A positively tuned voltage indicator for extended electrical recordings in the brain.

Genetically encoded voltage indicators (GEVIs) enable optical recording of electrical signals in the brain, providing subthreshold sensitivity and temporal resolution not possible with calcium indicators. However, one- and two-photon voltage imaging over prolonged periods with the same GEVI has not yet been demonstrated. Here, we report engineering of ASAP family GEVIs to enhance photostability by inversion of the fluorescence-voltage relationship. Two of the resulting GEVIs, ASAP4b and ASAP4e, respond to 100-mV depolarizations with ≥180% fluorescence increases, compared with the 50% fluorescence decrease of the parental ASAP3. With standard microscopy equipment, ASAP4e enables single-trial detection of spikes in mice over the course of minutes. Unlike GEVIs previously used for one-photon voltage recordings, ASAP4b and ASAP4e also perform well under two-photon illumination. By imaging voltage and calcium simultaneously, we show that ASAP4b and ASAP4e can identify place cells and detect voltage spikes with better temporal resolution than commonly used calcium indicators. Thus, ASAP4b and ASAP4e extend the capabilities of voltage imaging to standard one- and two-photon microscopes while improving the duration of voltage recordings.

Ultrafast Two-Photon Imaging of a High-Gain Voltage Indicator in Awake Behaving Mice.

Optical interrogation of voltage in deep brain locations with cellular resolution would be immensely useful for understanding how neuronal circuits process information. Here, we report ASAP3, a genetically encoded voltage indicator with 51% fluorescence modulation by physiological voltages, submillisecond activation kinetics, and full responsivity under two-photon excitation. We also introduce an ultrafast local volume excitation (ULoVE) method for kilohertz-rate two-photon sampling in vivo with increased stability and sensitivity. Combining a soma-targeted ASAP3 variant and ULoVE, we show single-trial tracking of spikes and subthreshold events for minutes in deep locations, with subcellular resolution and with repeated sampling over days. In the visual cortex, we use soma-targeted ASAP3 to illustrate cell-type-dependent subthreshold modulation by locomotion. Thus, ASAP3 and ULoVE enable high-speed optical recording of electrical activity in genetically defined neurons at deep locations during awake behavior.

Crystal Structure of FOXC2 in Complex with DNA Target.

Forkhead transcription factor C2 (FOXC2) is a transcription factor regulating vascular and lymphatic development, and its mutations are linked to lymphedema-distichiasis syndrome. FOXC2 is also a crucial regulator of the epithelial-mesenchymal transition processes essential for tumor metastasis. Here, we report the crystal structure of the FOXC2-DNA-binding domain in complex with its cognate DNA. The crystal structure provides the basis of DNA sequence recognition by FOXC2 for the T/CAAAC motif. Helix 3 makes the majority of the DNA-protein interactions and confers the DNA sequence specificity. The computational energy calculation results also validate the structural observations. The FOXC2 and DNA complex structure provides a detailed picture of protein and DNA interactions, which allows us to predict its DNA recognition specificity and impaired functions in mutants identified in human patients.

A Forkhead Box Protein†C2 Inhibitor: Targeting Epithelial-Mesenchymal Transition and Cancer Metastasis.

The epithelial-mesenchymal transition (EMT) has been suggested as a new target for therapeutic intervention of metastatic cancer. Forkhead box protein C2 (FOXC2) is known to be necessary for initiating and maintaining EMT, and therefore bestows on cancer cells metastatic and cancer stem cell (CSC)-like phenotypes, allowing cells to acquire higher motility, invasiveness, self-renewal, and therapy resistance. Here, we describe the first inhibitor of FOXC2, MC-1-F2. MC-1-F2 was able to induce cadherin switching and reverse EMT through the degradation of FOXC2 and blocking of its nuclear localization. In addition, MC-1-F2 was very effective in inhibiting cancer cell migration and invasion. As the first small-molecule inhibitor of FOXC2 and the first compound targeting EMT-associated transcription factor, MC-1-F2 will pave the way for a new anticancer therapeutic agent targeting metastatic cancer and help to elucidate the network of EMT signaling pathways.

Intermolecular Interactions of Cardiac Transcription Factors NKX2.5 and TBX5.

Heart development in mammalian systems is controlled by combinatorial interactions of master cardiac transcription factors such as TBX5 and NKX2.5. They bind to promoters/enhancers of downstream targets as homo- or heteromultimeric complexes. They physically interact and synergistically regulate their target genes. To elucidate the molecular basis of the intermolecular interactions, a heterodimer and a homodimer of NKX2.5 and TBX5 were studied using X-ray crystallography. Here we report a crystal structure of human NKX2.5 and TBX5 DNA binding domains in a complex with a 19 bp target DNA and a crystal structure of TBX5 homodimer. The ternary complex structure of NKX2.5 and TBX5 with the target DNA shows physical interactions between the two proteins through Lys158 (NKX2.5), Asp140 (TBX5), and Pro142 (TBX5), residues that are highly conserved in TBX and NKX families across species. Extensive homodimeric interactions were observed between the TBX5 proteins in both crystal structures. In particular, in the crystal structure of TBX5 protein that includes the N-terminal and DNA binding domains, intermolecular interactions were mediated by the N-terminal domain of the protein. The N-terminal domain of TBX5 was predicted to be "intrinsically unstructured", and in one of the two molecules in an asymmetric unit, the N-terminal domain assumes a ß-strand conformation bridging two ß-sheets from the two molecules. The structures reported here may represent general mechanisms for combinatorial interactions among transcription factors regulating developmental processes.

