The emergence of human gastrulation upon in vitro attachment.

While studied extensively in model systems, human gastrulation remains obscure. The scarcity of fetal biological material as well as ethical considerations limit our understanding of this process. In vitro attachment of natural blastocysts shed light on aspects of the second week of human development in the absence of the morphological manifestation of gastrulation. Stem cell-derived blastocyst models, blastoids, provide the opportunity to reconstitute pre- to post-implantation development in vitro. Here we show that upon in vitro attachment, human blastoids self-organize a BRA+ population and undergo gastrulation. Single-cell RNA sequencing of these models replicates the transcriptomic signature of the human gastrula. Analysis of developmental timing reveals that in both blastoid models and natural human embryos, the onset of gastrulation as defined by molecular markers, can be traced to timescales equivalent to 12 days post fertilization. In all, natural human embryos and blastoid models self-organize primitive streak and mesoderm derivatives upon in vitro attachment.

Report of the Assay Guidance Workshop on 3-Dimensional Tissue Models for Antiviral Drug Development.

The National Center for Advancing Translational Sciences (NCATS) Assay Guidance Manual (AGM) Workshop on 3D Tissue Models for Antiviral Drug Development, held virtually on 7-8 June 2022, provided comprehensive coverage of critical concepts intended to help scientists establish robust, reproducible, and scalable 3D tissue models to study viruses with pandemic potential. This workshop was organized by NCATS, the National Institute of Allergy and Infectious Diseases, and the Bill and Melinda Gates Foundation. During the workshop, scientific experts from academia, industry, and government provided an overview of 3D tissue models' utility and limitations, use of existing 3D tissue models for antiviral drug development, practical advice, best practices, and case studies about the application of available 3D tissue models to infectious disease modeling. This report includes a summary of each workshop session as well as a discussion of perspectives and challenges related to the use of 3D tissues in antiviral drug discovery.

Self-organization of human dorsal-ventral forebrain structures by light induced SHH.

Organizing centers secrete morphogens that specify the emergence of germ layers and the establishment of the body's axes during embryogenesis. While traditional experimental embryology tools have been instrumental in dissecting the molecular aspects of organizers in model systems, they are impractical in human in-vitro model systems to dissect the relationships between signaling and fate along embryonic coordinates. To systematically study human embryonic organizer centers, we devised a collection of optogenetic ePiggyBac vectors to express a photoactivatable Cre-loxP recombinase, that allows the systematic induction of organizer structures by shining blue-light on human embryonic stem cells (hESCs). We used a light stimulus to geometrically confine SHH expression in neuralizing hESCs. This led to the self-organization of mediolateral neural patterns. scRNA-seq analysis established that these structures represent the dorsal-ventral forebrain, at the end of the first month of development. Here, we show that morphogen light-stimulation is a scalable tool that induces self-organizing centers.

Synthetic by design: Exploiting tissue self-organization to explore early human embryology.

Recent advances in synthetic human embryology has provided a previously inexistent molecular portrait of human development. Models of synthetic human embryonic tissues capitalize on the self-organizing capabilities of human embryonic stem cells when they are cultured on biomimetic conditions that simulate in vivo human development. In this Review, we discuss these models and how they have shed light on the early stages of human development including amniotic sac development, gastrulation and neurulation. We discuss the mechanisms underlying the molecular logic of embryonic tissue self-organization that have been dissected using synthetic models of human embryology and explore future challenges in the field. Geared with technological advances in bioengineering, high resolution gene expression and imaging tools, these models are set to transform our understanding of the mechanistic basis of embryonic tissue self-organization during human development and how they may go awry in disease.

Gastruloids Gain Muscle: Somite Formation in Embryo-Like Structures.

Gastruloids are embryo-like structures that display key features of post-implantation embryonic development, yet whether they fully recapitulate in vivo embryogenesis remains unsolved. Recently in Nature, van den Brink et al. (2020) performed high-resolution gene expression analysis to identify significant similarities between mouse gastruloids and embryos in positional lineage segregation and somite formation.

Identification of a LIF-Responsive, Replication-Competent Subpopulation of Human ß Cells.

The beta (ß)-cell mass formed during embryogenesis is amplified by cell replication during fetal and early postnatal development. Thereafter, ß cells become functionally mature, and their mass is maintained by a low rate of replication. For those few ß cells that replicate in adult life, it is not known how replication is initiated nor whether this occurs in a specialized subset of ß cells. We capitalized on a YAP overexpression system to induce replication of stem-cell-derived ß cells and, by single-cell RNA sequencing, identified an upregulation of the leukemia inhibitory factor (LIF) pathway. Activation of the LIF pathway induces replication of human ß cells in vitro and in vivo. The expression of the LIF receptor is restricted to a subset of transcriptionally distinct human ß cells with increased proliferative capacity. This study delineates novel genetic networks that control the replication of LIF-responsive, replication-competent human ß cells.

YAP inhibition enhances the differentiation of functional stem cell-derived insulin-producing ß cells.

Stem cell-derived insulin-producing beta cells (SC-ß) offer an inexhaustible supply of functional ß cells for cell replacement therapies and disease modeling for diabetes. While successful directed differentiation protocols for this cell type have been described, the mechanisms controlling its differentiation and function are not fully understood. Here we report that the Hippo pathway controls the proliferation and specification of pancreatic progenitors into the endocrine lineage. Downregulation of YAP, an effector of the pathway, enhances endocrine progenitor differentiation and the generation of SC-ß cells with improved insulin secretion. A chemical inhibitor of YAP acts as an inducer of endocrine differentiation and reduces the presence of proliferative progenitor cells. Conversely, sustained activation of YAP results in impaired differentiation, blunted glucose-stimulated insulin secretion, and increased proliferation of SC-ß cells. Together these results support a role for YAP in controlling the self-renewal and differentiation balance of pancreatic progenitors and limiting endocrine differentiation in vitro.

A START-domain-containing protein is a novel marker of nervous system components of the sea cucumber Holothuria glaberrima.

One of the main challenges faced by investigators studying the nervous system of members of the phylum Echinodermata is the lack of markers to identify nerve cells and plexi. Previous studies have utilized an antibody, RN1, that labels most of the nervous system structures of the sea cucumber Holothuria glaberrima and other echinoderms. However, the antigen recognized by RN1 remained unknown. In the present work, the antigen has been characterized by immunoprecipitation, tandem mass spectrometry, and cDNA cloning. The RN1 antigen contains a START lipid-binding domain found in Steroidogenic Acute Regulatory (StAR) proteins and other lipid-binding proteins. Phylogenetic tree assembly showed that the START domain is highly conserved among echinoderms. We have named this antigen HgSTARD10 for its high sequence similarity to the vertebrate orthologs. Gene and protein expression analyses revealed an abundance of HgSTARD10 in most H. glaberrima tissues including radial nerve, intestine, muscle, esophagus, mesentery, hemal system, gonads and respiratory tree. Molecular cloning of HgSTARD10, consequent protein expression and polyclonal antibody production revealed the STARD10 ortholog as the antigen recognized by the RN1 antibody. Further characterization into this START domain-containing protein will provide important insights for the biochemistry, physiology and evolution of deuterostomes.