Adult Fibroblasts Research Articles

Biological Evaluation of a Native Amniotic Membrane Allograft

Category: Basic Sciences/Biologics; Other Introduction/Purpose: Placental tissue allografts have long been used as effective wound dressings for hard to heal wounds and are demonstrating increasing utility in the field of foot and ankle surgeries. Previous observations of the PURION-processed dehydrated amnion/chorion membrane (dHACM) demonstrated retention of regulatory proteins inherent to amniotic tissues and preservation of the bioactivity to stimulate cellular activities. Novel and patent-pending processing techniques have been developed to introduce a thicker and more robust allograft, as compared to dHACM. Lyophilized human amnion chorion membrane (LHACM) will confer versatility to clinicians with improved handling while maintaining the natural tissue composition and intrinsic biological activities. This study characterizes the biological properties of LHACM which may support the healing cascade. Methods: LHACM was processed using a modified PURION process which incorporates an optimized cleansing process, enabling retention of the intermediate layer, and lyophilization. Tissue architecture was visualized with hematoxylin and eosin staining. The hygroscopic contribution of the intermediate layer was appraised with absorbency measurements. Cleansing efficiency was determined through quantification of residual hemin remaining in the tissue. Regulatory proteins were quantified using a multiplex ELISA. The cellular response to LHACM treatment was assessed using multiple in vitro assays targeting cellular proliferation and analysis of signaling pathways. Adult dermal fibroblasts (HDFs) cultured over a 3-day period in LHACM eluates were assessed for cellular proliferation. In vitro models were developed to assess the regulation of relevant signaling pathways, including TGF-β1 and Wnt/β-catenin for fibrotic and proliferative processes, respectively. Cellular responses were evaluated through quantitative PCR and cell reporter lines. Results: Histological evaluation showed that processing maintains the tissue structure. Absorption testing demonstrated LHACM is more hygroscopic than dHACM. Hemin analysis demonstrated low levels of residual hemin which were comparable for LHACM and dHACM allografts. Screening for regulatory proteins indicate that LHACM contains a diverse array of regulatory proteins, inherent to amniotic membranes. In vitro treatment of primary cells with LHACM eluates promoted dermal fibroblast proliferation as well as regulation of elevated TGFβ- and Wnt/β-catenin signaling. Conclusion: The processing method of LHACM maintains the intrinsic properties of amniotic membranes with similar levels of biological activity as compared to dHACM, while providing an option for a thicker allograft with alternative handling characteristics. LHACM represents a novel product concept which increases versatility of amniotic membrane application in varied outpatient and surgical uses.

Age-related pathological impairments in directly reprogrammed dopaminergic neurons derived from patients with idiopathic Parkinson's disease.

SummaryWe have developed an efficient approach to generate functional induced dopaminergic (DA) neurons from adult human dermal fibroblasts. When performing DA neuronal conversion of patient fibroblasts with idiopathic Parkinson’s disease (PD), we could specifically detect disease-relevant pathology in these cells. We show that the patient-derived neurons maintain age-related properties of the donor and exhibit lower basal chaperone-mediated autophagy compared with healthy donors. Furthermore, stress-induced autophagy resulted in an age-dependent accumulation of macroautophagic structures. Finally, we show that these impairments in patient-derived DA neurons leads to an accumulation of phosphorylated alpha-synuclein, the classical hallmark of PD pathology. This pathological phenotype is absent in neurons generated from induced pluripotent stem cells from the same patients. Taken together, our results show that direct neural reprogramming can be used for obtaining patient-derived DA neurons, which uniquely function as a cellular model to study age-related pathology relevant to idiopathic PD.

