Per Thyberg

Amyloid β-peptide polymerization studied using fluorescence correlation spectroscopy

Background The accumulation of fibrillar deposits of amyloid β-peptide (Aβ) in brain parenchyma and cerebromeningeal blood vessels is a key step in the pathogenesis of Alzheimers disease. In this report, polymerization of Aβ was studied using fluorescence correlation spectroscopy (FCS), a technique capable of detecting small molecules and large aggregates simultaneously in solution. Results The polymerization of Aβ dissolved in Tris-buffered saline, pH 7.4, occurred above a critical concentration of 50 μM and proceeded from monomers/dimers into two discrete populations of large aggregates, without any detectable amount of oligomers. The aggregation showed very high cooperativity and reached a maximum after 40 min, followed by an increase in the amount of monomers/dimers and a decrease in the size of the large aggregates. Electron micrographs of samples prepared at the time for maximum aggregation showed a mixture of an amorphous network and short diffuse fibrils, whereas only mature amyloid fibrils were detected after one day of incubation. The aggregation was reduced when Aβ was incubated in the presence of Aβ ligands, oligopeptides previously shown to inhibit fibril formation, and aggregates were partly dissociated after the addition of the ligands. Conclusions The polymerization of Aβ is a highly cooperative process in which the formation of very large aggregates precedes the formation of fibrils. The entire process can be inhibited and, at least in early stages, partly reversed by Aβ ligands.

Molecular interactions of peptides with phospholipid vesicle membranes as studied by fluorescence correlation spectroscopy.

Interactions of the peptides melittin and magainin with phospholipid vesicle membranes have been studied using fluorescence correlation spectroscopy. Molecular interactions of melittin and magainin with phospholipid membranes are performed in rhodamine-entrapped vesicles (REV) and in rhodamine-labelled phospholipid vesicles (RLV), which did not entrap free rhodamine inside. The results demonstrate that melittin makes channels into vesicle membranes since exposure of melittin to vesicles causes rhodamine release only from REV but not from RLV. It is obvious that rhodamine can not be released from RLV because the inside of RLV is free of dye molecules. In contrast, magainin breaks vesicles since addition of magainin to vesicles results in rhodamine release from both REV and RLV. As the inside of RLV is free of rhodamine, the appearance of rhodamine in solution confirms that these vesicles are broken into rhodamine-labelled phospholipid fragments after addition of magainin. This study is of pharmaceutical significance since it will provide insights that fluorescence correlation spectroscopy can be used as a rapid protocol to test incorporation and release of drugs by vesicles.

INVERSE-FLUORESCENCE CORRELATION SPECTROSCOPY

An alternative version of fluorescence correlation spectroscopy is presented, where the signal from a medium surrounding the particles of interest is analyzed, as opposed to a signal from the particles themselves. This allows for analysis of unlabeled particles and potentially of biomolecules. Here, the concept together with principal experiments on polystyrene beads of 100, 200, 400, and 800 nm diameter in an aqueous solution of alexa 488-fluorophores are presented. The use of photo detectors allowing higher photon fluxes, or of reduced detection volumes, should enable analysis of significantly smaller particles or even biomolecules.

Modeling the Dynamics of Nonenzymatic and Enzymatic Nucleotide Processes by Fractal Dimension

We introduce here D as a fractal dimension according to Mandelbrot [5] for multicyclic nucleotide processes producing variabilities, where M (l,N) is the probability density of truncated, deleted and point-mutated sequence variabilities (l) as net term of the deterministic processes in the two-dimensional embedding space. The very generality of this result holds for all fractal sets of cumulative sequence variabilities. The minimal requirements sufficient to produce, or to degrade, a target DNA sequence N are multistep additions, recombinations or degradations of some monomeric or oligomeric building blocks with the propagation probability function d = d i at cycle i. Our fractal dimension D can be obtained from the scaling with respect to the largest nucleotide lengths of interest, N.

EXONUCLEASE DEGRADATION OF DNA STUDIED BY FLUORESCENCE CORRELATION SPECTROSCOPY

Abstract Here we developed an accurate method for kinetic analysis of enzymatic degradation processes of double and/or single-stranded DNA/oligonucleotides using fluorescent reporter dyes. 217-bp DNA fragments were produced by polymerase chain reaction and cleaved by the 3′ to 5′ exonuclease activity of T7-DNA polymerase. The analysis of the products was performed by Fluorescence Correlation Spectroscopy measuring autocorrelation amplitudes and diffusion times. We give proof of (i) complete enzymatic degradation, (ii) retardation of complete enzymatic degradation by internally labelled Rhodamine-4-nucleotides and Cy5-nucleotides, respectively. Data evaluation by global analysis indicated first-order reaction kinetics with full-length DNA and free fluorescent nucleotides in the time window of measurements used.

Parallel dual-color fluorescence cross-correlation spectroscopy using diffractive optical elements

Dual-color cross-correlation spectroscopy allows the detection and quantification of labeled biomolecules at ultra-low concentrations, whereby the sensitivity of the assay correlates with the measurement time. We now describe a parallel multifocal dual-color spectroscopic configuration employing multiple avalanche photodiodes and hardware correlators. Cross-correlation curves are obtained from several dual-color excitation foci simultaneously. Multifocal dual-color excitation is achieved by splitting each of two laser beams (488 and 633 nm) into four sub-beams with the help of two 2x2 fan-out diffractive optical elements (DOEs), and subsequent superposition of the two sets of four foci. The fluorescence emission from double-labeled biomolecules is detected by two 2x2 fiber arrays.

