Alzheimer's disease (AD) is a complex neurodegenerative disorder characterized by progressive cognitive decline and memory loss, significantly affecting the quality of life for millions of people worldwide. Current therapeutic options primarily focus on symptomatic relief, with limited effectiveness in addressing the underlying pathophysiology. Recent advancements in gene editing technologies, particularly CRISPR/Cas9 (Clustered Regularly Interspaced Short Palindromic Repeats), offer promising opportunities to enhance stem cell therapy for AD. This review explores the potential of gene editing to target genetic risk factors associated with AD, such as APOE4 (Apolipoprotein E) and TREM2 (Triggering Receptor Expressed on Myeloid Cells 2), and to improve the differentiation and functionality of induced pluripotent stem cells (iPSCs) derived from AD patients. By creating more accurate disease models and humanized animal systems, researchers can gain a deeper understanding of the mechanisms of AD and evaluate novel therapeutic strategies. Moreover, combining gene editing with stem cell therapy may facilitate cell replacement therapies and the development of exosome-based treatments that modulate neuroinflammation and promote neuroprotection. Despite the promise of these approaches, challenges, such as off-target effects, delivery efficiency, and ethical considerations, remain significant hurdles. This review aims to provide a comprehensive overview of the current state of research, emphasizing the potential of gene editing technologies to revolutionize stem cell therapy for AD and improve patient outcomes.

Early stem cell-material interactions are critically governed by interfacial physicochemical cues. In this study, chitosan films incorporating cellulose nanofibers (CNFs) or carbon nanotubes (CNTs) were investigated as distinct nanomaterial strategies to modulate the morphology and viability of stem cells from human exfoliated deciduous teeth (SHED). The films were prepared by solvent casting followed by ionic crosslinking and characterized in terms of surface morphology, chemical structure, swelling behavior, and wettability. CNF-containing films exhibited a granular distribution of nanoscale surface features and reduced apparent wettability, whereas CNT-containing films displayed an irregular distribution of nanoscale surface features with greater topographical complexity. SHED responses were evaluated through qualitative morphological assessment, quantitative cell-spreading analysis, metabolic activity assays (Alamar Blue and MTT), and membrane integrity testing (Trypan Blue). CNF/Ch films restricted cell spreading and were associated with reduced metabolic activity and membrane integrity. In contrast, CNT/Ch films supported enhanced cell spreading, maintained high Alamar Blue-derived metabolic activity, and exhibited recovery of membrane integrity after 72 h. Collectively, these findings demonstrate that CNFs and CNTs impart distinct interfacial cues to chitosan films, leading to differential early SHED responses and identifying CNT/Ch as the most supportive formulation among those tested under the present conditions. This work underscores the importance of nanomaterial-driven surface features in guiding early stem cell-material interactions and provides insights for the design of chitosan-based substrates for regenerative medicine applications.

The amygdala paralaminar nuclei (PL) contain immature excitatory neurons that develop on a delayed timeline from birth to adulthood and are more prominent in the amygdala of humans and other primates than in rodents. Whether this expansion is linked to brain complexity or is a feature of primates is unknown. We sought to identify the PL in the ferret (Mustela putorius furo), a small, gyrencephalic mammal that does not belong to the primate order. Here, we show that the amygdala of juvenile (P30-P67) and adult ferrets (>1 year) also contains a collection of immature excitatory neurons that express doublecortin (Dcx) and polysialylated neural cell adhesion molecule (Psa-Ncam). Similar to humans and mice, these immature neurons express Tbr1 and CoupTFII, but not FoxP2, which labels neighboring clusters of GABAergic cells in the intercalated nuclei. Ferret PL neurons extend into the ventral basolateral amygdala (BLA) and appear either in dense clusters surrounded by astroglia or as individual cells, and each subpopulation contains neurons with migratory morphology. This expansion of PL neurons into the amygdala is similar to what is seen in humans, but unlike in mice, where PL neurons are infrequent in the BLA. We compared these findings to the marmoset (Callithrix jacchus), a lissencephalic non-human primate, and the swine (Sus scrofa domesticus), a gyrencephalic mammal, and found immature neurons extending into the amygdala in both. Our study identifies the PL region of the ferret amygdala, which contains immature neurons with migratory features in juveniles and adults. Cross-species comparisons indicate that the expansion of PL neurons into the amygdala seen in primates with both high and low gyrencephalic indices has also occurred in species with gyrencephalic brains from different orders.