Direct Cell Conversion of Somatic Cells into Dopamine Neurons: Achievements and Perspectives

In the last decade, direct reprogramming has emerged as a novel strategy to obtain mature and functional dopamine neurons from somatic cells. This approach could overcome issues linked to the use of human pluripotent stem cells such as ethical concerns and safety problems that can arise from the overgrowth of undifferentiated cells after transplantation. Several conversion methodologies have been developed to obtain induced DA neurons (iDANs) or induced DA neuron progenitors (iDPs). iDANs have also proved to successfully integrate in mice striatum, alleviating Parkinson's disease (PD) motor symptoms. In the next decade, human iDANs and/or iDPs could be translated to clinic to achieve a patient-tailored therapy, but current critical issues hinder this goal, such as the low conversion rate of adult human fibroblasts and the risks associated with lentiviral delivery of conversion factors. In this study, we summarize the strategies and recent improvements developed for the generation of mouse and human iDANs/iDPs. Furthermore, we discuss the more recent application of in vivo direct conversion, which may enable clinical therapies for PD by means of brain in situ delivery of dopaminergic reprogramming transcription factors.

Deciphering multi-way interactions in the human genome

Chromatin architecture, a key regulator of gene expression, can be inferred using chromatin contact data from chromosome conformation capture, or Hi-C. However, classical Hi-C does not preserve multi-way contacts. Here we use long sequencing reads to map genome-wide multi-way contacts and investigate higher order chromatin organization in the human genome. We use hypergraph theory for data representation and analysis, and quantify higher order structures in neonatal fibroblasts, biopsied adult fibroblasts, and B lymphocytes. By integrating multi-way contacts with chromatin accessibility, gene expression, and transcription factor binding, we introduce a data-driven method to identify cell type-specific transcription clusters. We provide transcription factor-mediated functional building blocks for cell identity that serve as a global signature for cell types.

Investigation of PTC124-mediated translational readthrough in a retinal organoid model of AIPL1-associated Leber congenital amaurosis.

SummaryLeber congenital amaurosis type 4 (LCA4), caused by AIPL1 mutations, is characterized by severe sight impairment in infancy and rapidly progressing degeneration of photoreceptor cells. We generated retinal organoids using induced pluripotent stem cells (iPSCs) from renal epithelial cells obtained from four children with AIPL1 nonsense mutations. iPSC-derived photoreceptors exhibited the molecular hallmarks of LCA4, including undetectable AIPL1 and rod cyclic guanosine monophosphate (cGMP) phosphodiesterase (PDE6) compared with control or CRISPR-corrected organoids. Increased levels of cGMP were detected. The translational readthrough-inducing drug (TRID) PTC124 was investigated as a potential therapeutic agent. LCA4 retinal organoids exhibited low levels of rescue of full-length AIPL1. However, this was insufficient to fully restore PDE6 in photoreceptors and reduce cGMP. LCA4 retinal organoids are a valuable platform for in vitro investigation of novel therapeutic agents.

The Relative Abundances of Human Leukocyte Antigen-E, α-Galactosidase A and α-Gal Antigenic Determinants Are Biased by Trichostatin A-Dependent Epigenetic Transformation of Triple-Transgenic Pig-Derived Dermal Fibroblast Cells.

The present study sought to establish the mitotically stable adult cutaneous fibroblast cell (ACFC) lines stemming from hFUT2×hGLA×HLA-E triple-transgenic pigs followed by trichostatin A (TSA)-assisted epigenetically modulating the reprogrammability of the transgenes permanently incorporated into the host genome and subsequent comprehensive analysis of molecular signatures related to proteomically profiling the generated ACFC lines. The results of Western blot and immunofluorescence analyses have proved that the profiles of relative abundance (RA) noticed for both recombinant human α-galactosidase A (rhα-Gal A) and human leukocyte antigen-E (HLA-E) underwent significant upregulations in tri-transgenic (3×TG) ACFCs subjected to TSA-mediated epigenetic transformation as compared to not only their TSA-unexposed counterparts but also TSA-treated and untreated non-transgenic (nTG) cells. The RT-qPCR-based analysis of porcine tri-genetically engineered ACFCs revealed stable expression of mRNA fractions transcribed from hFUT2, hGLA and HLA-E transgenes as compared to a lack of such transcriptional activities in non-transgenic ACFC variants. Furthermore, although TSA-based epigenomic modulation has given rise to a remarkable increase in the expression levels of Galα1→3Gal (α-Gal) epitopes that have been determined by lectin blotting analysis, their semi-quantitative profiles have dwindled profoundly in both TSA-exposed and unexposed 3×TG ACFCs as compared to their nTG counterparts. In conclusion, thoroughly exploring proteomic signatures in such epigenetically modulated ex vivo models devised on hFUT2×hGLA×HLA-E triple-transgenic ACFCs that display augmented reprogrammability of translational activities of two mRNA transcripts coding for rhα-Gal A and HLA-E proteins might provide a completely novel and powerful research tool for the panel of further studies. The objective of these future studies should be to multiply the tri-transgenic pigs with the aid of somatic cell nuclear transfer (SCNT)-based cloning for the purposes of both xenografting the porcine cutaneous bioprostheses and dermoplasty-mediated surgical treatments in human patients.

