Easy method to count and size plastic nanoparticles in water. A combination of sensitive fluorescence video microscopy, NileRed staining of plastic particles, and single particle tracking allows for counting and sizing nanoplastics.
The fluorescence quantum yield of four representative red fluorescent proteins mCherry, mKate2, mRuby2, and the recently introduced mScarlet was investigated. The excited state lifetimes were measured as a function of the distance to a gold mirror in order to control the local density of optical states (LDOS). By analyzing the total emission rates as a function of the LDOS, we obtain separately the emission rate and the nonradiative rate of the bright states. We thus obtain for the first time the bright state quantum yield of the proteins without interference from dark, nonemitting states. The bright state quantum yields are considerably higher than previously reported quantum yields that average over both bright and dark states. We determine that mCherry, mKate2, and mRuby2 have a considerable fraction of dark chromophores up to 45%, which explains both the low measured quantum yields of red emitting proteins reported in the literature and the difficulties in developing high quantum yield variants of such proteins. For the recently developed bright mScarlet, we find a much smaller dark fraction of 14%, accompanied by a very high quantum yield of the bright state of 81%. The presence of a considerable fraction of dark chromophores has implications for numerous applications of fluorescent proteins, ranging from quantitative fluorescence microscopy to FRET studies to monitoring protein expression levels. We recommend that future optimization of red fluorescent proteins should pay more attention to minimizing the fraction of dark proteins.
Models
for bacterial adhesion to substratum surfaces all include
uncertainty with respect to the (ir)reversibility of adhesion. In
a model, based on vibrations exhibited by adhering bacteria parallel
to a surface, adhesion was described as a result of reversible binding
of multiple bacterial tethers that detach from and successively reattach
to a surface, eventually making bacterial adhesion irreversible. Here,
we use total internal reflection microscopy to determine whether adhering
bacteria also exhibit variations over time in their perpendicular
distance above surfaces. Streptococci with fibrillar surface tethers
showed perpendicular vibrations with amplitudes of around 5 nm, regardless
of surface hydrophobicity. Adhering, nonfibrillated streptococci vibrated
with amplitudes around 20 nm above a hydrophobic surface. Amplitudes
did not depend on ionic strength for either strain. Calculations of
bacterial energies from their distances above the surfaces using the
Boltzman equation showed that bacteria with fibrillar tethers vibrated
as a harmonic oscillator. The energy of bacteria without fibrillar
tethers varied with distance in a comparable fashion as the DLVO (Derjaguin,
Landau, Verwey, and Overbeek)-interaction energy. Distance variations
above the surface over time of bacteria with fibrillar tethers are
suggested to be governed by the harmonic oscillations, allowed by
elasticity of the tethers, piercing through the potential energy barrier.
Bacteria without fibrillar tethers “float” above a surface
in the secondary energy minimum, with their perpendicular displacement
restricted by their thermal energy and the width of the secondary
minimum. The distinction between “tether-coupled” and
“floating” adhesion is new, and may have implications
for bacterial detachment strategies.
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