Minimal in vitro systems composed of embryonic stem cells (ESCs) have been shown to recapitulate the establishment of the anteroposterior (AP) axis. In contrast to the native embryo, ESC aggregates - such as gastruloids - can break symmetry, which is demarcated by polarization of the mesodermal marker T, autonomously without any localized external cues. However, associated earliest patterning events, such as the spatial restriction of cell fates and concomitant transcriptional changes, remain poorly understood. Here, we dissect the dynamics of AP axis establishment in mouse gastruloids, particularly before external Wnt stimulation. Through single-cell RNA sequencing, we identify key cell state transitions and the molecular signatures of T+ and T- populations underpinning AP polarization. We also show that this process is robust to modifications of aggregate size. Finally, transcriptomic comparison with the mouse embryo indicates that gastruloids develop similar mesendodermal cell types, despite initial differences in their primed pluripotent populations, which adopt a more mesenchymal state in lieu of an epiblast-like transcriptome. Hence, our findings suggest the possibility of alternate ESC states in vivo and in vitro that can converge onto similar cell fates.

A vertebrate embryo undergoes gastrulation, wherein it reorganises into a structure with three germ layers and three distinct body axes. Here, Vikas Trivedi and colleagues investigate spatial patterning of germ layers in the absence of external cues. To find out more about their work, we spoke to the first author, Kerim Anlaş, and the corresponding author, Vikas Trivedi, Research Group Leader and Co-Chair of Theory Transversal Theme at European Molecular Biology Laboratory (EMBL), Barcelona, Spain.

Cell competition arises in heterogeneous tissues when neighbouring cells sense their relative fitness and undergo selection. It has been a challenge to define contexts in which cell competition is a physiologically relevant phenomenon and to understand the cellular features that underlie fitness and fitness sensing. Drawing on examples across a range of contexts and length scales, we illuminate molecular and cellular features that could underlie fitness in diverse tissue types and processes to promote and reinforce long-term maintenance of tissue function. We propose that by broadening the scope of how fitness is defined and the circumstances in which cell competition can occur, the field can unlock the potential of cell competition as a lens through which heterogeneity and its role in the fundamental principles of complex tissue organisation can be understood.

Ednrb is specifically required to develop neural crest (NC) stem cell-derived lineages. However, it is still unknown why Ednrb signaling is only needed for the early development of melanoblasts in the skin and eye. We show that Ednrb is required for the proliferation of melanoblasts during early mouse development. To understand the mechanism of melanoblast proliferation, we found that the gene absent in melanoma 2 (Aim2) is upregulated in Ednrb-deficient NC cells by RNA-sequencing analysis. Consequently, the knockdown or knockout of Aim2 partially rescued the proliferation of Ednrb-deficient melanoblasts. Conversely, the overexpression of Aim2 in melanoblasts suppressed their proliferation. We further show that Ednrb signaling could act through the microRNA miR-196b to block the suppression of melanoblast proliferation by Aim2 in primary NC cell cultures. These results reveal the Ednrb-Aim2-AKT axis in regulating melanocyte development and suggest that Ednrb signaling functions as a negative regulator of Aim2, which inhibits the proliferation of melanoblasts in early development. These findings uncover a previously unreported role for Aim2 outside the inflammasome, showing that it is a significant regulator controlling NC stem cell-derived lineage development.

A remarkable feature of limb regeneration is the ability to regenerate normal limb morphology and anatomical patterning. Although it is thought that regeneration uses similar mechanisms to those employed during development, it is not well understood how this is achieved in the context of varying blastema size. In a new study, Akira Satoh, Yoshihiro Morishita and colleagues investigate the allometric scaling of blastema size and pattern expressions of key genes relative to the size of the limb stump in axolotls. To find out more about the work, we caught up with first author Saya Furukawa, and corresponding authors Akira Satoh, professor at Okayama University, and Yoshihiro Morishita, Principal Investigator at RIKEN, Japan.

