Strengthening cardiac therapy pipelines using human pluripotent stem cell-derived cardiomyocytes

Functional analysis of JPH2-knockout cardiomyocytes identifies ECCD as a novel indicator in a human cardiac modelJPH2

BACKGROUND

Junctophilin-2 (JPH2) is a vital protein in cardiomyocytes, anchoring T-tubule and sarcoplasmic reticulum membranes to facilitate excitation-contraction coupling, a process essential for cardiac contractile function. Dysfunction of JPH2 is associated with cardiac disorders such as heart failure; however, prior studies using mouse models or primary human cardiomyocytes are limited by interspecies differences or poor cell viability, respectively. This study aimed to investigate JPH2's role in human cardiac function and disease using a novel stem cell-derived model, while introducing a new indicator to evaluate related cardiac impairments.

METHODS

We generated a JPH2-knockout model using human embryonic stem cell-derived cardiomyocytes (hESC-CMs) with CRISPR/Cas9. Cellular morphology, contractile function, calcium dynamics, and electrophysiological properties were assessed via transmission electron microscopy, the CardioExcyte96 system, calcium imaging with Fluo-4 AM, and multi-electrode array recordings, respectively. Wild-type JPH2 was overexpressed through lentiviral transfection to evaluate rescue effects, and two JPH2 variants-one benign (G505S) and one pathogenic (E85K)-were introduced to study mutation-specific effects.

RESULTS

JPH2 knockout disrupted excitation-contraction coupling in hESC-CMs by impairing junctional membrane complex structure, leading to heart failure-like phenotypes with reduced contractility, altered calcium dynamics, and electrophysiological irregularities. Overexpression of wild-type JPH2 restored these functions, affirming its critical role in cardiac physiology. We identified excitation-contraction coupling delay (ECCD) as a novel indicator that precisely quantified coupling impairment severity, with its applicability validated across distinct JPH2 variants (G505S and E85K).

CONCLUSIONS

This study demonstrates JPH2's essential role in sustaining excitation-contraction coupling by stabilizing the junctional membrane complex, with its deficiency driving heart failure-like cardiac dysfunction. ECCD is established as a sensitive, comprehensive indicator for assessing JPH2-related impairment severity. These findings advance our understanding of JPH2 in cardiac pathology and position ECCD as a valuable tool for research and potential clinical evaluation, with JPH2 and calcium regulation emerging as promising therapeutic targets.

3D-Printed Myocardium-Specific Structure Enhances Maturation and Therapeutic Efficacy of Engineered Heart Tissue in Myocardial Infarction

Despite advancements in engineered heart tissue (EHT), challenges persist in achieving accurate dimensional accuracy of scaffolds and maturing human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs), a primary source of functional cardiac cells. Drawing inspiration from cardiac muscle fiber arrangement, a three-dimensional (3D)-printed multi-layered microporous polycaprolactone (PCL) scaffold is created with interlayer angles set at 45° to replicate the precise structure of native cardiac tissue. Compared with the control group and 90° PCL scaffolds, the 45° PCL scaffolds exhibited superior biocompatibility for cell culture and improved hiPSC-CM maturation in calcium handling. RNA sequencing demonstrated that the 45° PCL scaffold promotes the mature phenotype in hiPSC-CMs by upregulating ion channel genes. Using the 45° PCL scaffold, a multi-cellular EHT is successfully constructed, incorporating human cardiomyocytes, endothelial cells, and mesenchymal stem cells. These complex EHTs significantly enhanced hiPSC-CM engraftment in vivo, attenuated ventricular remodeling, and improved cardiac function in mouse myocardial infarction. In summary, the myocardium-specific structured EHT developed in this study represents a promising advancement in cardiovascular regenerative medicine.

