Non-coding variants disrupting a tissue-specific regulatory element in HK1 cause congenital hyperinsulinism

Wakeling, Matthew N.; Owens, Nick; Hopkinson, Jessica R.; Johnson, Matthew; Houghton, Jayne; Dastamani, Antonia; Flaxman, Christine S.; Wyatt, Rebecca C.; Hewat, Thomas I.; Hopkins, Jasmin J; Laver, Thomas W; Heugten, Rachel van; Weedon, Michael N.; Franco, Elisa De; Patel, Kashyap; Ellard, Sian; Morgan, Noel G.; Cheesman, Edmund; Banerjee, Indraneel; Hattersley, Andrew T.; Dunne, Mark J.; Barić, Ivo; Vries, Liat de; Hassan, Samar Sabir; Humayun, Khadija Nuzhat; Levy‐Khademi, Floris; Limbert, Catarina; Rami‐Merhar, Birgit; Mericq, Verónica; Neville, Kristen A; Ouarezki, Yasmine; Tangari, Ana; Verge, Charles F.; Wiltshire, Esko; Richardson, Sarah J.; Flanagan, Sarah E.

doi:10.1038/s41588-022-01204-x

Cited by 19 publications

(15 citation statements)

References 50 publications

(85 reference statements)

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“…These features are similar to promoter element features of housekeeping genes, tailored for their ubiquitous expression [67]. HK1 promoter also contains regulatory sites known as sp sites within the P2 BOX which are essential for promoter activity and binding of protein factors in lower vertebrates to humans [60,68,69]. The role of non-coding elements in regulating HK1 and their association with congenital hyperinsulinism has also been reported [68].…”

Section: Regulation Of Hexokinase Expressionmentioning

confidence: 82%

“…HK1 promoter also contains regulatory sites known as sp sites within the P2 BOX which are essential for promoter activity and binding of protein factors in lower vertebrates to humans [60,68,69]. The role of non-coding elements in regulating HK1 and their association with congenital hyperinsulinism has also been reported [68]. Alternative splicing forms multiple HK1 isoforms, i.e., HK1 (ubiquitous), HKR (erythrocytes), HK-TA/TB (testis-A/B), HK-TB (testis-B), and HK-TD (testis-D).…”

Section: Regulation Of Hexokinase Expressionmentioning

confidence: 99%

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Aiding Cancer’s “Sweet Tooth”: Role of Hexokinases in Metabolic Reprogramming

Farooq¹,

Ismail²,

Bhat³

et al. 2023

Preprint

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Hexokinases (HKs) convert hexose sugars to hexose-6-phosphate, thus trapping them inside cells to meet the synthetic and energetic demands. HKs participate in various standard and altered physiological processes, including cancer, primarily through the reprogramming of cellular metabolism. Four canonical HKs have been identified with different expression patterns across tissues. HKs 1-3 play a role in glucose utilization, whereas HK 4 (glucokinase, GCK) also acts as a glucose sensor. Recently, a novel 5th HK, hexokinase domain containing 1 (HKDC1), has been identified, which plays a role in whole-body glucose utilization and insulin sensitivity. Beyond the metabolic functions, HKDC1 is differentially expressed in many forms of human cancer. This review focuses on the role of HKs, particularly HKDC1, in metabolic reprogramming and cancer progression.

show abstract

Section: Regulation Of Hexokinase Expressionmentioning

confidence: 82%

Section: Regulation Of Hexokinase Expressionmentioning

confidence: 99%

Aiding Cancer’s “Sweet Tooth”: Role of Hexokinases in Metabolic Reprogramming

Farooq¹,

Ismail²,

Bhat³

et al. 2023

Preprint

View full text Add to dashboard Cite

show abstract

“…These features are similar to promoter element features of housekeeping genes, tailored for their ubiquitous expression [64]. HK1 promoter also contains regulatory sites known as sp sites within the P2 BOX, which are essential for promoter activity and the binding of protein factors in lower vertebrates to humans [57,65,66]. The role of non-coding elements in regulating HK1 and their association with congenital hyperinsulinism has also been reported [65].…”

