20.3 +/- 5 fmol/mg of proteins respectively. This inhibitor was used to determine the molecular form of the enzyme, after separation of solubilized membrane proteins on SDS/PAGE and transfer on to nitrocellulose membranes. A single protein band with an apparent molecular mass of 140 kDa was observed. The labelling was abolished by specific neutral endopeptidase inhibitors. This study provides the first biochemical characterization of an endopeptidase with catalytic properties similar to those of neutral endopeptidase-24.11 in the mollusc Aplysia californica.

Project description:d-Amino acid-containing peptides (DAACPs) make up a class of post-translationally modified peptides in animals that play important roles as cell-to-cell signaling molecules. Despite the functional importance of l- to d-residue isomerization, little is known about its prevalence, mostly due to difficulties associated with detecting differences in peptide stereochemistry. Prior efforts to discover DAACPs have been largely focused on pursuing peptides based on homology to known DAACPs or DAACP-encoding precursors. Here, we used a combination of enzymatic screening, mass spectrometry, and chromatographic analysis to identify novel DAACPs in the central nervous system (CNS) of Aplysia californica. We identified five new DAACPs from the pleurin precursor and three DAACPs from previously uncharacterized proteins. In addition, two peptides from the pleurin precursor, Plrn2 and Plrn3, exist as DAACPs with the d-residue found at position 2 or 3. These differentially modified forms of Plrn2 and Plrn3 are located in specific regions of the animal's CNS. Plrn2 and Plrn3 appear to be the first animal DAACPs in which the d-residue is found at more than one position, and this suggests that l- to d-residue isomerization may be a more variable/dynamic modification than previously thought. Overall, this study demonstrates the utility of nontargeted DAACP discovery approaches for identifying new DAACPs and demonstrates that isomerization is prevalent throughout the CNS of A. californica.

Project description:The first Aplysia californica insulin gene is characterized and its proteolytic processing from prohormone to final peptides elucidated using a combination of biochemical and mass spectrometric methods. Aplysia insulin (AI) is one of the largest insulins found, with a molecular weight of 9146 Da, and an extended A chain compared with other invertebrate and vertebrate insulins. The AI prohormone produces a series of C peptides and also a unique N-terminally acetylated D peptide. AI-producing cells are restricted to the central region of the cerebral ganglia mostly within the F and C clusters, and AI is transported to neurohemal release sites located on the upper labial and anterior tentacular nerves. The expression of AI mRNA decreases when the animal is deprived of food, and injections of AI reduce hemolymph glucose levels, suggesting that the function of insulin-regulating metabolism has been conserved.

Project description:Genome-wide transcriptional changes in development provide important insight into mechanisms underlying growth, differentiation, and patterning. However, such large-scale developmental studies have been limited to a few representatives of Ecdysozoans and Chordates. Here, we characterize transcriptomes of embryonic, larval, and metamorphic development in the marine mollusc Aplysia californica and reveal novel molecular components associated with life history transitions. Specifically, we identify more than 20 signal peptides, putative hormones, and transcription factors in association with early development and metamorphic stages-many of which seem to be evolutionarily conserved elements of signal transduction pathways. We also characterize genes related to biomineralization-a critical process of molluscan development. In summary, our experiment provides the first large-scale survey of gene expression in mollusc development, and complements previous studies on the regulatory mechanisms underlying body plan patterning and the formation of larval and juvenile structures. This study serves as a resource for further functional annotation of transcripts and genes in Aplysia, specifically and molluscs in general. A comparison of the Aplysia developmental transcriptome with similar studies in the zebra fish Danio rerio, the fruit fly Drosophila melanogaster, the nematode Caenorhabditis elegans, and other studies on molluscs suggests an overall highly divergent pattern of gene regulatory mechanisms that are likely a consequence of the different developmental modes of these organisms.

Project description:Aging is associated with cognitive declines that originate in impairments of function in the neurons that make up the nervous system. The marine mollusk Aplysia californica (Aplysia) is a premier model for the nervous system uniquely suited to investigation of neuronal aging due to uniquely identifiable neurons and molecular techniques available in this model. This study describes the molecular processes associated with aging in two populations of sensory neurons in Aplysia by applying RNA sequencing technology across the aging process (age 6-12 months). Differentially expressed genes clustered into four to five coherent expression patterns across the aging time series in the two neuron populations. Enrichment analysis of functional annotations in these neuron clusters revealed decreased expression of pathways involved in energy metabolism and neuronal signaling, suggesting that metabolic and signaling pathways are intertwined. Furthermore, increased expression of pathways involved in protein processing and translation suggests that proteostatic stress also occurs in aging. Temporal overlap of enrichment for energy metabolism, proteostasis, and neuronal function suggests that cognitive impairments observed in advanced age result from the ramifications of broad declines in energy metabolism.

Project description:Study objectiveTo characterize sleep in the marine mollusk, Aplysia californica.DesignAnimal behavior and activity were assessed using video recordings to measure activity, resting posture, resting place preference, and behavior after rest deprivation. Latencies for behavioral responses were measured for appetitive and aversive stimuli for animals in the wake and rest states.SettingCircadian research laboratory for Aplysia.Patients or participantsA. californica from the Pacific Ocean.InterventionsN/A.Measurements and resultsAplysia rest almost exclusively during the night in a semi-contracted body position with preferential resting locations in the upper corners of their tank. Resting animals demonstrate longer latencies in head orientation and biting in response to a seaweed stimulus and less frequent escape response steps following an aversive salt stimulus applied to the tail compared to awake animals at the same time point. Aplysia exhibit rebound rest the day following rest deprivation during the night, but not after similar handling stimulation during the day.ConclusionsResting behavior in Aplysia fulfills all invertebrate characteristics of sleep including: (1) a specific sleep body posture, (2) preferred resting location, (3) reversible behavioral quiescence, (4) elevated arousal thresholds for sensory stimuli during sleep, and (5) compensatory sleep rebound after sleep deprivation.

Project description:L7 vs sensory cluster (Annotated array AAA)

Project description:Aplysia californica Raw sequence reads

Project description:Aplysia californica Transcriptome or Gene expression

Project description:Aplysia Pleural Ganglia 7 Days After Long-Term Sensitization Training