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Last update 08 May 2025

KCNN2

Last update 08 May 2025

Basic Info

Synonyms

hSK2, KCa2.2, KCNN2

+ [8]

Introduction

Small conductance calcium-activated potassium channel that mediates the voltage-independent transmembrane transfer of potassium across the cell membrane through a constitutive interaction with calmodulin which binds the intracellular calcium allowing its opening (PubMed:10991935, PubMed:33242881, PubMed:9287325). The current is characterized by a voltage-independent activation, an intracellular calcium concentration increase-dependent activation and a single-channel conductance of about 3 picosiemens (PubMed:10991935). Also presents an inwardly rectifying current, thus reducing its already small outward conductance of potassium ions, which is particularly the case when the membrane potential displays positive values, above + 20 mV (PubMed:10991935). The inward rectification could be due to a blockade of the outward current by intracellular divalent cations such as calcium and magnesium and could also be due to an intrinsic property of the channel pore, independent of intracellular divalent ions. There are three positively charged amino acids in the S6 transmembrane domain, close to the pore, that collectively control the conductance and rectification through an electrostatic mechanism. Additionally, electrostatic contributions from these residues also play an important role in determining the intrinsic open probability of the channel in the absence of calcium, affecting the apparent calcium affinity for activation. Forms an heteromeric complex with calmodulin, which is constitutively associated in a calcium-independent manner. Channel opening is triggered when calcium binds the calmodulin resulting in a rotary movement leading to the formation of the dimeric complex to open the gate (By similarity). Plays a role in the repolarization phase of cardiac action potential (PubMed:13679367).

Drugs associated with KCNN2

AP-30663

Target

KCNN2

Mechanism

KCNN2 inhibitors

Active Org.

Acesion Pharma ApS

Originator Org.

Acesion Pharma ApS

Active Indication

Atrial Fibrillation

Inactive Indication-

Drug Highest PhasePhase 2

First Approval Ctry. / Loc.-

First Approval Date20 Jan 1800

NSD-8011

Target

KCNN2 x KCa2.3

Mechanism

KCNN2 inhibitors [+1]

Active Org.

Cadent Therapeutics, Inc.

Originator Org.

NTG Nordic Transport Group A/S

Active Indication

Ataxia

Inactive Indication-

Drug Highest PhaseDiscovery

First Approval Ctry. / Loc.-

First Approval Date20 Jan 1800

Clinical Trials associated with KCNN2

NL-OMON20057

/ SuspendedNot Applicable

Extension of the randomized, double-blind, placebo-controlled single ascending dose study to assess the safety and tolerability of AP30663 in healthy subjects.

Start Date29 Oct 2020

Sponsor / Collaborator

Acesion Pharma ApS

NCT04571385

/ CompletedPhase 2

A Double-Blind, Randomised, Placebo-Controlled, Parallel-Group Study of AP30663 Given Intravenously for Cardioversion in Patients With Atrial Fibrillation

This study will evaluate the efficacy, safety, tolerability and pharmacokinetics (PK) of one or more doses of AP30663 for cardioversion in adult participants with AF.

Start Date09 Sep 2019

Sponsor / Collaborator

Acesion Pharma ApS

EUCTR2018-004445-17-HU

/ Unknown statusPhase 2

A Double-Blind, Randomised, Placebo-Controlled, Parallel-Group Study of AP30663 Given Intravenously for Cardioversion in Patients with Atrial Fibrillation

Start Date30 May 2019

Sponsor / Collaborator

Acesion Pharma ApS

100 Clinical Results associated with KCNN2

100 Translational Medicine associated with KCNN2

0 Patents (Medical) associated with KCNN2

144

Literatures (Medical) associated with KCNN2

01 Apr 2025·Gene

The role of genetic polymorphisms in KCNN2 in cardiovascular complications in patients with renal failure

Article

Author: Gomaa, Azza A ; Nagy, Ibrahim M ; Zeid, Amany M

Patients with end-stage renal disease (ESRD) are at a higher risk of cardiovascular (CV) complications and mortality compared to the general population. This study aimed to investigate the genetic polymorphisms of KCNN2, a key gene encoding a subtype of small-conductance calcium-activated potassium (SK) channels, which regulate an important SK current pathway potentially involved in the development of CV complications, particularly arrhythmias, in ESRD patients. A total of 169 ESRD patients were enrolled in this study. The patients were divided into two groups based on the presence of CV complications: Group I, consisting of 84 patients without CV complications, and Group II, comprising 85 patients with CV complications. Twelve tagging single nucleotide polymorphisms (tSNPs) in KCNN2 were examined. Polymerase chain reaction (PCR) was performed, and genotyping was correlated with CV complications in each group. The TC and CC genotypes of rs10076582, and the GT and TT genotypes of rs11738819 in the KCNN2 gene, were associated with an increased risk of CV complications in ESRD patients. After adjusting for potential risk factors, these associations remained significant. Additionally, KCNN2 haplotypes with the allele combinations GGCCCTCCGAG and AGTCCTCCGGT were significantly associated with a higher risk of CV complications in ESRD patients. In conclusion, our findings report that specific genetic polymorphisms in the KCNN2 gene, particularly the rs10076582 and rs11738819 variants, as well as GGCCCTCCGAG and AGTCCTCCGGT haplotypes, are significantly associated with an increased risk of cardiovascular complications in ESRD patients. These genetic markers may serve as potential biomarkers for identifying individuals at high risk of cardiovascular complications in this vulnerable population.

