Genetic reporter for live tracing fluid flow forces during cell fate segregation in mouse blastocyst development.

Mechanical forces are known to be important in mammalian blastocyst formation; however, due to limited tools, specific force inputs and how they relay to first cell fate control of inner cell mass (ICM) and/or trophectoderm (TE) remain elusive. Combining in toto live imaging and various perturbation experiments, we demonstrate and measure fluid flow forces existing in the mouse blastocyst cavity and identify Klf2(Krüppel-like factor 2) as a fluid force reporter with force-responsive enhancers. Long-term live imaging and lineage reconstructions reveal that blastomeres subject to higher fluid flow forces adopt ICM cell fates. These are reinforced by internal ferrofluid-induced flow force assays. We also utilize ex vivo fluid flow force mimicking and pharmacological perturbations to confirm mechanosensing specificity. Together, we report a genetically encoded reporter for continuously monitoring fluid flow forces and cell fate decisions and provide a live imaging framework to infer force information enriched lineage landscape during development. VIDEO ABSTRACT.

Continuous live imaging reveals a subtle pathological alteration with cell behaviors in congenital heart malformation.

To form fully functional four-chambered structure, mammalian heart development undergoes a transient finger-shaped trabeculae, crucial for efficient contraction and exchange for gas and nutrient. Although its developmental origin and direct relevance to congenital heart disease has been studied extensively, the time-resolved cellular mechanism underlying hypotrabeculation remains elusive. Here, we employed in toto live imaging and reconstructed the holistic cell lineages and cellular behavior landscape of control and hypotrabeculed hearts of mouse embryos from E9.5 for up to 24 h. Compared to control, hypotrabeculation in ErbB2 mutants arose mainly through dual mechanisms: both reduced proliferation of trabecular cardiomyocytes from early cell fate segregation and markedly impaired oriented cell division and migration. Further examination of mosaic mutant hearts confirmed alterations in cellular behaviors in a cell autonomous manner. Thus, our work offers a framework for continuous live imaging and digital cell lineage analysis to better understand subtle pathological alterations in congenital heart disease.

Long-term, in toto live imaging of cardiomyocyte behaviour during mouse ventricle chamber formation at single-cell resolution.

Mapping of the holistic cell behaviours sculpting the four-chambered mammalian heart has been a goal or previous studies, but so far only success in transparent invertebrates and lower vertebrates with two-chambered hearts has been achieved. Using a live-imaging system comprising a customized vertical light-sheet microscope equipped with a mouse embryo culture module, a heartbeat-gated imaging strategy and a digital image processing framework, we realized volumetric imaging of developing mouse hearts at single-cell resolution and with uninterrupted cell lineages for up to 1.5 d. Four-dimensional landscapes of Nppa+ cardiomyocyte cell behaviours revealed a blueprint for ventricle chamber formation by which biased outward migration of the outermost cardiomyocytes is coupled with cell intercalation and horizontal division. The inner-muscle architecture of trabeculae was developed through dual mechanisms: early fate segregation and transmural cell arrangement involving both oriented cell division and directional migration. Thus, live-imaging reconstruction of uninterrupted cell lineages affords a transformative means for deciphering mammalian organogenesis.

The lncRNA Hand2os1/Uph locus orchestrates heart development through regulation of precise expression of Hand2.

Exploration and dissection of potential actions and effects of long noncoding RNA (lncRNA) in animals remain challenging. Here, using multiple knockout mouse models and single cell RNA sequencing, we demonstrate that the divergent lncRNA Hand2os1/Uph has a key complex modulatory effect on the expression of its neighboring gene HAND2 and subsequently on heart development and function. Short deletion of the Hand2os1 promoter in mouse diminishes Hand2os1 transcription to ∼8-32%, but fails to affect HAND2 expression and yields no discernable heart phenotypes. Interestingly, full-length deletion of Hand2os1 in mouse causes moderate yet prevalent upregulation of HAND2 in hundreds of cardiac cells, leading to profound biological consequences, including dysregulated cardiac gene programs, congenital heart defects and perinatal lethality. We propose that the Hand2os1 locus dampens HAND2 expression to restrain cardiomyocyte proliferation, thereby orchestrating a balanced development of cardiac cell lineages. This study highlights the regulatory complexity of the lncRNA Hand2os1 on HAND2 expression, emphasizing the need for complementary genetic and single cell approaches to delineate the function and primary molecular effects of an lncRNA in animals.

Single-Cell Transcriptomics Reveals Chemotaxis-Mediated Intraorgan Crosstalk During Cardiogenesis.

