Solution based on digital signatures with message recovery
Let's assume that the message M you want to store can be split into two segments: M1 and M2, and that M = M1||M2.
In general, the verification step in a message recovery scheme will tell you if M is authentic, but it will also give you back one segment (for instance M2) so that you effectively need to store only the other segment (for instance M1). As a drawback, you cannot access M2 without verifying the signature first, but in most cases that is really not what one wants to do.
Intuitively, some storage can be used for both a part of the message and a part of the signature.
The most widespread example is probably the scheme standardized into ISO 9796-2 (which is not totally secure! Read below...). In that scheme, a 2048 bit RSA signature coupled to SHA-1 can be used to store 234 bytes of M2. In practice, that means that the signature length varies from 20 to 256 bytes, depedening on the length of M.
More specifically, if n is the length of your RSA key and h is the length of the hash output (both in bits), the number of bytes you can store in the signature is (n-h-16)/8.
Whether it is good or not for you depends on how long your data is.
The caveat I mention above is that Coron, Naccahe, Tibouchi, and Weinmann recently showed that ISO 9796-2 can be broken more easily that one would expect, even though not "in 5 minutes on one computer" (they had to resort on several EC2 instances). Yet, it may be good enough for you security wise.
Other message recovery schemes exist, but one thing you should pay attention to is their patent status. For instance, PSS-R, Naccache-Stern, Nyberg-Rueppel, Pintsov-Vanstone cannot be freely used.
Solution based on signatures with appendix
DSA is a possibility. In this case, the signature does not embed any part of the original message. The general rule is that if you want a security of s bits, you need a 4s bit long DSA signature. To say, for 80 bit security (equivalent to 2TDES) you need 40 bytes. The same formula applies for ECDSA, but DSA is simpler and more widespread in software libraries.
In both cases (DSA and ECDSA), the signing server must have a good source of randomness. If the random generator is not reliable (e.g. if the server is a Virtual Machine or an embedded system), DSA and ECDSA could be broken, no matter how long the signatures are.