Targeted DamID detects cell-type-specific histone modifications in intact tissues or organisms.

Histone modifications play a key role in regulating gene expression and cell fate during development and disease. Current methods for cell-type-specific genome-wide profiling of histone modifications require dissociation and isolation of cells and are not compatible with all tissue types. Here we adapt Targeted DamID (TaDa) to recognize specific histone marks, by fusing chromatin-binding proteins or single-chain antibodies to Dam, an Escherichia coli DNA adenine methylase.

Deterministic nuclear reprogramming of mammalian nuclei to a totipotency-like state by Amphibian meiotic oocytes for stem cell therapy in humans.

The ultimate aim of nuclear reprogramming is to provide stem cells or differentiated cells from unrelated cell types as a cell source for regenerative medicine. A popular route towards this is transcription factor induction, and an alternative way is an original procedure of transplanting a single somatic cell nucleus to an unfertilized egg. A third route is to transplant hundreds of cell nuclei into the germinal vesicle (GV) of a non-dividing Amphibian meiotic oocyte, which leads to the activation of silent genes in 24 h and robustly induces a totipotency-like state in almost all transplanted cells.

DNA-induced spatial entrapment of general transcription machinery can stabilize gene expression in a nondividing cell.

An important characteristic of cell differentiation is its stability. Only rarely do cells or their stem cell progenitors change their differentiation pathway. If they do, it is often accompanied by a malfunction such as cancer.

The initiation and maintenance of a differentiated state in development.

Proper function of the body is maintained by an intricate interaction and communication among cells. during the animal development how these cells are formed and maintained is an important yet elusive. Understanding of how cells such as muscle and nerve cells maintain their identities would enable us to control the diseases which include malfunctioning in cellular identities such as cancer.

A Brief History of in Biology.

is one of the premier model systems to study cell and developmental biology in vivo in vertebrates. Here we briefly review how this South African frog came to be favored by a large community of scientists after the explosive growth of molecular biology and examine some of the original discoveries arising from this sturdy frog. Experimental embryology started in but developed in newt embryos for historical reasons.

Injected cells provide a valuable complement to cell-free systems for analysis of gene expression.

The aim of this short review is to comment on the advantages of injecting purified molecules into a normal living cell as a complement to the constitution of a cell-free system for analyzing the function of cell components. We emphasize here that the major difference is that, by injection, most components of a cell are maintained at their normal concentration, which is difficult, even if at all possible, to achieve in a cell-free system. We exemplify the benefits of a cell injection system by the efficiency and long duration of DNA transcription by RNA polymerase II, as used by most genes, and by the widespread success of injecting purified messenger RNA for protein synthesis.

Epigenetic homogeneity in histone methylation underlies sperm programming for embryonic transcription.

Sperm contributes genetic and epigenetic information to the embryo to efficiently support development. However, the mechanism underlying such developmental competence remains elusive. Here, we investigated whether all sperm cells have a common epigenetic configuration that primes transcriptional program for embryonic development.

Long-term association of a transcription factor with its chromatin binding site can stabilize gene expression and cell fate commitment.

Some lineage-determining transcription factors are overwhelmingly important in directing embryonic cells to a particular differentiation pathway, such as for nerve. They also have an exceptionally strong ability to force cells to change from an unrelated pathway to one preferred by their action. Transcription factors are believed to have a very short residence time of only a few seconds on their specific DNA or chromatin-binding sites.

The myeloid lineage is required for the emergence of a regeneration-permissive environment following tail amputation.

Regeneration-competent vertebrates are considered to suppress inflammation faster than non-regenerating ones. Hence, understanding the cellular mechanisms affected by immune cells and inflammation can help develop strategies to promote tissue repair and regeneration. Here, we took advantage of naturally occurring tail regeneration-competent and -incompetent developmental stages of tadpoles.

Identification of a regeneration-organizing cell in the tail.

Unlike mammals, tadpoles have a high regenerative potential. To characterize this regenerative response, we performed single-cell RNA sequencing after tail amputation. By comparing naturally occurring regeneration-competent and -incompetent tadpoles, we identified a previously unrecognized cell type, which we term the regeneration-organizing cell (ROC).

