Lactylation-related potential targets and Chinese herbal medicine active ingredients targeting treatment of spinal cord injury: GEO database screening analysis

doi:10.12307/2026.709

Abstract

Abstract: BACKGROUND: Lactylation plays an important role in spinal cord injury by regulating the immune microenvironment, but its key biomarkers and mechanisms have not been clarified. The present study aims to systematically analyze the association between abnormal lactate metabolism and spinal cord injury based on multiple databases, including the GEO database, and the integration of multiregional spinal cord injury data (covering both European and Asian populations). By mining the regulatory network of lactation-related genes, we can reveal the new mechanism of metabolism-immunity interaction and predict the target drugs, which will provide a theoretical basis for the development of therapeutic strategies.
OBJECTIVE: To screen core biomarkers related to lactylation in spinal cord injury, to analyze their regulatory mechanisms, and to predict potential active components of traditional Chinese medicine.
METHODS: The study integrated three spinal cord injury datasets (GSE45006, GSE114426, and GSE2599, containing 30 spinal cord injury and 10 normal samples) and validation set (GSE151371, 58 samples) from the GEO database (maintained by NCBI, which contains global public gene expression profiles), combined with the MSigDB database (developed by the Broad Institute for gene function annotation) of 395 lactate-related genes, and screened the core genes by differential expression analysis, weighted gene co-expression network, and machine learning algorithms (LASSO, XGBoost, and Random Forest). Sample data from a total of 815 376 samples from the Integrated Epidemiological Unit (IEU) database (a repository developed and maintained by the MRC Integrated Epidemiological Unit for storing and sharing genome-wide association study (GWAS) data) and Mendelian randomization analyses were used to validate causal association between lactate metabolism and spinal cord injury, followed by immune infiltration analysis. The target components were also predicted from ITCM and HERB TCM database (constructed by the Chinese Academy of Sciences, covering active ingredients of traditional medicines).
RESULTS AND CONCLUSION: SLC16A7 and ACACA were identified as core lactylation genes associated with spinal cord injury, and their expression was significantly associated with M2 macrophage and T cell infiltration. Mendelian randomization analysis showed that lactate [odds ratio (OR)=1.89, 95% confidence interval (CI): 0.99-3.62] and lactate dehydrogenase (OR=0.34, 95% CI: 0.16-0.74) were significantly causally associated with spinal cord injury (P < 0.05), while SLC16A7 and ACACA were risk factors for spinal cord injury (OR > 1.00). Molecular docking identified quercetin, estradiol and ginseng saponin as active ingredients, which were stable in binding to their targets and met the criteria for drug-like properties. These findings indicate that SLC16A7 and ACACA are biomarkers associated with lactylation in spinal cord injury, and herbal medicines and their active ingredients targeting these genes have potential therapeutic values. To conclude, this study reveals the regulatory role of lactation modification in spinal cord injury based on international standardized databases and European cohort-led multi-omics data. Its methodological framework (e.g., multi-omics integration, Mendelian randomization for causal inference) provides an important reference for biomedical research in China: on the one hand, it promotes cross-ethnic data sharing and validation to make up for the lack of regional samples; on the other hand, it opens up a new pathway for drug development in the treatment of spinal cord injury with the combination of Chinese and Western medicines by tapping into the mechanism of interactions between Chinese herbal medicine’s active ingredients and their targets, which can advance the localization of precision medicine practices..

Key words: lactylation, spinal cord injury, biomarkers, immune infiltration, Mendelian randomization

CLC Number:

Liang Liang, Yan Yulu, Zheng Yang, Zhang Xiaoyun, Wang Lei, Qi Wen . Lactylation-related potential targets and Chinese herbal medicine active ingredients targeting treatment of spinal cord injury: GEO database screening analysis[J]. Chinese Journal of Tissue Engineering Research, 2026, 30(12): 3156-3170.

