Mechanisms Of Remodeling Research Articles

Prohibitin 1 deletion from activated cardiac fibroblasts in vivo attenuates cardiac fibrosis

Cardiac fibroblasts (CF) are responsible for extracellular matrix (ECM) deposition with cardiac injury. While fibrosis is a typical response to injury, excessive or uncontrolled fibrotic remodeling by CFs underlies the progression to heart failure. Cardiac injury-induced activated CFs are characteristically identified as periostin expressing cells that are proliferative and ECM secreting. This activated secretory phenotype is supported by altered mitochondrial mechanisms. Prohibitin 1 (PHB1) is known to play a role in cell survival via its impact on mitochondrial integrity, and we have established that it is enriched in activated CFs. This study aims to investigate the impact of conditional PHB1 deletion in vivo from activated CFs, and it is expected that PHB1 deletion will reduce or prevent isoproterenol (ISO)-induced fibrotic remodeling. Male and female Periostin-Cre (PC) Phb1fl/fl and WT Phb1fl/fl mice were infused with ISO (75 mg/kg/day) or vehicle (0.003% ascorbic acid in saline) for 1 or 2 weeks via osmotic micro-pump. Cre recombinase was induced by tamoxifen injection (75 mg/kg, i.p.). Hearts were collected, a mid-myocardial section was fixed and stained for fibrosis (Sirius red), and remaining tissue was frozen for protein and RNA extraction. Two weeks of ISO tended to increase hypertrophy in male (p=0.06) and female (p=0.08) mice compared to vehicle. Periostin protein expression was modulated similarly in male and female hearts, which exhibited a significant 7-fold increase following 2 weeks of ISO infusion (p=0.003 vs. vehicle). CF PHB1 deletion significantly attenuated this increase (p=0.009 vs. WT ISO). PHB1 deletion in activated CFs resulted in reduced Col1a1 gene expression following 2 weeks of ISO in males (38.6%) and in females (68.0%) relative to WT ISO. Further, both male and female PC mice exhibited ~55% reduction in Col3a1 gene expression after ISO infusion compared to WT. Taken together, these findings indicate that PHB1 deletion prevents ISO-induced CF activation in both sexes. Left ventricular fibrosis via Sirius red stain was more pronounced in mice treated for 2 weeks compared to 1 week, with males having markedly more fibrosis than females. The accumulation of ISO-induced fibrosis in males was prevented by PHB1 deletion. Interestingly, the extent of cardiac fibrosis with and without PHB1 deletion correlated with periostin protein expression in males, but not in females. Thus, the measured reduction in CF activation by conditional PHB1 deletion may limit ECM deposition in males. The lack of fibrotic tissue in the presence of elevated collagen gene expression and periostin in the ISO-treated females may reflect sex-specific CF phenotypes or fibrotic remodeling. In this model of fibrosis, it is unclear how PHB1 deletion is impacting the female heart structurally. Future studies will aim to elucidate altered mitochondrial mechanisms after PHB1 deletion in models of fibrosis, as well as sex-specific mechanisms of fibrotic remodeling. ECU REDE startup program, NIH T32HL007249-44, UArizona Sarver Heart Center. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Remodeling mechanism of gel network structure of soy protein isolate amyloid fibrils mediated by cellulose nanocrystals

The differences in the gelling properties of soy protein isolate (SPI) and soy protein isolate amyloid fibrils (SAFs) as well as the role of cellulose nanocrystals (CNC) in regulating their gel behaviors were investigated in this study. The binding of CNC to β-conglycinin (7S), glycinin (11S), and SAFs was predominantly driven by non-covalent interactions. CNC addition reduced the particle size, turbidity, subunit segments, and crystallinity of SPI and SAFs, promoted the conversion of α-helix to β-sheet, improved the thermal stability, exposed more tyrosine and tryptophan residues, and enhanced the intermolecular interactions. A more regular and ordered lamellar network structure was formed in the SAFs-CNC composite gel, which could be conducive to the improvement of gel quality. This study would provide theoretical reference for the understanding of the regulatory mechanism of protein amyloid fibrils gelation as well as the high-value utilization of SAFs-CNC complex as a functional protein-based material or food ingredient in food field.

