Development, Growth & Differentiation

The lack of a widely accessible method for expressing genes of interest in wild-type embryos is the fundamental obstacle in understanding genetic regulation during embryonic development. In particular, only a few methods are available for introducing gene expression vectors into cells prior to neural tube closure, a period for the drastic development of many tissues. In this study, we present a simple technique for transferring vectors into the endo- and ectodermal cells of mouse embryos at E7.0 or E8.0 via in utero injection, without any specialized equipment. Using this technique, introduction of retroviruses can facilitate the labeling of cells in various tissues, including the brain, spinal cord, epidermis, and digestive and respiratory organs. As such, this technique can aid in analyzing the roles of genes of interest during endo- and ectodermal development prior to neural tube closure.

Primordial germ cells (PGC), the precursors of the germline, have unique cellular characteristics to undergo long-distance migration to the embryonic gonads and have the potential to differentiate into somatic cells. Among the animal models studying PGC development, the chicken PGCs are an ideal model, since it is a rare model in which long-term PGC cultivation is applicable. Although the cultural applicability of chicken PGC makes it attractive for revealing the PGC character and its developmental processes, some differences from endogenous PGCs are known, such as the remarkable up-regulation of cell proliferation and a lesser ability to reach the gonads. Understanding these differences at the molecular level is crucial. To this end, we first performed SMART-seq-based single-cell RNA sequencing to compare transcriptomes between endogenous PGCs and cultivated PGCs. Our results revealed that PGC cultivation causes a shift from a MYC-dependent to a MYCN-dependent gene regulatory network in PGCs, suggesting that this reprogramming contributes to the acquisition of proliferation ability and stem cell characteristics in cultivated PGCs. Additionally, our results suggest that the MYCN-dependent gene regulatory network increases the risk of somatic differentiation, particularly in neural fate, in cultivated PGCs. In addition, our transcriptome analysis identified new cell populations that show molecular character as intermediate cell states between germline and pluripotent cells from the early embryonic stage. Thus, our study provides fundamental molecular information to understand both the effects of PGC cultivation and the developmental process of chicken PGCs.

Choanoflagellate genetics has undergone rapid and impactful developments in the last decade. Currently, the primary method for genetic modification of choanoflagellates relies on proprietary nucleofection reagents to deliver transgenes for ectopic expression or CRISPR-Cas9 ribonucleoprotein complexes for targeted genome editing. The acquisition of proprietary buffers required for nucleofection can hamper advances in choanoflagellate research due to costs, shipping limitations, and restrictions that prevent buffer components from being optimized for understudied organisms. Therefore, we test whether a low-cost in-house electroporation buffer developed for other systems can replace the proprietary buffer currently used for choanoflagellate transfection. Here, we present an in-house buffer with transfection efficiency comparable to that of the previously established proprietary buffer. This work increases the accessibility of choanoflagellate genetics and can broaden research participation in investigating animal origins.

The gut peristaltic movement, a wave-like propagation of a local contraction, is important for the transportation and digestion of ingested materials. Among three types of cells, the enteric nervous system (ENS), smooth muscle cells, and interstitial cells of Cajal (ICCs), the ICCs have been thought to act as a pacemaker, and therefore it is important to decipher the cellular functions of ICCs for the understanding of gut peristalsis. c-Kit, a tyrosine kinase receptor, has widely been used as a marker for ICCs. Most studies with ICCs have been conducted in mammals using commercially available anti-c-Kit antibody. Recently, the chicken embryonic gut has emerged as a powerful model to study the gut peristalsis. However, since the anti-c-Kit antibody for mammals does not work for chickens, cellular mechanisms by which ICCs are regulated have largely been unexplored. Here, we report a newly raised polyclonal antibody against the chicken c-Kit protein. The specificity of the antibody was validated by both Western blotting analyses and immunocytochemistry. Co-immunostaining with the new antibody and anti- smooth muscle actin (SMA) antibody successfully visualized ICCs in the chicken developing hindgut in the circular muscle- and longitudinal muscle layers: as previously shown in mice, common progenitors of ICCs and smooth muscle cells at early stages were double positive for SMA and c-Kit, and at later stages, differentiated ICCs and smooth muscle cells exhibited only c-Kit and SMA, respectively. A novel ICC population was also found that radially extended from the submucosal layer to circular muscle layer. Furthermore, the new antibody delineated individual ICCs in a cleared hindgut. The antibody newly developed in this study will facilitate the study of peristaltic movement in chicken embryos.

