Abstract
Pathological fibrosis is a significant complication of surgical procedures resulting from the accumulation of excess collagen at the site of repair which can compromise the tissue architecture and severely impede the function of the affected tissue. Few prophylactic treatments exist to counteract this process; however, the use of amniotic membrane allografts has demonstrated promising clinical outcomes. This study aimed to identify the underlying mechanism of action by utilizing relevant models that accurately represent the pathophysiology of the disease state. This study employed a pro-fibrotic in vitro system using TGFβ1 stimulation and macromolecular crowding techniques to evaluate the mechanism by which amniotic membrane allografts regulate collagen biosynthesis and deposition. Following treatment with dehydrated human amnion chorion membrane (DHACM), subsequent RNA sequencing and functional enrichment with Reactome pathway analysis indicated that amniotic membranes are indeed capable of regulating genes associated with the composition and function of the extracellular matrix. Furthermore, macromolecular crowding was used in vitro to expand the evaluation to include both the effects of DHACM and a lyophilized human amnion/chorion membrane (LHACM). DHACM and LHACM regulate the TGFβ pathway and myofibroblast differentiation. Additionally, both DHACM and LHACM modulate the production, secretion, and deposition of collagen type I, a primary target for pathological fibrosis. These observations support the hypothesis that amniotic membranes may interrupt pathological fibrosis by regulating collagen biosynthesis and associated pathways.
Similar content being viewed by others
Introduction
Upon acute dermal injury, the body responds by initiating regenerative and reparative pathways to restore tissue architecture and function. Collagen remodeling continues for months after wound closure and the tensile strength of the repaired tissue increases to about 80–85% of normal tissue if all processes proceed without any perturbations1. However, chronic and persistent pathologic circumstances may lead to an abnormal repair process with excessive accumulation of extracellular cellular matrix (ECM)2. The resultant scarring can range in severity from poor cosmetic outcomes to significant restrictions in function, identifying a significant unmet need. Therefore, targeting the molecular mechanisms associated with regulating ECM synthesis, deposition, and degradation could highlight potential therapeutic targets for the development of novel and effective therapies3,4.
An ideal clinical treatment would support the healing cascade to enable accelerated recovery and improved quality of healing, much like the fetal response to injury. The fetal dermis can regenerate a non-disrupted collagen matrix that is identical to that of the original tissue, commonly referred to as scarless healing5. While attempts have been made to harness this mechanism, modalities aimed at recreating fetal wound healing in adult tissues have not proven successful6,7. The difficulty largely stems from the complex mechanism that is not well-understood; however, similar properties have been reported in amniotic membranes. Allografts made from amniotic membrane have been used successfully in the treatment of complex wounds including burns, diabetic foot ulcers, venous ulcers, ocular injuries, and uterine adherences8,9,10,11. The primary endpoint in these studies is rate of closure; however, observations of reduced scarring and decreased incidence of recurrence may be attributable to amniotic membrane’s ability to regulate ECM architecture, making it a potential candidate for the treatment of fibrotic disease12,13,14.
Evaluating the underlying mechanism of action for the observed clinical outcomes can be difficult with the inherent shortcomings of in vitro cell culture systems. It is necessary to recreate the in vivo cellular environment by mimicking the complex network of the ECM containing fibroblasts that drive ECM deposition and remodeling15,16. Standard in vitro models are plagued by sluggish production and deposition of ECM components, severely limiting the ability to recreate hyperactive fibrosis. Limitations of the extracellular post-translational modifications of collagen, namely the slow enzymatic conversion of immature pro-collagen to mature collagen, and the formation of covalent crosslinks, results in minimal amounts of functional mature collagen in vitro17,18,19. Therefore, the data generated from these experiments cannot necessarily be extrapolated to the clinical setting, as the model does not fully represent clinical etiology. Macromolecular crowding (MMC) is a technique which facilitates more representative cell–cell interactions and enzyme–substrate reactions by closely approximating the components of the culture system, thus promoting the deposition of a more complex ECM20. This system provides a more physiologically relevant model for assessing anti-fibrotic therapeutics21,22,23.
In this study, two unique PURION® processed amniotic tissue allografts were evaluated for their ability to regulate collagen biosynthesis and deposition. Lyophilized human amnion, intermediate layer, and chorion membrane (LHACM) is a freeze-dried tri-layer allograft; whereas, dehydrated human amnion, chorion membrane (DHACM) is an air-dried bi-layer allograft. Previous experiments demonstrated that this patented and proprietary process retains well known regulatory proteins inherent to amniotic tissues, and preserves the bioactivity to stimulate cellular activities, such as proliferation, migration, and biosynthesis in multiple cell types24,25,26,27,28,29,30. Moreover, DHACM has been shown to contain anti-fibrotic potential through the regulation of the TGFβ-SMAD pathway leading to the modulation of myofibroblast contraction suggesting a potential impact on the production and deposition of ECM components31. However, the limitations of the culture system potentially necessitate the use of a more physiologically relevant model to validate this finding for DHACM and evaluate LHACM. This study aimed to provide an assessment of the effects of LHACM and DHACM treatment in a physiologically relevant in vitro fibrotic model on collagen production, deposition, and maturation in a simulated, pro-fibrotic environment.
Material and methods
Human amnion/chorion membrane
Human birth tissue was acquired and processed at previously described31. Briefly, human placentas, from Caesarean sections, were donated under informed written consent in compliance with the Food and Drug Administration’s Good Tissue Practice and American Association of Tissue Banks standards. MIMEDX Group is accredited by American Association of Tissue Banks for donor eligibility assessment, informed consent, acquisition, processing, release, storage, and distribution of birth tissue for transplantation and therefore this study did not require institutional approval. All donors were confirmed to be free of infectious diseases, including human immunodeficiency virus (HIV), human T-lymphotropic virus (HTLV), hepatitis B and C, and syphilis. Under controlled conditions, amnion and chorion are separated from the placenta and processed in accordance with the proprietary PURION® Process, in which the amnion and chorion layers are gently cleansed, laminated and dehydrated32,33,34. LHACM (MIMEDX, Marietta, GA) is a lyophilized human allograft composed of laminated amnion, intermediate and chorion layer and DHACM (MIMEDX, Marietta, GA) is a dehydrated human allograft comprised of laminated amnion and chorion. Both are derived from the human amniotic sac.
Extract preparation
Soluble extracts for cell culture experiments were prepared as previously described31. Briefly, 1–3 donors of DHACM and LHACM were minced, combined, and extracted overnight at 40 mg of tissue per milliliter of basal DMEM (Dulbecco’s modified eagle’s medium (DMEM) containing 1% penicillin streptomycin and 1% sodium pyruvate). The resulting extract was clarified and collected in a sterile container, followed by preparation at testing concentrations by dilution in basal DMEM. Three independent extracts of DHACM and LHACM samples were used in each subsequent experiment.
