To evaluate the efficacy and safety of canagliflozin, a sodium glucose co-transporter 2 inhibitor, in Asian patients with type 2 diabetes mellitus (T2DM) inadequately controlled by metformin or metformin in combination with sulphonylurea.
Anisomeles indica (L.) Kuntze is a perennial erect herb that belongs to the genus Epimeredi, family Labiatae (Hsieh et al., 2008). This herb is distributed in several southern provinces such as Yunnan, Sichuan and Guizhou in China, and it is also exported to Southeast Asian countries such as Singapore and Malaysia (Li., 2010; Yao et al., 2019). Due to its market potential and broad development prospects, the herb has been cultivated in Yunnan. In August 2021, virus-like symptoms on leaves, including shrinking, mosaic, and yellow mottling(Fig S1. A) appeared on approximately 80% of A. indica in the experimental fields of the Kunming Institute of Botany, Chinese Academy of Science, in Kunming, Yunnan. To unveil the possible viral agents associated with the disease symptoms, leaf samples were collected from 5 plants for transmission electron microscopy (TEM) analysis using negative staining (Zhang et al., 2016). Rhabditiform-shaped particles around 300 × 18 nm (Fig S1. C) were observed, which resemble those of tobamoviruses. To identify the exact virus, total RNA was extracted from the 20 leaf samples using the RNA-easy Isolation Reagent (Vazyme, Nanjing, China), followed by reverse transcription (RT)-PCR with a degenerate tobamovirus primer pair (Li et al., 2014). A 480-bp amplicon was obtained from each sample and cloned into the pMD18-T vector for Sanger sequencing (Takara, Dalian, China). BLASTn-analysis revealed that the 20 amplicons were identical and shared 100% nucleotide sequence identity with tobacco mosaic virus (TMV) isolate Bei Cang Zhu from Atractylodes lancea (acc. no. KU198186) One sequence was deposited in the GenBank under the accession number OK489807. ELISA testing with TMV-specific antibody (Agdia, USA) produced positive results for all of the 20 leaf samples. In order to understand the difference between TMV isolates from A. indica and those form other host plants, the sequences of movement protein (MP, 807 bp) and RNA-dependent RNA polymerase (RdRp, 3351 bp) of TMV were also obtained from one of the TMV infected samples using the target gene special primers (Tab. S1), and submitted to GenBank under the accession number OM3662406 (MP) and OM366242 (RdRp). BLASTn-analysis revealed that the amplicon of MP shared 97.75% nucleotide sequence identity with TMV isolate Henan 9-2-2017 from sweet potato (MN186255.1) and RdRp shared 97.43% nucleotide sequence identity with TMV isolate SXFQ from Solanum lycopersicum (JX993906.1). Phylogenetic analysis indicated that the isolate of A. indica grouped with several TMV isolates (e.g., tomato, AF103779.1 and tobacco, HE818449.1) from Northern China. The virus was successfully transmitted onto healthy A.indica plants (n = 5) upon mechanical inoculation as the plants not only developed foliar distortion symptoms but also tested positive for TMV by RT-PCR with the CP-specific primers (Tab. S1). Taken together, our results demonstrated that the diseased A. indica plants were infected with TMV. To our knowledge, this is the first report of TMV infected A. indica (L.) Kuntze in China. Symptomatic phenotype-based field surveys on some plantations in Yunnan Province indicated that the disease incidence ranged from 70% to 90%, resulting in significant loss of production of A. indica. It is necessary to monitor the viruses in the fields and find effective methods to protect TMV in the A. indica (L.) Kuntze industry.
Contamination of rice by arsenic represents a significant human health risk. Roxarsone -bearing poultry manure is a major pollution source of arsenic to paddy soils. A mesocosm experiment plus a laboratory experiment was conducted to reveal the role of rainwater-borne H2O2 in the degradation of roxarsone in paddy rice soils. While roxarsone could be degraded via chemical oxidation by Fenton reaction-derived hydroxyl radical, microbially mediated decomposition was the major mechanism. The input of H2O2 into the paddy soils created a higher redox potential, which favored certain roxarsone-degrading and As(III)-oxidizing bacterial strains and disfavored certain As(V)-reducing bacterial strains. This was likely to be responsible for the enhanced roxarsone degradation and transformation of As(III) to As(V). Fenton-like reaction also tended to enhance the formation of Fe plaque on the root surface, which acted as a filter to retain As. The dominance of As(V) in porewater, combined with the filtering effect of Fe plaque significantly reduced the uptake of inorganic As by the rice plants and consequently its accumulation in the rice grains. The findings have implications for developing management strategies to minimize the negative impacts from the application of roxarsone-containing manure for fertilization of paddy rice soils.
Phytomining technology cultivates hyperaccumulator plants on heavy metal contaminated soils, followed by biomass harvesting and incineration to recover valuable metals, offering an opportunity for resource recycling and soil remediation. Large areas of ultramafic soils, naturally rich in nickel (Ni), are present in numerous places around the world. As an environmentally friendly and cost-effective soil remediation technology, phytomining has a broad application prospect in such areas and thus has attracted great attention from global researchers. The key processes of phytomining include: (1) high-selectivity response of hyperaccumulator plants to Ni the underlying mechanisms involved in the rhizosphere; (2) underlying mechanisms of high-efficiency uptake and translocation of Ni in hyperaccumulators; and (3) resource recycling of high-added value Ni products from the Ni-rich bio-ore of hyperaccumulators. In recent 30 years, phytomining practices have successfully carried out in United States, Albania and Malaysia. However, the research and application of this technology in China are still in the fledging stage. This paper reviews the key processes and research progress of phytomining, and points out the bottleneck, to provide theoretical basis and technical guidance for phytomining.
Zero valent iron-loaded biochar (Fe0-BC) has shown promise for the removal of various organic pollutants, but is restricted by reduced specific surface area, low utilization efficiency and limited production of reactive oxygen species (ROS). In this study, iron carbide-loaded activated biochar (Fe3C-AB) with a high surface area was synthesized through the pyrolysis of H3PO4 activated biochar with Fe(NO3)3, tested for removing bisphenol A (BPA) and elucidated the adsorption and degradation mechanisms. As a result, H3PO4 activated biochar was beneficial for the transformation of Fe0 to Fe3C. Fe3C-AB exhibited a significantly higher removal rate and removal capacity for BPA than that of Fe0-BC within a wide pH range of 5.0-11.0, and its performance was maintained even under extremely high salinity and different water sources. Moreover, X-ray photoelectron spectra and density functional theory calculations confirmed that hydrogen bonds were formed between the COOH groups and BPA. 1O2 was the major reactive species, constituting 37.0% of the removal efficiency in the degradation of BPA by Fe3C-AB. Density functional reactivity theory showed that degradation pathway 2 of BPA was preferentially attacked by ROS. Thus, Fe3C-AB with low cost and excellent recycling performance could be an alternative candidate for the efficient removal of contaminants.