Calcium sensing receptor signalling in physiology and cancer

Brennan, Sarah C.; Thiem, Ursula; Roth, Susanne; Aggarwal, Abhishek; Fetahu, Irfete S.; Tennakoon, Samawansha; Gomes, Ana Rita; Brandi, Maria Luisa; Bruggeman, Frank J.; Mentaverri, Romuald; Riccardi, Daniela; Kállay, Enikö

doi:10.1016/j.bbamcr.2012.12.011

Cited by 125 publications

(125 citation statements)

References 162 publications

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“…This finding was in agreement with another study, which also showed that cation-sensing receptors are not activated by Zn 2+ (Riccardi 1999). The other well-described cation receptor is the Ca 2+ -sensing receptor (CaSR) (Brown 2000;Brennan et al 2013); despite the link between these ions, the Zn 2+ -dependent Ca 2+ increase was distinct from the activity of the CaSR as overexpression of CaSR did not produce an increase in Ca 2+ following application of extracellular Zn 2+ (Hershfinkel et al 2001 2+ , enhanced activation of the mitogen-activated protein (MAP) kinase pathway and the PI3 kinase pathways was observed. These pathways are closely linked to enhanced cell survival and proliferation (Chappell et al 2011), and thus the ZnR may be the mediator of the well-established role of Zn 2+ (MacDonald 2000).…”

supporting

confidence: 89%

The Zinc-Sensing Receptor, ZnR/GPR39: Signaling and Significance

Hershfinkel

2014

Zinc Signals in Cellular Functions and Disorders

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The structural role of Zn 2+ in stabilizing numerous enzymes and zinc fingers of transcription factors has been well established for several decades. Therefore, the major effects of this metal ion on growth, development, and cognitive function were not surprising. The importance of cellular homeostasis of Zn 2+ is underlined by the identification of more than 20 proteins involved in transport of Zn 2+ into the cytoplasm and various organelles. In the past decade, evidence for a signaling role of Zn 2+ is emerging, suggesting this ion acts as a first and second messenger. Thus, transient changes in extracellular and intracellular Zn 2+ were monitored and Zn 2+ -dependent regulation of multiple signaling pathways was shown. We have identified the function of ZnR, a Gq protein-coupled receptor that triggers the release of Ca 2+ via the IP3 pathway. This ZnR-dependent signaling regulates cellular pathways involved in survival and proliferation, such as the MAP and PI3 kinase pathways, as well as modulation of ion transport systems such as the Na + /H + exchanger or the K + /Cl À co-transporter. The GPR39 was then shown to mediate extracellular Zn 2+ -dependent ZnR signaling. Here we discuss the major role of ZnR/GPR39 as the link between extracellular Zn 2+ and intracellular signaling pathways regulating the physiological function of epithelial and neuronal cells. A major future challenge will be to identify the role of ZnR/GPR39 in diseases linked to Zn 2+ dyshomeostasis.

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supporting

confidence: 89%

The Zinc-Sensing Receptor, ZnR/GPR39: Signaling and Significance

Hershfinkel

2014

Zinc Signals in Cellular Functions and Disorders

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“…Blocking/inhibiting Trpv5/6 activity using four TRPV5/6 inhibitors/blockers all resulted in elevated pAkt signal in NaR cells under normal [Ca 2 þ ] conditions. These data suggest that Trpv5/6 represses IGF signaling and suppresses NaR cell proliferation under normal 27 Activation of CaSR has been shown to increase mammalian TRPV5 activity. 38 This possibility was not supported by our data.…”

Section: Discussionmentioning

confidence: 71%

“…The Ca 2 þ -sensing receptor (CaSR), a class C G-protein-coupled receptor that senses and is activated by high extracellular [Ca 2 þ ], has a key role in maintaining Ca 2 þ homeostasis by regulating the release of parathyroid hormone (PTH). 27 The CaSR is expressed in the entire digestive tract, including the colon, and has been hypothesized to be a major driver of colon cell differentiation under high extracellular [Ca 2 þ ]. 28 However, addition of NPS 2143, a selective CaSR antagonist, 29 to cultured Caco-2 cells did not affect IGF-induced Akt signaling in either normal or low [Ca 2 þ ] conditions (Figure 8e).…”

Section: Resultsmentioning

confidence: 99%

Calcium deficiency-induced and TRP channel-regulated IGF1R-PI3K-Akt signaling regulates abnormal epithelial cell proliferation

