I think it might be easier to look at this a replacement into trees problem. It's easy to define a function that takes a tree and replaces subtrees in it that satisfy a test. There's a standard function subst-if that does that, but it replaces every matching subtree with the same thing. It will be more useful to us if we replace the element with a value computed from the subtree:
(defun %subst-if (new test tree)
"Replace subtrees of TREE that satisfy TEST with the result
of calling NEW with the subtree."
;; If tree satifies the test, return (new tree).
((funcall test tree)
(funcall new tree))
;; If tree is a cons, recurse.
(cons (%subst-if new test (car tree))
(%subst-if new test (cdr tree))))
;; Otherwise, just return the leaf.
With this, its easy to define the kind of function we need. When an element X appears somewhere in a nested list structure, it means that there is a cons cell whose car is X. We want to replace that cons cell with its cdr, but to also recurse on the cdr of the cell. This isn't hard:
(defun replace* (x list &key (test 'eql))
"Remove occurrences of X in LIST and its sublists."
"Replace elements of the form (X . more) with
(replace* x more :test test)."
(replace* x (cdr cons) :test test))
"Detect subtrees of the form (X . more)."
(and (consp subtree)
(funcall test x (car subtree))))
(replace* 'a '(1 a (2 a 3) a 4 a 5))
;=> (1 (2 3) 4 5)