NuProPlot: nucleic acid and protein interaction analysis and plotting program.

Growing numbers of protein and nucleic acid complex structures are being determined and deposited in the Protein Data Bank and the Nucleic Acid Database. With the increasing complexity of these structures, it is challenging to analyse and visualize the three-dimensional interactions. The currently available programs for such analysis and visualization are limited in their applications. They can only analyse a subset of protein-nucleic acid complexes and require multiple iterations before obtaining plots that are suitable for presentation. An interactive web-based program, NuProPlot (http://www.nuproplot.com), has been developed which can automatically identify hydrogen, electrostatic and van der Waals interactions between proteins and nucleic acids and generate a plot showing all of the interactions. Protein-DNA and protein-RNA interactions can be visualized in simple two-dimensional schematics. Interactive schematic drawing options allow selection of the plotted area and repositioning of the individual interactions for better legibility. NuProPlot is a fully automated and user-friendly program providing various custom options. NuProPlot represents a greatly improved option for analysis and presentation of protein-nucleic acid interactions.

A mouse model of human congenital heart disease: high incidence of diverse cardiac anomalies and ventricular noncompaction produced by heterozygous Nkx2-5 homeodomain missense mutation.

BACKGROUND: Heterozygous human mutations of NKX2-5 are highly penetrant and associated with varied congenital heart defects. The heterozygous knockout of murine Nkx2-5, in contrast, manifests less profound cardiac malformations, with low disease penetrance. We sought to study this apparent discrepancy between human and mouse genetics. Because missense mutations in the NKX2-5 homeodomain (DNA-binding domain) are the most frequently reported type of human mutation, we replicated this genetic defect in a murine knockin model. METHODS AND RESULTS: We generated a murine model in a 129/Sv genetic background by knocking-in an Nkx2-5 homeodomain missense mutation previously identified in humans. The mutation was located at homeodomain position 52Arg→Gly (R52G). All the heterozygous neonatal Nkx2-5(+/R52G) mice demonstrated a prominent trabecular layer in the ventricular wall, so called noncompaction, along with diverse cardiac anomalies, including atrioventricular septal defects, Ebstein malformation of the tricuspid valve, and perimembranous and muscular ventricular septal defects. In addition, P10 Nkx2-5(+/R52G) mice demonstrated atrial sepal anomalies, with significant increase in the size of the interatrial communication and fossa ovalis, and decrease in the length of the flap valve compared with control Nkx2-5(+/+) or Nkx2-5(+/-) mice. CONCLUSIONS: The results of our study demonstrate that heterozygous missense mutation in the murine Nkx2-5 homeodomain (R52G) is highly penetrant and result in pleiotropic cardiac effects. Thus, in contrast to heterozygous Nkx2-5 knockout mice, the effects of the heterozygous knockin mimic findings in humans with heterozygous missense mutation in NKX2-5 homeodomain.

Crystallization and preliminary X-ray analysis of the cardiac transcription factor complex of NKX2.5 and TBX5 with DNA.

Heart development depends on timely expression of genes regulated by combinatorial interactions of master cardiac transcription factors. To elucidate the molecular basis of their interactions, a ternary complex of cardiac transcription factors, NKX2.5 and TBX5, and their target DNA was studied using X-ray crystallography. Here, the purification, crystallization and preliminary X-ray crystallographic analyses of the NKX2.5 homeodomain and TBX5 DNA-binding domain complex with a DNA element from the -252 promoter region of the atrial natriuretic factor are reported. The crystal diffracted to 2.88 Å resolution and belonged to space group P21, with unit-cell parameters a = 69.30, b = 77.78, c = 77.60 Å, ß = 108.31°. Two sets of ternary complexes are present in an asymmetric unit with a solvent content of 54%.

Crystal structure of the human NKX2.5 homeodomain in complex with DNA target.

NKX2.5 is a homeodomain containing transcription factor regulating cardiac formation and function, and its mutations are linked to congenital heart disease. Here we provide the first report of the crystal structure of the NKX2.5 homeodomain in complex with double-stranded DNA of its endogenous target, locating within the proximal promoter -242 site of the atrial natriuretic factor gene. The crystal structure, determined at 1.8 Å resolution, demonstrates that NKX2.5 homeodomains occupy both DNA binding sites separated by five nucleotides without physical interaction between themselves. The two homeodomains show identical conformation despite the differences in the DNA sequences they bind, and no significant bending of the DNA was observed. Tyr54, absolutely conserved in NK2 family proteins, mediates sequence-specific interaction with the TAAG motif. This high resolution crystal structure of NKX2.5 protein provides a detailed picture of protein and DNA interactions, which allows us to predict DNA binding of mutants identified in human patients.