Cell culture and treatment
Human dermal fibroblasts (HDF) (Thermo Fisher Scientific, Waltham, MA) between passages 5–9 were maintained as described previously in DMEM (Thermo Fisher Scientific, Waltham, MA) supplemented with 10% fetal bovine serum (FBS) (Thermo Fisher Scientific, Waltham, MA), 1% penicillin streptomycin (Fisher Scientific, Waltham, MA) and 1% sodium pyruvate (Thermo Fisher Scientific, Waltham, MA) at 37 °C, 5% CO2 until 80% confluent31.
To initiate experiments under MMC conditions, cells were seeded in 96 well plates, 6 well plates, 100 mm dishes, and 4 well slides plated at 10,000 cells/cm2 for each experiment. After 4 h, adherent cells were washed with basal DMEM, and incubated overnight in DMEM containing 0.4% FBS, 1% penicillin streptomycin, and 1% sodium pyruvate followed by treatment of HDFs for six days. Culture media and treatments were replaced on day 3. All treatments were carried out under MMC conditions in DMEM containing 0.4% FBS, 1% penicillin streptomycin, 1% sodium pyruvate, 1 mM of L-ascorbic acid 2-phospate (Sigma-Aldrich, St. Louis, MO), and a mixture of 37.5 mg/mL Ficoll 70 kDa (Sigma-Aldrich, St. Louis, MO) and 25 mg/ml Ficoll 400 kDa (Sigma-Aldrich, St. Louis, MO). The following control groups were included for each experiment: basal media and 10 ng/mL TGFβ1 (R&D Systems, Minneapolis, MN). Treatments were carried out with LHACM (10 mg/mL, and 1 mg/mL) or DHACM (20 mg/mL, 10 mg/mL, and 1 mg/mL) in the presence of 10 ng/mL TGFβ1. Extracts were prepared as described above.
RNA sequencing analysis
RNA isolation, library preparation and RNA sequencing was performed by Novogene (Sacramento, CA). Messenger RNA was purified from total RNA followed by library preparation. Libraries were sequenced on NovaSeq 6000, an Illumina platform. Differential expression analysis was conducted using DESeq2 R package (version 1.20.0). The resulting p values were adjusted using the Benjamini and Hochberg’s approach for controlling the false discovery rate. Genes with an adjusted p value < 0.05 found by DESeq2 and an absolute value of log2 fold change greater than 0.75 were differentially expressed. Reactome Pathway enrichment analysis of differentially expressed genes (DEGs) was done using the Reactome database’s default settings (http://www.reactome.org). This analysis allowed identification of over-represented biological pathways and processes associated with the gene expression changes observed in the dataset. The significance of pathway enrichment was determined based on multiple statistical tests, and pathways with adjusted p values below p < 0.05 were considered significantly enriched. Data visualization was done utilizing Novogene’s NovoMagic analysis portal.
Quantitative polymerase chain reaction
RNA and complimentary DNA was prepared utilizing the Cells-2-Ct Kit (Thermo Fisher Scientific, Waltham, MA), per the manufacturer’s protocol. Quantitative polymerase chain reaction amplification for each gene target was performed on a QuantStudio™ 7 Flex Real-Time PCR System (Thermo Fisher Scientific, Waltham, MA) using predesigned TaqMan Gene Expression Assays for ACTA2 (Hs00426835_g1), BMP1 (Hs00241807_m1), LOX (Hs00942483_m1), TGM2 (Hs01096681_m1), COL1A1 (Hs00164004_m1), CTGF (Hs00164004_m1), and eukaryotic 18s (4319413E) purchased from Thermo Fisher Scientific (Waltham, MA). Each replicate sample was analyzed in duplicate. Relative mRNA concentrations of the genes of interest were normalized to the relative mRNA of the housekeeping gene 18S. Differences were calculated with the comparative Ct method for each target gene with the results expressed as a fold increase over the control. For graphical representation, the technical replicate values for each sample were combined.
Western blotting
Total cellular protein was solubilized in radioimmunoprecipitation assay buffer containing proteinase inhibitors. After removal of cellular debris, cell culture supernatants were concentrated using protein concentrators with a molecular weight cutoff of 3 kDa. Samples of LHACM and DHACM extract were used as control for analysis of cell culture supernatants. The protein concentrations were determined using bicinchoninic acid protein assay reagent. Equal amounts of the proteins were separated on a 4–12% gradient sodium dodecyl sulfate poly-acrylamide gel and transferred to nitrocellulose membranes as previously described31. After blocking with 5% non-fat dry milk in 1× Tris Buffered Saline 0.05% Tween 20 for 1 h, membranes were probed with primary antibodies overnight at 4 °C: αSMA (19,245, Cell Signaling Technology, Danvers, MA), phospho-SMAD2 Ser465/467 (3108, Cell Signaling Technology, Danvers, MA), SMAD2 (3103 Cell Signaling Technology, Danvers, MA), phospho-SMAD3 Ser423/425 (ab40854, Abcam, Waltham, MA), SMAD3 (ab40854, Abcam, Waltham, MA), BMP1 (ab38953, Abcam, Waltham, MA), LOX (ab174316, Abcam, Waltham, MA), TGase2 (ab2386, Abcam, Waltham, MA), and GAPDH (ab8245, Abcam, Waltham, MA). Following overnight incubation, anti-mouse or anti-rabbit IgG HRP-conjugated secondary antibodies (Abcam, Cambridge, MA) were used to detect binding of antibodies. Immunoreactive proteins were visualized on the Amersham Imager 600 (GE Healthcare Systems Piscataway, NJ) after exposure to chemi-luminescence reagents (Cell Signaling Technology, Danvers, MA).
Immunofluorescence
Cells, cultured on 4-well slides, were fixed with 4% paraformaldehyde (Electron Microscopy Science, Hatfield, PA) for 30 min at room temperature. For intracellular analysis, cellular membranes were permeabilized with 0.1% Trition-X-100 for 2 min. Cells were blocked in serum free protein block (Agilent DAKO, Santa Clara, CA) for 1 h at room temperature. Incubation with primary antibody against collagen type I (ab138492, Abcam, Waltham, MA) diluted in Antibody Diluent (Agilent DAKO, Santa Clara, CA) was carried out overnight at 4 °C. For visualization, cells were incubated with Goat anti-Mouse IgG (H + L) Alexa Fluor 488 (A11034, Thermo Fisher Scientific, Waltham, MA) and DAPI 4′, 6′-diamidino-2-phenylindole (H-1500 Vector Laboratories, Burlingame, CA) to identify nuclei. Images were acquired on a Leica microscope fitted with 20× objective using Leica Application Suite Advance Fluorescence software and the Thunder Imager from Leica (Leica Microsystems, Wetzlar, Germany). Semi-quantitative analysis was performed on ten independent fields per treatment condition using the ImageJ software (NIH)35. Values for each sample were combined for graphical representation.