Chromatin Accessibility Impacts Transcriptional Reprogramming in Oocytes.

Oocytes have a remarkable ability to reactivate silenced genes in somatic cells. However, it is not clear how the chromatin architecture of somatic cells affects this transcriptional reprogramming. Here, we investigated the relationship between the chromatin opening and transcriptional activation.

Custom-Made Oocytes to Clone Non-human Primates.

In this issue of Cell, Liu et al. (2018) report the birth of two healthy cloned macaque monkeys using fetal fibroblasts. By artificially enhancing the arsenal of epigenetic modifiers in the oocyte, the authors overcome the earliest roadblocks that take place during somatic cell nuclear transfer (SCNT).

Reprogramming towards totipotency is greatly facilitated by synergistic effects of small molecules.

Animal cloning has been achieved in many species by transplanting differentiated cell nuclei to unfertilized oocytes. However, the low efficiencies of cloning have remained an unresolved issue. Here we find that the combination of two small molecules, trichostatin A (TSA) and vitamin C (VC), under culture condition with bovine serum albumin deionized by ion-exchange resins, dramatically improves the cloning efficiency in mice and 15% of cloned embryos develop to term by means of somatic cell nuclear transfer (SCNT).

H3K4 Methylation-Dependent Memory of Somatic Cell Identity Inhibits Reprogramming and Development of Nuclear Transfer Embryos.

Vertebrate eggs can induce the nuclear reprogramming of somatic cells to enable production of cloned animals. Nuclear reprogramming is relatively inefficient, and the development of the resultant embryos is frequently compromised, in part due to the inappropriate expression of genes previously active in the donor nucleus. Here, we identify H3K4 methylation as a major epigenetic roadblock that limits transcriptional reprogramming and efficient nuclear transfer (NT).

Nuclear transplantation, the conservation of the genome, and prospects for cell replacement.

Initial nuclear transplantation experiments in Xenopus eggs provided the first evidence for the conservation of the genome after cellular differentiation. This Discovery-in-Context Review recounts the early experiments that led to successful nuclear transfer in amphibians and the establishment of totipotency of a differentiated cell and shows how these discoveries paved the way for similar cloning experiments in other organisms.

Cell Fate Determination by Transcription Factors.

Transcription factors fulfill a key role in the formation and maintenance of different cell-types during development. It is known that transcription factors largely dissociate from chromosomes during mitosis. We found, previously, that mitosis is also a time when somatic nuclei can be far more easily reprogrammed after nuclear transfer than the nuclei of interphase cells.

The Expression of TALEN before Fertilization Provides a Rapid Knock-Out Phenotype in Xenopus laevis Founder Embryos.

Recent advances in genome editing using programmable nucleases have revolutionized gene targeting in various organisms. Successful gene knock-out has been shown in Xenopus, a widely used model organism, although a system enabling less mosaic knock-out in founder embryos (F0) needs to be explored in order to judge phenotypes in the F0 generation. Here, we injected modified highly active transcription activator-like effector nuclease (TALEN) mRNA to oocytes at the germinal vesicle (GV) stage, followed by in vitro maturation and intracytoplasmic sperm injection, to achieve a full knock-out in F0 embryos.

Histone H3 lysine 9 trimethylation is required for suppressing the expression of an embryonically activated retrotransposon in Xenopus laevis.

Transposable elements in the genome are generally silenced in differentiated somatic cells. However, increasing evidence indicates that some of them are actively transcribed in early embryos and the proper regulation of retrotransposon expression is essential for normal development. Although their developmentally regulated expression has been shown, the mechanisms controlling retrotransposon expression in early embryos are still not well understood.

The Egg and the Nucleus: A Battle for Supremacy.

This brief introduction is followed by a published version of my Nobel Laureate lecture, re-published herein with the kind permission of the Nobel Foundation. Much has happened since my original research, for which that prize was awarded. Hence, I am pleased to offer a few thoughts about the future of my research and its possible impact on humankind.