Elite sd1 alleles in japonica rice and their breeding applications in northeast China

The Green Revolution gene sd1 has been used extensively in modern rice breeding,especially in indica cultivars.However,elite sd1 alleles and related germplasm resources used for japonica rice breeding have not been identified,and extensive efforts are needed for japonica rice breeding to obtain new dwarfing sources.Data from MBKbase-Rice revealed seven sd1 haplotypes in indica and four in japonica rice.Two new sd1 alleles were identified in indica rice.In 295 japonica accessions from northeast Asia,except for the weak functional allele SD1-EQ,sd1-r was the major allele,reducing plant height in comparison with SD1-EQ.Japonica germplasm resources carrying reported sd1 alleles were identified by genotype searching and further verified by literature search,genealogical analysis,and d Caps markers.Pedigrees and geographic distribution showed that sd1-r is an excellent allele widely used in northern China and Tohoku in Japan,and sd1-j is commonly used in east China and Kyushu in Japan.Dongnong-and Xiushui-series cultivars carrying sd1-r and sd1-j,respectively,are essential branches of the backbone parents of Chinese japonica rice,Akihikari and Ce21,with the largest number of descendants and derived generations.In semi-dwarf japonica rice breeding,sd1-d was introgressed into Daohuaxiang 2(DHX2).Dwarf and semi-dwarf lines carrying sd1-d were selected and designated as 1279 and 1280,respectively,after withstanding typhoon-induced strong winds and heavy rains in 2020,and are anticipated to become useful intermediate materials for future genetic research and breeding.This work will facilitate the introduction,parental selection,and marker-assisted breeding,and provide a material basis for the next step in identifying favorable genes that selected together with the sd1 alleles in japonica backbone parents.     

Thrombin immobilization to enzymatic modified PET and PAN fabrics and their applications

Enzymatic modification of synthetic materials has immense potential both of the functionalization of polymeric materials, such as poly(acrylonitrile) or polyesters, and the production of polymers for special applications, such as medical devices and enzyme immobilization. In this study, poly(ethyleneterephtalate) and poly(acrylonitrile) fabrics were modified with commercial laccase and nitrilase, respectively. Contact angles of enzymatic modified and unmodified fabrics were measured and it was found contact angles of enzymatic modified fabrics were less than those of unmodified fabrics. Attenuated-Total-Reflection-Fourier-Transform infrared spectroscopy showed that carboxylic acid groups occurred on fabrics after enzymatic modifications. Surfaces of modified and unmodified fabrics were investigated using scanning electron microscopy. Surfaces of unmodified fabrics were smooth but surfaces of modified fabrics were rugged and cracked. Thrombin was immobilized in modified fabrics by using 1-Ethyl-3-(3-dimetylaminopropyl)-carbodiimide. Optimization studies were also performed for the immobilization of thrombin. After prepared material was tested to stop bleeding in vitro conditions and it was found that thrombin immobilized poly(ethyleneterephtalate) and poly(acrylonitrile) fabrics had a reduced recalcification time to 51 % and 89 %, respectively. Thrombin immobilized poly(ethyleneterephtalate) fabric was also tested in in vivo conditions by using Cavia porcellus and it was observed that this material caused bleeding to stop at a ratio of 24.6 %. The results were statistically significant.     

Preparation of collagen fiber/CaCO3 hybrid materials and their applications in synthetic paper

The collagen fiber/CaCO₃ hybrid materials were successfully prepared via in situ organic-inorganic hybrid technique. The surface morphology, hybrid mechanism, thermal and hydrothermal stability of these materials were investigated, respectively. Scanning electron microscopy (SEM) analysis showed that the size scale and distribution of CaCO₃ particles in collagen fiber relied on the concentration of CaCl₂. When the CaCl₂ was at low concentration, for example 6 wt%, the in-situ produced CaCO₃ particles were distributed evenly around the collagen fiber, the particle size could be controlled in the range of 2–4 µm and no apparent coagulation of CaCO₃ particles was found. Fourier transform infrared spectroscopy (FTIR) study revealed the interactions between the collagen fiber and CaCO₃ particles. The water solubility test and TGA analysis indicated that the solubility of collagen fiber in hot water decreased significantly after hybridization with CaCO₃ particles, whereas, the decomposition temperature was improved with increasing of the production of CaCO₃ particles. Moreover, the hybrid materials were used in conjunction with polyurethane and CaCO₃ powder to fabricate a novel synthetic paper. The result showed that the synthetic paper had good writing and printing.     

