The possible values are $1,2,3,4,5$.
Clearly $\Pr(X=1)=\dfrac{4}{52}$.
To have $X=2$, we need first card non-Ace, second card Ace. Thus $\Pr(X=2)=\dfrac{48}{52}\cdot\dfrac{4}{52}$. This is because of the hypothesis of replacement.
Similarly, $\Pr(X=3)=\left(\dfrac{48}{52}\right)^2\cdot\dfrac{4}{52}$.
Similarly, $\Pr(X=4)=\left(\dfrac{48}{52}\right)^3\cdot\dfrac{4}{52}$.
For $X=5$, the situation is a little different, since we don't care about the fifth card. So $\Pr(X=5)=\left(\dfrac{48}{52}\right)^4$ (four "failures" in a row)
Now expectation is a routine calculation. It is $\sum_{i=1}^5 i\Pr(X=i)$.
Remark: In most card games, we do not have replacement. (By replacement I assume you meant replacement and shuffling, not replacement on top of the deck!)
Without replacement, the probabilities would be a little different. For example, for $X=3$ we would have $\frac{48}{52}\frac{47}{51}\frac{4}{50}$.
If you prefer to use counting, let us calculate for example the probability that $X=4$. There are $52^4$ sequences of $4$ cards, all equally likely. Exactly $(48)(48)(48)(4)$ of them consist of $3$ non-Aces followed by an Ace. So $\Pr(X=4)=\frac{(48)^3(4)}{52^4}$. Earlier, we obtained the same answer in a somewhat different way.