Regarding your question 2 (how to encode GADT use cases in Haskell 98), you may want to look at this 2006 paper by Sulzmann and Wang: GADTless programming in Haskell 98.
Like the OCaml work you're referring to, this works by factoring GADTs through an equality type. There are various ways to define equality type; they use a form of Leibniz equality like for OCaml, which allows to substitute through any application of a type operator at kind
* -> *.
Depending on how a given type checker reason about GADT equalities, this may not be expressive enough to cover all examples of GADTs: the checker may implement equality reasoning rules that are not necessarily captured by this definition. For example,
a*b = c*d implies
a = c and
b = d: this form of decomposition does not come if you only apply type constructors at kind
* -> *. Later in 2010, Oleg discussed how you can use type families to apply "type deconstructors" through Leibniz equality, gaining decomposition properties for this definition -- but of course this is again outside Haskell 98.
That's something to keep in mind for type system designers: is your language complete for leibniz equality, in the sense that it can express what a specialized equality solver can do?
Even if you find an encoding of the equality type that is expressive enough, you will have very practical convenience issues: when you use GADTs, all uses of equality witness are inferred from type annotations. With this explicit encoding you'll have much more work to do.
Finally (no pun intended), a lot of use cases of GADTs can be equally expressed by tagless-final embeddings (again by Oleg), that IIRC can often be done in Haskell 98. The blog post by Martin Van Steenbergen that dons points to in its reply's comment is in this spirit, but Oleg has considerably improved this technique.