Preparation of electrospun silk fibroin/Cellulose Acetate blend nanofibers and their applications to heavy metal ions adsorption

Silk fibroin (SF)/Cellulose Acetate (CA) blend nanofibrous membranes were prepared by electrospinning and their heavy metal absorbabilities were examined in an aqueous solution after ethanol treatment. The electrospun nanofibrous membranes were comprised of randomly oriented ultrafine fibers of 100–600 nm diameters. As a result of field emission electron microscope (FEEM), the anti-felting properties of the blend nanofibrous membranes were markedly improved after treatment with 100 % ethanol when SF was blended with CA. Metal ion adsorption test was performed with Cu²⁺ as a model heavy metal ion in a stock solution. The SF/CA blend nanofiber membranes showed higher affinity for Cu²⁺ in an aqueous solution than pure SF and pure CA nanofiber membranes. Especially, the blend nanofibrous membranes with 20 % content of CA had an exceptional performance for the adsorption of Cu²⁺, and the maximum milligrams per gram of Cu²⁺ adsorbed reached 22.8 mg/g. This indicated that SF and CA had synergetic effect. Furthermore, the parameters affecting the metal ions adsorption, such as running time and initial concentration of Cu²⁺, had been investigated. The results showed that the adsorption of the Cu²⁺ sharply increased during the first 60 min, the amount of metal ions adsorbed increased rapidly as the initial concentration increased and then slope of the increase decreased as the concentration further increased. This study provides the relatively comprehensive data for the SF/CA blend nanofibrous membranes application to the removal of heavy metal ion in wastewater.     

N-acetylglucosamine: production and applications

N-Acetylglucosamine (GlcNAc) is a monosaccharide that usually polymerizes linearly through (1,4)-β-linkages. GlcNAc is the monomeric unit of the polymer chitin, the second most abundant carbohydrate after cellulose. In addition to serving as a component of this homogeneous polysaccharide, GlcNAc is also a basic component of hyaluronic acid and keratin sulfate on the cell surface. In this review, we discuss the industrial production of GlcNAc, using chitin as a substrate, by chemical, enzymatic and biotransformation methods. Also, newly developed methods to obtain GlcNAc using glucose as a substrate in genetically modified microorganisms are introduced. Moreover, GlcNAc has generated interest not only as an underutilized resource but also as a new functional material with high potential in various fields. Here we also take a closer look at the current applications of GlcNAc, and several new and cutting edge approaches in this fascinating area are thoroughly discussed.     

试管花卉的生产与应用

试管花卉是一种生长在精致的小试管或玻璃瓶内的迷你观赏花卉，可作为挂饰或摆饰。本文从试管花卉生产工艺及其应用，试管花卉开花的影响因素及其调控，市场现状等方面对试管花卉进行介绍，并对目前试管花卉研究存在的问题进行了分析，提出了相应的解决办法，旨在为试管花卉的研究提供参考。     

Thermal transitions of the amorphous polymers in wheat straw

The thermal transitions of the amorphous polymers in wheat straw were investigated using dynamic mechanical thermal analysis (DMTA). The study included both natural and solvent extracted wheat straw, in moist (8-9% water content) and dry conditions, and was compared to spruce samples. Under these conditions two transitions arising from the glass transition of lignin and hemicelluloses have been identified. Key transitions attributed to softening of lignin were found at 53, 63 and 91 °C for moist samples of wheat straw, extracted straw and spruce, respectively. Transitions for hemicelluloses were determined at 2, −1 and 5 °C, respectively. Differences are likely due to different compositions of lignin and hemicelluloses from straw and spruce and structural differences between the raw materials. The high wax content in wheat straw resulted in a transition at about 40 °C which was absent in solvent extracted wheat straw samples and spruce. This specific transition was further investigated and confirmed by differential scanning calorimetry (DSC) of extracted wheat straw wax. Information about the thermal transitions is of great importance for the utilization of wheat straw in pelletizing, briquetting and fiber board manufacturing.     

Platinum recovery using inherently conducting polymers and common fabrics

The recovery of platinum from solutions containing [PtCl₆]²⁻ using inherently conducting polymer (ICP) powders, membranes and coated fabrics has been investigated. Polyaniline (PAn) powders were able to recover platinum from solution, whereas polypyrrole (PPy) powders and membranes displayed almost no ability to perform this task. Uncoated pieces of nylon and nylon-lycra showed a significant capacity to recover platinum metal, unlike each of the other common fabrics investigated. Surprisingly the amount of platinum recovered by nylon-lycra was not improved by coating the fabric with a layer of ICP. Pieces of nylon-lycra that had previously been soaked in solutions containing [PtCl₆]²⁻ released only a small percentage of the bound metal when treated with 5 % HCl. However, subsequent treatment with aqua regia released all of the remaining platinum. A mechanism of platinum recovery by nylon and nylon-lycra involving coordination to functional groups present in their polymeric structures is proposed.     

