In relational theory, every table has at least one candidate key. Normally, you pick one of those keys to be the primary key, and the others become alternative keys. Candidate keys are crucial in normalization theory; primary keys per se are not.
Note, too, that the candidate keys are used to identify rows in the table. By specifying the table and a candidate key (column name(s) and value(s)), you can identify uniquely a single row in the table. This is the only guaranteed-to-work way of getting at single rows.
The SQL standard says nothing about indexes. It prescribes primary keys, and unique constraints, and foreign keys, but doesn't say that the DBMS must use indexes to enforce them.
Normally, a foreign key will cross-reference a primary key. It is, however, legitimate to have a foreign key reference any candidate key.
My favourite illustration of multiple candidate keys is 'The Table of Elements':
CREATE TABLE elements
atomic_number INTEGER NOT NULL PRIMARY KEY
CHECK (atomic_number > 0 AND atomic_number < 120),
symbol CHAR(3) NOT NULL UNIQUE,
name CHAR(20) NOT NULL UNIQUE,
atomic_weight DECIMAL(8,4) NOT NULL,
period SMALLINT NOT NULL
CHECK (period BETWEEN 1 AND 7),
group CHAR(2) NOT NULL
-- 'L' for Lanthanoids, 'A' for Actinoids
CHECK (group IN ('1', '2', 'L', 'A', '3', '4', '5', '6',
'7', '8', '9', '10', '11', '12', '13',
'14', '15', '16', '17', '18')),
stable CHAR(1) DEFAULT 'Y' NOT NULL
CHECK (stable IN ('Y', 'N'))
It has three plausible candidate keys — atomic number, symbol and name. The atomic weight actually is unique too, but that's not a good candidate key.
For the tables related to isotopes, the atomic number is the better key to reference. For the tables related to chemical formulae, the symbol is the better key to reference.
In practice, most DBMS require a unique index on the primary key to enforce uniqueness, and they'll typically use another index to enforce each of the unique constraints. For the most part, that's OK; the indexes make lookups on those columns faster.
In your table design, it isn't clear what the time stamps represent; I'm choosing to assume that they're simple examples of extra data rather than a part of the primary key.
I'm not entirely clear why you need two tables. However, assuming you do, each table has a primary key consisting of the 'followed ID' and the 'follower ID'. Further, each of these IDs is separately a foreign key referencing the 'person' table (which you've not mentioned by name).
Most DBMS will want a composite unique index on the two columns jointly to enforce the uniqueness (a given person can only follow another person once). You probably need one extra (duplicates) index to allow the second column to be referenced quickly. Depending on the DBMS, you may well need a second duplicates index on the first column, though some DBMS may be able to use the PK index for the FK on the first column. (You can use the leading columns of a composite index to speed lookups, even if you don't know the whole key. You can't use the trailing columns of an index. Thus, if you have a unique index on
(followed, follower) in that order, the index is usable to lookup up conditions based on just the
followed value as well as on combinations of
follower. The composite index cannot readily be used to lookup conditions based on just the
follower; you are virtually certain to need a separate index on that column.)