Response of photosynthesis, the xanthophyll cycle, and wax in Japanese yew (Taxus cuspidata L.) seedlings and saplings under high light conditions.

In order to understand the adaptative changes of the Japanese yew (Taxus cuspidate L.) to high light conditions, this study investigated gas-exchange, chlorophyll fluorescence, chlorophyll, and the impact of epicuticular wax on the gas-exchange and photoinhibition of Japanese yew seedlings and saplings. The chlorophyll content per unit area and photosynthetic rate in seedling leaves were significantly lower than in sapling leaves. When leaves from seedlings and saplings were exposed to 1,200 µmol·m-2·s-1 photon flux density (PFD) for 2 h, seedling leaves exhibited a greater down-regulation of maximum quantum yield (Fv/Fm) and actual photosystem II efficiency ( Φ PSII). Non-photochemical quenching (NPQ) and high energy quenching (qE) in sapling leaves were much higher than in seedling leaves when both were exposed to 1,200 µmol·m-2·s-1 PFD for 2 h. At a low level of O2, the photorespiration rate (Pr) and the ratio of photorespiration/gross photosynthetic rate (Pr/Pg) in seedling leaves were lower than in sapling leaves when both were exposed to 1,200 µmol·m-2·s-1 PFD, but this difference did not reach statistical significance (P < 0.05). Compared with sapling leaves, seedling leaves exhibited lower levels of xanthophyll pool. Epicuticular wax content on seedling leaves was significantly lower than on sapling leaves. The results of this study showed that wax coverage on the leaf surface decreased the photosynthetic rate in sapling leaves as a consequence of decreased stomatal conductance. Epicuticular wax is related to tree age and photoinhibition prevention in the Japanese yew. It is possible that lower photosynthetic rate, lower NPQ depending on the xanthophyll cycle, and lower deposition of epicuticular wax results in seedling plants that are not adapted to high light conditions.

First report of Corn Ear Rot Caused by Fusarium asiaticum in China.

Corn (Zea mays L.) ear rot, caused by various pathogens, is one of the most significant diseases of corn worldwide. In September 2020, a survey was undertaken to identify pathogenic fungi associated with corn ear rot in Suihua city (46.63°N 126.98°E), Heilongjiang Province, China. The average disease incidence was 14.2% and 15.6% in each of two fields sampled (~5 ha) using a five-point method (100 plants/each point). Twenty tissue samples from 20 diseased ears, showing white or pink mold on the surface of corn ears, were surface disinfected in 0.5% NaOCl for 5 min, rinsed 3 times in autoclaved distilled water. After drying, four treated corn kernels (one kernel/each ear) were placed onto potato dextrose agar (PDA) amended with 50 µg/mL streptomycin. The plates were sealed with parafilm sealing film and cultured in the dark at 26℃ with 80% RH for 3 days in an incubator. A total of 12 morphologically similar fungal isolates were obtained and subcultured by transferring hyphal tips for 3-5 days. Single-conidium isolates were generated with methods reported previously (Leslie and Summerell 2006). Colonies on PDA, reaching 20.3-20.9 mm·d-1 at 26℃, consisted of white to pale yellow, locculent, lush and dense aerial mycelium with red to apricot color. Macroconidia of six isolates randomly selected on carnation leaf agar (CLA) were falciform with a foot cell, three- to six-septate, measuring 12.6-67.2 × 2.6-5.4 µm (n = 100) in the dark at 26℃ with 80% RH for 5 days. No microconidia were observed. Based on these characteristics, the isolates were preliminarily identified as Fusarium asiaticum (Chang et al. 2020; Leslie and Summerell 2006). Genomic DNA of three representative isolates YSF2, YSF4 and YSF7 were extracted and the translation elongation factor 1-α (TEF-1ɑ) gene was amplified and sequenced using the primers EF1-728F/EF1-986R (Carbone and Kohn 1999). The DNA sequences of YSF2, YSF4 and YSF7 were deposited in GenBank (OL631287.1, OP272129 and OP272130). Analysis of TEF-1ɑ sequences of YSF2, YSF4 and YSF7 showed that they were 100% identical to F. asiaticum isolates NRRL 26156 (AF212452.1) in NCBI and NRRL 13818 (AF212451.1) in Fusarium MLST. A pathogenicity test was performed on corn cv. Xinxin 1. Four days after silk emergence, 3 mL conidial suspension (106 macroconidia/ml) of each 12 isolates was individually injected into the center of the ear through the husk sideways, penetrating the kernels to a depth of about 5 mm (6 ears/each isolate) in the field (Guo et al. 2020). Six corn ears treated with sterile distilled water were used as the control. After inoculation, normal field management was carried out. All inoculated ears showed symptoms similar to those observed in the field 50 days after inoculation, while no symptoms were observed on the blank control ears. Five fungal isolates with the same colony morphology as the naturally occurring ear rot in the field were re-isolated from the inoculated corn kernels and confirmed to be F. asiaticum according to morphological characteristics and sequence analysis of five fungal isolates. F. asiaticum has previously been reported to cause corn ear rots in Japan (Kawakami et al. 2015). To our knowledge, this is the first report of F. asiaticum causing corn ear rot in Northeast China. Corn ear rot poses a threat to significantly reduce the quality of corn in a major production zone of maize in China. Therefore, its distribution needs to be investigated and effective disease management strategies developed.

Magnesium Fertilization Affected Rice Yields in Magnesium Sufficient Soil in Heilongjiang Province, Northeast China.