Matrix deposition analysis
At day 6, the matrix deposited at the bottom of the wells together with the cells was washed twice with PBS and stored at − 80 °C. Prior to digestion, the matrix was thawed and dissolved with 0.5 M acetic acid overnight followed by digestion with 0.5 mg/mL Pepsin (Sigma-Aldrich St. Louis, MO), in 0.01 M HCl. Samples were neutralized with 1× LDS sample buffer (Thermo Fisher, Waltham, MA) and were analyzed by SDS-PAGE under reducing conditions. Protein bands were stained with the Silver Stain Kit (Thermo Fisher, Waltham, MA) according to the manufacturer’s instructions. Gel images were obtained with Amersham Imager 600 (GE Healthcare Systems Piscataway, NJ).
Statistical analysis
All values are reported as mean +/− standard deviation and statistical analyses were performed using GraphPad Prism software (version 10.0.2). p values ≤ 0.05 were considered statistically significant. Graphical illustrations and one-way ANOVA with pairwise comparisons were made using a Tukey test.
Results
Transcriptional profiling
DHACM has been previously shown to regulate the TGFβ signaling pathway, leading to a reduced contractile phenotype31. This was further investigated in this MMC model using RNA sequencing to assess the gene expression patterns in HDFs and TGFβ1 stimulus with and without DHACM treatment. Treatment of cells with TGFβ1 resulted in 2968 DEGs of which 1565 were down regulated and 1403 were upregulated (Supplementary Fig. S1a). DHACM + TGFβ1 treatment resulted in 3054 DEGs of which 1716 were down regulated and 1338 were upregulated (Fig. 1a). A full list of DEGs is available in Supplementary Tables S1 and S2. Hierarchical clustering demonstrated a clear separation between the two groups (Fig. 1b).
Further refinement and greater biological characterization of DEGs were pursued through functional enrichment analysis utilizing Reactome Pathway analysis. Comparative analysis between the TGFβ1 and basal samples identified the top 10 enriched pathways contained well known pathways involved in the development of fibrosis, including extracellular matrix organization and collagen formation (Supplementary Fig. S1c). The majority of DEGs associated with each Reactome were up regulated by TGFβ1. Interestingly, the top 10 Reactome pathways affected with DHACM treatment include biological pathways associated with regulation of the ECM including, extracellular matrix organization, collagen formation and collagen degradation with a majority of DEGs being down regulated with DHACM treatment (Fig. 1c).
DHACM and LHACM attenuates the TGFβ1-mediated fibrotic phenotype
Under MMC conditions, with recombinant TGFβ1 stimulation, HDFs increased the expression of phosphorylated SMAD2 and SMAD3 (Fig. 2e), two key transcription factors in the TGFβ signaling cascade. Treatment at 20 and 10 mg/mL DHACM + TGFβ1 reduced the phosphorylation of SMAD2 and SMAD3. The phosphorylation of SMAD2 was decreased by LHACM at 10 and 1 mg/mL + TGFβ1, however, SMAD3 phosphorylation was only impacted at 10 mg/mL LHACM + TGFβ1. Total protein expression was unchanged (Fig. 2e).
As part of the fibrotic process, TGFβ1 governs increased expression of pro-fibrotic genes and myofibroblast differentiation36,37,38,39. Recombinant TGFβ1 stimulation resulted in an increase in mRNA expression of CTGF which is known to contribute to the accumulation of collagen and reduced ECM degradation40,41 (Fig. 2c and d). As shown in Fig. 2c, treatment with 20 and 10 mg/mL DHACM + TGFβ1 significantly suppressed the TGFβ1-dependent induction of CTGF mRNA. Of note, CTGF was significantly suppressed to levels seen in the basal control by treatment with 10 mg/mL LHACM + TGFβ1 (Fig. 2d). A key indicator of fibroblast differentiation into myofibroblasts is the marked increase of αSMA expression38. Fibroblasts, under MMC conditions, stimulated with 10 ng/mL of TGFβ1 showed increased mRNA expression of ACTA2, the gene coding for αSMA, compared with that of basal control (unstimulated) (Fig. 2a and b). Treatment with DHACM significantly suppressed the TGFβ1-dependent induction of the ACTA2 mRNA in a dose-dependent manner. Moreover, the TGFβ1-dependent increase of ACTA2 mRNA was decreased to the basal level at both the 20 and 10 mg/mL doses (Fig. 2a). Similarly, treatment with 10 and 1 mg/mL LHACM + TGFβ1 decreased ACTA2 expression with 10 mg/mL resulting in mRNA levels similar to the basal level (Fig. 2b). Consequently, western blotting demonstrated DHACM and LHACM significantly inhibited the TGFβ1 induced protein expression of αSMA at all concentrations tested (Fig. 2e).
DHACM and LHACM regulate collagen biosynthesis and deposition
A comparison of the control groups demonstrated that HDFs under MMC conditions and stimulated with TGFβ1 resulted in increased gene expression of COL1A1, compared with that of basal control. COL1A1 expression was significantly reduced by treatment with 20 mg/mL of DHACM + TGFβ1 and 10 mg/mL LHACM + TGFβ1 (Fig. 3a and b). Further evaluation of the regulation of collagen synthesis and subsequent secretion was assessed in cells that were permeabilized with 0.1% Triton X-100 for visualization of intracellular and extracellular collagen type I. Immunofluorescence staining confirmed that TGFβ1 stimulation increases the extracellular collagen as suggested by the diffuse, mesh-like pattern. In response to DHACM and LHACM treatment, collagen type I remains predominately localized intracellularly (Fig. 3c). Semi-quantitative analysis demonstrates that there is a marked decrease of collagen type I in response to DHACM and LHACM treatment (Fig. 3d).
Collagen matrices feature hierarchical structures that are self-assembled through sequential steps. BMP1 cleaves the C-propeptide of procollagen type I during the assembly of extracellular matrix collagen fibrils42. Protein analysis demonstrated that TGFβ1 increased BMP1 protein compared to the basal control. Both DHACM and LHACM reduced the TGFβ1 induced increase in BMP1 (Fig. 4g). These results were confounded by gene expression analysis that shows DHACM + TGFβ1 at concentrations tested and the LHACM + TGFβ1 at 1 mg/mL increased expression of BMP1 (Fig. 4a and d).
