云南鹤庆白依人植物染料的民族植物学研究

植物染料有绿色环保、安全性高等优势,但其资源量少、成本高、色牢度低等缺点限制了植物染料在工业化的应用。云南鹤庆白依人有植物染色的传统习俗,当地有丰富的染料植物资源和传统染色工艺。为调查、记录和研究白依人植物染色和相关传统知识,拓展植物染料资源并促进植物染料的开发利用,该研究对大理州鹤庆县六合彝族乡白依人植物染色及相关传统知识进行了民族植物学调研。2019年9月至2020年3月,对大理州鹤庆县六合彝族乡4个村落的288位信息报告人进行半结构式访谈,对当地植物染料进行实地调研,以参与式观察法记录传统植物染色技艺,通过定量分析法对传统植物染色知识(f值、CII_s值、ICF值)进行分析研究。结果表明:(1)鹤庆白依人使用11种植物染料,分属10科11属。(2)不同地区、年龄、性别的白依人对传统植物染色知识的认知有差异。(3)水红木和密蒙花的使用频率和文化重要性指数较高,并且白依人对蓝染的植物染料认知高度一致。(4)白依人常用植物染料给本民族服饰火草衣染色。该文揭示了鹤庆白依人有较完整的传统植物染色知识体系,但随着时代的发展而逐渐流失。该研究结果为植物染料资源的开发和传统植物染色工艺的研究提供科学线索,促进少数民族植物染料的产业化应用,对少数民族地区的经济发展有重要意义和应用价值。     

The microbial degradation of azo dyes: minireview

The removal of dyes in wastewater treatment plants still involves physical or chemical processes. Yet numerous studies currently exist on degradation based on the use of microbes—which is a well-studied field. However progress in the use of biological methods to deal with this environmentally noxious waste is currently lacking. This review focuses on the largest dye class, that is azo dyes and their biodegradation. We summarize the bacteria identified thus far which have been implicated in dye decolorization and discuss the enzymes involved and mechanisms by which these colorants are broken down.     

Ethonobotany and sustainable utilization of natural dye plants in Sierra Leone

An ethnobotanical survey of practicing dyers in the biodiversity rich ecosystems of Sierra Leone and of the literature was conducted on the common plant species used to produce natural dyes. In addition, the methods used to obtain these dyes and to dye fabric, together with the techniques used to produce various patterns on fabric were investigated. Although the thriving dye industry is now predominantly serviced by synthetic dyes, the knowledge of the plants used still survives among some dyers, who use plant dyes to some extent. However this indigenous knowledge is rapidly being lost as increasingly less of it is being passed on to succeeding generations. Several plants used in the dyeing process are documented, together with their taxonomic characteristics; local names; how the dyes are produced and fabric dyed; the colors obtained; in addition to how various patterns are designed. Sustainable utilization of this important renewable natural resource is discussed.     

A cost-effective high-resolution melting approach using the EvaGreen dye for DNA polymorphism detection and genotyping in plants

High-resolution melting (HRM) analysis relies on the use of fluorescent dyes, such as LCGreen,ResoLight, and SYTO9, which bind in a saturated manner to the double-stranded DNAs. These dyes are expensive in use and may not be affordable when dealing with a large quantity of samples. EvaGreen is a much cheaper DNA helix intercalating dye and has been used in quantitative real-time polymerase chain reaction (PCR) and post-PCR DNA melt curve analysis. Here we report on the development of an EvaGreen-based HRM analysis and its performance, in comparison with the popular LCGreen-based HRM analysis, in detection of DNA polymorphism in plants. We found that various polymorphisms ranged from single nucleotide polymorphisms (SNPs) to Indels were equally detected by using EvaGreen- or LCGreen-based HRM. EvaGreen dye was sensitive enough in discovery of SNPs in fivefold pooled samples.Using this economical dye we successfully identified multiple novel mutant alleles of Gln1-3 gene,which produces a cytosolic glutamine synthetase isoenzyme (GS1), in a maize ethyl methanesulfonate (EMS)-mutagenized library, and genotyped rice mapping populations with SNP markers. The current results suggest that EvaGreen is a promising dye for HRM analysis for its ease to use and cost effectiveness.     

