Systematic Comparison of Computational Tools for Sanger Sequencing-Based Genome Editing Analysis.

Successful genome editing depends on the cleavage efficiency of programmable nucleases (PNs) such as the CRISPR-Cas system. Various methods have been developed to assess the efficiency of PNs, most of which estimate the occurrence of indels caused by PN-induced double-strand breaks. In these methods, PN genomic target sites are amplified through PCR, and the resulting PCR products are subsequently analyzed using Sanger sequencing, high-throughput sequencing, or mismatch detection assays.

CRISPR-Cas9-Mediated Genome Modifications in Zebrafish.

CRISPR-Cas9 genome editing technology has been successfully applied to generate various genetic modifications in zebrafish. The CRISPR-Cas9 system, which originally consisted of three components, CRISPR RNA (crRNA), trans-activating crRNA (tracrRNA), and Cas9, efficiently induces DNA double-strand breaks (DSBs) at targeted genomic loci, often resulting in frameshift-mediated target gene disruption (knockout). However, it remains difficult to perform the targeted integration of exogenous DNA fragments (knock-in) with CRISPR-Cas9.

Key sequence features of CRISPR RNA for dual-guide CRISPR-Cas9 ribonucleoprotein complexes assembled with wild-type or HiFi Cas9.

Specific sequence features of the protospacer and protospacer-adjacent motif (PAM) are critical for efficient cleavage by CRISPR-Cas9, but current knowledge is largely derived from single-guide RNA (sgRNA) systems assessed in cultured cells. In this study, we sought to determine gRNA sequence features of a more native CRISPR-Cas9 ribonucleoprotein (RNP) complex with dual-guide RNAs (dgRNAs) composed of crRNA and tracrRNA, which has been used increasingly in recent CRISPR-Cas9 applications, particularly in zebrafish. Using both wild-type and HiFi SpCas9, we determined on-target cleavage efficiencies of 51 crRNAs in zebrafish embryos by assessing indel occurrence.

Efficient CRISPR-Cas9-Mediated Knock-In of Composite Tags in Zebrafish Using Long ssDNA as a Donor.

Despite the unprecedented gene editing capability of CRISPR-Cas9-mediated targeted knock-in, the efficiency and precision of this technology still require further optimization, particularly for multicellular model organisms, such as the zebrafish (). Our study demonstrated that an ∼200 base-pair sequence encoding a composite tag can be efficiently "knocked-in" into the zebrafish genome using a combination of the CRISPR-Cas9 ribonucleoprotein complex and a long single-stranded DNA (lssDNA) as a donor template. Here, we targeted the , , and genes to evaluate the knock-in efficiency of lssDNA donors with different structures in somatic cells of injected embryos and for their germline transmission.

HiBiT-qIP, HiBiT-based quantitative immunoprecipitation, facilitates the determination of antibody affinity under immunoprecipitation conditions.

The affinity of an antibody for its antigen serves as a critical parameter for antibody evaluation. The evaluation of antibody-antigen affinity is essential for a successful antibody-based assay, particularly immunoprecipitation (IP), due to its strict dependency on antibody performance. However, the determination of antibody affinity or its quantitative determinant, the dissociation constant (K), under IP conditions is difficult.

Cooperation of Sall4 and Sox8 transcription factors in the regulation of the chicken Sox3 gene during otic placode development.

To elucidate the transcriptional regulation that underlies specification of the otic placode, we investigated the Sox3 downstream enhancer Otic1 of the chicken, the activity of which is restricted to and distributed across the entire otic placode. The 181-bp Otic1 enhancer sequence was dissected into a 68-bp minimal activating sequence, which exhibited dimer enhancer activity in the otic placode and cephalic neural crest, and this was further reduced to a 25-bp Otic1 core sequence, which also showed octamer enhancer activity in the same regions. The Otic1 core octamer was activated by the combined action of Sall4 and the SoxE transcription factors (TFs) Sox8 or Sox9.

Regulation of trunk neural crest delamination by δEF1 and Sip1 in the chicken embryo.

The vertebrate Zfhx1 transcription factor family comprises δEF1 and Sip1, which bind to CACCT-containing sequences and act as transcriptional repressors. It has been a longstanding question whether these transcription factors share the same regulatory functions in vivo. It has been shown that neural crest (NC) delamination depends on the Sip1 activity at the cranial level in mouse and chicken embryos, and it remained unclear how NC delamination is regulated at the trunk level.

Nano-analysis of DNA conformation changes induced by transcription factor complex binding using plasmonic nanodimers.