Adult fibroblasts use aggresomes only in distinct cell-states

The aggresome is a protein turnover system in which proteins are trafficked along microtubules to the centrosome for degradation. Despite extensive focus on aggresomes in immortalized cell lines, it remains unclear if the aggresome is conserved in all primary cells and all cell-states. Here we examined the aggresome in primary adult mouse dermal fibroblasts shifted into four distinct cell-states. We found that in response to proteasome inhibition, quiescent and immortalized fibroblasts formed aggresomes, whereas proliferating and senescent fibroblasts did not. Using this model, we generated a resource to provide a characterization of the proteostasis networks in which the aggresome is used and transcriptomic features associated with the presence or absence of aggresome formation. Using this resource, we validate a previously reported role for p38 MAPK signaling in aggresome formation and identify TAK1 as a novel driver of aggresome formation upstream of p38 MAPKs. Together, our data demonstrate that the aggresome is a non-universal protein degradation system which can be used cell-state specifically and provide a resource for studying aggresome formation and function.

Role of MMP3 and fibroblast-MMP14 in skin homeostasis and repair

Early lethality of mice with complete deletion of the matrix metalloproteinase MMP14 emphasized the proteases’ pleiotropic functions. MMP14 deletion in adult dermal fibroblasts (MMP14Sf-/-) caused collagen type I accumulation and upregulation of MMP3 expression. To identify the compensatory role of MMP3, mice were generated with MMP3 deletion in addition to MMP14 loss in fibroblasts. These double deficient mice displayed a fibrotic phenotype in skin and tendons as detected in MMP14Sf-/- mice, but no additional obvious defects were detected. However, challenging the mice with full thickness excision wounds resulted in delayed closure of early wounds in the double deficient mice compared to wildtype and MMP14 single knockout controls. Over time wounds closed and epidermal integrity was restored. Interestingly, on day seven, post-wounding myofibroblast density was lower in the wounds of all knockout than in controls, they were higher on day 14. The delayed resolution of myofibroblasts from the granulation tissue is paralleled by reduced apoptosis of these cells, although proliferation of myofibroblasts is induced in the double deficient mice. Further analysis showed comparable TGFβ1 and TGFβR1 expression among all genotypes. In addition, in vitro, fibroblasts lacking MMP3 and MMP14 retained their ability to differentiate into myofibroblasts in response to TGFβ1 treatment and mechanical stress. However, in vivo, p-Smad2 was reduced in myofibroblasts at day 5 post-wounding, in double, but most significant in single knockout, indicating their involvement in TGFβ1 activation. Thus, although MMP3 does not compensate for the lack of fibroblast-MMP14 in tissue homeostasis, simultaneous deletion of both proteases in fibroblasts delays wound closure during skin repair. Notably, single and double deficiency of these proteases modulates myofibroblast formation and resolution in wounds.

