Additive Strategy Enhancing In Situ Polymerization Uniformity for High-Voltage Sodium Metal Batteries.

In situ polymerization to prepare quasi-solid electrolyte has attracted wide attentions for its advantage in achieving intimate electrode-electrolyte contact and the high process compatibility with current liquid batteries; however, gases can be generated during polymerization process and remained in the final electrolyte, severely impairing the electrolyte uniformity and electrochemical performance. In this work, an in situ polymerized poly(vinylene carbonate)-based quasi-solid electrolyte for high-voltage sodium metal batteries (SMBs) is demonstrated, which contains a novel multifunctional additive N-methyl-N-(trimethylsilyl)trifluoroacetamide (MSTFA). MSTFA as high-efficient plasticizer diminishes residual gases in electrolyte after polymerization; the softer and homogeneous electrolyte enables much faster ionic conduction. The HF/H2 O scavenge effect of MSTFA mitigates the corrosion of free acid to cathode and interfacial passivating layers, enhancing the cycle stability under high voltage. As a result, the 4.4 V Na||Na3 V2 (PO4 )2 F3 cell employing the optimized electrolyte possesses an initial discharge capacity of 112.0 mAh g-1 and a capacity retention of 91.3% after 100 cycles at 0.5C, obviously better than those of its counterparts without MSTFA addition. This work gives a pioneering study on the gas residue phenomenon in in situ polymerized electrolytes, and introduces a novel multifunctional silane additive that effectively enhances electrochemical performance in high-voltage SMBs, showing practical application significance.

Soybean ZINC FINGER PROTEIN03 targets two SUPEROXIDE DISMUTASE1s and confers resistance to Phytophthora sojae.

Phytophthora sojae causes Phytophthora root and stem rot disease of soybean (Glycine max), leading to huge annual yield loss worldwide, but resistance to Phytophthora sojae (Rps) genes remains elusive. Soybean cultivar "Yudou 29" is resistant to P. sojae strain PsMC1, and this study aimed to clone, identify, and characterize the Rps gene in Yudou 29 (RpsYD29) and clarify its functional mechanism. We map-based cloned RpsYD29 (ZINC FINGER PROTEIN03, GmZFP03) using the families of a cross between Yudou 29 and a P. sojae-susceptible soybean cultivar "Jikedou 2". P. sojae resistance of GmZFP03 was functionally validated by stable soybean genetic transformation and allele-phenotype association analysis. GmZFP03 was identified as a C2H2-type zinc finger protein transcription factor, showing 4 amino acid residue polymorphisms (V79F, G122-, G123-, and D125V) and remarkably different expression patterns between resistant and susceptible soybeans. Notably boosted activity and gene expression of superoxide dismutase (SOD) in resistant-type GmZFP03-expressed transgenic soybean, substantial enhancement of P. sojae resistance of wild-type soybean by exogenous SOD treatment, and GmZFP03 binding to and activation of 2 SOD1 (Glyma.03g242900 and Glyma.19g240400) promoters demonstrated the involvement of SOD1s in GmZFP03-mediated resistance to P. sojae strain PsMC1. Thus, this study cloned the soybean P. sojae-resistant GmZFP03, the product of which specifically targets 2 SOD1 promoters. GmZFP03 can be directly used for precise P. sojae-resistance soybean breeding.

Engineering Dispersive-Dissipative Modal Coupling in Hybrid Optical Microresonators.

Hybrid microresonators have served an intriguing platform for fundamental research and applied photonics. Here, we study the plasmonics-engineered coupling between degenerate optical whispering gallery modes, which can be tuned in a complex space featuring the dissipative strong, dispersive strong, and weak coupling regimes. Experimentally, the engineering of a single plasmonic resonance to a cavity mode family is examined in a waveguide-integrated high-Q microdisk, from which the complex coupling coefficients are extracted and agree well with theoretical predictions. The coupling strength over 10 GHz is achieved for both dissipative and dispersive interactions, showing a remarkable enhancement compared to that induced by a dielectric scatterer. Furthermore, the far fields of hybridized cavity modes are measured, revealing the coherent interference between the radiative channels. Our results shed light on the engineering of whispering gallery modes through plasmonic resonances, and provide fundamental guidance to practical microcavity devices.

Fine mapping and identification of a Fusarium wilt resistance gene FwS1 in pea.