Effectiveness of Rice Agricultural Waste,Microbes and Wetland Plants in the Removal of Reactive Black-5 Azo Dye in Microcosm Constructed Wetlands

Azo dyes are commonly generated as effluent pollutants by dye using industries, causing contamination of surface and ground water. Various strategies are employed to treat such wastewater; however, a multi-faceted treatment strategy could be more effective for complete removal of azo dyes from industrial effluent than any single treatment. In the present study, rice husk material was used as a substratum in two constructed wetlands (CWs) and augmented with microorganisms in the presence of wetland plants to effectively treat dye-polluted water. To evaluate the efficiency of each process the study was divided into three levels, i.e., adsorption of dye onto the substratum, phytoremediation within the CW and then bioremediation along with the previous two processes in the augmented CW. The adsorption process was helpful in removing 50% dye in presence of rice husk while 80% in presence of rice husk biocahr. Augmentation of microorganisms in CW systems has improved dye removal efficiency to 90%. Similarly presence of microorganisms enhanced removal of total nitrogen (68% 0 and Total phosphorus (75%). A significant improvement in plant growth was also observed by measuring plant height, number of leaves and leave area. These findings suggest the use of agricultural waste as part of a CW substratum can provide enhanced removal of textile dyes.     

Calculation of binding length of base-specific DNA dyes by comparison of sequence and flow cytometric data. Application to Oryza sativa and Arabidopsis thaliana

From biochemical experiments it has been found that AT- and GC-specific dyes need a certain number of consecutive bases of the same type for binding one dye molecule. From known base sequences the amount of bases included in dye binding can be calculated and compared with experimental data from flow cytometry. Oryza sativa and Arabidopsis thaliana are the first higher plants which are nearly completely (>90%) sequenced. From the published sequences the theoretical fluorescence intensity of base-specific dyes in relation to a base-unspecific dye is calculated for different binding lengths. These values are compared with the actual fluorescence intensities of nuclei analyzed by flow cytometry. For all investigated dyes (DAPI, Hoechst 33258, Hoechst 33342 (all AT specific) and Mithramycin A (GC specific)) a binding length of 1 bp results from the comparison of theoretical and experimental data. This is, however, in disagreement with former results on dye binding. The main reason for the discrepancy seems to be the remaining gap in the sequencing of the Arabidopsis genome.     

Contemporary Knowledge of Dye Plant Species and Natural Dye Use in Kurdish Autonomous Region, Iraq

Contemporary knowledge of dye plant species and natural dye use in Kurdish Autonomous Region, Iraq In Kurdistan, natural dyes once played an important role in the life of nomads as they wild-crafted and traded natural dyes for their survival. They learned from their family how to find, harvest, process, and dye with natural dyes. Abandonment of weaving and the nomadic life, and recent changes in the economy have contributed to significant changes in the natural dyeing culture. Traditional knowledge of natural dyeing plants is no longer common among weavers. This study documents the surviving knowledge of dye plant species and assesses the transmission of knowledge between elderly weavers and a younger generation of weavers’ apprentices. Information on dyeing and dyeing plants was elicited through a species recognition task using picture cards, a pile-sorting task, and through in-depth interviews with nomads in the mountains of the Soran district as well as weaving teachers and students in the city of Erbil, Kurdish Autonomous Region, Iraq. Consensus analysis of pile-sorting data supports the hypothesis that informants belong to a single culture. The results confirm the erosion of natural dyeing culture in Kurdistan and stress the need to stimulate knowledge transfer from the elderly, empirical generation to the younger, learning generation. The study also uncovered the existence of a keen interest among the student informants in traditional herbal medicine. If this trend is true for Kurdish urban youth in general, then it could lead to a revival and perpetuation of traditional plant knowledge.     