Cyclic strain alters the transcriptional and migratory response of scleral fibroblasts to TGFβ

In glaucoma, scleral fibroblasts are exposed to IOP-associated mechanical strain and elevated TGFβ levels. These stimuli, in turn, lead to scleral remodeling. Here, we examine the scleral fibroblast migratory and transcriptional response to these stimuli to better understand mechanisms of glaucomatous scleral remodeling. Human peripapillary scleral (PPS) fibroblasts were cultured on parallel grooves, treated with TGFβ (2 ng/ml) in the presence of vehicle or TGFβ signaling inhibitors, and exposed to uniaxial strain (1 Hz, 5%, 12–24 h). Axis of cellular orientation was determined at baseline, immediately following strain, and 24 h after strain cessation with 0° being completely aligned with grooves and 90° being perpendicular. Fibroblasts migration in-line and across grooves was assessed using a scratch assay. Transcriptional profiling of TGFβ-treated fibroblasts with or without strain was performed by RT-qPCR and pERK, pSMAD2, and pSMAD3 levels were measured by immunoblot. Pre-strain alignment of TGFβ-treated cells with grooves (6.2 ± 1.5°) was reduced after strain (21.7 ± 5.3°, p < 0.0001) and restored 24 h after strain cessation (9.5 ± 2.6°). ERK, FAK, and ALK5 inhibition prevented this reduction; however, ROCK, YAP, or SMAD3 inhibition did not. TGFβ-induced myofibroblast markers were reduced by strain (αSMA, POSTN, ASPN, MLCK1). While TGFβ-induced phosphorylation of ERK and SMAD2 was unaffected by cyclic strain, SMAD3 phosphorylation was reduced (p = 0.0004). Wound healing across grooves was enhanced by ROCK and SMAD3 inhibition but not ERK or ALK5 inhibition. These results provide insight into the mechanisms by which mechanical strain alters the cellular response to TGFβ and the potential signaling pathways that underlie scleral remodeling.

EXPLORING THE IMPACT OF PTH THERAPY ON BONE REMODELING: A MATHEMATICAL INVESTIGATION

The regulatory influence of the parathyroid hormone (PTH) is exerted on bone, which serves as a vital reservoir of calcium within the body. While various aspects of bone growth, turnover, and mechanisms operate independently of gonadal hormones, a crucial role is assumed by sex steroids, particularly estrogen, in maintaining bone equilibrium in adults. In order to unravel the underlying mechanisms of bone remodeling mediated by PTH, a distinguished mathematical model of this intricate process is presented. Subsequently, the temporal effects of Plasma PTH and PTH external dosages are investigated using the proposed mathematical model. Among the limited repertoire of approved and accessible anabolic treatments for severe osteoporosis, daily injections of PTH stand out. This pharmaceutical marvel possesses a unique dual action, capable of acting either anabolically or catabolically, contingent upon the mode of administration. The study aims to accurately predict osteogenic responses to introduced and endogenous PTH, incorporating factors such as [Formula: see text]-[Formula: see text], [Formula: see text], and bisphosphonates in osteoblast–osteoclast signaling, as well as considering PTH’s influence on the gland and the regulatory roles of [Formula: see text], [Formula: see text], and [Formula: see text] in osteoblast apoptosis and bone volume effects. Through diverse methods including illustrative depictions, numerical simulations, sensitivity analysis, and stability analysis, this work seeks to comprehend how PTH therapy impacts bone volume, enhancing its therapeutic relevance.

Mechanisms of vibration-induced structural myocardial remodeling

The review analyzes literature data on structural changes in the heart of patients with vibration disease, as detected by echocardiographic methods. Particularly, it highlights concentric remodeling of the left ventricle chambers and disturbances in diastolic function. The review also discusses a 1.2-fold decrease in heart structure intensity compared to healthy individuals (p 0.05). Furthermore, it examines changes in morphometric and bioenergetic parameters of cardiomyocytes under different experimental vibration modes (7 and 56 sessions at a frequency of 8 Hz), confirming the disruptions in the relationship between the spatial configuration of the heart cavities, contractile ability, and energy supply potential. Loss of cardiac myofibrils represents the transition from myocardial hypertrophy to decompensation, accompanied by an increase in degenerative (dystrophic) signs such as the loss of sarcomeres in cardiomyocytes. Understanding these pathological (morphological) processes requires consideration of various mediators that regulate cell metabolism, proliferation, growth, and survival, including stromal interaction molecule, calcium ATPase of the endo(sarco)plasmic reticulum, inositol-1,4,5-triphosphate receptor, protein that forms CRAC channels, and transient receptor potential canonical. The degradation system of the extracellular matrix, including matrix metalloproteinases and tissue inhibitors, plays a crucial role in structural cardiac remodeling. This system regulates the rate of mRNA synthesis on the DNA matrix by binding to specific DNA regions that control cardiac nutrition and plasticity. The review suggests that these findings can help explain some patterns of cardiac remodeling development in patients with vibration disease and determine the direction of pathogenetically based therapy. This therapy should consider not only the vibration-protective effect of drugs but also their ability to inhibit and regress myocardial remodeling.