KEY MESSAGE: A Fusarium wilt resistance gene FwS1 on pea chromosome 6 was identified and mapped to a 91.4 kb region by a comprehensive genomic-based approach, and the gene Psat6g003960 harboring NB-ARC domain was identified as the putative candidate gene. Pea Fusarium wilt, incited by Fusarium oxysporum f. sp. pisi (Fop), has always been a devastating disease that causes severe yield losses and economic damage in pea-growing regions worldwide. The utilization of pea cultivars carrying resistance gene is the most efficient approach for managing this disease. In order to finely map resistance gene, F2 populations were established through the cross between Shijiadacaiwan 1 (resistant) and Y4 (susceptible). The resistance genetic analysis indicated that the Fop resistance in Shijiadacaiwan 1 was governed by a single dominant gene, named FwS1. Based on the bulked segregant analysis sequencing analyses, the gene FwS1 was initially detected on chromosome 6 (i.e., linking group II, chr6LG2), and subsequent linkage mapping with 589 F2 individuals fine-mapped the gene FwS1 into a 91.4 kb region. The further functional annotation and haplotype analysis confirmed that the gene Psat6g003960, characterized by a NB-ARC (nucleotide-binding adaptor shared by APAF-1, R proteins, and CED-4) domain, was considered as the most promising candidate gene. The encoding amino acids were altered by a "T/C" single-nucleotide polymorphism (SNP) in the first exon of the Psat6g003960, and based on this SNP locus, the molecular marker A016180 was determined to be a diagnostic marker for FwS1 by validating its specificity in both pea accessions and genetic populations with different genetic backgrounds. The FwS1 with diagnostic KASP marker A016180 could facilitate marker-assisted selection in resistance pea breeding in pea. In addition, a comparison of the candidate gene Psat6g003960 in 74SN3B and SJ1 revealed the same sequences. This finding indicated that 74SN3B carried the candidate gene for FwS1, suggesting that FwS1 and Fwf may be closely linked or an identical resistant gene against Fusarium wilt.

Three novel er1 alleles and their functional markers for breeding resistance to powdery mildew (Erysiphe pisi) in pea.

Powdery mildew caused by Erysiphe pisi DC is a global notorious disease on peas. Deploying resistance pea cultivars is the most efficient and environmentally friendly method for the disease control. This study focuses on revealing the resistance genes in three pea germplasms and developing their functional markers for resistance breeding. The identification of resistance genes involved genetic mapping and the sequencing of the PsMLO1 gene. To confirm the hereditary in three reisistant germplasms, they were crossed with susceptible cultivars to generate F1, F2, and F2:3 populations. The F1 generation exhibited susceptibility to E. pisi, while segregation patterns in subsequent generations adhered to the 3:1 (susceptible: resistant) and 1:2:1 (susceptible homozygotes: heterozygotes: resistant homozygotes) ratios, indicating that powdery mildew resistance was governed by single recessive gene in each germplasm. Analysis of er1-linked markers and genetic mapping suggested that the resistance genes could be er1 alleles in these germplasms. The multiple clone sequencing results of the three homologous PsMLO1 genes showed they were novel er1 alleles, named er1-15, er1-16, and er1-17, respectively. The er1-15 and er1-16 were caused by 1-bp deletion at position 335 (A) and 429 (T) in exon 3, respectively, while er1-17 was caused a 1-bp insertion at position 248 in exon 3, causing a frame-shift mutation and premature termination of PsMLO1 protein translation. Their respective functional markers KASP-er1-15, KASP-er1-16 and KASP-er1-17 were successfully developed and validated in respective mapping populations and pea germplasms. These results provide valuable tools for pea breeding resistance to E pisi.

Single-cell RNA sequencing profiles reveal cell type-specific transcriptional regulation networks conditioning fungal invasion in maize roots.

Stalk rot caused by Fusarium verticillioides (Fv) is one of the most destructive diseases in maize production. The defence response of root system to Fv invasion is important for plant growth and development. Dissection of root cell type-specific response to Fv infection and its underlying transcription regulatory networks will aid in understanding the defence mechanism of maize roots to Fv invasion. Here, we reported the transcriptomes of 29 217 single cells derived from root tips of two maize inbred lines inoculated with Fv and mock condition, and identified seven major cell types with 21 transcriptionally distinct cell clusters. Through the weighted gene co-expression network analysis, we identified 12 Fv-responsive regulatory modules from 4049 differentially expressed genes (DEGs) that were activated or repressed by Fv infection in these seven cell types. Using a machining-learning approach, we constructed six cell type-specific immune regulatory networks by integrating Fv-induced DEGs from the cell type-specific transcriptomes, 16 known maize disease-resistant genes, five experimentally validated genes (ZmWOX5b, ZmPIN1a, ZmPAL6, ZmCCoAOMT2, and ZmCOMT), and 42 QTL or QTN predicted genes that are associated with Fv resistance. Taken together, this study provides not only a global view of maize cell fate determination during root development but also insights into the immune regulatory networks in major cell types of maize root tips at single-cell resolution, thus laying the foundation for dissecting molecular mechanisms underlying disease resistance in maize.

First Report of Botrytis cinerea Causing Stem Rot on Pea (Pisum sativum L.) in China.

