Zebrafish (Danio rerio) is a unique potential model animal for dissecting innate immune signaling. Here we demonstrate that herpes simplex virus 1 (HSV-1) could infect zebrafish at its different developmental stages and trigger the expression of type I interferons (IFNs) as well as interferon-stimulated genes (ISGs) in zebrafish larvae. Silencing of zSTING, but not zMAVS, markedly attenuates the DNA virus-induced antiviral responses. Notably, a conserved serine residue (S373) is essential for the action of zSTING. Unexpectedly, zebrafish cyclic GMP-AMP synthase (cGAS) is dispensable for the STING signaling, whereas zDHX9 and zDDX41 are potential sensors for HSV-1 infection in vivo. Taken together, this proof-of-concept study establishes the zebrafish larva as a feasible model for investigating the cytosolic DNA sensing mechanism, shedding light on the conservation of the STING antiviral signaling pathway. IMPORTANCEThe zebrafish larva provides technical advantages for understanding host-pathogen interactions. In this study, we established the zebrafish larva as a useful model for studying HSV-1 infection. HSV-1 infection triggers strong type I interferon production, which depends on STING expression. In addition, STING-mediated antiviral signaling is conserved in zebrafish. Interestingly, zDHX9 and zDDX41 are indispensable for detecting HSV-1, while cGAS is dispensable. This proof-of-concept study indicates that the zebrafish represents an amenable model for the investigation of cytosolic DNA sensing mechanisms.
We consider the application of infrared spectroscopy to protein crystals, with particular emphasis on exploiting molecular orientation through polarization measurements on oriented single crystals. Infrared microscopes enable transmission measurements on individual crystals using either thermal or nonthermal sources, and can accommodate flow cells, used to measure spectral changes induced by exposure to soluble ligands, and cryostreams, used for measurements of flash-cooled crystals. Comparison of unpolarized infrared measurements on crystals and solutions probes the effects of crystallization and can enhance the value of the structural models refined from X-ray diffraction data by establishing solution conditions under which they are most relevant. Results on several proteins are consistent with similar equilibrium conformational distributions in crystal and solutions. However, the rates of conformational change are often perturbed. Infrared measurements also detect products generated by X-ray exposure, including CO(2). Crystals with favorable symmetry exhibit infrared dichroism that enhances the synergy with X-ray crystallography. Polarized infrared measurements on crystals can distinguish spectral contributions from chemically similar sites, identify hydrogen bonding partners, and, in opportune situations, determine three-dimensional orientations of molecular groups. This article is part of a Special Issue entitled: Protein Structure and Function in the Crystalline State.
In recent years, micropeptides have been increasingly identified as important regulators in various biological processes. However, whether micropeptides are functionally conserved remains largely unknown. Here, we uncovered a micropeptide with evolutionarily conserved roles in myogenesis. RNA-seq data analysis of proliferating mouse satellite cells (SCs) and differentiated myotubes identified a previously annotated lncRNA, MyolncR4 (1500011K16RIK), which is upregulated during muscle differentiation. Significantly, MyolncR4 is highly conserved across vertebrate species. Multiple lines of evidence demonstrate that MyolncR4 encodes a 56-aa micropeptide, which was named as LEMP (lncRNA encoded micropeptide). LEMP promotes muscle formation and regeneration in mouse. In zebrafish, MyolncR4 is enriched in developing somites and elimination of LEMP results in impaired muscle development, which could be efficiently rescued by expression of the mouse LEMP. Interestingly, LEMP is localized at both the plasma membrane and mitochondria, and associated with multiple mitochondrial proteins, suggestive of its involvement in mitochondrial functions. Together, our work uncovers a micropeptide that plays an evolutionarily conserved role in skeletal muscle differentiation, pinpointing the functional importance of this growing family of small peptides.
