Functional Characterization of CLCN4 Variants Associated With X-Linked Intellectual Disability and Epilepsy

Guzman, Raul E.; Sierra-Marquez, Juan; Bungert-Plümke, Stefanie; Franzen, Arne; Fahlke, Christoph

doi:10.3389/fnmol.2022.872407

Cited by 13 publications

(11 citation statements)

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“…Their physiological importance has been demonstrated by studies of knockout animal models and by naturally occurring mutations in patients with genetic diseases: genetic ablation or naturally occurring mutations in CLCN3 or CLCN7 causes neurodegeneration in the central nervous system (CNS; Kornak et al, 2001 ; Stobrawa et al, 2001 ; Dickerson et al, 2002 ; Kasper et al, 2005 ; Duncan et al, 2021 ). Mutations in the CLCN4 gene are associated with intellectual disability and epilepsy ( Veeramah et al, 2013 ; Hu et al, 2016 ; Palmer et al, 2018 ; He et al, 2021b ; Guzman et al, 2022 ), and CLCN6 mutations result in West syndrome and lysosomal storage disease ( Poet et al, 2006 ; He et al, 2021a ). Genetic ablation of ClC-6 or downregulation of ClC-3 alters pain sensitivity in mice ( Poet et al, 2006 ; Pang et al, 2016 ), suggesting a role for Cl – /H + exchangers in pain regulation.…”

Section: Introductionmentioning

confidence: 99%

ClC-3 regulates the excitability of nociceptive neurons and is involved in inflammatory processes within the spinal sensory pathway

Sierra-Marquez

Gehlen

Schöneck

et al. 2022

Front. Cell. Neurosci.

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ClC-3 Cl–/H+ exchangers are expressed in multiple endosomal compartments and likely modify intra-endosomal pH and [Cl–] via the stoichiometrically coupled exchange of two Cl– ions and one H+. We studied pain perception in Clcn3–/– mice and found that ClC-3 not only modifies the electrical activity of peripheral nociceptors but is also involved in inflammatory processes in the spinal cord. We demonstrate that ClC-3 regulates the number of Nav and Kv ion channels in the plasma membrane of dorsal root ganglion (DRG) neurons and that these changes impair the age-dependent decline in excitability of sensory neurons. To distinguish the role of ClC-3 in Cl–/H+ exchange from its other functions in pain perception, we used mice homozygous for the E281Q ClC-3 point mutation (Clcn3E281Q/E281Q), which completely eliminates transport activity. Since ClC-3 forms heterodimers with ClC-4, we crossed these animals with Clcn4–/– to obtain mice completely lacking in ClC-3-associated endosomal chloride–proton transport. The electrical properties of Clcn3E281Q/E281Q/Clcn4–/– DRG neurons were similar to those of wild-type cells, indicating that the age-dependent adjustment of neuronal excitability is independent of ClC-3 transport activity. Both Clcn3–/– and Clcn3E281Q/E281Q/Clcn4–/– animals exhibited microglial activation in the spinal cord, demonstrating that competent ClC-3 transport is needed to maintain glial cell homeostasis. Our findings illustrate how reduced Cl–/H+ exchange contributes to inflammatory responses and demonstrate a role for ClC-3 in the homeostatic regulation of neuronal excitability beyond its function in endosomal ion balance.

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Section: Introductionmentioning

confidence: 99%

ClC-3 regulates the excitability of nociceptive neurons and is involved in inflammatory processes within the spinal sensory pathway

Sierra-Marquez

Gehlen

Schöneck

et al. 2022

Front. Cell. Neurosci.

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“…Independence of both fluorescence signals was guaranteed by using proteins with separate emission and excitation spectra as well as performing sequential rather than simultaneous imaging of color channels. However, based on our experience with solubilizing ion channels and transporters tagged with fluorescent proteins ( Guzman et al, 2022 ; Stölting et al, 2014 ; Stölting et al, 2015a ; Tan et al, 2017 ), we expected that a fraction of fluorescent proteins might be cleaved off within the linker region or within M, leading to the simultaneous removal of both F and M. We introduced an additional factor, m , to describe the probability of this phenomenon occurring. Notwithstanding that we cannot exclude other possibilities contributing to the loss of both fluorescent proteins, m remains generally as the probability of both M and F simultaneously being dysfunctional.…”

Section: Resultsmentioning

confidence: 99%

Determination of oligomeric states of proteins via dual-color colocalization with single molecule localization microscopy