Pea (Pisum sativum L.) is one of the most important cool season legumes consumed as vegetable in the world. In March 2022, a severe stem rot was observed on pea cultivars in vegetative stage in Wuhan, Hubei Province, China (30°39' N, 114°66' E). The infection started on the lower stems, and the lesions were water soaked, then girdled the stem, resulting in wilting of the leaves. Eventually, the entire plant died, and some necrotic stems were covered with gray conidia. To investigate the causal agent, small pieces cut from diseased stems were surface sterilized with 2% NaOCl for 1 min, then incubated on potato dextrose agar (PDA) at 25°C for 3 days. Pure cultures were obtained by hyphal tip transfer and five isolates were studied further. Colonies initially appeared white, turned gray from the center, then became taupe with cottony aerial mycelia, and finally black hard, round or irregular sclerotia (0.92 to 5.34 × 0.86 to 4.42 mm, n = 20) developed. The sealing film of several plates were removed after 5 days, and abundant conidia were produced 3 days later. The conidia are terminally arranged at the end of long, grayish branched conidiophores, conidia are unicellular, hyaline and round or elliptical, (9.2 to 11.4 × 6.7 to 9.2 µm, n = 50), and the conidiophores are (10.7 to 13.0 µm × 760 to 1080 µm, n=20) in size. The morphological characteristics were consistent with descriptions of Botrytis cinerea (Li et al., 2016). Genomic DNA of the five isolates was extracted, and the internal transcribed spacer region (ITS), glyceraldehyde-3-phosphate dehydrogenase (G3PDH) gene, heat-shock protein 60 (HSP60) gene, and DNA-dependent RNA polymerase subunit II (RPB2) gene were amplified using the primers described by Aktaruzzaman et al. (2018). The sequences were deposited in GenBank (accession nos. ON533694 and ON566787-ON566790 for ITS; ON600613 to ON600617 for HSP60; ON600608 to ON600612 for G3PDH; ON600603 to ON600607 for RPB2). The BLASTn analysis of these sequences showed that the isolates had high similarity (99 to 100%) with other B. cinerea isolates. A phylogenetic tree was constructed by MEGA11, and our isolates clustered in the B. cinerea clade. In pathogenicity test, 2-week-old seedlings of pea cultivar 'Zhongqin1' were inoculated. Mycelial plugs (5 mm diameter) taken from a 3-day-old colony of each isolate were placed on the axil of a stipule at the 4th node of potted pea plants (n=5 per isolate), and PDA plugs were placed on the same location of control (n=3). Inoculated and control plants were kept in a humid plastic box at 23°C for 2 days, and then placed in a glasshouse. Symptoms with water-soaked lesions were observed on the inoculated plants after 2 days, stems showed soft rot and broke off after 3 to 5 days, disease symptoms similar to those in the field, while the controls remained healthy. The pathogen was re-isolated from the affected stems, fulfilling Koch's postulates. B. cinerea had been reported to cause foliar, pod, seed and stem rot of pea after flowering in many pea production regions in the world (Kraft and Pfleger, 2001). Pea was recorded as a host of B. cinerea in Zhejiang, Sichuan and Yunnan Provinces (Tai, F. L. 1979; Zhuang, W.-Y. 2005; Zhang, Z. 2006.), but there has been no detailed disease description and identification of pathogen. To our knowledge, this is the first report of B. cinerea causing stem rot on pea in vegetative stage in China. Since B. cinerea can infect pea at any developmental stage, it could have a high economic impact as green pea production increases in China.

Molecular Characterizations of the er1 Alleles Conferring Resistance to Erysiphe pisi in Three Chinese Pea (Pisum sativum L.) Landraces.

Powdery mildew caused by Erysiphe pisi DC. is a major disease affecting pea worldwide. This study aimed to confirm the resistance genes contained in three powdery mildew-resistant Chinese pea landraces (Suoshadabaiwan, Dabaiwandou, and Guiwan 1) and to develop the functional markers of the novel resistance genes. The resistance genes were identified by genetic mapping and PsMLO1 gene sequence identification. To confirm the inheritance of powdery mildew resistance in the three Landraces, the susceptible cultivars Bawan 6, Longwan 1, and Chengwan 8 were crossed with Suoshadabaiwan, Dabaiwandou, and Guiwan 1 to produce F1, F2, and F2:3 populations, respectively. All F1 plants were susceptible to E. pisi, and phenotypic segregation patterns in all the F2 and F2:3 populations fit the 3:1 (susceptible: resistant) and 1:2:1 (susceptible homozygotes: heterozygotes: resistant homozygotes) ratios, respectively, indicating powdery mildew resistance in the three Landraces were controlled by a single recessive gene, respectively. The analysis of er1-linked markers and genetic mapping in the F2 populations suggested that the recessive resistance genes in three landraces could be er1 alleles. The cDNA sequences of 10 homologous PsMLO1 cDNA clones from the contrasting parents were obtained. A known er1 allele, er1-4, was identified in Suoshadabaiwan. Two novel er1 alleles were identified in Dabaiwandou and Guiwan 1, which were designated as er1-13 and er1-14, respectively. Both novel alleles were characterized with a 1-bp deletion (T) in positions 32 (exon 1) and 277 (exon 3), respectively, which caused a frame-shift mutation to result in premature termination of translation of PsMLO1 protein. The co-dominant functional markers specific for er1-13 and er1-14, KASPar-er1-13, and KASPar-er1-14 were developed and effectively validated in populations and pea germplasms. Here, two novel er1 alleles were characterized and their functional markers were validated. These results provide powerful tools for marker-assisted selection in pea breeding.

Disease Resistance and Molecular Variations in Irradiation Induced Mutants of Two Pea Cultivars.

