Effect of desert plant ecophysiological adaptation on soil nematode communities   总被引：1，自引：0，他引：1  

Stanislav Pen-Mouratov  Ginetta Barness  Yosef Steinberger   《European Journal of Soil Biology》2008,44(3):298-308

Nutrient source limitation in desert ecosystems enhances competition among plant communities, leading to creation of microhabitats beneath the shrubs that can determine composition and abundance of soil organisms. The aim of the study was to determine the effect of plant ecophysiological adaptation on soil nematode communities in the rhizosphere of tightly interweaving shrubby communities. Soil samples were collected monthly under the canopies of three perennial desert shrubs: Artemesia herba-alba, possessing the allelopathic ability to dominate in relationships with other plants; Reaumuria negevensis, a salt-resistant plant; and Noea mucronata, a typical dry desert shrub. An inter-plant area was used as a control. The results demonstrated that soil water content (SWC) and total organic carbon (C_org) were significantly different under different plants and inter-plant areas, with the highest values found under R. negevensis (SWC) and N. mucronata and R. negevensis (C_org). Plant parasite and omnivore-predator nematodes were more sensitive to the ecophysiological individual features of observed plants versus the total number of nematodes and bacteria- and fungi-feeding nematodes. Generally accepted ecological indices such as Wasilewska (WI), trophic diversity (T), maturity (MI, MMI), basal (BI), enrichment (EI), structure (SI), and channel (CI), pointed to specific ecological conditions under canopies of the observed plants.  相似文献   

Spatial heterogeneity of a microbial community in a sandy soil ecosystem     

Varsik Martirosyan  Racheli Ehrlich  Yaffa Frend  Gineta Barness  Yosef Steinberger 《Pedobiologia》2013,56(4-6):195-203

A fieldwork was carried out in Caesarea sand dunes, Israel, to determine the influence of fine-scale landscape-patch abiotic-factor heterogeneity on microbial activity in a Mediterranean region. Soil organisms in terrestrial systems are unevenly distributed in time and space, and are often aggregated. Spatio-temporal patchiness in the soil environment is thought to be crucial for the maintenance of soil biodiversity, providing diverse microhabitats that are tightly interwoven with resource partitioning. Determination of a ‘scale unit’ to help understand ecological processes has become one of the important and most debatable problems in recent years. To better understand the distribution of soil microbial communities at multiple spatial scales, a survey was conducted to examine the spatial organization of the community structure in two sandy soil ecosystems. One-hundred forty-four soil samples were collected from two patches 4000 m apart from each other. Basal respiration (CO₂ evolution without the addition of any external substrate), microbial biomass, functional diversity, and community-level physiological profile (CLPP) in soil were measured with a MicroResp? system. Soil abiotic analysis was performed by soil standard analytical methods. The results demonstrated that bacterial distributions can be highly structured, even within a habitat that appears to be relatively homogeneous at the plot and field scale. Different subsets of the microbial community were distributed differently across the plot. This is due to spatial heterogeneity associated with soil physical, chemical, and biological properties. Although spatial variability in the distribution of soil microorganisms is generally regarded as random, this variability often has a predictable spatial structure. This study provided evidence that a spatially explicit approach to soil ecology can enable the identification of factors that drive the spatial heterogeneity of populations and activities of soil organisms, at scales ranging from meters to hundreds of meters. Furthermore, there is increasing evidence that spatial soil ecology can yield new insights into the factors that maintain and regulate soil biodiversity, as well as on how the spatial distribution of soil organisms influences plant growth and plant community structure.  相似文献   

Nematode community composition and diversity associated with a topoclimatic transect in a rain shadow desert   总被引：1，自引：0，他引：1  

Yosef Steinberger  Wenju Liang  Elena Savkina  Tania Meshi  Ginetta Barness 《European Journal of Soil Biology》2001,37(4):315

The effect of a topoclimatic gradient on soil nematode communities was investigated in the Israeli Judean Desert. Four locations along a 35 km gradient, from an elevation of 650 m above sea level with 620 mm rainfall to a –60 m relative to sea level with a rainfall below 110 m, were studied: Givat Yearim, Maale Adumim, Mishor Adumim and Kalia. Monthly soil samples were collected between January 1994 and December 1995. Thirteen nematode families and 17 genera were observed. Cephalobus, Heterocephalobus, Aphelenchoides, Tylenchus, Dorylaimus and Eudorylaimus were found to be the dominant genera. Ecological measurements of soil nematode community structure, diversity, and maturity indices were assessed, and comparisons between four locations and four seasons were made. Significant differences in the total numbers of nematodes were found between the locations (p < 0.01) and seasons (p < 0.05), where Givat Yearim > Maale Adumim > Mishor Adumim > Kalia, winter > spring > autumn > summer. Bacterivores were found to be the most abundant trophic group across locations and seasons, with a mean relative abundance of 55.0%. The densities of bacterivores, plant parasites and omnivores-predators during the winter season exhibited similar trends at all four locations, with Givat Yearim > Maale Adumim > Mishor Adumim > Kalia. None of the ecological indices were significantly different between locations. However, the maturity index (MI), trophic diversity (TD) and Simpson diversity (SI) exhibited significant differences between seasons.  相似文献   

Cellulase dynamics in a desert soil     

Jack Doyle  Ginetta Barness 《Soil biology & biochemistry》2006,38(2):371-376

A field study was conducted in the Negev Desert over three seasons: June (summer), October (autumn), and April (spring). Cellulose of plant or paper origin was added to the study soils. The concentration of cellulase in the soil was determined by monitoring the rate of solubilization of chromophoric molecules covalently linked to artificial insoluble cellulose (cellulose-azure). The amount of CO₂ evolved from the soil was also evaluated at 60-day intervals.In this paper, we demonstrate that significant differences (p<0.01) in the cellulase concentration in desert soils are mainly due to the time period during which organic matter was incorporated into the soil. Data are presented showing changes in cellulase concentrations in the soil as a response to different cellulose sources (plant and paper origin) throughout the year.The results of our field experiments show that the cellulase concentration in the soil surrounding cellulose (paper) is higher during the summer than during the other seasons. The concentration of cellulase associated with fresh organic matter was found to be double that associated with paper. CO₂ evolution was higher in soil samples supplemented with organic matter than in control samples. This study demonstrates that the concentration of cellulase in desert soil changes over the year and is influenced by the cellulose source and by the quality of the cellulose incorporated in the soil.  相似文献   

Soil carbohydrates along a topoclimatic gradient in a Judean desert ecosystem     

Y. Steinberger  H. Lavee  G. Barness  M. Davidor 《Land Degradation \u0026amp; Development》1999,10(6):523-530

Soil carbohydrates, which include polysaccharides, are partly of microbial origin, contributing to soil structure and improving soil aggregates. This study examined the effect of climate along a topoclimatic gradient in the Judean desert. Soil was sampled at four locations representing different abiotic environments along the transect during the 1994 and 1995 study period. Significant differences in soil organic matter between the locations were obtained, decreasing towards the dry extreme desert sites. Carbohydrates, which probably are mainly composed of microbial extracellular polysaccharides, were found to increase during the dry season reaching maximum values by the end of autumn. The spatial and temporal changes in carbohydrate content are of great importance, representing biological activity that contributes to bonding between soil particles and helps promote nutrient accessibility to microorganisms. Copyright © 1999 John Wiley & Sons, Ltd.  相似文献