Fast and slow skeletal muscle types in larval zebrafish can be distinguished by a fivefold difference in the time course of their synaptic decay. Single-channel recordings indicate that this difference is conferred through kinetically distinct nicotinic acetylcholine receptor (AChR) isoforms. The underlying basis for this distinction was explored by cloning zebrafish muscle AChR subunit cDNAs and expressing them in Xenopus laevis oocytes. Measurements of single-channel conductance and mean open burst duration assigned α2βδε to fast muscle synaptic current. Contrary to expectations, receptors composed of only αβδ subunits (presumed to be α2βδ2 receptors) recapitulated the kinetics and conductance of slow muscle single-channel currents. Additional evidence in support of γ/ε-less receptors as mediators of slow muscle synapses was reflected in the inward current rectification of heterologously expressed α2βδ2 receptors, a property normally associated with neuronal-type nicotinic receptors. Similar rectification was reflected in both single-channel and synaptic currents in slow muscle, distinguishing them from fast muscle. The final evidence for α2βδ2 receptors in slow muscle was provided by our ability to convert fast muscle synaptic currents to those of slow muscle by knocking down ε subunit expression in vivo. Thus, for the first time, muscle synaptic function can be ascribed to a receptor isoform that is composed of only three different subunits. The unique functional features offered by the α2βδ2 receptor likely play a central role in mediating the persistent contractions characteristic to this muscle type.
Zebrafish (Danio rerio) have been used to study multiple effects of nicotine, for example on cognition, locomotion, and stress responses, relying on the assumption that pharmacological tools will operate similarly upon molecular substrates in the fish and mammalian systems. We have cloned the zebrafish nicotinic acetylcholine receptor (nAChR) subunits and expressed key nAChR subtypes in Xenopus oocytes including neuronal (α4β2, α2β2, α3β4, and α7) and muscle (α1β1bεδ) nAChR. Consistent with studies of mammalian nAChR, nicotine was relatively inactive on muscle-type receptors, having both low potency and efficacy. It had high efficacy but low potency for α7 receptors, and the best potency and good efficacy for α4β2 receptors. Cytisine, a key lead compound for the development of smoking cessation agents, is a full agonist for both mammalian α7 and α3β4 receptors, but a full agonist only for the fish α7, with surprisingly low efficacy for α3β4. The efficacy of cytisine for α4β2 was somewhat greater than typically reported for mammalian α4β2. The ganglionic blocker mecamylamine was most potent for blocking α3β4 receptors, least potent for α7, and roughly equipotent for the muscle receptors and the β2-containing nAChR. However, the block of β2-containing receptors was slowly reversible, consistent with effective targeting of these CNS-type receptors in vivo. Three prototypical α7-selective agonists, choline, tropane, and 4OH-GTS-21, were tested, and these agents were observed to activate both fish α7 and α4β2 nAChR. Our data therefore indicate that while some pharmacological tools used in zebrafish may function as expected, others will not.
In the formation of the spinal network, various transcription factors interact to develop specific cell types. Using a gene trap technique, we established a stable line of zebrafish in which the red fluorescent protein (RFP) was inserted in the pax8 gene. RFP insertion marked putative pax8-lineage cells with fluorescence and inhibited pax8 expression in homozygous embryos. Pax8 homozygous embryos displayed defects in the otic vesicle, as previously reported in studies using morpholinos. The pax8 homozygous embryos survived to adulthood in contrast to mammalian counterparts that die prematurely. RFP is expressed in the dorsal spinal cord. Examination of the axon morphology revealed that RFP (+) neurons include Commissural Bifurcating Longitudinal (CoBL) interneurons, but other inhibitory neurons such as Commissural Local (CoLo) interneurons and Circumferential Ascending (CiA) interneurons do not express RFP. We examined the effect of inhibiting pax2a/pax8 expression on interneuron development. In pax8 homozygous fish, the RFP (+) cells undergo differentiation similar to that of pax8 heterozygous fish, and the swimming behavior remained intact. In contrast, the RFP (+) cells of pax2a/pax8 double mutants displayed altered cell fates. CoBLs were not observed. Instead, RFP (+) cells exhibited axons descending ipsilaterally: a morphology resembling that of V2a/V2b interneurons.
The behavioral effects of ethanol have been studied in multiple animal models including zebrafish. Locomotion of zebrafish larvae is resistant to high concentrations of ethanol in bath solution. This resistance has been attributed to a lower systemic concentration of ethanol in zebrafish when compared with bath solution, although the mechanism to maintain such a steep gradient is unclear. Here we examined whether the intrinsic properties of neurons play roles in this resistance. In order to minimize the contribution of metabolism and diffusional barriers, larvae were hemisected and the anterior half immersed in a range of ethanol concentrations thereby ensuring the free access of bath ethanol to the brain. The response to vibrational stimuli of three types of reticulospinal neurons: Mauthner neurons, vestibulospinal neurons, and MiD3 neurons were examined using an intracellular calcium indicator. The intracellular [Ca2+] response in MiD3 neurons decreased in 100 mM ethanol, while Mauthner neurons and vestibulospinal neurons required >300 mM ethanol to elicit similar effects. The ethanol effect in Mauthner neurons was reversible following removal of ethanol. Interestingly, activities of MiD3 neurons displayed spontaneous recovery in 300 mM ethanol, suggestive of acute tolerance. Finally, we examined with mechanical vibration the startle response of free-swimming larvae in 300 mM ethanol. Ethanol treatment abolished long latency startle responses, suggesting a functional change in neural processing. These data support the hypothesis that individual neurons in larval zebrafish brains have distinct patterns of response to ethanol dictated by specific molecular targets.
