हरपीज के अध्ययन के लिए एक प्राथमिक न्यूरॉन संस्कृति सिस्टम वायरस लेटेंसी और पुनर्सक्रियण सिंप्लेक्स
Summary
प्रोटोकॉल एक कुशल और प्रतिलिपि प्रस्तुत करने योग्य मॉडल प्रणाली के अध्ययन दाद सिंप्लेक्स वायरस टाइप 1 (एचएसवी -1) विलंबता और पुनर्सक्रियन का वर्णन करता है. परख समरूप सहानुभूति न्यूरॉन संस्कृतियों को रोजगार और वायरस न्यूरॉन शाही सेना के हस्तक्षेप और पुनः संयोजक प्रोटीन की अभिव्यक्ति सहित उपकरणों की एक किस्म का उपयोग कर बातचीत की आणविक विच्छेदन के लिए अनुमति देता है.
Abstract
Herpes simplex virus type-1 (HSV-1) establishes a life-long latent infection in peripheral neurons. This latent reservoir is the source of recurrent reactivation events that ensure transmission and contribute to clinical disease. Current antivirals do not impact the latent reservoir and there are no vaccines. While the molecular details of lytic replication are well-characterized, mechanisms controlling latency in neurons remain elusive. Our present understanding of latency is derived from in vivo studies using small animal models, which have been indispensable for defining viral gene requirements and the role of immune responses. However, it is impossible to distinguish specific effects on the virus-neuron relationship from more general consequences of infection mediated by immune or non-neuronal support cells in live animals. In addition, animal experimentation is costly, time-consuming, and limited in terms of available options for manipulating host processes. To overcome these limitations, a neuron-only system is desperately needed that reproduces the in vivo characteristics of latency and reactivation but offers the benefits of tissue culture in terms of homogeneity and accessibility.
Here we present an in vitro model utilizing cultured primary sympathetic neurons from rat superior cervical ganglia (SCG) (Figure 1) to study HSV-1 latency and reactivation that fits most if not all of the desired criteria. After eliminating non-neuronal cells, near-homogeneous TrkA+ neuron cultures are infected with HSV-1 in the presence of acyclovir (ACV) to suppress lytic replication. Following ACV removal, non-productive HSV-1 infections that faithfully exhibit accepted hallmarks of latency are efficiently established. Notably, lytic mRNAs, proteins, and infectious virus become undetectable, even in the absence of selection, but latency-associated transcript (LAT) expression persists in neuronal nuclei. Viral genomes are maintained at an average copy number of 25 per neuron and can be induced to productively replicate by interfering with PI3-Kinase / Akt signaling or the simple withdrawal of nerve growth factor1. A recombinant HSV-1 encoding EGFP fused to the viral lytic protein Us11 provides a functional, real-time marker for replication resulting from reactivation that is readily quantified. In addition to chemical treatments, genetic methodologies such as RNA-interference or gene delivery via lentiviral vectors can be successfully applied to the system permitting mechanistic studies that are very difficult, if not impossible, in animals. In summary, the SCG-based HSV-1 latency / reactivation system provides a powerful, necessary tool to unravel the molecular mechanisms controlling HSV1 latency and reactivation in neurons, a long standing puzzle in virology whose solution may offer fresh insights into developing new therapies that target the latent herpesvirus reservoir.
Protocol
Discussion
यह प्राथमिक न्यूरॉन संस्कृति और संक्रमण प्रणाली आणविक एचएसवी -1 विलंबता और पुनर्सक्रियन अंतर्निहित तंत्र का पता लगाने के लिए एक सरल और प्रभावी करने के लिए विधि प्रदान करता है. प्रणाली ईमानदारी ?…
Declarações
The authors have nothing to disclose.
Acknowledgements
हम अपने विचारशील सुझाव है कि इस पांडुलिपि में सुधार करने में मदद के लिए समीक्षकों धन्यवाद. यह काम (HD23315 NS21072,) MVC, ACW (S10RR017970, GM61139) के के और आईएम (GM056927, AI073898) NIH से अनुदान द्वारा समर्थित किया गया. एम के हिस्से में एक NIH प्रशिक्षण अनुदान (AI007180 5T32) के द्वारा समर्थित किया गया था.
Materials
| Reagent | Company | Catalog# | Comments |
| 70μm nylon filter( cell strainer) | BD Biosciences | 352350 | |
| 1x Hank’s Balanced Salt Solution (HBSS-/-) | Invitrogen | 14175 | w/o CaCl2 and MgCl2 |
| 1x Minimum Essential Media (MEM) | Invitrogen | 11095-080 | |
| 5-Fluoro-2′-deoxyuridine | Sigma | F0503 | prepare 20 mM stock in 1x MEM; store at -20°C |
| 96-well flat well bottom TC plates | Corning | 3599 | |
| Acyclovir | Calbiochem | 114798 | prepare 31 mM stock in DMSO; store at -20°C |
| Aphidicolin | Calbiochem | 178273 | prepare 10 mM stock in DMSO; store at -20°C |
| B-27 Supplement | Invitrogen | 17504-44 | |
| Collagenase | Sigma | C2674 | prepare 10 mg/ml stock in HBSS-/-; store at -20°C |
| D-(+)-Glucose | Sigma | G6152 | prepare 40% stock in H2O; filter sterilize & store at 4°C |
| L-Glutamine | Invitrogen | 25030-081 | |
| Laminin | Sigma | L2020 | prepare 1 mg/ml stock in H2O; quick-freeze 20 μl aliquats & store at -80°C; dilute to 2 μg/ml working conc. in sterile H2O |
| Leibovit’z L-15 media | Invitrogen | 11415 | |
| Nerve Growth Factor | Harlan Laboratories | BT.5017 | prepare 50 μg/ml stock in HBSS-/-; store at -80°C |
| Neurobasal medium | Invitrogen | 12348 | |
| Phosphonoacetic acid (PAA) | Sigma | P6909 | prepare 75 mg/ml stock in H2O; store at -20°C |
| Poly-D-lysine hydrobromide | Sigma | P0899 | prepare 20 mg/ml stock in H2O; store at -20°C |
| Rat-tail collagen | Millipore | 08-115 | Concentration varies with supply lot; store at 4°C and dilute to 0.66 mg/ml working conc. in sterile H2O |
| Trichostatin A | Sigma | T8552 | prepare 1 mM stock in DMSO; store at -20°C |
| Trypsin 2.5% | Invitrogen | 15090-04 |
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