Synaptogenesis involves the transformation of dendritic filopodial contacts into stable connections with the exact apposition of synaptic components. Signalling triggered by Wnt/β-catenin and calcium has been postulated to aid this process. However, it is unclear how such a signalling process orchestrates synapse formation to organise the spatial arrangement of synapses along dendrites. We show that Wnt7a is loaded on dynamic dendritic filopodia during spine formation in human cortical neurons. Wnt7a is present at the tips of the filopodia and the contact sites with dendrites of neighbouring neurons, triggering spatially restricted localisation of the Wnt co-receptor Lrp6. Here, we find the induction of calcium transients, the clustering of pre- and postsynaptic proteins, and the subsequent transformation into mature spines. Although soluble Wnt7a protein can also support synaptogenesis, it fails to provide this degree of spatial information for spine formation and calcium transients and synaptic markers are induced ectopically along the dendrites. Our data suggest that dendritic filopodia are Wnt7a-bearing cytonemes required for focal calcium signalling, initiate synapse formation, and provide an elegant mechanism for orchestrating the positioning of synapses along dendrites.

Developmental signaling inputs are fundamental for shaping cell fates and behavior. However, traditional fluorescent-based signaling reporters have limitations in scalability and molecular resolution of cell types. We present SABER-seq, a CRISPR-Cas molecular recorder that stores transient developmental signaling cues as permanent mutations in cellular genomes for deconstruction at later stages via single-cell transcriptomics. We applied SABER-seq to record Notch signaling in developing zebrafish brains. SABER-seq has two components: a signaling sensor and a barcode recorder. The sensor activates Cas9 in a Notch-dependent manner with inducible control while the recorder obtains mutations in ancestral cells where Notch is active. We combine SABER-seq with an expanded juvenile brain atlas to identify cell types derived from Notch-active founders. Our data reveals rare examples where differential Notch activities in ancestral progenitors are detected in terminally differentiated neuronal subtypes. SABER-seq is a novel platform for rapid, scalable and high-resolution mapping of signaling activity during development.

The Mediator complex plays a pivotal role in facilitating RNA polymerase II-dependent transcription in eukaryotes. Within this complex, the CDK8 kinase module (CKM), comprising CDK8, Cyclin C (CycC), Med12, and Med13, serves as a dissociable subcomplex that modulates the activity of the small Mediator complex. Genetic studies in Drosophila have revealed distinct phenotypes associated with mutations in CKM subunits, but the underlying mechanisms have remained unclear. Using Drosophila as a model, we generated transgenic strains to individually or simultaneously deplete the four CKM subunits in all possible combinations, uncovering unique phenotypes in the eyes and wings. Depletion of CDK8-CycC enhanced E2F1 target gene expression and promoted cell-cycle progression, whereas Med12-Med13 depletion had no significant impact on these processes. Instead, depleting Med12-Med13 altered the expression of ribosomal protein genes and fibrillarin, reduced nascent protein synthesis, indicating a severe reduction in ribosome biogenesis and cellular growth compared to the loss of CDK8-CycC. These findings reveal distinct in vivo roles for CKM subunits, with Med12-Med13 disruption having a more pronounced effect on ribosome biogenesis and protein synthesis than CDK8-CycC loss.

Cellular retinoic acid (RA) binding proteins (Crabps) solubilize intracellular RA and transport it to its nuclear receptors or cytoplasmic degradation enzymes. Despite their extreme conservation across chordates, genetic studies of Crabp function have revealed few essential functions. We have generated loss-of-function mutations in all four zebrafish Crabps and find essential roles for Crabp2s in gonad development and sex determination. Transgenic RA reporters show strong RA-responses in germ cells at the bipotential stage of gonad development. Double mutants lacking the functions of both Crabp2a and Crabp2b predominantly become male, which correlates with their smaller gonad size and reduced germ cell proliferation during gonad development at late larval and early juvenile stages. In contrast, mutants lacking the functions of both Crabp1a and Crabp1b have normal sex ratios. Exogenous RA treatments at bipotential gonad stages increase germ cell number, consistent with a direct role for RA in promoting germ cell proliferation. Our results suggest essential functions for Crabps in gonad development and sex determination.