Abstract PO012: In silico drug repurposing identifies mebendazole as a treatment option for chemoresistant hepatoblastoma

Abstract Resistance to conventional chemotherapy remains a huge challenge in the clinical management and treatment of hepatoblastoma, the most common liver tumor of childhood. The in silico repurposing of drugs with known pharmacokinetics and safety profiles, which have been approved for other indications, represents a promising strategy to identify new drugs effective in chemoresistant hepatoblastoma. In this study, we integrated RNA sequencing-derived gene expression data into the pharmacologic perturbation prediction tool Connectivity Map (CMap) and identified the clinical widely used anthelmintic drug mebendazole as a putative drug to circumvent chemoresistance in hepatoblastoma. Consequently, we experimentally validated the efficacy of mebendazole in permanent and patient-derived xenograft cell lines that are resistant to cisplatin, the therapeutic backbone of hepatoblastoma treatment. Viability assays clearly indicated a potent reduction of tumor cell growth upon mebendazole treatment in a dose-dependent manner. In contrast, similar mebendazole concentrations had little inhibitory effect on the growth of normal neonatal and adult skin fibroblasts. The combination of mebendazole and cisplatin revealed a strong synergistic effect, which was comparable to the one seen with cisplatin and doxorubicin (cardiotoxic), the current standard treatment for high-risk hepatoblastoma patients. Moreover, mebendazole treatment resulted in reduced colony formation capability, induction of apoptosis, and cell cycle arrest of hepatoblastoma cells. Immunofluorescent staining of alpha-tubulin showed that mebendazole causes blockage of microtubule formation and subsequent RNA sequencing analyses confirmed the transcriptional downregulation of tubulins as the major mode of action of mebendazole treatment. Most importantly, mebendazole significantly reduced tumor growth in a subcutaneous xenograft transplantation mouse model. In conclusion, our results strongly support the clinical use of mebendazole as a replacement for doxorubicin in the treatment of chemoresistant hepatoblastoma. This could potentially not only improve outcome but also reduce severe long-term side effects. Citation Format: Qian Li, Salih Demir, Xuanwen Bao, Alexandra Wagner, Yanxin Fan, Stefano Cairo, Roland Kappler. In silico drug repurposing identifies mebendazole as a treatment option for chemoresistant hepatoblastoma [abstract]. In: Proceedings of the AACR Special Conference: Advances in the Pathogenesis and Molecular Therapies of Liver Cancer; 2022 May 5-8; Boston, MA. Philadelphia (PA): AACR; Clin Cancer Res 2022;28(17_Suppl):Abstract nr PO012.

Cellular taxonomy of Hic1+ mesenchymal progenitor derivatives in the limb: from embryo to adult

Tissue development and regeneration rely on the cooperation of multiple mesenchymal progenitor (MP) subpopulations. We recently identified Hic1 as a marker of quiescent MPs in multiple adult tissues. Here, we describe the embryonic origin of appendicular Hic1+ MPs and demonstrate that they arise in the hypaxial somite, and migrate into the developing limb at embryonic day 11.5, well after limb bud initiation. Time-resolved single-cell-omics analyses coupled with lineage tracing reveal that Hic1+ cells generate a unique MP hierarchy, that includes both recently identified adult universal fibroblast populations (Dpt+, Pi16+ and Dpt+Col15a1+) and more specialised mesenchymal derivatives such as, peri and endoneurial cells, pericytes, bone marrow stromal cells, myotenocytes, tenocytes, fascia-resident fibroblasts, with limited contributions to chondrocytes and osteocytes within the skeletal elements. MPs endure within these compartments, continue to express Hic1 and represent a critical reservoir to support post-natal growth and regeneration.

Abstract P2050: Acetyl-coa Synthesis Is Required For Chromatin Remodeling In Myofibroblast Differentiation And Persistence