Figures/Tables 16

B)。LASSO回归从LR-DEGs中预测了5个基因，受试者工作特征曲线的曲线下面积为0.89(图3C-E)。XGBoost算法鉴定了8个基因(图3F)。通过使用维恩图确定所有3种方法的共同基因，得出3个特征基因SLC16A7、ACACA和COX4I1(图3G)。 2.4 脊髓损伤生物标志物的临床相关性检验为了进一步研究已鉴定的生物标志物与脊髓损伤的联系。通过受试者工作特征曲线验证了模型的性能和准确性(图4A-F)。其中，SLC16A7和ACACA曲线下面积值均高于0.5，突出了它们对脊髓损伤出色的诊断潜力。COX4I1在验证集中并未表现出具有出色的诊断能力(曲线下面积未高于0.5)，这可能与GEO数据集中同一基因的表达组织不同而导致的结果，其诊断能力需要进一步研究验证。同时，评估了此研究使用的数据集中SLC16A7、ACACA和COX4I1的表达，包括训练队列和单独的验证队列。SLC16A7和ACACA表达的趋势在所有数据集中保持一致，但COX4I1表达的趋势未保持一致(图4G，H)，故在后续分析中将其排除。只选择SLC16A7和ACACA为关键基因以进行后续分析。 2.5 单基因GSEA分析为探讨SLC16A7和ACACA在脊髓损伤机制中的作用，进行了单基因GSEA分析。选择KEGG通路富集以揭示了其与关键通路的关联，通路包括“各类信号通路”和“神经活性物质与受体相互作用”等(图5A，B)。 2.6 免疫浸润分析使用TIMER2.0 (http://timer.cistrome.org/)平台以CIBERSORT算法分析了免疫细胞的组成(图6A，B)。评估训练集中免疫细胞的表达水平(图6C)。值得注意的是，4种免疫细胞类型，包括初始CD4+ T细胞、滤泡辅助性T细胞、γδ T细胞和M2巨噬细胞在脊髓损伤样本之间的丰度显著不同。进一步分析揭示了关键基因(SLC16A7和ACACA)与特异性免疫细胞(尤其是T细胞和M2巨噬细胞)之间的强相关性(图7)。 2.7 双样本孟德尔随机化分析乳酸[Lactate：OR=1.89；95%CI(0.99-3.62)；P=0.054 843]和乳酸脱氢酶[Lactate dehydrogenas：OR=0.34；95%CI (0.16，0.74)；P=0.006 991]与脊髓损伤均表现强因果关系。2个基因(SLC16A7和ACACA)的OR值大于1，表明基因表"

达与脊髓损伤可能性增加相关，为危险因素。敏感性分析显示因果效应的漏斗图近似对称。留一法分析表明，在去除每个单核苷酸多态性后对剩余的单核苷酸多态性进行孟德尔随机化分析会产生一致的结果，表明这一发现的稳健性，见图8。 2.8 关键基因可药性分析 SLC16A7和ACACA均满足得分> 60，具有潜在可药性，见表2。D-乳酸、α-D-喹啉并吡喃糖、尼氟米卡酸、乙酰乙酸和α-酮异戊酸11种实验室药物靶向SLC16A7，靶向ACACA的实验室药物有生物素等，见表3。在相关研究中提到多巴胺也是靶向SLC16A7的潜在药物 [12，19]。故而通过靶向SLC16A7、ACACA或者其他相关基因的药物帮助脊髓损伤恢复具有一定可行性。同时研究检索到SLC16A7和ACACA与脊髓损伤有显著关系[20]。综上，SLC16A7和ACACA具有成为研究防治脊髓损伤药物的潜在靶点。 2.9 基于脊髓损伤关键基因筛选活性成分及潜在中药基于ITCM数据库和HERB数据库的检索结果，发现与SLC16A7相关的活性成分有8种，与之相关的中药有4味。与ACACA相关的活性成分有16种，与之相关的中药有3味(表3)。其中，关键基因(SLC16A7和ACACA)与活性成分的分子对接分数前3名化合物组合分别是雌二醇(Estradiol)、丙酮酸(pyruvate，PYR)、槲皮素(quercetin)与SLC16A7；马德卡糖苷(madecassoside)、灵芝酸α(ganodericacidα)、熊果酸(augustic-acid)与ACACA，见图9和表4。同时对关键基因(SLC16A7和ACACA)与活性成分的分子对接分数前2名化合物组合进行分子动力学模拟，均方根偏差(root mean square deviation，RMSD)曲线表明SLC16A7- Estradiol在5 ns后开始趋于稳定；SLC16A7-quercetin在5 ns后开始趋于稳定；ACACA-madecassoside在50 ns后开始趋于稳定；ACACA-ganodericacidα在30 ns后开始趋于稳定。均方根波动(root mean square fluctuation，RMSF)图表明4对核心成分的峰值范围均在0.01-1.00 nm之间，表明SLC16A7和ACACA在特定压力和温度下十分稳定。总之分子动力学模拟有力地支持了对接结果的有效性，见图10。"

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