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RAPGEF3

This article was updated by an external expert under a dual publication model. The corresponding peer-reviewed article was published in the journal Gene. Click to view.
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RAPGEF3
Identifiers
AliasesRAPGEF3, CAMP-GEFI, EPAC, EPAC1, HSU79275, bcm910, Rap guanine nucleotide exchange factor 3
External IDsOMIM: 606057; MGI: 2441741; HomoloGene: 21231; GeneCards: RAPGEF3; OMA:RAPGEF3 - orthologs
Orthologs
SpeciesHumanMouse
Entrez
Ensembl
UniProt
RefSeq (mRNA)

NM_001098531
NM_001098532
NM_006105

NM_001177810
NM_001177811
NM_144850
NM_001357630

RefSeq (protein)

NP_001092001
NP_001092002
NP_006096

NP_001171281
NP_001171282
NP_659099
NP_001344559

Location (UCSC)Chr 12: 47.73 – 47.77 MbChr 15: 97.74 – 97.77 Mb
PubMed search[3][4]
Wikidata
View/Edit HumanView/Edit Mouse

Rap guanine nucleotide exchange factor 3 also known as exchange factor directly activated by cAMP 1 (EPAC1) or cAMP-regulated guanine nucleotide exchange factor I (cAMP-GEFI) is a protein that in humans is encoded by the RAPGEF3 gene.[5][6][7]

As the name suggests, EPAC proteins (EPAC1 and EPAC2) are a family of intracellular sensors for cAMP, and function as nucleotide exchange factors for the Rap subfamily of RAS-like small GTPases.

History and discovery

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Since the landmark discovery of the prototypic second messenger cAMP in 1957, three families of eukaryotic cAMP receptors have been identified to mediate the intracellular functions of cAMP. While protein kinase A (PKA) or cAMP-dependent protein kinase and cyclic nucleotide regulated ion channel (CNG and HCN) were initially unveiled in 1968 and 1985 respectively; EPAC genes were discovered in 1998 independently by two research groups. Kawasaki et al. identified cAMP-GEFI and cAMP-GEFII as novel genes enriched in brain using a differential display protocol and by screening clones with cAMP-binding motif.[7] De Rooij and colleagues performed a database search for proteins with sequence homology to both GEFs for Ras and Rap1 and to cAMP-binding sites, which led to the identification and subsequent cloning of RAPGEF3 gene.[6] The discovery of EPAC family cAMP sensors suggests that the complexity and possible readouts of cAMP signaling are much more elaborate than previously envisioned. This is due to the fact that the net physiological effects of cAMP entail the integration of EPAC- and PKA-dependent pathways, which may act independently, converge synergistically, or oppose each other in regulating a specific cellular function.[8][9][10]

Gene

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Human RAPGEF3 gene is present on chromosome 12 (12q13.11: 47,734,367-47,771,041).[11] Out of the many predicted transcript variants, three that are validated in the NCBI database include transcript variant 1 (6,239 bp), 2 (5,773 bp) and 3 (6,003 bp). While variant 1 encodes for EPAC1a (923 amino acids), both variant 2 and 3 encode EPAC1b (881 amino acids).[5]

Protein family

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In mammals, the EPAC protein family contains two members: EPAC1 (this protein) and EPAC2 (RAPGEF4). They further belong to a more extended family of Rap/Ras-specific GEF proteins that also include C3G (RAPGEF1), PDZ-GEF1 (RAPGEF2), PDZ-GEF2 (RAPGEF6), Repac (RAPGEF5), CalDAG-GEF1 (ARHGEF1), CalDAG-GEF3 (ARHGEF3), PLCε1 (PLCE1) and RasGEF1A, B, C.

