T-DNA insertion mutagenesis in Penicillium brocae results in identification of an enolase gene mutant impaired in secretion of organic acids and phosphate solubilization.

Penicillium brocae strain P6 is a phosphate-solubilizing fungus isolated from farmland in Guangdong Province, China. To gain better insights into the phosphate solubilization mechanisms of strain P6, a T-DNA insertion population containing approximately 4500 transformants was generated by Agrobacterium tumefaciens-mediated transformation. The transformation procedure was optimized by using a Hybond N membrane for co-cultivation of A. tumefaciens and P. brocae. A mutant impaired in phosphate solubilization (named MT27) was obtained from the T-DNA insertion population. Thermal asymmetric interlaced PCR was then used to identify the nucleotide sequences flanking the T-DNA insertion site. The T-DNA in MT27 was inserted into the fourth exon of an enolase gene, which shows 90.8 % nucleotide identity with enolase mRNA from Aspergillus neoniger. Amino acid sequence homology analysis indicated that the enolase is well conserved among filamentous fungi and Saccharomyces cerevisiae. Complementation tests with the MT27 mutant confirmed that the enolase gene is involved in phosphate solubilization. Analysis of organic acids in culture supernatants indicated reduced levels of oxalic acid and lactic acid for the MT27 mutant compared to the parent strain P6 or the complementation strain. In conclusion, we suggest that the identified enolase gene of P. brocae is involved in production of specific organic acids, which, when secreted, act as phosphate solubilizing agents.

First report of Meloidogyne arenaria on roots of Grona triflora in Guangdong Province, China.

Grona triflora (Desmodium triflorum), a perennial herbaceous legume, is widely distributed in southern China. G. triflora has antipyretic, antiseptic and expectorant properties and can therefore be used as a phytomedicine (Ghosal et al. 1973). In July 2020, roots of G. triflora were investigated for nodules and rhizobia collection at the Shibaluohan Mountain Forest Park of Guangzhou. Root galls induced by a root-knot nematode were observed on 90% of the G. triflora samples (in a 200 m2 plot) and the infested plants had yellow, small and withered leaves compared with the healthy ones. The galls number on a G. triflora root ranged from 43 to 92 and the population densities of second stage juveniles (J2s) ranged from 573 to 894 per 100 cm3 soil surrounding the plant. The female perineal patterns showed a low dorsal arch, with lateral field marked by forked and broken striae, no punctate markings between the anus and tail terminus, which matched with the description of Meloidogyne arenaria (Hartman and Sasser 1985). The J2s had the following morphometric characters (n = 15): body length = 501.05 ± 23.71 µm; body width = 17.14 ± 1.23 µm; DGO = 3.13 ± 0.27 µm; stylet length = 12.97 ± 1.38 µm; tail length = 58.02 ± 4.77 µm; hyaline tail terminus = 10.08 ± 0.65 µm. DNA from four female nematodes was isolated for PCR-based diagnostic analyses. A fragment between the COII and LrRNA genes of the mitochondrial DNA was amplified with primers C2F3/1108 (Powers and Harris 1993). In addition, a 28S ribosomal DNA D2/D3 region was amplified with primers MF/MR (Hu et al. 2011). The amplicons were sequenced (GenBank No. MW315989 and MW307358). Nucleotide BLAST results indicated that both sequences show 100% identity with corresponding M. arenaria sequences of isolates from various countries such as Brazil, China, Myanmar and Vietnam (e.g., MK033428, JQ446377, KY293688 and MK026624). For further confirmation, sequence characterized amplified region (SCAR) PCR was employed using the M. arenaria specific primers Far/Rar (Zijlstra et al. 2000). The amplicon was also sequenced (GenBank No. MW315990). The Nucleotide BLAST results showed >99% identity with M. arenaria isolates from Indonesia and Argentina (KP234264, KP253748 and MK015624). Greenhouse tests were conducted to analyze the capacity of M. arenaria to induce galls on G. triflora roots. The G. triflora seeds were collected from the sampling plot and germinated on 0.8% (W/V) agar plates. Then the seedlings were planted in 14 cm deep and 15 cm diam pots filled with sterilized soil from sampling plot. Every seedling was inoculated with 2,000 J2s (n = 15) and plants without J2s were used as a control. Two months later, galls were observed for inoculated roots while no galls were formed on roots of control plants. An average of 13,300 J2s and eggs of M. arenaria (reproduction factor = 6.65) were recovered from the root. Stanton and Rizo (1988) found that G. triflora was susceptible to M. javanica in Australia, and Ogbuji (1978) reported that a population of M. incognita reproduced on roots of G. triflora in Nigeria after artificial inoculation. To our knowledge, this is the first report on G. triflora parasitized by M. arenaria in Guangdong province. M. arenaria has potential to infest local, economically important plants like citrus, pomelo, sugarcane, maize and peanut. As G. triflora is widely distributed in southern China, there is the risk of spreading M. arenaria into agricultural and horticultural systems, that will cause yield loss and economic impacts.

Biochemical properties and in planta effects of NopM, a rhizobial E3 ubiquitin ligase.

Nodulation outer protein M (NopM) is an IpaH family type three (T3) effector secreted by the nitrogen-fixing nodule bacterium Sinorhizobium sp. strain NGR234. Previous work indicated that NopM is an E3 ubiquitin ligase required for an optimal symbiosis between NGR234 and the host legume Lablab purpureus Here, we continued to analyze the function of NopM. Recombinant NopM was biochemically characterized using an in vitro ubiquitination system with Arabidopsis thaliana proteins. In this assay, NopM forms unanchored polyubiquitin chains and possesses auto-ubiquitination activity. In a NopM variant lacking any lysine residues, auto-ubiquitination was not completely abolished, indicating noncanonical auto-ubiquitination of the protein. In addition, we could show intermolecular ubiquitin transfer from NopM to C338A (enzymatically inactive NopM form) in vitro Bimolecular fluorescence complementation analysis provided clues about NopM-NopM interactions at plasma membranes in planta NopM, but not C338A, expressed in tobacco cells induced cell death, suggesting that E3 ubiquitin ligase activity of NopM induced effector-triggered immunity responses. Likewise, expression of NopM in Lotus japonicus caused reduced nodule formation, whereas expression of C338A showed no obvious effects on symbiosis. Further experiments indicated that serine residue 26 of NopM is phosphorylated in planta and that NopM can be phosphorylated in vitro by salicylic acid-induced protein kinase (NtSIPK), a mitogen-activated protein kinase (MAPK) of tobacco. Hence, NopM is a phosphorylated T3 effector that can interact with itself, with ubiquitin, and with MAPKs.