Biology and resource acquisition of mistletoes, and the defense responses of host plants

• Published in: Ecological processes Vol. 11; no. 1; pp. 1 - 13
• Main Authors: Muche, Meseret, Muasya, A. Muthama, Tsegay, Berhanu Abraha
• Format: Journal Article
• Language: English
• Published: Berlin/Heidelberg Springer Berlin Heidelberg 21.02.2022; Springer Nature B.V; SpringerOpen
• Subjects: Biology; Biotic stress; Butterflies & moths; Cell walls; Chemical interactions; Dispersal; Dispersion; Earth and Environmental Science; Environment; Feeders; Flowering; Flowers & plants; Haustorium; Herbivory; Host defense; Host plants; Host specificity; Infections; Metabolites; Mimicry; Mineral nutrients; Minerals; Mistletoes; Nitrogen; Nutrient loading; Parasites; Parasitic plants; Phenols; Plant growth; Plants; Plants (botany); Pollination; Resource procurement; Review; Secondary metabolites; Seed dispersal; Specificity; Spines; Stress (physiology); Survival; Terpenes; Xylem; Xyloglucan; Biotic stress; Host defense; Mistletoes; Haustorium; Resource procurement; Mimicry
• ISSN: 2192-1709; 2192-1709
• DOI: 10.1186/s13717-021-00355-9

Background Mistletoes are the most successful group of obligatory hemi-parasitic flowering plants that attach to the host via haustorium for obtaining water and minerals. This review aims to assess the current knowledge on mistletoes host plant recognition, haustorium formation, water/minerals acquisition, and host plants’ defense signaling and responses against mistletoe attack. Results Some mistletoes are host-specific while others are generalists occurring on a wide range of vascular plants. The host nitrogen (N) content, parasite–host chemical interactions, compatibility, and dispersal agents are the main determinant factors for host specificity. Mistletoes take up substantial amounts of water and minerals passively via apoplastic routes, and most are xylem feeders, but could shift to phloem-feeding during the physiological stress of the host plants. Current evidence highlighted that cell wall loosening and modification are critical during the development of the haustorium in the host tissue. This is made possible by the application of physical pressures by the developing haustorium and cell wall degradation using enzymes (xyloglucan endotransglycosylases, glucanase, expansins, etc.) produced by the mistletoe. Host plants defend against mistletoe infection mechanically by producing spines, lignin, suberin, etc., which discourages dispersers, and chemically defend by killing the infector or inhibiting the establishment of the haustorium using their secondary metabolites such as terpenes, phenolics, and N-containing compounds. Although the host plants' response to mistletoe attack resembles the response to other biotic stresses, unlike short-term stressors, the effect of mistletoe attack is long-term and depends on the parasite load. Infection by mistletoe leads to water and nutrient stress of the host plant and deteriorates its healthy establishment and survival. Conclusion Mistletoes are heterogeneous group in the order Santalales which have versatile mechanisms for pollination, seed dispersal and nutrient acquisition from host plants. Infection by mistletoes triggers host plant responses, varying from mechanical to chemical mechanisms which are analogous to herbivory defences, and negatively impacts host plant growth and reproduction.