Abdesslam Chrachri scite author profile

Marine coccolithophorid phytoplankton are major producers of biogenic calcite, playing a significant role in the global carbon cycle. Predicting the impacts of ocean acidification on coccolithophore calcification has received much recent attention and requires improved knowledge of cellular calcification mechanisms. Uniquely amongst calcifying organisms, coccolithophores produce calcified scales (coccoliths) in an intracellular compartment and secrete them to the cell surface, requiring large transcellular ionic fluxes to support calcification. In particular, intracellular calcite precipitation using HCO3 − as the substrate generates equimolar quantities of H+ that must be rapidly removed to prevent cytoplasmic acidification. We have used electrophysiological approaches to identify a plasma membrane voltage-gated H+ conductance in Coccolithus pelagicus ssp braarudii with remarkably similar biophysical and functional properties to those found in metazoans. We show that both C. pelagicus and Emiliania huxleyi possess homologues of metazoan Hv1 H+ channels, which function as voltage-gated H+ channels when expressed in heterologous systems. Homologues of the coccolithophore H+ channels were also identified in a diversity of eukaryotes, suggesting a wide range of cellular roles for the Hv1 class of proteins. Using single cell imaging, we demonstrate that the coccolithophore H+ conductance mediates rapid H+ efflux and plays an important role in pH homeostasis in calcifying cells. The results demonstrate a novel cellular role for voltage gated H+ channels and provide mechanistic insight into biomineralisation by establishing a direct link between pH homeostasis and calcification. As the coccolithophore H+ conductance is dependent on the trans-membrane H+ electrochemical gradient, this mechanism will be directly impacted by, and may underlie adaptation to, ocean acidification. The presence of this H+ efflux pathway suggests that there is no obligate use of H+ derived from calcification for intracellular CO2 generation. Furthermore, the presence of Hv1 class ion channels in a wide range of extant eukaryote groups indicates they evolved in an early common ancestor.

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A separate local pattern-generating circuit controls the movements of each swimmeret in crayfish

Murchison

Chrachri²,

Mulloney³

1993

Journal of Neurophysiology

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1. Within an abdominal segment, the motor output from the segmental ganglion to the swimmerets consists of coordinated bursts of impulses in the separate pools of motor neurons innervating the left and right limbs. This coordinated motor pattern features alternating (out-of-phase) bursts of impulses in the power-stroke (PS) and return-stroke (RS) motor axons that innervate each swimmeret. PS bursts on both sides of each segment occur simultaneously (in-phase), and so RS bursts on both sides are also in-phase. 2. With all intersegmental connections interrupted, isolated abdominal ganglia were able to sustain the normal swimmeret motor pattern of alternating PS/RS activity that was bilaterally in-phase. 3. After an isolated ganglion was surgically bisected down the midline, the isolated hemiganglia that resulted could produce stable, coordinated alternation of PS and RS bursts. 4. The neuropeptide proctolin could induce rhythmic oscillations of membrane potential in swimmeret neurons when spiking was blocked by tetrodotoxin (TTX). For neurons within the same hemiganglion, these oscillations retained the same phase relations they displayed in controls, but the oscillations of neurons in different hemiganglia became uncoordinated. 5. Synaptic transmission between swimmeret neurons in the same hemiganglion persisted in the presence of TTX. Swimmeret interneurons that could activate the pattern-generating circuitry under control conditions could induce membrane-potential oscillations in swimmeret neurons of the same hemiganglion when TTX was present. 6. We conclude that a separate hemisegmental pattern-generating circuit controls the rhythmic PS and RS movements of each swimmeret. Each circuit is located in the same hemiganglion as the population of motor neurons that innervates the local swimmeret. Graded transmission is sufficient to coordinate the timing of oscillatory activity within the hemisegmental circuitry. These hemisegmental circuits are coupled by intersegmental and bilateral coordinating pathways that are dependent on sodium action potentials for their operation.

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Alternative Mechanisms for Fast Na+/Ca2+ Signaling in Eukaryotes via a Novel Class of Single-Domain Voltage-Gated Channels

et al. 2019

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Cephalopod Neural Networks

Williamson

Chrachri²

2004

Neurosignals

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Cephalopods have arguably the largest and most complex nervous systems amongst the invertebrates; but despite the squid giant axon being one of the best studied nerve cells in neuroscience, and the availability of superb information on the morphology of some cephalopod brains, there is surprisingly little known about the operation of the neural networks that underlie the sophisticated range of behaviour these animals display. This review focuses on a few of the best studied neural networks: the giant fiber system, the chromatophore system, the statocyst system, the visual system and the learning and memory system, with a view to summarizing our current knowledge and stimulating new studies, particularly on the activities of identified central neurons, to provide a more complete understanding of networks within the cephalopod nervous system.

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Dynamic changes in carbonate chemistry in the microenvironment around single marine phytoplankton cells

et al. 2018

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Photosynthesis by marine diatoms plays a major role in the global carbon cycle, although the precise mechanisms of dissolved inorganic carbon (DIC) uptake remain unclear. A lack of direct measurements of carbonate chemistry at the cell surface has led to uncertainty over the underlying membrane transport processes and the role of external carbonic anhydrase (eCA). Here we identify rapid and substantial photosynthesis-driven increases in pH and [CO3 2−] primarily due to the activity of eCA at the cell surface of the large diatom Odontella sinensis using direct simultaneous microelectrode measurements of pH and CO3 2− along with modelling of cell surface inorganic carbonate chemistry. Our results show that eCA acts to maintain cell surface CO2 concentrations, making a major contribution to DIC supply in O. sinensis. Carbonate chemistry at the cell surface is therefore highly dynamic and strongly dependent on cell size, morphology and the carbonate chemistry of the bulk seawater.

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