Endophytes Alleviate Drought-Derived Oxidative Damage in Achnatherum inebrians Plants Through Increasing Antioxidants and Regulating Host Stress Responses.

Endophytes generally increase antioxidant contents of plants subjected to environmental stresses. However, the mechanisms by which endophytes alter the accumulation of antioxidants in plant tissues are not entirely clear. We hypothesized that, in stress situations, endophytes would simultaneously reduce oxidative damage and increase antioxidant contents of plants and that the accumulation of antioxidants would be a consequence of the endophyte ability to regulate the expression of plant antioxidant genes. We investigated the effects of the fungal endophyte Epichloë gansuensis (C.J. Li & Nan) on oxidative damage, antioxidant contents, and expression of representative genes associated with antioxidant pathways in Achnatherum inebrians (Hance) Keng plants subjected to low (15%) and high (60%) soil moisture conditions. Gene expression levels were measured using RNA-seq. As expected, the endophyte reduced the oxidative damage by 17.55% and increased the antioxidant contents by 53.14% (on average) in plants subjected to low soil moisture. In line with the accumulation of antioxidants in plant tissues, the endophyte increased the expression of most plant genes associated with the biosynthesis of antioxidants (e.g., MIOX, crtB, gpx) while it reduced the expression of plant genes related to the metabolization of antioxidants (e.g., GST, PRODH, ALDH). Our findings suggest that endophyte ability of increasing antioxidant contents in plants may reduce the oxidative damage caused by stresses and that the fungal regulation of plant antioxidants would partly explain the accumulation of these compounds in plant tissues.

First Report of Leaf Spot Caused by Alternaria brassicae on Avena sativa in China.

Oat (Avena sativa) is an annual gramineous crop, which contains a source of soluble dietary fiber, ß-glucan, unsaturated fatty acids, vitamins, minerals, phenolic acids and avenanthramides. It widely cultivated in cool and semi-arid areas in northern China (Li et al, 2017). In July 2018, a severe leaf spot infection was observed in the Forage Germplasm Nursery (31°17'22″N, 103°40'15″E, 2885 m elevation) in Tianzhu County, Wuwei City of Gansu Province in China. Disease incidence (total number of diseased leaves / total number of surveyed leaves X 100%) was 93% over 300 m2 planting area. Symptoms initially appeared as small circular to irregular, gray-green, water-soaked spots on the leaves in the middle or along the margin of leaves, that enlarged and coalesced. The center of the leaf spots turned brown to reddish-brown. Infected tissues from symptomatic leaves were cut into small pieces (5×5 mm), surface sterilized with 70% ethanol for 60 s, soaked in 5% commercial bleach (~0.275% NaClO) for 5 min (Xue et al, 2018), rinsed five times with distilled water, plated on potato dextrose agar (PDA) medium, and incubated for 3 days in the dark at 25°C (Zhang, 2003; Blagojevic et al, 2020; Humpherson et al, 1989). Hyphae emerging from the tissue were subcultured on fresh PDA medium for purification. All colonies were light brown with intensive sporulation in rings that was grayish white, and later became grayish brown. The back of the colony was dark brown. Conidiophores were light brown, unbranched, grew vertically on hyphae, and each conidiophore produced 3 to 7 conidia (mostly 6). Conidia were light brown, septate, straight to slightly curved, single or in chains, oval or obclavate, measured 17 to 32 µm wide and 63 to 106 µm long with the conical beak cell, 7 to 12 transverse septa, 0 to 5 longitudinal septa. These morphological characteristics were similar to the descriptions of Alternaria spp. (Simmons, 2008). A single isolate, YMZZ1, was selected for molecular identification. The ITS region of rDNA, partial GAPDH and Tef1-α gene sequences were amplified by PCR with the primer pairs of ITS1/ITS4, gpd1/gpd2 and EF1-728F/EF1-986R, respectively (Woudenberg et al, 2013). Sequences were deposited in GeneBank under accessions MN446739 (ITS), MN481462 (GAPDH), and MN464104 (Tef1-α). A nucleotide BLAST search revealed ITS, GAPDH and Tef1-α sequences to be 99% similar to accessions numbers MN856410 (565/573 bp), MK026431 (575/575 bp), and MH754531 (211/211 bp), respectively) of A. brassicae. Neighbor-joining (NJ) and Maximum Likelihood (ML) phylogenetic analysis were conducted based on ITS, GAPDH and TEF-1α sequences using MEGA7.0 under Kimura 2-parameter model. The isolate YMZZ1 clustered with a representative strain A. brassicae LGBA22 with 100% bootstrap support. To test its pathogenicity, six healthy 3 week old plants were spray-inoculated with a suspension of 3×105 conidia/mL of YMZZ1. The same number of plants were sprayed with sterilized water as control. All plants were covered with transparent plastic bags for 48 h to maintain high relative humidity and incubated in a 25°C growth chamber (16/8 h light/dark) for observation. Ten days after inoculation, leaf spot symptoms were observed on leaves similar to those previously observed in nursery; no symptoms were observed on the control. The pathogenicity test was repeated twice under the same conditions and A. brassicae was re-isolated from inoculated plants each time fulfilling Koch's postulates. A. brassicae has not been previously reported as a pathogen of A. sativa in the world, but has been mentioned as a pathogen of horse radish (Armoracia rusticana) in Serbia (Blagojevic et al, 2015). To our knowledge, this is the first report of leaf spot caused by A. brassicae on A. sativa in China. This study stresses an urgent need to identify appropriate management strategies of A. brassicae that help in preventing losses in quality and yield of oats in northern China.