Emily K. Mis

CRISPRscan: designing highly efficient sgRNAs for CRISPR-Cas9 targeting in vivo

CRISPR-Cas9 technology provides a powerful system for genome engineering. However, variable activity across different single guide RNAs (sgRNAs) remains a significant limitation. We analyzed the molecular features that influence sgRNA stability, activity and loading into Cas9 in vivo. We observed that guanine enrichment and adenine depletion increased sgRNA stability and activity, whereas differential sgRNA loading, nucleosome positioning and Cas9 off-target binding were not major determinants. We also identified sgRNAs truncated by one or two nucleotides and containing 5′ mismatches as efficient alternatives to canonical sgRNAs. On the basis of these results, we created a predictive sgRNA-scoring algorithm, CRISPRscan, that effectively captures the sequence features affecting the activity of CRISPR-Cas9 in vivo. Finally, we show that targeting Cas9 to the germ line using a Cas9-nanos 3′ UTR led to the generation of maternal-zygotic mutants, as well as increased viability and decreased somatic mutations. These results identify determinants that influence Cas9 activity and provide a framework for the design of highly efficient sgRNAs for genome targeting in vivo.

CRISPR-Cpf1 mediates efficient homology-directed repair and temperature-controlled genome editing

Cpf1 is a novel class of CRISPR-Cas DNA endonucleases, with a wide range of activity across different eukaryotic systems. Yet, the underlying determinants of this variability are poorly understood. Here, we demonstrate that LbCpf1, but not AsCpf1, ribonucleoprotein complexes allow efficient mutagenesis in zebrafish and Xenopus. We show that temperature modulates Cpf1 activity by controlling its ability to access genomic DNA. This effect is stronger on AsCpf1, explaining its lower efficiency in ectothermic organisms. We capitalize on this property to show that temporal control of the temperature allows post-translational modulation of Cpf1-mediated genome editing. Finally, we determine that LbCpf1 significantly increases homology-directed repair in zebrafish, improving current approaches for targeted DNA integration in the genome. Together, we provide a molecular understanding of Cpf1 activity in vivo and establish Cpf1 as an efficient and inducible genome engineering tool across ectothermic species.Cpf1 is a promising addition to the CRISPR toolkit but displays wide variability of activity in different eurkaryotes. Here the authors identify temperature as a modulator of activity and use this to efficiently edit ectothermic vertebrate species.

Automated sorting of live C. elegans using laFACS

To the Editor: A recent paper in Nature Methods describes the use of fluorescence-activated cell sorting (FACS) is to sort Caenorhabditis elegans embryos1. Here we report FACS-based method to sort live C. elegans larvae, which permits us to rapidly collect large quantities of live genotyped worms from a mixed population. Using GFP-marked balancer chromosomes (Fig. 1a), and live-animal FACS laFACS, we routinely collected >100,000 genotyped animals in less than one hour. To test laFACS, we combined it with large-scale RNA interference (RNAi) screening and identified genetic interactors of mel-28, an important regulator of nuclear envelope and chromatin functions2–5. Figure 1 laFACS of GFP-negative L1 larvae. (a) Genetic scheme. A mel-28 mutant allele is kept over a balancer chromosome containing a GFP marker and a recessive lethal allele. GFP-negative progeny (F1) are mel-28 homozygotes and grow up to produce only dead embryos. ... Although a FACS machine is designed to sort single cells, a few modifications enabled sorting of ~0.25 mm long L1 C. elegans. First, we used a reduced drop-drive frequency of ~16.4 kHz to keep the larvae undamaged. We also used a 100-µm nozzle and set a gate to capture events with a high forward-scatter signal (Fig. 1b), confining our collections to larger objects (Supplementary Methods). After worm sorting, the same FACS machine could be used for several other applications, including sorting of yeast, Drosophila melanogaster cells, mammalian cells, and plant protoplasts. The worm sort had no impact on these applications, and the worm-specific FACS modifications were easily reversed to accommodate single-cell applications. We used laFACS to collect mel-28 (maternal-effect-lethal-28) homozygous worms from a mixed population. mel-28 homozygous hermaphrodites derived from heterozygous mothers appear phenotypically indistinguishable from wild-type animals until they mature and produce only inviable progeny. This selection is usually performed manually and thus is not amenable to large-scale applications. We first generated a GFP-marked strain in which the mel-28(t1684) mutation is balanced over a chromosome bearing lag-2::GFP6 (Fig. 1a). We sorted L1 worms, collecting GFP-negative mel-28(t1684) homozygotes. We selected GFP-negative larvae on the basis of the ratio of green (GFP fluorescence; 530/30 nm) to red (red-spectrum autofluorescence; 610/20 nm) signal (Fig. 1c,d). We separated GFP-positive and GFP-negative worms (Supplementary Figure 1). Typically, from a population of 600,000 larvae we retrieved ~130,000 healthy animals after one sort. This first-pass population was ~95-98% homozygous (n > 1,000, verified by microscopy). A second sort recovered an essentially 100% pure population of about 100,000 homozygous larvae (n > 20,000, verified by microscopy and by genetic analysis). This scheme can be easily adapted for the majority of C. elegans genes using available balancers. We used the collected homozygous mel-28 animals to perform an RNAi-based synthetic interaction screen using clones representing chromosome I genes7. The ability to easily collect large amounts of mel-28 homozygous animals allowed us to perform the RNAi repeatedly (up to 16 times). From over 2,000 genes tested, 12 showed synthetic phenotypes with mel-28: npp-2, npp-4, npp-12, npp-14, npp-17, his-67, his-68, exos-3, pas-5, phi-56, rpa-0, and rpl-30 (Supplementary Fig. 2 and Supplementary Table 1). These results agreed well with mel-28’s role in coordinating chromatin and nuclear envelope functions2,3. Obtaining large quantities of pure mutant populations could also be useful for chemical screens, microarrays, or biochemical assays, expanding the arsenal of high-throughput tools available in C. elegans.