Induced mutation is useful for improving the disease resistance of various crops. Fusarium wilt and powdery mildew are two important diseases which severely influence pea production worldwide. In this study, we first evaluated Fusarium wilt and powdery mildew resistance of mutants derived from two elite vegetable pea cultivars, Shijiadacaiwan 1 (SJ1) and Chengwan 8 (CW8), respectively. Nine SJ1 and five CW8 M3 mutants showed resistant variations in Fusarium wilt, and the same five CW8 mutants in powdery mildew. These resistant variations were confirmed in M4 and M5 mutants as well. Then, we investigated the genetic variations and relationships of mutant lines using simple sequence repeat (SSR) markers. Among the nine effective SSR markers, the genetic diversity index and polymorphism information content (PIC) values were averaged at 0.55 and 0.46, which revealed considerable genetic variations in the mutants. The phylogenetic tree and population structure analyses divided the M3 mutants into two major groups at 0.62 genetic similarity (K = 2), which clearly separated the mutants of the two cultivars and indicated that a great genetic difference existed between the two mutant populations. Further, the two genetic groups were divided into five subgroups at 0.86 genetic similarity (K = 5) and each subgroup associated with resistant phenotypes of the mutants. Finally, the homologous PsMLO1 cDNA of five CW8 mutants that gained resistance to powdery mildew was amplified and cloned. A 129 bp fragment deletion was found in the PsMLO1 gene, which was in accord with er1-2. The findings provide important information on disease resistant and molecular variations of pea mutants, which is useful for pea production, new cultivar breeding, and the identification of resistance genes.

Early cleavage of preimplantation embryos is regulated by tRNAGln-TTG-derived small RNAs present in mature spermatozoa.

tRNA-derived small RNAs (tsRNAs) from spermatozoa could act as acquired epigenetic factors and contribute to offspring phenotypes. However, the roles of specific tsRNAs in early embryo development remain to be elucidated. Here, using pigs as a research model, we probed the tsRNA dynamics during spermatogenesis and sperm maturation and demonstrated the delivery of tsRNAs from semen-derived exosomes to spermatozoa. By microinjection of antisense sequences into in vitro fertilized oocytes and subsequent single-cell RNA-seq of embryos, we identified a specific functional tsRNA group (termed here Gln-TTGs) that participate in the early cleavage of porcine preimplantation embryos, probably by regulating cell cycle-associated genes and retrotransposons. We conclude that specific tsRNAs present in mature spermatozoa play significant roles in preimplantation embryo development.

Genetic characteristics and ploidy trigger the high inducibility of double haploid (DH) inducer in Brassica napus.

BACKGROUND: Our recently reported doubled haploid (DH) induction lines e.g., Y3380 and Y3560 are allo-octoploid (AAAACCCC, 2n = 8× ≈ 76), which can induce the maternal parent to produce DH individuals. Whether this induction process is related to the production of aneuploid gametes form male parent and genetic characteristics of the male parent has not been reported yet. RESULTS: Somatic chromosome counts of DH inducer parents, female wax-less parent (W1A) and their F1 hybrid individuals revealed the reliability of flow cytometry analysis. Y3560 has normal chromosome behavior in metaphase I and anaphase I, but chromosome division was not synchronized in the tetrad period. Individual phenotypic identification and flow cytometric fluorescence measurement of F1 individual and parents revealed that DH individuals can be distinguished on the basis of waxiness trait. The results of phenotypic identification and flow cytometry can identify the homozygotes or heterozygotes of F1 generation individuals. The data of SNP genotyping coupled with phenotypic waxiness trait revealed that the genetic distance between W1A and F1 homozygotes were smaller as compared to their heterozygotes. It was found that compared with allo-octoploids, aneuploidy from allo-octoploid segregation did not significantly increase the DH induction rate, but reduced male infiltration rate and heterozygous site rate of induced F1 generation. The ploidy, SNP genotyping and flow cytometry results cumulatively shows that DH induction is attributed to the key genes regulation from the parents of Y3560 and Y3380, which significantly increase the induction efficiency as compared to ploidy. CONCLUSION: Based on our findings, we hypothesize that genetic characteristics and aneuploidy play an important role in the induction of DH individuals in Brassca napus, and the induction process has been explored. It provides an important insight for us to locate and clone the genes that regulate the inducibility in the later stage.

Maternal karyogene and cytoplasmic genotype affect the induction efficiency of doubled haploid inducer in Brassica napus.

