et al., 2010). The MICP has been sh

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 urease:
(NH2)2CO + 2H2O→2NH4+ + CO3
2− occurs in the presence of
dissolved calcium ions, leading to the precipitation of calcium carbonate
crystal: Ca2+ + CO3
2− →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 CaCO3 can fill pore spaces
within various soil matrices and cement soil grains together to
form sandstone (Burbank et al., 2011; Deepak et al., 2009; De Jong
et 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; Whiffin et al., 2007).
Bacterial mixtures systems have long been used to study the
interactions between cell populations and fundamental cell–cell
interactions. Recently, these systems have been of particular interest
to synthetic biologists for the study and engineering of complex
multicellular synthetic systems. At the basic level, a co-culture is
a cell culture set-up, in which two or more populations of cells
are grown with some degree of contact between them (Goers
et al., 2014). The ultimate aim of the bacterial mixtures system
is to deliver societal benefits via its industrial, medical, and environmental
applications (Chen, 2012; Kitney and Freemont, 2012).