FCS cell surface measurements—Photophysical limitations and consequences on molecular ensembles with heterogenic mobilities

Fluorescence Correlation Spectroscopy is a powerful method to analyze densities and diffusive behavior of molecules in membranes, but effects of photodegradation can easily be overlooked.

C677T Single Nucleotide Polymorphisms of the Human Methylene Tetrahydrofolate Reductase and Specific Identification

AbstractBackground: A methylene tetrahydrofolate reductase (MTHFR) deficiency at site C677T renders the enzyme thermolabile and consequently represents a risk factor for vascular disease, neural tube defects, preeclampsia, and thrombosis. Highly specific identification techniques for genotyping are mandatory to give guidance for the diagnosis and monitoring of this deficiency. Methods: A new approach for performing genotyping has been introduced with the identification of single nucleotide polymorphisms of the human MTHFR. It is based on PCR followed by two-color cross-correlation fluorescence spectroscopy (FCS). Experiments were carried out with green- and red-tagged allele-specific primers, which were fully compatible with the two-color fluorescence cross-correlation setup at 488nm and 633nm excitation wavelengths. Results: The measured data of the amplification mixes (tubes) were normalized as the maximum correlation amplitude of each tube. Correlated and uncorrelated data were optically separated in the amplification mixes by their characteristic correlation times, which significantly differed from each other. The correlated data were generated in the presence of the proper mutated genotype template, whereas uncorrelated data were due to the absence of the proper genotype template. Furthermore, the specific association of the two-color fluorescence correlated signals with the target DNA was experimentally proven. Using this novel two-color cross-correlation approach, the MTHFR genotypes, which were determined in 21 clinical samples, showed concordance with methods involving a PCR-based assay with hexachloro-6-carboxy-fluorescein (HEX)- and 6-carboxy-fluorescein (FAM)-tagged allele-specific primers and a subsequent separation step with capillary electrophoresis, yet are simpler to perform. There was no evidence of a central trend of false-positive or false-negative results. We demonstrated how the novel, ultrasensitive typing system could be applied to studies where researchers are trying to perfect their assays and are often working with the unknown, or application to problematic assays in a clinical environment for those involved in molecular diagnosis. Conclusions: We present an alternative method to those commonly used in genotyping. Two-color cross-correlation FCS allows the detection of the fluorescence signals specifically associated with the heterozygous mutated, the homozygous mutated, and normal individuals, as exemplified in this study. The presence of nonspecific amplification products, which interfere with subsequent DNA analysis, could therefore highlight the need for two-color cross-correlation FCS as a means of discriminating between specific association of the fluorescence signals with the target DNA and DNA not related to the target.

C677T single nucleotide polymorphisms of the human methylene tetrahydrofolate reductase and specific identification : a novel strategy using two-color cross-correlation fluorescence spectroscopy.

thermolabile and consequently represents a risk factor for vascular disease, neural tube defects, preeclampsia, and thrombosis. Highly specific identification techniques for genotyping are mandatory to give guidance for the diagnosis and monitoring of this deficiency. Methods: A new approach for performing genotyping has been introduced with the identification of single nucleotide polymorphisms of the human MTHFR. It is based on PCR followed by two-color cross-correlation fluorescence spectroscopy (FCS). Experiments were carried out with green- and red-tagged allele-specific primers, which were fully compatible with the two-color fluorescence cross-correlation setup at 488nm and 633nm excitation wavelengths. Results: The measured data of the amplification mixes (tubes) were normalized as the maximum correlation amplitude of each tube. Correlated and uncorrelated data were optically separated in the amplification mixes by their characteristic correlation times, which significantly differed from each other. The correlated data were generated in the presence of the proper mutated genotype template, whereas uncorrelated data were due to the absence of the proper genotype template. Furthermore, the specific association of the two-color fluorescence correlated signals with the target DNA was experimentally proven. Using this novel two-color cross-correlation approach, the MTHFR genotypes, which were determined in 21 clinical samples, showed concordance with methods involving a PCR-based assay with hexachloro-6-carboxy-fluorescein (HEX)- and 6-carboxy-fluorescein (FAM)-tagged allele-specific primers and a subsequent separation step with capillary electrophoresis, yet are simpler to perform. There was no evidence of a central trend of false-positive or false-negative results. We demonstrated how the novel, ultrasensitive typing system could be applied to studies where researchers are trying to perfect their assays and are often working with the unknown, or application to problematic assays in a clinical environment for those involved in molecular diagnosis. Conclusions: We present an alternative method to those commonly used in genotyping. Two-color crosscorrelation FCS allows the detection of the fluorescence signals specifically associated with the heterozygous

Modulation Filtering Enables Removal of Spikes in Fluorescence Correlation Spectroscopy Measurements without Affecting the Temporal Information

The appearance of intensity spikes in measurements is a common problem in fluorescence correlation spectroscopy (FCS) studies of biological samples. In this work, we present a new method for generating artifact-free correlation curves from fluorescence traces that have undergone spike removal. This method preserves the temporal information throughout the measurement and properly represents the correlation between events separated by removed spikes. The method was validated using experimental data. The proposed algorithm is demonstrated herein to be generally applicable, but it is particularly powerful for cases where spikes occur frequently.