BACKGROUND: Artificial synthesis of octoploid rapeseed double haploid (DH) induction lines Y3380 and Y3560 was made possible by interspecific hybridization and genome doubling techniques. Production of pure lines by DH induction provides a new way to achieve homozygosity earlier in B.napus. Previously, the mechanism of induction, and whether the induction has obvious maternal genotypic differences or not, are not known so far. RESULTS: In this study, different karyogene and cytoplasmic genotype of B.napus were pollinated with the previously reported DH inducers e.g. Y3380 and Y3560. Our study presents a fine comparison of different cytoplasmic genotypes hybridization to unravel the mechanism of DH induction. Ploidy identification, fertility and SSR marker analysis of induced F1 generation, revealed that ploidy and phenotype of the induced F1 plants were consistent with that type of maternal, rather than paternal parent. The SNP chip analysis revealed that induction efficiency of DH inducers were affected by the karyogene when the maternal cytoplasmic genotypes were the same. However, DH induction efficiency was also affected by cytoplasmic genotype when the karyogenes were same, and the offspring of the ogura cytoplasm showed high frequency inducer gene hybridization or low-frequency infiltration. CONCLUSION: The induction effect is influenced by the interaction between maternal karyogene and cytoplasmic genotype, and the results from the partial hybridization of progeny chromosomes indicate that the induction process may be attributed to the selective elimination of paternal chromosome. This study provides a basis for exploring the mechanism of DH inducer in B.napus, and provides new insights for utilization of inducers in molecular breeding.

A Novel Disease of Mung Bean, Phytophthora Stem Rot Caused by a New Forma Specialis of Phytophthora vignae.

An emerging soilborne disease resembling Phytophthora stem rot was observed on mung bean plants grown in Anhui, China. To identify the causal agent, diseased plants and soil samples from 13 fields were collected to isolate the pathogen. Twenty-two Phytophthora isolates were recovered from the samples and detailed identification was conducted. Based on morphological and molecular characterizations, all of the isolates were consistently identified as P. vignae. Phylogenetic analysis using eight nuclear loci sequences of the internal transcribed spacer region, rRNA gene large subunit, a partial sequence of the ß-tubulin gene, translation elongation factor 1α, 60S ribosomal protein L10, the enolase gene, heat shock protein 90, and triose phosphate isomerase/glyceraldehyde-3-phosphate dehydrogenase and a mitochondrial locus cytochrome c oxidase subunit I revealed that the mung bean isolates grouped in the same clade as P. vignae and its two formae speciales, P. vignae f. sp. adzukicola and P. vignae f. sp. vignae. A host specificity test showed that the mung bean isolates of P. vignae were pathogenic toward mung bean with a much stronger virulence and toward adzuki bean with a relatively weak virulence, but they were nonpathogenic to the other tested legume crops, including soybean, cowpea, pea, common bean, faba bean, and chickpea. The host range of mung bean isolates significantly differs from those of P. vignae f. sp. adzukicola and P. vignae f. sp. vignae based on our results and on previous studies. Thus, the pathogen causing Phytophthora stem rot of mung bean is proposed as a new forma specialis of P. vignae, designated as P. vignae f. sp. mungcola.

Genome Sequence Data of Three Formae Speciales of Phytophthora vignae Causing Phytophthora Stem Rot on Different Vigna Species.

Phytophthora vignae is an important oomycete pathogen causing Phytophthora stem rot on some Vigna spp. Three P. vignae isolates obtained from mung bean, adzuki bean, and cowpea exhibited high similarities in morphology and physiology but are specialized to infect different hosts. Here, we report the first de novo assembly of the draft genomes of three P. vignae isolates, which were performed using the PacBio SMRT Sequel platform. This study will extend the genomic resource available for the Phytophthora genus and provide a good foundation for further research on comparative genomics of Phytophthora spp. and interaction mechanism between hosts and pathogens.

First Report of Maize Stalk Rot Caused by Fusarium kyushuense in China.

