土曲霉的伤口愈合、代谢物分析和 In Silico 研究。

IF 2.8 3区 生物学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY Current Issues in Molecular Biology Pub Date : 2024-10-19 DOI:10.3390/cimb46100694
Amal A Al Mousa, Mohamed E Abouelela, Ahmed Mansour, Mohamed Nasr, Yasser H Ali, Nadaa S Al Ghamidi, Youssef Abo-Dahab, Hassan Mohamed, Nageh F Abo-Dahab, Abdallah M A Hassane
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引用次数: 0

摘要

烧伤严重影响全球公众健康,需要针对不同严重程度的烧伤采取有效的治疗策略。真菌被认为是一种可持续的、易于繁殖的先导治疗发现来源。在这项研究中,我们通过结合体外、体内、代谢物分析和硅学分析,探索了土曲霉的烧伤伤口愈合潜力。利用人体皮肤成纤维细胞进行的体外划痕试验显示了良好的伤口愈合活性。此外,烧伤诱导的大鼠模型也显示出皮肤伤口愈合的明显改善,这表现在经过 14 天的赤霉土提取物处理后,伤口闭合速度加快,皮肤再生能力增强。这项研究结果表明,经过处理的大鼠模型的伤口闭合和组织再生能力显著增强,超过了标准疗法的效果。这种可控的愈合过程表现为卓越的胶原合成和血管生成,并得到了组织病理学研究的证实,这表明赤霉菌具有超越传统研究的真菌代谢物的潜力。通过对接分析,对 27 种生物活性化合物的代谢物谱进行了进一步研究,以了解它们对 NF-κB 通路的潜在抑制作用,NF-κB 通路在炎症和伤口修复中具有重要功能。Eurobenzophenone A (7)、aspernolide D (16)、asperphenalenone A (23)、aspergilate D (15)、kodaistatin A (18) 和 versicolactone A (14) 与目标蛋白质的结合亲和力最高,姿势得分分别为 -16.86、-14.65、-12.65、-12.45、-12.19 和 -12.08 kcal/mol。此外,还进行了药物相似性研究。这些研究结果表明,赤霉土具有潜在的伤口愈合特性,可作为发现先导治疗候选药物的来源。
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Wound Healing, Metabolite Profiling, and In Silico Studies of Aspergillus terreus.

Burn injuries, which significantly affect global public health, require effective treatment strategies tailored to varying severity. Fungi are considered a sustainable, easily propagated source for lead therapeutic discovery. In this study, we explored the burn wound healing potential of Aspergillus terreus through a combination of in vitro, in vivo, metabolite profiling, and in silico analysis. The in vitro scratch assays performed with human skin fibroblast cells showed promising wound healing activity. Furthermore, the burn-induced rats model showed a marked improvement in cutaneous wound healing, evidenced by an accelerated rate of wound closure and better skin regeneration after A. terreus extract treatment at 14 days. The results of this study demonstrated significant enhancements in wound closure and tissue regeneration in the treated rat model, surpassing the outcomes of standard treatments. This controlled healing process, evidenced by superior collagen synthesis and angiogenesis and confirmed by histopathological studies, suggests that A. terreus has potential beyond the traditionally studied fungal metabolites. The metabolite profiling of 27 bioactive compounds was further investigated by docking analysis for the potential inhibition of the NF-κB pathway, which has an important function in inflammation and wound repair. The compounds eurobenzophenone A (7), aspernolide D (16), asperphenalenone A (23), aspergilate D (15), kodaistatin A (18), and versicolactone A (14) showed the highest binding affinity to the target protein with a pose score of -16.86, -14.65, -12.65, -12.45, -12.19, and -12.08 kcal/mol, respectively. Drug-likeness properties were also conducted. The findings suggest the potential wound healing properties of A. terreus as a source for lead therapeutic candidate discovery.

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来源期刊
Current Issues in Molecular Biology
Current Issues in Molecular Biology 生物-生化研究方法
CiteScore
2.90
自引率
3.20%
发文量
380
审稿时长
>12 weeks
期刊介绍: Current Issues in Molecular Biology (CIMB) is a peer-reviewed journal publishing review articles and minireviews in all areas of molecular biology and microbiology. Submitted articles are subject to an Article Processing Charge (APC) and are open access immediately upon publication. All manuscripts undergo a peer-review process.
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