Targeting genes to specific neuronal or glial cell types is valuable both for understanding and for repairing brain circuits. Adeno-associated viral vectors (AAVs) are frequently used for gene delivery, but targeting expression to specific cell types is a challenge. We created a library of 230 AAVs, each with a different synthetic promoter designed using four independent strategies. We show that ~11% of these AAVs specifically target expression to neuronal and glial cell types in the mouse retina, mouse brain, non-human primate retina in vivo, and in the human retina in vitro. We demonstrate applications for recording, stimulation, and molecular characterization, as well as the intersectional and combinatorial labeling of cell types. These resources and approaches allow economic, fast, and efficient cell-type targeting in a variety of species, both for fundamental science and for gene therapy.Despite the central importance for both basic and translational research, most current technologies available for cell-type-targeting rely on transgenic animals, which limits their applicability. Either the genetic tool that senses or modulates brain function, or the enzyme, such as Cre recombinase, that allows the genetic tool to be conditionally expressed, is expressed from the animal's genome. The inclusion of a transgenic component in the cell-type-targeting strategy excludes its use in therapy for humans, limits its range of application in pre-clinical, non-human primate research, and complicates its use in model organisms such as mice. The development of transgenic non-human primates and mice is costly and slow, especially since cell-type targeting is often applied in the context of other genetic manipulations, such as double or triple gene knockouts, or when targeting different cell types with different tools.Viral vectors for cell-type-targeting may overcome such limitations. AAVs are the most frequently used vectors in both basic research and gene therapy, as they are safe for use in all tested species, including humans and non-human primates, and their production is simple, cheap, and fast (Planul and Dalkara, 2017). They have three important components: the capsid for cell entry, the promoter that drives transgene expression, and the gene of interest to be expressed in the transduced cells, and they drive expression episomally (Duan et al., 1998; Penaud-Budloo et al., 2008). Futhermore, many genetic tools are small enough to fit into AAVs, different AAVs can be injected together, and synthetic AAV capsids allow brain-wide delivery (Deverman et al., 2016).Cell-type-targeting by AAVs could be achieved by engineering the capsid and/or by using specific promoters. Capsid protein mutations can be used to tune the efficacy of
Our investigation was conducted in order to verify a recent severe epidemic at several swine farms in northern China that indicated a newly emerging disease. Evidence confirmed that the epidemic was caused by a virulent Pseudorabies virus infection in swine herds.
Purpose To report and disscuss the postoperative complications in patients after Densiron 68 intraocular tamponade in the management of complicated retinal detachment with proliferative vitreoretinopathy (PVR). Methods We presented a prospective interventional non-comparative case series of 27 eyes of 27 consecutive patients. Inclusion criteria were PVR, posterior or inferior retinal breaks, and the patient's inability to posture. Vitreoretinal surgery with Densiron 68 intraocular tamponade was performed in all patients. Complications were recorded at 1 week and 1, 2, and 3 months after Densiron 68 intraocular tamponade and after removal of Densiron 68 endotamponade at same periods. Results The most common complication was posterior capsule opacification and cataract development in seven eyes (25.9%) and in two eyes (25%, 2/8), respectively, the second complication was intraocular inflammation in six eyes (22.2%), the third complication was emulsification and dispersion and raised intraocular pressure in five eyes (18.5%), respectively. The success rate with one operation using Densiron 68 was 85.2% and with further surgery 92.5%. Visual acuity improved from mean logMAR of 2.12 (SD ¼ 0.68) to 1.16 (SD ¼ 0.84), P ¼ 0.0001. Conclusions According to the results of this study, postoperative complications did not increase significantly in the vitreoretinal surgery with temporary Densiron 68 intraocular tamponade. Densiron 68 intraocular tamponade is safe and effective in treating complicated retinal detachment.
The aim of the present study was to analyze an outbreak of hemorrhagic fever with renal syndrome (HFRS), caused by a Hantavirus, in college students in the northern urban area of Xi’an in 2012. The outbreak affected six students and included two deaths. The epidemiological survey revealed that both of the deceased cases were misdiagnosed initially, and treatment was delayed. Furthermore, a higher rodent population density and lower HFRS vaccine coverage were observed in the affected area, which indicates a possible role in the outbreak. Rattus norvegicus (Rn) and Mus musculus (Mm) were the predominant host populations in the area. Genotyping revealed that all HVs from patients and rodents were Hantaan virus (HTNV). Sequence analysis of the S segments revealed that the HTNVs reported in this study had high similarity with strains reported in 2011 and 1985, but these viruses diverged from a strain isolated in 1984 and the HTNV prototype strain 76-118. Detection of anti-HV IgG and amplification of the S segment of HTNV from a non-natural HTNV reservoir indicates that further investigations by increased rodent trapping are necessary.
Targeting genes to specific neuronal or glial cell types is valuable both for understanding and for repairing brain circuits. Adeno-associated viral vectors (AAVs) are frequently used for gene delivery, but targeting expression to specific cell types is a challenge. We created a library of 230 AAVs, each with a different synthetic promoter designed using four independent strategies. We show that ~11% of these AAVs specifically target expression to neuronal and glial cell types in the mouse retina, mouse brain, non-human primate retina in vivo, and in the human retina in vitro. We demonstrate applications for recording, stimulation, and molecular characterization, as well as the intersectional and combinatorial labeling of cell types. These resources and approaches allow economic, fast, and efficient cell-type targeting in a variety of species, both for fundamental science and for gene therapy.Despite the central importance for both basic and translational research, most current technologies available for cell-type-targeting rely on transgenic animals, which limits their applicability. Either the genetic tool that senses or modulates brain function, or the enzyme, such as Cre recombinase, that allows the genetic tool to be conditionally expressed, is expressed from the animal's genome. The inclusion of a transgenic component in the cell-type-targeting strategy excludes its use in therapy for humans, limits its range of application in pre-clinical, non-human primate research, and complicates its use in model organisms such as mice. The development of transgenic non-human primates and mice is costly and slow, especially since cell-type targeting is often applied in the context of other genetic manipulations, such as double or triple gene knockouts, or when targeting different cell types with different tools.
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