During 2017 to 2019, a field survey for maize stalk rot was conducted in 21 counties (districts) across the Guangxi province of China. This disease caused yield losses ranging from 20% to 30%. Maize plants with stalk rot were collected during the late milk stage and pieces of diseased pith tissue were cultured as previously described (Shan et al. 2017). Fungal colonies and mycelia with morphological characteristics of Fusarium species were subcultured onto fresh potato dextrose agar (PDA) and carnation leaf agar (CLA) plates. Based on morphological characteristics and molecular detection by amplification of Fusarium genus-specific primers (Duan et al. 2016), 39 Fusarium isolates were identified. Among them, five isolates from Du'an, Pingguo, Debao, and Daxin had abundant, pale orange to yellow aerial mycelium with deep red pigments when grown on PDA (Fig. 1A; 1B). The average growth rate was 8.0 to 12.0 mm per day at 25°C in the dark. The fungi produced two types of spores on CLA. Microconidia were ovoid to clavate, generally 0- to 3-septate, and 4.6 to 9.4 µm in length (n = 30) (Fig. 1D); Macroconidia were slightly curved with an acute apical cell, mostly 3- to 4- septate, and 19.4 to 38.2 µm in length (n = 30) (Fig. 1C). No chlamydospores were observed. These five isolates were initially identified as Fusarium kyushuense based on morphological features. PCR was performed to amplify three phylogenetic genes (TEF1-α, RPB1, and RPB2) (O'Donnell et al. 1998) and species specific primers kyuR1F/kyuR1R (5-TTTTCCTCACCAAGGAGCAGATCATG-3/5-TCCAATGGACTGGGCAGCCAAAACACC-3), kyuR2F/kyuR2R (5-CAGATATACATTTGCCTCGACAC-3/5-TACTTGAGCACGGAGCTTG-3) were used to confirm species identity. The obtained sequences were deposited in GenBank under the accession numbers MT997084, MT997080, MT997081 (TEF1-α); MT550012, MT997085, MT997086 (RPB1); MT550009, MT997089, and MT997090 (RPB2), respectively. Using BLAST, sequences of TEF1-α, RPB1, and RPB2 of the isolates were 99.33% (MH582297.1) to 100% (MG282364.1) similar to those of F. kyushuense strains (Supplementary Table 1). Based on phylogenetic analysis with maximum likelihood methods using tools of the website of CIPRES (http://www.phylo.org), isolates GX27, GX167, and GX204 clustered with F. kyushuense with 100% bootstrap support (Fig. 2). The pathogenicity of the three isolates was tested using young seedlings and adult plants as previously described with modification (Ye et al. 2013; Zhang et al. 2016). The primary roots of three-leaf-old seedlings were inoculated by immersing the roots into a 1 × 106 macroconidia solution, incubating for 6 h at 25°C, and transferring to normal growth conditions (26°C, 16 h light/22°C, 8 h dark). The second or third internode above the soil surface of flowering stage plants grown in a greenhouse was bored with a Bosch electric drill to make a hole (ca. 8 mm in diameter) and inoculated with 0.5 mL of mycelia plug then sealed with petrolatum. The inoculum was created by homogenizing five plates of flourish hyphal mats (approximately 125 mL) with kitchen blender and adjusting to a final volume of 200 mL with sterilized ddH2O. No symptoms were observed in the seedlings or adult plants that were mock-inoculated with PDA plugs. Three days post-inoculation (dpi), roots of the infected seedling turned dark-brown and shrunk and the leaves wilted (Fig. 1E). Typical stalk rot symptoms observed in the inoculated plants were premature wilting of entire plant and hollow and weak stalks, leading to lodging; the longitudinal section of the internodes exhibited obvious dark brown necrosis and reddish discoloration at 14 dpi and 30 dpi, respectively (Fig. 1F). Fusarium kyushuense was re-isolated from the inoculated stalk lesions but not from the control. This is the first record of stalk rot caused by F. kyushuense on maize plants in China. However, F. kyushuense is known to cause maize ear rot in China (Wang et al. 2014) and can produce type A and type B trichothecene mycotoxins in kernels (Aoki and O'Donnell 1998). The occurrence of maize stalk rot and ear rot caused by F. kyushuense should be monitored in China due to the potential risk for crop loss and mycotoxin contamination.

First Report of Fusarium thapsinum Causing Maize Stalk Rot in China.

Maize (Zea mays L.) is the most widely grown crop in China, which was planted 41.28 million hectares in 2019 (http://data.stats.gov.cnw/easyquery.htm?cn=C01&zb=A0D0F&sj=2019). Several fungal diseases of maize are reported in which stalk rot has become one of the most destructive diseases in China. The average yield losses affected by the disease are estimated at 10% to 20% (Yu et al. 2016). From 2017 to 2019, a survey was conducted to determine the population diversity of Fusarium species associated with maize diseases in 18 cities across Henan province. Fusarium stalk rot of maize with disease incidence more than 25% was observed in two continuous maize fields at Xuchang city. The diseased stem tissues from junctions in health and disease were chopped into small pieces (3 × 8 mm), superficially disinfected (70% ethyl alcohol for 1 min), placed onto potato dextrose agar (PDA) amended with L-(+)-Lactic-acid (1 g/L), poured in petri plates and incubated at 25°C for 4 days. Mycelia showing morphological characteristic of Fusarium spp. were sub-cultured from single conidium. The pure fungal isolates produced fluffy colonies, white aerial mycelium with yellow pigment in agar. The radial mycelial growth was measured and calculated at an average growth rate 10.9 mm/day at 25°C (Fig. 1A; 1B). Macroconidia produced on carnation leaf agar (CLA) were relatively slender, slightly curved and thick-walled, mostly 3 to 5 marked septa, with a curved and tapering apical cell and poorly developed foot cell, 46.9 ± 5.6 µm × 4.9 ± 0.2 µm (Fig. 1C). Microconidia formed abundantly and were generally oval on CLA, 8.2 ± 0.5 µm × 3.4± 0.1 µm (Fig. 1D). No chlamydospores were observed. Morphological characteristics of the isolates matched the description of Fusarium thapsinum (Leslie and Summerell 2006). To further get the phylogenetic evidence, TEF1-α (translation elongation factor), RPB1 (the largest subunit of RNA polymerase II) and RPB2 (the second largest subunit of RNA polymerase II) were amplified with primer pairs EF1/EF2 (O'Donnell et al. 1998), thapR1F (5'-TTTTCCTCACAAAGGAGCAAATCATG-3')/thapR1R (5'-GTTCACCCAAGATATGGTCGAAAGCC-3'), and thapR2F (5'-ACTCTTTCACATTTGCGCCGAAC-3')/thapR2R (5'-CGGAGCTTTCGTCCAGTGTGAC-3'), and sequenced, respectively. The BLAST search of the sequences of EF1-α, RPB1 and RPB2 shared 99.87% to 100% identity with those of F. thapsinum strains deposited in the GenBank (Supplementary Table 1). Sequences from two isolates (XCCG-3-B-1 and XCCG-3-A-1) were deposited in GenBank (Accession No. MT550014, MT997082 for EF-1α; MT550011, MT997087 for RPB1 and MT550008, MT997091 for RPB2). The phylogenetic relationships based on analysis of the partial sequences showed the representive isolates clustered together with F. thapsinum at 96% bootstrap values (Fig. 2). Combined with the results of morphological characteristics and phylogenetic analysis, the strain designated as Fusarium thapsinum. To complete Koch's postulates, the pathogenicity of the isolates was tested using the silking-stage plants in a greenhouse based on previously described method with modification (Zhang et al. 2016). An 8 mm in diameter wound hole was created at the second or third internode of the plant above the soil surface and injected with 0.5 ml of mycelia plug. The inoculated stalk exhibited internal dark brown necrotic regions and the brown area elongated obviously around the insertion at 14 dpi (days post inoculation). At 30 dpi, the stalks turned soft, hollow and even lodging of the plants for those severe ones, which are similar to those observed on naturally infected maize plants in the field (Fig. 1F). When the roots of the three-leaf-stage seedlings were inoculated with 1×106 macroconidia solution (Ye et al. 2013), the root rot and leaf wilting symptoms were observed (Fig. 1E). While the control plants that were inoculated with only sterile water showed no disease symptoms. The pathogen was re-isolated from the inoculated tissues and the identity was confirmed by the morphological characters. Fusarium thapsinum had been described as causal agent of maize stalk rot in Pakistan (Tahir et al. 2018). To our knowledge, this is the first report of F. thapsinum associated with maize stalk rot in China. The discovery will strengthen the theoretical foundation of maize stalk rot disease management.