The proneural transcription factor ASCL1 regulates neurogenesis and drives somatic cell reprogramming into neurons. However, not all cell types can be reprogrammed by ASCL1, raising the questions of what provides competence and how we can overcome barriers to enable directed differentiation. Here, we investigate how levels of ASCL1 and its phosphorylation modulate its activity over progressive lineage restriction of embryonic stem cells. We find that inhibition of ASCL1 phosphorylation enhances reprogramming of both mesodermal and neuroectodermal cells, while pluripotent cells remain refractory to ASCL1-directed neuronal differentiation. By performing RNA-seq and ATAC-seq in neuroectoderm, we find that un(der)phosphorylated ASCL1 causes increased chromatin accessibility at sites proximal to neuronal genes, accompanied by their increased expression. Combined analysis of protein stability and proneural function of phosphomutant and phosphomimetic ASCL1 reveals that protein stability plays only a marginal role in regulating activity, while changes in amino acid charge cannot fully explain enhanced activity of the serine-proline mutant variants of ASCL1. Our work provides new insights into proneural factor activity and regulation and suggests ways to optimize reprogramming protocols in cancer and regenerative medicine.

In the vertebrate nervous system, neurogenesis generally precedes gliogenesis. The mechanisms driving the switch in cell type production and generation of the correct proportion of cell types remain unclear. Here, we show that Fgf20 signalling patterns progenitors to induce the switch from neurogenesis to oligodendrogenesis in the zebrafish hindbrain. Fgf20 emanating from earlier-born neurons signals at a short range to downregulate proneural gene expression in the segment centre with high spatial precision along both anterior-posterior (AP) and dorsal-ventral (DV) axes. This signal induces oligodendrocytes in the segment centre by upregulating olig2 and sox10 expression in pre-patterned competent progenitors. We show that the magnitude of proneural gene downregulation and the quantity of OPCs specified is dependent on the extent of Fgf20 signalling. Overexpression of fgf20a induces precocious specification and differentiation of oligodendrocytes among olig2+ progenitors, resulting in an increase in oligodendrocytes at the expense of neurogenesis. Thus, Fgf20 signalling defines the proportion of each cell type produced. Taken together, Fgf20 signalling from earlier-born neurons patterns hindbrain segments spatially and temporally to induce the neurogenesis-to-oligodendrogenesis switch.

Paired locomotion appendages are hypothesized to have redeployed the developmental program of median appendages, such as the dorsal and anal fins. Compared with paired fins, and limbs, median appendages remain surprisingly understudied. Here, we report that a dominant zebrafish mutant, smoothback(smb), fails to develop a dorsal fin. Moreover, the anal fin is reduced along the antero-posterior axis, and spine defects develop. Mechanistically, smb is caused by an insertion of a sox10:Gal4VP16transgenic construct into a non-coding region. The first step in fin, and limb, induction is aggregation of undifferentiated mesenchyme at the appendage development site. In smb, this dorsal fin mesenchyme is absent. Lineage tracing demonstrates the previously unknown developmental origin of the mesenchyme, the sclerotome, which also gives rise to the spine. Strikingly, we find that there is significantly less sclerotome in smb compared to wild type. Our results give insight into the origin and modularity of understudied median fins, which have changed position, number, size, and even disappeared across evolutionary time.

The establishment of CRISPR/Cas9 gene editing in Anolis sagrei has positioned this species as a powerful model for studies of reptilian gene function. To enhance this model, we developed an immortalized lizard fibroblast cell line (ASEC-1) for the exploration of reptilian gene function in cellular processes. We demonstrate the use of this cell line by scrutinizing the role of primary cilia in lizard Hedgehog (Hh) signaling. Using CRISPR/Cas9 mutagenesis, we disrupted the ift88 gene, which is required for ciliogenesis in diverse organisms. We determined that loss of itf88 from lizard cells leads to an absence of primary cilia, a partial derepression of gli1 transcription, and an inability of the cells to respond to the Smoothened agonist, SAG. Through a cross-species analysis of SAG-induced transcriptional responses in cultured limb bud cells, we further determined that ∼46% of genes induced as a response to Hh pathway activation in A. sagrei are also SAG responsive in Mus musculus limb bud cells. Our results highlight conserved and diverged aspects of Hh signaling in anoles and establish a new resource for investigations of reptilian gene function.

