Tianda Li

Simultaneous generation and germline transmission of multiple gene mutations in rat using CRISPR-Cas systems

Simultaneous generation and germline transmission of multiple gene mutations in rat using CRISPR-Cas systems

Microbiotic soil crust and its effect on vegetation and habitat on artificially stabilized desert dunes in Tengger Desert, North China

Abstract. We have conducted a long-term (from 1956 to 1999) rehabilitation experiment on mobile sand dunes in Tengger Desert, China, to investigate the chronological development of microbiotic soil crusts. We systematically analyzed the progression and development of the soil crusts by investigating the plant cover (herbs and shrubs), and some microorganism (mosses and algae), physical (particle size, saturated hydraulic conductivity and saturated water content) and chemical (major plant nutrients and organic matter) soil particles. The Limburg Soil Erosion Model was used to simulate infiltration and runoff. Three stages of microbiotic crust development occurred during the progressive stabilization of unconsolidated aeolian dunes, from 1956 to the present day: (1) raindrop impact and development of a non-biological crust; (2) crust enriched with mosses; (3) crust dominated by abundant algae, mosses and liverworts. It is considered that the most significant driving factor in the ecological development of microbiotic crusts in the Tengger Desert is the spatial variability of rainfall infiltration depth within the various soil layers occurring on, for example, dune top, leeward slopes, inter-dune depression (hollow) and windward slopes, immediately after a single individual rainfall event. Crust development leads to a change from shrubs to herbs because of decreased soil moisture in deeper soil layers.

Androgenetic haploid embryonic stem cells produce live transgenic mice

Haploids and double haploids are important resources for studying recessive traits and have large impacts on crop breeding, but natural haploids are rare in animals. Mammalian haploids are restricted to germline cells and are occasionally found in tumours with massive chromosome loss. Recent success in establishing haploid embryonic stem (ES) cells in medaka fish and mice raised the possibility of using engineered mammalian haploid cells in genetic studies. However, the availability and functional characterization of mammalian haploid ES cells are still limited. Here we show that mouse androgenetic haploid ES (ahES) cell lines can be established by transferring sperm into an enucleated oocyte. The ahES cells maintain haploidy and stable growth over 30 passages, express pluripotent markers, possess the ability to differentiate into all three germ layers in vitro and in vivo, and contribute to germlines of chimaeras when injected into blastocysts. Although epigenetically distinct from sperm cells, the ahES cells can produce viable and fertile progenies after intracytoplasmic injection into mature oocytes. The oocyte-injection procedure can also produce viable transgenic mice from genetically engineered ahES cells. Our findings show the developmental pluripotency of androgenentic haploids and provide a new tool to quickly produce genetic models for recessive traits. They may also shed new light on assisted reproduction.

Genetic modification and screening in rat using haploid embryonic stem cells.

The rat is an important animal model in biomedical research, but practical limitations to genetic manipulation have restricted the application of genetic analysis. Here we report the derivation of rat androgenetic haploid embryonic stem cells (RahESCs) as a tool to facilitate such studies. Our approach is based on removal of the maternal pronucleus from zygotes to generate androgenetic embryos followed by derivation of ESCs. The resulting RahESCs have 21 chromosomes, express pluripotency markers, differentiate into three germ layer cells, and contribute to the germline. Homozygous mutations can be introduced by both large-scale gene trapping and precise gene targeting via homologous recombination or the CRISPR-Cas system. RahESCs can also produce fertile rats after intracytoplasmic injection into oocytes and are therefore able to transmit genetic modifications to offspring. Overall, RahESCs represent a practical tool for functional genetic studies and production of transgenic lines in rat.

Generation and Application of Mouse-Rat Allodiploid Embryonic Stem Cells

Mammalian interspecific hybrids provide unique advantages for mechanistic studies of speciation, gene expression regulation, and X chromosome inactivation (XCI) but are constrained by their limited natural resources. Previous artificially generated mammalian interspecific hybrid cells are usually tetraploids with unstable genomes and limited developmental abilities. Here, we report the generation of mouse-rat allodiploid embryonic stem cells (AdESCs) by fusing haploid ESCs of the two species. The AdESCs have a stable allodiploid genome and are capable of differentiating into all three germ layers and early-stage germ cells. Both the mouse and rat alleles have comparable contributions to the expression of most genes. We have proven AdESCs as a powerful tool to study the mechanisms regulating X chromosome inactivation and to identify X inactivation-escaping genes, as well as to efficiently identify genes regulating phenotypic differences between species. A similar method could be used to create hybrid AdESCs of other distantly related species.