Resveratrol protects boar sperm in vitro via its antioxidant capacity.

The objective of the present study was to elucidate whether resveratrol could facilitate the survival of boar sperm during liquid preservation and fast cooling processes. Boar semen were diluted with Modena extender containing different concentrations of resveratrol. Sperm motility was evaluated by visual estimation. Membrane integrity, acrosome integrity and mitochondrial membrane potentials were measured by SYBR-14/PI, FITC-PNA and JC-1 staining, respectively. Moreover, the levels of reactive oxygen species (ROS), malonaldehyde (MDA) and total antioxidant capacity (T-AOC) were measured using commercial assay kits. B-cell lymphoma protein-2 (BCL2) content was determined by western blotting. During liquid preservation at 17oC, the addition of 50 µM resveratrol to the Modena extender significantly improved sperm motility, membrane integrity, acrosome integrity, and sperm mitochondrial membrane potentials. Similar results were also observed in the 150 µM resveratrol group during the fast cooling process. Furthermore, addition of resveratrol led to a decrease of ROS and MDA, and an increase in the content of T-AOC and BCL2. These observations suggest that addition of resveratrol to Modena extender protects boar sperm against oxidative stress. The optimal concentrations of resveratrol are 50 µM and 150 µM during liquid preservation and fast cooling process, respectively.

First Report of Paramyrothecium foliicola Causing Leaf Spot on Vigna radiata L. in China.

Mung bean (Vigna radiata L.) is an important legume crop cultivated widely in China (Nair et al. 2013). In September 2018, a severe foliar disease occurred on some mung bean cultivars (Jilv0816, Baolv200810-1, Liaolv10L708-5, and Zhonglv5) in Shijiazhuang (38°03'N, 114°29'E), Hebei Province, China. Initially, lesions were circular to irregular, with dark brown margins and pale centers (Supplementary Fig.1). Later, tiny dark stroma with oval or irregular shape were observed on spots. The infected field was about 0.067 hectare with 50-70% disease incidence, but with no significant yield losses. Several leaves with necrotic spots were collected and cut into 2-3-mm pieces, surface sterilized with 2% NaClO for 2 min, rinsed three times in sterile distilled water, and incubated on potato dextrose agar (PDA) at 25ºC in darkness for 7 days. Three of 10 obtained single spore isolates, QB1, QB2 and QB3, were used for further studies. Colonies had abundant white aerial mycelia and produced black sporodochia bearing masses of viscid spores on PDA after 7-10 days. Conidia were aseptate, hyaline, and cylindrical, with the size of 5.6-7.5 µm × 1.6-3.3 µm (n=50). Conidiophores branched repeatedly. These morphological characteristics resembled that of Paramyrothecium-like isolates (Lombard et al. 2016). Given that P. roridum, P. foliicola, and P. nigrum were all reported to cause leaf spot on leafy vegetables and ornamental crops, five loci (the internal transcribed spacer (ITS), translation elongation factor 1-alpha (tef1), ß-tubulin (tub2), 28S rRNA (LSU) and calmodulin (cmdA)) were amplified and sequenced for molecular analysis (Mati et al. 2019). The resulting sequences were deposited in GenBank under accession numbers: MK335967, MT415351-MT415364. Among the five loci, ITS and LSU sequences showed 99-100% (584/590, 545/546 base pairs) similarity with P. foliicola type strain CBS113121 (NR_145074.1; KU846324.1) by BLASTn analysis, while the tef1, tub2, and cmdA sequences exhibited high identity (99%) (398/404 bp, 323-324/326 bp, 555-558/560 bp) with P. foliicola strain Bas4_m2 (MH939239.1; MH824739.1; MH807772.1) (Mati et al. 2019). Phylogenetic tree of the five concatenated loci showed that our isolates cluster with P. foliicola, although they show slight difference from other P. foliicola strains (Supplementary Fig.2). Based on morphology and molecular analysis, the pathogen was identified as P. foliicola. Pathogenicity tests of the three isolates were performed by spraying 2 ml of 1.0 × 106/ml spore suspension on each three-week-old seedlings of mung bean cultivar 'Jilv 7' (n=5 for each isolate), whereas the controls were inoculated with sterile water (n=3). All inoculations were incubated in a moist chamber at 25ºC with a 12h light cycle. The experiment was repeated twice. After 7 to 10 days, symptoms with necrotic brown spots were observed on plants inoculated with P. foliicola, but not on controls. The pathogen was reisolated from randomly selected diseased leaves and identified as P. foliicola by morphology and DNA sequencing of tub2 and cmdA loci. No pathogens were isolated from controls. Although P. roridum has been reported to cause mung bean leaf spot in India (Singh and Shukla 1997; Singh and Narain 2008), to our knowledge, this is the first report of P. foliicola causing leaf spot on mung bean in China. This finding suggests a potential threat to mung bean production in China and further studies should focus on epidemiology and control of this disease.

