Abstract
Tropical Calcific Pancreatitis (TCP) is a neglected juvenile form of chronic non-alcoholic pancreatitis. Cathepsin B (CTSB), a lysosomal protease involved in the cellular degradation process, has recently been studied as a potential candidate gene in the pathogenesis of TCP. According to the Cathepsin B hypothesis, mutated CTSB can lead to premature intracellular activation of trypsinogen, a key regulatory mechanism in pancreatitis. So far, CTSB mutations have been studied in pancreatitis and neurodegenerative disorders, but little is known about the structural and functional effect of variants in CTSB. In this study, we investigated the effect of single nucleotide variants (SNVs) specifically associated with TCP, using molecular dynamics and simulation algorithms. There were two non-synonymous variants (L26V and S53G) of CTSB, located in the propeptide region. We tried to predict the effect of these variants on structure and function using multiple algorithms: SIFT, Polyphen2, PANTHER, SDM sever, i-Mutant2.0 suite, mCSM algorithm, and Vadar. Further, using databases like miRdbSNP, PolymiRTS, and miRNASNP, two SNPs in the 3′UTR region were predicted to affect the miRNA binding sites. Structural mutated models of nsSNP mutants (L26V and S53G) were prepared by MODELLER v9.15 and evaluated using TM-Align, Verify 3D, ProSA and Ramachandran plot. The 3D mutated structures were simulated using GROMACS 5.0 to predict the impact of these SNPs on protein stability. The results from in silico analysis and molecular dynamics simulations suggested that these variants in the propeptide region of Cathepsin B could lead to structural and functional changes in the protein and thus could be pathogenic. Hence, the structural and functional analysis results have given interim conclusions that these variants can have a deleterious effect in TCP pathogenesis, either uniquely or in combination with other mutations. Thus, it could be extrapolated that Cathepsin B gene can be screened in samples from all TCP patients in future, to decipher the distribution of variants in patients.
Highlights
Pancreatitis is a multifactorial, heterogeneous disease whose etiologies are still enigmatic
The results from in silico analysis and molecular dynamics simulations suggested that these variants in the propeptide region of cathepsin B could lead to structural and functional changes in the protein
B and zymogens.(16) The reason behind this colocalization is yet to be deciphered which can be due to mutations in procathepsin B or in the molecules associated with the trafficking of procathepsin B in diseased state. Taking this as a background, we studied the effect of two non-synonymous mutations in the coding region of procathepsin B, screened in the Tropical CalcificPancreatitis (TCP) patients by molecular dynamics and simulation studies
Summary
Pancreatitis is a multifactorial, heterogeneous disease whose etiologies are still enigmatic. We try to comply with the “cathepsin B hypothesis”(15) in tropical calcific pancreatitis According to this hypothesis, cathepsin B plays an essential role in the premature activation of trypsinogen in the pancreas, largely due to colocalization of cathepsin. Evidential results from the structural analysis and comparison of 2D and 3D mutated models of cathepsin B to wild-type protein has implicated the potential role of these variants in the pathobiology of tropical calcific pancreatitis. This is the first attempt to structurally and functionally characterize the variants found in human cathepsin B protein screened in TCP patients
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