Gene integration at site-specific loci, such as safe harbor regions for stable expression via transgenesis, is a critical approach for understanding the function of a gene in cells or animals. The AAVS1 locus is a well-known safe harbor site for human and mouse studies. In the present study, we found an AAVS1-like sequence in the porcine genome using the UCSC Genome Browser and designed TALEN and CRISPR/Cas9 to target AAVS1. The efficiency of CRISPR/Cas9 for targeting the AAVS1 locus in porcine cells was superior to that of TALEN. An AAVS1-targeting donor vector containing GFP was designed and cloned. We added a loxP-lox2272 cassette sequence to the donor vector for further exchange of various transgenes in the AAVS1-targeted cell line. The donor vector and CRISPR/Cas9 components targeting AAVS1 were transfected into a porcine fibroblast cell line. Targeted cells of CRISPR/Cas9-mediated homologous recombination were identified by antibiotic selection. Gene knock-in at the AAVS1 locus was confirmed by PCR analysis. To induce recombinase-mediated cassette exchange (RMCE), another donor vector containing the loxP-lox2272 cassette and inducible (Tet-on) Cre recombinase was cloned. The Cre-donor vector was transfected into the AAVS1-targeted cell line, and RMCE was induced by adding doxycycline to the culture medium. RMCE in porcine fibroblasts was confirmed using PCR analysis. In conclusion, gene targeting at the AAVS1 locus and RMCE in porcine fibroblasts was successful. This technology will be useful for future porcine transgenesis studies and the generation of stable transgenic pigs.

The embryonic shell field of mollusks first appears during gastrulation of the dorsal ectoderm and subsequently develops into the shell-secreting mantle in adult animals. Although several lines of evidence have revealed that this shell field lineage is exclusively derived from the second quartet (2q) of the 16-cell embryos, it is generally believed that the establishment of the shell field fate would be accomplished only after receiving inductive signals from the invaginated endoderm. Despite being accepted as a comprehensive model for molluskan shell field specification, the validity of this induction hypothesis remains questionable owing to the lack of clear experimental evidence and contradictory results. Here, we attempted to re-investigate the inductive role of the endoderm in shell field fate establishment in the limpet Nipponacmea fuscoviridis by experimentally disrupting cell-cell contacts between cell lineages after the 16-cell stage. First, we characterized the shell field cell population by performing two-color in situ hybridization. We characterized at least three cell populations in the developing shell field. Using single-cell transcriptome analysis, we identified several specific effector genes for each population, as well as transcription factor genes. Differentiation of each shell field population was inspected in 2q blastomeres isolated from other cells of the 16-cell embryos. Despite the absence of any interlineage interactions (including ectoderm-endoderm contacts), the expression of marker genes for each shell field population was observed in the isolated 2q fragments. In addition, the expression of several shell field genes was detected in embryos in which cytokinesis was blocked at the 16-cell stage. We concluded that the early process of shell field differentiation in the 2q lineage occurs mostly independently of the interactions with other lineages.

Urodele amphibians, Pleurodeles waltl and Ambystoma mexicanum, have organ-level regeneration capability, such as limb regeneration. Multipotent cells are induced by an endogenous mechanism in amphibian limb regeneration. It is well known that dermal fibroblasts receive regenerative signals and turn into multipotent cells, called blastema cells. However, the induction mechanism of the blastema cells from matured dermal cells was unknown. We previously found that BMP2, FGF2, and FGF8 (B2FF) could play sufficient roles in blastema induction in urodele amphibians. Here, we show that B2FF treatment can induce dermis-derived cells that can participate in multiple cell lineage in limb regeneration. We first established a newt dermis-derived cell line and confirmed that B2FF treatment on the newt cells provided plasticity in cellular differentiation in limb regeneration. Interspecies comparative analysis clarified that Pde4b upregulation by B2FF specifically took place in the newt cells. Blocking PDE4B signaling by Rolipram suppressed dermis-to-cartilage transformation and the mosaic knockout animals showed consistent results. Our results are a valuable insight into how dermal fibroblasts acquire multipotency during the early phase of limb regeneration via an endogenous program in amphibian limb regeneration.

In mammals, the transcription of transposable elements (TEs) is important for maintaining early embryonic development. Here, we systematically analyzed the expression characteristics of TE-derived transcripts in early embryos by constructing a database of TEs and transcriptome data from goats and using it to study the function of endogenous retroviruses (ERVs) in regulating early embryo development. We found that ERV1 made up the highest proportion of TE sequences and exhibited a stage-specific expression pattern during early embryonic development. Among ERV elements, ERV1 had the potential to encode the Gag protein domain to form virus-like particles (VLPs) in early goat embryos. Knockdown of ERV1_1_574 significantly reduced the embryo development rate and the number of trophoblast cells (P< 0.05). Transcriptome sequencing analysis of morula embryos showed that ERV1_1_574 mainly regulated the expression of genes related to embryo compaction and trophoblast cell differentiation, such as CX43 and CDX2. In summary, we found that ERV1 expression was essential for early embryonic development in goats through regulation of trophoblast cell differentiation.