Chromosome karyotyping, particularly G-banding, is a fundamental diagnostic and prognostic tool for hematological malignancies, providing a genome-wide view of large-scale numerical and structural chromosomal abnormalities. Its clinical utility is paramount for disease classification, risk stratification, and the evaluation of hematopoietic stem cell transplantation (HSCT) across diseases such as acute myeloid leukemia (AML), chronic lymphocytic leukemia (CLL), multiple myeloma (MM), and myelodysplastic syndromes (MDS). However, clinical challenges including low resolution and culture failure necessitate complementary advanced techniques. Fluorescence in situ hybridization (FISH) targets specific aberrations in non-dividing cells, while array comparative genomic hybridization (aCGH) and single-nucleotide polymorphism (SNP) arrays offer higher resolution for detecting cryptic copy number variations (CNVs) and copy-neutral loss of heterozygosity (CN-LOH). Furthermore, the modern diagnostic standard has evolved into a multi-omics approach that integrates morphology, flow cytometry, karyotyping, and next-generation sequencing (NGS). This comprehensive workflow significantly enhances diagnostic accuracy, refines risk stratification, and informs personalized therapeutic strategies. Clinically, karyotyping is essential for assessing cytogenetic remission, though it is less sensitive for minimal residual disease (MRD) detection than molecular methods. As emerging technologies such as optical genome mapping (OGM) demonstrate the potential to streamline these workflows, karyotyping continues to evolve, solidifying its indispensable role in the comprehensive management of hematologic cancers.

Using the well-studied two-stage model of skin carcinogenesis, the first transgenic mouse with targeted expression of a polyamine metabolic enzyme was generated 30 years ago. Ornithine decarboxylase (ODC), a key regulating enzyme of polyamine biosynthesis, was constitutively expressed in the outer root sheath cells of hair follicles near the bulge stem cell niche using a keratin 6 promoter in K6/ODC mice. Early studies using K6/ODC mice demonstrated that polyamines play an essential role in the early promotional phase of skin tumorigenesis. Treatment with inhibitors of ODC activity blocked the formation of skin tumors and caused the rapid regression of existing tumors. We review how use of the K6/ODC mouse has shown that elevated polyamines in epithelial cells stimulate proliferation and invasiveness, recruit stem cells, alter chromatin remodeling and cell signaling leading to metabolic reprogramming, increase vascularization, activate underlying fibroblasts, and have powerful effects on immune cell function, all contributing to the development and progression of tumors.

Post-transcriptional regulation is pivotal for cellular differentiation, yet how translationally silent mRNAs are selectively reactivated remains elusive. Here, we identify the MEX3D-HIP1 (MX-H) pathway and its associated organelle, the MEX3D-associated lysosomal vesicle (MXLV), as a shared system governing mRNA activation during spermiogenesis. Our data support a model in which MEX3D acts as an RNA-associated E3 ligase that selectively promotes ubiquitination of RBPs within RBP-mRNA complexes. This ubiquitination signal recruits HIP1, triggering the formation of MXLV, an autophagic vesicle that degrades translationally silent mRNP complexes. Genetic ablation of MX-H components in male germ cells disrupts spermiogenesis, leading to the accumulation of mRNP aggregates and male infertility. Intriguingly, we discovered that this germline-restricted pathway is aberrantly activated in gastric cancer cells, where MXLV biogenesis promotes tumor progression. The strict restriction of MXLV to male germ cells under physiological conditions may provide a unique therapeutic window, suggesting that targeting this pathway could suppress tumor progression while minimizing adverse effects on normal physiological functions. Our work establishes MXLV as a specialized vesicular structure essential for cellular remodeling during development and reveals how a germline-specific membrane trafficking system is co-opted in pathological proteome remodeling in gastric cancer.

How tumors manipulate neural circuits to evade immunity is unclear. In a recent study, Wei et al. reveal, in lung adenocarcinoma, a vagal sensory-brain stem sympathetic circuit that suppresses macrophages and CD8+ T cells via β2-adrenergic signaling. Disrupting this axis restores antitumor immunity, nominating β-blockers and neural modulation as promising therapies.

