Most AST node implementations are pretty simple.
They are a struct (ok, ok, "class") containing a node type (usually an integer), a list of children (List is OK; high performance implementations have a set of members for statistically common 1st, 2nd, 3rd children), and some additional fields to carry values specific to the AST node instance, (e.g., the value "5" for the AST node "integer constant"). To enable efficient navigation of the tree from any node back to parents, there is often a special reference back to the parent node.
What's harder is deciding what set of AST nodes you should have. For a large grammar, this is inconvenient as you'll have to define a set of several hundred of them, and there will be churn as you modify the grammar in your attempts to get it right.
A simple trick is simply define one AST node per grammar rule. (This would be called a "concrete syntax tree" by most). But it is brainless and you don't miss anything.
Our DMS Software Reengineering Toolkit follows this "simple trick" idea, generating the AST node types dirrectly from the grammar rules. It additionally optimizes: leaf AST nodes that don't carry values aren't present in the tree, nodes for unary productions aren't present in the tree, and list-forming productions have the List style of children, while other node types have the fixed slot types for children. The net result is you what is pretty close to a "abstract" syntax tree anyway. All of this is automatically constructed by DMS's parser generator so you don't have think at all.
DMS also has a full, well-test C# 4.0 front end. Once you get past the headache of defining the AST, you'll then want to analyze/transform/generate from it, and the rest of DMS will suddenly become obviously valuable.