Plants used as natural dye sources in Turkey

This study was carried out in the regions where handcrafts such as carpet and rug weaving are common in Turkey. In the regions where natural dyes are used, 123 plant species belonging to 50 families were identified as sources of natural dyes. In natural dye production, different parts of the plant or the whole aboveground plant is used. Ten different colors are gained from the plants. Sometimes the same color can be obtained from different plants. By mixing different plants, it is possible to produce various colors. We also identified more than 12 natural and more than eight chemical assistant substances (mordant) that are used in the regions to bind dye to fibers, to maintain the strongness and brightness of the colors, and to obtain various colors     

Bioremediation concepts for treatment of dye containing wastewater: a review

Synthetic dyes are extensively used in wide range of industries amongst which textile processing industries are the major consumers. Large amounts of dyes are lost in wastewaters of these industries during dyeing and subsequent washing steps of textiles. These dyes are resistant to de gradation by conventional wastewater treatment plants and are released into environment untreated thus causing pollution of surface and ground waters in the areas of the world harboring such industries. Presence of color in wastewaters has become major environmental concern and stringent discharge standards are being enforced on release of colored wastewaters in environment. The seriousness of the problem is apparent from the magnitude of the research done in this field in last decade. Increasing number of microorganisms are being described for their ability to decolorize and degrade artificial dyes and novel bioremediation approaches for treatment dye bearing wastewaters are being worked out. In this review we have investigated potential microbial processes for developing feasible remediation technology to combat environmental pollution due to dye bearing wastewaters.     

PHYTOREMEDIATION IN EDUCATION: TEXTILE DYE TEACHING EXPERIMENTS

Phytoremediation, the use of plants to clean up contaminated soil and water, has a wide range of applications and advantages, and can be extended to scientific education. Phytoremediation of textile dyes can be used as a scientific experiment or demonstration in teaching laboratories of middle school, high school and college students. In the experiments that we developed, students were involved in a hands-on activity where they were able to learn about phytoremediation concepts. Experiments were set up with 20—40 mg L^?1 dye solutions of different colors. Students can be involved in the set up process and may be involved in the experimental design. In its simplest forms, they use two-week-old sunflower seedlings and place them into a test tube of known volume of dye solution. Color change and/ or dye disappearance can be monitored by visual comparison or with a spectrophotometer. Intensity and extent of the lab work depends on student's educational level, and time constraints. Among the many dyes tested, Evan's Blue proved to be the most readily decolorized azo dye. Results could be observed within 1–2 hours. From our experience, dye phytoremediation experiments are suitable and easy to understand by both college and middle school students. These experiments help visual learners, as students compare the color of the dye solution before and after the plant application. In general, simple phytoremediation experiments of this kind can be introduced in many classes including biology, biochemistry and ecological engineering. This paper presents success stories of teaching phytoremediation to middle school and college students.     

New dye-labeled terminators for improved DNA sequencing patterns.

We have used two new dye sets for automated dye-labeled terminator DNA sequencing. One set consists of four, 4,7-dichlororhodamine dyes (d-rhodamines). The second set consists of energy-transfer dyes that use the 5-carboxy-d-rhodamine dyes as acceptor dyes and the 5- or 6-carboxy isomers of 4'-aminomethylfluorescein as the donor dye. Both dye sets utilize a new linker between the dye and the nucleotide, and both provide more even peak heights in terminator sequencing than the dye-terminators consisting of unsubstituted rhodamine dyes. The unsubstituted rhodamine terminators produced electropherograms in which weak G peaks are observed after A peaks and occasionally C peaks. The number of weak G peaks has been reduced or eliminated with the new dye terminators. The general improvement in peak evenness improves accuracy for the automated base-calling software. The improved signal-to-noise ratio of the energy-transfer dye-labeled terminators combined with more even peak heights results in successful sequencing of high molecular weight DNA templates such as bacterial artificial chromosome DNA.     