Heart failure (HF) features fibrotic remodeling by myofibroblasts, a differentiated fibroblast population responsible for wound repair. Discovering mechanisms of myofibroblast formation and function may yield novel targets to delay or reverse HF. Myofibroblasts metabolically reprogram to mediate transcriptional activation of fibrotic genes through chromatin remodeling. We previously reported that α-ketoglutarate production for histone demethylation is essential for cardiac fibrosis, but metabolic regulation of histone acetylation in fibrosis is unclear. ATP-citrate lyase (ACLY) and Acetyl-coenzyme A synthetase 2 (ACSS2) synthesize acetyl-CoA in the cytoplasm and have also been reported to supply substrate for histone acetyltransferases in the nucleus to modify regulatory histone residues. To investigate acetyl-CoA metabolism in myofibroblast formation, we stimulated adult mouse and human cardiac fibroblasts (CFs) with the pro-fibrotic agonist transforming growth factor β (TGFβ) and treated cells with pharmacological inhibitors of ACLY and ACSS2. Either ACLY or ACSS2 inhibition sufficiently reverted differentiated myofibroblasts to a non-fibrotic phenotype, even during continuous TGFβ stimulation. Genetic deletion of ACLY in fibroblasts recapitulated these results. Further, ACLY inactivation was sufficient to decrease global histone acetylation. ACLY deletion, specifically in activated myofibroblasts in the adult mouse heart, slowed LV functional decline and remodeling in a model of pressure overload HF. Our data indicate that ACLY and ACSS2 are necessary for myofibroblast differentiation and persistence. We hypothesize that acetyl-CoA synthesis is necessary for histone acetylation required for activation of myofibroblast genes. Ongoing work will determine the molecular mechanisms of both enzymes in chromatin remodeling and in cardiac injury. In summary, acetyl-CoA producing enzymes are attractive clinical targets to reverse cardiac fibrosis.

Abstract P1132: Cardiac Tissue Chip Model Of Arteriovenous-fistula-associated Hemodynamics Elicits Fibrotic Changes Seen In Mouse Model

Introduction: Cardiovascular disease is the primary cause of death amongst end-stage renal disease (ESRD) patients. Though arteriovenous fistulas (AVFs) are the access of choice for hemodialysis, joining a high-pressure artery and low-pressure vein leads to cardiac volume overload acutely. Debate exists as to the cardiac ramifications of AVFs, due in part to the difficulty of recruiting ESRD patients and controls for prospective studies. Animal models have been essential in AVF studies, but their usefulness is limited by interspecies differences in physiology and other factors. Thus, we have developed a three-dimensional (3D) cardiac tissue chip with tunable pressure and stretch to model the acute hemodynamic changes associated with AVF creation. Hypothesis: In this study, we aimed to replicate the hemodynamics of murine AVF models in vitro and hypothesized that if 3D cardiac constructs were subjected to “volume overload”, they would display fibrosis and key gene expression changes seen in AVF mice. Methods: Mice underwent either AVF or sham procedure and were monitored for 28 d. Cardiac tissue constructs composed of h9c2 rat cardiac myoblasts and normal adult human dermal fibroblasts in hydrogel were seeded into devices and exposed for 96 h to 100 mmHg/10 mmHg pressure (0.4 s/0.6 s) at 1 Hz. "Systolic" pressure was generated via pneumatic pump while a hydrostatic pressure head gave rise to "diastolic" pressure. The controls were exposed to “normal” stretch while the experimental group was exposed to “volume overload”. Results and Conclusions: The in vitro model yielded similar fibrosis-related gene expression profiles (see figure) and patterns of fibrosis as the murine model.

Abstract P1067: IRS Mediated Recruitment Of PI3Kgamma By Insulin Inhibits Beta-adrenergic Receptor Function