Macrophage-like cells called hemocytes are key effectors of Drosophila cellular innate immune function. Larval hemocytes exist either in circulation or localise to segmentally-repeated sessile hemocyte compartments (SHCs). While numerous functions have been proposed for SHCs, the mechanisms directing hemocytes to them are unclear. Here, we have exploited the developmentally-regulated dispersal of SHCs that occurs at pupariation to identify the Abrupt (Ab) transcription factor (TF) and Ninjurin cell adhesion molecules as regulators of hemocyte recruitment to SHCs. We show that larval hemocytes express Ninjurins which are required for targeting hemocytes to SHCs. However, at pupariation, ecdysteroid signaling stimulates Ab expression, which collaborates with TFs including Blimp-1 and Hr3 to repress Ninjurins and disperse hemocytes. We observe that experimental manipulations that antagonise Ninjurin function in larval hemocytes cause premature SHC dispersal, while stabilization of Ninjurins in hemocytes blocks developmentally-regulated SHC remodeling and increases sensitivity to immune challenges. Cumulatively, our data indicate that control of Ninjurin activity provides a common target through which diverse developmental, environmental, and immune stimuli can be integrated to control hemocyte dispersal and immune function.

Hepatoblasts are the bipotential progenitors of liver cells that differentiate into either hepatocytes or cholangiocytes. In their study, Marino Zerial and colleagues reveal how hepatoblast polarisation and lumen morphogenesis are linked to hepatocyte cell fate determination. To know more about their work, we spoke to the first authors, Maarten Bebelman and Lenka Belicova, and the corresponding author, Marino Zerial, Director and Scientific Member at the Max Planck Institute of Molecular Cell Biology and Genetics.

Meristems are three-dimensional generative structures that contain stem cells and produce new organs and tissues. Meristems develop in all land plants, however we know little about the spatial and temporal regulation of meristem structure in lineages such as bryophytes. Here we describe the three-dimensional meristem anatomy during the development of the liverwort, Marchantia polymorpha. We show that the apical stem cell of the mature meristem is sub-apical, ventral, and in the outer cell layer. Mature meristem anatomy is therefore asymmetrical in the dorsoventral axis, which is reflected by the domain specific protein localisation of Class III and Class IV Homeodomain-Leucine-Zippers (MpC3HDZ and MpC4HDZ) and promoter activity of MpYUCCA2. The dorsoventral asymmetry that defines the mature meristem is absent in the juvenile meristems of asexual propagules known as gemmae. We discovered that anatomical dorsoventral asymmetry of the meristem forms after one to two days of gemmaling growth and is accompanied by expression of the dorsal identity reporter, MpC3HDZ. We conclude that the gemma meristem has arrested development and undergoes anatomical rearrangement to develop the three-dimensional meristem structure of the mature plant.

Seasonal spermatogenesis in fish is driven by spermatogonial stem cells (SSCs), which undergo a complex cellular process to differentiate into mature sperm. In this study, we characterized spermatogenesis in the large yellow croaker (Larimichthys crocea), a marine fish of significant commercial value, based on a high-resolution single-cell RNA-sequencing atlas of testicular cells from three distinct developmental stages: juvenile, adult differentiating and regressed testes. We detailed a continuous developmental trajectory of spermatogenic cells, from spermatogonia to spermatids, elucidating the molecular events involved in spermatogenesis. We uncovered dynamic heterogeneity in cellular compositions throughout the annual reproductive cycle, accompanied by strong molecular signatures within specific testicular cells. Notably, we identified a distinct population of SSCs and observed a critical metabolic transition from glycolysis to oxidative phosphorylation, enhancing our understanding of the biochemical and molecular characteristics of SSCs. Additionally, we elucidated the interactions between somatic cells and spermatogonia, illuminating the mechanisms that regulate SSC development. Overall, this work enhances our understanding of spermatogenesis in seasonal breeding teleosts and provides essential insights for the further conservation and culture of SSCs.

