Chronic stress causes a variety of psychiatric disorders such as anxiety and depression, but its mechanism is not well understood. Tripartite motif-containing protein 32 (TRIM32) was strongly associated with autism spectrum disorder, attention deficit hyperactivity disorder, anxiety and obsessive compulsive disorder based on a study of copy number variation, and deletion of TRIM32 increased neural proliferation and reduced apoptosis. Here, we propose that TRIM32 is involved in chronic stress-induced affective behaviors. Using a chronic unpredictable mild stress mouse depression model, we studied expression of TRIM32 in brain tissue samples and observed behavioral changes in Trim32 knockout mice. The results showed that TRIM32 protein but not its mRNA was significantly reduced in hippocampus in a time-dependent manner within 8 weeks of chronic stress. These stress-induced affective behaviors and reduction of TRIM32 protein expression were significantly reversed by antidepressant fluoxetine treatment. In addition, Trim32 knockout mice showed reduced anxiety and depressive behaviors and hyperactivities compared with Trim32 wild-type mice under normal and mild stress conditions. We conclude that TRIM32 plays important roles in regulation of hyperactivities and positively regulates the development of anxiety and depression disorders induced by chronic stress.
Fusarium oxysporum KB-3 had been reported as a mycorrhizal fungus of Bletilla striata, which can promote the seed germination and vegetative growth. Endohyphal bacteria were demonstrated in the hyphae of the KB-3 by 16S rDNA PCR amplification and SYTO-9 fluorescent nucleic acid staining. A strain Klebsiella aerogenes KE-1 was isolated and identified based on the multilocus sequence analysis. The endohyphal bacterium was successfully removed from the wild strain KB-3 (KB-3−), and GFP-labeled KE-1 was also transferred to the cured strain KB-3− (KB-3+). The production of indole-3-acetic acid (IAA) in the culturing broths of strains of KE-1, KB-3, KB-3−, and KB-3+ was examined by HPLC. Their IAA productions were estimated using Salkowski colorimetric technique. The highest concentrations of IAA were 76.9 (at 48 h after inoculation), 31.4, 9.6, and 19.4 μg/ml (at 60 h after inoculation), respectively. Similarly, the three fungal cultural broths exhibited plant promoting abilities on the tomato root and stem growth. The results indicated that the ability of mycorrhizal Fusarium strain KB-3 to promote plant growth was enhanced because its endohyphal bacterium, Klebsiella aerogenes KE-1, produced a certain amount of IAA.
<abstract> <p>Beneficial endophytic bacteria influence their host plant to grow and resist pathogens. Despite the advantages of endophytic bacteria to their host, their application in agriculture has been low. Furthermore, many plant growers improperly use synthetic chemicals due to having no or little knowledge of the role of endophytic bacteria in plant growth, the prevention and control of pathogens and poor access to endobacterial bioproducts. These synthetic chemicals have caused soil infertility, environmental contamination, disruption to ecological cycles and the emergence of resistant pests and pathogens. There is more that needs to be done to explore alternative ways of achieving sustainable plant production while maintaining environmental health. In recent years, the use of beneficial endophytic bacteria has been noted to be a promising tool in promoting plant growth and the biocontrol of pathogens. Therefore, this review discusses the roles of endophytic bacteria in plant growth and the biocontrol of plant pathogens. Several mechanisms that endophytic bacteria use to alleviate plant biotic and abiotic stresses by helping their host plants acquire nutrients, enhance plant growth and development and suppress pathogens are explained. The review also indicates that there is a gap between research and general field applications of endophytic bacteria and suggests a need for collaborative efforts between growers at all levels. Furthermore, the presence of scientific and regulatory frameworks that promote advanced biotechnological tools and bioinoculants represents major opportunities in the applications of endophytic bacteria. The review provides a basis for future research in areas related to understanding the interactions between plants and beneficial endophytic microorganisms, especially bacteria.</p> </abstract>
Cymbidium sinense (Jackson ex Andr.) Willd is a perennial terrestrial plant in the orchid family mainly distributed in China, Japan, India and Southeast Asia that occupies a strong position in the flower market due to its bright green leaves and fragrant flowers (Zhang et al. 2013). Cymbidium sinense is not only valued by people for its ornamental and economic value, but its roots have antiasthmatic medicinal properties (Ke et al. 2004). In August 2020, about 15% stem rot on two-year old C. sinense with varying severity was observed in five nursery gardens located in Enshi city (N 30° 16′, E 109° 29′), Hubei province, China. Typical symptoms of C. sinense included roots and inner part of the pseudobulbs changing from white to brown and rotting. Leaves became brown and withered from bottom to top, and there was an obvious blight yellow halo at the junction of diseased and healthy tissue, which eventually caused the whole plant to wilt and die (Fig. 1d). To isolate