The plasmon resonant wavelength for a pair of gold nanoparticles, or gold nanodimer, increases inversely with the gap distance between the two nanoparticles. Taking advantage of this property, we performed nanoscale measurements of DNA conformation changes induced by transcription factor binding. Gold nanoparticles were bridged by double-stranded DC5 DNA that included binding sequences for the transcription factors SOX2 and PAX6, which interact on the DC5 enhancer sequence and activate transcription.

Sox proteins: regulators of cell fate specification and differentiation.

Sox transcription factors play widespread roles during development; however, their versatile funtions have a relatively simple basis: the binding of a Sox protein alone to DNA does not elicit transcriptional activation or repression, but requires binding of a partner transcription factor to an adjacent site on the DNA. Thus, the activity of a Sox protein is dependent upon the identity of its partner factor and the context of the DNA sequence to which it binds. In this Primer, we provide an mechanistic overview of how Sox family proteins function, as a paradigm for transcriptional regulation of development involving multi-transcription factor complexes, and we discuss how Sox factors can thus regulate diverse processes during development.

An efficient binary system for gene expression in the silkworm, Bombyx mori, using GAL4 variants.

A binary gene expression system using the yeast GAL4 DNA-binding protein and the upstream activating sequence (UAS) of galactose-driven yeast genes is an established and powerful tool for the analysis of gene function. However, in the domesticated silkworm, Bombyx mori, this system has been limited in its utility by the relatively low transcriptional activation activity of GAL4 and by its toxicity. In this study, we investigated the potential of several established GAL4 variants (GAL4Δ, GAL4VP16, GAL4VPmad2, GAL4VPmad3, and GAL4NFκB) and of two new GAL4 variants, GAL4Rel and GAL4Relish, which contain the transcription-activating regions of the BmRel and BmRelish genes, respectively, to improve the utility of the GAL4/UAS system in B.

The Pou5f1/Pou3f-dependent but SoxB-independent regulation of conserved enhancer N2 initiates Sox2 expression during epiblast to neural plate stages in vertebrates.

The transcription factor Sox2 is a core component of the pluripotency control circuits in the early embryo, and later controls many aspects of neural development. Here, we demonstrate that Sox2 expression in the epiblast (mouse blastoderm) and anterior neural plate (ANP) is determined by the upstream enhancer N2. The mouse enhancer N2 exhibits strong activity in mouse ES cells, epiblast and ANP, and is regulated correctly in chicken and zebrafish embryos.

B1 SOX coordinate cell specification with patterning and morphogenesis in the early zebrafish embryo.

The B1 SOX transcription factors SOX1/2/3/19 have been implicated in various processes of early embryogenesis. However, their regulatory functions in stages from the blastula to early neurula remain largely unknown, primarily because loss-of-function studies have not been informative to date. In our present study, we systematically knocked down the B1 sox genes in zebrafish.

SOX-partner code for cell specification: Regulatory target selection and underlying molecular mechanisms.

Transcriptional regulatory functions of SOX proteins generally require the cooperation of partner factors that bind DNA in the vicinity of the SOX site. Each SOX-partner pair selects a specific group of regulatory target genes, with resultant gene expression patterns characterizing a particular cell differentiation state. Specific examples include the SOX2-OCT3/4 pairing in ES cells and the SOX2-PAX6 pairing in visual system primordia.

Analysis of protein interactions with two-hybrid system in cultured insect cells.

Many biological processes are usually coupled to the formation of protein complexes. The yeast two-hybrid system is a powerful tool for analyzing protein-protein interactions. Different patterns of protein modifications, such as glycosylation, phosphorylation, and acetylation, may affect the ability of proteins to interact.

Evolution of non-coding regulatory sequences involved in the developmental process: reflection of differential employment of paralogous genes as highlighted by Sox2 and group B1 Sox genes.

In higher vertebrates, the expression of Sox2, a group B1 Sox gene, is the hallmark of neural primordial cell state during the developmental processes from embryo to adult. Sox2 is regulated by the combined action of many enhancers with distinct spatio-temporal specificities. DNA sequences for these enhancers are conserved in a wide range of vertebrate species, corresponding to a majority of highly conserved non-coding sequences surrounding the Sox2 gene, corroborating the notion that the conservation of non-coding sequences mirrors their functional importance.

Adaptation of GAL4 activators for GAL4 enhancer trapping in zebrafish.

An enhancer trap-based GAL4-UAS system in zebrafish requires strong GAL4 activators with minimal adverse effects. However, the activity of yeast GAL4 is too low in zebrafish, while a fusion protein of the GAL4 DNA-binding domain and the VP16 activation domain is toxic to embryonic development, even when expressed at low levels. To alleviate this toxicity, we developed variant GAL4 activators by fusing either multimeric forms of the VP16 minimal activation domain or the NF-kappaB activation domain to the GAL4 DNA-binding domain.