Tan

Bungert-Plümke

Kortzak

et al. 2022

eLife

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The oligomeric state of plasma membrane proteins is the result of the interactions between individual proteins and an important determinant of their function. Most approaches used to address this question rely on extracting these complexes from their native environment, which may disrupt weaker interactions. Therefore, microscopy techniques have been increasingly used in recent years to determine oligomeric states in situ. Classical light microscopy suffers from insufficient resolution, but super-resolution methods such as single molecule localization microscopy (SMLM) can circumvent this problem. When using SMLM to determine oligomeric states of proteins, subunits are labeled with fluorescent proteins that only emit light following activation or conversion at different wavelengths. Typically, individual molecules are counted based on a binomial distribution analysis of emission events detected within the same diffraction-limited volume. This strategy requires low background noise, a high recall rate for the fluorescent tag and intensive post-imaging data processing. To overcome these limitations, we developed a new method based on SMLM to determine the oligomeric state of plasma membrane proteins. Our dual-color colocalization (DCC) approach allows for accurate in situ counting even with low efficiencies of fluorescent protein detection. In addition, it is robust in the presence of background signals and does not require temporal clustering of localizations from individual proteins within the same diffraction limited volume, which greatly simplifies data acquisition and processing. We used DCC-SMLM to resolve the controversy surrounding the oligomeric state of two SLC26 multifunctional anion exchangers and to determine the oligomeric state of four members of the SLC17 family of organic anion transporters.

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“…Independence of both fluorescence signals was guaranteed by using proteins with separate emission and excitation spectra as well as performing sequential rather than simultaneous imaging of color channels. However, based on our experience with solubilizing ion channels and transporters tagged with fluorescent proteins (Guzman et al, 2022; Stölting et al, 2014; Stölting, Bungert-Plümke, et al, 2015; Tan et al, 2017), we expected that a small fraction of fluorescent proteins might be cleaved off within the linker region or within M, leading to the simultaneous removal of both F and M. We introduced an additional factor, m , to describe the probability of this phenomenon occurring. Notwithstanding that we cannot exclude other possibilities contributing to the loss of both fluorescent proteins, m remains generally as the probability of both M and F simultaneously being dysfunctional.…”

Section: Resultsmentioning

confidence: 99%

Determination of oligomeric states of proteins via dual-color colocalization with single molecule localization microscopy

Tan

Bungert-Plümke

Kortzak

et al. 2021

Preprint

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View full text Add to dashboard Cite

The stoichiometry of plasma membrane protein complexes is an important determinant of their function and of interactions between the individual proteins. Most approaches used to address this question rely on extracting these complexes from their native environment, which may disrupt weaker interactions. Therefore, microscopy techniques have been increasingly used in recent years to determine protein stoichiometries in situ. Classical light microscopy suffers from insufficient resolution, but super-resolution methods such as single molecule localization microscopy (SMLM) can circumvent this problem. When using SMLM to determine protein stoichiometries, subunits are labeled with fluorescent proteins that only emit light following activation or conversion at different wavelengths. Typically, individual signals are counted based on a binomial distribution analysis of emission events detected within the same diffraction-limited volume. This strategy requires low background noise, a high detection efficiency for the fluorescent tag and intensive post-imaging data processing. To overcome these limitations, we developed a new method based on SMLM to determine the stoichiometry of plasma membrane proteins. Our dual-color colocalization (DCC) approach allows for accurate in situ counting even with low efficiencies of fluorescent protein detection. In addition, it is robust in the presence of background signals and does not require strong temporal separation of emission events within the same diffraction-limited volume, which greatly simplifies data acquisition and processing. We used DCC-SMLM to resolve the controversy surrounding the stoichiometries of two SLC26 multifunctional anion exchangers and to determine the stoichiometries of four members of the SLC17 family of organic anion transporters.

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Functional Characterization of CLCN4 Variants Associated With X-Linked Intellectual Disability and Epilepsy

Cited by 13 publications

References 59 publications

ClC-3 regulates the excitability of nociceptive neurons and is involved in inflammatory processes within the spinal sensory pathway

ClC-3 regulates the excitability of nociceptive neurons and is involved in inflammatory processes within the spinal sensory pathway

Determination of oligomeric states of proteins via dual-color colocalization with single molecule localization microscopy

Determination of oligomeric states of proteins via dual-color colocalization with single molecule localization microscopy

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