Identification of triacylglycerol remodeling mechanism to synthesize unusual fatty acid containing oils

Typical plant membranes and storage lipids are comprised of five common fatty acids yet over 450 unusual fatty acids accumulate in seed oils of various plant species. Plant oils are important human and animal nutrients, while some unusual fatty acids such as hydroxylated fatty acids (HFA) are used in the chemical industry (lubricants, paints, polymers, cosmetics, etc.). Most unusual fatty acids are extracted from non-agronomic crops leading to high production costs. Attempts to engineer HFA into crops are unsuccessful due to bottlenecks in the overlapping pathways of oil and membrane lipid synthesis where HFA are not compatible. Physaria fendleri naturally overcomes these bottlenecks through a triacylglycerol (TAG) remodeling mechanism where HFA are incorporated into TAG after initial synthesis. TAG remodeling involves a unique TAG lipase and two diacylglycerol acyltransferases (DGAT) that are selective for different stereochemical and acyl-containing species of diacylglycerol within a synthesis, partial degradation, and resynthesis cycle. The TAG lipase interacts with DGAT1, localizes to the endoplasmic reticulum (with the DGATs) and to puncta around the lipid droplet, likely forming a TAG remodeling metabolon near the lipid droplet-ER junction. Each characterized DGAT and TAG lipase can increase HFA accumulation in engineered seed oils.

Vascular damage and excessive proliferation compromise liver function after extended hepatectomy in mice.

Surgical resection remains the gold standard for liver tumor treatment, yet the emergence of post-operative liver failure, known as the small for size syndrome (SFSS), poses a significant challenge. The activation of hypoxia sensors in a SFSS liver remnant initiated early angiogenesis, improving vascular architecture, safeguarding against liver failure and reducing mortality. The study aimed to elucidate vascular remodeling mechanisms in SFSS, its impact on hepatocyte function and subsequent liver failure. Mice underwent extended partial hepatectomy to induce SFSS, with a subset exposed to hypoxia immediately after surgery. Hypoxia bolstered post-hepatectomy survival rates. Early proliferation of liver sinusoidal cells, coupled with recruitment of putative endothelial progenitor cells (EPC), increased vascular density, improved lobular perfusion, and limited hemorrhagic events in the regenerating liver under hypoxia. Administration of granulocyte colony stimulating factor (G-CSF) in hepatectomized mice mimicked the effects of hypoxia on vascular remodeling and EPC recruitment, but failed to rescue survival. Compared to normoxia, hypoxia favored hepatocyte function over proliferation, promoting functional preservation in the regenerating remnant. Injection of AAV8-TBG-HNF4α virus for hepatocyte-specific overexpression of HNF4α, the master regulator of hepatocyte function, enforced functionality in proliferating hepatocytes but did not rescue survival. The combination of HNF4α overexpression and G-CSF treatment rescued survival after SFSS-setting hepatectomy. In summary, SFSS arises from an imbalance and desynchronized interplay between functional regeneration and vascular restructuring. To improve survival following SFSS-hepatectomy, it is essential to adopt a two-pronged strategy aimed at preserving the function of proliferating parenchymal cells and simultaneously attenuating vascular damage.

Solo regulates the localization and activity of PDZ-RhoGEF for actin cytoskeletal remodeling in response to substrate stiffness.

Recent findings indicate that Solo, a RhoGEF, is involved in cellular mechanical stress responses. However, the mechanism of actin cytoskeletal remodeling via Solo remains unclear. Therefore, this study aimed to identify Solo-interacting proteins using the BioID, a proximal-dependent labeling method, and elucidate the molecular mechanisms of function of Solo. We identified PDZ-RhoGEF (PRG) as a Solo-interacting protein. PRG colocalized with Solo in the basal area of cells, depending on Solo localization, and enhanced actin polymerization at the Solo accumulation sites. Additionally, Solo and PRG interaction was necessary for actin cytoskeletal remodeling. Furthermore, the purified Solo itself had little or negligible GEF activity, even its GEF-inactive mutant directly activated the GEF activity of PRG through interaction. Moreover, overexpression of the Solo and PRG binding domains, respectively, had a dominant-negative effect on actin polymerization and actin stress fiber formation in response to substrate stiffness. Therefore, Solo restricts the localization of PRG and regulates actin cytoskeletal remodeling in synergy with PRG in response to the surrounding mechanical environment.

