Search citation statements
Paper Sections
Citation Types
Year Published
Publication Types
Relationship
Authors
Journals
The infection processes of ascospores and pycnidiospores of Leptosphaeria maculans were studied on cotyledons of six cultivars of spring-type Brassica napus: one with resistance controlled by a single dominant gene (cv. Surpass 400), three with polygenic resistance (cvs. Dunkeld, Grouse, and Outback), and two susceptible cultivars (Westar and Q2). On all cultivars, ascospore germination, penetration, and development of symptoms on cotyledons were much earlier than that with pycnidiospores. At 2 h after inoculation ascospores began to germinate, by 4 h about 50% had germinated, and by 6-8 h 85%-90% had germinated. In contrast, pycnidiospores began to germinate 1 day after inoculation (dai) and reached only 50% germination by 3 dai. Ascospores began germinating from terminal cells and then later from the interstitial cells. Pycnidiospores germinated predominantly from one end and sometimes from both ends. Germ tubes from ascospores penetrated stomata as early as 4 h after inoculation, whereas those from pycnidiospores penetrated at 2 dai. Symptom development with ascospores was 2 days earlier than that with pycnidiospores. Symptoms on Surpass 400 were evident as early as 3-5 dai with ascospores and 5-7 dai with pycnidiospores. However, on other cultivars, symptoms were not evident until 10 dai with ascospores and 12 dai with pycnidiospores. This report is the first on differences in the infection processes by the two spore types. Ascospore and pycnidiospore attachment, germination, and penetration did not differ between resistant and susceptible cultivars, but there were major differences after penetration. Under high humidity, 80%-90% of stomata of susceptible Westar and Q2 had aerial hyphae emerging from stomatal pores. However, fewer stomata (5%-10%) had aerial hyphae on Surpass 400 by 10 dai with ascospores and 12 dai with pycnidiospores, but even these were usually poorly developed. Host differences in spring-type B. napus in relation to production of aerial hyphae have not previously been reported. In Surpass 400, rapid necrosis of guard cells occurred within a few hours of penetration by either type of spore, and subsequently one or a few cells immediately adjacent to the penetration site died. This necrosis then spread to the cells around the penetration site to form a hypersensitive response (in the form of a small, dark lesion) to both ascospores and pycnidiospores. This is the first detailed report on interactions between spring-type B. napus and L. maculans in relation to single dominant genebased resistance. Neither the cultivars with polygenic resistance nor the susceptible cultivars had such a response.
The infection processes of ascospores and pycnidiospores of Leptosphaeria maculans were studied on cotyledons of six cultivars of spring-type Brassica napus: one with resistance controlled by a single dominant gene (cv. Surpass 400), three with polygenic resistance (cvs. Dunkeld, Grouse, and Outback), and two susceptible cultivars (Westar and Q2). On all cultivars, ascospore germination, penetration, and development of symptoms on cotyledons were much earlier than that with pycnidiospores. At 2 h after inoculation ascospores began to germinate, by 4 h about 50% had germinated, and by 6-8 h 85%-90% had germinated. In contrast, pycnidiospores began to germinate 1 day after inoculation (dai) and reached only 50% germination by 3 dai. Ascospores began germinating from terminal cells and then later from the interstitial cells. Pycnidiospores germinated predominantly from one end and sometimes from both ends. Germ tubes from ascospores penetrated stomata as early as 4 h after inoculation, whereas those from pycnidiospores penetrated at 2 dai. Symptom development with ascospores was 2 days earlier than that with pycnidiospores. Symptoms on Surpass 400 were evident as early as 3-5 dai with ascospores and 5-7 dai with pycnidiospores. However, on other cultivars, symptoms were not evident until 10 dai with ascospores and 12 dai with pycnidiospores. This report is the first on differences in the infection processes by the two spore types. Ascospore and pycnidiospore attachment, germination, and penetration did not differ between resistant and susceptible cultivars, but there were major differences after penetration. Under high humidity, 80%-90% of stomata of susceptible Westar and Q2 had aerial hyphae emerging from stomatal pores. However, fewer stomata (5%-10%) had aerial hyphae on Surpass 400 by 10 dai with ascospores and 12 dai with pycnidiospores, but even these were usually poorly developed. Host differences in spring-type B. napus in relation to production of aerial hyphae have not previously been reported. In Surpass 400, rapid necrosis of guard cells occurred within a few hours of penetration by either type of spore, and subsequently one or a few cells immediately adjacent to the penetration site died. This necrosis then spread to the cells around the penetration site to form a hypersensitive response (in the form of a small, dark lesion) to both ascospores and pycnidiospores. This is the first detailed report on interactions between spring-type B. napus and L. maculans in relation to single dominant genebased resistance. Neither the cultivars with polygenic resistance nor the susceptible cultivars had such a response.
Infection processes were examined to investigate the breach by a strain of Leptosphaeria maculans of anatomical barriers in cv. Surpass 400, a cultivar containing single dominant gene-based resistance (SDGBR). Two strains, UWA 192 and UWA P11, were used to inoculate cvs. Surpass 400 and Westar. The pre-penetration and penetration behaviour of both strains was similar in both cultivars. However, they differed significantly after penetration. When UWA P11 infected cv. Surpass 400 through stomata, guard cells rapidly died within a few hours and the surrounding mesophyll cells became necrotic, constituting a hypersensitive reaction (HR). Hyphal growth continued, albeit slowly, through the intercellular palisade mesophyll and spongy mesophyll spaces, but hyphae rarely spread beyond the HR region, and did not sporulate. Polyphenolic compounds accumulated in the area bordering the HR. However, when UWA 192 infected through stomata, symptoms were not evident until 10-12 days postinoculation (dpi) and were typically characterized by pale tan to grey circular lesions in which abundant pycnidia were produced by 14 dpi. Subsequently, hyphae extensively spread beyond the lesion border, reaching the veins and progressing down the petiole towards the stem. Where the SDGBR remained effective (i.e. against strain UWA P11) death of cells was restricted to a few palisade cells within the HR, even though hyphae were present in the lower tissue layers of the cotyledon. In contrast, where the SDGBR was not present (cv. Westar) or was overcome (cv. Surpass 400 with UWA 192), extensive death of epidermal and upper and lower palisade cells occurred throughout infected areas of the cotyledon, with subsequent abundant production of pycnidia. Polyphenolic compounds, which are also associated with resistance, did not accumulate in this instance. It was evident that the ability of the host to instigate the HR mechanism displayed by cv. Surpass 400 was lost with UWA 192 resulting in a ''normal'' susceptible response. This is the first study of the specific processes involved in the breaching of the HR in cv. Surpass 400.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.