Success with genome editing by the RNA-programmed nuclease Cas9 has been limited by the inability to predict effective guide RNAs and DNA target sites. Not all guide RNAs have been successful, and even those that were, varied widely in their efficacy. Here we describe and validate a strategy for Caenorhabditis elegans that reliably achieved a high frequency of genome editing for all targets tested in vivo. The key innovation was to design guide RNAs with a GG motif at the 39 end of their target-specific sequences. All guides designed using this simple principle induced a high frequency of targeted mutagenesis via nonhomologous end joining (NHEJ) and a high frequency of precise DNA integration from exogenous DNA templates via homology-directed repair (HDR). Related guide RNAs having the GG motif shifted by only three nucleotides showed severely reduced or no genome editing. We also combined the 39 GG guide improvement with a co-CRISPR/co-conversion approach. For this co-conversion scheme, animals were only screened for genome editing at designated targets if they exhibited a dominant phenotype caused by Cas9-dependent editing of an unrelated target. Combining the two strategies further enhanced the ease of mutant recovery, thereby providing a powerful means to obtain desired genetic changes in an otherwise unaltered genome. KEYWORDS CRISPR; Cas9; genome editing; co-conversion; C. elegans T HE use of site-specific nucleases with programmable target specificity has transformed the art of genome editing and thereby revolutionized the dissection and manipulation of genome function (reviewed in Mali et al. 2013;Carroll 2014;Doudna and Charpentier 2014;Hsu et al. 2014). Most widely used is the CRISPR-associated nuclease Cas9, whose RNA-programmed DNA cleaving activities create DNA double-strand breaks (DSBs). These DSBs can be repaired imprecisely by nonhomologous end joining (NHEJ) to generate random insertions and deletions or repaired precisely by homology-directed repair (HDR) templated from exogenous DNA to generate custom-designed insertions, deletions, or substitutions (Gasiunas et al. 2012;Jinek et al. 2012;Cong et al. 2013;Jinek et al. 2013;Mali et al. 2013). Modified variants of Cas9 that lack DNA cleaving activity have also been utilized to regulate transcription of designated gene targets and to cytologically mark and track genomic loci in living cells (Bikard et al. 2013;Chen et al. 2013;Larson et al. 2013;Maeder et al. 2013;Perez-Pinera et al. 2013;Qi et al. 2013;Gilbert et al. 2014;Tanenbaum et al. 2014).The Cas9 protein is targeted to a specific genomic locus by a guide RNA that encodes a 20-nt region of homology to the DNA target ( Figure 1A) (Mojica et al. 2009;Garneau et al. 2010;Jinek et al. 2012). The most commonly used guide RNAs are chimeric fusions between the CRISPR RNA (crRNA), which encodes the 20-nt target-specific sequence, and the tracer RNA (trRNA), which enables the formation of active Cas9-guide RNA complexes ( Figure 1A) (Jinek et al. 2012). Few constraints are known for Cas9 ...
Migration of Human Keratinocytes in Electric Fields Requires Growth Factors and Extracellular Calcium
Currents that leak out of wounds generate electric fields lateral to the wound. These fields induce directional locomotion of human keratinocytes in vitro and may promote wound healing in vivo. We have examined the effects of growth factors and calcium, normally present in culture medium and the wound fluid, on the directional migration of human keratinocytes in culture. In electric fields of physiologic strength (100 mV per mm), keratinocytes migrated directionally towards the cathode at a rate of about 1 microm per min. This directional migration requires several growth factors. In the absence of these growth factors, the cell migration rate decreased but directionality was maintained. Epidermal growth factor alone restored cell migration rates at concentrations as low as 0.2 ng per ml. Insulin at 5-100 microg per ml or bovine pituitary extract at 0.2%-2% vol/vol also stimulated keratinocyte motility but was not sufficient to fully restore the migration rate. Keratinocyte migration in electric fields requires extracellular calcium. Changes in calcium concentrations from 3 microM to 3.3 mM did not significantly change keratinocyte migration rate nor directionality in electric fields; however, addition of the chelator ethyleneglycol-bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid to migration medium reduced, and eventually abolished, keratinocyte motility. Our results show that (i) growth factors and extracellular calcium are required for electric field-induced directional migration of human keratinocytes, and (ii) keratinocytes migrate equally well in low and high calcium media.
Resistance to thyroid hormone (RTH) syndrome is an inherited inability to respond appropriately to T3 hormone. In generalized RTH, the T3 response of both the pituitary and periphery is disrupted. In pituitary (or central) RTH, the ability of the pituitary to sense (and down-regulate) elevated T3 is selectively impaired, whereas the periphery remains relatively T3 responsive, resulting in peripheral thyrotoxicity. Both forms of disease are linked to mutations in thyroid hormone receptor (TR)-beta. TRbeta is expressed by alternate mRNA splicing as two isoforms: TRbeta2, found primarily in the pituitary/hypothalamus, and TRbeta1, expressed broadly in many tissues. We report here that the wild-type TRbeta2 isoform displays an enhanced T3 response relative to the TRbeta1 isoform. Mutations associated with generalized RTH (P453S, G345S) impair both TRbeta2 and TRbeta1 function proportionally, whereas mutations associated with pituitary-specific RTH (R338L, R338W, R429Q) disproportionately disrupt TRbeta2 function. We propose that in the normal organism, and in generalized RTH, TRbeta2 in the pituitary can sense rising T3 levels in advance of TRbeta1 in the periphery, preventing thyrotoxicity. In contrast, the TRbeta mutations associated with pituitary RTH disproportionately disrupt the pituitary's ability to sense and suppress elevated T3 levels in advance of the periphery, producing symptoms of thyrotoxicity.
The targetable DNA endonuclease CRISPR-Cas9 has transformed analysis of biological processes by enabling robust genome editing in model and nonmodel organisms. Although rules directing Cas9 to its target DNA via a guide RNA are straightforward, wide variation occurs in editing efficiency and repair outcomes for both imprecise error-prone repair and precise templated repair. We found that imprecise and precise DNA repair from double-strand breaks (DSBs) is asymmetric, favoring repair in one direction. Using this knowledge, we designed RNA guides and repair templates that increased the frequency of imprecise insertions and deletions and greatly enhanced precise insertion of point mutations in Caenorhabditis elegans. We also devised strategies to insert long (10 kb) exogenous sequences and incorporate multiple nucleotide substitutions at a considerable distance from DSBs. We expanded the repertoire of co-conversion markers appropriate for diverse nematode species. These selectable markers enable rapid identification of Cas9-edited animals also likely to carry edits in desired targets. Lastly, we explored the timing, location, frequency, sex dependence, and categories of DSB repair events by developing loci with allele-specific Cas9 targets that can be contributed during mating from either male or hermaphrodite germ cells. We found a striking difference in editing efficiency between maternally and paternally contributed genomes. Furthermore, imprecise repair and precise repair from exogenous repair templates occur with high frequency before and after fertilization. Our strategies enhance Cas9-targeting efficiency, lend insight into the timing and mechanisms of DSB repair, and establish guidelines for achieving predictable precise and imprecise repair outcomes with high frequency.
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