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Serine protease inhibitor Kazal type 1 (SPINK1) plays an important role in preventing pancreatitis by inhibiting activated trypsin in the pancreas. The N34S variant of SPINK1 was found to be associated with chronic pancreatitis. However, this mutation is also expressed in the healthy population, indicating that the mutation alone does not cause the disease.
In this study, we investigated at single molecular level the effect of pH on the binding characteristics of human cationic trypsin to SPINK1 by single-molecule force spectroscopy (SMFS).
We found that at pH 8.0, trypsin shows twice the binding force to wild type SPINK1 (90.9 pN ± 3.9 pN) compared to the N34S mutant (47.3 pN ± 3.9 pN). An acidic pH of 4.8 results in a lower binding forces for trypsin-wild type SPINK1 (41.9 pN ± 4.0 pN) to a similar level as the binding force of trypsin-N34S mutant (54.6 pN ± 4.6 pN) complexes. These results are complemented by dynamic force spectroscopy findings which show a higher stability of the wild type SPINK1-trypsin complexes at pH 8.0 in comparison to N34S mutant-trypsin complexes. In addition, the binding profiles for both wild type and N34S mutant SPINK1 to trypsin equalize at pH 4.8.
Our results indicate that the presence of the mutation in the healthy population would most probably not affect the interaction with trypsin at acidic pH such as physiological conditions in pancreatic acinar cells. However, an increase in pH, leads to a difference of binding strength between SPINK1 or N34S mutant towards human cationic trypsin. These findings may be relevant for understanding the role of SPINK1 and its mutation N34S in the pathogenesis of pancreatitis.
Pancreatitis is an inflammatory disorder of the pancreas with a mortality rate of 5% and severe negative effects on the quality of life. Of all non-malignant gastrointestinal diseases, it is the most common reason for hospitalization. Pancreatitis is a disease of multiple etiologies with different underlying pathomechanisms. Due to the diversity of mechanisms by which homeostasis within the exocrine pancreas can be disrupted, finding appropriate therapeutic approaches is challenging. Current treatment options are inadequate and are mostly limited to supportive treatment like fluid administration, bowel rest, antibiotics and pain control. Although significant advancements have been achieved in recent decades, the mortality rate for pancreatitis has not decreased. Furthermore, progress is slow due to limited patient sample availability and lack of an appropriate cell model. Taking samples from a human pancreas is typically avoided, because damaging the pancreatic tissue can itself induce pancreatitis. Additionally, while it is possible to keep individual acini in culture, it is not possible to grow pancreatic acinar cells. Thus, less appropriate cell models, often derived from pancreatic cancer samples, have to be used. The most common animal model for pancreatitis is mice, with caerulein administration being the most common method of inducing pancreatitis. However, the use of animal models has significant drawbacks, as they are time-consuming, costly, and pose ethical questions. Furthermore, exposing the pancreas to appropriate stimuli in animal models is difficult. For example, alcohol is the leading cause of pancreatitis in humans, but is typically avoided by animals. Thus, alcohol feeding methods had to be developed to overcome the natural aversion of rodents to alcohol. Results obtained from animal models are also often not transferable into clinical trials and outcomes in humans remain largely unpredictable. Due to the lack of experimental models, our understanding of this highly complex disease is still limited and significant progress is required for the development of effective therapy options.
In this dissertation recombinantly expressed trypsin isoforms and variants of the serine protease inhibitor Kazal-type 1 (SPINK1) inhibitor are used to investigate mechanisms, by which tryptic activity is regulated in pancreatic acinar cells. With premature tryptic activity in the exocrine pancreas being the common focal point of most etiologies connected to pancreatitis, trypsin represents by far the most promising target for treating pancreatitis. Understanding the mechanisms by which the pancreas protects itself and rationalizing mutations that can undermine these protective mechanisms, are important steps towards developing effective therapies.