Your search keyword '"Dallman Julia"' showing total 56 results

51. Action potential waveform voltage clamp shows significance of different Ca2+channel types in developing ascidian muscle

Author

Dallman, Julia E., Dorman, Jennie B., and Moody, William J.

Abstract

1Early in development, ascidian muscle cells generate spontaneous, long‐duration action potentials that are mediated by a high‐threshold, inactivating Ca2+current. This spontaneous activity is required for appropriate physiological development.2Mature muscle cells generate brief action potentials only in response to motor neuron input. The mature action potential is mediated by a high‐threshold sustained Ca2+current.3Action potentials recorded from these two stages were imposed as voltage‐clamp commands on cells of the same and different stages from which they were recorded. This strategy allowed us to study how immature and mature Ca2+currents are optimized to their particular functions.4Total Ca2+entry during an action potential did not change during development. The developmental increase in Ca2+current density exactly compensated for decreased spike duration. This compensation was a function purely of Ca2+current density, not of the transition from immature to mature Ca2+current types.5In immature cells, Ca2+entry was spread out over the entire waveform of spontaneous activity, including the interspike voltage trajectory. This almost continuous Ca2+entry may be important in triggering Ca2+‐dependent developmental programmes, and is a function of the slightly more negative voltage dependence of the immature Ca2+current.6In contrast, Ca2+entry in mature cells was confined to the action potential itself, because of the slightly more positive voltage dependence of the mature Ca2+current. This may be important in permitting rapid contraction‐relaxation cycles during larval swimming.7The inactivation of the immature Ca2+current serves to limit the frequency and burst duration of spontaneous activity. The sustained kinetics of the mature Ca2+current permit high‐frequency firing during larval swimming.

Published

2000

52. Author Correction: Biallelic mutations in SORDcause a common and potentially treatable hereditary neuropathy with implications for diabetes

Author

Cortese, Andrea, Zhu, Yi, Rebelo, Adriana P., Negri, Sara, Courel, Steve, Abreu, Lisa, Bacon, Chelsea J., Bai, Yunhong, Bis-Brewer, Dana M., Bugiardini, Enrico, Buglo, Elena, Danzi, Matt C., Feely, Shawna M. E., Athanasiou-Fragkouli, Alkyoni, Haridy, Nourelhoda A., Isasi, Rosario, Khan, Alaa, Laurà, Matilde, Magri, Stefania, Pipis, Menelaos, Pisciotta, Chiara, Powell, Eric, Rossor, Alexander M., Saveri, Paola, Sowden, Janet E., Tozza, Stefano, Vandrovcova, Jana, Dallman, Julia, Grignani, Elena, Marchioni, Enrico, Scherer, Steven S., Tang, Beisha, Lin, Zhiqiang, Al-Ajmi, Abdullah, Schüle, Rebecca, Synofzik, Matthis, Maisonobe, Thierry, Stojkovic, Tanya, Auer-Grumbach, Michaela, Abdelhamed, Mohamed A., Hamed, Sherifa A., Zhang, Ruxu, Manganelli, Fiore, Santoro, Lucio, Taroni, Franco, Pareyson, Davide, Houlden, Henry, Herrmann, David N., Reilly, Mary M., Shy, Michael E., Zhai, R. Grace, and Zuchner, Stephan

Abstract

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

Published

2020

53. Context-dependent hyperactivity in syngap1a and syngap1b zebrafish autism models.

Author

Sumathipala SH, Khan S, Kozol RA, Araki Y, Syed S, Huganir RL, and Dallman JE

Abstract

Background and Aims: SYNGAP1 disorder is a prevalent genetic form of Autism Spectrum Disorder and Intellectual Disability (ASD/ID) and is caused by de novo or inherited mutations in one copy of the SYNGAP1 gene. In addition to ASD/ID, SYNGAP1 disorder is associated with comorbid symptoms including treatment-resistant-epilepsy, sleep disturbances, and gastrointestinal distress. Mechanistic links between these diverse symptoms and SYNGAP1 variants remain obscure, therefore, our goal was to generate a zebrafish model in which this range of symptoms can be studied., Methods: We used CRISPR/Cas9 to introduce frameshift mutations in the syngap1a and syngap1b zebrafish duplicates ( syngap1ab ) and validated these stable models for Syngap1 loss-of-function. Because SYNGAP1 is extensively spliced, we mapped splice variants to the two zebrafish syngap1a and b genes and identified mammalian-like isoforms. We then quantified locomotory behaviors in zebrafish syngap1ab larvae under three conditions that normally evoke different arousal states in wild type larvae: aversive, high-arousal acoustic, medium-arousal dark, and low-arousal light stimuli., Results: We show that CRISPR/Cas9 indels in zebrafish syngap1a and syngap1b produced loss-of-function alleles at RNA and protein levels. Our analyses of zebrafish Syngap1 isoforms showed that, as in mammals, zebrafish Syngap1 N- and C-termini are extensively spliced. We identified a zebrafish syngap1 α1-like variant that maps exclusively to the syngap1b gene. Quantifying locomotor behaviors showed that syngap1ab larvae are hyperactive compared to wild type but to differing degrees depending on the stimulus. Hyperactivity was most pronounced in low arousal settings, with overall movement increasing with the number of mutant syngap1 alleles., Conclusions: Our data support mutations in zebrafish syngap1ab as causal for hyperactivity associated with elevated arousal that is especially pronounced in low-arousal environments.