Benzidine-based dyes: effects of industrial practices,regulations, and world trade on the biological stains market

One of the most sweeping changes in the dye industry since the advent of synthetic dyes grew out of the health risks associated with benzidine. Dyes made from benzidine and its derivatives were used around the world until adverse health effects become incontrovertible. Workers and family members of workers involved in production and use of benzidine-based dyes had a high incidence of bladder cancer. Following publication of several reports documenting this health hazard, dye makers in the USA, Europe, and Japan phased these dyes out of production in the 1970s. Government regulations lent legal support for these voluntary initiatives. Two strategies subsequently evolved to compensate: developed nations brought alternative substances to market while emerging countries increased production of carcinogenic dyes and sold them at discount prices around the world. Nearly all dye manufacturing now has moved away from nations whose costs of production and compliance rendered them unable to compete. The purpose of this brief review is to publicize the health risks associated with dyes made from benzidine and its congeners, and to alert all companies and end users handling these dyes for biomedical applications that composition of the product and lot-to-lot variability may be problematic because of the manufacturing and distribution practices of the countries where they are produced.     

Comparison of historic Grübler dyes with modern counterparts using thin layer chromatography

The aniline dye industry was created in 1856 when William Perkin prepared the dye, mauve, from coal tar. Following that discovery, several dye manufacturing businesses were formed in Western Europe, most successfully in Germany. It was to these companies that early investigators turned to obtain these new dyes for the developing field of biology. In 1880, Dr. Georg Grübler started a company in Germany to supply the needs of biologists. Grübler dyes developed a reputation for excellence. In the study reported here, 29 samples of 12 Grübler dyes were compared to modern counterparts using thin layer chromatography. The dyes studied were basic fuchsine, acid fuchsine, safranine, pyronine, aniline blue, ponceau, gentian violet, methylene blue, orange G, malachite green, and Sudan III and IV. I found that these early Grübler dyes closely resembled modern day counterparts; however, the use of synonyms was confusing and some of the fat stains were mislabeled by modern criteria. The chromatograms of some dyes exhibited smearing, probably representing multiple closely related dye species. The study of old dyes provides interesting comparisons with modern counterparts as the center of dye manufacturing is moving from Europe and the United States to Asia.     

Mapping of antibody responses to the protective antigen of Bacillus anthracis by flow cytometric analysis

BACKGROUND: Different plant species vary as to the ratio of nucleotide base pairs of genomic DNA. A correlation between genome size and base pair ratio has been claimed. Base composition can be analyzed by base-specific dyes. METHODS: Genome size is determined by flow cytometry of suspensions of nuclei stained by the base independent dye, PI. For estimation of the AT frequency, the AT-specific dyes 4,6-diamidino-2-phenylindole, dihydrochloride (DAPI) and Hoechst 33342 (HO) were used. We define a dye factor (DF) as the ratio of the two estimates (peak ratios) of nuclear fluorescence intensities of sample relative to reference plant nuclei using a given dye and an intercalating fluorochrome. RESULTS: No significant correlation between genome size and the DF for DAPI was found when 54 plant species were investigated. However, similarities within and differences among the plant families were shown. The comparison of DAPI and HO DFs gave no consistent differences as would be predicted from the model of different binding site length of dyes. This result may be explained by the nonrandom distribution of base pairs. CONCLUSIONS: There is no general correlation between genome size and AT/GC ratio in higher plants. Similar AT/GC ratios within a plant family result from the general similarity of the DNA sequences within a family. The fluorescence of base-specific dyes is influenced by the nonrandom distribution of bases in the DNA molecule.     

Comparison of historic Grübler dyes with modern counterparts using thin layer chromatography.

The aniline dye industry was created in 1856 when William Perkin prepared the dye, mauve, from coal tar. Following that discovery, several dye manufacturing businesses were formed in Western Europe, most successfully in Germany. It was to these companies that early investigators turned to obtain these new dyes for the developing field of biology. In 1880, Dr. Georg Grübler started a company in Germany to supply the needs of biologists. Grübler dyes developed a reputation for excellence. In the study reported here, 29 samples of 12 Grübler dyes were compared to modern counterparts using thin layer chromatography. The dyes studied were basic fuchsine, acid fuchsine, safranine, pyronine, aniline blue, ponceau, gentian violet, methylene blue, orange G, malachite green, and Sudan III and IV. I found that these early Grübler dyes closely resembled modern day counterparts; however, the use of synonyms was confusing and some of the fat stains were mislabeled by modern criteria. The chromatograms of some dyes exhibited smearing, probably representing multiple closely related dye species. The study of old dyes provides interesting comparisons with modern counterparts as the center of dye manufacturing is moving from Europe and the United States to Asia.     