01 Feb 2025·Journal of Biological Chemistry

A new regulation mechanism for KCNN4, the Ca2+-dependent K+ channel, by molecular interactions with the Ca2+pump PMCA4b

Article

Author: Mignotet, Morgane ; Allegrini, Benoit ; Rapetti-Mauss, Raphaël ; Soriani, Olivier ; Borgese, Franck ; Guizouarn, Hélène

KCNN4, a Ca²⁺-activated K⁺ channel, is involved in various physiological and pathological processes. It is essential for epithelial transport, immune system, and other physiological mechanisms, but its activation is also involved in cancer pathophysiology as well as red blood cell (RBC) disorders. The activation of KCNN4 in RBC leads to loss of KCl and water, a mechanism known as the "Gardos effect" described 70 years ago. This Ca²⁺-induced dehydration is irreversible in human RBC and must be tightly controlled to prevent not only hemolysis but also alterations in RBC rheological properties. In this study, we have investigated the regulation of KCNN4 activity after changes in RBC Ca²⁺ concentration. Using electrophysiology, immunoprecipitation, and proximity ligation assay in human embryonic kidney 293-transfected cells, K562 cells, or RBCs, we have found that KCNN4 and the Ca²⁺ pump PMCA4b (plasma membrane calcium-transporting ATPase 4b) interact tightly with each other, such that the C-terminal domain of PMCA4b regulates KCNN4 activity, independently of the Ca²⁺ extrusion activity of the pump. This regulation was not restricted to KCNN4: the small-conductance Ca²⁺-activated K⁺ channel KCNN2 was similarly regulated by the calcium pump. We propose a new mechanism that could control KCNN4 activity by a molecular inhibitory interaction with PMCA4b. It is suggested that this mechanism could attenuate erythrocyte dehydration in response to an increase in intracellular Ca²⁺.

01 Feb 2025·Experimental Cell Research

The intervention of B. longum metabolites in Fnevs' carcinogenic capacity: A potential double-edged sword

Article

Author: Wu, Xinyu ; Xu, Jingyu ; Yang, Luyi ; Xu, Xiaoxi

Colorectal cancer (CRC) ranks among the most prevalent malignant tumors globally. Fusobacterium nucleatum and its metabolites are effective biological targets for colon cancer promotion. Probiotics such as Bifidobacterium can block the occurrence and development of CRC by regulating the host intestinal mucosal immunity, eliminating carcinogens, and interfering with tumor cell proliferation and apoptosis. We selected six Bifidobacterium species to explore the inhibitory effect of their cell-free supernatant (CFS) on Fusobacterium nucleatum, and screened the best functional strain Bifidobacterium longum (B. longum) to explore its intervention effect on Fnevs infection of CRC cells. In the genus Bifidobacterium, B. longum-CFS can effectively inhibit the growth and membrane formation of Fusobacterium nucleatum. The metabolites of B. longum can inhibit the proliferation, migration and invasion of Fnevs-infected CRC cells. However, the transcriptomic analysis of Fnevs-infected CRC cells treated with Bl-CFS revealed that Bl-CFS exerted inhibitory effects on the expression of specific oncogenes (e.g., Myc, IL16, KCNN2, ACSBG1, Pum1, MET, NR5A2), while simultaneously promoting the expression of other oncogenes. This modulation potentially enhances the proliferation, epithelial-mesenchymal transition (EMT), stemness properties and other characteristics associated with CRC cells. Metabolomics also showed that Bl-CFS altered organic acid and lipid metabolism in Fnevs-infected CRC cells, and switched energy supply from aerobic glucose metabolism (TCA cycle) to anaerobic glycolysis, which increased the malignancy potential of CRC cells. The observed outcome may be attributed to the presence of both probiotics and toxic substances in the metabolites derived from Bifidobacterium longum. Therefore, this study concludes that the anti-colorectal cancer (CRC) effect of natural metabolites derived from Bifidobacterium longum is limited. Future investigations should focus on refining these natural substances and optimizing their composition ratios to extract their essence while eliminating impurities, thereby obtaining anticancer biologics with exceptional and consistent efficacy.

