This answer uses a trick (for expert only 😊) due to Adam Chlipala.
Don't hesitate to ask for more explanation if something is unclear.

`Ltac`

does not allow to go under binder but you can trick it by
folding the quantifiers.
Let us take `forall x y, x + y = 0`

that is a nested universal quantification.
You can fold it in into `forall p, fst p + snd p = 0`

that is a simple quantification. If you can arbitrary fold and unfold nested quantifications, you are done: you fold, perform your transformation then unfold.

Here is the code that does the trick

```
Ltac fold_forall f :=
let rec loop F :=
match F with
| forall x y, @?body x y =>
let v := (eval cbv beta in (forall t, body (fst t) (snd t))) in
loop v
| _ => F
end
in loop (forall _ : unit, f).
Ltac unfold_forall f :=
let rec loop F :=
match F with
| forall t : _ * _, @?body t =>
let v := (eval cbv beta in (forall x y, (body (x, y)))) in
loop v
| _ => match eval simpl in F with
| _ -> ?G => G
end
end
in loop f.
Ltac mk_left f :=
match f with
| forall x : ?T, ?A <-> ?B => constr:(forall x : T, A -> B)
end.
Ltac mk_right f :=
match f with
| forall x : ?T, ?A <-> ?B => constr:(forall x : T, B -> A)
end.
Ltac my_tac H :=
match type of H with
| ?v => let v1 := fold_forall v in
let v2 := mk_left v1 in
let v3 := unfold_forall v2 in
let v4 := mk_right v1 in
let v5 := unfold_forall v4 in
assert v3 by apply H;
assert v5 by apply H
end.
Goal (forall x y z : nat, (x = z) <-> (z = y)) -> False.
intros H.
my_tac H.
```