Collagen in the extracellular space is stabilized through intra and intermolecular crosslinks catalyzed by the lysyl oxidase (LOX) and Transglutaminase (TGase) family43. Contrary to expectations, LOX gene expression was decreased upon stimulation with TGFβ1 in MMC conditions. However, DHACM treatment at 20 mg/mL further down regulated LOX expression in the presence of TGFβ1. No differences were observed at 10 mg/mL and 1 mg/mL DHACM + TGFβ1. Similarly, 10 mg/mL LHACM + TGFβ1 down regulated LOX expression. No difference was seen with 1 mg/mL LHACM (Fig. 4b and e). LOX is synthesized and processed intracellularly and the resulting proenzyme is secreted into the extracellular space where it undergoes further proteolytical processing to the mature enzyme44. The proenzyme was increased intracellularly upon TGFβ1 stimulation. DHACM treatment in the presence of TGFβ1 resulted in only minor changes at the protein level, whereas LHACM significantly reduced the LOX proenzyme. Additionally, TGFβ1 resulted in an increased intracellular accumulation of the mature form of the LOX enzyme. This effect was significantly reduced by both DHACM and LHACM treatment (Fig. 4g). DHACM treatment returned the protein level to that observed in the basal control (Fig. 4g). Expression of TGM2 was substantially elevated upon TGFβ1 stimulation. LHACM and DHACM treatment in the presence of TGFβ1 reduced the expression of TGM2 at all concentrations tested (Fig. 4c and f). Analysis of protein levels confirm that LHACM and DHACM decreased the TGFβ1 induced protein level of TGase2. DHACM treatment returned the protein level to that observed in the basal control (Fig. 4g).
The modifications elicited by BMP1, LOX, and TGase2 are catalyzed in the extracellular environment necessitating the evaluation of collagen modifying enzymes in the supernatnt43. The extracellular fraction was evaluated using western blotting of cell culture supernatants. The mature form of LOX was increased in the supernatants by TGFβ1 compared to basal. However, treatment with both DHACM (20 mg/mL and 10 mg/mL) and LHACM (10 mg/mL) also significantly increased the amount of mature LOX in the cell culture supernatants (Fig. 4h). Of note, neither the proenzyme nor mature enzyme forms of LOX were detected in the extracts controls. BMP1 was not detected by this method in the cell culture supernatant and assessment of TGase2 was confounded by the presence of this enzyme in the LHACM and DHACM extracts themselves (Supplementary Figure S3).
Collagen type I deposition which was evaluated in cultures of HDFs under MMC conditions. TGFβ1 enhanced extracellular collagen type I deposition as compared to the basal control as assessed by immunofluorescence. As shown in Fig. 5 both DHACM and LHACM prevented the TGFβ1-induced extracellular accumulation of collagen type I in the deposited matrix (Fig. 5a and b). Type 1 collagen deposition was further assessed by pepsin digestion followed by SDS-PAGE. Analysis of solubilized matrices showed that TGFβ1 treatment induced greater collagen type I deposition, however DHACM and LHACM treatment dose dependently reduced the accumulation of collagen type I in the deposited ECM in the presence of TGFβ1 (Fig. 5c).
Discussion
Despite the remarkable heterogeneity in the etiologic mechanisms responsible for the development of fibrotic diseases and in their clinical manifestations, numerous studies have identified common cellular elements that play a critical role in the regulation of fibrosis45. Ultimately, dysregulation of these same elements is responsible for the replacement of normal tissues with compromised or nonfunctional fibrotic tissue. The development of therapeutic strategies that limit the progression of fibrosis without adversely affecting the overall repair process would represent an important technological advancement46. The use of amniotic tissue allografts in severe burns and chronic wounds was originally intended to accelerate wound closure; however, an unexpected outcome of treatment was an improved quality of healing47,48. In a 30-patient pediatric burn case series, the return to normally functioning skin including dynamic compliance, movement, and color was superior in patients treated with DHACM grafts47. In addition to burns, amniotic membranes have also been shown to reduce scar tissue formation and enhance wound healing in diabetic foot ulcers and venous leg ulcers9,49,50,51. The mechanism of action by which amniotic membranes may satisfy this unmet need was explored in this study.
One of the primary cellular mediators of fibrosis is the fibroblast, which when activated becomes a myofibroblast and acquires a contractile phenotype with increased matrix synthesis. This process is largely regulated by the influx of TGFβ into a wound, which has been corroborated by experimental evidence including, cell biological studies, animal model experiments, and clinical evidence52. Establishing a bio-similar in vitro model for fibrosis requires appropriate cell types and signals; however, it also is highly dependent upon the organization of the microenvironment. Previous experiments evaluating DHACM utilized standard assays involving a cell monolayer in a matrix-poor system. The controls demonstrated elevated COL1A expression with TGFb1 treatment, but failed to capture the pathophysiology and complexity of the disease state31. The addition of DHACM counteracted the TGFb1 effect, but without a bio-similar model, the mechanism is regarded as largely speculative. However, the addition of Ficoll to the culture conditions in this study introduced volume exclusion to accelerate the enzymatic conversion of procollagen to insoluble collagen allowing for protein and post-translational modification analysis. This demonstrates the utility of this model as it is more representative of the in vivo disease state and thus, more appropriate for assessing the significance of a potential treatment. This study not only used a more physiologically relevant in vitro model to substantiate the previous data demonstrating an effect of DHACM on collagen type I biosynthesis but additionally investigated how DHACM and LHACM impacts collagen type I biosynthesis and deposition.
Whole mRNA profiles of MMC cultured fibroblasts treated with DHACM + TGFβ1 identified 3054 genes that were differentially expressed. Interestingly, many of the identified genes are related to myofibroblast differentiation, collagen synthesis and matrix regulation, making them potential therapeutic targets for fibrotic indications37,53,54,55,56,57,58,59. LHACM, like DHACM, is comprised of PURION® processed amnion and chorion membranes, but also retains the intermediate layer30. LHACM is expected to exhibit similar properties, but inclusion in this study provided a direct comparison to DHACM. Under MMC conditions, fibroblasts treated with TGFβ1 exhibited expected behavior: increased phosphorylation of SMAD2 and SMAD3, increased ACTA2 and CTGF expression and elevated COL1A1. The addition of DHACM and LHACM reversed these effects, indicating their role in the regulation of downstream collagen accumulation and ECM degradation suseptibility40,41,60. TGFβ1 induced increased intracellular collagen synthesis and extracellular collagen deposition, which was attenuated with the addition of DHACM and LHACM treatment. Interestingly, visualization of collagen type I in the cell system revealed a retention of intracellular collagen and a marked reduction in extracellular collagen with treatment. In line with published results on other anti-fibrotic modalities, this data suggests that DHACM and LHACM may target gene expression, protein synthesis and secretion mechanisms of collagen to regulate the fibrotic process61.