Magnesium (Mg) plays a crucial role in rice yield. Heilongjiang Province is the main rice-producing region of China, playing an important role in guaranteeing China's and the world's grain security. However, rarely Mg fertilization is applied in this province. Soil Mg status of main rice-producing areas in Heilongjiang Province was investigated and Mg fertilizer experiments were conducted aiming to provide fertilizer recommendation in this region. A total of 358 soil samples from the 0-20 cm and 20-40 cm soil layer from the main rice-producing areas of Heilongjiang Province were collected to analyze soil exchangeable Mg (ex-Mg) and relative chemical properties. Meanwhile, field experiments of soil and foliar Mg application were performed in 2017-2019 to identify the effect of this nutrient on rice yield. The results showed that the ex-Mg concentration in the 0-20 cm and 20-40 cm soil layer was 282 mg kg-1 and 243 mg kg-1, respectively. Moreover, ex-Mg ranged on the abundant and exceptionally abundant level accounted for 75% in 0-20 cm and 55.3% in 20-40 cm. The ex-Mg concentration in the upper soil layer was higher than in the lower soil layer and varied depending on regions, which the west part of Heilongjiang Province showed the highest concentration in both soil layers. Correlation analysis showed that there had a significant (P < 0.05) linear relationship between ex-Mg and pH, CEC, ex-K, Ca, K/Mg, and Ca/Mg. Meanwhile, the results of path coefficients demonstrated that pH, CEC, and Ca/Mg had the most direct effect on ex-Mg concentration among these above factors. Soil Mg application had little effect on rice yield, which might be related to the soil Mg concentration and availability, and root uptake activity. Foliar Mg application increased rice yield by 8.45% (P < 0.05) compared to without Mg treatment, increased 1,000-grain weight by 2.62% (P < 0.05), and spikelet number per panicle by 4.19% (P < 0.05). In general, the paddy soil ex-Mg concentration in Heilongjiang Province was abundant. Soil-applied Mg played little role in rice yield in ex-Mg abundant regions, while foliar application increased rice yields significantly via increasing 1,000-grain weight and spikelet number per panicle.

Grain production versus resource and environmental costs: towards increasing sustainability of nutrient use in China.

Over the past five decades, Chinese grain production has increased 4-fold, from 110 Mt in 1961 to 557 Mt in 2014, with less than 9% of the world's arable land feeding 22% of the world's population, indicating a substantial contribution to global food security. However, compared with developed economies, such as the USA and the European Union, more than half of the increased crop production in China can be attributed to a rapid increase in the consumption of chemicals, particularly fertilizers. Excessive fertilization has caused low nutrient use efficiency and high environmental costs in grain production. We analysed the key requirements underpinning increased sustainability of crop production in China, as follows: (i) enhance nutrient use efficiency and reduce nutrient losses by fertilizing roots not soil to maximize root/rhizosphere efficiency with innovative root zone nutrient management; (ii) improve crop productivity and resource use efficiency by matching the best agronomic management practices with crop improvement; and (iii) promote technology transfer of the root zone nutrient management to achieve the target of high yields and high efficiency with low environmental risks on a broad scale. Coordinating grain production and environmental protection by increasing the sustainability of nutrient use will be a key step in achieving sustainable crop production in Chinese agriculture.

Different Growth Responses of an Invasive Weed and a Native Crop to Nitrogen Pulse and Competition.

Resource pulses are a common event in agro-ecosystems. A pot experiment was conducted to assess the effects of nitrogen (N) pulses and competition on the growth of an invasive weed, Amaranthus retroflexus, and a native crop, Glycine max. A. retroflexus and G. max were planted in pure culture with two individuals of one species in each pot and in mixed culture with one A. retroflexus and one G. max individual and subjected to three N pulse treatments. The N treatments included a no-peak treatment (NP) with N applied stably across the growing period, a single-peak treatment (SP) with only one N addition on the planting date, and a double-peak treatment (DP) with two N additions, one on the planting date and the other on the flowering date. N pulse significantly impacted biomass and height of the two species across the whole growing season. However, only the relative growth rate (RGR) of A. retroflexus was significantly affected by N pulse. A. retroflexus had the greatest biomass and height in the SP treatment at the first harvest, and in the DP treatment at the last three harvests. Pure culture G. max produced the greatest biomass in the DP treatment. In mixed culture, G. max produced the greatest biomass in the NP treatment. Biomass production of both species was significantly influenced by species combination, with higher biomass in mixed culture than in pure culture at most growth stages. Relative yield total (RYT) values were all greater than 1.0 at the last three harvests across the three N treatments, suggesting partial resource complementarity occurred when A. retroflexus is grown with G. max. These results indicate that A. retroflexus has a strong adaptive capacity to reduce interspecific competition, likely leading to its invasion of G. max cropland in China.

Cloning and functional identification of the AcLFY gene in Allium cepa.

Onion (Allium cepa L.) is one of the important vegetable crops in the world, usually with a two-year life cycle. The bulbs form in the first year after sowing, then bolting and flowering are induced by low temperature in the following year. Previous studies have shown that LEAFY gene is an inflorescence tissue specific gene, and that it is also the ultimate collection channel of all flowering pathway. In this study, using homologous gene cloning and reverse transcription-PCR (RT-PCR), we isolated an inflorescence meristem specific LEAFY cDNA, AcLFY (JX275962), from onion. AcLFY contains a 1119 bp open reading frame, which encodes a putative protein of 372 amino acids, with ∼70% homology to the daffodils LEAFY and >50% homology to LEAFY proteins from other higher plants. Fluorescence quantitative results showed that AcLFY gene has the highest expression level in inflorescence meristem during early bolting, and is still expressed in leaves after the formation of flower organs. Overexpression of AcLFY gene in Arabidopsis thaliana induced early bolting and flowering, whereas knockdown of the endogenous LEAFY gene by RNAi caused a significant delay in bolting. In addition, transgenic plants also exhibited significant morphological changes in rosette leaves, branches, and plant height.