Is calculating an MD5 hash less CPU intensive than SHA family functions?

Yes, MD5 is somewhat less CPU-intensive. On my Intel x86 (Core2 Quad Q6600, 2.4 GHz, using one core), I get this in 32-bit mode:

MD5       411
SHA-1     218
SHA-256   118
SHA-512    46

and this in 64-bit mode:

MD5       407
SHA-1     312
SHA-256   148
SHA-512   189

Figures are in megabytes per second, for a "long" message (this is what you get for messages longer than 8 kB). This is with sphlib, a library of hash function implementations in C (and Java). All implementations are from the same author (me) and were made with comparable efforts at optimizations; thus the speed differences can be considered as really intrinsic to the functions.

As a point of comparison, consider that a recent hard disk will run at about 100 MB/s, and anything over USB will top below 60 MB/s. Even though SHA-256 appears "slow" here, it is fast enough for most purposes.

Note that OpenSSL includes a 32-bit implementation of SHA-512 which is quite faster than my code (but not as fast as the 64-bit SHA-512), because the OpenSSL implementation is in assembly and uses SSE2 registers, something which cannot be done in plain C. SHA-512 is the only function among those four which benefits from a SSE2 implementation.

Edit: on this page (archive), one can find a report on the speed of many hash functions (click on the "Telechargez maintenant" link). The report is in French, but it is mostly full of tables and numbers, and numbers are international. The implemented hash functions do not include the SHA-3 candidates (except SHABAL) but I am working on it.

On my 2012 MacBook Air (Intel Core i5-3427U, 2x 1.8 GHz, 2.8 GHz Turbo), SHA-1 is slightly faster than MD5 (using OpenSSL in 64-bit mode):

$ openssl speed md5 sha1
OpenSSL 0.9.8r 8 Feb 2011
The 'numbers' are in 1000s of bytes per second processed.
type             16 bytes     64 bytes    256 bytes   1024 bytes   8192 bytes
md5              30055.02k    94158.96k   219602.97k   329008.21k   384150.47k
sha1             31261.12k    95676.48k   224357.36k   332756.21k   396864.62k

Update: 10 months later with OS X 10.9, SHA-1 got slower on the same machine:

$ openssl speed md5 sha1
OpenSSL 0.9.8y 5 Feb 2013
The 'numbers' are in 1000s of bytes per second processed.
type             16 bytes     64 bytes    256 bytes   1024 bytes   8192 bytes
md5              36277.35k   106558.04k   234680.17k   334469.33k   381756.70k
sha1             35453.52k    99530.85k   206635.24k   281695.48k   313881.86k

Second update: On OS X 10.10, SHA-1 speed is back to the 10.8 level:

$ openssl speed md5 sha1
OpenSSL 0.9.8zc 15 Oct 2014
The 'numbers' are in 1000s of bytes per second processed.
type             16 bytes     64 bytes    256 bytes   1024 bytes   8192 bytes
md5              35391.50k   104905.27k   229872.93k   330506.91k   382791.75k
sha1             38054.09k   110332.44k   238198.72k   340007.12k   387137.77k

Third update: OS X 10.14 with LibreSSL is a lot faster (still on the same machine). SHA-1 still comes out on top:

$ openssl speed md5 sha1
LibreSSL 2.6.5
The 'numbers' are in 1000s of bytes per second processed.
type             16 bytes     64 bytes    256 bytes   1024 bytes   8192 bytes
md5              43128.00k   131797.91k   304661.16k   453120.00k   526789.29k
sha1             55598.35k   157916.03k   343214.08k   489092.34k   570668.37k

As someone who's spent a bit of time optimizing MD5 performance, I thought I'd supply more of a technical explanation than the benchmarks provided here, to anyone who happens to find this in the future.

MD5 does less "work" than SHA1 (e.g. fewer compression rounds), so one may think it should be faster. However, the MD5 algorithm is mostly one big dependency chain, which means that it doesn't exploit modern superscalar processors particularly well (i.e. exhibits low instructions-per-clock). SHA1 has more parallelism available, so despite needing more "computational work" done, it often ends up being faster than MD5 on modern superscalar processors.
If you do the MD5 vs SHA1 comparison on older processors or ones with less superscalar "width" (such as a Silvermont based Atom CPU), you'll generally find MD5 is faster than SHA1.

SHA2 and SHA3 are even more compute intensive than SHA1, and generally much slower.
One thing to note, however, is that some new x86 and ARM CPUs have instructions to accelerate SHA1 and SHA256, which obviously helps these algorithms greatly if the instructions are being used.

As an aside, SHA256 and SHA512 performance may exhibit similarly curious behaviour. SHA512 does more "work" than SHA256, however a key difference between the two is that SHA256 operates using 32-bit words, whilst SHA512 operates using 64-bit words. As such, SHA512 will generally be faster than SHA256 on a platform with a 64-bit word size, as it's processing twice the amount of data at once. Conversely, SHA256 should outperform SHA512 on a platform with a 32-bit word size.

Note that all of the above only applies to single buffer hashing (by far the most common use case). If you're fancy and computing multiple hashes in parallel, i.e. a multi-buffer SIMD approach, the behaviour changes somewhat.