One of the MDS methods is distance scaling and it is divided in metric and non-metric. Another one is the classical scaling (also called distance geometry by those in bioinformatics). Classical scaling can be carried out in R by using the command cmdscale. Kruskal's method of nonmetric distance scaling (using the stress function and isotonic regression) can be carried out by using the command isoMDS in library MASS.
The standard treatment of classical scaling yields an eigendecomposition problem and as such is the same as PCA if the goal is dimensionality reduction. The distance scaling methods, on the other hand, use iterative procedures to arrive at a solution.
If you refer to the distance structure, I guess you should pass a structure of the class dist which is an object with distance information. Or a (symmetric) matrix of distances, or an object which can be coerced to such a matrix using as.matrix(). (As I read in the help, only the lower triangle of the matrix is used, the rest is ignored).
(for classical scaling method): One way of determining the dimensionality of the resulting configuration is to look at the eigenvalues of the doubly centered symmetric matrix B (= HAH). The usual strategy is to plot the ordered eigenvalues (or some function of them) against dimension and then identify a dimension at which the eigenvalues become “stable” (i.e., do not change perceptively). At that dimension, we may observe an “elbow” that shows where stability occurs (for points of a n-dimensional space, stability in the plot should occur at dimension n+1). For easier graphical interpretation of a classical scaling solution, we usually choose n to be small, of the order 2 or 3.