Bakteriální RTX proteiny a jejich vazebná místa pro vápník. / Bacterial RTX toxins and their calcium-binding sites

Lišková, Petra

January 2018

FrpC protein produced by Neisseria meningitidis in a human host belongs to the family of bacterial RTX toxins due to the presence of RTX domain. FrpC possesses a calcium-dependent auto-catalytic cleavage activity which is localized within its 177 amino-acids long segment Self-Processing Module (SPM). As the SPM is naturally intrinsically disordered protein without bound Ca2+, the calcium binding is crucial for SPM folding which is followed by the auto-catalytic processing. The elucidation of the SPM structure may be the key step for understanding of enzymatic and biological function. The structure of folded SPM itself can be characterized only with difficulties due to the presence of flexible loop according to preliminary NMR data. The subject of this work is the description of SPM using fluorescence methods, characterization of ions binding to SPM and structural changes occurring during Ca2+ binding. In this work, the ion binding properties of SPM segment and its ion-induced folding was characterized. It was found that the dissociation constant kD of 17 μM coincided with the folding of SPM into the native calcium-bound state which occurs in the concentration range between 1 and 20 μM Ca2+. In the attempt to characterize the structure of ion binding site, the fully active single tryptophan mutants...

Fluorescence Detectors for Proteins and Toxic Heavy Metals

Paul, Uchenna Prince

21 April 2004

An inexpensive detector for proteins is described. The detection technique was based on two-photon excitation intrinsic protein fluorescence using a visible 532 nm diode-pumped nano laser as the excitation source. Proteins that exhibit intrinsic fluorescence must contain at least one tryptophan, tyrosine, or phenylalanine residue in their amino acid sequences. The detector was characterized and was found to have a detection limit of 4 micro-molar for tryptophan, 22 micro-molar for tyrosine and 500 micro-molar for phenylalanine. Bovine serum albumin, a serum protein with 3 tryptophan residues in its amino acid sequence was also used to characterize the detector. It was found that the detection limit for this protein was 0.9 micro-molar. The detector volume was determined based on a photon counting histogram - a technique in fluorescence fluctuation spectroscopy. From the results of this analysis, the excitation volume was found to be 2.9 fL. With such an excitation volume, the detection limits were either within or below the atto-mole range.

protein detection

intrinsic protein fluorescence

tryptophan fluorescence

tyrosine fluorescence

excitation volume

chemosensors

cadmium detection

Biochemistry

Chemistry

Betaine analogues and related compounds for biomedical applications

Vasudevamurthy, Madhusudan

January 2006

Living cells accumulate compensatory solutes for protection against the harmful effects of extreme environmental conditions such as high salinity, temperature and desiccation. Even at high concentrations these solutes do not disrupt the normal cellular functions and at times counteract by stabilizing the cellular components. These properties of compensatory solutes have been exploited for stabilizing proteins and cells in vitro. Betaines are widespread natural compensatory solutes that have also been used in other applications such as therapeutic agents and polymerase chain reaction (PCR) enhancers. Some biomedical applications of novel synthetic analogues of natural betaines were investigated. Natural compensatory solutes are either dipolar zwitterionic compounds or polyhydroxyl compounds, and the physical basis of compensation may differ between these, so one focus was on synthetic betaines with hydroxyl substituents. The majority of the synthetic solutes stabilized different model proteins against stress factors such as high and low temperatures. The presence of hydroxyl groups improved protection against desiccation. The observed stabilization effect is not just on the catalytic activity of the enzyme, but also on its structural conformation. Synthetic compensatory solutes have a potential application as protein stabilizers. Dimethylthetin was evaluated as a therapeutic agent and found to be harmful in a sheep model. However, from the study we were able to generate a large-animal continuous ambulatory peritoneal dialysis (CAPD) model and showed that glycine betaine could be added to the dialysis fluid in chronic renal failure. Some synthetic compensatory solutes reduce the melting temperatures of DNA better than most natural solutes. Synthetic solutes were identified that have potential to enhance PCR and could replace some reagents marketed by commercial suppliers. Density, viscosity and molecular model data on the solutes showed correlations with the biochemical effects of the solutes, but no physical measurements were found that reliably predicted their potential for biotechnological applications.

Betaine analogues

synthetic compensatory solutes

compatible solutes

protein stabilization

enzyme stabilization

heat denaturation

freeze-thawing

freeze-drying

protein fluorescence

protein conformation

dimethylthetin

peritoneal dialysis

sheep model

renal failure

homocysteine

DNA melting temperature

PCR enhancers

fragile X PCR

apparent hydration number

dipole mement

polarizability

mulliken charges

biotechnological applications