RAPGEF4


Rap guanine nucleotide exchange factor 4, also known as exchange protein directly activated by cAMP 2 is a protein that in humans is encoded by the RAPGEF4 gene.
Epac2 is a target of cAMP, a major second messenger in various cells. Epac2 is coded by the RAPGEF4 gene, and is expressed mainly in brain, neuroendocrine, and endocrine tissues. Epac2 functions as a guanine nucleotide exchange factor for the Ras-like small GTPase Rap upon cAMP stimulation. Epac2 is involved in a variety of cAMP-mediated cellular functions in endocrine and neuroendocrine cells and neurons.

Gene and transcripts

Human Epac2 is coded by RAPGEF4 located at chromosome 2q31-q32, and three isoforms are generated by alternate promoter usage and differential splicing. Epac2A is a multi-domain protein with 1,011 amino acids, and is expressed mainly in brain and neuroendocrine and endocrine tissues such as pancreatic islets and neuroendocrine cells. Epac2A is composed of two regions, an amino-terminal regulatory region and a carboxy-terminal catalytic region. The regulatory region contains two cyclic nucleotide-binding domains and a DEP domain. The catalytic region, which is responsible for the activation of Rap, consists of a CDC25 homology domain, a Ras exchange motif domain, and a Ras association domain. Epac2B is devoid of the first cNBD-A domain and Epac2C is devoid of a cNBD-A and a DEP domain. Epac2B and Epac2C are expressed specifically in adrenal gland and liver, respectively.

Mechanism of action

The crystal structure reveals that the catalytic region of Epac2 interacts with cNBD-B intramolecularly, and in the absence of cAMP is sterically masked by a regulatory region, which thereby inhibits interaction between the catalytic region and Rap1. The crystal structure of the cAMP analog-bound active form of Epac2 in a complex with Rap1B indicates that the binding of cAMP to the cNBD-B domain induces the dynamic conformational changes that allow the regulatory region to rotate away. This conformational change enables access of Rap1 to the catalytic region and allows activation.

Specific agonists

Several Epac-selective cAMP analogs have been developed to clarify the functional roles of Epacs as well those of the Epac-dependent signaling pathway distinct from the PKA-dependent signaling pathway. The modifications of 8-position in the purine structure and 2’-position in ribose is considered to be crucial to the specificity for Epacs. So far, 8-pCPT-2’-O-Me-cAMP and its membrane permeable form 8-pCPT-AM are used for their great specificity toward Epacs. Sulfonylurea drugs, widely used for the treatment of type 2 diabetes through stimulation of insulin secretion from pancreatic β-cells, have also been shown to specifically activate Epac2.

Function

In pancreatic β-cells, cAMP signaling, which can be activated by various extracellular stimuli including hormonal and neural inputs primarily through Gs-coupled receptors, is of importance for normal regulation of insulin secretion to maintain glucose homeostasis. Activation of cAMP signaling amplifies insulin secretion by Epac2-dependent as well as PKA-dependent pathways. Epac2-Rap1 signaling is critical to promote exocytosis of insulin-containing vesicles from the readily releasable pool. In Epac2-mediated exocytosis of insulin granules, Epac2 interacts with Rim2, which is a scaffold protein localized in both plasma membrane and insulin granules, and determines the docking and priming states of exocytosis. In addition, piccolo, a possible Ca2+ sensor protein, interacts with the Epac2-Rim2 complex to regulate cAMP-induced insulin secretion. It is suggested that phospholipase C-ε, one of the effector proteins of Rap, regulates intracellular Ca2+ dynamics by altering the activities of ion channels such as ATP-sensitive potassium channel, ryanodine receptor, and IP3 receptor.
In neurons, Epac is involved in neurotransmitter release in glutamatergic synapses from calyx of Held and in crayfish neuromuscular junction. Epac also has roles in the development of brain by regulation of neurite growth and neuronal differentiation as well as axon regeneration in mammalian tissue. Furthermore, Epac2 may regulate synaptic plasticity, and thus control higher brain functions such as memory and learning.
In heart, Epac1 is expressed predominantly, and is involved in the development of hypertrophic events by chronic cAMP stimulation through β-adrenergic receptors. In contrast, chronic stimulation of Epac2 may be a cause of cardiac arrhythmia through CaMKII-dependent diastolic sarcoplasmic reticulum Ca2+ release in mice. Epac2 also is involved in GLP-1-stimulated atrial natriuretic peptide secretion from heart.

Clinical implications

As Epac2 is involved in many physiological functions in various cells, defects in the Epac2/Rap1 signaling mechanism could contribute to the development of various pathological states. Studies of Epac2 knockout mice indicate that Epac-mediated signaling is required for potentiation of insulin secretion by incretins such as glucagon-like peptide-1 and glucose-dependent insulinotropic polypeptide, suggesting that Epac2 is a promising target for treatment of diabetes. In fact, incretin-based diabetes therapies are currently used in clinical practice worldwide; development of Epac2-selective agonists might well lead to the discovery of further novel anti-diabetic drugs. An analog of GLP-1 has been shown to exert a blood pressure-lowering effect by stimulation of atrial natriuretic peptide secretion through Epac2. In heart, chronic stimulation of β-adrenergic receptor is known to progress to arrhythmia through an Epac2-dependent mechanism. In brain, up-regulation of Epac1 and down-regulation of Epac2 mRNA are observed in patients with Alzheimer’s disease, suggesting roles of Epacs in the disease. An Epac2 rare coding variant is found in patients with autism and could be responsible for the dendritic morphological abnormalities.
Thus, Epac2 is involved in the pathogenesis and pathophysiology of various diseases, and represents a promising therapeutic target.