Angiopoietin 2 as a Novel Potential Biomarker for Acute Aortic Dissection

Integrated bioinformatic analysis of immune infiltration and disulfidptosis related gene subgroups in type A aortic dissection

Type A aortic dissection (TAAD) is a lethal cardiovascular disease characterized by the separation of the layers within the aortic wall. The underlying pathological mechanisms of TAAD requires further elucidation to develop effective prevention and pharmacological treatment strategies. Inflammation plays a crucial role in TAAD pathogenesis. Disulfidptosis, an emerging type of cell death, may shed light on disease mechanisms. This study investigates the role of disulfidptosis-related genes in immune infiltration in TAAD. TAAD gene expression datasets were obtained from the Gene Expression Omnibus (GEO) database. Immune cell infiltration analysis assessed immune cell dysregulation in TAAD. Differentially expressed genes (DEGs) between TAAD samples and controls were identified and intersected with known disulfidptosis-related gene sets to obtain relevant DEGs. Hub genes were identified using machine learning algorithms. A diagnostic model was constructed using Least Absolute Shrinkage and Selection Operator (LASSO) regression on 25 TAAD samples. Consensus clustering classified TAAD samples based on disulfidptosis-related gene expression. Functional enrichment analyses, including Gene Ontology (GO) terms and Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway analyses, elucidated associated biological processes and pathways. A total of 13,316 DEGs were identified, among which 11 disulfidptosis-related genes were screened: INF2, CD2AP, PDLIM1, ACTN4, MYH10, MYH9, FLNA, FLNB, TLN1, MYL6, ACTB, CAPZB, DSTN, and IQGAP1. Most of these genes exhibited lower expression levels in TAAD samples, except CAPZB, and were correlated with immune cell infiltration. Cluster-specific DEGs were found in one cluster, involving several immune response processes. Co-clustering analysis based on disulfidptosis-related genes classified TAAD samples into two clusters, with higher gene expression levels observed in cluster C2 compared to cluster C1. Three key hub genes were identified, and potential therapeutic mechanisms for TAAD were explored. Immuno-infiltration results revealed significant differences in immune profiles, with higher immunological scores and more extensive immune infiltration in TAAD. Disulfidptosis occurs in TAAD and is associated with immune cell infiltration and metabolic activity, influencing immune cell function and responses. These findings suggest that disulfidptosis may promote TAAD progression through the induction of immune responses and metabolic activities. This research provides new insights into the pathogenesis and identifies potential therapeutic targets for TAAD.

The vascular microenvironment and its stem cells regulate vascular homeostasis

The vascular microenvironment comprises of anatomical structures, extracellular matrix components, and various cell populations, which play a crucial role in regulating vascular homeostasis and influencing vascular structure and function. Under physiological conditions, intrinsic regulation of the vascular microenvironment is required to sustain vascular homeostasis. In contrast, under pathological conditions, alterations to this microenvironment lead to vascular injury and pathological remodeling. According to the anatomy, the vascular microenvironment can be subdivided into three sections from the inside out. The vascular endothelial microenvironment, centered on vascular endothelial cells (VECs), includes the extracellular matrix and various vascular physicochemical factors. The VECs interact with vascular physicochemical factors to regulate the function of various parenchymal cells, including hepatocytes, neurons and tumor cells. The vascular wall microenvironment, comprising the vasa vasorum and their unique stem/progenitor cell niches, plays a pivotal role in vascular inflammation and pathological remodeling. Additionally, the perivascular microenvironment, which includes perivascular adipose tissue, consists of adipocytes and stem cells, which contribute to the pathological processes of atherosclerosis. It is anticipated that targeted regulation of the vascular microenvironment will emerge as a novel approach for the treatment of various diseases. Accordingly, this review will examine the structure of the vascular microenvironment, the regulation of vascular function by vascular cells and stem/progenitor cells, and the role of the vascular microenvironment in regulating cardiovascular diseases.

The diagnostic and prognostic value of SAA1 as a novel biomarker for acute aortic dissection

BACKGROUND AND AIMS

Acute aortic dissection (AAD) is a serious life-threatening cardiovascular condition. It is necessary to find rapid and accurate biomarkers for the diagnosis of AAD. This study aimed to determine the efficacy of serum amyloid A1 (SAA1) in the diagnosis and prediction of long-term adverse events in AAD.