Forward genetics defines Xylt1 as a key, conserved regulator of early chondrocyte maturation and skeletal length

The long bones of the vertebrate body are built by the initial formation of a cartilage template that is later replaced by mineralized bone. The proliferation and maturation of the skeletal precursor cells (chondrocytes) within the cartilage template and their replacement by bone is a highly coordinated process which, if misregulated, can lead to a number of defects including dwarfism and other skeletal deformities. This is exemplified by the fact that abnormal bone development is one of the most common types of human birth defects. Yet, many of the factors that initiate and regulate chondrocyte maturation are not known. We identified a recessive dwarf mouse mutant (pug) from an N-ethyl-N-nitrosourea (ENU) mutagenesis screen. pug mutant skeletal elements are patterned normally during development, but display a ~20% length reduction compared to wild-type embryos. We show that the pug mutation does not lead to changes in chondrocyte proliferation but instead promotes premature maturation and early ossification, which ultimately leads to disproportionate dwarfism. Using sequence capture and high-throughput sequencing, we identified a missense mutation in the Xylosyltransferase 1 (Xylt1) gene in pug mutants. Xylosyltransferases catalyze the initial step in glycosaminoglycan (GAG) chain addition to proteoglycan core proteins, and these modifications are essential for normal proteoglycan function. We show that the pug mutation disrupts Xylt1 activity and subcellular localization, leading to a reduction in GAG chains in pug mutants. The pug mutant serves as a novel model for mammalian dwarfism and identifies a key role for proteoglycan modification in the initiation of chondrocyte maturation.

High-throughput fluorescence-based isolation of live C. elegans larvae

For the nematode Caenorhabditis elegans, automated selection of animals of specific genotypes from a mixed pool has become essential for genetic interaction or chemical screens. To date, such selection has been accomplished using specialized instruments. However, access to such dedicated equipment is not common. Here we describe live animal fluorescence-activated cell sorting (laFACS), a protocol for automatic selection of live first larval stage (L1) animals using a standard FACS system. We show that FACS can be used for the precise identification of GFP-expressing and non-GFP-expressing subpopulations and can accomplish high-speed sorting of live animals. We have routinely collected 100,000 or more homozygotes from a mixed starting population within 2 h, and with greater than 99% purity. The sorted animals continue to develop normally, making this protocol ideally suited for the isolation of terminal mutants for use in genetic interaction or chemical genetic screens.

Uncovering Buffered Pleiotropy: A Genome-Scale Screen for mel- 28 Genetic Interactors in Caenorhabditis elegans

mel-28 (maternal-effect-lethal-28) encodes a conserved protein required for nuclear envelope function and chromosome segregation in Caenorhabditis elegans. Because mel-28 is a strict maternal-effect lethal gene, its function is required in the early embryo but appears to be dispensable for larval development. We wanted to test the idea that mel-28 has postembryonic roles that are buffered by the contributions of other genes. To find genes that act coordinately with mel-28, we did an RNA interference−based genetic interaction screen using mel-28 and wild-type larvae. We screened 18,364 clones and identified 65 genes that cause sterility in mel-28 but not wild-type worms. Some of these genes encode components of the nuclear pore. In addition we identified genes involved in dynein and dynactin function, vesicle transport, and cell-matrix attachments. By screening mel-28 larvae we have bypassed the requirement for mel-28 in the embryo, uncovering pleiotropic functions for mel-28 later in development that are normally provided by other genes. This work contributes toward revealing the gene networks that underlie cellular processes and reveals roles for a maternal-effect lethal gene later in development.

