You're basically just missing
let complement = function
| G -> C
| C -> G
| A -> T
| T -> A
let complementary_helix (x: helix) : helix =
List.map complement x
(For what it's worth, it's not necessary to specify types. OCaml will infer the types. It's good style to specify them for documentation but maybe not if they're obvious.)
OK, I guess this is a homework problem in which you're supposed to use recursion to solve the problem.
The way to think of recursion is that you want to solve a little piece of the problem, which gives you a smaller problem to solve. You pass the smaller problem to yourself (either before or after you solve your little piece). You also need to know when the problem has gotten so small there's no more work to do on it.
In your case, the little piece would be to translate one nucleotide to its complement. You're doing that semi-OK (you have lists where you would really just want to work on single nucleotides). But you're not passing the remainder of the problem to yourself to solve recursively. You're also not checking whether the problem is so small there's nothing to do.
For functions on lists, around 99% of the time you're going to make the problem smaller by splitting the list into the head (a single element) and the tail (a list that's smaller by one). That will work for you here.
As an example of how list recursion looks, here's a function that adds up all the integers in a list:
let rec sum l =
match l with
|  -> 0
| head :: tail -> head + sum tail
This has all the parts I described. The
match is used both to tell when the problem is trivial (when the list is empty) and to split the list into the head and the tail. Assuming you had the sum for the tail (which you can get recursively), the answer is pretty obvious. You just need to add the head onto this sum. You just need to ask yourself (almost always): if I had the answer for the tail of the list, what would I need to do to combine it with the head?