Vascular endothelial growth factor C (Vegfc) is crucial for lymphatic and blood vessel development, yet its cellular sources and specific functions in heart development remain unclear. To address this, we created a vegfc reporter and an inducible overexpression line in zebrafish. We found vegfc expression in large coronary arteries, circulating thrombocytes, cardiac adipocytes, and outflow tract smooth muscle cells. Notably, although coronary lymphangiogenesis aligns with Vegfc-expressing arteries in juveniles, it occurs only after coronary artery formation. Vegfc overexpression induced ectopic lymphatics on the ventricular surface prior to arterial formation, indicating that Vegfc abundance, rather than arterial presence, drives lymphatic development. However, this overexpression did not affect coronary artery coverage, suggesting a specific role for Vegfc in lymphatic, rather than arterial, development. Thrombocytes emerged as the initial Vegfc source during inflammation following heart injuries, transitioning to endocardial and myocardial expression during regeneration. Lower Vegfc levels in an amputation model corresponded with a lack of lymphatic expansion. Importantly, Vegfc overexpression enhanced lymphatic expansion and promoted scar resolution without affecting cardiomyocyte proliferation, highlighting its role in regulating lymphangiogenesis and promoting heart regeneration.

Neural stem cells (NSCs) generate neurons over a lifetime in adult vertebrate brains. In the adult zebrafish pallium, NSCs persist long term through balanced fate decisions. These decisions include direct neuronal conversions, i.e. delamination and neurogenesis without a division. To characterize this process, we reanalyze intravital imaging data of adult pallial NSCs, and observe shared delamination dynamics between NSCs and committed neuronal progenitors. Searching for mechanisms predicting direct NSC conversions, we build an NSC-specific genetic tracer of Caspase3/7 activation (Cas3*/Cas7*) in vivo. We show that non-apoptotic Cas3*/7* events occur in adult NSCs and are biased towards lineage termination under physiological conditions, with a predominant generation of single neurons. We further identify the transcription factor Atf3 as necessary for this bias. Finally, we show that the Cas3*/7* pathway is engaged by NSCs upon parenchymal lesion and correlates with NSCs more prone to lineage termination and neuron formation. These results provide evidence for non-apoptotic caspase events occurring in vertebrate adult NSCs and link these events with the NSC fate decision of direct conversion, which is important for long-term NSC population homeostasis.

Studies of traditional model organisms like the fruit fly Drosophila melanogaster have contributed immensely to our understanding of the genetic basis of developmental processes. However, the generalizability of these findings cannot be confirmed without functional genetic analyses in additional organisms. Direct genome editing using targeted nucleases has the potential to transform hitherto poorly-understood organisms into viable laboratory organisms for functional genetic study. To this end, here we present a method to induce targeted genome knock-out and knock-in of desired sequences in an insect that serves as an informative contrast to Drosophila, the cricket Gryllus bimaculatus. The efficiency of germ line transmission of induced mutations is comparable to that reported for other well-studied laboratory organisms, and knock-ins targeting introns yield viable, fertile animals in which knock-in events are directly detectable by visualization of a fluorescent marker in the expression pattern of the targeted gene. Combined with the recently assembled and annotated genome of this cricket, this knock-in/knock-out method increases the viability of G. bimaculatus as a tractable system for functional genetics in a basally branching insect.

cAMP-PKA signaling initiates the critical process of oocyte meiotic maturation in many animals, but inhibits it in vertebrates. To address this "cAMP paradox", we exchanged the key PKA substrate, ARPP19, between representative species, the vertebrate Xenopus and the cnidarian Clytia, comparing its phosphorylation and function. We found that as in Xenopus, Clytia maturing oocytes undergo ARPP19 phosphorylation on a highly conserved Gwl site, which inhibits PP2A and promotes M-phase entry. In contrast, despite a PKA phosphorylation signature motif recognisable across most animals, Clytia ARPP19 was only poorly phosphorylated by PKA in vitro and in vivo. Furthermore, unlike Xenopus ARPP19, exogenous Clytia ARPP19 did not delay Xenopus oocyte maturation. We conclude that in Clytia ARPP19 does not intervene in oocyte maturation initiation because of both poor recognition by PKA and the absence of effectors that mediate vertebrate oocyte prophase arrest. We propose that ancestral ARPP19 phosphorylated by Gwl has retained a key role in M-phase across eukaryotes and it has acquired new functions during animal evolution mediated by enhanced PKA phosphorylation, allowing co-option into oocyte maturation regulation in the vertebrate lineage.