RATIONALE: We hypothesized that the differentiation processes of cardiac progenitor cell (CP) from first and second heart fields (FHF and SHF) may undergo the unique instructive gene regulatory networks or signaling pathways, and the precise SHF progression is contingent on the FHF signaling developmental cues. OBJECTIVE: We investigated how the intraorgan communications control sequential building of discrete anatomic regions of the heart at single-cell resolution. METHODS AND RESULTS: By single-cell transcriptomic analysis of Nkx2-5 (NK2 homeobox 5) and Isl1 (ISL LIM homeobox 1) lineages at embryonic day 7.75, embryonic day 8.25, embryonic day 8.75, and embryonic day 9.25, we present a panoramic view of distinct CP differentiation hierarchies. Computational identifications of FHF- and SHF-CP descendants revealed that SHF differentiation toward cardiomyocytes underwent numerous step-like transitions, whereas earlier FHF progressed toward cardiomyocytes in a wave-like manner. Importantly, single-cell pairing analysis demonstrated that SHF-CPs were attracted to and expanded FHF-populated heart tube region through interlineage communications mediated by the chemotactic guidance (MIF [macrophage migration inhibitory factor]-CXCR2 [C-X-C motif chemokine receptor 2]). This finding was verified by pharmacological blockade of this chemotaxis in embryos manifesting limited SHF cell migration and contribution to the growth of the outflow tract and right ventricle but undetectable effects on the left ventricle or heart tube initiation. Genetic loss-of-function assay of Cxcr2 showed that the expression domain of CXCR4 was expanded predominantly at SHF. Furthermore, double knockout of Cxcr2/Cxcr4 exhibited defective SHF development, corroborating the redundant function. Mechanistically, NKX2-5 directly bound the Cxcr2 and Cxcr4 genomic loci and activated their transcription in SHF. CONCLUSIONS: Collectively, we propose a model in which the chemotaxis-mediated intraorgan crosstalk spatiotemporally guides the successive process of positioning SHF-CP and promoting primary heart expansion and patterning upon FHF-derived heart tube initiation.

Replication-Independent Histone Turnover Underlines the Epigenetic Homeostasis in Adult Heart.

RATIONALE: Replication-independent histone turnover has been linked to cis-regulatory chromatin domains in cultured cell lines, but its molecular underpinnings and functional relevance in adult mammalian tissues remain yet to be defined. OBJECTIVE: We investigated regulatory functions of replication-independent histone turnover in chromatin states of postmitotic cardiomyocytes from adult mouse heart. METHODS AND RESULTS: We used H2B-GFP (histone 2B-green fluorescent protein) fusion protein pulse-and-chase approaches to measure histone turnover rate in mouse cardiomyocytes. Surprisingly, we found that the short histone half-life (≈2 weeks) contrasted dramatically with the long lifetime of cardiomyocytes, and rapid histone turnover regions corresponded to cis-regulatory domains of heart genes. Interestingly, recruitment of chromatin modifiers, including Polycomb EED (embryonic ectoderm development), was positively correlated with histone turnover rate at enhancers. Mechanistically, through directly interacting with and engaging the BAF (BRG1 [Brahma-related gene-1]-associated factor) complex for nucleosome exchange for stereotyped histone modifications from the free histone pool, EED augmented histone turnover to restrain enhancer overactivation. CONCLUSIONS: We propose a model in which replication-independent histone turnover reinforces robustness of local chromatin states for adult tissue homeostasis.

Divergent Requirements for EZH1 in Heart Development Versus Regeneration.

RATIONALE: Polycomb repressive complex 2 is a major epigenetic repressor that deposits methylation on histone H3 on lysine 27 (H3K27me) and controls differentiation and function of many cells, including cardiac myocytes. EZH1 and EZH2 are 2 alternative catalytic subunits with partial functional redundancy. The relative roles of EZH1 and EZH2 in heart development and regeneration are unknown. OBJECTIVE: We compared the roles of EZH1 versus EZH2 in heart development and neonatal heart regeneration. METHODS AND RESULTS: Heart development was normal in Ezh1-/- (Ezh1 knockout) and Ezh2f/f::cTNT-Cre (Ezh2 knockout) embryos. Ablation of both genes in Ezh1-/-::Ezh2f/f::cTNT-Cre embryos caused lethal heart malformations, including hypertrabeculation, compact myocardial hypoplasia, and ventricular septal defect. Epigenome and transcriptome profiling showed that derepressed genes were upregulated in a manner consistent with total EZH dose. In neonatal heart regeneration, Ezh1 was required, but Ezh2 was dispensable. This finding was further supported by rescue experiments: cardiac myocyte-restricted re-expression of EZH1 but not EZH2 restored neonatal heart regeneration in Ezh1 knockout. In myocardial infarction performed outside of the neonatal regenerative window, EZH1 but not EZH2 likewise improved heart function and stimulated cardiac myocyte proliferation. Mechanistically, EZH1 occupied and activated genes related to cardiac growth. CONCLUSIONS: Our work unravels divergent mechanisms of EZH1 in heart development and regeneration, which will empower efforts to overcome epigenetic barriers to heart regeneration.

EED orchestration of heart maturation through interaction with HDACs is H3K27me3-independent.

In proliferating cells, where most Polycomb repressive complex 2 (PRC2) studies have been performed, gene repression is associated with PRC2 trimethylation of H3K27 (H3K27me3). However, it is uncertain whether PRC2 writing of H3K27me3 is mechanistically required for gene silencing. Here, we studied PRC2 function in postnatal mouse cardiomyocytes, where the paucity of cell division obviates bulk H3K27me3 rewriting after each cell cycle. EED (embryonic ectoderm development) inactivation in the postnatal heart (EedCKO) caused lethal dilated cardiomyopathy. Surprisingly, gene upregulation in EedCKO was not coupled with loss of H3K27me3. Rather, the activating histone mark H3K27ac increased. EED interacted with histone deacetylases (HDACs) and enhanced their catalytic activity. HDAC overexpression normalized EedCKO heart function and expression of derepressed genes. Our results uncovered a non-canonical, H3K27me3-independent EED repressive mechanism that is essential for normal heart function. Our results further illustrate that organ dysfunction due to epigenetic dysregulation can be corrected by epigenetic rewiring.