We study the complexity of determining a winning committee under the Chamberlin--Courant voting rule when voters preferences are single-crossing on a line, or, more generally, on a median graph (this class of graphs includes, e.g., trees and grids). For the line, Skowron et al. (2015) describe an $O(n^2mk)$ algorithm (where $n$, $m$, $k$ are the number of voters, the number of candidates and the committee size, respectively); we show that a simple tweak improves the time complexity to $O(nmk)$. We then improve this bound for $k=Omega(log n)$ by reducing our problem to the $k$-link path problem for DAGs with concave Monge weights, obtaining a $nm2^{Oleft(sqrt{log kloglog n}right)}$ algorithm for the general case and a nearly linear algorithm for the Borda misrepresentation function. For trees, we point out an issue with the algorithm proposed by Clearwater, Puppe and Slinko (2015), and develop a $O(nmk)$ algorithm for this case as well. For grids, we formulate a conjecture about the structure of optimal solutions, and describe a polynomial-time algorithm that finds a winning committee if this conjecture is true; we also explain how to convert this algorithm into a bicriterial approximation algorithm whose correctness does not depend on the conjecture.