11 research outputs found
Two-Photon Fluorescence Spectroscopy and Imaging of 4-Dimethylaminonaphthalimide Peptide and Protein Conjugates
We report detailed photophysical studies on the two-photon fluorescence processes of the solvatochromic fluorophore 4-DMN as a conjugate of the calmodulin (CaM) and the associated CaM-binding peptide M13. Strong two-photon fluorescence enhancement has been observed which is associated with calcium binding. It is found that the two-photon absorption cross-section is strongly dependent on the local environment surrounding the 4-DMN fluorophore in the CaM conjugates, providing sensitivity between sites of fluorophore attachment. Utilizing time-resolved measurements, the emission dynamics of 4-DMN under various environmental (solvent) conditions are analyzed. In addition, anisotropy measurements reveal that the 4-DMN–S38C–CaM system has restricted rotation in the calcium-bound calmodulin. To establish the utility for cellular imaging, two-photon fluorescence microscopy studies were also carried out with the 4-DMN-modified M13 peptide in cells. Together, these studies provide strong evidence that 4-DMN is a useful probe in two-photon imaging, with advantageous properties for cellular experiments.German Science Foundation (SO 1100/1-1
PNA FIT-Probes for the Dual Color Imaging of Two Viral mRNA Targets in Influenza H1N1 Infected Live Cells
Fluorogenic hybridization probes that allow RNA imaging provide
information as to how the synthesis and transport of particular RNA
molecules is orchestrated in living cells. In this study, we explored
the peptide nucleic acid (PNA)-based FIT-probes in the simultaneous
imaging of two different viral mRNA molecules expressed during the
replication cycle of the H1N1 influenza A virus. PNA FIT-probes are
non-nucleotidic, nonstructured probes and contain a single asymmetric
cyanine dye which serves as a fluorescent base surrogate. The fluorochrome
acts as a local intercalator probe and reports hybridization of target
DNA/RNA by enhancement of fluorescence. Though multiplexed hybridization
probes are expected to facilitate the analysis of RNA expression,
there are no previous reports on the dual color imaging of two different
viral mRNA targets. In this work, we developed a set
of two differently colored PNA FIT-probes that allow the spectrally
resolved imaging of mRNA coding for neuraminidase (NA) and matrix
protein 1 (M1); proteins which execute distinct functions during the
replication of the influenza A virus. The probes are characterized
by a wide range of applicable hybridization temperatures. The same
probe sequence enabled live-cell RNA imaging (at 37 °C) as well
as real-time PCR measurements (at 60 °C annealing temperature).
This facilitated a comprehensive analysis of RNA expression by quantitative
(qPCR) and qualitative (imaging) means. Confocal laser scanning microscopy
showed that the viral-RNA specific PNA FIT-probes neither stained
noninfected cells nor cells infected by a control virus. The joint
use of differently colored PNA FIT-probes in this feasibility study
revealed significant differences in the expression pattern of influenza
H1N1 mRNAs coding for NA or M1. These experiments provide evidence
for the usefulness of PNA FIT-probes in investigations on the temporal
and spatial progression of mRNA synthesis in living cells for two
mRNA species
Two-Photon Fluorescence Spectroscopy and Imaging of 4‑Dimethylaminonaphthalimide Peptide and Protein Conjugates
We report detailed photophysical
studies on the two-photon fluorescence
processes of the solvatochromic fluorophore 4-DMN as a conjugate of
the calmodulin (CaM) and the associated CaM-binding peptide M13. Strong
two-photon fluorescence enhancement has been observed which is associated
with calcium binding. It is found that the two-photon absorption cross-section
is strongly dependent on the local environment surrounding the 4-DMN
fluorophore in the CaM conjugates, providing sensitivity between sites
of fluorophore attachment. Utilizing time-resolved measurements, the
emission dynamics of 4-DMN under various environmental (solvent) conditions
are analyzed. In addition, anisotropy measurements reveal that the
4-DMN–S38C–CaM system has restricted rotation in the
calcium-bound calmodulin. To establish the utility for cellular imaging,
two-photon fluorescence microscopy studies were also carried out with
the 4-DMN-modified M13 peptide in cells. Together, these studies provide
strong evidence that 4-DMN is a useful probe in two-photon imaging,
with advantageous properties for cellular experiments
Role of two single nucleotide polymorphisms in secreted frizzled related protein 1 and bladder cancer risk
In this study, we determined the genotype distribution of two single nucleotide polymorphisms (SNPs) in secreted frizzled related protein 1 (SFRP1), rs3242 and rs921142, in a Caucasian bladder cancer case-control study. Allelic variants of the SNPs were determined using restriction fragment length polymorphism (RFLP) analysis and partly verified by sequencing analysis. Overall, DNA from 188 consecutive and 215 early-onset bladder cancer patients (≤45 years) as well as from 332 controls was investigated. Potential microRNA binding sites were determined for rs3242, and microRNA expression was analysed in cell lines and tumour specimens. We observed a remarkable distribution difference in rs3242 between bladder cancer patients and healthy controls (p=0.05). Additionally, we found a significant difference in genotype distribution (p=0.032), resulting from the difference of early-onset patients and the control group (p=0.007). The risk allele T showed increased frequency in the early-onset patient group (p=0.002). Genotype-dependent differences of microRNA binding capacity were predicted in SFRP1 mRNA for two microRNAs. Hsa-miR-3646 showed strong expression in cell lines and tumour tissue, whereas hsa-miR-603 exhibited weak expression. The rs921142 SNP showed no significant association with bladder cancer risk. This is the first study to describe an association of the SFRP1 SNP rs3242 and bladder cancer risk as well as the influence of rs3242 on genotype-dependent microRNA capacity on SFRP1 mRNA. The onset of bladder seems to be associated with the increased occurrence of the T-allele in rs3242
Design Principles for SuCESsFul Biosensors: Specific Fluorophore/Analyte Binding and Minimization of Fluorophore/Scaffold Interactions
Quantifying protein location and concentration is critical for understanding function in situ. Scaffold conjugated to environment-sensitive fluorophore (SuCESsFul) biosensors, in which a reporting fluorophore is conjugated to a binding scaffold, can, in principle, detect analytes of interest with high temporal and spatial resolution. However, their adoption has been limited due to the extensive empirical screening required for their development. We sought to establish design principles for this class of biosensor by characterizing over 400 biosensors based on various protein analytes, binding proteins, and fluorophores. We found that the brightest readouts are attained when a specific binding pocket for the fluorophore is present on the analyte. Also, interaction of the fluorophore with the binding protein it is conjugated to can raise background fluorescence, considerably limiting sensor dynamic range. Exploiting these two concepts, we designed biosensors that attain a 100-fold increase in fluorescence upon binding to analyte, an order of magnitude improvement over the previously best-reported SuCESsFul biosensor. These design principles should facilitate the development of improved SuCESsFul biosensors. Keywords: solvatochromism; Sso7d scaffold; sensors; protein engineering; directed evolutionNational Science Foundation (U.S.) (Grant MCB-115803)National Institutes of Health (U.S.) (Grant U54CA112967)National Cancer Institute (U.S.) (Grant U54CA112967)National Institutes of Health (U.S.) (Grant R01 EB 010246