近红外光谱技术及其在茶叶上应用研究

本文主要介绍了近红外光谱技术的发展历程和特点,以及近红外技术在茶叶上应用研究现状,并指出近红外光谱技术在茶叶上有着广阔的应用前景。     

Synthesis and characterization of polyurethane-based side-chain cholesteric liquid crystal polymers

Polyurethane-based side-chain cholesteric liquid crystalline polymers (ChLCPs) with variable clearing temperatures were synthesized in a two-step reaction. The chemical structures of ChLCPs were confirmed by FT-IR and ¹H-NMR spectroscopy. The mesogenic properties and phase transition behavior were investigated by means of differential scanning calorimetry (DSC), polarizing optical microscopy (POM), and X-ray diffraction measurements. The DSC studies show that the melting temperature and isotropic transition temperature of the ChLCPs increased with the weight percentage of cholesterol in the polymer. POM shows that the ChLCPs had a distinct spherulite structure that melted at about 140 °C, and these results are consistent with those of the DSC studies. The thermogravimetric studies show that the ChLCPs were stable up to 200 °C, though there was a reduction in the thermal stability as the weight proportion of cholesterol and glycerol in the polymer increased.     

CRISPR-based genome editing technology and its applications in oil crops

Oil crops, mainly comprised of soybean, rapeseed, groundnut, sunflower and etc., have provided substantial edible oil and other tremendous nutrients for human beings, as well as valuable biofuels for associated industries. The genetic improvement of significant oil crops and/or domesticating novel high-yielding oil crops are in urgent need to cope with the ever-increasing demand for various oil crop products. CRISPR (Clustered Regularly Interspaced Short Palindromic Repeats)-based genome editing technology, born a few years ago, edits stretches of DNA in a targeted and RNA-dependent fashion. The Characteristics of targeted mutagenesis and easy manipulation owned by the technology make it have been applied to many plants and exhibited great potential in the genetic improvement of many important oil crops. In the face of growing need for oil crop products and the rapid developments in CRISPR-based genome editing technology, a critical review regarding the technology and its application in oil crops is badly required to provide references for the better use of this technology to modify the oil crops for higher yield. In this review paper, we briefly described the CRISPR-based genome editing technology and summarized its applications and future prospects in oil crops.     

Antibacterial efficacy of polypyrrole in textile applications

This paper describes application and evaluation of polypyrrole as an antibacterial polymer. Polypyrrole was produced embedding two doping agents: chloride and dicyclohexyl sulfosuccinate ions. Stability of the antibacterial efficacy of polypyrrole deposited on cotton fabrics was assessed before and after three different kinds of washing (namely, laundering with anionic and non-ionic detergents and dry-cleaning). Polypyrrole showed excellent antibacterial properties (100 % of bacterial reduction) against Escherichia coli for both doping agents. Treated fabrics were further characterised by scanning electron microscopy, energy dispersive X-ray analysis and infrared spectroscopy. The antibacterial efficacy diminished after launderings with anionic and non-ionic detergents because of two different mechanisms: the neutralisation of positive charges under alkali conditions (dedoping), and a partial removal of polypyrrole by abrasion and surfactant action. After dry-cleaning, polypyrrole embedding chloride and dicyclohexyl sulfosuccinate ions still showed excellent antibacterial efficacy. Moreover, scanning electron microscopy investigations were used to intuitively explain the bactericidal mechanism of polypyrrole on Escherichia coli bacteria.     

Marine biocatalysts: enzymatic features and applications

In several recent reports related to biocatalysis the enormous pool of biodiversity found in marine ecosystems is considered a profitable natural reservoir for acquiring an inventory of useful biocatalysts. These enzymes are characterized by well-known habitat-related features such as salt tolerance, hyperthermostability, barophilicity and cold adaptivity. In addition, their novel chemical and stereochemical characteristics increase the interest of biocatalysis practitioners both in academia and research industry. In this review, starting from the analysis of these featuring habitat-related properties, important examples of marine enzymes in biocatalysis will be reported. Completion of this report is devoted to the analysis of novel chemical and stereochemical biodiversity offered by marine biocatalysts with particular emphasis on current or potential applications of these enzymes in chemical and pharmaceutical fields. The analysis of literature cited here and the many published patent applications concerning the use of marine enzymes supports the view that these biocatalysts are just waiting to be discovered, reflecting the importance of the marine environment. The potential of this habitat should be thoroughly explored and possibly the way to access useful biocatalysts should avoid destructive large-scale collections of marine biomass for enzyme production. These two aspects are day by day increasing in interest and a future increase in the use of marine enzymes in biocatalysis should be expected.     

