There is nothing wrong in theory with the use of randomForest's method on class variables that have more than 32 classes - it's computationally expensive, but not impossible to handle any number of classes using the randomForest methodology. The normal R package randomForest sets 32 as a max number of classes for a given class variable and thus prohibits the user from running randomForest on anything with > 32 classes for any class variable.
Linearlizing the variable is a very good suggestion - I've used the method of ranking the classes, then breaking them up evenly into 32 meta-classes. So if there are actually 64 distinct classes, meta-class 1 consists of all things in class 1 and 2, etc. The only problem here is figuring out a sensible way of doing the ranking - and if you're working with, say, words it's very difficult to know how each word should be ranked against every other word.
A way around this is to make n different prediction sets, where each set contains all instances with any particular subset of 31 of the classes in each class variable with more than 32 classes. You can make a prediction using all sets, then using variable importance measures that come with the package find the implementation where the classes used were most predictive. Once you've uncovered the 31 most predictive classes, implement a new version of RF using all the data that designates these most predictive classes as 1 through 31, and everything else into an 'other' class, giving you the max 32 classes for the categorical variable but hopefully preserving much of the predictive power.