Cells exposed to phorbol 12-myristate 13-acetate (PMA) undergo a choreographed sequence of morphological changes. Some of these, including stimulation of membrane ruffles and the later appearance of stress fibers, rely on remodeling of the actin cytoskeleton. Although this process is poorly understood, it is important, because the same features are affected during oncogenic transformation. PMA also activates protein kinase C (PKC). Enzyme activation is followed by degradation. Either process might affect the remodeling of actin. The present studies determined whether any PKC isozymes were subject to degradation in tracheal epithelial cells by quantifying the amount of each isozyme present after PMA exposure. PKC-epsilon was the only isozyme to show declining content correlated with increased stress fiber accumulation. Stress fibers increased between 5 and 10 h, whereas PKC-epsilon declined to 38% of its starting value (95% confidence interval, 10-68%). The relationship could be fit by the function F(x) = 0.683 x exp[-0.841(x - 0.387)], where F is the frequency of fiber-containing cells and x is PKC-epsilon content. Fiber accumulation was further investigated after knockdown of PKC-epsilon with RNA interference and antisense oligodeoxynucleotide. Knockdown enhanced stress fibers in cells not yet exposed to PMA as well as the final frequency of fiber-containing cells after PMA exposure. With knockdown at both transcriptional and protein levels, approximately 15% of the original content was predicted and achieved, as judged from real-time PCR and PKC-epsilon content measurements. The results suggest that PKC-epsilon negatively regulates stress fibers, either by directly turning over one of their components or by regulating an upstream step affecting fiber organization.
The contraction of skeletal muscle is dependent on synaptic transmission through acetylcholine receptors (AChRs) at the neuromuscular junction (NMJ). The lack of an AChR subunit causes a fetal akinesia in humans, leading to death in the first trimester and characteristic features of Fetal Akinesia Deformation Sequences (FADS). A corresponding null mutation of the ␦-subunit in zebrafish (sofa potato; sop) leads to the death of embryos around 5 d postfertilization (dpf). In sop Ϫ/Ϫ mutants, we expressed modified ␦-subunits, with one (␦1YFP) or two yellow fluorescent protein (␦2YFP) molecules fused at the intracellular loop, under the control of an ␣-actin promoter. AChRs containing these fusion proteins are fluorescent, assemble on the plasma membrane, make clusters under motor neuron endings, and generate synaptic current. We screened for germ-line transmission of the transgene and established a line of sop Ϫ/Ϫ fish stably expressing the ␦2YFP. These ␦2YFP/sop Ϫ/Ϫ embryos can mount escape behavior close to that of their wild-type siblings. Synaptic currents in these embryos had a smaller amplitude, slower rise time, and slower decay when compared with wild-type fish. Remarkably, these embryos grow to adulthood and display complex behaviors such as feeding and breeding. To the best of our knowledge, this is the first case of a mutant animal corresponding to first trimester lethality in human that has been rescued by a transgene and survived to adulthood. In the rescued fish, a foreign promoter drove the transgene expression and the NMJ had altered synaptic strength. The survival of the transgenic animal delineates requirements for gene therapies of NMJ.Key words: zebrafish; neuromuscular junction; acetylcholine receptor; synapse; fetal akinesia deformation sequence; fluorescent protein IntroductionThe synapse between the motor nerve and skeletal muscle, commonly referred to as the neuromuscular junction (NMJ), is cholinergic in vertebrates and is a model system for the investigation of synapses (Sanes and Lichtman, 2001;Ono, 2008). On the postsynaptic face of the NMJ, the AChRs span the membrane, with each AChR forming a pentameric structure. The five subunits comprising AChRs are 2␣s, , ␦ and ␥/. ␥ and are developmentally regulated and can substitute for each other. The embryonic-type ␥ is replaced by the adult-type as the synapse matures (Mishina et al., 1986).A group of genetic disorders have mutations in genes coding for components of the NMJ. Congenital myasthenic disorders (CMDs) result from mutations in genes coding for expression of proteins such as AChR, rapsyn, MuSK, and cholinesterase (Engel and Sine, 2005). CMD patients display weak muscle strength resulting from compromised synaptic currents. Functional nulls of AChRs were predicted to be lethal and, indeed, fetuses homozygous for these mutations die in the first trimester (Michalk et al., 2008). Affected fetuses display characteristic anatomical features that are collectively called Fetal Akinesia Deformation Sequences (FADS).Zebrafish (Danio rerio)...
Mutations in muscle ACh receptors cause slow-channel syndrome (SCS) and Escobar syndrome, two forms of congenital myasthenia. SCS is a dominant disorder with mutations reported for all receptor subunits except γ. Escobar syndrome is distinct, with mutations located exclusively in γ, and characterized by developmental improvement of muscle function. The zebrafish mutant line, twister , models SCS in terms of a dominant mutation in the α subunit (α twi ) but shows the behavioral improvement associated with Escobar syndrome. Here, we present a unique electrophysiological study into developmental improvement for a myasthenic syndrome. The embryonic α twi βδγ receptor isoform produces slowly decaying synaptic currents typical of SCS that transit to a much faster decay upon the appearance of adult ε, despite the α twi mutation. Thus, the continued expression of α twi into adulthood is tolerated because of the ε expression and associated recovery, raising the likelihood of unappreciated myasthenic cases that benefit from the γ−ε switch.
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