Anna Bierczynska-Krzysik

Rat brain proteome in morphine dependence

The aim of this study was to reveal potential markers associated with drug dependence, using the proteomic approach. Gels containing samples derived from morphine-treated and control animals were compared and analyzed. Inspection of protein profiles, following TCA/acetone precipitation and the use of nano-scale liquid chromatography coupled to tandem mass spectrometry, allowed for identification of eleven potential dependence markers, mainly cytoplasmic and mitochondrial enzymes, e.g. proteins that belong to GTPase and GST superfamilies, ATPase, asparaginase or proteasome subunit p27 families.

The Proteomic Analysis of Primary Cortical Astrocyte Cell Culture after Morphine Administration

Astrocytes are supportive cells, necessary for ensure optimal environment for neural cells functioning. They are involved in extracellular K+ level regulation and neurotransmitters removal. They are also dependent for myelination and synapses formation. They may make a contribution in signal propagation in the central nervous system, for example, through Ca2+ signaling. With the use of neonatal pure astrocyte cell culture, we investigated changes in astrocytes proteomes under the influence of morphine. We found 10 major proteins, which show different expression between physiological cell culture and morphine treatment. With 2D gel electrophoresis and nanoLC-ESI-MS/MS, we identified proteins and characterized their potential role in morphine dependence. Observed differences were also confirmed by Western blotting. Our data suggests a role for astrocytes in the formation of the morphine dependence at the molecular level. This finding may support interpretation of causes of morphine dependence formation based only on behavioral data.

Mass spectrometrical identification of brain proteins including highly insoluble and transmembrane proteins.

Conventional two-dimensional electrophoresis (2DE) is the main technique used for protein profiling of tissues and cells, however separation of strongly acidic, basic or highly insoluble proteins is still limited. A series of methods have been proposed to cope with this problem and the use of discontinuous gel electrophoresis in an acidic buffer system using the cationic detergent benzyldimethyl-n-hexadecylammonium chloride (16-BAC) with subsequent SDS-PAGE followed by mass spectrometry showed that results from 2DE can be complemented by this approach. It was the aim of this study to separate and identify proteins from whole mouse brain that were not demonstrated by 2DE. For this purpose samples were homogenised, soluble proteins were removed by ultracentrifugation and the water-insoluble pellet was resuspended in a mixture containing urea, 16-BAC, glycerol, pyronine Y and dithiothreitol. Electrophoresis was run in the presence of 16-BAC, the strip from the gel containing separated proteins was cut out and was re-run on SDS-PAGE. Protein spots were analyzed by MALDI-TOF-TOF mass spectrometry. One hundred and six individual proteins represented by 187 spots were unambiguously identified consisting of 42 proteins with predicted pI values of pI>8.0, 25 with a 6.0<pI<8.0 and 39 with a pI<6.0. Twelve proteins with transmembrane domains (ranging from 1 to 8) including channels and carriers were identified. The generated map revealed a series of important brain proteins that were not separated and identified previously. Therefore, this system may be relevant for protein chemical determination of channels and carriers independent of antibody availability and specificity. The fact that transmembrane, basic, acidic as well as hydrophobic proteins with a positive Gravy Index can be resolved warrants work on further improvement of this analytical tool.

Proteomic analysis of striatal neuronal cell cultures after morphine administration

Using primary neuronal cell culture assays, combined with 2-D gel electrophoresis and capillary LC-MS, we identified differences in proteomes between control and morphine-treated cells. Statistically significant differences were observed among 26 proteins. Nineteen of them were up-regulated, while seven were down-regulated in morphine-treated cell populations. The identified proteins belong to classes involved in energy metabolism, associated with oxidative stress, linked with protein biosynthesis, cytoskeletal ones, and chaperones. The detected proteins demand further detailed studies of their biological roles in morphine addiction. It is crucial to confirm observed processes in vivo in order to reveal the nature and importance of the biological effect of proteome changes after morphine administration. Further investigations may lead to the discovery of new proteome-based effects of morphine on living organisms.

Morphinome – proteome of the nervous system after morphine treatment

Summary.Proteome is a natural consequence of the post-genome era when the HUGO project (Human Genome Organization) has almost been completed. Here, a specifically aimed proteome in drug dependence – morphinome, is described, including tasks, strategies and pitfalls of the methodology.

Identification of bikunin as an endogenous inhibitor of dynorphin convertase in human cerebrospinal fluid

Dynorphin‐converting enzymes constitute a group of peptidases capable of converting dynorphins to enkephalins. Through the action of these enzymes, the dynorphin‐related peptides bind to δ‐opioid instead of κ‐opioid receptors, leading to a change in the biological function of the neuropeptides. In this article, we describe the identification of the protein bikunin as an endogenous, competitive inhibitor of a dynorphin‐converting enzyme in human cerebrospinal fluid. This protein is present together with its target enzyme in the same body fluids. The KM value of the convertase was found to be 9 µm, and the Ki value of the inhibitor was 1.7 nm. The finding indicates that bikunin may play a significant role as a regulatory mechanism of neuropeptides, where one bioactive peptide is converted to a shorter sequence, which in turn, can affect the action of its longer form.