Coelenterazine (CTZ)-utilizing marine luciferases and their derivatives have attracted significant attention because of their ATP-independency, fast enzymatic turnover, and high bioluminescence brightness. However, marine luciferases typically emit blue photons and their substrates, including CTZ and the recently developed diphenylterazine (DTZ), have poor water solubility, hindering their in vivo applications. Herein, we report a family of pyridyl CTZ and DTZ analogs that exhibit spectrally shifted emission and improved water solubility. Through directed evolution, we engineered a LumiLuc luciferase with broad substrate specificity. In the presence of corresponding pyridyl substrates (i.e., pyCTZ, 6pyDTZ, or 8pyDTZ), LumiLuc generates highly bright blue, teal, or yellow bioluminescence. We compared our LumiLuc-8pyDTZ pair with several benchmark reporters in a tumor xenograft mouse model. Our new pair, which does not need organic cosolvents for in vivo administration, surpasses other reporters by detecting early tumors. We further fused LumiLuc to a red fluorescent protein, resulting in a LumiScarlet reporter with further red-shifted emission and enhanced tissue penetration. LumiScarlet-8pyDTZ was comparable to Akaluc-AkaLumine, the brightest ATP-dependent luciferase-luciferin pair, for detecting cells in deep tissues of mice. In summary, we have engineered a new family of ATP-independent bioluminescent reporters, which will have broad applications because of their ATP-independency, excellent biocompatibility, and superior in vivo sensitivity.
Although fluorescent indicators have been broadly utilized for monitoring bioactivities, fluorescence imaging, when applied to mammals, is limited to superficial targets or requires invasive surgical procedures. Thus, there is emerging interest in developing bioluminescent indicators for noninvasive mammalian imaging. Bioluminescence imaging (BLI) of neuronal activity is highly desired but hindered by insufficient photons needed to digitalize fast brain activities. In this work, we develop a luciferase prosubstrate deliverable at an increased dose and activated in vivo by nonspecific esterase. We further engineer a bright, bioluminescent indicator with robust responsiveness to calcium ions (Ca2+) and appreciable emission above 600 nm. Integration of these advantageous components enables the imaging of the activity of neuronal ensembles in awake mice minimally invasively with excellent signal-to-background and subsecond temporal resolution. This study thus establishes a paradigm for studying brain function in health and disease.
In vivo bioluminescence imaging (BLI) has become a standard, non-invasive imaging modality for following gene expression or the fate of proteins and cells in living animals. Currently, bioluminescent reporters used in laboratories are mostly derivatives of two major luciferase families: ATP-dependent insect luciferases and ATP-independent marine luciferases. Inconsistent results have been reported for experiments using different bioluminescent reporters, such as Akaluc and Antareas2. Herein, we reexamined the inconsistency in several experimental settings and identified that factors, such as ATP dependency, stability in serum, and molecular sizes of luciferases, contributed to the observed differences. We expect this study will make the research community aware of these factors and facilitate more accurate interpretation of BLI data by considering the nature of each bioluminescent reporter.
UHRF1 (ubiquitin-like, containing PHD and RING finger domains, 1) is one of the essential components of mammalian DNA methylation machinery. Chromatin association of UHRF1 is controlled via an interplay between its intramolecular interaction and dual recognition of histone H3 trimethylated at lysine 9 (H3K9me3) and hemimethylated DNA. Here, we report the crystal structure of the N-terminal tandem Tudor domain (TTD) of UHRF1 in complex with the C-terminal polybasic region (PBR). Structural analysis reveals that PBR binding leads to displacement of the TTD-plant homeodomain (PHD) linker, as well as blockage of the H3K9me3-engaging cage, both of which contribute to a chromatin-occluded UHRF1 conformation. Disruption of the TTD-PBR interaction, which is facilitated by the binding of UHRF1 to hemimethylated DNA or regulatory protein USP7, shifts the UHRF1 conformation toward an open state, allowing for efficient H3K9me3 binding. Together, this study provides structural basis for the allosteric regulation of UHRF1.
