Management with willow short rotation coppice increase the functional gene diversity and functional activity of a heavy metal polluted soil.

[1]  D. W. Nelson,et al.  Nitrogen—Inorganic Forms , 2015 .

[2]  Hao Yu,et al.  GeoChip 4: a functional gene‐array‐based high‐throughput environmental technology for microbial community analysis , 2014, Molecular ecology resources.

[3]  Jaco Vangronsveld,et al.  Field Evaluation of Willow Under Short Rotation Coppice for Phytomanagement of Metal-Polluted Agricultural Soils , 2013, International journal of phytoremediation.

[4]  N Witters,et al.  Safe use of metal-contaminated agricultural land by cultivation of energy maize (Zea mays). , 2013, Environmental pollution.

[5]  C. Tyler-Smith,et al.  The Distribution of Diversity , 2013 .

[6]  Panos Panagos,et al.  Contaminated Sites in Europe: Review of the Current Situation Based on Data Collected through a European Network , 2013, Journal of environmental and public health.

[7]  E. Puglisi,et al.  Soil enzymology: classical and molecular approaches , 2012, Biology and Fertility of Soils.

[8]  S. Van Passel,et al.  Phytoremediation, a sustainable remediation technology? II: Economic assessment of CO2 abatement through the use of phytoremediation crops for renewable energy production. , 2012 .

[9]  Jaco Vangronsveld,et al.  Short Rotation Coppice Culture of Willows and Poplars as Energy Crops on Metal Contaminated Agricultural Soils , 2011, International journal of phytoremediation.

[10]  S. Audry,et al.  Sedimentary mercury stable isotope records of atmospheric and riverine pollution from two major European heavy metal refineries , 2010 .

[11]  Jizhong Zhou,et al.  Impact of Metal Pollution and Thlaspi caerulescens Growth on Soil Microbial Communities , 2010, Applied and Environmental Microbiology.

[12]  V. Kitunen,et al.  Proteins as nitrogen source for plants , 2010, Plant signaling & behavior.

[13]  Jean-Paul Schwitzguébel,et al.  Successes and limitations of phytotechnologies at field scale: outcomes, assessment and outlook from COST Action 859 , 2010 .

[14]  L. Landi,et al.  A protocol for the assay of arylesterase activity in soil , 2009 .

[15]  J. Ascher,et al.  Composition, biomass and activity of microflora, and leaf yields and foliar elemental concentrations of lettuce, after in situ stabilization of an arsenic-contaminated soil , 2009 .

[16]  Brandi L. Cantarel,et al.  The Carbohydrate-Active EnZymes database (CAZy): an expert resource for Glycogenomics , 2008, Nucleic Acids Res..

[17]  C. Garbisu,et al.  Functional diversity as indicator of the recovery of soil health derived from Thlaspi caerulescens growth and metal phytoextraction , 2008 .

[18]  J. Ascher,et al.  Long-term effects of aided phytostabilisation of trace elements on microbial biomass and activity, enzyme activities, and composition of microbial community in the Jales contaminated mine spoils. , 2008, Environmental pollution.

[19]  L. Landi,et al.  Microbial and hydrolase activity after release of low molecular weight organic compounds by a model root surface in a clayey and a sandy soil , 2007 .

[20]  Baohua Gu,et al.  GeoChip: a comprehensive microarray for investigating biogeochemical, ecological and environmental processes , 2007, The ISME Journal.

[21]  G. Renella,et al.  Impact of river overflowing on trace element contamination of volcanic soils in south Italy: part I. Trace element speciation in relation to soil properties. , 2006, Environmental pollution.

[22]  A. Polettini,et al.  A kinetic study of chelant-assisted remediation of contaminated dredged sediment. , 2006, Journal of hazardous materials.

[23]  J. Munch,et al.  Identification of bacterial sources of soil peptidases , 2000, Biology and Fertility of Soils.

[24]  I. Lo,et al.  EDTA Extraction of Heavy Metals from Different Soil Fractions and Synthetic Soils , 1999 .

[25]  A. Osborn,et al.  Distribution, diversity and evolution of the bacterial mercury resistance (mer) operon. , 1997, FEMS microbiology reviews.

[26]  J. Tiedje,et al.  DNA recovery from soils of diverse composition , 1996, Applied and environmental microbiology.

[27]  Göran Bengtsson,et al.  Heavy-metal ecology of terrestrial plants, microorganisms and invertebrates , 1989 .

[28]  J. R. Sanders,et al.  Extractability and bioavailability of zinic, nickle, cadmium and copper in three Danish soils sampled 5 years after application of sewage sludge , 1986 .

[29]  M. Tabatabai,et al.  Phosphodiesterase Activity of Soils1 , 1978 .

[30]  P. Nannipieri,et al.  Use of 0·1 m pyrophosphate to extract urease from a podzol , 1974 .

[31]  J. Ladd,et al.  Short-term assays of soil proteolytic enzyme activities using proteins and dipeptide derivatives as substrates , 1972 .

[32]  J. M. Bremner,et al.  Use of p-nitrophenyl phosphate for assay of soil phosphatase activity , 1969 .

[33]  A. Walkley,et al.  A CRITICAL EXAMINATION OF A RAPID METHOD FOR DETERMINING ORGANIC CARBON IN SOILS—EFFECT OF VARIATIONS IN DIGESTION CONDITIONS AND OF INORGANIC SOIL CONSTITUENTS , 1947 .

[34]  J. Kumpiene,et al.  Microbial biomass, respiration and enzyme activities after in situ aided phytostabilization of a Pb- and Cu-contaminated soil. , 2009, Ecotoxicology and environmental safety.

[35]  J. Bradford,et al.  Oxygen Effects on Carbon, Polyphenols, and Nitrogen Mineralization Potential in Soil , 2007 .

[36]  S. Grayston,et al.  Rhizosphere carbon flow in trees, in comparison with annual plants: the importance of root exudation and its impact on microbial activity and nutrient availability , 1997 .

[37]  P. Nannipieri,et al.  A comparison of methods for measuring ATP in soil , 1990 .

[38]  M. Tabatabai Soil Enzymes 1 , 1982 .

[39]  J. M. Bremner,et al.  Gas Chromatographic Analysis of Soil Atmospheres , 1977 .