One thing that's wrong in your code is your use of EQ. EQ compares for identity.
EQ is not for comparing numbers. EQ of two numbers can be true or false.
Use EQL if you want to compare by identity, numbers by value or characters. Not EQ.
(remove-if (lambda (x) (eql x item)) list)
(remove item list)
For your code the EQ bug COULD mean that permute gets called in the recursive call without actually a number removed from the list.
Other than that, I think SBCL is just busy with memory management. SBCL on my Mac acquired lots of memory (more than a GB) and was busy doing something. After some time the result was computed.
Your recursive function generates huge amount of 'garbage'. LispWorks says: 1360950192 bytes
Maybe you can come up with a more efficient implementation?
Lisp provides some automatic memory management, but that does not free the programmer from thinking about space effects.
Lisp uses both a stack and the heap to allocate memory. The heap maybe structured in certain ways for the GC - for example in generations, half spaces and/or areas. There are precise garbage collectors and 'conservative' garbage collectors (used by SBCL on Intel machines).
When a program runs we can see various effects:
normal recursive procedures allocate space on the stack. Problem: the stack size is usually fixed (even though some Lisps can increase it in an error handler).
a program may allocate huge amount of memory and return a large result. PERMUTE is such a function. It can return very large lists.
a program may allocate memory and use it temporarily and then the garbage collector can recycle it. The rate of creation and destruction can be very high, even though the program does not use a large amount of fixed memory.
There are more problems, though. But for each of the above the Lisp programmer (and every other programmer using a language implementation with garbage collection) has to learn how to deal with that.
Replace recursion with iteration. Replace recursion with tail recursion.
Return only the part of the result that is needed and don't generate the full solution. If you need the n-th permutation, then compute that and not all permutations. Use lazy datastructures that are computed on demand. Use something like SERIES, which allows to use stream-like, but efficient, computation. See SICP, PAIP, and other advanced Lisp books.
Reuse memory with a resource manager. Reuse buffers instead of allocating objects all the time. Use an efficient garbage collector with special support for collecting ephemeral (short-lived) objects. Sometimes it also may help to destructively modify objects, instead of allocating new objects.
Above deals with the space problems of real programs. Ideally our compilers or runtime infrastructure may provide some automatic support to deal with these problems. But in reality this does not really work. Most Lisp systems provide low-level functionality to deal with this and Lisp provides mutable objects - because the experience of real-world Lisp programs has shown that programmers do want to use them to optimize their programs. If you have a large CAD application that computes the form of turbine blades, then theoretical/puristic views about non-mutable memory simply does not apply - the developer wants the faster/smaller code and the smaller runtime footprint.