Collagen maturation is facilitated by the extracellular crosslinking events which influence collagen deposition, matrix stability and rate of turnover. Regulation of these activities is important in assessing the prevention and irreversibility of fibrosis, as abnormalities in these crosslinking events have been directly linked to the clinical manifestation of stiffness and persistence in keloid and hypertrophic scars62,63. BMP1, LOX and TGase2 are the primary enzymes responsible for post-translational collagen modification and aberrant activity of these specifically have been implicated in fibrotic diseases69,70,71. TGFβ1 is known to be a key regulator of all three enzymes, however, in this study under MMC conditions, TGFβ1 increased TGM2 expression, but did not increase BMP1 and LOX gene expression 64,65,66. Despite these unexpected results, the protein levels did exhibit intracellular increases in BMP1, LOX and TGase2, validating the model. The discrepancy between gene expression and protein secretion is likely due to the temporal nature of gene regulation. An expanded time point analysis would be necessary to elucidate the impact of stimulation on the timing of gene regulation. The addition of DHACM and LHACM treatment to this system altered the expression of BMP1 and demonstrated corresponding changes to BMP1 protein levels relative to the TGFβ1 stimulated cells. BMP1 regulation is important as it directly impacts TGFβ signaling and the downstream effects of LOX67,68.
The extracellular crosslinking events catalyzed by LOX are critical for the stabilization of extracellular collagen43. The absence of LOX-mediated crosslinking in vivo results in weak collagen fibers and fragile collagenous tissues69. Consequently, elevated LOX levels play a critical role in scar formation and maintenance70. LOX is synthesized as a ~ 50 kDa proenzyme that is secreted and extracellularly processed by BMP1 to a mature active enzyme of ~ 30 kDa44. Intracellularly, DHACM and LHACM reduce the expression of the LOX proenzyme. Additionally, a LOX protein band at the molecular weight of the mature enzyme was also detected in the cell lysate or intracellular space of TGFβ1 stimulated cells and was diminished by DHACM and LHACM treatment. Cell culture supernatant from TGFβ1 stimulated HDFs showed an increase in accumulation of the mature LOX enzyme; however, DHACM and LHACM treatment further increased levels found in the cell culture supernatant. The contrasting influence of DHACM and LHACM on LOX gene expression and LOX protein levels reflect the inherent complexity of tissue-based biologics. DHACM and LHACM may not only regulate the production of the proenzyme but also play a role in regulating the trafficking of mature LOX into the intracellular space. Even though processed extracellularly, LOX has been shown to have intracellular functions in the cytoplasm and nucleus. Nellaiappan et. al. previously reported that secreted and proteolytically processed-LOX can re-enter cells and concentrate within nuclei71,72. DHACM and LHACM treated groups have significantly less mature LOX in the intracellular space, which may correspond to the elevated extracellular levels. Growing evidence implicating LOX as not only a major player in ECM remodeling but of also having intracellular activities that enable cell communication and ECM remodeling supports the hypothesis that LHACM and DHACM may modulate LOX at multiple levels71. The rigidity of the ECM and subsequent resistance to turnover is modulated in part by the crosslinking actions of TGase2 which is known to be involved in several diseases73,74,75.TGase2 is a key player in wound healing and inflammation as well as in pathological states such as fibrosis and arthritis76. TGFβ1 stimulation of HDFs significantly increased the gene expression and protein level of TGase2 which was subsequently reduced with DHACM and LHACM treatment. This suggests that the resulting collagen matrix may be more susceptible to degradation. Taken together, DHACM and LHACM demonstrate a multi-faceted approach to influence collagen deposition, rigidity, and maturation through the regulation of enzymatic crosslinking actions. This data, in addition to other reports, suggest that by controlling the extent of crosslinking, the matrix is more susceptible to remodeling and less likely to form excessive scar tissue57,77,78.
Clinically, fibrosis is recognized as a major health challenge with an incidence of approximately 4968 per 100,000 person-year. The complex pathogenesis of fibrotic diseases complicates the development of safe and effective therapeutics79. These data corroborate the earlier findings in the monolayer culture experiments and provides insight into the multi-functional effects of DHACM and LHACM on the regulation of TGFβ1-induced collagen production and deposition, further expanding the potential role of amniotic tissue allografts as modulators of fibrosis. Amniotic tissue allografts have been used for many years and have been safe and well tolerated with no adverse complications offering an advantage over the use of traditional therapeutics with known adverse effects8,9,10,11,12,13,14,80. While additional preclinical animal models, clinical data and investigating alternative crosslinking pathways will be beneficial in determining how the in vitro characteristics of DHACM and LHACM may translate to clinical efficacy, these data further expand the understanding of the regulatory capabilities of DHACM and LHACM on fibrotic pathways and may solve for a significant unmet clinical need.
Data availability
RNA-seq data used in this study are deposited in the Gene Expression Omnibus (GEO, https://www.ncbi.nlm.nih.gov/geo/) under the accession number GSE247237.
References
Krafts, K. P. Tissue repair: The hidden drama. Organogenesis 6, 225–233. https://doi.org/10.4161/org.6.4.12555 (2010).
Shi, X., Young, C. D., Zhou, H. & Wang, X. Transforming growth factor-beta signaling in fibrotic diseases and cancer-associated fibroblasts. Biomolecules https://doi.org/10.3390/biom10121666 (2020).
McKleroy, W., Lee, T. H. & Atabai, K. Always cleave up your mess: targeting collagen degradation to treat tissue fibrosis. Am. J. Physiol. Lung Cell Mol. Physiol. 304, L709-721. https://doi.org/10.1152/ajplung.00418.2012 (2013).
Uitto, J., Tan, E. M. & Ryhanen, L. Inhibition of collagen accumulation in fibrotic processes: Review of pharmacologic agents and new approaches with amino acids and their analogues. J. Invest. Dermatol. 79(Suppl 1), 113s–120s. https://doi.org/10.1111/1523-1747.ep12545951 (1982).
Larson, B. J., Longaker, M. T. & Lorenz, H. P. Scarless fetal wound healing: A basic science review. Plast. Reconstr. Surg. 126, 1172–1180. https://doi.org/10.1097/PRS.0b013e3181eae781 (2010).
Moore, A. L. et al. Scarless wound healing: Transitioning from fetal research to regenerative healing. Wiley Interdiscip. Rev. Dev. Biol. https://doi.org/10.1002/wdev.309 (2018).
