We account for lateral orderings of III-V nanostructures resulting from a GaAs/InAs/InGaAs/GaAs sequence grown on GaAs by metallorganic vapour phase epitaxy at two different temperatures. For both samples, the ordering is induced by the stress field of a periodic dislocation network (DN) shallowly buried and parallel to the surface. This DN is a grain boundary (GB) that forms, between a thinGaAs layer (onwhich growthwas performed) and aGaAs substrate joined together by wafer bonding, in order to accommodate a tilt and a twist between these two crystals; both these misorientations are imposed in a controlled manner. This GB is composed of a one-dimensional network of mixed dislocations and of a one-dimensional network of screwdislocations. For both samples, the nanostructures observed by transmission electronmicroscopy (TEM) and atomic forcemicroscopy are ordered by the underlyingDNobserved byTEMsince they have same dimensions andorientations as the cells of the DN.