Genetically encoded calcium indicator with NTnC-like design and enhanced fluorescence contrast and kinetics.

BACKGROUND: The recently developed genetically encoded calcium indicator (GECI), called NTnC, has a novel design with reduced size due to utilization of the troponin C (TnC) as a Ca2+-binding moiety inserted into the mNeonGreen fluorescent protein. NTnC binds two times less Ca2+ ions while maintaining a higher fluorescence brightness at the basal level of Ca2+ in neurons as compared with the calmodulin-based GECIs, such as GCaMPs. In spite of NTnC's high brightness, pH-stability, and high sensitivity to single action potentials, it has a limited fluorescence contrast (F-Ca2+/F+Ca2+) and slow Ca2+ dissociation kinetics. RESULTS: Herein, we developed a new NTnC-like GECI with enhanced fluorescence contrast and kinetics by replacing the mNeonGreen fluorescent subunit of the NTnC indicator with EYFP. Similar to NTnC, the developed indicator, named iYTnC2, has an inverted fluorescence response to Ca2+ (i.e. becoming dimmer with an increase of Ca2+ concentration). In the presence of Mg2+ ions, iYTnC2 demonstrated a 2.8-fold improved fluorescence contrast in vitro as compared with NTnC. The iYTnC2 indicator has lower brightness and pH-stability, but similar photostability as compared with NTnC in vitro. Stopped-flow fluorimetry studies revealed that iYTnC2 has 5-fold faster Ca2+ dissociation kinetics than NTnC. When compared with GCaMP6f GECI, iYTnC2 has up to 5.6-fold faster Ca2+ association kinetics and 1.7-fold slower dissociation kinetics. During calcium transients in cultured mammalian cells, iYTnC2 demonstrated a 2.7-fold higher fluorescence contrast as compared with that for the NTnC. iYTnC2 demonstrated a 4-fold larger response to Ca2+ transients in neuronal cultures than responses of NTnC. iYTnC2 response in neurons was additionally characterized using whole-cell patch clamp. Finally, we demonstrated that iYTnC2 can visualize neuronal activity in vivo in the hippocampus of freely moving mice using a nVista miniscope. CONCLUSIONS: We demonstrate that expanding the family of NTnC-like calcium indicators is a promising strategy for the development of the next generation of GECIs with smaller molecule size and lower Ca2+ ions buffering capacity as compared with commonly used GECIs.

Histone H3K4me3 binding is required for the DNA repair and apoptotic activities of ING1 tumor suppressor.

Inhibitor of growth 1 (ING1) is implicated in oncogenesis, DNA damage repair, and apoptosis. Mutations within the ING1 gene and altered expression levels of ING1 are found in multiple human cancers. Here, we show that both DNA repair and apoptotic activities of ING1 require the interaction of the C-terminal plant homeodomain (PHD) finger with histone H3 trimethylated at Lys4 (H3K4me3). The ING1 PHD finger recognizes methylated H3K4 but not other histone modifications as revealed by the peptide microarrays. The molecular mechanism of the histone recognition is elucidated based on a 2.1 A-resolution crystal structure of the PHD-H3K4me3 complex. The K4me3 occupies a deep hydrophobic pocket formed by the conserved Y212 and W235 residues that make cation-pi contacts with the trimethylammonium group. Both aromatic residues are essential in the H3K4me3 recognition, as substitution of these residues with Ala disrupts the interaction. Unlike the wild-type ING1, the W235A mutant, overexpressed in the stable clones of melanoma cells or in HT1080 cells, was unable to stimulate DNA repair after UV irradiation or promote DNA-damage-induced apoptosis, indicating that H3K4me3 binding is necessary for these biological functions of ING1. Furthermore, N216S, V218I, and G221V mutations, found in human malignancies, impair the ability of ING1 to associate with H3K4me3 or to induce nucleotide repair and cell death, linking the tumorigenic activity of ING1 with epigenetic regulation. Together, our findings reveal the critical role of the H3K4me3 interaction in mediating cellular responses to genotoxic stresses and offer new insight into the molecular mechanism underlying the tumor suppressive activity of ING1.

[Probing of contacts between EcoRII DNA methyltransferase and DNA using substrate analogs and molecular modeling].

To determine the molecular mechanism of DNA recognition and catalysis by EcoRII DNA-methyltransferase (M.EcoRII) binding and methylation by the enzyme of 14-mer substrate analogs containing 2-aminopurine or 1',2'-dideoxy-D-ribofuranose in the M.EcoRII recognition site have been studied. Efficiencies of methylation and DNA binding affinities depend on the location of modified nucleoside residues within the M.EcoRII recognition site. A structural model of M.EcoRII in complex with substrate DNA and cofactor analog S-adenosyl-L-homocysteine (AdoHcy) was built using the previously solved structures of Hhal and HaeIII DNA-methyltransferases as templates. The model was constructed according to the recently developed "Frankenstein's monster" approach. Based on the model, amino acid residues taking part in interactions with DNA were predicted. Besides, based on both theoretical and experimental data obtained the groups of atoms of the heterocyclic bases within the M.EcoRII recognition site presumably involved in interaction with the enzyme were proposed.