Discovery and Fine Mapping of qSCR6.01, a Novel Major QTL Conferring Southern Rust Resistance in Maize.

Southern corn rust (SCR), an airborne disease caused by Puccinia polysora, can severely reduce the yield of maize (Zea mays L.). Using recombinant inbred lines (RILs) derived from a cross between susceptible inbred line Ye478 and resistant Qi319 in combination with their high-density genetic map, we located five quantitative trait loci (QTLs) against SCR, designated as qSCR3.04, qSCR5.07, qSCR6.01, qSCR9.03, and qSCR10.01, on chromosomes 3, 5, 6, 9, and 10, respectively. Each QTL could explain 2.84 to 24.15% of the total phenotypic variation. qSCR6.01, detected on chromosome 6, with the highest effect value, accounting for 17.99, 23.47, and 24.15% of total phenotypic variation in two environments and best linear unbiased prediction, was a stably major resistance QTL. The common confidence interval for qSCR6.01 was 2.95 Mb based on the B73 RefGen_v3 sequence. The chromosome segment substitution lines (CSSLs) constructed with Qi319 as the donor parent and Ye478 as the recurrent parent were used to further verify qSCR6.01 resistance to SCR. The line CL183 harboring introgressed qSCR6.01 showed obvious resistance to SCR that was distinctly different from that of Ye478 (P = 0.0038). Further mapping of qSCR6.01 revealed that the resistance QTL was linked to insertion-deletion markers Y6q77 and Y6q79, with physical locations of 77.6 and 79.6 Mb, respectively, on chromosome 6. Different from previous major genes or QTLs against SCR on chromosome 10, qSCR6.01 was a newly identified major QTL resistance to SCR on chromosome 6 for the first time. Using RIL and CSSL populations in combination, the SCR-resistance QTL research can be dissected effectively, which provided important gene resource and genetic information for breeding resistant varieties.

Magnetic precession modes with enhanced frequency and intensity in hard/NM/soft perpendicular magnetic films.

High frequency magnetic precessions with strong intensity are strongly desired in material systems for high performance magnetic memory or nano-oscillator applications with ultrafast manipulation speed. Here, we demonstrate an exchange-coupled asymmetric composite film structure of Ta/Pd/[Pd/Co]5/Cu(tCu)/[Co/Ni]5/Ta with adjustable strong perpendicular magnetic anisotropy and interlayer coupling strength, in which the dynamic magnetic properties are systematically studied by using time-resolved magneto-optical Kerr effect spectroscopy. It is demonstrated that the in-phase precession frequency is between those of the single hard magnetic [Pd/Co]5 and soft [Co/Ni]5 multilayers, which can be significantly enhanced for the strongly coupled case at tCu < 1 nm. Moreover, in the weakly coupled samples with tCu = 1.0-3.0 nm, besides the common in-phase acoustic mode, an out-of-phase optical mode occurs simultaneously with a frequency even higher than that of the hard magnetic [Pd/Co]5 layer. The optical mode precession frequency and amplitude show an unusual non-monotonic variation trend with the increase of tCu, which has been theoretically analyzed and attributed to the co-effect of decreased coupling strength and increased magnetic anisotropy field difference between the two multilayer stacks. Moreover, by adjusting tCu and the [Co/Ni] repetition number N, an optical mode of strong intensity can be actively achieved, even reaching 80% as compared to the acoustic mode. These results provide effective control and better understanding of magnetic dynamics in perpendicular composite films, which are of key importance for developing ultrafast spintronics-based devices.