Hyperthreading takes one core and effectively splits it down the middle into two virtual cores, each running at half the speed of the original.
So let's say you have a Quad-core CPU running at 2Ghz.
With hyperthreading off, you have 4 2Ghz cores.
With hyperthreading on, you effectively have 8 1Ghz cores.
This is fine and great when you're using software designed to take advantage of multiple cores. You'll rarely see a decrease in performance, and sometimes see an increase with hyperthreading on.
However, despite the fact that multi-core processors have been out for decades, there are still a LOT of applications (or certain portions of applications) that either aren't tuned for SMP (Symmetric Multi-Processing), or cannot be tuned (in the case where one step in the program flow can't be calculated until the result from another step is received). Here are some examples I've seen in the last month.
Oracle table scans on non-partitioned tables
McAfee on-access virus scan on a single large file
Complex batch (.bat) file execution
Each of these will use 100% of one "core". So on our example CPU, these processes will run at 2GHz with hyperthreading off, and 1GHz with hyperthreading on, and will finish twice as fast with it off.
If you think Hyperthreading is bad, some Sun machines come with CPUs that split a 1.6GHz core 8 ways. I'm constantly waiting on some process to execute in a single virtual 200MHz core while 127 other virtual cores sit idle. It's very frustrating. Add to this the fact that the bzip2 utility included with Solaris is single-threaded. The only way I get things compressed in a reasonable amount of time is when I write a script to split the compression job into 128 individual compression jobs manually.