Background Diabetic retinopathy (DR) is the leading cause of blindness in the working age population. Transthyretin (TTR) showed a significantly decreased concentration in DR patients and exerted a visual protective effect by repressing neovascularization. This work intended to identify long non coding RNAs (lncRNAs) and explore their potential mechanism underlying the protective role of TTR. Methods Transcriptome of human retinal endothelial cells (hRECs) treated with low glucose (LG), high glucose (HG) or high glucose with 4 μM TTR (HG + TTR) was conducted. Differentially expressed lncRNAs, mRNAs and TTR related lncRNAs and mRNA were acquired. Functional annotation and Gene Set Enrichment Analysis were applied to analyse TTR affected pathways and processes. Weighted gene co-expression network analysis (WGCNA) was implemented to obtain hub modules and genes. LncRNA-mRNA regulatory networks were constructed based on cis, trans and competing endogenous RNAs acting mode. QRT-PCR was conducted to validate the expression of lncRNAs in aqueous humor and serum samples from 30 DR patients and 10 normal controls. Results RNA-sequencing of hRECs treated with low glucose (LG), high glucose (HG) or high glucose with 4 μM TTR (HG + TTR) was conducted. 146,783 protein-coding transcripts, 12,403 known lncRNA transcripts and 1184 novel non-coding transcripts were characterized. A total of 11,407 differentially expressed mRNAs (DE-mRNAs), 679 differentially expressed lncRNAs (DE-lncRNAs) in HG group versus LG group, 6206 DE-mRNAs and 194 DE-lncRNAs in HG + TTR versus HG group were obtained, respectively. 853 TTR-mRNAs and 48 TTR-lncRNAs were acquired, and functionally involved in cell cycle, apoptosis, inflammation signalling pathway, response to oxidative stress, neovascularization and autophagy. The WGCNA analysis identified a hub module of 133 genes, with the core function of oxidative stress response, angiogenesis, MAPK pathway, cell proliferation and apoptosis. After qRT-PCR validation, a 3-lncRNA regulatory network was proposed. At last, lncRNAs MSTRG.15047.3 and AC008403.3 showed significantly relative higher expression levels in both aqueous humor and serum samples, compared with normal controls, and FRMD6-AS2 was significantly down-regulated. Conclusions TTR regulated mRNAs and biological processes including oxidative stress, inflammation signalling and autophagy. A 3-lncRNA regulatory network was characterized underlying TTR repressing neovascularization, and showed potential diagnostic performance in DR.
A total of 45 moderately halophilic bacteria was isolated from sediment and saline water collected from the Weihai Solar Saltern (China). The phylogenetic position of all the isolated strains was determined by 16S rRNA sequencing. The halophilic strains were tested for their antimicrobial activity. Cytotoxicity assay was performed to determine which of the halophilic strains could inhibit proliferation of human hepatocellular carcinoma Bel 7402 cells. Our results showed that all of the isolated 45 strains displayed moderately halophilic characteristics. Phylogenetic analysis indicated that 17 of the isolated strains were related to the phylum Firmicutes and belonged to four genera, Bacillus, Halobacillus, Planococcus and Salinicoccus. The other strains identified as genus of Halomonas belonged to phylum c-Proteobacteria. Most of the halophilic bacterial strains showed potent activities against Gram-positive bacteria, human pathogenic fungi and plant pathogenic fungi. In addition, the crude extracts from 14 halophilic bacterial strains showed cytotoxic activity against tumor cells Bel 7402, and five of them showed remarkable activities with IC 50 less than 40 lg ml -1 . Our results suggest that the moderately halophilic bacteria may be developed as promising sources for the discovery of novel bioactive substances.
Recent structural investigations have generated uncertainty regarding the protonation state of the exogenous oxo ligand in ferryl derivatives of several heme proteins. We used nuclear resonance vibrational spectroscopy (NRVS) to reveal the complete spectrum of Fe−ligand modes for compound II of myoglobin. Comparison with vibrational DFT predictions allows us to identify vibrations involving FeO tilting, coupled with stretching of the Fe−N bonds to the heme, and stretching of the proximal Fe−His bond, in addition to the previously observed Fe−O stretching vibration. Additional calculations, coupled with measurements on the hydroxyl derivative of metmyoglobin, reveal vibrational signatures for the putative protonated ferryl species. These include a 33 cm-1 splitting of the FeO tilting modes due to the asymmetrically placed proton, as well as a 250 cm-1 decrease of the Fe−O stretching frequency. The vibrational data suggest a fully deprotonated oxo ligand in compound II.
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