the pathogen, a total of 15 leaf tissues from the disease-health junction (3 × 3 mm) from 5 individual plants (3 leaves/plant) with symptoms were surface sterilized with 75% ethanol for 30 s and 2% sodium hypochlorite (NaOCl) for 3 min. The sterilized tissue was rinsed three times with sterilized water, and then placed on potato dextrose agar (PDA) for incubation at 28°C in the dark for 5 days. Isolated colonies were subcultured by a hyphal tip protocol. Thirteen fungal isolates were obtained. Through preliminary pathogenicity tests, we found that ten isolates induced leaf blight. These ten isolates with pathogenicity showed similar morphological characteristics, with initial white-flocculent aerial mycelium that secreted a lavender pigment and produced colonies with an irregular edge after 3 days on PDA. The ten strains were cultured on PDA plates at 28℃ for 5 and 15 days to observe colony and conidial characteristics. The ten strains were identified as Fusarium based on morphological characteristics (Leslie and Summerell 2006). Strain ML0303 was selected for further identification. Macroconidia were falciform, hyaline, slightly pointed at both ends with two to four septa, 24.0 ± 5.6 µm × 4.7 ± 0.8 µm (n = 50). Microconidia were hyaline, oval, globose, with zero to one septum, 5.5 ± 1.3 µm × 2.2 ± 0.5 µm (n = 50) (Fig. 1c). Total genomic DNA of strain ML0303 was extracted with a CTAB protocol (Stenglein and Balatti 2006). The translation elongation factor (EF-1α), RNA polymerase II second largest subunit (RPB2) and β-tubulin (Tub2) genes were amplified respectively using primer pairs EF1/EF2, RPB2-5F2/RPB2-7cR and T1/T22 respectively (O’Donnell. et al. 2010, O’Donnell. et al. 1997). The EF-1α, RPB2 and Tub2 (accession numbers-MW719874, OL614838, OL689398, respectively) gene sequences were submitted to GenBank. EF-1α, RPB2 and Tub2 sequences of ML0303 showed 99.5% - 100% identity respectively with Fusarium oxysporum in the Genbank and FUSARIUM-ID databases. The multilocus sequence data was used to infer a phylogenetic tree via a Neighbor-joining (NJ), Maximum-likelihood (ML) and Maximum-Parsimony(MP) together with reference sequences from GenBank. The topology of the three trees was similar; only the NJ tree is presented here. Strain ML0303 and F. oxysporum formed a clade supported with high values (NJ/ML/MP: 96,95,97). The results indicated that the fungus was F. oxysporum based on the phylogenetic analysis and BLASTn queries. For pathogenicity tests, conidia of strain ML0303 were collected by rinsing PDA plates. Two-year-old C. sinense grown in plastic pots filled with sterilized autoclaved sandy loam soil were used for the tests. Three pots (two plants/pot) were included in each treatment. Spore suspensions (106spores/ml) of strain ML0303 were used to irrigate the stem-zone of the plants, and sterile water was used as control. The two treatments were placed in a greenhouse and incubated at 28±2℃ with a 14-hour light/10-hour dark cycle. The experiment was repeated twice. After three weeks, stem rot symptoms were observed on C. sinense inoculated with ML0303, that were the as same as observed in the nursery (Fig. 1e-h). No symptoms were observed on the negative control. Fusarium oxysporum was re-isolated from the infected plants to fulfill Koch’s postulates. Partial EF-1α and RPB2 gene sequences were used for molecular identification. Members of the FOSC are notorious for causing many diseases, which includes stem rot of Sulcorebutia heliosa and root rot of Torreya grandis (Garibaldi et al. 2020; Zhang et al. 2016). To our knowledge, this is the first report of stem rot by F. oxysporum on C. sinense in China. The finding of this pathogen provides a clear target for stem rot control.
The soil inhabits many microbes, including plant parasitic nematodes. Plant parasitic nematodes are reported to cause substantial damage to crops which results in yield and economic losses. Chemical control is the most widely used method to control plant parasitic nematodes. However, the consequences of synthetic chemicals are detrimental to human health, animals, and the environment and face so many strict regulatory measures. Synthetic chemicals are also not reliable with their inability to provide long-term protection. Many studies have shown that the use of beneficial fungi and bacteria has the potential to prevent and suppress plant parasitic nematodes while keeping the environment safe. Several experiments have demonstrated that bioproducts of microbial origin are cheap, safe, and provide long-lasting biocontrol effects against pathogens both in vitro and field conditions. Therefore, this review aims to discuss mechanisms that beneficial microbes and their products use to successfully suppress plant parasitic nematodes. The review also explains the importance of using commercial bionematicides in the sustainable management of plant parasitic nematodes. The existing challenges that are limiting the full application of beneficial microbes, and what needs to be done to fully utilize biocontrol agents in the management of plant parasitic nematodes have also been discussed. To the best of our knowledge, this review has come at the right time to give researchers and plant growers more options when several synthetic chemical nematicides are being banned by regulatory authorities due to their hazardous effects.
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