Rabhi and Lapalme's Algorithms: A Functional Programming Approach has a nice chapter on this which illustrates some FP concepts being put to use, namely higher order functions and lazy evaluation. I assume it's OK for me to reproduce a simplified version of their higher order function.
It's simplified in that it only works on functions that take Int as input and produce Int as output. Because we're using Int in two different ways, I'll make synonyms for them "Key" and "Value". But don't forget that because these are synonynms, it's perfectly possible to use Keys and Values and viceversa. They're only used for readability.
type Key = Int
type Value = Int
dynamic :: (Table Value Key > Key > Value) > Key > Table Value Key
dynamic compute bnd = t
where t = newTable (map (\coord > (coord, compute t coord)) [0..bnd])
Let's dissect this function a little.
First, what does this function do? From the type signature we can see that it somehow manipulates tables. Indeed the first argument "compute" is a function (hence dynamic is a "higher order" function) which produces some sort of value from a table, and the second argument is just some kind of upper bound, telling us where to stop. And as output, the "dynamic" function gives us some kind of Table. If we want to get the answer to some DPfriendly problem, we run "dynamic" and then look up the answer from our Table.
To use this function to compute fibonacci, we would run it a little like this
fib = findTable (dynamic helper n) n
where
helper t i =
if i <= 1
then i
else findTable t (i1) + findTable t (i2)
Don't worry too much about understanding this fib function for now. It'll become a bit clearer as we explore "dynamic".
Second, what sort of prerequisites do we need to know about to understand this function? I'll assume you're more or less familiar with the syntax, the [0..x] to indicate a list from 0 to x, the > in type signatures like Int > Table > ... versus the > in anonymous functions like \coord > ... If you're not comfortable with these, they might get in the way.
Another prerequisite to tackle is this lookup Table. We don't want to worry about how it works, but let's assume that we can create them from lists of keyvalue pairs and also look up entries in them:
newTable :: [(k,v)] > Table v k
findTable :: Table v k > k > v
Three things to note here:
 For simplicity, we're not using the equivalent from the Haskell standard library
 findTable will crash if you ask it to look up a nonexistent value from the table. We can use a fancier version to avoid this if needed, but that's a subject for a different post
 Strangely enough, I didn't mention any sort of "add a value to the table" function, even though the book and standard Haskell libraries provide one. Why not?
Finally, how does this function actually work? What's going on here? We can zoom in a bit on the meat of the function,
t = newTable (map (\coord > (coord, compute t coord)) [0..bnd])
and methodically tear it apart. Going from the outside in, we've got t = newTable (...), which seems to tell us that we're building a table from some sort of list. Boring. What about the list?
map (\coord > (coord, compute t coord)) [0..bnd]
Here we've got the higher order map function walking down a list from 0 to bnd and producing a new list as a result. To compute the new list, it's using a function \coord > (coord, compute t coord).
Keep in mind the context: we're trying to build a table from key valuepairs, so if you study the tuple, the first part coord must be the key and the second part compute t coord must be the value. That second part is where things get exciting. Let's zoom in a little further
compute t coord
We're building up a table from keyvalue pairs and the value we're plugging into these tables comes from running "compute t coord". Something I didn't mention earlier is that compute takes a table and a key as input and tells us what value we ought to plug into the table, in other words, what value we should associate with that key. The idea then, to bring this back to dynamic programming, is that the compute function uses previous values from the table to compute that new value we ought to plug in.
And that's all! To do dynamic programming in Haskell we can build up some kind of table by successively plugging values into cells using a function that looks up prior values from the table. Easy, right?... or is it?
Perhaps you have a similar experience as I did. So I want to share my current progress grappling with this function. When I first read this function, it seemed to make a kind of intuitive sense and I didn't think much more of it. Then I read it closer and did a sort of doubletake, wait what?! How can this possibly work? Take a second look at this snippet of code here.
compute t coord
To compute the value at a given cell and thus fill the table, we pass in t, the very table we're trying to trying to create in the first place. If functional programming is about immutability as you point out, how can this business of using values we haven't computed yet possibly work? If you have a little bit of FP under your belt, you might be asking yourself as I did, "is that an error?", shouldn't this be a "fold" instead of a "map"?
The key here is lazy evaluation. The little bit of magic that makes it possible to create an immutable value from bits of itself all comes down to laziness. Being a sort of longtermyellowbelt Haskeller, I still find the notion of laziness a bit baffling. So I'll have to let somebody else take over here.
In the meantime, I simply tell myself that this is OK. I content myself with visualising the Table as a sort of dot with lots of arrows sticking out of it. Taking fib as an example:
o

0> 1

1> 1

2> 2

3> 2
.
.
.
The bits of the table we haven't seen yet are undiscovered territory. When we first walk down the list it's all undiscovered
o
.
.
.
When we want to compute the first value, we don't need to know anything more about the table because i <= 1.
helper t i =
if i <= 1
then i
else findTable t (i1) + findTable t (i2)
o

0> 1
.
.
.
When we want to compute successive values, we're always only looking back into already discovered parts of the table (dynamic programming, heyhey!). The key thing to remember is that we're 100% working with immutable values here, no fancy tricks beside laziness. "t" really means the table, and not "the table in its current state at iteration 42". It's just that we only discover the bits of table that tell us what the value that corresponds to 42 is when we actually ask for it.
Hopefully with others on StackOverflow, you'll go further than me and not be left mumbling vaguely "uhm yeah, laziness something or another" It's really not a big deal :)