Table 1.
Proteomics study in invasive plants, there are very few proteomics studies that have specifically focused on invasive plants.
| Invasive Plant Species | Techniques of Omic | Findings of Study | References |
|---|---|---|---|
| Ageratina adenophora (crofton weed). | Proteomic (root exudates) | Identified proteins involved in allelopathy, which may contribute to the invasiveness of the plant. | [96,97,98] |
| Acacia saligna (golden wattle). | Proteomics (N fixing root nodules) | Identified protein elaboration in N fixation and transport; it enhances the plant’s growth and competitive ability in nutrient-poor soils. | [99] |
| Microstegium vimineum (Japanese stiltgrass). | Proteomic (invasive and native populations) | Identified differences in protein expression related to photosynthesis, stress response. | [73] |
| Cytisus scoparius (Scotch broom). | Proteomics (leaves and roots) | Identified proteins involved in plant defense, nutrient uptake. | [100] |
| S. alterniflora. | Chemico-proteomics | The function of H2S signaling in the adaptation of an invasive plant species and the important role of H2S adaptation in S. alterniflora to saline environments. | [101] |
| R. solanacearum. | Proteomics | Plant–bacterium interactions. | [102] |
| Incompatible rice/Magnaporthe grisae. | Proteomics | Plant–pathogen relationship; it is important in apoplastic protein patterns that occur during pathogen infection. | [103] |
| Potato with Ralstonia solanacearum UW551. | Proteomics | T3Es of R. solanacearum can subvert potato root immune-related proteins in a redundant manner. | [104] |
| Tomato (Solanum lycopersicum) fruit was invaded by Sclerotinia rolfsii. | Proteomics | To prioritize candidate proteins for storage organ quality improvement. | [105] |
| Aspergillus terreus invades Solanum tuberosum L. | Proteomics | During colonization, TA. terreus differently activated enzymes in potato tubers. | [106] |
| Phytophthora infestans, the pathogen responsible for potato late blight. | Proteomics | The potential magnitude of proteins encoded in the genome. | [107] |
| Expressed in Nicotiana benthamiana, R. solan. | Proteomics | Pathogens can adapt to the specific host they encounter. | [108] |
| Interactions between plants and viruses, bacteria, fungi, and nematode. | Proteomics | Interactions between plants and viruses, bacteria, fungi, and nematodes were identified and reported in proteomic studies. | [109] |
| Arabidopsis thaliana plants. | Proteomics | Providing insight into the signaling networks of a particular cell type. | [110] |
| The symbiotic interaction between Brassica napus and Piriformospora indica. | Proteomics | GO and KEGG pathway analysis revealed gene sets involved in metabolic processes. | [111] |
| Magnaporthe oryzae (M. oryzae). | Proteomics | Response to M. oryzae invasion; the iTRAQ approach was utilized to identify differentially expressed proteins (DEPs) in both the durable, resistant rice variety Gangyuan8 (GY8) and the susceptible rice variety Lijiangxintuanheigu (LTH). | [112] |
| Study interactions between plants and pathogens | Proteomics | Interactions between plants and pathogens in compatible systems. | [113] |
| Potato, a model for periderm. | Proteomics | Early tuber growth in potatoes; periderm tissue replaces the epidermis. | [114] |
| Microbial pathogens. | Proteomics | Bacterial interactions among distinct bacterial taxa, including symbiotic, pathogenic, and commensal bacteria. | [115] |
| Tomato | Proteomics | Proteome study investigation of the dynamics of various disease responses in tomato. | [116] |
| Hybrids of Solanum differing in resistance to Dickeya solani. | Proteomics | Significant differences were observed in the large-fold of various proteins between resistant and susceptible potato cultivars, and diploid clones were induced. | [117] |
| Proteomics toward the improvement of crop productivity and stress resistance. | Proteomics | The limitations of non-model organism proteomics techniques and data interpretation. | [118] |
| Plant. | Proteomics | Plant-specific issues on how proteomics can help plant systems biology. | [119] |
| Plant. | Proteomics | Plant proteomics is currently in its early stages and is subject to a significant impact on plant biology. | [120] |
| Alternanthera philoxeroides (Alligator weed). | Proteomics | The response of Alternanthera philoxeroides roots stems, and leaves to potassium deficiency stress. | [121] |
| Gibberella stalk rot in maize. | Proteomics | The defense response of corn stalks against graminearum, proteins from various immune-related pathways. | [122] |
| Rice in biotic stress. | Proteomics, metabolomics | Proteins and metabolites defense response of rice to biotic stress. | [123] |