Insulin (INS) treatment results in impaired response to β-agonist isoproterenol (ISO) associated with phosphorylated β2-adrenergic receptor (β2AR) and impaired cAMP response. Although INS does not mediate dissociation of G-protein Gβγ subunits, yet surprisingly recruits phosphoinositide 3-kinase γ (PI3Kγ) to the plasma membrane. Correspondingly, knock-down of PI3Kγ (PI3Kγ KD) in HEK 293 or ablation in primary adult cardiomyocytes and fibroblasts (isolated from PI3Kγ knockout mice) abrogated β2AR phosphorylation reflecting a key role for PI3Kγ in retaining β2AR phosphorylation. Also, adult cardiomyocytes isolated from C57Bl6 mice showed significant loss of in vitro ISO-stimulated cardiomyocyte contraction upon INS pre-treatment which was remarkably preserved in the PI3Kγ knockout cardiomyocytes despite INS. As PI3Kγ is traditionally recruited to the βAR complex by the Gβγ subunits, we hypothesized that INS-mediates Gβγ-independent recruitment of PI3Kγ to the βAR complex underlying its dysfunction. INS stimulation is known to recruit insulin receptor substrate (IRS 1 & 2) to the receptor complex, and therefore, we tested whether PI3Kγ interacts with IRS 1/2 leading to Gβγ-independent recruitment of PI3Kγ to the β2AR complex. Immunoprecipitation PI3Kγ following INS showed that PI3Kγ interacts with IRS2 recruiting PI3Kγ to the β2AR complex bypassing the traditional Gβγ-dependent pathway. Since PI3Kγ KD resulted in loss of INS-mediated β2AR phosphorylation, we tested whether PI3Kγ inhibits protein phosphatase 2A (PP2A) function impairing β2AR de-phosphorylation. INS treatment resulted in significant loss of β2AR-associated PP2A activity which was rescued in PI3Kγ KD cells showing that PI3Kγ impairs PP2A function. Furthermore, our studies show that PI3Kγ phosphorylates the endogenous inhibitor of PP2A, I2PP2A which then robustly binds and inhibits PP2A activity impairing β2AR dephosphorylation. Consistently, CRISPR ablation of I2PP2A relieves this inhibition on PP2A leading to increased PP2A activity. This reduces accumulation of phosphorylated βARs despite the presence of PI3Kγ showing an underappreciated regulation of PP2A by insulin through non-canonical recruitment of PI3Kγ that impairs β2AR function.

Abstract P2025: BET Bromodomain Proteins Are Necessary For TGFβ2-Mediated Myofibroblast Activation

Fibrosis is a key feature of dilated cardiomyopathy (DCM). Stress signaling triggers the activation of quiescent fibroblasts to myofibroblasts. Bromodomain and extraterminal (BET) epigenetic reader proteins integrate stress-responsive signaling. We explored the role of BETs on distinct inflammatory signaling pathways in cardiac fibroblasts. Fibroblasts were isolated from wild type hearts using the Langendorff procedure. Cell cultures were treated with vehicle, the pan-BET inhibitor JQ1, or siRNA targeting Smad3 or Rela (to inhibit TGFβ and NFκB pathways, respectively) followed by TGFβ2 stimulation. Gene expression was assessed by QPCR, α-smooth muscle actin (αSMA) was quantified by western blot, and NFκB transcription was evaluated using a dual luciferase reporter assay. The interaction between BRD4 and SMAD3 was assessed by coimmunoprecipitation (coIP) in immortalized adult mouse cardiac fibroblast cell cultures treated with TGFβ2, JQ1, or vehicle. TGFβ2-induced fibroblast activation was ablated by JQ1 and Smad3 siRNA (reduced expression of Acta2, Col3a1, Postn and αSMA). CoIP revealed a direct interaction between BRD4 and SMAD3 in fibroblasts, which increased 2.2-fold (p<0.05) after TGFβ2 stimulation. By contrast, Rela siRNA alone induced myofibroblast gene expression ( Acta2 , 6.9-fold; Col3a1 , 7.0-fold; Postn , 11.2-fold; p<0.05 vs. vehicle for all), and increased αSMA levels (2.2-fold; p<0.05). This effect of Rela siRNA was similar to that observed with TGFβ2 stimulation. Further, TGFβ2 inhibited NFκB-driven gene transcription (-2.9-fold; p<0.05 vs. vehicle). These data demonstrate that BRD4 is a critical co-activator of TGFβ2-SMAD3 signaling and cardiac fibroblast activation. We also found that NFκB signaling is downregulated by TGFβ2, suggesting that NFκB may modulate inflammatory gene network activation.

Donor Age and Time in Culture Affect Dermal Fibroblast Contraction in an In Vitro Hydrogel Model.

