Molecular characterization of soil microorganisms: effect of industrial pollution on distribution and biodiversity

Hafez, Elsayed E.; El-Bestawy, Ebtesam

doi:10.1007/s11274-008-9881-5

Cited by 26 publications

(12 citation statements)

References 47 publications

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“…biotic or abiotic. Starting from the available literature we proposed and assessed the potential risk related to thirteen possible stresses: (1) climate change (global warming) (Van der Putten, 2012), (2) land use change (Spurgeon et al, 2013), (3) habitat fragmentation (Halme et al, 2013), (4) intensive human exploitation (Tsiafouli et al, 2015), (5) soil organic matter decline (Heenan et al, 1995), (6) industrial pollution (Hafez and Elbestawy, 2009), (7) nuclear pollution (radioactivity) (Brodie et al, 2006), (8) soil compaction (Whalley et al, 1995), (9) soil erosion (Pimentel et al, 1995), (10) soil sealing (Setälä et al, 2014), (11) soil salinization (Sardinha et al, 2003), (12) use of genetically modified organisms (GMOs) in agriculture (Verbruggen et al, 2012), and (13) introduction and diffusion of invasive species (Kourtev et al, 2002).…”

Section: Introductionmentioning

confidence: 99%

A knowledge-based approach to estimating the magnitude and spatial patterns of potential threats to soil biodiversity

Orgiazzi

Panagos

Yiğini

et al. 2016

Science of The Total Environment

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Because of the increasing pressures exerted on soil, below-ground life is under threat. Knowledge-based rankings of potential threats to different components of soil biodiversity were developed in order to assess the spatial distribution of threats on a European scale. A list of 13 potential threats to soil biodiversity was proposed to experts with different backgrounds in order to assess the potential for three major components of soil biodiversity: soil microorganisms, fauna, and biological functions. This approach allowed us to obtain knowledge-based rankings of threats. These classifications formed the basis for the development of indices through an additive aggregation model that, along with ad-hoc proxies for each pressure, allowed us to preliminarily assess the spatial patterns of potential threats. Intensive exploitation was identified as the highest pressure. In contrast, the use of genetically modified organisms in agriculture was considered as the threat with least potential. The potential impact of climate change showed the highest uncertainty. Fourteen out of the 27 considered countries have more than 40% of their soils with moderate-high to high potential risk for all three components of soil biodiversity. Arable soils are the most exposed to pressures. Soils within the boreal biogeographic region showed the lowest risk potential. The majority of soils at risk are outside the boundaries of protected areas. First maps of risks to three components of soil biodiversity based on the current scientific knowledge were developed. Despite the intrinsic limits of knowledge-based assessments, a remarkable potential risk to soil biodiversity was observed. Guidelines to preliminarily identify and circumscribe soils potentially at risk are provided. This approach may be used in future research to assess threat at both local and global scale and identify areas of possible risk and, subsequently, design appropriate strategies for monitoring and protection of soil biota.

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Section: Introductionmentioning

confidence: 99%

A knowledge-based approach to estimating the magnitude and spatial patterns of potential threats to soil biodiversity

Orgiazzi

Panagos

Yiğini

et al. 2016

Science of The Total Environment

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“…These organisms were identified by amplification of ITS gene (in case of fungi) and 16S rRNA gene (in case of bacteria), using universal primers according to Hafez and Elbestawy [9] method. The PCR amplicones were sequenced in Macrogene Company (Seoul, Korea).…”

Section: Molecular Identification Of the Microorganismsmentioning

confidence: 99%

Induction of New Defensin Genes in Tomato Plants via Pathogens-Biocontrol Agent Interaction

Ee¹

2013

J Plant Pathol Microb

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Defensins and defensin-like peptides are functionally diverse and commonly presented as an immune reaction between plant and pathogen. Trichoderma viride and Bacillus subtilis as biological control agents, were inoculated into the soil, to suppress the activity of the pathogenic fungi Fusarium oxysporum and Rhizoctonia solani on tomato. The up-and down-regulated genes were examined in both treated and non-treated plants, using differential display technique. In treated plants, many up-regulated genes (21) with different molecular sizes, ranging from 50 to 7000 bp, were observed. Only four up-regulated genes were isolated from plants treated with B. subtilis+R. solani. The sequence analysis revealed that the identified genes were defensin genes; Amino Acid/Auxin Permease Family, Endopolygalacturonase PG1, Fructose-1,6-bisphosphatase and glycosyl transferase. Moreover, chitinase gene, defensin genes (DF1 and DF2) were quantitatively determined using RT-PCR. The comparative expression level of the three induced genes was exponentially increased as a function of time, after the application of the biological control agents. However, while the expression levels of DF1 and DF2 were high in plants infected with either F. oxysporum or R. solani in the beginning of the experiment, the highest expression level of these genes was attained in the tomato plant treated with either T. viride or B. subtilis, after 24 hour post inoculation.

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“…Soil biodiversity influences a huge range of ecosystem processes that contribute to the sustainability of life on earth [2]. Soil biodiversity maintains critical and key processes such as carbon storage, nutrient cycling, plant species diversity, soil fertility, soil erosion, nutrient uptake by plants, formation of soil organic matter, nitrogen fixation, biodegradation of organic materials, reducing hazardous waste, production of organic acids that weather rocks, and control of plant and insect populations through natural biocontrol [3,4,5].…”

Section: Introductionmentioning

confidence: 99%

Bacterial Biodiversity of Industrial Soils from Aydın and Trabzon Province

Törün

Kalyoncu²,

Çoban

et al. 2017

International Journal of Secondary Metabolite

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The aim of this study was to determine bacterial biodiversity of industrial soils from Aydın and Trabzon Province using morphological, cultural, biochemical and molecular methods. Factory wastes, detergents, pesticides and gasoline are accepted as pollutants to the environment. In this study a total of 65 samples which can tolerate xylene, acetone, chloroform and methanol were acquired. According to the Bergey's Manual of Systematic Bacteriology morphological, cultural and biochemical tests, 48 of these samples were found to be Bacillus sp. and 17 of them were found to be Pseudomonas sp. For molecular identification 16S rDNA-PCR method was used. Seven different genera and a total of sixteen species were found as a result of the study.

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Molecular characterization of soil microorganisms: effect of industrial pollution on distribution and biodiversity

Cited by 26 publications

References 47 publications

A knowledge-based approach to estimating the magnitude and spatial patterns of potential threats to soil biodiversity

A knowledge-based approach to estimating the magnitude and spatial patterns of potential threats to soil biodiversity

Induction of New Defensin Genes in Tomato Plants via Pathogens-Biocontrol Agent Interaction

Bacterial Biodiversity of Industrial Soils from Aydın and Trabzon Province

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