KCNG4 antibody Host rabbit
- Known as:
- KCNG4 (anti-) Host host: rabbit
- Catalog number:
- 'ARP35473_P050
- Product Quantity:
- 50
- Category:
- -
- Supplier:
- ACR
- Gene target:
- KCNG4 antibody Host rabbit
Related genes to: KCNG4 antibody Host rabbit
- Gene:
- KCNG4 NIH gene
- Name:
- potassium voltage-gated channel modifier subfamily G member 4
- Previous symbol:
- -
- Synonyms:
- Kv6.4
- Chromosome:
- 16q24.1
- Locus Type:
- gene with protein product
- Date approved:
- 2002-11-20
- Date modifiied:
- 2016-02-04
Related products to: KCNG4 antibody Host rabbit
Related articles to: KCNG4 antibody Host rabbit
- Purkinje cells (PCs), the sole outputs of the cerebellar cortex, transform granule cell firing patterns into appropriate outputs to drive learning and behavior. Two major PC classes (typically defined by expression) can be further subdivided into nine molecularly distinct PC subtypes, suggesting that each subtype might be specialized for distinct categories of cerebellar processing. This has been difficult to test due to limited tools to target PC subtypes. We therefore developed intersectional tools to target PC subtypes, specifically Kcng4+ PCs (primarily Aldoc-) and Gpr176+ PCs (Aldoc1). We mapped their distributions within the cerebellar cortex and quantitatively characterized their outputs onto different types of cerebellar nuclei (CbN) neurons. Although projections by PC subtypes defined by Kcng4 and Gpr176 are regionally segregated within the CbN, each PC subtype synapses onto many types of CbN neurons, and individual CbN neurons often receive convergent inputs from multiple PC subtypes. We also selectively silenced PC subtype outputs and found that silencing Kcng4+ PC outputs impaired motor behaviors while sparing emotional and social behaviors, whereas silencing Gpr176+ PC outputs selectively increased exploratory behavior and reduced anxiety without affecting motor and social behaviors. These findings demonstrate that molecularly defined PC subtypes differentially regulate specific behaviors and establish a versatile framework for uncovering how cerebellar circuits are specialized to control diverse behaviors. - Source: PubMed
Publication date: 2026/05/21
Wu ShutingLin Chih-ChunLee Joon-HyukHwang KyoungdooGayoso Cameron AChawla KanupriyaJohnston Naomi BFerrando Victor IRegehr Wade G - Fast-spiking parvalbumin-positive (PV) neurons provide precisely timed, context-dependent inhibition within cortical circuits. PV neuron firing properties are specialized among cortical neurons, suggesting that they express a unique complement of ion channels. Here, we show that the PV-specific silent voltage-gated potassium (Kv) channel subunit Kv6.4 (encoded by ) modulates both intrinsic and synaptic properties of cortical PV neurons. Kv6.4 does not form functional channels on its own but, as shown in prior work, assembles with Kv2 subunits to create heterotetrameric channel complexes, effectively reducing Kv2-mediated delayed rectifier current. We find that expression is enriched within a distinct -expressing subclass in primary somatosensory (S1) and motor (M1) cortex and emerges during postnatal development. In PV neurons, Kv6.4 loss reduces action potential (AP) height and width, hyperpolarizes the threshold and interspike potential, and accelerates AP upstroke particularly during repetitive firing. Kv6.4 loss, potentially due to the changes in AP waveform, also alters GABA release and paired-pulse depression at synapses made by PV onto pyramidal (PYR) neurons. The effects of Kv6.4 loss are amplified during high-frequency firing, within the physiological range of fast-spiking PV neurons, likely due to altered repolarization dynamics that accumulate across successive APs. These findings are thus consistent with the function of Kv6.4 in modifying Kv2-mediated delayed rectifier currents. Hence, Kv6.4 tunes the temporal precision of PV inhibitory output, a feature that may be critical for stable excitation-inhibition ratios and adaptive circuit function underlying learning and behavior. - Source: PubMed
Publication date: 2026/02/03