MATERIALS AND METHODS

Four-dimensional label-free quantification (4D-LFQ) technique was used to identify the differentially expressed proteins (DEPs) in aortic tissues of AAD. After comprehensive analysis, SAA1 was identified as a potential biomarker of AAD. ELISA was used to confirm the expression of SAA1 in serum of AAD patients. Moreover, the source of SAA1 in serum was explored by constructing AAD mouse model.

RESULTS

A total of 247 DEPs were identified, of which 139 were upregulated while 108 were downregulated. SAA1 was nearly 6.4-fold and 4.5-fold upregulated in AAD tissue and serum. ROC curve and Kaplan-Meier survival curve confirmed the good efficacy of SAA1 for the diagnosis and prediction of long-term adverse events in AAD. In vivo experiments revealed that SAA1 was mainly derived from the liver when AAD occurred.

CONCLUSION

SAA1 can be used as a potential biomarker for AAD with effective diagnostic and prognostic value.

SIGNIFICANCE

Despite the advances in medical technology in recent years, the mortality rate of acute aortic dissection (AAD) is still high. It is still challenging for clinicians to diagnose AAD patients on time and reduce the mortality rate. In this study, 4D-LFQ technology was used to identify serum amyloid A1 (SAA1) as a potential biomarker of AAD and was verified in subsequent work. The results of this study determined the efficacy of SAA1 in the diagnosis and prediction of long-term adverse events in patients with AAD.

Applying multi-omics techniques to the discovery of biomarkers for acute aortic dissection

Acute aortic dissection (AAD) is a cardiovascular disease that manifests suddenly and fatally. Due to the lack of specific early symptoms, many patients with AAD are often overlooked or misdiagnosed, which is undoubtedly catastrophic for patients. The particular pathogenic mechanism of AAD is yet unknown, which makes clinical pharmacological therapy extremely difficult. Therefore, it is necessary and crucial to find and employ unique biomarkers for Acute aortic dissection (AAD) as soon as possible in clinical practice and research. This will aid in the early detection of AAD and give clear guidelines for the creation of focused treatment agents. This goal has been made attainable over the past 20 years by the quick advancement of omics technologies and the development of high-throughput tissue specimen biomarker screening. The primary histology data support and add to one another to create a more thorough and three-dimensional picture of the disease. Based on the introduction of the main histology technologies, in this review, we summarize the current situation and most recent developments in the application of multi-omics technologies to AAD biomarker discovery and emphasize the significance of concentrating on integration concepts for integrating multi-omics data. In this context, we seek to offer fresh concepts and recommendations for fundamental investigation, perspective innovation, and therapeutic development in AAD.

DNA methylation alternation in Stanford- A acute aortic dissection

Background

Acute aortic dissection (AAD) is a life-threatening cardiovascular disease. Recent studies have shown that DNA methylation may be associated with the pathological mechanism of AAD, but the panorama of DNA methylation needs to be explored.

Methods

DNA methylation patterns were screened using Infinium Human Methylation 450 K BeadChip in the aortic tissues from 4 patients with Stanford-A AAD and 4 controls. Gene enrichment was analyzed by Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway and gene ontology (GO). DNA methylation levels of candidate genes were determined by pyrosequencing in the replication cohort including 16 patients with AAD and 7 controls. Protein expression level of candidate gene was assessed by Western blot.

Results

A total of 589 differentially methylated positions including 315 hypomethylated and 274 hypermethylated positions were found in AAD group. KEGG analysis demonstrated that differentially methylated position-associated genes were enriched in MAPK signaling pathway, TNF signaling pathway and apoptosis pathway, et al. GO analysis demonstrated that differentially methylated position-associated genes were enriched in protein binding, angiogenesis and heart development et al. The differential DNA methylation in five key genes, including Fas, ANGPT2, DUSP6, FARP1 and CARD6, was authenticated in the independent replication cohort. The protein expression level of the Fas was increased by 1.78 times, indicating the possible role of DNA methylation in regulation of gene expression.

Conclusion

DNA methylation was markedly changed in the aortic tissues of Stanford-A AAD and associated with gene dysregulation, involved in AAD progression.

Supplementary Information

The online version contains supplementary material available at10.1186/s12872-022-02882-5.