Zhou, S. et al. New insights into balancing wound healing and scarless skin repair. J. Tissue Eng. 14, 20417314231185850. https://doi.org/10.1177/20417314231185848 (2023).
Kheirkhah, A. et al. Temporary sutureless amniotic membrane patch for acute alkaline burns. Arch. Ophthalmol. 126, 1059–1066. https://doi.org/10.1001/archopht.126.8.1059 (2008).
Zelen, C. M., Serena, T. E., Denoziere, G. & Fetterolf, D. E. A prospective randomised comparative parallel study of amniotic membrane wound graft in the management of diabetic foot ulcers. Int. Wound J. 10, 502–507. https://doi.org/10.1111/iwj.12097 (2013).
Zheng, F., Zhu, B., Liu, Y., Wang, R. & Cui, Y. Meta-analysis of the use of amniotic membrane to prevent recurrence of intrauterine adhesion after hysteroscopic adhesiolysis. Int. J. Gynaecol. Obstet. 143, 145–149. https://doi.org/10.1002/ijgo.12635 (2018).
Shpichka, A. et al. Skin tissue regeneration for burn injury. Stem Cell Res. Ther. 10, 94. https://doi.org/10.1186/s13287-019-1203-3 (2019).
Walker, C. T. et al. Human amniotic membrane for the prevention of intradural spinal cord adhesions: Retrospective review of its novel use in a case series of 14 patients. Neurosurgery 83, 989–996. https://doi.org/10.1093/neuros/nyx608 (2018).
Riordan, N. H., George, B. A., Chandler, T. B. & McKenna, R. W. Case report of non-healing surgical wound treated with dehydrated human amniotic membrane. J. Transl. Med. 13, 242. https://doi.org/10.1186/s12967-015-0608-8 (2015).
Rezazadeh, D., Anvari Aliabad, R. & Norooznezhad, A. H. Autologous amniotic membrane: An accelerator of wound healing for prevention of surgical site infections following cesarean delivery. Med. Hypotheses 137, 109532. https://doi.org/10.1016/j.mehy.2019.109532 (2020).
Zamir, E. et al. Dynamics and segregation of cell-matrix adhesions in cultured fibroblasts. Nat. Cell Biol. 2, 191–196. https://doi.org/10.1038/35008607 (2000).
Shieh, A. C., Rozansky, H. A., Hinz, B. & Swartz, M. A. Tumor cell invasion is promoted by interstitial flow-induced matrix priming by stromal fibroblasts. Cancer Res. 71, 790–800. https://doi.org/10.1158/0008-5472.CAN-10-1513 (2011).
Lareu, R. R., Arsianti, I., Subramhanya, H. K., Yanxian, P. & Raghunath, M. In vitro enhancement of collagen matrix formation and crosslinking for applications in tissue engineering: A preliminary study. Tissue Eng. 13, 385–391. https://doi.org/10.1089/ten.2006.0224 (2007).
Rosell-Garcia, T. & Rodriguez-Pascual, F. Enhancement of collagen deposition and cross-linking by coupling lysyl oxidase with bone morphogenetic protein-1 and its application in tissue engineering. Sci. Rep. 8, 10780. https://doi.org/10.1038/s41598-018-29236-6 (2018).
Benny, P. & Raghunath, M. Making microenvironments: A look into incorporating macromolecular crowding into in vitro experiments, to generate biomimetic microenvironments which are capable of directing cell function for tissue engineering applications. J. Tissue Eng. 8, 2041731417730467. https://doi.org/10.1177/2041731417730467 (2017).
Lareu, R. R. et al. Collagen matrix deposition is dramatically enhanced in vitro when crowded with charged macromolecules: The biological relevance of the excluded volume effect. FEBS Lett. 581, 2709–2714. https://doi.org/10.1016/j.febslet.2007.05.020 (2007).
Tsiapalis, D. & Zeugolis, D. I. It is time to crowd your cell culture media—Physicochemical considerations with biological consequences. Biomaterials 275, 120943. https://doi.org/10.1016/j.biomaterials.2021.120943 (2021).
Chen, C. Z. et al. The scar-in-a-jar: Studying potential antifibrotic compounds from the epigenetic to extracellular level in a single well. Br. J. Pharmacol. 158, 1196–1209. https://doi.org/10.1111/j.1476-5381.2009.00387.x (2009).
Ronnow, S. R. et al. Prolonged scar-in-a-jar: An in vitro screening tool for anti-fibrotic therapies using biomarkers of extracellular matrix synthesis. Respir. Res. 21, 108. https://doi.org/10.1186/s12931-020-01369-1 (2020).
Koob, T. J., Lim, J. J., Massee, M., Zabek, N. & Denoziere, G. Properties of dehydrated human amnion/chorion composite grafts: Implications for wound repair and soft tissue regeneration. J. Biomed. Mater. Res. B Appl. Biomater. 102, 1353–1362. https://doi.org/10.1002/jbm.b.33141 (2014).
Koob, T. J. et al. Angiogenic properties of dehydrated human amnion/chorion allografts: Therapeutic potential for soft tissue repair and regeneration. Vasc. Cell 6, 10. https://doi.org/10.1186/2045-824X-6-10 (2014).
Koob, T. J. et al. Biological properties of dehydrated human amnion/chorion composite graft: Implications for chronic wound healing. Int. Wound J. 10, 493–500. https://doi.org/10.1111/iwj.12140 (2013).
Lei, J., Priddy, L. B., Lim, J. J. & Koob, T. J. Dehydrated human amnion/chorion membrane (dHACM) allografts as a therapy for orthopedic tissue repair. Tech. Orthop. 32, 149–157. https://doi.org/10.1097/BTO.0000000000000229 (2017).
Massee, M. et al. Dehydrated human amnion/chorion membrane regulates stem cell activity in vitro. J. Biomed. Mater. Res. B Appl. Biomater. 104, 1495–1503. https://doi.org/10.1002/jbm.b.33478 (2016).
Massee, M. et al. Type I and II diabetic adipose-derived stem cells respond in vitro to dehydrated human amnion/chorion membrane allograft treatment by increasing proliferation, migration, and altering cytokine secretion. Adv. Wound Care (New Rochelle) 5, 43–54. https://doi.org/10.1089/wound.2015.0661 (2016).
Moreno, S. et al. PURION((R)) processed human amnion chorion membrane allografts retain material and biological properties supportive of soft tissue repair. J. Biomater. Appl. https://doi.org/10.1177/08853282241246034 (2024).
Moreno, S. E., Massee, M. & Koob, T. J. Dehydrated human amniotic membrane inhibits myofibroblast contraction through the regulation of the TGFβ‒SMAD pathway in vitro. JID Innov. https://doi.org/10.1016/j.xjidi.2021.100020 (2021).
