Optical control of the antigen translocation by synthetic photo-conditional viral inhibitors.

The immune system makes use of major histocompatibility complex class I (MHC I) molecules to present peptides to other immune cells, which can evoke an immune response. Within this process of antigen presentation, the MHC I peptide loading complex, consisting of a transporter associated with antigen processing TAP, MHC I, and chaperones, is key to the initiation of immune response by shuttling peptides from the cytosol into the ER lumen. However, it is still enigmatic how the flux of antigens is precisely coordinated in time and space, limiting our understanding of antigen presentation pathways. Here, we report on the development of a synthetic viral TAP inhibitor that can be cleaved by light. This photo-conditional inhibitor shows temporal blockade of TAP-mediated antigen translocation, which is unleashed upon illumination. The recovery of TAP activity was monitored at single-cell resolution both in human immune cell lines and primary cells. The development of a photo-conditional TAP inhibitor thus expands the repertoire of chemical intervention tools for immunological processes.

Nanomolar affinity protein trans-splicing monitored in real-time by fluorophore-quencher pairs.

High background originating from non-reacted, 'always-on' fluorescent probes remains a key unsolved problem in life science since washing procedures are not easily applicable. Covalent labeling approaches with simultaneous activation of fluorescence are advantageous to increase sensitivity and to reduce background signal. Here, we combined high-affinity protein trans-splicing with fluorophore/quencher pairs for online detection of covalent N-terminal 'traceless' protein labeling under physiological conditions in cellular environments. Substantial fluorescence enhancement at nanomolar probe concentrations was achieved.

'Traceless' tracing of proteins - high-affinity trans-splicing directed by a minimal interaction pair.

Protein trans-splicing mediated by split inteins is a powerful technique for site-specific protein modification. Despite recent developments there is still an urgent need for ultra-small high-affinity intein tags for in vitro and in vivo approaches. To date, only very few in-cell applications of protein trans-splicing have been reported, all limited to C-terminal protein modifications. Here, we developed a strategy for covalent N-terminal intein-mediated protein labeling at (sub) nanomolar probe concentrations. Combined with a minimal synthetic lock-and-key element, the affinity between the intein fragments was increased more than 50-fold to 10 nM. Site-specific and efficient 'traceless' protein modification by high-affinity trans-splicing is demonstrated at nanomolar concentrations in living mammalian cells.

Linking child maltreatment retrospectively to birth and home visit records: an initial examination.

The study reported here tested the feasibility of linking administrative datasets for evaluation of home visiting as a strategy to reduce the incidence of child abuse and neglect. It also examined associations between maternal and child attributes coded in the birth record, and subsequent child maltreatment. The results show that home visiting efforts in Vermont were, in general, targeted to the populations most at-risk for child maltreatment. Mother's educational attainment, in particular, was identified as a potent correlate of child maltreatment, a finding with implications for high school dropout prevention and recovery efforts.