The color palette of genetically encoded fluorescent protein indicators (GEFPIs) has expanded rapidly in recent years. GEFPIs with excitation and emission within the “optical window” above 600 nm are expected to be superior in many aspects, such as enhanced tissue penetration, reduced autofluorescence and scattering, and lower phototoxicity. Circular permutation of fluorescent proteins (FPs) is often the first step in the process of developing single-FP-based GEFPIs. This study explored the tolerance of two far-red FPs, mMaroon1 and mCarmine, towards circular permutation. Several initial constructs were built according to previously reported circularly permuted topologies for other FP analogs. Mutagenesis was then performed on these constructs and screened for fluorescent variants. As a result, five circularly permuted far-red FPs (cpFrFPs) with excitation and emission maxima longer than 600 nm were identified. Some displayed appreciable brightness and efficient chromophore maturation. These cpFrFPs variants could be intriguing starting points to further engineer far-red GEFPIs for in vivo tissue imaging.
Synaptic zinc ion (Zn 2+ ) has emerged as a key neuromodulator in the brain. However, the lack of research tools for directly tracking synaptic Zn 2+ in the brain of awake animals hinders our rigorous understanding of the physiological and pathological roles of synaptic Zn 2+ . In this study, we developed a genetically encoded far-red fluorescent indicator for monitoring synaptic Zn 2+ dynamics in the nervous system. Our engineered far-red fluorescent indicator for synaptic Zn 2+ (FRISZ) displayed a substantial Zn 2+ -specific turn-on response and low-micromolar affinity. We genetically anchored FRISZ to the mammalian extracellular membrane via a transmembrane (TM) ⍺ helix and characterized the resultant FRISZ-TM construct at the mammalian cell surface. We used FRISZ-TM to image synaptic Zn 2+ in the auditory cortex in acute brain slices and awake mice in response to electric and sound stimuli, respectively. Thus, this study establishes a technology for studying the roles of synaptic Zn 2+ in the nervous system.
Synaptic Zn2+ has emerged as a key neuromodulator in the brain. However, the lack of research tools for directly tracking synaptic Zn2+ in the brain in live animals hinders our rigorous understanding of the physiological and pathological roles of synaptic Zn2+. In this study, we developed a genetically encoded far-red fluorescent indicator for monitoring synaptic Zn2+ dynamics in the nervous system. Our engineered far-red fluorescent indicator for synaptic Zn2+ (FRISZ) displayed a substantial Zn2+-specific turn-on response and low micromolar affinity. We genetically anchored FRISZ to the mammalian extracellular membrane via a transmembrane α-helix. We further successfully used membrane-tethered FRISZ (FRISZ-TM) to image synaptic Zn2+ dynamics in response to sound in the primary auditory cortex (A1) in awake mice. This study thus establishes a new technology for studying the roles of synaptic Zn2+ in the nervous system.
The distribution network has multiple points, long lines, wide coverage, complex structure, and intersecting management links. In order to improve the quality of the analysis and evaluation of the standard grid structure of the distribution network, this approach uses the 10kV medium voltage distribution network as the object to identify the standard connection Research. First, abstract the wiring diagram of the distribution network, extract the characteristics of standard connection types, establish a eigenvector expression model and standard connection type feature library. Second, use breadth-first search to form the network topology structure, and check data to detect the transfer capacity of closed loops, islands, and contact switches. Then use the principle of statistics to calculate the content of the eigenvector expression. Finally, use the pattern recognition method to match the eigenvector expression of the connection group to be identified with the standard wiring type feature library. Based on the statistical standard connection characteristics, this approach adopts the method of pattern recognition to judge the standard grid, which has a good recognition effect and accuracy on the actual distribution network wiring, and is of great significance to the later power grid transformation.
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