You could start by determining the convex hull of this point cloud (see e.g. http://softsurfer.com/Archive/algorithm_0109/algorithm_0109.htm), and try to find the two parallel lines that bound this polygon with the shortest distance.
I think this should be an easier problem because it allows you to base the direction of the parallel lines on the segments of the convex hull (of which there are a limited number).
One implementation could be to process each segment of the convex hull in turn. Per segment, draw a line through it (this is one of the two parallel lines), and then determine the closest other parallel line that encloses the convex hull. Do this for each segment of the convex hull while recording the minimum distance you have found between the parallel lines so far. At the end you should have your optimum result.
Obviously, this still requires an efficient way to determine the closest other parallel line. A (naive, but maybe good enough) way of doing this, is to take all vertices of the convex hull that are not on the current segment, and determine the perpendicular distance to the line through it (e.g. http://en.wikipedia.org/wiki/Distance_from_a_point_to_a_line). The maximum distance for all these vertices is also the minimum distance to the parallel line.
Function FindThinnestLine(PointCloud P)
CH = ConvexHull(P)
optS = nothing
optDist = infinite
For each segment S in CH
L = the line through S
/* Find the minimum distance that the line parallel to L must have in order to enclose CH */
maxDist = 0
For each vertex P in CH, except the two that limit S
dist = The distance between L and P
maxDist = max(dist, maxDist)
/* If the current S has a smaller maxDist, it is our new optimum */
if(maxDist < optDist)
optS = S
optDist = maxDist
Return the line through optS and the line parallel to optS at a distance of optDist as the result
This is an O(n^2) algorithm, with n being the number of segments in your convex hull.
Come to think of it, you don't need to iterate over O(n) vertices of the convex hull for every S (in order to find the maxDist), only for the first S. Let's say we call this first vertex oppV (opp for opposite to S), and let's say we process the segments of the convex hull in clockwise order. For every subsequent S that we process, the new oppV can be either the same vertex, or one of its right neigbours (but never a left neighbour, otherwise the segments wouldn't form a convex polygon).
Hence, processing the segments of the convex hull can then be done in O(n) (but creating the convex hull is still O(n log n)).