Aged Tendons Exhibit Altered Mechanisms of Strain-Dependent Extracellular Matrix Remodeling.

Aging is a primary risk factor for degenerative tendon injuries, yet the etiology and progression of this degeneration are poorly understood. While aged tendons have innate cellular differences that support a reduced ability to maintain mechanical tissue homeostasis, the response of aged tendons to altered levels of mechanical loading has not yet been studied. To address this question, we subjected young and aged murine flexor tendon explants to various levels of in vitro tensile strain. We first compared the effect of static and cyclic strain on matrix remodeling in young tendons, finding that cyclic strain is optimal for studying remodeling in vitro. We then investigated the remodeling response of young and aged tendon explants after 7 days of varied mechanical stimulus (stress deprivation, 1%, 3%, 5%, or 7% cyclic strain) via assessment of tissue composition, biosynthetic capacity, and degradation profiles. We hypothesized that aged tendons would show muted adaptive responses to changes in tensile strain and exhibit a shifted mechanical setpoint, at which the remodeling balance is optimal. Interestingly, we found that 1% cyclic strain best maintains native physiology while promoting extracellular matrix (ECM) turnover for both age groups. However, aged tendons display fewer strain-dependent changes, suggesting a reduced ability to adapt to altered levels of mechanical loading. This work has a significant impact on understanding the regulation of tissue homeostasis in aged tendons, which can inform clinical rehabilitation strategies for treating elderly patients.

New Mechanisms to Prevent Heart Failure with Preserved Ejection Fraction Using Glucagon-like Peptide-1 Receptor Agonism (GLP-1 RA) in Metabolic Syndrome and in Type 2 Diabetes: A Review.

This review examines the impact of obesity on the pathophysiology of heart failure with preserved ejection fraction (HFpEF) and focuses on novel mechanisms for HFpEF prevention using a glucagon-like peptide-1 receptor agonism (GLP-1 RA). Obesity can lead to HFpEF through various mechanisms, including low-grade systemic inflammation, adipocyte dysfunction, accumulation of visceral adipose tissue, and increased pericardial/epicardial adipose tissue (contributing to an increase in myocardial fat content and interstitial fibrosis). Glucagon-like peptide 1 (GLP-1) is an incretin hormone that is released from the enteroendocrine L-cells in the gut. GLP-1 reduces blood glucose levels by stimulating insulin synthesis, suppressing islet α-cell function, and promoting the proliferation and differentiation of β-cells. GLP-1 regulates gastric emptying and appetite, and GLP-1 RA is currently indicated for treating type 2 diabetes (T2D), obesity, and metabolic syndrome (MS). Recent evidence indicates that GLP-1 RA may play a significant role in preventing HFpEF in patients with obesity, MS, or obese T2D. This effect may be due to activating cardioprotective mechanisms (the endogenous counter-regulatory renin angiotensin system and the AMPK/mTOR pathway) and by inhibiting deleterious remodeling mechanisms (the PKA/RhoA/ROCK pathway, aldosterone levels, and microinflammation). However, there is still a need for further research to validate the impact of these mechanisms on humans.

The role of language-related functional brain regions and white matter tracts in network plasticity of post-stroke aphasia.

The neural mechanisms underlying language recovery after a stroke remain controversial. This review aimed to summarize the plasticity and reorganization mechanisms of the language network through neuroimaging studies. Initially, we discussed the involvement of right language homologues, perilesional tissue, and domain-general networks. Subsequently, we summarized the white matter functional mapping and remodeling mechanisms associated with language subskills. Finally, we explored how non-invasive brain stimulation (NIBS) promoted language recovery by inducing neural network plasticity. It was observed that the recruitment of right hemisphere language area homologues played a pivotal role in the early stages of frontal post-stroke aphasia (PSA), particularly in patients with larger lesions. Perilesional plasticity correlated with improved speech performance and prognosis. The domain-general networks could respond to increased "effort" in a task-dependent manner from the top-down when the downstream language network was impaired. Fluency, repetition, comprehension, naming, and reading skills exhibited overlapping and unique dual-pathway functional mapping models. In the acute phase, the structural remodeling of white matter tracts became challenging, with recovery predominantly dependent on cortical activation. Similar to the pattern of cortical activation, during the subacute and chronic phases, improvements in language functions depended, respectively, on the remodeling of right white matter tracts and the restoration of left-lateralized language structural network patterns. Moreover, the midline superior frontal gyrus/dorsal anterior cingulate cortex emerged as a promising target for NIBS. These findings offered theoretical insights for the early personalized treatment of aphasia after stroke.

