Linux (or any other OS) divides memory up into pages (typically 4Kb). Each of these pages represent a chunk of memory. Usage information for these pages is maintained, which basically contains info about whether the page is free or is in use (part of some process), whether it has been accessed recently, what kind of data it contains (process data, executable code etc.), owner of the page, etc. These pages can also be broadly divided into two categories - filesystem pages or the page cache (in which all data read/written to your filesystem resides) and pages belonging to processes.
When the system is running low on memory, the kernel starts swapping out pages based on their usage. Using a list of pages sorted w.r.t recency of access is common for determining which pages can be swapped out (linux kernel has such a list too).
During swapping, Linux kernel needs to decide what to trade-off when nuking pages in memory and sending them to swap. If it swaps filesystem pages too aggressively, more reads are required from the filesystem to read those pages back when they are needed. However, if it swaps out process pages more aggressively it can hurt interactivity, because when the user tries to use the swapped out processes, they will have to be read back from the disk. See a nice discussion here on this.
By setting swappiness = 0, you are telling the linux kernel not to swap out pages belonging to processes. When setting swappiness = 100 instead, you tell the kernel to swap out pages belonging to processes more aggressively. To tune your system, try changing the swappiness parameter in steps of 10, monitoring performance and pages being swapped in/out at each setting using the "vmstat" command. Keep the setting that gives you the best results. Remember to do this testing during peak usage hours. :)
For database applications, swappiness = 0 is generally recommended. (Even then, test different settings on your systems to arrive to a good value).