技术资料

Genome editing via homologous recombination (HR) (gene targeting) in human hematopoietic stem cells (HSCs) has the power to reveal gene-function relationships and potentially transform curative hematological gene and cell therapies. However,there are no comprehensive and reproducible protocols for targeting HSCs for HR. Herein,we provide a detailed protocol for the production,enrichment,and in vitro and in vivo analyses of HR-targeted HSCs by combining CRISPR/Cas9 technology with the use of rAAV6 and flow cytometry. Using this protocol,researchers can introduce single-nucleotide changes into the genome or longer gene cassettes with the precision of genome editing. Along with our troubleshooting and optimization guidelines,researchers can use this protocol to streamline HSC genome editing at any locus of interest. The in vitro HSC-targeting protocol and analyses can be completed in 3 weeks,and the long-term in vivo HSC engraftment analyses in immunodeficient mice can be achieved in 16 weeks. This protocol enables manipulation of genes for investigation of gene functions during hematopoiesis,as well as for the correction of genetic mutations in HSC transplantation-based therapies for diseases such as sickle cell disease,$\beta$-thalassemia,and primary immunodeficiencies. View Publication

We have developed models of HIV latency using microglia derived from adult human patient brain cortex and transformed with the SV40 T large and hTERT antigens. Latent clones infected by HIV reporter viruses display high levels of spontaneous HIV reactivation in culture. BrainPhys,a medium highly representative of the CNS extracellular environment,containing low glucose and 1{\%} FBS,reduced,but did not prevent,HIV reactivation. We hypothesized that spontaneous HIV reactivation in culture was due to the expression of pro-inflammatory genes,such as TNF-alpha$,taking place in the absence of the natural inhibitory signals from astrocytes and neurons. Indeed,expression and secretion of TNF-alpha$ is strongly reduced in HIV-latently infected microglia compared to the subset of cells that have undergone spontaneous HIV reactivation. Whereas inhibitors of NF-kappa$B or of macrophage activation only had a short-term silencing effect,addition of dexamethasone (DEXA),a glucocorticoid receptor (GR) agonist and mediator of anti-inflammation,silenced the HIV provirus in a long-term,and shRNA-mediated knock-down of GR activated HIV. DEXA also decreased secretion of a number of cytokines,including TNF-alpha$. Chromatin immunoprecipitation analysis revealed that DEXA strongly increased GR occupancy at the HIV promoter,and reduced histone 3 acetylated levels. Moreover,TNF-alpha$ expression inhibitors in combination with DEXA induced further HIV silencing and increased the histone 3 lysine 27 tri-methylated epigenetic mark of repression at the HIV promoter region. We conclude that GR is a critical repressor of HIV transcription in microglia,and a novel potential pharmacological target to restrict HIV expression in the CNS. View Publication

We introduce a novel all-optical assay for functional studies of biological neural networks in vitro. We created a novel optogenetic construct named OptoCaMP which is a combination of a channelrhodopsin variant (CheRiff) and a red genetically encoded calcium indicator (GECI) (jRCaMP1b). It enables simultaneous optical stimulation and recording from large population of neurons with single-cell readout. Additionally,we have developed a spatio-temporal all-optical assay to simultaneously stimulate a sub-section of a neural network and record evoked calcium activity,in both stimulated and non-stimulated neurons,thus allowing the investigation of the spread of excitation through an interconnected network. Finally,we demonstrate the sensitivity of this assay to the change of neural network connectivity. View Publication