The molecular mechanisms linking immune cell signaling to osteoclastogenesis remain incompletely defined. Here, we identify an Annexin A1 (AnxA1)-Dectin-1 axis as a key driver of osteoclast differentiation. Dectin-1 (CLEC7A), a myeloid C-type lectin receptor best known for β-glucan recognition, is shown to bind the endogenous ligand AnxA1 on pre-osteoclasts, thereby promoting their maturation. In Dectin-1 deficient mice, reduced osteoclast numbers resulted in increased bone volume, whereas β-glucan-induced Dectin-1 activation enhanced osteoclastogenesis. Within the bone marrow niche, AnxA1 was abundantly expressed on B220+ B cells, and γ-irradiation markedly increased its surface translocation both in vitro and in vivo. γ-irradiated B220+ B cells exhibited strong Dectin-1 binding capacity and robustly stimulated osteoclast differentiation in a Dectin-1-dependent manner. These findings establish the AnxA1-Dectin-1 interaction as a critical immune-skeletal communication pathway, revealing a mechanism by which radiation exposed immune cells can accelerate bone resorption. Targeting this axis offers a potential strategy to mitigate radiation-induced bone degradation and preserve skeletal homeostasis.

Several protocols for generating oligodendrocytes (OLs) from human pluripotent stem cells have been reported. However, they are limited by long culture duration, intensive handling, and low yield of mature OLs. Transcription factor-based strategies have improved efficiency, but OLIG2 and SOX10, key regulators of oligodendrocyte precursor cells (OPCs), also promote alternative neural fates. Here, we developed a Tet-inducible system to control SOX10 and OLIG2 expression, including that of a phosphorylation-deficient OLIG2 mutant (S147A). Co-expression of SOX10 and OLIG2 enhanced OPC induction, confirmed by O4 positivity and transcriptomic profiling. Interestingly, only a brief induction of SOX10 + OLIG2(S147A) (2-5 days) efficiently yielded myelin basic protein positive OLs within 25 days, reaching approximately 20% of total cells. In contrast, sustained doxycycline-mediated expression of SOX10 and OLIG2(S147A) favored OPC proliferation and delayed OL maturation. These findings highlight the importance of temporal control of transcription factor activity in accelerating OL differentiation and provide a practical platform for disease modeling and regenerative applications.

Failure of remyelination is a major determinant of progressive neurological decline in demyelinating disorders of the central nervous system. Although endogenous repair mechanisms are activated following injury, the generation of fully functional myelinating oligodendrocytes is frequently insufficient to restore long-term tissue integrity. In addition to oligodendrocyte progenitor cells, neural stem cells (NSCs) residing in adult neurogenic niches represent a potential endogenous source of oligodendroglial regeneration. However, promoting effective remyelination from NSCs requires more than stimulating lineage commitment, as progenitor fate and maturation are tightly regulated by lesion-specific microenvironmental cues. Over the past decades, a wide range of experimental models-including reductionist in vitro systems, organoid platforms, toxin-induced or immune-mediated demyelination in vivo models-have provided important mechanistic insights into NSCs activation and oligodendroglial differentiation. Yet, no single model fully captures the complexity of chronic human pathology, highlighting significant translational limitations. Moreover, inflammatory signaling, glial reactivity, and extracellular matrix remodeling critically influence whether enhanced oligodendrogenesis results in effective remyelination. In this review, we analyze current experimental frameworks used to investigate NSCs-driven oligodendrogenesis and discuss how microenvironmental regulation shapes regenerative outcomes. We further examine emerging therapeutic strategies aimed at modulating endogenous NSCs and their niche, including pharmacological approaches, cell-based interventions, and nanotechnology-based platforms. By integrating experimental and translational perspectives, we propose that successful remyelination requires coordinated modulation of both progenitor competence and lesion microenvironment.

Regenerative medicine for stroke patients has been attracting attention. However, the effects of rehabilitation after the cell transplantation have not been fully elucidated. The purpose of the present study was to investigate whether intensive gait-focused rehabilitation using a robotic orthosis after regenerative medicine improved gait function and induced plastic changes in cortical networks. The present study was conducted in a retrospective cohort study. We selected seven chronic stroke patients, those who had undergone adipose-derived mesenchymal stem cells (MSC) transplantation therapy after the onset of stroke and had been receiving adequate subsequent gait rehabilitation with a robot for more than 2 months. During hospitalization, each patient received at least 2 h of rehabilitation, including robotic-assisted gait training more than five times per week. As the assessments, gait performance and M1 seed-based resting state-functional connectivity (rs-FC) obtained by a magnetoencephalography were compared before and after hospitalization. After rehabilitation, cadence and spatial gait symmetry ratio were significantly improved, and a significant negative correlation was found between the changes in the gait symmetry ratio and the time from transplant to rehabilitation. Seed-based rs-FC in the beta band between the lesioned M1 and multiple brain regions (e.g., both frontal areas, ipsilateral postcentral gyrus) was significantly decreased after the rehabilitation. Significant negative correlations were also observed between the changes in the gait symmetry ratio and the changes in lesioned M1 seed-based rs-FC in the paracentral gyrus and regions associated with the default mode network. It was revealed that intensive gait-focused rehabilitation using a robotic orthosis improved gait function and induced plastic changes in the cortical networks. The improvements were significantly correlated with the timing of the start of rehabilitation after MSC transplantation.