Protein structure and mechanism of activation

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EPAC proteins consist of two structural lobes/halves connected by the so-called central “switchboard” region.[12] The N terminal regulatory lobe is responsible for cAMP binding while the C-terminal lobe contains the nucleotide exchange factor activity. At the basal cAMP-free state, EPAC is kept in an auto-inhibitory conformation, in which the N-terminal lobe folds on top of the C-terminal lobe, blocking the active site.[13][14] Binding of cAMP to EPAC induces a hinge motion between the regulatory and catalytic halves. As a consequence, the regulatory lobe moves away from catalytic lobe, freeing the active site.[15][16] In addition, cAMP also prompts conformational changes within the regulatory lobe that lead to the exposure of a lipid binding motif, allowing the proper targeting of EPAC1 to the plasma membrane.[17][18] Entropically favorable changes in protein dynamics have also been implicated in cAMP mediated EPAC activation.[19][20]

Tissue distribution and cellular localization

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Human and mice EPAC1 mRNA expression is rather ubiquitous. As per Human Protein Atlas documentation, EPAC1 mRNA is detectable in all normal human tissues. Further, medium to high levels of corresponding protein are also measureable in more than 50% of the 80 tissue samples analyzed.[21] In mice, high levels of EPAC1 mRNA are detected in kidney, ovary, skeletal muscle, thyroid and certain areas of the brain.[7]

EPAC1 is a multifunctional protein whose cellular functions are tightly regulated in spatial and temporal manners. EPAC1 is localized to various subcellular locations during different stages of the cell cycle.[22] Through interactions with an array of cellular partners, EPAC1 has been shown to form discrete signalsomes at plasma membrane,[18][23][24][25] nuclear-envelope,[26][27][28] and cytoskeleton,[29][30][31] where EPAC1 regulates numerous cellular functions.

Clinical relevance

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Studies based on genetically engineered mouse models of EPAC1 have provided valuable insights into understanding the in vivo functions of EPAC1 under both physiological and pathophysiological conditions. Overall, mice deficient of EPAC1 or both EPAC1 and EPAC2 appear relatively normal without major phenotypic defects. These observations are consistent with the fact that cAMP is a major stress response signal not essential for survival. This makes EPAC1 an attractive target for therapeutic intervention as the on-target toxicity of EPAC-based therapeutics will likely be low. Up to date, genetic and pharmacological analyses of EPAC1 in mice have revealed that EPAC1 plays important roles in cardiac stresses and heart failure,[32][33] leptin resistance and energy homeostasis,[34][35][36] chronic pain,[37][38] infection,[39][40] cancer metastasis,[41] metabolism[42] and secondary hemostasis.[43] Interestingly, EPAC1 deficient mice have prolonged clotting time and fewer, younger, larger and more agonist-responsive blood platelets. EPAC1 is not present in mature platelets, but is required for normal megakaryopoiesis and the subsequent expression of several important proteins involved in key platelets functions.[43]

Pharmacological agonists and antagonists

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There have been significant interests in discovering and developing small modulators specific for EPAC proteins for better understanding the functions of EPAC mediated cAMP signaling, as well as for exploring the therapeutic potential of targeting EPAC proteins. Structure-based design targeting the key difference between the cAMP binding sites of EPAC and PKA led to the identification of a cAMP analogue, 8-pCPT-2’-O-Me-cAMP that is capable of selectively activate EPAC1.[44][45] Further modifications allowed the development of more membrane permeable and metabolically stable EPAC-specific agonists.[46][47][48][49]

A high throughput screening effort resulted in the discovery of several novel EPAC specific inhibitors (ESIs),[50][51][52] among which two ESIs act as EPAC2 selective antagonists with negligible activity towards EPAC1.[51] Another ESI, CE3F4, with modest selectivity for EPAC1 over EPAC2, has also been reported.[53] The discovery of EPAC specific antagonists represents a research milestone that allows the pharmacological manipulation of EPAC activity. In particular, one EPAC antagonist, ESI-09, with excellent activity and minimal toxicity in vivo, has been shown to be a useful pharmacological tool for probing physiological functions of EPAC proteins and for testing therapeutic potential of targeting EPAC in animal disease models.[39][41][54]

Notes

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References

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  2. ^ a b c GRCm38: Ensembl release 89: ENSMUSG00000022469Ensembl, May 2017
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Further reading

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