Another nice benefit of immutable structures is that you can locally cache instances of them and reuse them across multiple threads without fear of unexpected behaviors as would be the case if they were mutable.
For instance, suppose you are using an external caching service such as memcached or Velocity or some other equally simplistic distributed hashtable service. You could just use the C# client library and call it good enough. However, that is being wasteful with resources given a short-lived context like a web request scenario. What you really want is to pull each object from the cache once and only once in your context.
The safest way to get this job done is to place a local hashtable in your process in front of the cache provider. On the first request for the cache key you'd pull down the serialized byte stream that represents the object you wish to use and store that byte stream in your local hashtable. On subsequent requests for the same cache key, just look up the byte stream in the local hashtable and deserialize the object to a new instance for each request. This is to prevent multiple redundant trips to the cache server node for the same information that assumedly has not changed over the lifetime of your context.
With immutable structures, you could deserialize the byte stream only once on the first request and get away with storing the deserialized instance in the hashtable instead of the byte stream and just share that one single immutable instance of your object. This obviously cuts down on deserialization penalties which can add up rather quickly if your consuming code is written in such a fashion that it does not care how many calls it makes to the caching provider, assuming the cache is faster than querying your underlying data store.
Perhaps this is more of a subjective answer, but it's a specific problem that can be solved uniquely by using immutable structures so I thought it was relevant to share.