Current cellular hydrogel-based skin grafts composed of human dermal fibroblasts and a hydrogel scaffold tend to minimize contraction of full-thickness skin wounds and support skin regeneration. However, there has been no comparison between the sources of the dermal fibroblast used. Products using human adult or neonatal foreskin dermal fibroblasts are often expanded in vitro and used after multiple passages without a clear understanding of the effects of this initial production step on the quality and reproducibility of the cellular behavior. Based on the known effects of 2D tissue culture expansion on cellular proliferation and gene expression, we hypothesized that differences in donor age and time in culture may influence cellular properties and contractile behavior in a fibroblast-populated collagen matrix. Using porcine skin as a model based on its similarity to human skin in structure and wound healing properties, we isolated porcine dermal fibroblasts of three different donor ages for use in a 2D proliferation assay and in a 3D cell-populated collagen matrix contractility assay. In 2D cell culture, doubling time remained relatively consistent between all age groups from passage 1 to 6. In the contractility assays, fetal and neonatal groups contracted faster and generated more contractile force than the adult group at passage 1 in vitro. However, after five passages in culture, there was no difference in contractility between ages. These results show how cellular responses in a hydrogel scaffold differ based on donor age and time in culture in vitro, and suggest that consistency in the cellular component of bioengineered skin products could be beneficial in the biomanufacturing of consistent, reliable skin grafts and graft in vivo models. Future research and therapies using bioengineered skin grafts should consider how results may vary based on donor age and time in culture before seeding. Impact statement Little is known about the impact of donor cell age and time in culture on the contraction of cellular, hydrogel-based skin grafts. These results show how cellular phenotypes of porcine fibroblasts differ based on donor age and time in culture. This information is beneficial when addressing important inconsistencies in biomanufacturing of bioengineered skin grafts and in vitro models. These findings are relevant to research and therapies using bioengineered skin graft models and the results can be used to increase reproducibility and consistency during the production of bioengineered skin constructs. The information from this study can be extrapolated to future in vivo studies using human dermal fibroblasts in an in vivo model to help determine the best donor age and time in culture for optimal wound healing outcomes or more reproducible in vitro testing constructs.

Lipoplexes for effective in vitro delivery of microRNAs to adult human cardiac fibroblasts for perspective direct cardiac cell reprogramming

Design of nanocarriers for efficient miRNA delivery can significantly improve miRNA-based therapies. Lipoplexes based on helper lipid, dioleoyl phosphatidylethanolamine (DOPE) and cationic lipid [2-(2,3-didodecyloxypropyl)-hydroxyethyl] ammonium bromide (DE) were formulated to efficiently deliver miR-1 or a combination of four microRNAs (miRcombo) to adult human cardiac fibroblasts (AHCFs). Lipoplexes with amino-to-phosphate groups ratio of 3 (N/P 3) showed nanometric hydrodynamic size (372 nm), positive Z-potential (40 mV) and high stability under storage conditions. Compared to commercial DharmaFECT1 (DF), DE-DOPE/miRNA lipoplexes showed superior miRNA loading efficiency (99 % vs. 64 %), and faster miRNA release (99 % vs. 82 % at 48 h). DE-DOPE/miR-1 lipoplexes showed superior viability (80–100 % vs. 50 %) in AHCFs, a 2-fold higher miR-1 expression and Twinfilin-1 (TWF-1) mRNA downregulation. DE-DOPE/miRcombo lipoplexes significantly enhanced AHCFs reprogramming into induced cardiomyocytes (iCMs), as shown by increased expression of CM markers compared to DF/miRcombo.

Effects of bone morphogenetic protein 4 on TGF-β1-induced cell proliferation, apoptosis, activation and differentiation in mouse lung fibroblasts via ERK/p38 MAPK signaling pathway.

