Canteri Paolo, Battarra Claudia, Mandalà Giulia, Monti Francesca, Bellini Erika, Hidasi Nora, Guardini Zeno, Ferrari Simone, Bassi Roberto, Dall'Osto Luca
Dipartimento di Biotecnologie, Università di Verona, Strada Le Grazie 15, 37134, Verona, Italy.
Dipartimento di Informatica, Università Verona, Strada Le Grazie 15, 37134, Verona, Italy.
Biotechnol Biofuels Bioprod. 2025 Jun 5;18(1):59. doi: 10.1186/s13068-025-02663-0.
Large-scale cultivation of microalgae provides a carbon-neutral source of biomass for extracting valuable compounds and producing renewable fuels. Owing to their high metabolic activity and rapid reproduction rates, Chlorella species are highly productive when grown in photobioreactors. However, wild-type strains have some biological limitations that make algal bioproducts more expensive than those from more traditional sources. Domestication is thus required for improving strains. Engineering Chlorella species has been made difficult by their chemically complex and highly resistant cell wall, making transformation difficult. Cell wall also restricts diffusion of organic solvents; thus, limiting the extraction of valuable intracellular compounds. Obtaining strains with weakened cell wall is crucial to enhance the extractability of intracellular molecules, reducing the costs of biomass disruption, and to improve genetic transformation efficiency.
We developed a mutagenesis pipeline combined with single-cell fluorescence scanning on the microalga Chlorella vulgaris to identify mutants with altered cell wall properties. We used the fluorescent dyes erythrosin B and calcofluor white, as markers for cell wall permeability and for binding the structural polysaccharides of the cell wall, respectively. Flow cytometry with fluorescence-activated cell sorting was employed to enrich mutagenized populations with altered emission profiles. After a first round of mutagenesis, we found six mutants with significantly higher cell permeability to erythrosin B than the wild type (CWP lines) and altered cell wall structure and composition. A second round of mutagenesis on a selected CWP strain, followed by selection for lower calcofluor white signal, resulted in the isolation of CFW lines, which exhibited reduced mechanical resistance when the biomass was subjected to cell disruption procedures. This two-steps procedure allowed us to identify new mutant strains with both an increased cell wall permeability and a reduced mechanical resistance, making a novel step towards Chlorella domestication.
This study demonstrated the feasibility of using mutagenesis and phenotypic selection based on flow cytometry screening to alter the cell wall of C. vulgaris and identify promising strains with improved traits for industrial applications.
微藻的大规模培养为提取有价值的化合物和生产可再生燃料提供了一种碳中和的生物质来源。由于其高代谢活性和快速繁殖率,小球藻属物种在光生物反应器中生长时具有很高的生产力。然而,野生型菌株存在一些生物学限制,使得藻类生物产品比来自更传统来源的产品成本更高。因此,需要进行驯化以改良菌株。小球藻属物种的细胞壁化学组成复杂且高度抗性,这使得对其进行基因工程改造变得困难,导致转化困难。细胞壁还限制了有机溶剂的扩散,从而限制了有价值的细胞内化合物的提取。获得细胞壁弱化的菌株对于提高细胞内分子的可提取性、降低生物质破碎成本以及提高遗传转化效率至关重要。
我们开发了一种诱变流程,并结合对普通小球藻进行单细胞荧光扫描,以鉴定细胞壁特性发生改变的突变体。我们使用荧光染料赤藓红B和荧光增白剂,分别作为细胞壁通透性的标记和用于结合细胞壁结构多糖的标记。采用荧光激活细胞分选的流式细胞术来富集发射谱改变的诱变群体。第一轮诱变后,我们发现了六个突变体,它们对赤藓红B的细胞通透性明显高于野生型(CWP系),并且细胞壁结构和组成发生了改变。对选定的CWP菌株进行第二轮诱变,然后选择较低的荧光增白剂信号,从而分离出CFW系,当对生物质进行细胞破碎操作时,该系表现出降低的机械抗性。这个两步程序使我们能够鉴定出细胞壁通透性增加且机械抗性降低的新突变菌株,这是小球藻驯化的一个新进展。
本研究证明了基于流式细胞术筛选使用诱变和表型选择来改变普通小球藻细胞壁并鉴定具有改进性状的有前景菌株用于工业应用的可行性。