The development of multicellular organisms relies on controlled cell divisions and differentiation that generate specific cell types of functional tissues and organs. Control of the cell cycle and its checkpoints are tightly intertwined with the maintenance of stem cells, cell fate acquisition and cellular reprogramming. This Review focuses on cell cycle-mediated control of plant development and regeneration, where cell division and differentiation occur in the absence of cell migration. We examine two systems - the root apical meristem and leaf epidermis (stomata) - and explore how master-regulatory transcription factors directly impact the cell cycle to achieve differentiation of specific cell types, as well as how epigenetic machineries guide or constrain such processes. We further emphasize the importance of G1 cell cycle phase duration and G2/M checkpoints for stem cell differentiation and regeneration. By synthesizing recent discoveries, we aim to highlight cell cycle regulation that underpins both robustness and plasticity of plant development and regeneration. Such knowledge will ultimately enhance our understanding of the commonalities and uniqueness of cell cycle regulation between plants and metazoans.

Not available.

Single-cell passaging of induced pluripotent stem cells (iPSCs) has historically been discredited, as it may risk mutations. Here, however, in combination with Rho kinase inhibition and based on stringent quality control, we successfully validate a corresponding iPSC banking process under Good Manufacturing Practice (GMP) conditions. The underlying culture system features enhanced consistency, sustains genomic integrity in the resulting cell lines, and enables excellent priming for gene editing and directed differentiation. The process, as well as the resulting GMP iPSC lines, will provide a robust foundation for clinical manufacturing.

Globally, third leading cause of cancer-related deaths is contributed by Hepatocellular carcinoma (HCC). Chronic hepatitis B virus infection is one of the seminal etiological drivers of HCC. Hepatitis B viral DNA integration, host genomic instability, persistent inflammatory responses and the oncogenic activity of the viral oncoprotein Hepatitis B virus X (HBx), contribute to the hepatocarcinogenesis. Emerging evidences indicate that epigenetic dysregulation plays a seminal role in linking viral persistence in the liver tissue to its malignant transformation. In HBV-infected hepatocytes, aberrant DNA methylation, histone modifications, and dysregulated non-coding RNAs reprogram transcriptional networks that activate oncogenic pathways, promote proliferative signaling, and sustain cancer stem cell-like phenotypes driving HCC progression. The epigenetic modifications in the infected, malignant hepatic cells can influence the tumor microenvironment, contributing to the infiltration of exhausted cytotoxic T lymphocytes with elevated PD-1 and Tim-3 expression. Further, the T lymphocytes exhibit reduced proliferative capacity, impaired cytokine secretion, and diminished cytotoxic activity. In the clinical perspective, long-term nucleotide analogue therapy causes viral suppression and attenuation of inflammation, thereby reducing HCC progression by 40-80%. Despite the extensive T-cell exhaustion, HBV-associated HCC (HBV-HCC) is responsive to immune checkpoint blockade, as highlighted in the CheckMate-040 trial. Emerging therapeutic strategies combine anti-viral agents with immune checkpoint inhibitors, epi-drugs and HBsAg-directed TCR-engineered T cells. These clinical approaches aim to simultaneously restore antitumor immune responses as well as neutralize the viral oncogenic drivers, offering promising avenues for improved management of HBV-induced HCC.

Employing a comprehensive strategy that integrated network pharmacology, molecular docking, and in vitro experimental techniques, this study examined the effect of neohesperidin on the proliferation and osteogenic differentiation of human periodontal ligament stem cells (hPDLSCs) upon lipopolysaccharide (LPS)-induced inflammatory conditions.

