Most cited article - PubMed ID 12009445
Differential pulse adsorptive stripping voltammetry of osmium-modified peptides
This year we celebrate seventy years since the establishment of the Institute of Biophysics of the Czechoslovak Academy of Sciences (IBP) (founded on January 1, 1955). If we look into the biography of Professor Emil Paleček (born on October 3, 1930), one of the most world-recognized personalities associated with the Institute and one of the most cited Czech scientists, known as the founder of nucleic acids electrochemistry, we are drawn to the same year, i.e. 1955, as the year in which Emil Paleček finished his studies in biochemistry and joined the IBP, where he worked with admirable vitality, enthusiasm and dedication until his death (October 30, 2018). In the context of celebration of founding of the Institute, we would like to commemorate in this article a personality who significantly influenced the history of the Institute alongside the important discoveries and research directions that defined his extremely successful career. We prefer this form, which is a sort of a mini-review of the most important results of the laboratory obtained under EP's leadership over 63 years, presented in mutual context and natural relations. For his life's work, Professor Paleček received many prestigious awards, with the Czech Head Award in 2014 and the Neuron Foundation Award in 2017 being the most distinguished.
- Keywords
- Electrochemistry, Glycans, Modification, Nucleic acids, Proteins, Structure,
- Publication type
- Journal Article MeSH
- Review MeSH
Electrochemical methods can be used not only for the sensitive analysis of proteins but also for deeper research into their structure, transport functions (transfer of electrons and protons), and sensing their interactions with soft and solid surfaces. Last but not least, electrochemical tools are useful for investigating the effect of an electric field on protein structure, the direct application of electrochemical methods for controlling protein function, or the micromanipulation of supramolecular protein structures. There are many experimental arrangements (modalities), from the classic configuration that works with an electrochemical cell to miniaturized electrochemical sensors and microchip platforms. The support of computational chemistry methods which appropriately complement the interpretation framework of experimental results is also important. This text describes recent directions in electrochemical methods for the determination of proteins and briefly summarizes available methodologies for the selective labeling of proteins using redox-active probes. Attention is also paid to the theoretical aspects of electron transport and the effect of an external electric field on the structure of selected proteins. Instead of providing a comprehensive overview, we aim to highlight areas of interest that have not been summarized recently, but, at the same time, represent current trends in the field.
- Keywords
- Electrode, Microdevice, Peptide, Protein, Sensor,
- MeSH
- Electrochemical Techniques * methods MeSH
- Electrochemistry MeSH
- Oxidation-Reduction MeSH
- Proteins * MeSH
- Electron Transport MeSH
- Publication type
- Journal Article MeSH
- Research Support, Non-U.S. Gov't MeSH
- Review MeSH
- Names of Substances
- Proteins * MeSH
- MeSH
- Biosensing Techniques instrumentation methods MeSH
- Electrochemical Techniques instrumentation methods MeSH
- Glycomics instrumentation methods MeSH
- Glycoproteins analysis metabolism MeSH
- Humans MeSH
- Models, Molecular MeSH
- Molecular Sequence Data MeSH
- Proteins analysis metabolism MeSH
- Carbohydrate Sequence MeSH
- Amino Acid Sequence MeSH
- Animals MeSH
- Check Tag
- Humans MeSH
- Animals MeSH
- Publication type
- Journal Article MeSH
- Research Support, Non-U.S. Gov't MeSH
- Review MeSH
- Names of Substances
- Glycoproteins MeSH
- Proteins MeSH
Lactoferrin is a multifunctional protein with antimicrobial activity and others tohealth beneficial properties. The main aim of this work was to propose easy to usetechnique for lactoferrin isolation from cow colostrum samples. Primarily we utilizedsodium dodecyl sulphate - polyacrylamide gel electrophoresis for isolation of lactoferrinfrom the real samples. Moreover we tested automated microfluidic Experionelectrophoresis system to isolate lactoferrin from the collostrum sample. The welldeveloped signal of lactoferrin was determined with detection limit (3 S/N) of 20 ng/ml. Inspite of the fact that Experion is faster than SDS-PAGE both separation techniques cannotbe used in routine analysis. Therefore we have tested third separation technique, ionexchange chromatography, using monolithic column coupled with UV-VIS detector (LCUV-VIS). We optimized wave length (280 nm), ionic strength of the elution solution (1.5M NaCl) and flow rate of the retention and elution solutions (0.25 ml/min and 0.75 ml/min.respectively). Under the optimal conditions the detection limit was estimated as 0.1 μg/mlof lactoferrin measured. Using LC-UV-VIS we determined that lactoferrin concentrationvaried from 0.5 g/l to 1.1 g/l in cow colostrums collected in the certain time interval up to 72 hours after birth. Further we focused on miniaturization of detection device. We testedamperometric detection at carbon electrode. The results encouraged us to attempt tominiaturise whole detection system and to test it on analysis of real samples of humanfaeces, because lactoferrin level in faeces is closely associated with the inflammations ofintestine mucous membrane. For the purpose of miniaturization we employed thetechnology of printed electrodes. The detection limit of lactoferrin was estimated as 10μg/ml measured by the screen-printed electrodes fabricated by us. The fabricatedelectrodes were compared with commercially available ones. It follows from the obtainedresults that the responses measured by commercial electrodes are app. ten times highercompared with those measured by the electrodes fabricated by us. This phenomenonrelates with smaller working electrode surface area of the electrodes fabricated by us(about 50 %) compared to the commercial ones. The screen-printed electrodes fabricatedby us were utilized for determination of lactoferrin faeces. Regarding to fact that sample offaeces was obtained from young and healthy man the amount of lactoferrin in sample wasunder the limit of detection of this method.