Copaiba oil minimizes inflammation and promotes parenchyma re-epithelization in acute allergic asthma model induced by ovalbumin in BALB/c mice.

Introduction: Asthma is a condition of airflow limitation, common throughout the world, with high mortality rates, especially as it still faces some obstacles in its management. As it constitutes a public health challenge, this study aimed to investigate the effect of copaiba oil (e.g., Copaifera langsdorffii), as a treatment resource, at doses of 50 and 100mg/kg on certain mediators of acute lung inflammation (IL-33, GATA3, FOXP3, STAT3, and TBET) and early mechanisms of lung remodeling (degradation of elastic fiber tissues, collagen deposition, and goblet cell hyperplasia). Methods: Using an ovalbumin-induced acute allergic asthma model in BALB/c mice, we analyzed the inflammatory mediators through immunohistochemistry and the mechanisms of lung remodeling through histopathology, employing orcein, Masson's trichrome, and periodic acid-Schiff staining. Results: Copaiba oil treatment (CO) reduced IL-33 and increased FOXP3 by stimulating the FOXP3/GATA3 and FOXP3/STAT3 pathways. Additionally, it upregulated TBET, suggesting an additional role in controlling GATA3 activity. In the respiratory epithelium, CO decreased the fragmentation of elastic fibers while increasing the deposition of collagen fibers, favoring epithelial restructuring. Simultaneously, CO reduced goblet cell hyperplasia. Discussion: Although additional research is warranted, the demonstrated anti-inflammatory and re-epithelializing action makes CO a viable option in exploring new treatments for acute allergic asthma.

Bioactive scaffolds for tissue engineering: A review of decellularized extracellular matrix applications and innovations

AbstractDecellularized extracellular matrix (dECM) offers a three‐dimensional, non‐immunogenic scaffold, enriched with bioactive components, making it a suitable candidate for tissue regeneration. Although dECM‐based scaffolds have been successfully implemented in preclinical and clinical settings within tissue engineering and regenerative medicine, the mechanisms of tissue remodeling and functional restoration are not fully understood. This review critically assesses the state‐of‐the‐art in dECM scaffolds, including decellularization techniques for various tissues, quality control and cross‐linking. It highlights the functional properties of dECM components and their latest applications in multiorgan tissue engineering and biomedicine. Additionally, the review addresses current challenges and limitations of decellularized scaffolds and offers perspectives on future directions in the field.

MALAT1: A Long Non-Coding RNA with Multiple Functions and Its Role in Processes Associated with Fat Deposition.

Metastasis-associated lung adenocarcinoma transcript 1 (MALAT1) belongs to the lncRNA molecules, which are involved in transcriptional and epigenetic regulation and the control of gene expression, including the mechanism of chromatin remodeling. MALAT1 was first discovered during carcinogenesis in lung adenocarcinoma, hence its name. In humans, 66 of its isoforms have been identified, and in pigs, only 2 are predicted, for which information is available in Ensembl databases (Ensembl Release 111). MALAT1 is expressed in numerous tissues, including adipose, adrenal gland, heart, kidney, liver, ovary, pancreas, sigmoid colon, small intestine, spleen, and testis. MALAT1, as an lncRNA, shows a wide range of functions. It is involved in the regulation of the cell cycle, where it has pro-proliferative effects and high cellular levels during the G1/S and mitotic (M) phases. Moreover, it is involved in invasion, metastasis, and angiogenesis, and it has a crucial function in alternative splicing during carcinogenesis. In addition, MALAT1 plays a significant role in the processes of fat deposition and adipogenesis. The human adipose tissue stem cells, during differentiation into adipocytes, secrete MALAT1 as one the most abundant lncRNAs in the exosomes. MALAT1 expression in fat tissue is positively correlated with adipogenic FABP4 and LPL. This lncRNA is involved in the regulation of PPARγ at the transcription stage, fatty acid metabolism, and insulin signaling. The wide range of MALAT1 functions makes it an interesting target in studies searching for drugs to prevent obesity development in humans. In turn, in farm animals, it can be a source of selection markers to control the fat tissue content.