Section: Regulation Of Hexokinase Expressionmentioning

confidence: 82%

“…HK1 promoter also contains regulatory sites known as sp sites within the P2 BOX, which are essential for promoter activity and the binding of protein factors in lower vertebrates to humans [57,65,66]. The role of non-coding elements in regulating HK1 and their association with congenital hyperinsulinism has also been reported [65]. Alternative splicing generates multiple HK1 isoforms, i.e., HK1 (ubiquitous), HKR (erythrocytes), HK-TA/TB (testis-A/B), HK-TB (testis-B), and HK-TD (testis-D).…”

Section: Regulation Of Hexokinase Expressionmentioning

confidence: 99%

Aiding Cancer’s “Sweet Tooth”: Role of Hexokinases in Metabolic Reprogramming

Farooq

Ismail

Bhat

et al. 2023

Life

View full text Add to dashboard Cite

Hexokinases (HKs) convert hexose sugars to hexose-6-phosphate, thus trapping them inside cells to meet the synthetic and energetic demands. HKs participate in various standard and altered physiological processes, including cancer, primarily through the reprogramming of cellular metabolism. Four canonical HKs have been identified with different expression patterns across tissues. HKs 1–3 play a role in glucose utilization, whereas HK 4 (glucokinase, GCK) also acts as a glucose sensor. Recently, a novel fifth HK, hexokinase domain containing 1 (HKDC1), has been identified, which plays a role in whole-body glucose utilization and insulin sensitivity. Beyond the metabolic functions, HKDC1 is differentially expressed in many forms of human cancer. This review focuses on the role of HKs, particularly HKDC1, in metabolic reprogramming and cancer progression.

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“…2). Recently, Wakeling et al performed whole genome sequencing on 135 individuals with genetic testing negative HI and identified non-coding variants within a regulatory region of HK1 intron 2 that co-segregated with disease in families [7 ▪▪ ]. Using epigenomic analysis, single-nuclei assay for transposase-accessible chromatine with sequencing and a high-throughput genomic and epigenomic technique, they demonstrated that these variants encompass a region of chromatin accessibility within a regulatory domain for the HK1 promoter.…”

Section: Molecular Mechanisms Of Diseasementioning

confidence: 99%

Bridging the gaps: recent advances in diagnosis, care, and outcomes in congenital hyperinsulinism

Rosenfeld

León

2023

Current Opinion in Pediatrics

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Purpose of review To highlight advances in congenital hyperinsulinism (HI), including newly described molecular mechanisms of disease, novel therapeutic interventions, and improved understanding of long-term outcomes. Recent findings Important advances have been made elucidating the molecular mechanisms responsible for HI. Non-coding variants in HK1 have been found to cause aberrant hexokinase expression. Inactivating mutations in SLC25A36 have been identified in children with features of the hyperinsulinism hyperammonemia syndrome. Low-level mosaic mutations in known HI genes have been detected in cases of ‘genetic testing negative’ HI. Identification and localization of focal HI lesions remains a priority, since focal HI can be cured with surgery. Use of 68Ga-NODAGA-exendin-4 PET has been proposed to localize focal lesions. Additional studies are needed before this technique replaces 18F-DOPA PET as standard of care. Treatment options for children with diffuse HI remain limited. The long-acting somatostatin analog, lanreotide, was shown to significantly improve glycemic control in a large series of children with HI. New therapies are under development, with promising preliminary results. Long-term quality of life and neurodevelopmental outcomes remain suboptimal. Summary Advanced genetic and epigenomic analytic techniques have uncovered novel molecular mechanisms of HI. Development of new drugs holds promise to improve long-term outcomes for individuals with HI.

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Non-coding variants disrupting a tissue-specific regulatory element in HK1 cause congenital hyperinsulinism

Cited by 19 publications

References 50 publications

Aiding Cancer’s “Sweet Tooth”: Role of Hexokinases in Metabolic Reprogramming

Aiding Cancer’s “Sweet Tooth”: Role of Hexokinases in Metabolic Reprogramming

Aiding Cancer’s “Sweet Tooth”: Role of Hexokinases in Metabolic Reprogramming

Bridging the gaps: recent advances in diagnosis, care, and outcomes in congenital hyperinsulinism

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