Distance measurements in the F0F1-ATP synthase from E. coli using smFRET and PELDOR spectroscopy.

Fluorescence resonance energy transfer in single enzyme molecules (smFRET, single-molecule measurement) allows the measurement of multicomponent distance distributions in complex biomolecules similar to pulsed electron-electron double resonance (PELDOR, ensemble measurement). Both methods use reporter groups: FRET exploits the distance dependence of the electric interaction between electronic transition dipole moments of the attached fluorophores, whereas PELDOR spectroscopy uses the distance dependence of the interaction between the magnetic dipole moments of attached spin labels. Such labels can be incorporated easily to cysteine residues in the protein. Comparison of distance distributions obtained with both methods was carried out with the H+-ATPase from Escherichia coli (EF0F1). The crystal structure of this enzyme is known. It contains endogenous cysteines, and as an internal reference two additional cysteines were introduced (EF0F1-γT106C-εH56C). These positions were chosen to allow application of both methods under optimal conditions. Both methods yield very similar multicomponent distance distributions. The dominating distance distribution (> 50%) is due to the two cysteines introduced by site-directed mutagenesis and the distance is in agreement with the crystal structure. Two additional distance distributions are detected with smFRET and with PELDOR. These can be assigned by comparison with the structure to labels at endogenous cysteines. One additional distribution is detected only with PELDOR. The comparison indicates that under optimal conditions smFRET and PELDOR result in the same distance distributions. PELDOR has the advantage that different distributions can be obtained with ensemble measurements, whereas FRET requires single-molecule techniques.

Single-particle EM reveals plasticity of interactions between the adenovirus penton base and integrin αVß3.

Human adenoviruses are double-stranded DNA viruses responsible for numerous infections, some of which can be fatal. Furthermore, adenoviruses are currently used in clinical trials as vectors for gene therapy applications. Although initial binding of adenoviruses to host attachment receptors has been extensively characterized, the interactions with the entry receptor (integrins) remain poorly understood at the structural level. We characterized the interactions between the adenovirus 9 penton base subunit and αVß3 integrin using fluorescence correlation spectroscopy and single-particle electron microscopy to understand the mechanisms underlying virus internalization and infection. Our results indicate that the penton base subunit can bind integrins with high affinity and in several different orientations. These outcomes correlate with the requirement of the pentameric penton base to simultaneously bind several integrins to enable their clustering and promote virus entry into the host cell.