Rhizodegradation and phyto-accumula

Rhizodegradation and phyto-accumulation of organic contaminants
Recent studies have indicated that biostimulation of microbial activity in the rhizosphere of plants can accelerate the removal of various xenobiotics through various biochemical mechanisms commonly known as rhizodegradation or rhizoremediation 31 and 32. Given that regulation of ethylene by ACC deaminase leads to a more extensive root system of the plant, increased exploration of soil by roots might consequently enhance rates of rhizoremediation. Huang et al. [11] investigated the potential of different grass species inoculated with PGPR containing ACC deaminase for phytoremediation of a creosote-contaminated soil environment. Enhanced biomass production, in terms of root and shoot densities in response to ACC deaminase activity of PGPR, resulted in plants acting as an efficient sink for creosote. In another study, Huang et al. [33] developed an improved multi-process phytoremediation system for removal of polycyclic aromatic hydrocarbons from contaminated soil. Creosote was selected as a test contaminant, and a multi-process phytoremediation system comprised physical (volatilization), photochemical (photooxidation), microbial remediation, and phytoremediation (plant-assisted remediation) approaches. The strategies used to realize these processes included land-farming (aeration and light exposure), bioaugmentation, PGPR containing ACC deaminase activity, and plant growth of contaminant-tolerant tall fescue (Festuca arundinacea). After an experimental period of four months, the average efficiency of removal of 16 polyaromatic hydrocarbons (PAHs) by the multi-process remediation system was twice that of land-farming alone, 50% more than bioremediation alone, and 45% more than phytoremediation by itself. In this approach, bacteria containing ACC deaminase activity (Pseudomonas putida UW3, Azospirillum brasilense Cd and Enterobactor cloacae CAL2) played a major part because they enabled plants to grow under higher concentrations of PAHs by alleviating stress on them. Such synergistic application of these approaches caused a rapid and massive biomass accumulation of plant tissue and consequently more uptake of contaminants from the soil environment ( Figure 2). Very recently, Liu et al. [32] demonstrated that inoculation of alfalfa with Comamonas sp. strain CNB-1 not only removed 4-chloronitrobenzene (4-CNB) completely within 1 or 2 days from soil but also eliminated the phytotoxicity of 4-CNB to alfalfa plants. The authors did not investigate ACC deaminase activity in this bacterium. It is very likely that the bacterium might have ACC deaminase activity in addition to some other specific traits, which promoted plant tolerance against the toxicity of 4-CNB.