Farag Mohamed A, Saied Doaa B, Afifi Sherif M, Kunzmann Andreas, Wessjohann Ludger A, Westphal Hildegard, Kühnhold Holger, Stuhr Marleen
Pharmacognosy Department, Faculty of Pharmacy, Cairo University, Cairo 11562, Egypt.
Chemistry Department, School of Sciences and Engineering, The American University in Cairo, New Cairo 11835, Egypt.
J Adv Res. 2025 Aug;74:255-268. doi: 10.1016/j.jare.2024.10.007. Epub 2024 Oct 15.
Climate change poses various threats to marine life, particularly in shallow tropical waters.
The impact of increased temperature and ultraviolet (UV) exposure on two photosymbiotic cnidarians, a common bubble-tip anemone and an upside-down jellyfish, was investigated.
To illustrate the response of aquatic organisms, the metabolomes of unstressed Entacmaea quadricolor and Cassiopea andromeda were compared for detailed metabolite profiling. UHPLC-MS coupled with chemometrics and GNPS molecular networking was employed for sample classification and identification of markers unique to stress responses in each organism.
Several compounds with bioactive functions, including peptides and terpenoids, were reported for the first time in both organisms, viz. cyclic tetraglutamate, campestriene, and ceramide aminoethyl phosphonate (CEAP d18:2/16:0). Both anemone and jellyfish were subjected to either elevated UV-B light intensity up to 6.6 KJ m or increased temperatures (28 °C, 30 °C, 32 °C, and 34 °C) over 4 days. Phospholipids, steroids, and ceramides emerged as chief markers of both types of stress, as revealed by the multivariate data analysis. Lysophosphatidylcholine (LPC 16:0), LPC (18:0/0:0), and echinoclasterol sulfate appeared as markers in both UV and thermal stress models of the anemone, whereas methyl/propyl cholestane-hexa-ol were discriminatory in the UV stress model only. In the case of jellyfish, nonpolar glycosyl ceramide GlcCer (d14:1/28:6) served as a marker for UV stress, whereas polar peptides were elevated in the thermal stress model. Interestingly, both models of jellyfish share a phospholipid, lysophosphatidylethanolamine (LPE 20:4), as a distinctive marker for stress, reported to be associated indirectly with the activity of innate immune response within other photosymbiotic Cnidaria such as corals and appears to be a fundamental stress response in marine organisms.
This study presents several bioinformatic tools for the first time in two cnidarian organisms to provide not only a broader coverage of their metabolome but also broader insights into cnidarian bleaching in response to different stressors, i.e., heat and UV light, by comparing their effects in anemone versus jellyfish.
气候变化对海洋生物构成了各种威胁,尤其是在热带浅水区。
研究温度升高和紫外线(UV)照射对两种光合共生刺胞动物的影响,这两种动物分别是常见的气泡海葵和倒立水母。
为了阐明水生生物的反应,比较了未受胁迫的四色艾氏海葵和仙女杯根口水母的代谢组,以进行详细的代谢物谱分析。采用超高效液相色谱 - 质谱联用技术结合化学计量学和全球天然产物社会分子网络(GNPS)进行样本分类,并识别每种生物应激反应特有的标志物。
在这两种生物中首次报道了几种具有生物活性功能的化合物,即环状四谷氨酸、菜子甾烯和神经酰胺氨基乙基膦酸酯(CEAP d18:2/16:0)。海葵和水母在4天内分别受到高达6.6 KJ m的增强UV - B光强度照射或温度升高(28°C、30°C、32°C和34°C)的影响。多变量数据分析表明,磷脂、类固醇和神经酰胺是这两种应激类型的主要标志物。溶血磷脂酰胆碱(LPC 16:0)、LPC(18:0/0:0)和硫酸海胆甾醇在海葵的UV和热应激模型中均作为标志物出现,而甲基/丙基胆甾烷 - 六醇仅在UV应激模型中具有区分性。就水母而言,非极性糖基神经酰胺GlcCer(d14:1/28:6)作为UV应激的标志物,而极性肽在热应激模型中升高。有趣的是,水母的两种模型都有磷脂溶血磷脂酰乙醇胺(LPE 20:4)作为应激的独特标志物,据报道它与其他光合共生刺胞动物如珊瑚体内的先天免疫反应活性间接相关,并且似乎是海洋生物中的一种基本应激反应。
本研究首次在两种刺胞动物中展示了几种生物信息学工具,通过比较海葵和水母中不同应激源(即热和UV光)的影响,不仅更全面地覆盖了它们的代谢组,还更深入地了解了刺胞动物因不同应激源导致的白化现象。
