RESUMEN
Magnolia denudata (Lilytree or Yulan magnolia) is an important ornamental species of the genus Magnolia. It has considerable economical value because of its beautiful fragrant flowers and excellent tree structure (Wang et al. 2010). In Beijing, nurseries cultivate M. denudata as an ornamental plant and traditional medicine. In May 2020, patches of root rotted plants were observed in a field in Beijing, China, with an estimated incidence of approximately 31%. Early symptoms comprised leaves melanocratic shrunken, and the vascular tissue of roots turned brown. Progressively, the roots rotted and the whole plant died (Fig. 1 a-d). Infected roots tissue was surface disinfested and plated on potato dextrose agar (PDA) medium at 25±2 °C and incubated in the dark for 7 days. Pure cultures were obtained by hyphal tip excision (strain MFR1215.4). Fungal colonies were entire margins, and the aerial mycelium was copious, early white, and gradually developed into cream white. Colonies developed to 45.1 mm in 4 days at 25±2 °C on PDA media. On Spezieller Nährstoffarmer Agar (SNA) medium at 25±2 °C for 10 days. The morphological characteristics including macroconidia, microconidia, and chlamydospores were shown in Fig.1 (i-p). These morphological characteristics of the isolate corresponded to the description given for Fusarium solani sensu lato (Nelson et al. 1983, Summerell, 2003). Molecular identification was confirmed via amplification of translation elongation factor 1α (EF-1α), RNA polymerase I beta subunit gene (RPB1), and RNA polymerase II beta subunit gene (RPB2) regions using EF1/EF2, RPB1-Fa/G2R, RPB2-5f2/7cR, and RPB2-7cF/11aR primers (O'Donnell, 2010). Sequences were registered in GenBank. In the Fusarium-ID database, the EF-1α, RPB1, and RPB2 sequences showed 100% (677/677 bp), 99.8% (1568/1571 bp), and 100% (1457/1457 bp) identity with the F. solani species complex (FSSC). The same species-level identification was also found using Fusarium MLST. A best maximum likelihood tree was constructed using PhyloSuite v1.2.2 (Zhang et al. 2020), and the sequences of the MFR1215.4 isolation showed the same homology with FSSC 6. Pathogenicity tests were conducted on healthy one-year-old M. denudata potted seedlings. 200 ml spore suspension (1×106 spores/ml) was poured over the roots of twenty seedlings, and sterile distilled water was irrigated into twenty seedlings as controls in a greenhouse with 25/15°C day/night temperature and 80% relative humidity. The experiment was repeated three times. All inoculated seedlings showed similar symptoms to those in the field after 65 days, whereas the controls remained symptomless. The reisolating pathogens from symptomatic tissues were identical to the original isolates by morphology and EF-1α sequence identification. Based on morphological, molecular, and pathogenic characterization, the isolated pathogen was identified as FSSC 6. Fusarium species have been recorded in various places of the world and are known to be harmful to numerous plants (Trabelsi et al. 2017). It has been reported that FSSC has infected soybeans (Coleman, 2016, Nelson et al. 1989), oil palm (Hafizi et al. 2013), tobacco (Yang et al. 2020), resulting in sudden death syndrome, crown disease, and root rot. To our knowledge, this is the first report of FSSC-induced root rot in M. denudata in China. This research may contribute to the development of epidemiology and management strategies for root rot caused by FSSC on M. denudata.
RESUMEN
Magnolia wufengensis belongs to the Magnoliaceae family. Its variation-rich flowers (tepal number from 9 to 46, tepal color from pink to bright red) and excellent wood characteristics (strong, straight, texture) have important ornamental and economic value (Duan et al. 2019; Luyi et al. 2006). M. wufengensis is popularly cultivated in parks, courtyards, mountains, and along roadsides. In May 2020, leaf spot symptoms were observed on over 85% of M. wufengensis in Yuyangguan Township, Wufeng County, Hubei Province (110.60°E, 30.21°N). The damaged area was over 18.7 hectares. Early symptoms began as small brown spots with a light-yellow halo. Gradual lesions expanded, and the center was withered, gray, and necrotic with a dark brown border. Eventually, several spots combined with larger irregular lesions, turning the leaves yellow and causing them to fall off. The border of lesions and healthy tissues were cut into small pieces (5×5 mm), and surface sterilized with 1% sodium hypochlorite solution for three minutes, rinsed three times with sterile water, and plated on potato dextrose agar (PDA) medium at 25±2 °C with a 12h photoperiod under fluorescent lighting. Pure isolates (MCS1228.1, MCS1228.4, MCS1228.9) were gray to pale grayish, and their average growth rate was 10.5±1.23 mm/day. Conidiophores were hyaline, aseptate, branched. Conidia were hyaline, aseptate, cylindrical, and 14.00 to 25.17 × 4.74 to 6.56 µm in size (average 17.48 × 5.58 µm) (n=50). Appressoria were brown and showed multivariate shape. The morphological characteristics of the isolates corresponded to the description given for Colletotrichum fructicola (Liu et al. 2015). Molecular identification was accomplished through amplification of the internal transcribed spacer (IST), actin (ACT), calmodulin (CAL), chitin synthase (CHS-1) glyceraldehyde-3-phosphate dehydrogenase (GAPDH), and beta-tubulin (TUB2) genes (Fu et al. 2018). The ITS (OL800580.1, OL800581.1, OL800582.1), ACT (GenBank accession No. OL873155- OL873157), CAL (GenBank accession No. OL873158- OL873160), CHS-1 (GenBank accession No. OL873161- OL873163), GAPDH (GenBank accession No. OL873164- OL873166) and TUB2 (GenBank accession No. OL873167- OL873169) sequences were deposited in GenBank. A Bayesian inference phylogenetic tree based on multilocus sequences was constructed, and the sequences of the 3 isolations showed the same homology with C. fructicola (Fu et al. 2018). To fulfill Koch's postulates, 30 potted seedlings were inoculated with 1×10^6 conidia/ml suspension of each isolate by spraying the leaves, and 30 potted seedlings were sprayed with sterile distilled water as control. Inoculated and control plants were kept in a greenhouse with 25/15°C (day/night) temperature and 80% relative humidity. In addition, 30 healthy detached leaves free of pests and diseases were washed three times with sterile distilled water, air-dried, and artificially inoculated using a 6 mm (diameter) PDA medium (5 days incubation) with mycelium. 30 leaves were inoculated with sterile PDA medium as control. All leaves were sprayed with sterile water every 24 hours, covered with plastic wrap, and incubated at 25±2 °C, 100% humidity. The experiment was repeated three times. Similar symptoms to those found initially were both observed on all the inoculated potted seedlings and detached leaves after 14 days and 5 days post inoculation (dpi), respectively. Whereas the controls remained symptomless. The reisolated pathogens from symptomatic tissues were identical to the original isolates. In this study, isolated fungi associated with M. wufengensis leaf spot were identified as C. fructicola based on morphological and multiloci phylogenetic analyses, and Koch's postulates. Colletotrichum species are important plant pathogens and cause diseases in a wide variety of woody and herbaceous plants (Cannon et al. 2012). C. fructicola has been identified as a responsible pathogen for apple (Casanova et al. 2016), Fatsia japonica (Shi et al. 2017), and Rubus corchorifolius (Wu et al. 2021) leaf spot. To our knowledge, this is the first report of C. fructicola causing leaf spot in M. wufengensis in China. This research may contribute to the development of management strategies for this disease.