Neuronally differentiated macula densa cells regulate tissue remodeling and regeneration in the kidney.

Tissue regeneration is limited in several organs, including the kidney, contributing to the high prevalence of kidney disease globally. However, evolutionary and physiological adaptive responses and the presence of renal progenitor cells suggest an existing remodeling capacity. This study uncovered endogenous tissue remodeling mechanisms in the kidney that were activated by the loss of body fluid and salt and regulated by a unique niche of a minority renal cell type called the macula densa (MD). Here, we identified neuronal differentiation features of MD cells that sense the local and systemic environment and secrete angiogenic, growth, and extracellular matrix remodeling factors, cytokines and chemokines, and control resident progenitor cells. Serial intravital imaging, MD nerve growth factor receptor and Wnt mouse models, and transcriptome analysis revealed cellular and molecular mechanisms of these MD functions. Human and therapeutic translation studies illustrated the clinical potential of MD factors, including CCN1, as a urinary biomarker and therapeutic target in chronic kidney disease. The concept that a neuronally differentiated key sensory and regulatory cell type responding to organ-specific physiological inputs controls local progenitors to remodel or repair tissues may be applicable to other organs and diverse tissue-regenerative therapeutic strategies.

Ganglioside GD3 Regulates Inflammation and Epithelial-to-Mesenchymal Transition in Human Nasal Epithelial Cells.

Chronic sinusitis with nasal polyps (CRSwNP) is one of the most common chronic inflammatory diseases, and involves tissue remodeling. One of the key mechanisms of tissue remodeling is the epithelial-mesenchymal transition (EMT), which also represents one of the pathophysiological processes of CRS observed in CRSwNP tissues. To date, many transcription factors and forms of extracellular stimulation have been found to regulate the EMT process. However, it is not known whether gangliosides, which are the central molecules of plasma membranes, involved in regulating signal transmission pathways, are involved in the EMT process. Therefore, we aimed to determine the role of gangliosides in the EMT process. First, we confirmed that N-cadherin, which is a known mesenchymal marker, and ganglioside GD3 were specifically expressed in CRSwNP_NP tissues. Subsequently, we investigated whether the administration of TNF-α to human nasal epithelial cells (hNECs) resulted in the upregulation of ganglioside GD3 and its synthesizing enzyme, ST8 alpha-N-acetyl-neuraminide alpha-2,8-sialytransferase 1 (ST8Sia1), and the consequently promoted inflammatory processes. Additionally, the expression of N-cadherin, Zinc finger protein SNAI2 (SLUG), and matrix metallopeptidase 9 (MMP-9) were elevated, but that of E-cadherin, which is known to be epithelial, was reduced. Moreover, the inhibition of ganglioside GD3 expression by the siRNA or exogenous treatment of neuraminidase 3 (NEU 3) led to the suppression of inflammation and EMT. These results suggest that gangliosides may play an important role in prevention and therapy for inflammation and EMT.

Role of bioenergetic hypoxia in the morphological transformation of the myocardium during vibration disease

BACKGROUND: Analysis of literature on the structural changes in the heart in patients with vibration disease using echocardiographic research methods revealed a concentric type of remodeling of the left ventricular chambers, which is associated with a high risk of cardiovascular complications, including sudden cardiac death, in people of working age.&#x0D; AIM: To determine the role of bioenergetic hypoxia in the development of morphological transformation of the myocardium to substantiate the efficacy of pharmacotherapy for vibration disease.&#x0D; MATERIALS AND METHODS: The energy production activity of cellular systems of heart tissue in vitro was analyzed by the polarographic method using a closed galvanic-type oxygen sensor (Clark electrode). The stressful effects of vibration were confirmed by the dynamics of the morphohistological picture of changes in the myocardial tissue of the left ventricle in the apical region after standard alcohol–paraffin wiring and staining of histological preparations with hematoxylin and eosin.&#x0D; RESULTS: Evaluation of the morphometric and bioenergetic parameters of cardiomyocytes under various experimental vibration modes (7, 21, and 56 sessions with a frequency of 8 and 44 Hz) confirmed the relationship between the provision of tissue with energy potential and morphological signs of pathological structural changes in the myocardial tissue, such as hypertrophy of cardiomyocytes, development of fibrosis, restructuring of the vascular bed, and necrosis.&#x0D; CONCLUSION: Analysis of the relationship between energy metabolism and morphohistological transformation of heart tissue allows us to resolve the role of universal and specific mechanisms in cardiac remodeling in the presence of vibration and pathogenetically substantiate the choice of drugs that not only have a vibration-protective effect but also inhibit pathological structural changes in the myocardial tissue.

