Your first option with an explicit join between the two tables on explicit fields is the better option to choose for a number of reasons.
The second option is still effectively a join even if you don't use the JOIN keyword as it's an implied join. This means that your database engine will effectively perform it's own join between your table list.
In MySQL, this implied join is a CROSS JOIN which in MySQL is equivalent to an INNER JOIN, however, be aware that a CROSS JOIN is NOT equivalent to an INNER JOIN in "standard" SQL, so whilst your second query may well work if constructed correctly with the correct where filtering, it's ambiguous.
As a result, your second query (with the implied join) can effectively produce a Cartesian product between the two tables (where effectively every row from one table is combined with every row from another table). You'll almost certainly NOT want this and it's one way to destroy the performance of a SQL query, especially if at least one of the tables contains quite a few rows! Even if your filter clauses (i.e. your WHERE clauses) can correctly filter out the rows you don't want to only return the correct result set, it'll be less efficient than explicitly defining your own explicit joins (Even though most database engines will attempt to optimize such implied queries). Your first query uses an explicit LEFT JOIN and so a Cartesian product shouldn't be possible (assuming you are joining on "sensible" fields - from your question it seems the table relationship is "sensible").
Also, be aware that the precedence of simply implying joins between tables by listing tables with a comma separator is lower than actual explicit JOIN statements (at least since MySQL v5.x) This can lead to incorrect query results, especially in the case of join between 3 or more tables where, again, ambiguity in the query expression makes it difficult to determine precedence, and thus the exact same query can produce entirely different results between database versions. See this link for more information.
The best source of information for the various JOIN types in MySQL is the MySQL documentation itself, and the page specifically relating to joins can be found here:
188.8.131.52. JOIN Syntax (MySql v5)
184.108.40.206. JOIN Syntax (MySql v6)
Just for speed, I've quoted the most pertinent sections below:
INNER JOIN and , (comma) are semantically equivalent in the absence of a join condition: both produce a Cartesian product between the specified tables (that is, each and every row in the first table is joined to each and every row in the second table).
However, the precedence of the comma operator is less than of INNER JOIN, CROSS JOIN, LEFT JOIN, and so on. If you mix comma joins with the other join types when there is a join condition, an error of the form Unknown column 'col_name' in 'on clause' may occur.
The evaluation of multi-way natural joins differs in a very important way that affects the result of NATURAL or USING joins and that can require query rewriting. Suppose that you have three tables t1(a,b), t2(c,b), and t3(a,c) that each have one row: t1(1,2), t2(10,2), and t3(7,10). Suppose also that you have this NATURAL JOIN on the three tables:
SELECT ... FROM t1 NATURAL JOIN t2 NATURAL JOIN t3;
Previously, the left operand of the second join was considered to be t2, whereas it should be the nested join (t1 NATURAL JOIN t2). As a result, the columns of t3 are checked for common columns only in t2, and, if t3 has common columns with t1, these columns are not used as equi-join columns. Thus, previously, the preceding query was transformed to the following equi-join:
SELECT ... FROM t1, t2, t3
WHERE t1.b = t2.b AND t2.c = t3.c;
That join is missing one more equi-join predicate (t1.a = t3.a). As a result, it produces one row, not the empty result that it should. The correct equivalent query is this:
SELECT ... FROM t1, t2, t3
WHERE t1.b = t2.b AND t2.c = t3.c AND t1.a = t3.a;
If you require the same query result in current versions of MySQL as in older versions, rewrite the natural join as the first equi-join.
Previously, the comma operator (,) and JOIN both had the same precedence, so the join expression t1, t2 JOIN t3 was interpreted as ((t1, t2) JOIN t3). Now JOIN has higher precedence, so the expression is interpreted as (t1, (t2 JOIN t3)). This change affects statements that use an ON clause, because that clause can refer only to columns in the operands of the join, and the change in precedence changes interpretation of what those operands are.
CREATE TABLE t1 (i1 INT, j1 INT);
CREATE TABLE t2 (i2 INT, j2 INT);
CREATE TABLE t3 (i3 INT, j3 INT);
INSERT INTO t1 VALUES(1,1);
INSERT INTO t2 VALUES(1,1);
INSERT INTO t3 VALUES(1,1);
SELECT * FROM t1, t2 JOIN t3 ON (t1.i1 = t3.i3);
Previously, the SELECT was legal due to the implicit grouping of t1,t2 as (t1,t2). Now the JOIN takes precedence, so the operands for the ON clause are t2 and t3. Because t1.i1 is not a column in either of the operands, the result is an Unknown column 't1.i1' in 'on clause' error. To allow the join to be processed, group the first two tables explicitly with parentheses so that the operands for the ON clause are (t1,t2) and t3:
SELECT * FROM (t1, t2) JOIN t3 ON (t1.i1 = t3.i3);
Alternatively, avoid the use of the comma operator and use JOIN instead:
SELECT * FROM t1 JOIN t2 JOIN t3 ON (t1.i1 = t3.i3);
This change also applies to statements that mix the comma operator with INNER JOIN, CROSS JOIN, LEFT JOIN, and RIGHT JOIN, all of which now have higher precedence than the comma operator.