First Report of Stem Wilt and Root Rot of Schlumbergera truncata Caused by Fusarium oxysporum f. sp. Opuntiarum in Southern Italy

First Report of Fusarium oxysporum Causing Stem Rot on Mammillaria humboldtii in China

Mammillaria humboldtii found in Mexico is a short-globose ornamental cactus species of the Cactaceae family, which has gained increasing popularity in China. It is characterized by tuberculate stems, dimorphic areoles, small pink flowers and pitted seed cell walls. The populations of wild M. humboldtii are critically endangered and are now of international conservation concern. In July 2021, stem rot symptoms were observed on M. humboldtii in a commercial greenhouse located in Zhangzhou (117°39'44.0064″E, 24°28'3.7236″N), Fujian Province (southern China). The typical symptoms were water-soaking, rotting and wilting on the stem, eventually leading to necrosis of the plants within 20 to 30 days. The vascular system of infected stems and roots showed a reddish-brown discolouration. The disease affected approximately 10% of 1000 plants. Fungi were isolated from the diseased stems of 26 samples, which were chopped into small pieces (5 × 5 mm), surface-sterilized with 75% ethanol for 40 s, and placed onto potato dextrose agar (PDA). After seven days of dark culture at 28°C, morphologically similar fungal isolates with whitish aerial mycelium and purple pigment were observed. On carnation leaf agar (CLA), isolates produced sickle and slightly curved macroconidia with three to four septa, measuring 12.8 to 27.9 × 1.9 to 3.8 μm (n = 15), and unicellular, ovoid to elliptical microconidia measuring 3.8 to 7.7 × 1.4 to 2.5 μm (n = 30). Smooth walled chlamydospores were terminal or intercalary, single or in pairs, measuring 9.2 to 13.1 μm (n = 15) in diameter. For molecular identification, the internal transcribed spacer (ITS) region of rDNA (Schoch et al. 2012), translation elongation factor-1α (EF1-α) (Maryani et al. 2019) and gene coding endopolygalacturonase 1 (PG1) (Hirano et al. 2006) of the representative isolate FJMH7 were amplified, purified and sequenced. BLASTn analysis of the ITS, EF1-α and pg1 sequences (GenBank accession numbers: ON832660, ON843495 and ON843496) showed 100%, 99.70% and 98.96% identity with F. oxysporum (GenBank accession numbers: KX611626, OM801797 and KF437345), respectively. Phylogenetic analysis based on the the concatenated ITS and EF1-α sequences and pg1 genes placed isolate FJMH7 with F. oxysporum reference strains in the phylogenetic trees. Based on morphological identification and sequence analysis, this isolate was identified as F. oxysporum. For the pathogenicity assay, six 6-month-old healthy plants of Mammillaria humboldtii were inoculated by dipping roots in a conidial suspension (106 conidia/mL) of isolate FJMH7 cultured in Bilai's medium for three days. Six noninoculated plants treated with Bilai's medium served as a control. Plants were transplanted into pots filled with sterilized soils and placed in a glasshouse at 25°C. After 15 days, all the inoculated plants exhibited rot symptoms on stems, which were similar to those observed in the commercial greenhouses. All inoculated plants were dead 30 days after inoculation. Control plants did not show any symptoms. F. oxysporum was reisolated and confirmed based on morphology and sequencing. No fungi were reisolated from control plants. To fulfil Koch's postulates, the pathogenicity assay was repeated twice with the same results. To date, F. oxysporum isolates have been reported on golden barrel cactus (Echinocactus grusonii) (Polizzi et al. 2004), night-blooming cereus (Hylocereus undatus) (Wright et al. 2007), apple cactus (Cereus peruvianus monstruosus) (Garibaldi et al. 2011), Schlumbergera truncate (Lops et al. 2013), Astrophytum ornatum (Quezada-Salinas et al. 2017) and Nopalea cochenillifera (Santiago et al. 2018). To our knowledge, this is the first report of F. oxysporum on M. humboldtii in China, indicating that this pathogen could cause wilt and rot disease on different cactus hosts.

Understanding Root Rot Disease in Agricultural Crops

Root rot diseases remain a major global threat to the productivity of agricultural crops. They are usually caused by more than one type of pathogen and are thus often referred to as a root rot complex. Fungal and oomycete species are the predominant participants in the complex, while bacteria and viruses are also known to cause root rot. Incorporating genetic resistance in cultivated crops is considered the most efficient and sustainable solution to counter root rot, however, resistance is often quantitative in nature. Several genetics studies in various crops have identified the quantitative trait loci associated with resistance. With access to whole genome sequences, the identity of the genes within the reported loci is becoming available. Several of the identified genes have been implicated in pathogen responses. However, it is becoming apparent that at the molecular level, each pathogen engages a unique set of proteins to either infest the host successfully or be defeated or contained in attempting so. In this review, a comprehensive summary of the genes and the potential mechanisms underlying resistance or susceptibility against the most investigated root rots of important agricultural crops is presented.

Epiphytic fungi induced pathogen resistance of invasive plant Ipomoea cairica against Colletotrichum gloeosporioides

Background

Ipomoea cairica (L.) Sweet is a destructive invasive weed in South China but rarely infected with pathogens in nature. Its pathogen resistance mechanism is largely unknown at present. Some non-pathogenic isolates of Fusarium oxysporum and Fusarium fujikuroi are prevalent on many plant species and function as pathogen resistance inducers of host plants. The objective of the present research is to investigate whether the symbiosis between the both fungi and I. cairica is present, and thereby induces pathogen resistance of I. cairica.

Methods

Through field investigation, we explored the occurrence rates of F. oxysporum and F. fujikuroi on leaf surfaces of I. cairica plants in natural habitats and compared their abundance between healthy leaves and leaves infected with Colletotrichum gloeosporioides, a natural pathogen. With artificial inoculation, we assessed their pathogenicity to I. cairica and studied their contribution of pathogen resistance to I. cairica against C. gloeosporioides.

Results

We found that F. oxysporum and F. fujikuroi were widely epiphytic on healthy leaf surfaces of I. cairica in sunny non-saline, shady non-saline and sunny saline habitats. Their occurrence rates reached up to 100%. Moreover, we found that the abundance of F. oxysporum and F. fujikuroi on leaves infected with C. gloeosporioides were significantly lower than that of healthy leaves. With artificial inoculation, we empirically confirmed that F. oxysporum and F. fujikuroi were non-pathogenic to I. cairica. It was interesting that colonization by F. fujikuroi, F. oxysporum alone and a mixture of both fungi resulted in a reduction of C. gloeosporioides infection to I. cairica accompanied by lower lesion area to leaf surface area ratio, increased hydrogen peroxide (H₂O₂) concentration and salicylic acid (SA) level relative to the control. However, NPR1 expression, chitinase and β-1,3-glucanase activities as well as stem length and biomass of I. cairica plant only could be significantly improved by F. oxysporum and a mixture of both fungi but not by F. fujikuroi. In addition, as compared to colonization by F. oxysporum and a mixture of both fungi, F. fujikuroi induced significantly higher jasmonic acid (JA) level but significantly lower β-1,3-glucanase activity in leaves of I. cairica plants. Thus, our findings indicated the symbiosis of epiphytic fungiF. fujikuroi and F. oxysporum induced systemic resistance of I. cairica against C. gloeosporioides. F. oxysporum played a dominant role in inducing pathogen resistance of I. cairica. Its presence alleviated the antagonism of the JA signaling on SA-dependent β-1,3-glucanase activity and enabled I. cairica plants to maintain relatively higher level of resistance against C. gloeosporioides.