Anti-Schistosomal activity and ADMET properties of 1,2,5-oxadiazinane-containing compound synthesized by visible-light photoredox catalysis

The incorporation of saturated nitrogen-containing heterocycle 1,2,5-oxadiazinane into small molecules represents a compelling avenue in drug discovery due to its unexplored behavior within biological systems and incomplete protocols for synthesis. In this study, we present 1,2,5-oxadiazinane, an innovative heterocyclic bioisostere of piperizin-2-one and novel chemotype of the anti-schistosomal drug praziquantel (PZQ), which has been the only clinical drug available for three decades. PZQ is associated with significant drawbacks, including poor solubility, a bitter taste, and low metabolic stability. Therefore, the discovery of a new class of anti-schistosomal agents is imperative. To address this challenge, we introduce a pioneering method for the synthesis of 1,2,5-oxadiazinane derivatives through the cycloaddition of nitrones with N,N,N',N'-tetraalkyldiaminomethane in the presence of an IrIII complex photosensitizer. This transformative reaction offers a streamlined route to various kinds of 1,2,5-oxadiazinanes that is characterized by mild reaction conditions and broad substrate scope. Mechanistic investigations suggest that the photoredox pathway underlies the [3 + 3] photocycloaddition process. Thus, based on bioisosteric replacement, we identified a remarkable molecule as a new chemotype of a potent anti-schistosomal compound that not only exhibits superior solubility, but also retains the potent biological activity inherent to PZQ.

Cardiomyocyte proliferation and regeneration in congenital heart disease

Despite advances in prenatal screening and a notable decrease in mortality rates, congenital heart disease (CHD) remains the most prevalent congenital disorder in newborns globally. Current therapeutic surgical approaches face challenges due to the significant rise in complications and disabilities. Emerging cardiac regenerative therapies offer promising adjuncts for CHD treatment. One novel avenue involves investigating methods to stimulate cardiomyocyte proliferation. However, the mechanism of altered cardiomyocyte proliferation in CHD is not fully understood, and there are few feasible approaches to stimulate cardiomyocyte cell cycling for optimal healing in CHD patients. In this review, we explore recent progress in understanding genetic and epigenetic mechanisms underlying defective cardiomyocyte proliferation in CHD from development through birth. Targeting cell cycle pathways shows promise for enhancing cardiomyocyte cytokinesis, division, and regeneration to repair heart defects. Advancements in human disease modeling techniques, CRISPR-based genome and epigenome editing, and next-generation sequencing technologies will expedite the exploration of abnormal machinery governing cardiomyocyte differentiation, proliferation, and maturation across diverse genetic backgrounds of CHD. Ongoing studies on screening drugs that regulate cell cycling are poised to translate this nascent technology of enhancing cardiomyocyte proliferation into a new therapeutic paradigm for CHD surgical interventions.

Advancing Cardiovascular Drug Screening Using Human Pluripotent Stem Cell-Derived Cardiomyocytes

Human pluripotent stem cell-derived cardiomyocytes (hPSC-CMs) have emerged as a promising tool for studying cardiac physiology and drug responses. However, their use is largely limited by an immature phenotype and lack of high-throughput analytical methodology. In this study, we developed a high-throughput testing platform utilizing hPSC-CMs to assess the cardiotoxicity and effectiveness of drugs. Following an optimized differentiation and maturation protocol, hPSC-CMs exhibited mature CM morphology, phenotype, and functionality, making them suitable for drug testing applications. We monitored intracellular calcium dynamics using calcium imaging techniques to measure spontaneous calcium oscillations in hPSC-CMs in the presence or absence of test compounds. For the cardiotoxicity test, hPSC-CMs were treated with various compounds, and calcium flux was measured to evaluate their effects on calcium dynamics. We found that cardiotoxic drugs withdrawn due to adverse drug reactions, including encainide, mibefradil, and cetirizine, exhibited toxicity in hPSC-CMs but not in HEK293-hERG cells. Additionally, in the effectiveness test, hPSC-CMs were exposed to ATX-II, a sodium current inducer for mimicking long QT syndrome type 3, followed by exposure to test compounds. The observed changes in calcium dynamics following drug exposure demonstrated the utility of hPSC-CMs as a versatile model system for assessing both cardiotoxicity and drug efficacy. Overall, our findings highlight the potential of hPSC-CMs in advancing drug discovery and development, which offer a physiologically relevant platform for the preclinical screening of novel therapeutics.