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Exp Clin Endocrinol Diabetes 2011; 119(1): 26-29
DOI: 10.1055/s-0030-1255106
Article

© J. A. Barth Verlag in Georg Thieme Verlag KG Stuttgart · New York

Multifactorial Genesis of Pancreatitis in Primary Hyperparathyroidism: Evidence for “Protective” (PRSS2) and “Destructive” (CTRC) Genetic Factors

P. Felderbauer1 , 3 , E. Karakas2 , 3 , V. Fendrich2 , R. Lebert1 , D. K. Bartsch2 , K. Bulut1
  • 1Department of Medicine I, St. Josef-Hospital, Ruhr-University, Medical School, Bochum
  • 2Department of Visceral-, Thoracic- and Vascular Surgery, University-Hospital Gießen-Marburg, Marburg, Germany
  • 3Both authors contributed equally
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Publication History

received 26.01.2010 first decision 05.05.2010

accepted 02.06.2010

Publication Date:
12 July 2010 (online)

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Abstract

Objective: A relationship between primary hyperparathyroidism (pHPT) and pancreatitis has long been debated and remains a rare epiphenomenon. In a cohort of patients with pHPT and pancreatitis mutations in the serine protease inhibitor Kazal type I (SPINK1) and cystic fibrosis transmembrane conductance regulator (CFTR) genes, that increase the risk for pancreatitis have already been detected. Among the identification of additional pancreatitis-associtated mutations in the Chymotrypsin C gene (CTRC) it became clear that also protective genetic variants exist in the anionic trypsinogen gene (PRSS2) that decrease susceptibility for pancreatitis. Our aim was to detect either protective or inducing genetic factors in a large cohort of pHPT patients.

Methods: Among 1 259 patients with pHPT, 57 patients were identified with pancreatitis (4.5%). DNA was available from 31 patients (16 acute pancreatitis/15 chronic pancreatitis). These individuals and 100 patients with pHPT without pancreatitis were analysed for CTRC (p.R254W and p.K247_R254del) and PRSS2 (p.G191R) mutations using melting curve analysis and DNA sequencing or PCR and gel electrophoresis (in case of p.K247_R254del CTRC).

Results: 2 of 31 patients with pHPT and pancreatitis carried the CTRC p.R254W missense mutation (6.5%), while all 100 pHPT controls without pancreatitis showed no CTRC mutation (P=0.055). No further SPINK1 p.N34S (n=4) mutations were detected but the probability of either CTRC or SPINK1 mutations in pHPT patients with pancreatitis is high (P<0.05). 1 patient was trans-heterozygous (SPINK1: N34S/CTRC p.R254W). CTRC p.K247_R254del was not detected in both groups. PRSS2 (p.G191R) mutation was present in 1 patient with pancreatitis (3.2%) and in 6 pHPT controls (6%) (P=1).

Conclusion: This study underlines the relevance of a genetic background in pHPT related pancreatitis. However, it only indicates that the CTRC (p.R254W) mutation might also contribute to the panel of mutations (SPINK1 and CFTR) that have been formerly reported to elevate pancreatitis susceptibility in pHPT. Besides it suggests that protective genetic variants, i. e., p.G191R PRSS2, may contribute to the low prevalence of pancreatitis in pHPT patients.

Key words

pancreatitis - hyperparathyroidism - hypercalcaemia - PRSS2 - CTRC

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Correspondence

P. FelderbauerMD 

Department of Medicine I

St. Josef-Hospital

Ruhr-University of Bochum

Gudrunstraße 54

44791 Bochum

Germany

Phone: +49/0234/509 2378

Fax: +49/0234/509 2396

Email: peter.felderbauer@rub.de