1. Academic Validation
  2. Region-specific bioconversion of dynorphin neuropeptide detected by in situ histochemistry and MALDI imaging mass spectrometry

Region-specific bioconversion of dynorphin neuropeptide detected by in situ histochemistry and MALDI imaging mass spectrometry

  • Peptides. 2017 Jan:87:20-27. doi: 10.1016/j.peptides.2016.11.006.
Erik Bivehed 1 Robert Strömvall 1 Jonas Bergquist 2 Georgy Bakalkin 1 Malin Andersson 3
Affiliations

Affiliations

  • 1 Department of Pharmaceutical Biosciences, Uppsala University, Uppsala 751 24, Sweden.
  • 2 Department of Chemistry-BMC, Analytical Chemistry and SciLifeLab, Uppsala University, Uppsala 751 24, Sweden.
  • 3 Department of Pharmaceutical Biosciences, Uppsala University, Uppsala 751 24, Sweden. Electronic address: Malin.Andersson@farmbio.uu.se.
Abstract

Brain region-specific expression of proteolytic Enzymes can control the biological activity of endogenous neuropeptides and has recently been targeted for the development of novel drugs, for neuropathic pain, Cancer, and Parkinson's disease. Rapid and sensitive analytical methods to profile modulators of enzymatic activity are important for finding effective inhibitors with high therapeutic value. Combination of in situ enzyme Histochemistry with MALDI imaging mass spectrometry allowed developing a highly sensitive method for analysis of brain-area specific neuropeptide conversion of synthetic and endogenous neuropeptides, and for selection of peptidase inhibitors that differentially target conversion Enzymes at specific anatomical sites. Conversion and degradation products of Dynorphin B as model neuropeptide and effects of peptidase inhibitors applied to native brain tissue sections were analyzed at different brain locations. Synthetic dynorphin B (2pmol) was found to be converted to the N-terminal fragments on brain sections whereas fewer C-terminal fragments were detected. N-ethylmaleimide (NEM), a non-selective inhibitor of cysteine peptidases, almost completely blocked the conversion of dynorphin B to dynorphin B(1-6; Leu-Enk-Arg), (1-9), (2-13), and (7-13). Proteinase inhibitor cocktail, and also incubation with acetic acid displayed similar results. Bioconversion of synthetic dynorphin B was region-specific producing dynorphin B(1-7) in the cortex and dynorphin B (2-13) in the striatum. Enzyme inhibitors showed region- and enzyme-specific inhibition of dynorphin bioconversion. Both phosphoramidon (inhibitor of the known dynorphin converting enzyme Neprilysin) and opiorphin (inhibitor of Neprilysin and Aminopeptidase N) blocked cortical bioconversion to dynorphin B(1-7), wheras only opiorphin blocked striatal bioconversion to dynorphin B(2-13). This method may impact the development of novel therapies with aim to strengthen the effects of endogenous neuropeptides under pathological conditions such as chronic pain. Combining Histochemistry and MALDI imaging MS is a powerful and sensitive tool for the study of inhibition of Enzyme activity directly in native tissue sections.

Keywords

Bioconversion; Dynorphin; Enzyme; Enzyme inhibitor; Histochemistry; MALDI imaging mass spectrometry; Mass spectrometry; Neuropathic pain; Neuropeptide; Parkinson’s disease.

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