Comparative genomics approach to the expression of figalpha, one of the earliest marker genes of oocyte differentiation in medaka (Oryzias latipes).

We analyzed molecular cascades of sex differentiation in medaka gonads by examining the transcriptional regulation of the oocyte-expressed gene, figalpha. We first confirmed that figalpha is one of the earliest marker genes of oocyte differentiation by quantitative RT-PCR and in situ hybridization. Expression of putative figalpha target genes, zpc4 and zpb, followed that of figalpha.

Quantitative assessment of the knockdown efficiency of morpholino antisense oligonucleotides in zebrafish embryos using a luciferase assay.

Despite the broad use of morpholino antisense oligonucleotides (MO) to knockdown gene function in zebrafish embryos, the efficiency of this method has not been successfully assessed, particularly in the cases of translation-blocking MOs. In our current study, we describe a luciferase assay-based system that can monitor the MO knockdown levels in zebrafish by the use of a fusion reporter construct containing the 5'-mRNA sequence of the gene of interest and the luciferase coding sequence. The decrease in luciferase activity in zebrafish embryos that have been coinjected with this reporter RNA construct and a MO that targets the gene of interest correlated well with the level of inhibition of the corresponding endogenous protein synthesis, and also with the appearance of a knockdown phenotype.

PAX6 and SOX2-dependent regulation of the Sox2 enhancer N-3 involved in embryonic visual system development.

Sox2 is universally expressed in the neural and placodal primordia in early stage embryos, and this expression depends on various phylogenetically conserved enhancers having different regional and temporal specificities. The enhancer N-3 was identified as a regulator of the Sox2 gene active in the diencephalon, optic vesicle, and after the contact of the vesicle with the ectoderm, in the lens placodal surface area, suggesting its involvement in embryonic visual system development. A 36-bp minimal essential core sequence was defined in the 568-bp-long enhancer N-3, which in a tetrameric form emulates the original enhancer activity.

Hypogonadotropic hypogonadism in an adult female with a heterozygous hypomorphic mutation of SOX2.

Objective: Heterozygous SOX2 mutations have recently been reported to cause isolated hypogonadotropic hypogonadism (HH), in addition to ocular and brain abnormalities. Here, we report a further case with a heterozygous hypomorphic SOX2 mutation and isolated HH.

Patient: The patient was a 28-year-old Japanese female with congenital right anophthalmia and poor pubertal development, who was found to have HH by a gonadotropin-releasing hormone test (peak serum LH, 2.

Triggering neural differentiation of ES cells by subtype switching of importin-alpha.

Nuclear proteins are selectively imported into the nucleus by transport factors such as importin-alpha and importin-beta. Here, we show that the expression of importin-alpha subtypes is strictly regulated during neural differentiation of mouse embryonic stem (ES) cells, and that the switching of importin-alpha subtype expression is critical for neural differentiation. Moreover, reproducing the switching of importin-alpha subtype expression in undifferentiated ES cells induced neural differentiation in the presence of leukaemia inhibitory factor (LIF) and serum, coordinated with the regulated expression of Oct3/4, Brn2 and SOX2, which are involved in ES-neural identity determination.

Comparative genomic and expression analysis of group B1 sox genes in zebrafish indicates their diversification during vertebrate evolution.

Group B1 Sox genes encode HMG domain transcription factors that play major roles in neural development. We have identified six zebrafish B1 sox genes, which include pan-vertebrate sox1a/b, sox2, and sox3, and also fish-specific sox19a/b. SOX19A/B proteins show a transcriptional activation potential that is similar to other B1 SOX proteins.

Convergence of Wnt and FGF signals in the genesis of posterior neural plate through activation of the Sox2 enhancer N-1.

The expression of the transcription factor gene Sox2 precisely marks the neural plate in various vertebrate species. We previously showed that the Sox2 expression prevailing in the neural plate of chicken embryos is actually regulated by the coordination of five phylogenetically conserved enhancers having discrete regional coverage, among which the 420-bp long enhancer N-1, active in the node-proximal region, is probably involved directly in the genesis of the posterior neural plate. We investigated the signaling systems regulating this enhancer, first identifying the 56-bp N-1 core enhancer (N-1c), which in a trimeric form recapitulates the activity of the enhancer N-1.

Multiple N-cadherin enhancers identified by systematic functional screening indicate its Group B1 SOX-dependent regulation in neural and placodal development.

Neural plate and sensory placodes share the expression of N-cadherin and Group B1 Sox genes, represented by Sox2. A 219-kb region of the chicken genome centered by the N-cadherin gene was scanned for neural and placodal enhancers. Random subfragments of 4.