Daniel, J. Placental Tissue Grafts. US Patent 8,372.437 B2 (2013).
Daniel, J., Tofe, R., Spencer, R. & Russo, J. Placental Tissue Grafts. US Patent 8,357,403 B2 (2013a).
Daniel, J., Tofe, R., Spencer, R. & Russo, J. Placental Tissue Grafts. US Patent 8,409,626 B2 (2013b).
Schneider, C. A., Rasband, W. S. & Eliceiri, K. W. NIH Image to ImageJ: 25 years of image analysis. Nat. Methods 9, 671–675. https://doi.org/10.1038/nmeth.2089 (2012).
Abreu, J. G., Ketpura, N. I., Reversade, B. & De Robertis, E. M. Connective-tissue growth factor (CTGF) modulates cell signalling by BMP and TGF-beta. Nat. Cell Biol. 4, 599–604. https://doi.org/10.1038/ncb826 (2002).
Lipson, K. E., Wong, C., Teng, Y. & Spong, S. CTGF is a central mediator of tissue remodeling and fibrosis and its inhibition can reverse the process of fibrosis. Fibrogenesis Tissue Repair 5, S24. https://doi.org/10.1186/1755-1536-5-S1-S24 (2012).
Vallee, A. & Lecarpentier, Y. TGF-beta in fibrosis by acting as a conductor for contractile properties of myofibroblasts. Cell. Biosci. 9, 98. https://doi.org/10.1186/s13578-019-0362-3 (2019).
Wang, Q. et al. Cooperative interaction of CTGF and TGF-beta in animal models of fibrotic disease. Fibrogenesis Tissue Repair 4, 4. https://doi.org/10.1186/1755-1536-4-4 (2011).
Leask, A., Holmes, A. & Abraham, D. J. Connective tissue growth factor: A new and important player in the pathogenesis of fibrosis. Curr. Rheumatol. Rep. 4, 136–142. https://doi.org/10.1007/s11926-002-0009-x (2002).
Leask, A., Parapuram, S. K., Shi-Wen, X. & Abraham, D. J. Connective tissue growth factor (CTGF, CCN2) gene regulation: A potent clinical bio-marker of fibroproliferative disease?. J Cell Commun Signal 3, 89–94. https://doi.org/10.1007/s12079-009-0037-7 (2009).
N’Diaye, E. N. et al. Extracellular BMP1 is the major proteinase for COOH-terminal proteolysis of type I procollagen in lung fibroblasts. Am. J. Physiol. Cell Physiol. 320, C162–C174. https://doi.org/10.1152/ajpcell.00012.2020 (2021).
Onursal, C., Dick, E., Angelidis, I., Schiller, H. B. & Staab-Weijnitz, C. A. Collagen biosynthesis, processing, and maturation in lung ageing. Front. Med. (Lausanne) 8, 593874. https://doi.org/10.3389/fmed.2021.593874 (2021).
Trackman, P. C., Bedell-Hogan, D., Tang, J. & Kagan, H. M. Post-translational glycosylation and proteolytic processing of a lysyl oxidase precursor. J. Biol. Chem. 267, 8666–8671 (1992).
Rosenbloom, J., Macarak, E., Piera-Velazquez, S. & Jimenez, S. A. Human fibrotic diseases: Current challenges in fibrosis research. Methods Mol. Biol. 1627, 1–23. https://doi.org/10.1007/978-1-4939-7113-8_1 (2017).
Wynn, T. A. Cellular and molecular mechanisms of fibrosis. J. Pathol. 214, 199–210. https://doi.org/10.1002/path.2277 (2008).
Ahuja, N., Jin, R., Powers, C., Billi, A. & Bass, K. Dehydrated human amnion chorion membrane as treatment for pediatric burns. Adv. Wound Care (New Rochelle) 9, 602–611. https://doi.org/10.1089/wound.2019.0983 (2020).
Zelen, C. M., Serena, T. E. & Fetterolf, D. E. Dehydrated human amnion/chorion membrane allografts in patients with chronic diabetic foot ulcers: A long-term follow-up study. Wound Med. 4, 1–4 (2014).
Glat, P. M. & Davenport, T. Current techniques for burn reconstruction: Using dehydrated human amnion/chorion membrane allografts as an adjunctive treatment along the reconstructive ladder. Ann. Plast. Surg. 78, S14–S18. https://doi.org/10.1097/SAP.0000000000000980 (2017).
Reilly, D. A., Hickey, S., Glat, P., Lineaweaver, W. C. & Goverman, J. Clinical experience: Using dehydrated human amnion/chorion membrane allografts for acute and reconstructive burn care. Ann. Plast. Surg. 78, S19–S26. https://doi.org/10.1097/SAP.0000000000000981 (2017).
Serena, T. E. et al. A multicenter, randomized, controlled clinical trial evaluating the use of dehydrated human amnion/chorion membrane allografts and multilayer compression therapy vs. multilayer compression therapy alone in the treatment of venous leg ulcers. Wound Repair Regen. 22, 688–693. https://doi.org/10.1111/wrr.12227 (2014).
Frangogiannis, N. Transforming growth factor-beta in tissue fibrosis. J. Exp. Med. 217, e20190103. https://doi.org/10.1084/jem.20190103 (2020).
Yu-Wai-Man, C. et al. Local delivery of novel MRTF/SRF inhibitors prevents scar tissue formation in a preclinical model of fibrosis. Sci. Rep. 7, 518. https://doi.org/10.1038/s41598-017-00212-w (2017).
Wu, M. et al. Identification of cadherin 11 as a mediator of dermal fibrosis and possible role in systemic sclerosis. Arthritis Rheumatol. 66, 1010–1021. https://doi.org/10.1002/art.38275 (2014).
Pedroza, M., Welschhans, R. L. & Agarwal, S. K. Targeting of cadherin-11 decreases skin fibrosis in the tight skin-1 mouse model. PLoS One 12, e0187109. https://doi.org/10.1371/journal.pone.0187109 (2017).
Flanders, K. C. Smad3 as a mediator of the fibrotic response. Int. J. Exp. Pathol. 85, 47–64. https://doi.org/10.1111/j.0959-9673.2004.00377.x (2004).
Fell, S., Wang, Z., Blanchard, A., Nanthakumar, C. & Griffin, M. Transglutaminase 2: A novel therapeutic target for idiopathic pulmonary fibrosis using selective small molecule inhibitors. Amino Acids 53, 205–217. https://doi.org/10.1007/s00726-020-02938-w (2021).
Puente, A. et al. LOXL2—A new target in antifibrogenic therapy?. Int. J. Mol. Sci. https://doi.org/10.3390/ijms20071634 (2019).