Published

2023

54. Author Correction: Biallelic mutations in SORD cause a common and potentially treatable hereditary neuropathy with implications for diabetes.

Author

Cortese A, Zhu Y, Rebelo AP, Negri S, Courel S, Abreu L, Bacon CJ, Bai Y, Bis-Brewer DM, Bugiardini E, Buglo E, Danzi MC, Feely SME, Athanasiou-Fragkouli A, Haridy NA, Isasi R, Khan A, Laurà M, Magri S, Pipis M, Pisciotta C, Powell E, Rossor AM, Saveri P, Sowden JE, Tozza S, Vandrovcova J, Dallman J, Grignani E, Marchioni E, Scherer SS, Tang B, Lin Z, Al-Ajmi A, Schüle R, Synofzik M, Maisonobe T, Stojkovic T, Auer-Grumbach M, Abdelhamed MA, Hamed SA, Zhang R, Manganelli F, Santoro L, Taroni F, Pareyson D, Houlden H, Herrmann DN, Reilly MM, Shy ME, Zhai RG, and Zuchner S

Abstract

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

Published

2020

55. Biallelic mutations in SORD cause a common and potentially treatable hereditary neuropathy with implications for diabetes.

Author

Cortese A, Zhu Y, Rebelo AP, Negri S, Courel S, Abreu L, Bacon CJ, Bai Y, Bis-Brewer DM, Bugiardini E, Buglo E, Danzi MC, Feely SME, Athanasiou-Fragkouli A, Haridy NA, Isasi R, Khan A, Laurà M, Magri S, Pipis M, Pisciotta C, Powell E, Rossor AM, Saveri P, Sowden JE, Tozza S, Vandrovcova J, Dallman J, Grignani E, Marchioni E, Scherer SS, Tang B, Lin Z, Al-Ajmi A, Schüle R, Synofzik M, Maisonobe T, Stojkovic T, Auer-Grumbach M, Abdelhamed MA, Hamed SA, Zhang R, Manganelli F, Santoro L, Taroni F, Pareyson D, Houlden H, Herrmann DN, Reilly MM, Shy ME, Zhai RG, and Zuchner S

Abstract

Here we report biallelic mutations in the sorbitol dehydrogenase gene (SORD) as the most frequent recessive form of hereditary neuropathy. We identified 45 individuals from 38 families across multiple ancestries carrying the nonsense c.757delG (p.Ala253GlnfsTer27) variant in SORD, in either a homozygous or compound heterozygous state. SORD is an enzyme that converts sorbitol into fructose in the two-step polyol pathway previously implicated in diabetic neuropathy. In patient-derived fibroblasts, we found a complete loss of SORD protein and increased intracellular sorbitol. Furthermore, the serum fasting sorbitol levels in patients were dramatically increased. In Drosophila, loss of SORD orthologs caused synaptic degeneration and progressive motor impairment. Reducing the polyol influx by treatment with aldose reductase inhibitors normalized intracellular sorbitol levels in patient-derived fibroblasts and in Drosophila, and also dramatically ameliorated motor and eye phenotypes. Together, these findings establish a novel and potentially treatable cause of neuropathy and may contribute to a better understanding of the pathophysiology of diabetes.

Published

2020

56. Glycinergic synapse development, plasticity, and homeostasis in zebrafish.

Author

Ganser LR and Dallman JE

Abstract

The zebrafish glial glycine transporter 1 (GlyT1) mutant provides an animal model in which homeostatic plasticity at glycinergic synapses restores rhythmic motor behaviors. GlyT1 mutants, initially paralyzed by the build-up of the inhibitory neurotransmitter glycine, stage a gradual recovery that is associated with reductions in the strength of evoked glycinergic responses. Gradual motor recovery suggests sequential compensatory mechanisms that culminate in the down-regulation of the neuronal glycine receptor. However, how motor recovery is initiated and how other forms of plasticity contribute to behavioral recovery are still outstanding questions that we discuss in the context of (1) glycinergic synapses as they function in spinal circuits that produce rhythmic motor behaviors, (2) the proteins involved in regulating glycinergic synaptic strength, (3) current models of glycinergic synaptogenesis, and (4) plasticity mechanisms that modulate the strength of glycinergic synapses. Concluding remarks (5) explore the potential for distinct plasticity mechanisms to act in concert at different spatial and temporal scales to achieve a dynamic stability that results in balanced motor behaviors.

Published

2009