News (Medical) associated with KCNN2

13 Jul 2021

·www.biospace.com

Ambry Genetics Leads in Clinical Contributions to GenCC, a Public Database to Inform the Relationship Between Various Genes and Diseases

ALISO VIEJO, Calif., July 13, 2021 /PRNewswire/ -- Ambry Genetics Corporation (Ambry), a Konica Minolta Precision Medicine (KMPM) company and leader in clinical diagnostic testing, has been the leading organization in contributions to The Gene Curation Coalition (GenCC) Database since its launch in December 2020. This coalition of public and private research and commercial entities work together to facilitate the consistent assessment and validation of gene-disease relationships to unify standards and terminologies for socially shared collaborations on gene curation projects. "We know our contribution to this data is vital in providing the right diagnosis to healthcare providers and their patients," said Tom Schoenherr, Chief Executive Officer at Ambry Genetics. "In addition, these advancements will assist in shaping our technological platforms CARE™ and LATTICE™ by providing relevant data to make informed healthcare and therapy decisions. It's exciting to be leading and innovating in this space." Ambry has pioneered the discovery of several gene-disease relationships, including the KCNN2 gene. These gene mutations are now known to cause a KCNN2-related neurodevelopmental disorder which commonly presents with tremor and extrapyramidal movements. Though the variant in the KCNN2 gene had previously been associated with neurological disorders in animals, association in humans was unknown in 2016 when Ambry Exome team scientists were able to identify and report rare, de novo variants in this gene as a potential cause of disease during exome analysis of uncharacterized genes in a patient with a previously unsolved neurodevelopmental disorder. In the fall of 2020, Ambry, in collaboration with researchers at the Paris Brain Institute (ICM) of La Pitié Salpêtrière University Hospital in France, and other global collaborators, published on the new gene in the peer-reviewed scientific journal Brain.1 After issuing reclassification reports on patients with KCNN2 sourced through Ambry's Patient-for-Life Program, Ambry added the gene to its appropriate neurology test panels in December 2020 and currently offers the KCNN2 gene in its test menu. The collective data shows that there is "Strong" clinical validity for the role of KCNN2 in this syndromic neurodevelopmental disorder and Ambry plans to submit this gene-disease relationship to the GenCC database. Since the GenCC Database launched in December 2020, Ambry has contributed over 1,460 curated published genes on their website, more than any other single public or private entity globally, including national research entities and private industry groups. Ambry's contribution is attributed to its history as a pioneer of clinical validity standards, especially among private industry groups, launching the initiative back in 2015. In addition, ACMG updated their recommendations for exome and genome secondary findings in the May 2021 publication of Genetics in Medicine2, an ACMG-published monthly journal focused on medical genetics. Ambry updated its exome menu on June 14 to include all 73 genes on the ACMG v3.0 list, making it among the first labs to address the ACMG recommendations. The recommendations developed by the ACMG Secondary Findings Maintenance Working Group (SFWG), convened by the Board of Directors, evaluate the minimum list of genes assessed in individuals undergoing clinical exome and genome sequencing. About Ambry Genetics Ambry Genetics, as part of Konica Minolta Precision Medicine, excels at translating scientific research into clinically actionable test results based upon a deep understanding of the human genome and the biology behind genetic disease. Our unparalleled track record of discoveries over 20 years, and growing database that continues to expand in collaboration with academic, corporate and pharmaceutical partners, means we are first to market with innovative products and comprehensive analysis that enable clinicians to confidently inform patient health decisions. We care about what happens to real people, their families, and the people they love, and remain dedicated to providing them and their clinicians with deeper knowledge and fresh insights, so together they can make informed, potentially life-altering healthcare decisions. About Konica Minolta Precision Medicine, Inc. Konica Minolta Precision Medicine, Inc. (KMPM) is a comprehensive precision diagnostics company dedicated to advancing technologies that accurately predict, detect and treat disease. Powered by proprietary software platforms, best-in-class genomics technology from Ambry Genetics Corporation, and industry-leading radiology and pathology services from Invicro, LLC, KMPM is uniquely equipped to collect, analyze, and report on multi-modal precision diagnostic data sets. This comprehensive approach will drive clinical access to novel diagnostic assays through the company's extensive network of healthcare providers and pharmaceutical partners. Media Contact: Liz Squire esquire@tridentdmg.com 1 Mochel, Fanny et al. "Variants in the SK2 channel gene (KCNN2) lead to dominant neurodevelopmental movement disorders." Brain : a journal of neurology, vol. 143,12 (2020): 3564-3573. 1 Dec 2020, doi:10.1093/brain/awaa346 2 Miller, David T et al. "ACMG SF v3.0 list for reporting of secondary findings in clinical exome and genome sequencing: a policy statement of the American College of Medical Genetics and Genomics (ACMG)." Genetics in medicine: official journal of the American College of Medical Genetics, 10.1038/s41436-021-01172-3. 20 May. 2021, doi:10.1038/s41436-021-01172-3

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KCNN2

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