et al. 2013

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Calcium deficiency causes abnormal colonic growth and increases colon cancer risk with poorly understood mechanisms. Here we elucidate a novel signaling mechanism underlying the Ca 2 þ deficiency-induced epithelial proliferation using a unique animal model. The zebrafish larval yolk sac skin contains a group of Ca 2 þ -transporting epithelial cells known as ionocytes. Their number and density increases dramatically when acclimated to low [Ca 2 þ ] environments. BrdU pulse-labeling experiments suggest that low [Ca 2 þ ] stimulates pre-existing ionocytes to re-enter the cell cycle. Low [Ca 2 þ ] treatment results in a robust and sustained activation of IGF1R-PI3K-Akt signaling in these cells exclusively. These ionocytes specifically express Igfbp5a, a high-affinity and specific binding protein for insulin-like growth factors (IGFs) and the Ca 2 þ -selective channel Trpv5/6. Inhibition or knockdown of Igfbp5a, IGF1 receptor, PI3K, and Akt attenuates low [Ca 2 þ ]-induced ionocyte proliferation. The role of Trpv5/6 was investigated using a genetic mutant, targeted knockdown, and pharmacological inhibition. Loss-of-Trpv5/6 function or expression results in elevated pAkt levels and increased ionocyte proliferation under normal [Ca 2 þ ]. These increases are eliminated in the presence of an IGF1R inhibitor, suggesting that Trpv5/6 represses IGF1R-PI3K-Akt signaling under normal [Ca 2 þ ]. Intriguingly, blockade of Trpv5/6 activity inhibits the low [Ca 2 þ ]-induced activation of Akt. Mechanistic analyses reveal that the low [Ca 2 þ ]-induced IGF signaling is mediated through Trpv5/6-associated membrane depolarization. Low extracellular [Ca 2 þ ] results in a similar amplification of IGF-induced PI3K-PDK1-Akt signaling in human colon cancer cells in a TRPV6-dependent manner. These results uncover a novel and evolutionarily conserved signaling mechanism that contributes to the abnormal epithelial proliferation associated with Ca 2 þ deficiency.

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“…Asimismo, la suplementación con Ca reduce la recurrencia de los adenomas de colon. Según diversos estudios, este efecto del Ca se relaciona con la capacidad de este catión de unirse a ácidos grasos y ácidos biliares en la luz intestinal, evitando que ambos, en su forma ionizada, puedan ejercer un efecto proliferativo sobre los colonocitos, aumentando la probabilidad de formación de células con errores del genoma (20).…”

Section: Calcio Y Cáncerunclassified

El calcio, esencial para la salud

Victoria¹

2016

Nutr Hosp

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Calcium (Ca) is the most abundant mineral element in our body. It accounts for about 2% of body weight. The functions of calcium are: a) functions skeletal and b) regulatory functions. Bone consists of a protein matrix that mineralizes mainly with calcium (the most abundant), phosphate and magnesium, for it is essential an adequate dietary intake of Ca, phosphorus and vitamin D. The ionic Ca (Ca 2+ ) is essential to maintain and / or perform different specialized functions of, virtually, all body cells cellular. Because of its important functions Ca 2+ must be closely regulated, keeping plasma concentrations within narrow ranges. For this reason there is an accurate response against hypocalcemia or hypercalcemia in which the parathormone, calcitriol, calcitonin and vitamin K are involved. Ca intakes in the Spanish population are low in a signifi cant percentage of the older adult's population, especially in women. The main source of Ca in the diet is milk and milk derivatives. Green leafy vegetables, fruits and legumes can be important sources of Ca in a Mediterranean dietary pattern. The bioavailability of dietary Ca depends on physiological and dietary factors. Physiological include age, physiological status (gestation and lactation) Ca and vitamin D status and disease. Several studies relate Ca intake in the diet and various diseases, such as osteoporosis, cancer, cardiovascular disease and obesity. ResumenEl calcio (Ca) es el elemento mineral más abundante en nuestro organismo, ya que forma parte importante del esqueleto y los dientes. Supone alrededor del 2% del peso corporal. Las funciones del calcio son: a) funciones esqueléticas y b) funciones reguladoras. El hueso está formado por una matriz proteica que se mineraliza de forma mayoritaria con calcio (el más abundante), fosfato y magnesio; para ello es imprescindible un correcto aporte dietético de Ca, fósforo y vitamina D. El Ca iónico (Ca 2+ ) es un componente celular imprescindible para mantener y/o realizar las diferentes funciones especializadas de prácticamente todas las células del organismo. Debido a sus importantes funciones, el Ca 2+ debe estar estrechamente regulado, manteniéndose sus concentraciones plasmáticas dentro de unos rangos estrechos. Para ello existe una respuesta precisa frente a la hipocalcemia o la hipercalcemia, en la que intervienen la parathormona, el calcitriol, la calcitonina y la vitamina K. Las ingestas de Ca en la población española son bajas en un porcentaje signifi cativo de la población, especialmente en adultos mayores, sobre todo en las mujeres. La principal fuente de Ca en la dieta son la leche y todos sus derivados. Las verduras de hoja verde, frutas y legumbres pueden tener importancia como fuentes de Ca en un patrón alimentario mediterráneo. La biodisponibilidad del Ca de la dieta depende de factores fi siológicos y dietéticos. Los fi siológicos incluyen la edad, situación fi siológica (gestación y lactación), el estatus de Ca y vitamina D y la enfermedad. Diversos estudios relacionan la ingesta de Ca en ...

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Calcium sensing receptor signalling in physiology and cancer

Cited by 125 publications

References 162 publications

The Zinc-Sensing Receptor, ZnR/GPR39: Signaling and Significance

The Zinc-Sensing Receptor, ZnR/GPR39: Signaling and Significance

Calcium deficiency-induced and TRP channel-regulated IGF1R-PI3K-Akt signaling regulates abnormal epithelial cell proliferation

El calcio, esencial para la salud

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