Use of acetylated softwood kraft lignin as filler in synthetic polymers

Partially acetylated softwood kraft lignin (ASKL) is used as filler in synthetic polymers such as LDPE, PP, PS and PET. ASKL/synthetic polymer composites are prepared by melt-blending and compression molding with ASKL content up to 50.0 wt%. The chemical and physical properties of ASKL/synthetic polymer composites are also investigated. TGA results show that ASKL is more thermally stable than SKL up to 200 °C. FTIR spectra demonstrate a formation of free volume by crystallization of LDPE in ASKL/LDPE composite. DSC results show that the glass transition temperature of ASKL decreased by acetylation, and ASKL/synthetic polymer composites (50/50 w/w) have a single glass transition. The AFM images of ASKL/synthetic polymer composites show no significant phase separation. Young’s moduli of ASKL/synthetic polymer composites increased with ASKL content in some extents. Tensile strength and breaking strain of ASKL/PET composite are almost retained in spite of the addition of ASKL as a result of a contraction in free volume or densification.     

Properties of polymers as a nanoscale material for fibers in leather

Hyperbranched polymers, an innovative class of nano-polymers, could enhance the properties of fibers owning to their unique structures. In this study, the ester compound (HPAE) of 3-(bis(2-hydroxyethyl)amino)propionic acid and pentaerythritol was treated with undecylenic acid to obtain novel hyperbranched multiterminal alkenyl polymers (HPAE-UAs). The sizes of the HPAE-UAs could be controlled conveniently from 400 to 1300 nm by adjusting the capped fraction of the hydroxyl groups with undecylenic acids. The molecular structures of HPAE-UAs were characterized by means of FT-IR and ¹H-NMR. Then, the effect of the HPAE-UAs on the structures, thermal, and mechanical properties of the wet blue leather were investigated. TEM and SEM demonstrated that the spacing between fibers was enlarged. The thermogravimetric analysis showed that the residual volume of leather could reach up to 30.3 % at about 500 °C. Furthermore, the shrinkage temperature increased to 89.4 °C. It was found that the HPAE-UAs used in leather could improve the thermal performance, physical and mechanical properties. All of these results indicate that HPAE-UAs can be used as a fatliquor with retanning in leather process.     

Bromophenols in marine algae and their bioactivities

Marine algae contain various bromophenols that have been shown to possess a variety of biological activities, including antioxidant, antimicrobial, anticancer, anti-diabetic, and anti-thrombotic effects. Here, we briefly review the recent progress of these marine algal biomaterials, with respect to structure, bioactivities, and their potential application as pharmaceuticals.     

新疆甜菜田杂草危害与防治

本文阐述了新疆甜菜田杂草种群结构、消长规律及危险性,提出了以“农业措施为基础、化学除草为中心、人工除草为补充”的综合防治措施：一是合理轮作;二是土地深翻将杂草种子埋于土壤深层;三是清除田边、地头、渠边杂草,以免种子传播;四是地膜覆盖栽培甜菜可制约杂草生长;五是科学合理轮换使用化学除草剂。     

我国野生花卉资源开发利用的若干问题及对策

本文阐述我国野生花卉资源的优良特性，论述我国野生花卉资源开发利用的前景、现状和存在问题，提出我国野生花卉资源的开发利用的对策。     

茶皂素在农药上的应用研究概况

本文从茶皂素对有害生物的生物活性及其对农药的增效作用等方面阐述了茶皂素的研究进展,并就茶皂素的生物活性和增效作用机制进行了初步探讨。     

Marine carotenoids: biological functions and commercial applications

Carotenoids are the most common pigments in nature and are synthesized by all photosynthetic organisms and fungi. Carotenoids are considered key molecules for life. Light capture, photosynthesis photoprotection, excess light dissipation and quenching of singlet oxygen are among key biological functions of carotenoids relevant for life on earth. Biological properties of carotenoids allow for a wide range of commercial applications. Indeed, recent interest in the carotenoids has been mainly for their nutraceutical properties. A large number of scientific studies have confirmed the benefits of carotenoids to health and their use for this purpose is growing rapidly. In addition, carotenoids have traditionally been used in food and animal feed for their color properties. Carotenoids are also known to improve consumer perception of quality; an example is the addition of carotenoids to fish feed to impart color to farmed salmon.