Added: FiniteA's answer is the right one for this problem (the OP needs to put the problem in standard form, with a basic feasible solution, first, and then the difficulty goes away). I'm going to leave my answer up, though, for those who want to see what it means in general when there is no leaving variable.
Original answer: You've determined that
$x3$ is the entering variable, and you're looking for a variable to leave the basis. The
$-1$ in column
$x3$, row
$x1$, means that each unit increase in the value of
$x3$ causes
$x1$ to increase by one unit. The
$0$ in column
$x3$, row
$x1$, means that each unit increase in the value of
$x3$ has no effect on the value of
$x2$. So letting
$x3$ enter the basis doesn't force
$x1$ or
$x2$ ever to be negative (and thus infeasible). Therefore, you can increase
$x3$ indefinitely without causing the current solution to go infeasible. Since each unit increase in the value of
$x3$ causes the objective function value to drop by
$2$ units, you can make the objective function go to
$-\infty$ by continually increasing
$x3$.
In other words, your problem is unbounded. In general, the inability to find a leaving variable, as here, means that the problem is unbounded.