Ganesh SanikaCanty Theresa MSabatini Bernardo L - Fast-spiking parvalbumin-positive (PV) neurons provide precisely timed, context-dependent inhibition within cortical circuits. PV neuron firing properties are specialized among cortical neurons, suggesting that they express a unique complement of ion channels. Here, we identify the PV-specific silent voltage-gated potassium (Kv) channel subunit Kv6.4 (encoded by ), whose role in cortical PV neuron physiology was previously unknown, as a modulator of both intrinsic and synaptic properties. Kv6.4 does not form functional channels on its own but, as shown in prior work, assembles with Kv2 subunits to create heterotetrameric channel complexes, effectively reducing Kv2-mediated delayed rectifier current. We find that expression is enriched within a distinct -expressing subclass in primary somatosensory (S1) and motor (M1) cortex and emerges during postnatal development. In PV neurons, Kv6.4 loss reduces action potential (AP) height and width, hyperpolarizes the threshold and interspike potential, and accelerates AP upstroke particularly during repetitive firing. Kv6.4 loss, potentially due to the changes in AP waveform, also alters GABA release and paired-pulse depression at synapses made by PV onto pyramidal (PYR) neurons. The effects of Kv6.4 loss are amplified during high-frequency firing, within the physiological range of fast-spiking PV neurons, likely due to altered repolarization dynamics that accumulate across successive APs. These findings are thus consistent with the function of Kv6.4 in modifying Kv2-mediated delayed rectifier currents. Hence, Kv6.4 tunes the temporal precision of PV inhibitory output, a feature that may be critical for stable excitation-inhibition ratios and adaptive circuit function underlying learning and behavior. - Source: PubMed
Publication date: 2025/12/22
Ganesh SanikaCanty Theresa MSabatini Bernardo L - KvS proteins are voltage-gated potassium channel subunits that form functional channels when assembled into heteromers with Kv2.1 () or Kv2.2 (). Mammals have 10 KvS subunits: Kv5.1 (), Kv6.1 (), Kv6.2 (), Kv6.3 (), Kv6.4 (), Kv8.1 (), Kv8.2 (), Kv9.1 (), Kv9.2 (), and Kv9.3 (). Electrically excitable cells broadly express channels containing Kv2 subunits and most neurons have substantial Kv2 conductance. However, whether KvS subunits contribute to these conductances has not been clear, leaving the physiological roles of KvS subunits poorly understood. Here, we identify that two potent Kv2 inhibitors, used in combination, can distinguish conductances of Kv2/KvS heteromers and Kv2-only channels. We find that Kv5, Kv6, Kv8, or Kv9-containing channels are resistant to the Kv2-selective pore-blocker RY785 yet remain sensitive to the Kv2-selective voltage sensor modulator guangxitoxin-1E (GxTX). Using these inhibitors in mouse superior cervical ganglion neurons, we find predominantly RY785-sensitive conductances consistent with channels composed entirely of Kv2 subunits. In contrast, RY785-resistant but GxTX-sensitive conductances consistent with Kv2/KvS heteromeric channels predominate in mouse and human dorsal root ganglion neurons. These results establish an approach to pharmacologically distinguish conductances of Kv2/KvS heteromers from Kv2-only channels, enabling investigation of the physiological roles of endogenous KvS subunits. These findings suggest that drugs which distinguish KvS subunits could modulate electrical activity of subsets of Kv2-expressing cell types. - Source: PubMed
Publication date: 2025/05/27
Stewart Robert GMarquis Matthew JamesJo SooyeonHarris Brandon JAberra Aman SCook VerityWhiddon ZacharyYarov-Yarovoy VladimirFerns MichaelSack Jon T - Toxoplasma gondii can cause severe damage to immunodeficient hosts, and also compromise brain structure and function in immunocompetent hosts during latent infection. In China, the two different isolates, Chinese I (ToxoDB#9) and Chinese III are dominant epidemic strains widely spreading in humans and domestic animals and can lead to latent infection in host brain tissues, but the comparison of their manipulation patterns and mechanisms remains unclear. - Source: PubMed
Publication date: 2025/05/26
Zhou Bei-BeiDong Hong-JieSun HangXie Xiao-ManXie Huan-HuanZhu Wen-JuLi Ya-NanXu ChaoCao Jian-PingZhao Gui-HuaYin Kun