I suspect the following greedy approach works: starting with the largest group, take each group and allocate one person of that group per table, picking first tables with the most free seats.
Indeed. And a small variation of tkleczek's argument proves it.
Suppose there is a solution. We have to prove that the algorithm finds a solution in this case.
This is vacuously true if the number of groups is 0.
For the induction step, we have to show that if there is any solution, there is one where one member of the largest group sits at each of the (size of largest group) largest tables.
Condition L: For all pairs (T1,T2) of tables, if T1 < T2 and a member of the largest group sits at T1, then another member of the largest group sits at T2.
Let S1 be a solution. If S1 fulfills L we're done. Otherwise there is a pair (T1,T2) of tables with T1 < T2 such that a member of the largest group sits at T1 but no member of the largest group sits at T2.
Since T2 > T1, there is a group which has a member sitting at T2, but none at T1 (or there is a free place at T2). So these two can swap seats (or the member of the largest group can move to the free place at T2) and we obtain a solution S2 with fewer pairs of tables violating L. Since there's only a finite number of tables, after finitely many steps we have found a solution Sk satisfying L.
Induction hypothesis: For all constellations of N groups and all numbers M of tables, if there is a solution, the algorithm will find a solution.
Now consider a constellation of (N+1) groups and M tables where a solution exists. By the above, there is also a solution where the members of the largest group are placed according to the algorithm. Place them so. This reduces the problem to a solvable constellation of N groups and M' tables, which is solved by the algorithm per the induction hypothesis.