That statement declares an array of bytes, and assigns to it 4 elements - each of those being a single byte (in theory!) in size. The actual values - 85, 86, 67, 75 - stored in that array are each values that can fit into a single byte. In your code sample, those values are represented in decimal form. Once your code is translated into executable form, those values will eventually be seen by your computer in their binary representations, bandied about from register to register, pushed, popped, and accumulated, etc.
You could represent values in other bases within your source - hexadecimal, or base 16, for instance, which is closer to the metal than decimal, and correspondingly allows your thought process to move easily between human representation and what your code is actually saying since there's virtually no actual math to mentally go between hex and binary; another good example is octal.
Or you can think of it this way: represent values within your code using the base that best relates to what you're doing. If you're OR'ing together permissions or color values, hex or octal; if you're calculating interest on a checking account, then the obvious choice is decimal.
Now, for your specific code snippet - if you're dealing with individual characters or writing raw stuff to a block device, an array of bytes might be just fine - however, as you become one with your compiler, your brain may eventually consider hex the easier-to-handle representation.