(10) - Physiological Mechanisms of Reverse Pulmonary Vascular Remodeling in Pulmonary Hypertension Due to Left Heart Disease

(10) - Physiological Mechanisms of Reverse Pulmonary Vascular Remodeling in Pulmonary Hypertension Due to Left Heart Disease

Cell size and xylem differentiation regulating genes from Salicornia europaea contribute to plant salt tolerance.

Cell wall is involved in plant growth and plays pivotal roles in plant adaptation to environmental stresses. Cell wall remodelling may be crucial to salt adaptation in the euhalophyte Salicornia europaea. However, the mechanism underlying this process is still unclear. Here, full-length transcriptome indicated cell wall-related genes were comprehensively regulated under salinity. The morphology and cell wall components in S. europaea shoot were largely modified under salinity. Through the weighted gene co-expression network analysis, SeXTH2 encoding xyloglucan endotransglucosylase/hydrolases, and two SeLACs encoding laccases were focused. Meanwhile, SeEXPB was focused according to expansin activity and the expression profiling. Function analysis in Arabidopsis validated the functions of these genes in enhancing salt tolerance. SeXTH2 and SeEXPB overexpression led to larger cells and leaves with hemicellulose and pectin content alteration. SeLAC1 and SeLAC2 overexpression led to more xylem vessels, increased secondary cell wall thickness and lignin content. Notably, SeXTH2 transgenic rice exhibited enhanced salt tolerance and higher grain yield. Altogether, these genes may function in the succulence and lignification process in S. europaea. This work throws light on the regulatory mechanism of cell wall remodelling in S. europaea under salinity and provides potential strategies for improving crop salt tolerance and yields.

Evaluation of angiogenesis and microvascular remodeling in the subventricular zone of the brain of mice with experimental Alzheimer’s disease

BACKGROUND: Under the influence of external factors (learning), processes of microvasculature remodeling occur in the neurogenic niche to meet the metabolic needs of activated cells. However, it remains unclear how these mechanisms of brain plasticity are disrupted during neurodegeneration.&#x0D; AIM: To study the expression features of markers of angiogenesis and microvascular remodeling in the subventricular zone of the brain during training of animals, including against the background of the development of Alzheimer’s-type neurodegeneration in them.&#x0D; MATERIAL AND METHODS: The studies were carried out on C57BL/6 mice at the age of 8 months. Modeling of Alzheimer’s disease was carried out by intrahippocampal injection of 2 μl of a 1 mM solution of β-amyloid Aβ25-35. To assess cognitive deficits, a conditioned passive avoidance test using an aversive stimulus was used. The expression of LC3B, ZO1, VEGFR2, VEGFR3, CD146, ICAM2, Dll4, Tie2 in the subventricular zone per 100 DAPI-positive cells was assessed. The test results were processed using one-way ANOVA and Fisher's test, the Mann–Whitney U test, the results were considered significant at p 0.05.&#x0D; RESULTS: On the 9th day after the administration of β-amyloid, before the application of the aversive stimulus, an increase in the expression level of LC3 (7.95±5.83%, p=0.045), CD146 (18.35±0.01%, p=0.045) was recorded, as well as VEGFR3 (17.13±5.05%, p=0.045), which continued to increase after the presentation of the stimulus (26.61±0.01%, p=0.045). By the beginning of registration of cognitive impairment (38th day of the experiment), the expression level of VEGFR2 (20.61±2.8%, p=0.045) and ICAM2 (126.61±41.28%, p=0.045) increased, the content of Dll4 (29.66±8.72%, p=0.045) and Tie2 (36.39±7.8%, p=0.045) decreased in animals with experimental Alzheimer’s disease.&#x0D; CONCLUSION: An aversive stimulus stimulates microvascular remodeling mechanisms in the subventricular zone of the animal’s brain, but when exposed to β-amyloid, these processes are significantly disrupted.