Fibroblasts, in particular myofibroblasts, are the critical effector cells in idiopathic pulmonary fibrosis (IPF), a deadly lung disease characterized by abnormal lung remodeling and the formation of “fibroblastic foci”. Aberrant activation of TGF-β1 is frequently encountered and promotes fibroblast proliferation, activation, and differentiation in pulmonary fibrosis. Hence, the inhibition of TGF-β1-induced lung fibroblast activation holds promise as a therapeutic strategy for IPF. The present study aimed to investigate the potential effect and underlying mechanisms of bone morphogenetic protein 4 (BMP4) on TGF-β1-induced proliferation, apoptosis, activation and myofibroblast differentiation of adult lung fibroblasts. Here, we demonstrated that BMP4 expression was significantly decreased in TGF-β1-stimulated mouse primary lung fibroblasts (PLFs). BMP4 inhibited proliferation and apoptosis resistance of TGF-β1-stimulated mouse PLFs. BMP4 suppressed TGF-β1-induced fibroblast activation and differentiation in mouse PLFs. We also found that BMP4 inhibited TGF-β1-induced ERK and p38 MAPK phosphorylation. Our findings indicate that BMP4 exerts its anti-fibrotic effects by regulating fibroblast proliferation, apoptosis, activation and differentiation via the inhibition of the ERK/p38 MAPK signaling pathway, and thus has a potential for the treatment of pulmonary fibrosis.

Chemical Replacement of Noggin with Dorsomorphin Homolog 1 for Cost-Effective Direct Neuronal Conversion.

The direct conversion of adult human skin fibroblasts (FBs) into induced neurons (iNs) represents a useful technology to generate donor-specific adult-like human neurons. Disease modeling studies rely on the consistently efficient conversion of relatively large cohorts of FBs. Despite the identification of several small molecular enhancers, high-yield protocols still demand addition of recombinant Noggin. To identify a replacement to circumvent the technical and economic challenges associated with Noggin, we assessed dynamic gene expression trajectories of transforming growth factor-β signaling during FB-to-iN conversion. We identified ALK2 (ACVR1) of the bone morphogenic protein branch to possess the highest initial transcript abundance in FBs and the steepest decline during successful neuronal conversion. We thus assessed the efficacy of dorsomorphin homolog 1 (DMH1), a highly selective ALK2-inhibitor, for its potential to replace Noggin. Conversion media containing DMH1 (+DMH1) indeed enhanced conversion efficiencies over basic SMAD inhibition (tSMADi), yielding similar βIII-tubulin (TUBB3) purities as conversion media containing Noggin (+Noggin). Furthermore, +DMH1 induced high yields of iNs with clear neuronal morphologies that are positive for the mature neuronal marker NeuN. Validation of +DMH1 for iN conversion of FBs from 15 adult human donors further demonstrates that Noggin-free conversion consistently yields iN cultures that display high βIII-tubulin numbers with synaptic structures and basic spontaneous neuronal activity at a third of the cost.

LB1014 Hedgehog signaling reprograms hair follicle mesenchyme toward a hyper-activated state

Dermal papilla (DP) is the key mesenchymal niche cell type, that regulates cyclic regeneration of hair follicles by orchestrating paracrine signaling crosstalk with epithelial progenitors. We discovered that leptin receptor (Lepr) is a robust marker gene of adult DP fibroblasts in mice and that constitutive Cre and inducible CreER genetic tools, whose activity follows the expression of the Lepr isoform B, can efficiently target DPs for labeling and gene modulation during both growth (anagen) and rest (telogen) phases of the hair growth cycle.

599 Selective inhibition Of fibro-inflammatory kinase TAK1: A potential therapeutic strategy to ameliorate systemic sclerosis

Fibrosis leads to failure of the skin, lungs, and other organs in systemic sclerosis (SSc); accounts for substantial morbidity and mortality; and lacks effective therapy. Recent findings implicated TGFβ-activated kinase 1 (TAK1), triggered by TGF-β and toll-like receptor signaling, in SSc pathogenesis. The objectives were to evaluate the activation of TAK1 signaling axis in SSc patients and to evaluate the antifibrotic ability of pharmacological TAK1 blockade in organ fibrosis. HS-276, a drug-like novel small molecule inhibitor of TAK1 was screened for its anti-fibrotic potential in cell cultures using foreskin, adult and SSc skin fibroblasts, and in bleomycin induced skin and lung fibrosis model.