The answer is really "historical reasons".
Computer memory must be addressable at some level. When you ask your RAM for information, you need to specify which information you want - and it will return that to you. In theory, one could produce bit-addressable memory: you ask for one bit, you get one bit back.
But that wouldn't be very efficient, since the interface connecting the processor to the memory needs to be able to convey enough information to specify which address it wants. The smaller the granularity of access, the more wires you need (or the more pushes along the same number of wires) before you've given an accurate enough address for retrieval. Also, returning one bit multiple times is less efficient than returning multiple bits one time (side note: true in general. This is a serial-vs-parallel debate, and due to reduced system complexity and physics, serial interfaces can generally run faster. But overall, more bits at once is more efficient).
Secondly, the total amount of memory in the system is limited in part by the size of the smallest addressable block, since unless you used variably-sized memory addresses, you only have a finite number of addresses to work with - but each address represents a number of bits which you get to choose. So a system with logically byte-addressable memory can hold eight times the RAM of one with logically bit-addressable memory.
So, we use memory logically addressable at less fine levels (although physically no RAM chip will return just one byte). Only powers of two really make sense for this, and historically the level of access has been a byte. It could just as easily be a nibble or a two-byte word, and in fact older systems did have smaller chunks than eight bits.
Now, of course, modern processors mostly eat memory in cache-line-sized increments, but our means of expressing groupings and dividing the now-virtual address space remained, and the smallest amount of memory which a CPU instruction can access directly is still an eight-bit chunk. The machine code for the CPU instructions (and/or the paths going into the processor) would have to grow the same way the number of wires connecting to the memory controller would in order for the registers to be addressable - it's the same problem as with the system memory accessibility I was talking about earlier.