Institute of Organic Chemistry and Center for Molecular Biosciences, University of Innsbruck, 6020, Innsbruck, Austria.
Chemistry. 2024 Jun 20;30(35):e202401288. doi: 10.1002/chem.202401288. Epub 2024 May 23.
Breakdown of chlorophyll (Chl), as studied in angiosperms, follows the pheophorbide a oxygenase/phyllobilin (PaO/PB) pathway, furnishing linear tetrapyrroles, named phyllobilins (PBs). In an investigation with fern leaves we have discovered iso-phyllobilanones (iPBs) with an intriguingly rearranged and oxidized carbon skeleton. We report here a key second group of iPBs from the fern and on their structure analysis. Previously, these additional Chl-catabolites escaped their characterization, since they exist in aqueous media as mixtures of equilibrating isomers. However, their chemical dehydration furnished stable iPB-derivatives that allowed the delineation of the enigmatic structures and chemistry of the original natural catabolites. The structures of all fern-iPBs reflect the early core steps of a PaO/PB-type pathway and the PB-to-iPB carbon skeleton rearrangement. A striking further degradative chemical ring-cleavage was observed, proposed to consume singlet molecular oxygen (O). Hence, Chl-catabolites may play a novel active role in detoxifying cellular O. The critical deviations from the PaO/PB pathway, found in the fern, reflect evolutionary developments of Chl-breakdown in the green plants in the Paleozoic era.
叶绿素(Chl)的分解,如在被子植物中所研究的,遵循脱镁叶绿酸 a 加氧酶/叶啉(PaO/PB)途径,提供线性四吡咯,命名为叶啉(PBs)。在对蕨类植物叶子的研究中,我们发现了具有引人注目的重排和氧化碳骨架的同型叶啉酮(iPBs)。我们在这里报告了来自蕨类植物的第二类关键 iPBs 及其结构分析。以前,由于这些额外的 Chl 分解产物存在于水介质中作为平衡异构体的混合物,因此它们的特征分析被遗漏了。然而,它们的化学脱水提供了稳定的 iPB 衍生物,允许对原始天然分解产物的神秘结构和化学进行描述。所有蕨类植物-iPB 的结构反映了 PaO/PB 型途径的早期核心步骤以及 PB 到 iPB 碳骨架重排。观察到进一步的惊人降解化学环裂解,据推测其消耗单重态分子氧(O)。因此,Chl 分解产物可能在细胞 O 的解毒中发挥新的积极作用。在蕨类植物中发现的与 PaO/PB 途径的关键偏离反映了古生代绿色植物中 Chl 分解的进化发展。