The trigeminal is one of the best characterized sensory systems in amniotes. It comprises two populations of first-order sensory neurones: the trigeminal ganglion (TG) which are peripheral to the central nervous system and the mesencephalic trigeminal nucleus (MTN), the only sensory neurones that lie within the central nervous system in amniotes. Islet-1, a LIM homeodomain transcription factor which plays essential roles during embryogenesis, contributes to axon pathfinding of sensory neurons in the TG. However, if Islet-1 plays a similar role in the MTN neurones is unknown. To answer whether Islet-1 is as important for axon guidance in these centrally-located sensory neurons as it is for the peripherally-located TG neurones, we investigated the effect of disrupting Islet-1 on axonal pathfinding in the chick MTN. We employed in ovo electroporation to transfect short interfering RNA for Islet-1 (si-Islet-1) into the dorsal midbrain. Our findings showed that, within the central nervous system, Islet-1 knockdown did not affect axonal growth of MTN neurones. However, reduction of Islet-1 in dorsal midbrain cells led to disorganized axonal growth once outside the central nervous system. As a consequence, we observed an abnormal organisation in the maxillary division of the trigeminal nerve in these embryos.

In the embryonic neuroepithelium (NE), neural progenitor cells undergo cell cycle-dependent interkinetic nuclear migration (IKNM) along the apicobasal axis. Extensive IKNM supports increasing cell production rates per unit apical surface, as typically observed in the mammalian telencephalic NE. Apical nucleokinesis during the G2 phase is an essential premitotic event, but its occurrence has not yet been quantitatively analyzed at a large 3D scale with sufficient spatiotemporal resolution. Here, we comprehensively analyzed apically migrating nuclei/somata in reference to their surroundings from embryonic day (E)11 to E13 in the mouse telencephalon. The velocity of apical nucleokinesis decreased, with more frequent nuclear pausing occurring at E12 and E13, whereas the nuclear density in the middle NE zone (20-40 m deep) increased. This result, together with the results of Shh-mediated overproliferation experiments in which the nuclear density was increased in vivo at E11, suggests that apical nucleokinesis is physically influenced by the surrounding nuclei. Mean square displacement analysis for nuclei being passed by the apically migrating nuclei via horizontal sectioning in toto-recorded movies revealed that the "tissue fluidity" or physical permissiveness of the NE to apical nucleokinesis gradually decreased (E11 > E12 > E13). To further investigate the spatial relationship between preexisting mitoses and subsequent premitotic apical nucleokinesis, the horizontal distribution of mitoses was cumulatively ([~]3 hours) analyzed under in toto monitoring. The four-dimensional cumulative apical mitoses presented a "random", not "clustered" or "regular", distribution pattern throughout the period examined. These methodologies provide a basis for future comparative studies of interspecies differences.

Organelles in cells are appropriately positioned, despite crowding in the cytoplasm. However, our understanding of the force required to move large organelles, such as the nucleus, inside the cytoplasm is limited, in part owing to a lack of accurate methods for measurement. We devised a novel method to apply forces to the nucleus of living, wild-type Caenorhabditis elegans embryos to measure the force generated inside the cell. We utilized a centrifuge polarizing microscope (CPM) to apply centrifugal force and orientation-independent differential interference contrast (OI-DIC) microscopy to characterize the mass density of the nucleus and cytoplasm. The cellular forces moving the nucleus toward the cell center increased linearly at [~]14 pN/m depending on the distance from the center. The frictional coefficient was [~]1,100 pN s/m. The measured values were smaller than previously reported estimates for sea urchin embryos. The forces were consistent with the centrosome-organelle mutual pulling model for nuclear centration. Frictional coefficient was reduced when microtubules were shorter or detached from nuclei in mutant embryos, demonstrating the contribution of astral microtubules. Finally, the frictional coefficient was higher than a theoretical estimate, indicating the contribution of uncharacterized properties of the cytoplasm.