Giannandrea, M. & Parks, W. C. Diverse functions of matrix metalloproteinases during fibrosis. Dis. Model Mech. 7, 193–203. https://doi.org/10.1242/dmm.012062 (2014).
Holm Nielsen, S. et al. Serological assessment of activated fibroblasts by alpha-smooth muscle actin (alpha-SMA): A noninvasive biomarker of activated fibroblasts in lung disorders. Transl. Oncol. 12, 368–374. https://doi.org/10.1016/j.tranon.2018.11.004 (2019).
Puerta Cavanzo, N., Bigaeva, E., Boersema, M., Olinga, P. & Bank, R. A. Macromolecular crowding as a tool to screen anti-fibrotic drugs: The scar-in-a-jar system revisited. Front. Med. (Lausanne) 7, 615774. https://doi.org/10.3389/fmed.2020.615774 (2020).
Di Cesare, P. E. et al. Alteration of collagen composition and cross-linking in keloid tissues. Matrix 10, 172–178. https://doi.org/10.1016/s0934-8832(11)80166-6 (1990).
Limandjaja, G. C., Niessen, F. B., Scheper, R. J. & Gibbs, S. Hypertrophic scars and keloids: Overview of the evidence and practical guide for differentiating between these abnormal scars. Exp. Dermatol. 30, 146–161. https://doi.org/10.1111/exd.14121 (2021).
Lee, S., Solow-Cordero, D. E., Kessler, E., Takahara, K. & Greenspan, D. S. Transforming growth factor-beta regulation of bone morphogenetic protein-1/procollagen C-proteinase and related proteins in fibrogenic cells and keratinocytes. J. Biol. Chem. 272, 19059–19066. https://doi.org/10.1074/jbc.272.30.19059 (1997).
Fang, Y. et al. Transforming growth factor-beta1 increases lysyl oxidase expression by downregulating MIR29A in human granulosa lutein cells. Reproduction 152, 205–213. https://doi.org/10.1530/REP-16-0144 (2016).
Gundemir, S., Colak, G., Tucholski, J. & Johnson, G. V. Transglutaminase 2: a molecular Swiss army knife. Biochim. Biophys. Acta 406–419, 2012. https://doi.org/10.1016/j.bbamcr.2011.09.012 (1823).
Ge, G. & Greenspan, D. S. BMP1 controls TGFbeta1 activation via cleavage of latent TGFbeta-binding protein. J. Cell. Biol. 175, 111–120. https://doi.org/10.1083/jcb.200606058 (2006).
Uzel, M. I. et al. Multiple bone morphogenetic protein 1-related mammalian metalloproteinases process pro-lysyl oxidase at the correct physiological site and control lysyl oxidase activation in mouse embryo fibroblast cultures. J. Biol. Chem. 276, 22537–22543. https://doi.org/10.1074/jbc.M102352200 (2001).
Avery, N. C. & Bailey, A. J. Collagen: Structure and mechanics, an introduction. In Collagen: Structure and Mechanics (ed. Fratzl, P.) 81–110 (Springer US, 2008).
Chaudhari, N. et al. Topical application of an irreversible small molecule inhibitor of lysyl oxidases ameliorates skin scarring and fibrosis. Nat. Commun. 13, 5555. https://doi.org/10.1038/s41467-022-33148-5 (2022).
Zaffryar-Eilot, S. & Hasson, P. Lysyl oxidases: Orchestrators of cellular behavior and ECM remodeling and homeostasis. Int. J. Mol. Sci. https://doi.org/10.3390/ijms231911378 (2022).
Nellaiappan, K., Risitano, A., Liu, G., Nicklas, G. & Kagan, H. M. Fully processed lysyl oxidase catalyst translocates from the extracellular space into nuclei of aortic smooth-muscle cells. J. Cell. Biochem. 79, 576–582. https://doi.org/10.1002/1097-4644(20001215)79:4%3c576::aid-jcb60%3e3.0.co;2-a (2000).
Kim, S. Y., Jeitner, T. M. & Steinert, P. M. Transglutaminases in disease. Neurochem. Int. 40, 85–103. https://doi.org/10.1016/s0197-0186(01)00064-x (2002).
Elli, L., Bergamini, C. M., Bardella, M. T. & Schuppan, D. Transglutaminases in inflammation and fibrosis of the gastrointestinal tract and the liver. Dig. Liver Dis. 41, 541–550. https://doi.org/10.1016/j.dld.2008.12.095 (2009).
Telci, D. & Griffin, M. Tissue transglutaminase (TG2)—a wound response enzyme. Front. Biosci. 11, 867–882. https://doi.org/10.2741/1843 (2006).
Griffin, M., Casadio, R. & Bergamini, C. M. Transglutaminases: Nature’s biological glues. Biochem. J. 368, 377–396. https://doi.org/10.1042/BJ20021234 (2002).
Bai, M. et al. BMP1 inhibitor UK383,367 attenuates renal fibrosis and inflammation in CKD. Am. J. Physiol. Renal Physiol. 317, F1430–F1438. https://doi.org/10.1152/ajprenal.00230.2019 (2019).
Chen, L., Li, S. & Li, W. LOX/LOXL in pulmonary fibrosis: Potential therapeutic targets. J. Drug Target 27, 790–796. https://doi.org/10.1080/1061186X.2018.1550649 (2019).
Zhao, M. et al. Targeting fibrosis, mechanisms and cilinical trials. Signal Transduct. Target Ther. 7, 206. https://doi.org/10.1038/s41392-022-01070-3 (2022).
Subach, B. R. & Copay, A. G. The use of a dehydrated amnion/chorion membrane allograft in patients who subsequently undergo reexploration after posterior lumbar instrumentation. Adv. Orthop. 2015, 501202. https://doi.org/10.1155/2015/501202 (2015).
Author information
Authors and Affiliations
Contributions
S.M., I.E.L., and K.D. designed, performed, analyzed experimental work; S.M., I.E.L., K.D., and T.K. discussed results; S.M. and M.M. wrote the main manuscript; all authors critically reviewed the manuscript.
Corresponding author
Ethics declarations
Competing interests
All authors were full time employees at MIMEDX Group Inc at the time experiments were executed. S.M., M.M., T.K., and J.H. hold equity in MIMEDX Group Inc.
Additional information
Publisher's note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary Information
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Moreno, S.E., Enwerem-Lackland, I., Dreaden, K. et al. Human amniotic membrane modulates collagen production and deposition in vitro. Sci Rep 14, 15998 (2024). https://doi.org/10.1038/s41598-024-64364-2
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41598-024-64364-2
- Springer Nature Limited