Volumetric Musculoskeletal Trauma (VMST), which is characterized by volumetric muscle loss accompanied by bone injury, poses a significant challenge to regenerative medicine. While current therapies primarily focus on the individual regeneration of muscle or bone, there is no systematic and integrated treatment strategy. In this study, we developed a CuMBG-PA, a copper-doped nanozyme based on mesoporous bioactive glass (MBG) and procyanidin (PA), for integrated muscle and bone repair of VMST. CuMBG-PA self-assembles into a stable polyphenol network via Cu-PA coordination bonds, enhancing PA stability and reactive oxygen species-scavenging capacity. In vitro and in vivo experiments demonstrated that CuMBG-PA promoted osteogenesis and myogenesis while exhibiting high biocompatibility and antibacterial activity. Single-cell RNA-sequencing results revealed that CuMBG-PA synergistically induces stem cell differentiation and promotes tissue repair through multiple myoskeletal shared metabolic pathways. Mechanistically, CuMBG-PA exerts its beneficial effects by increasing the number of Proteoglycan 4 (Prg4) + fibro/adipogenic progenitor cells (FAPs), which highly express fibronectin and insulin-like growth factor. In addition, PRG4 regulates immune cells, removes overactivated muscle satellite cells, reduces muscle fibrosis, and promotes functional recovery during regeneration. In summary, this work demonstrates that the novel self-assembled CuMBG-PA nanozyme represents a potential biomaterial-based strategy for integrated muscle and bone repair in VMST.

Patients with polycystic ovary syndrome (PCOS) are at an elevated risk of depression, yet the underlying mechanisms remain elusive. Emerging evidence implicates the gut-brain axis and systemic lipid homeostasis alterations as potential key contributors. We profiled untargeted plasma lipidomes of PCOS patients with and without comorbid depression (PCOS-DP) and integrated these data with our prior gut microbial and host transcriptomic datasets to construct multi-omics interaction networks. The causal role of the candidate gut microbial was preliminary explored in a germ-free PCOS mouse model using fecal microbiota transplantation, followed by behavioral phenotyping and ELISA-based protein quantification. We identified a distinct plasma lipidomic signature differentiating PCOS-DP from PCOS alone, characterized primarily by the downregulation of 26 lipid species. Most of these altered lipids were triacylglycerols (TAGs) enriched with FA18:1 and FA18:2, whose levels correlated with coagulation dysfunction. Multi-omics network analysis revealed significant interconnections between depression-associated gut microbiota (including Bacteroides eggerthii), specific altered lipids such as TAG (60:12/FA22:6), and host genes involved in inflammation (e.g., IL22, NLRP7), metabolism, and neural processes. Animal validation demonstrated that B. eggerthii colonization in PCOS mice specifically exacerbated anhedonia and hyperlocomotion, alongside modulating plasma IL-22 expression, suggesting its context-dependent neurobehavioral effect role. This study delineates a TAG-downregulated lipid signature with diagnostic potential and reveals a novel "gut microbiota-lipid-host gene" interaction network underpinning PCOS-DP, with B. eggerthii as a key microbial modulator of neurobehavioral phenotypes in the context of PCOS. These findings provide new pathophysiological insights and highlights potential diagnostic biomarkers for PCOS-DP.

Repairing large-scale craniomaxillofacial bone defects is hindered by a limited availability of stem-cell sources and a low osteogenic efficiency. To address these challenges, Fe3O4 nanoparticles were modified with methacrylic anhydride (MAA), which helped to introduce photopolymerizable methacryloyl groups, resulting in MAA-Fe3O4 nanoparticles that exhibit excellent magnetic properties and colloidal stability. These nanoparticles were incorporated into gelatin methacryloyl (GelMA) and covalently crosslinked to form an injectable, photocurable GelMA-Fe3O4 magnetic composite hydrogel. This hydrogel provided a three-dimensional culture microenvironment for human dental follicle stem cells (hDFSCs), and upon encapsulation, osteogenesis was significantly enhanced under a 100 mT static magnetic field (SMF). In vitro, GelMA-Fe3O4 hydrogels demonstrated increased porosity and improved mechanical properties, thereby significantly promoting hDFSCs proliferation, adhesion and spreading. Additionally, under SMF exposure, the expression of osteogenesis-related genes and proteins, including alkaline phosphatase (ALP), Runx2, Col-I and OPN, was significantly upregulated. In a rat calvarial defect model, bone mineralization centers with multi-site distribution were observed in the GelMA-Fe3O4 + SMF group as early as 4 weeks postoperatively, leading to high-quality defect repair. The limitations of traditional 'peripheral-to-center' unidirectional repair were overcome by this model of synchronous multi-site osteogenesis, maximizing bone regeneration with a minimal number of stem cells and providing an efficient, controllable tissue-engineering strategy for the clinical treatment of craniomaxillofacial bone defects.