Understanding the functions of maternal effect genes during oocyte growth is essential for elucidating the mechanisms of oogenesis and early embryonic development. However, conventional gene knockout and conditional knockout approaches require extensive breeding and are time-consuming. Here, we present a rapid in vitro gene functional analysis system that combines microinjection of mRNA, siRNA and plasmid DNA into mouse secondary follicles with a two-step oocyte growth culture system. Mouse secondary follicles were subjected to microinjection of mCherry mRNA and subsequently cultured for 15 days to produce fully grown oocytes. mCherry fluorescence persisted throughout the oocyte growth period but declined rapidly after fertilization. Despite minor cellular damage occasionally caused by microinjection, injected follicles developed normally and retained developmental competence. To evaluate the efficiency of gene suppression, we introduced siRNA targeting Dnmt3l, which is abundantly expressed during oocyte growth phase. Although Dnmt3l deficiency is known not to affect oocyte growth, we observed that oocyte growth was maintained normally despite a marked reduction in endogenous Dnmt3l mRNA levels in our knockdown model. These results demonstrate that this method enables efficient manipulation of gene expression specifically during oocyte growth while preserving developmental competence, providing a versatile platform for rapid functional screening of maternal effect genes in vitro.

In this study, we demonstrate that mouse DLX2 binds to the Olig2 gene locus in mouse embryonic forebrain in vivo. We further confirm the specificity and the transcriptional repressive effect of the binding in vitro. Furthermore, loss of Dlx1/2 function leads to increased Olig2 expression in the ventral embryonic mouse forebrain in vivo. As well, we demonstrate that chicken DLX1 binds to one chicken Olig2 gene domain in vitro, and overexpression of Dlx1 is sufficient to repress Olig2 expression in the developing chicken forebrain in ovo. Chicken DLX1 with a mutation eliminating its DNA binding ability is unable to bind to the Olig2 probe in vitro, and abrogates its repressive function on Olig2 expression in ovo. Our results establish that Dlx1/2 is both necessary and sufficient to repress oligodendrocyte specification mediated via direct transcriptional inhibition of Olig2 expression in the developing vertebrate forebrain.

In the mammalian cerebellum, three types of astroglial cells--Bergmann glial cells (BGs), inner granule cell layer (IGL) astrocytes, and white matter (WM) astrocytes--arise in postnatal timing from two types of progenitors: Bergmann glia-like progenitors (BGLPs) and astrocyte-like progenitors (AsLPs). In contrast to AsLPs, which are commonly observed in other brain regions, BGLPs have not been well studied. Here we investigate their dynamic changes in number, their differentiation abilities and their gene expression profiles during cerebellar development. BGLPs and AsLPs decrease in number as development progresses from P0, and are almost absent by P10. We developed an electroporation-based method to investigate the progeny cells of BGLPs. We found that BGLPs at P6 differentiate into BGs and IGL astrocytes, but not into WM astrocytes, which is consistent with a previous report. However, BGLPs at P0 were observed to differentiate into not only BGs and IGL astrocytes, but also WM astrocytes, indicating that P0 BGLPs possess wider pluripotency than P6 BGLPs. By conducting spatial transcriptomic analysis of the cerebellum at P0 and P6 with over 5,000 probes (Xenium, 5k), we successfully obtained clusters corresponding to BGLPs at P0 and P6, respectively. Further informatics analyses suggested that P0 BGLPs exhibit more stem cell-like features, while P6 BGLPs show a shift toward BG-like characteristics. This study, which includes transcriptome big data, will contribute to understanding the differentiation of BGs and astrocytes, as well as other types of cells, during postnatal cerebellar development.

Teleost species possess complex caudal musculoskeletal systems. While mid-trunk muscles exhibit simple segmental patterns, several caudal skeletal muscles display intricate orientations in their muscle fibers. Due to this distinctive morphology, both early and recent researchers have studied the structure and development of the caudal musculoskeletal system. However, the early developmental origin of the cell populations within the caudal muscle system remains largely unknown. In this study, we performed lineage tracing of caudal muscle primordia in zebrafish using a transgenic line expressing EGFP in somite derivatives following tamoxifen induction. This approach allowed us to observe the specific cell populations that contribute to caudal muscle tissue formation at the early larval stage. By monitoring the growth of these labeled cells from the early larval stage, we identified the origins of muscle fibers in caudal fin muscles unique to teleosts, such as the adductor caudalis and flexor caudalis. Our findings provide descriptions that aid in understanding how fish-specialized caudal muscle structures were formed through the modification of developmental processes during evolution.

Rod photoreceptor formation in the postnatal mouse is a widely used model system for studying mammalian photoreceptor development. This experimental paradigm provides opportunities for both gain and loss-of-function studies which can be accomplished through in vivo plasmid delivery and electroporation. However, the cis-regulatory elements used to implement this approach have not been fully evaluated or optimized for the unique transcriptional environment of photoreceptors. Here we report that the use of a photoreceptor cis-regulatory element from the Crx gene in combination with broadly active promoter elements can increase the targeting of developing rod photoreceptors in the mouse. This can lead to greater reporter expression, as well as enhanced misexpression and loss-of-function phenotypes in these cells. This study also highlights the importance of identifying and testing relevant cis-regulatory elements when planning cell subtype specific experiments. The use of the specific hybrid elements in this study will provide a more efficacious gene delivery system to study mammalian photoreceptor formation.