The use of fluorescent dyes to measure membrane potentials: a response

The use of fluorescent cyanine dyes to estimate membrane potential in cell suspensions has been considered. Several problems related tot he application of the dyes have been reviewed. These problems include: 1) alteration of the membrane potential (Em) and factors involved in establishing Em by the dyes themselves, 2) the effects of altered energy metabolism on the fluorescent response of the dyes and on Em, and 3) calibration of dye fluorescence. Recent reports that advocate the use of the fluorescent dyes are misleading.     

A review on biological synthesis of ZnO nanostructures and its application in photocatalysis mediated dye degradation: An overview

Zinc oxide (ZnO) has several industrial applications due to its versatile properties, which lead to its continuously increasing demand in different industrial sectors. Additionally, ZnO nanostructures possess unique photocatalytic activity, and because of this, they are being applied to degrade organic dyes through photocatalysis for wastewater treatment. Nevertheless, chemical synthesis methods to develop ZnO nanostructures have raised concerns related to environmental issues, furthermore, these methods are found to be costly and tedious. As a result, the synthesis of ZnO nanostructures using green methods is gaining popularity due to its low cost and eco-friendly mode, while avoiding the use of toxic chemicals. Green synthesis of ZnO nanostructures using different biological approaches involving plants, algae, and different microorganism-derived bioactive compounds has been well reported for diverse applications. Among different applications, ZnO nanostructures that enable photocatalysis to degrade dye have been found to be imperative for wastewater treatments. Therefore, the current review explores recent studies on green synthesis approaches to prepare ZnO nanostructures via adopting different biological methods that rely on plants, algae, and bacterial microorganisms. The properties of ZnO nanostructures, along with their green synthesis routes and feasible mechanisms, have also been discussed in this review. This review focuses on the use and efficiency of green route synthesized ZnO nanostructures as nanophotocatalysts for the degradation of organic dyes in wastewater treatment. Additionally, existing challenges in green synthesis methods and the efficiency of ZnO nanostructures to degrade organic dyes following photocatalysis has been discussed.     

An integrated process of textile dye removal and hydrogen evolution using cyanobacterium,Phormidium valderianum

The work deals with the removal of textile dyes from wastewater using cyanobacteria and integrating the dye removal ability of the organism with the ability to produce hydrogen. Phormidium valderianum, a marine cyanobacterium, has been shown to remove more than 90% of textile dyes Acid red, Acid red 119 and Direct black 155 from the solutions in the pH range higher than 11. Presence of phenolic compounds and metal chelators drastically reduced the dye adsorption capacity of the organisms. The mechanism involved in the dye adsorption has been investigated. Hydrogen production by cells grown in presence of dyes in any phase of their growth was found to be less in comparison to that of control (grown without dye). A laboratory scale reactor was designed to integrate the hydrogen production and dye removal ability of P. valderianum.     

Asymmetrical,water-soluble phthalocyanine dyes for covalent labeling of oligonucleotides

Two new water-soluble, porphyrazine (Pz) dyes containing an isothiocyanate function for covalent linking have each been prepared by cross condensation of two different aromatic dinitriles, one containing carboxylates for solubilizing purposes and the other containing a nitro group for conversion into the labeling function. The initial mononitrotricarboxylato Pzs have been purified to homogeneity from the mixture of Pz congeners formed in the condensation reaction by anion exchange chromatography. The phthalocyanine dye 1 has an absorption maxima at 683 nm while the trinaphthoporphyrazine dye 2 has an absorption maxima at 755 nm, due to the increased size of the aromatic system. Both dyes were successfully conjugated to oligonucleotide primers, showing their potential for use in near-infrared-based DNA diagnostic applications.