CRISPR/Cas9 F0 Screening of Congenital Heart Disease Genes in Xenopus tropicalis

In the US and Europe, birth defects are the leading cause of infant mortality. Among birth defects, Congenital Heart Disease (CHD) occurs in approximately 8 out of 1000 live births, affects 1.3 million newborns per year worldwide, and has the highest mortality rate. While there is evidence to indicate that CHD does have a genetic basis, most of the CHD burden remains unexplained genetically. Fortunately, new genomics technologies are enabling genetic analyses of CHD patients. Whole exome sequencing of trios as well as copy number variations assayed by high-density SNP arrays can now be obtained at high efficiency and relatively low cost. These efforts are identifying a number of sequence variations in patients with CHD, but only a small percentage have second unrelated alleles to validate them as disease causing. Importantly, most of these candidate genes do not have an identified molecular mechanism implicating them in cardiac development. Therefore, there is a pressing need to develop rapid functional assays to evaluate candidate genes for a role in cardiac development, and then to investigate the underlying developmental mechanisms. Most recently, the advent of CRISPR/Cas9 genome editing technology has greatly enhanced the ability to manipulate and observe the function of the genome in model systems and cell culture. Incorporating the power of a developmental system such as Xenopus tropicalis with the CRISPR/Cas9 system and the microscale imaging modality optical coherence tomography (OCT), the analysis of thousands of different genes in cardiac development becomes possible.

De novo pathogenic variants in neuronal differentiation factor 2 (NEUROD2) cause a form of early infantile epileptic encephalopathy

Background Early infantile epileptic encephalopathies are severe disorders consisting of early-onset refractory seizures accompanied often by significant developmental delay. The increasing availability of next-generation sequencing has facilitated the recognition of single gene mutations as an underlying aetiology of some forms of early infantile epileptic encephalopathies. Objectives This study was designed to identify candidate genes as a potential cause of early infantile epileptic encephalopathy, and then to provide genetic and functional evidence supporting patient variants as causative. Methods We used whole exome sequencing to identify candidate genes. To model the disease and assess the functional effects of patient variants on candidate protein function, we used in vivo CRISPR/Cas9-mediated genome editing and protein overexpression in frog tadpoles. Results We identified novel de novo variants in neuronal differentiation factor 2 (NEUROD2) in two unrelated children with early infantile epileptic encephalopathy. Depleting neurod2 with CRISPR/Cas9-mediated genome editing induced spontaneous seizures in tadpoles, mimicking the patients’ condition. Overexpression of wild-type NEUROD2 induced ectopic neurons in tadpoles; however, patient variants were markedly less effective, suggesting that both variants are dysfunctional and likely pathogenic. Conclusion This study provides clinical and functional support for NEUROD2 variants as a cause of early infantile epileptic encephalopathy, the first evidence of human disease caused by NEUROD2 variants.

RPSA, a candidate gene for isolated congenital asplenia, is required for pre-rRNA processing and spleen formation in Xenopus

ABSTRACT A growing number of tissue-specific inherited disorders are associated with impaired ribosome production, despite the universal requirement for ribosome function. Recently, mutations in RPSA, a protein component of the small ribosomal subunit, were discovered to underlie approximately half of all isolated congenital asplenia cases. However, the mechanisms by which mutations in this ribosome biogenesis factor lead specifically to spleen agenesis remain unknown, in part due to the lack of a suitable animal model for study. Here we reveal that RPSA is required for normal spleen development in the frog, Xenopus tropicalis. Depletion of Rpsa in early embryonic development disrupts pre-rRNA processing and ribosome biogenesis, and impairs expression of the key spleen patterning genes nkx2-5, bapx1 and pod1 in the spleen anlage. Importantly, we also show that whereas injection of human RPSA mRNA can rescue both pre-rRNA processing and spleen patterning, injection of human mRNA bearing a common disease-associated mutation cannot. Together, we present the first animal model of RPSA-mediated asplenia and reveal a crucial requirement for RPSA in pre-rRNA processing and molecular patterning during early Xenopus development. Summary: Mutations in RPSA cause isolated congenital asplenia in humans; this paper presents the first animal model of RPSA-mediated asplenia and explores the role of RPSA in vertebrate spleen formation.

Visualization and quantification of injury to the ciliated epithelium using quantitative flow imaging and speckle variance optical coherence tomography

Mucociliary flow is an important defense mechanism in the lung to remove inhaled pathogens and pollutants. Disruption of ciliary flow can lead to respiratory infections. Multiple factors, from drugs to disease can cause an alteration in ciliary flow. However, less attention has been given to injury of the ciliated epithelium. In this study, we show how optical coherence tomography (OCT) can be used to investigate injury to the ciliated epithelium in a multi-contrast setting. We used particle tracking velocimetry (PTV-OCT) to investigate the cilia-driven flow field and 3D speckle variance imaging to investigate size and extent of injury caused to the skin of Xenopus embryos. Two types of injuries are investigated, focal injury caused by mechanical damage and diffuse injury by a calcium chloride shock. We additionally investigate injury and regeneration of cilia to calcium chloride on ex vivo mouse trachea. This work describes how OCT can be used as a tool to investigate injury and regeneration in ciliated epithelium.