Induced Pluripotent Stem–Induced Cells Show Better Constitutive Heterochromatin Remodeling and Developmental Potential After Nuclear Transfer Than Their Parental Cells

Recently, reprogramming of somatic cells from a differentiated to pluripotent state by overexpression of specific external transcription factors has been accomplished. It has been widely speculated that an undifferentiated state may make donor cells more efficient for nuclear transfer. To test this hypothesis, we derived induced pluripotent stem cells (iPS cells) from several somatic cell lines: mouse embryonic fibroblast (MEF), adult tail tip fibroblast (TTF), and brain neural stem cells (NSCs). Three dimensional (3D)-fluorescent in situ hybridization (FISH) and quantitative-FISH (Q-FISH) were then used to evaluate constitutive (pericentric and telomeric) heterochromatin organization in these iPS cells and in their parental differentiated cells. Here, we show that important nuclear remodeling and telomeres rejuvenation occur in these iPS cells regardless of their parental origin. When we used these cells as donors for nuclear transfer, we produced live-born cloned mice at much higher rates with the iPS-induced cells than with the parental cell lines. Interestingly, we noticed that developmental potential after nuclear transfer could be correlated with telomere length of the donor cells. Altogether, our findings suggest that constitutive heterochromatin organization from differentiated somatic cells can be reprogrammed to the pluripotent state by induction of iPS cells, which in turn support nuclear transfer procedure quite efficiently.

Generation of Transgenic Rats through Induced Pluripotent Stem Cells

Background: Rat induced pluripotent stem cells (riPSCs) failed to produce transgenic rats. Results: We found that an optimized induction medium improved the efficiency of iPSC generation from rat somatic cells. The riPSCs could successfully generate transgenic rats. Conclusion: We could generate high quality riPSCs that could be used to produce transgenic rats. Significance: RiPSCs can be used as a novel tool in genetic and genomic studies of the rat. The rat is an important animal model for human disease research. Using inhibitors of glycogen synthase kinase 3 and MAPK signaling pathways, rat embryonic stem cells and rat induced pluripotent stem cells (riPSCs) have been derived. However, unlike rat embryonic stem cells, germ line competent riPSCs have only been derived from Wistar rats at low efficiency. Here, we found that an optimized induction medium containing knock-out serum replacement and vitamin C improved the rate and efficiency of riPSCs generation from Dark Agouti rat fibroblasts and Sertoli cells. riPSCs maintained an undifferentiated status for >30 passages and could differentiate into various cells types including germ cells when injected into rat blastocysts. Moreover, transgenic riPSCs could be generated through the PiggyBac transposon, which could be used to generate transgenic rats through germ line transmission. riPSCs can be used as a novel tool in genetic and genomic studies of the rat.

Efficient Production of Fluorescent Transgenic Rats using the piggyBac Transposon

Rats with fluorescent markers are of great value for studies that trace lineage-specific development, particularly those assessing the differentiation potential of embryonic stem cells (ESCs). The piggyBac (PB) transposon is widely used for the efficient introduction of genetic modifications into genomes, and has already been successfully used to produce transgenic mice and rats. Here, we generated transgenic rats carrying either the desRed fluorescent protein (RFP) gene or the enhanced green fluorescent protein (eGFP) gene by injecting pronuclei with PB plasmids. We showed that the transgenic rats expressed the RFP or eGFP gene in many organs and had the capability to transmit the marker gene to the next generation through germline integration. In addition, rat embryonic stem cells (ESCs) carrying an RFP reporter gene can be derived from the blastocysts of the transgenic rats. Moreover, the RFP gene can be detected in chimeras derived from RFP ESCs via blastocyst injection. This work suggests that PB-mediated transgenesis is a powerful tool to generate transgenic rats expressing fluorescent proteins with high efficiency, and this technique can be used to derive rat ESCs expressing a reporter protein.

Durable pluripotency and haploidy in epiblast stem cells derived from haploid embryonic stem cells in vitro

Haploid pluripotent stem cells, such as haploid embryonic stem cells (haESCs), facilitate the genetic study of recessive traits. In vitro, fish haESCs maintain haploidy in both undifferentiated and differentiated states, but whether mammalian haESCs can preserve pluripotency in the haploid state has not been tested. Here, we report that mouse haESCs can differentiate in vitro into haploid epiblast stem cells (haEpiSCs), which maintain an intact haploid genome, unlimited self-renewal potential, and durable pluripotency to differentiate into various tissues in vitro and in vivo. Mechanistically, the maintenance of self-renewal potential depends on the Activin/bFGF pathway. We further show that haEpiSCs can differentiate in vitro into haploid progenitor-like cells. When injected into the cytoplasm of an oocyte, androgenetic haEpiSC (ahaEpiSCs) can support embryonic development until midgestation (E12.5). Together, these results demonstrate durable pluripotency in mouse haESCs and haEpiSCs, as well as the valuable potential of using these haploid pluripotent stem cells in high-throughput genetic screening.

Generation of Mouse Haploid Somatic Cells by Small Molecules for Genome-wide Genetic Screening

The recent success of derivation of mammalian haploid embryonic stem cells (haESCs) has provided a powerful tool for large-scale functional analysis of the mammalian genome. However, haESCs rapidly become diploidized after differentiation, posing challenges for genetic analysis. Here, we show that the spontaneous diploidization of haESCs happens in metaphase due to mitotic slippage. Diploidization can be suppressed by small-molecule-mediated inhibition of CDK1 and ROCK. Through ROCK inhibition, we can generate haploid somatic cells of all three germ layers from haESCs, including terminally differentiated neurons. Using piggyBac transposon-based insertional mutagenesis, we generated a haploid neural cell library harboring genome-wide mutations for genetic screening. As a proof of concept, we screened for Mn2+-mediated toxicity and identified the Park2 gene. Our findings expand the applications of mouse haploid cell technology to somatic cell types and may also shed light on the mechanisms of ploidy maintenance.