IntroductionThe accumulation of hea

Introduction
The accumulation of heavy metals in water, sediments, and soils has led to serious environmental problems. In recent years, several processes have been developed with the aim of reducing or recovering heavy metals from contaminated environments (Akinciand Guven, 2011). Physical and chemical approaches are capable of removing a broad spectrum of contaminants, but the main disadvantages of these methods lie in the increased energy consumption and the need of additional chemicals (Ilhan et al., 2004). In recent years, the processes such as bio leaching, bio sorption, and bio precipitation are all based on the use of microorganisms that have the ability to solubilize, adsorb, or precipitate heavy metals (Ballesteret al., 1992; Zouboulis et al., 1997).To date, most of the research on microbially induced calcite precipitation (MICP) has been confined to ureolytic bacteria,with specific focus on the catalysis of urea hydrolysis (Ferriset al., 2003), efficiency of calcite production (Muynck et al.,2010; van Paassen et al., 2010), and modification of soil physical properties by model bacteria (Burbank et al., 2011; De Jong∗ et al., 2010). The MICP has been shown to increase the shear strength of porous materials (De Jong et al., 2006; Harkes et al.,2010). MICP arises when the following reaction catalyzed by ure-ase: (NH2)2CO + 2H2O → 2NH4++ CO32 occurs in the presence ofdissolved calcium ions, leading to the precipitation of calcium car-bonate crystal: Ca2++ CO32−→ CaCO3(s).The crystals formed by this process create bridges between particles, thus improving the strength and stiffness of the material(Harkes et al., 2010). Urease induced CaCO3can fill pore spaces within various soil matrices and cement soil grains together to form sandstone (Burbank et al., 2011; Deepak et al., 2009; De Jonget al., 2006). Precipitation of CaCO3 induced by the urease catalyzed hydrolysis of urea has been shown to change the engineering properties of geomaterials (Burbank et al., 2011; Whiff in et al., 2007).Bacterial mixtures systems have long been used to study the interactions between cell populations and fundamental cell cellinteractions. Recently, these systems have been of particular interest to synthetic biologists for the study and engineering of complexmulticellular synthetic systems. At the basic level, a co culture isa cell culture setup, in which two or more populations of cell sare grown with some degree of contact between them (Goerset al., 2014). The ultimate aim of the bacterial mixtures systemis to deliver societal benefits via its industrial, medical, and environmental applications (Chen, 2012; Kitney and Freemont, 2012).Therefore, many bacterial mixtures systems are developed forfuture industrial, medical, or environmental applications. Althoughthe synergetic interactions between metals and ureolytic bacteria have attracted a fair share of attention, the effects of metal contaminated environments on bacterial mixtures growth are still unknown.The utilization of microorganisms with proven remediation potential and survivability in the contaminated environment is cru-cial for a successful bioremediation. In view of this, the present paper aims to study the remediation capacity of heavy metalsby pure and mixed bacterial cultures, for bioremediation process applications.