Avian embryos can halt their development for long periods at low temperature in a process called diapause and successfully resume development when reincubated at maternal body temperature. Successful resumption of development depends on different factors, including temperature. We have recently shown that embryos that enter diapause at 18 {degrees}C present a significant reduction in their ability to develop normally when put back into incubation, compared to embryos entering diapause at 12 {degrees}C. However, the mechanisms underlying these differences are unknown. To address this question, transcriptome analysis was performed to compare the effect of diapause temperature on gene expression, and to identify pathways involved in the process. Genetic comparison and pathway-enrichment analysis revealed that TGF-{beta} and pluripotency-related pathways are differentially regulated at the two temperatures, with higher expression at 12 {degrees}C compared to 18 {degrees}C. Investigating the involvement of the TGF-{beta} pathway revealed an essential role for BMP4 in regulating the expression of the transcription factors Nanog and Id2, which are known to regulate pluripotency and self-renewal in embryonic stem cells. BMP4 gain- and loss-of-function experiments in embryos in diapause at the different temperatures revealed the main role of BMP4 in enabling resumption of normal development following diapause. Collectively, these findings identify molecular regulators that facilitate embryos ability to undergo diapause at different temperatures and resume a normal developmental program.

The maintenance of adult epithelial tissues, such as the lining of the intestine, depends on their periodical renewal. This is achieved through small populations of adult stem cells. Lgr5 serves as a marker for these cells. Here we report a novel non-variegated Lgr5 mouse model, which was generated via the CRISPR/Cas9 system. We show that this Lgr5-2A-CreERT2-2A-mOrange2 mouse line can be used for lineage tracing, as well as for directing gene expression to Lgr5+ cells. The introduction of the transgene affects neither the expression, nor the function of endogenous Lgr5. Therefore, this new tool will serve to mark and manipulate intestinal stem cells to gain new biological insights.

The periodic cartilage and smooth muscle structures in mammalian trachea are derived from tracheal mesoderm, and tracheal malformations result in serious respiratory defects in neonates. Here we show that canonical Wnt signaling in mesoderm is critical to confer trachea mesenchymal identity in human and mouse. Loss of {beta}-catenin in fetal mouse mesoderm caused loss of Tbx4+ tracheal mesoderm and tracheal cartilage agenesis. The Tbx4 expression relied on endodermal Wnt activity and its downstream Wnt ligand but independent of known Nkx2.1-mediated respiratory development, suggesting that bidirectional Wnt signaling between endoderm and mesoderm promotes trachea development. Repopulating in vivo model, activating Wnt, Bmp signaling in mouse embryonic stem cell (ESC)-derived lateral plate mesoderm (LPM) generated tracheal mesoderm containing chondrocytes and smooth muscle cells. For human ESC-derived LPM, SHH activation was required along with Wnt to generate proper tracheal mesoderm. Together, these findings may contribute to developing applications for human tracheal tissue repair.

Cerebellar neurons such as Purkinje cells (PCs) and granule cells (GCs) are differentiated from neural progenitors expressing proneural genes. Zebrafish mutants of proneural genes ptf1a and neurogenin1 showed a reduction or loss of PCs, GABAergic interneurons (INs), and reduced expression of GC progenitor genes atoh1a/b/c. Lineage tracing revealed that the ptf1a-expressing progenitors gave rise to PCs, INs, and a part of GCs in zebrafish. These data indicate that the ptf1a/neurognin1-expressing neural progenitors can generate a variety of cerebellar neurons. In this study, we found that genes encoding transcriptional regulators Foxp1b and Foxp4, as well as Skor1b and Skor2, which are reportedly expressed in PCs, were not expressed in ptf1a;neurogenin1 mutants. foxp1b;foxp4 mutants showed a strong reduction in PCs, while skor1b;skor2 mutants completely lacked PCs but instead displayed an increase in immature GCs. Misexpression of skor2 in GC progenitors expressing atoh1c suppressed GC fate. These data indicate that Foxp1b/4 and Skor1b/2 function as key transcriptional regulators in the initial step of PC differentiation from ptf1a/neurogenin1-expressing neural progenitors, while Skor1b and Skor2 control PC differentiation by suppressing their differentiation into GCs.