The no-three-in-line problem, introduced by Dudeney in 1917, asks for the maximum number of points in the n× n grid with no three points collinear. In 1951, Erdös proved that the answer is Θ(n). We consider the analogous three-dimensional problem, and prove that the maximum number of points in the n× n× n grid with no three collinear is Θ(n 2). This result is generalised by the notion of a 3D drawing of a graph. Here each vertex is represented by a distinct gridpoint in ℤ3, such that the line-segment representing each edge does not intersect any vertex, except for its own endpoints. Note that edges may cross. A 3D drawing of a complete graph K n is nothing more than a set of n gridpoints with no three collinear. A slight generalisation of our first result is that the minimum volume for a 3D drawing of K n is Θ(n 3/2). This compares favourably to Θ(n 3) when edges are not allowed to cross. Generalising the construction for K n , we prove that every k-colourable graph on n vertices has a 3D drawing with $\mathcal{O}(n\sqrt{k})$ volume. For the k-partite Turán graph, we prove a lower bound of Ω((kn)3/4).