<HashMap><database>iProX</database><scores/><additional><omics_type>Proteomics</omics_type><submitter>Weizhang Fu</submitter><species>Acyrthosiphon Pisum</species><full_dataset_link>http://www.iprox.org/page/project.html?id=IPX0016442000</full_dataset_link><submitter_email>sdaufwz@sdau.edu.cn</submitter_email><submitter_affiliation>Shandong Agricultural University,College of Resources and Environment</submitter_affiliation><sample_protocol></sample_protocol><repository>iProX</repository><data_protocol></data_protocol></additional><is_claimable>false</is_claimable><name>Multi-omics analysis reveals the adaptation strategies of diatoms under high nitrogen-phosphorus ratios: from growth inhibition to reprogramming of metabolic networks</name><description>To investigate the response of a dominant freshwater diatom to changes in nutrient stoichiometry, Cyclotella meneghiniana isolated from the Chaiwen River, an important tributary of the lower Yellow River, and Dongping Lake, a shallow eutrophic freshwater lake in northern China, was used as the study species. Indoor culture experiments were conducted under four nitrogen-to-phosphorus (N:P) ratios, namely 4:1, 8:1, 16:1, and 64:1. By combining nutrient monitoring with integrated transcriptomic and proteomic analyses, we investigated the physiological and molecular responses of Cyclotella meneghiniana to different N:P conditions. The results showed that lower N:P ratios were associated with higher biomass accumulation and faster nitrogen and phosphorus consumption, whereas the 64:1 treatment showed lower final biomass and reduced nutrient utilization efficiency. Integrated transcriptomic and proteomic analyses further showed that the high-N:P treatment exhibited a more distinct transcriptional profile, whereas proteomic responses were comparatively more dispersed, suggesting partial transcript–protein decoupling. GO and KEGG enrichment analyses suggested that different N:P ratios were mainly associated with changes in broadly conserved processes related to protein synthesis, energy metabolism, and cellular homeostasis, including ribosome-related functions, protein processing, oxidative phosphorylation, and glyoxylate metabolism. This study provides new insight into the physiological and molecular adaptation of a dominant freshwater diatom to altered nitrogen and phosphorus stoichiometry, and offers a basis for understanding how nutrient imbalance may influence algal responses in eutrophic waters.</description><dates><publication>Tue Mar 31 00:00:00 GMT+01:00 2026</publication></dates><accession>PXD076358</accession><cross_references><TAXONOMY>7029</TAXONOMY></cross_references></HashMap>