No, there is no good reason. Nor is there any good reason why the signedness of char is implementation-defined. There exists no symbol table of any kind that uses negative number indexing.
I think all of this originates from the incorrect, weird assumption that there are 8 bit integers and then there are "characters", where "characters" is some sort of magical mysterious thing.
This is just one of many irrational flaws the C standard, inherited from the days when dinosaurs walked the earth. The mysterious signedness of char adds nothing to the language, except perhaps a potential for signedness-related bugs caused by implicit integer promotions.
Likely they let char be signed because they wanted it to behave just as the other integer types: short, int, long, which are all guaranteed by the standard to alwasy be signed by default.
working with unsigned integers might be faster/more effective, or generate smaller code on some processors.
What type you end up with in the end isn't exactly intuitive. Whenever you use char as operand in an expression, it will always get promoted to int. Similarly, constant character literals 'a', '\n' etc are of type int, not char. The C language forces the compiler to promote the types according to the implicit promotion rules (known as "integer promotions" and "the usual arithmetic conversions"/"balancing").
Once that promotion is done, the compiler may optimize the type into the one that is most effective, if it can prove that the optimization doesn't change the result.
If you have this code:
char a = 'a';
char b = 'b';
char c = a + b;
there are many obscure things going on between the lines. First of all, the literals 'a' and 'b' get silently truncated from
int into signed/unsigned char. Then in the expression
a + b, both a and b are implicitly promoted by the integer promotion rules into
int types. The addition is performed on two
int. Then the result is silently truncated back into a signed/unsigned char.
If the compiler can prove that optimization does not affect any of the above obscurities, it may replace it all with sane, 8-bit operations.