Here is an interesting case study involving a directed and well-ordered index set.
Assume that the Continuum Hypothesis holds, i.e., $ 2^{\aleph_{0}} = \aleph_{1} $. As the cardinality of the closed interval $ [0,1] $ is $ 2^{\aleph_{0}} $, we can find a bijection $ \phi: \omega_{1} \to [0,1] $. Define a net $ (f_{\alpha}: [0,1] \to [0,1])_{\alpha < \omega_{1}} $ of Lebesgue-measurable functions by
$$
\forall \alpha < \omega_{1}, ~ \forall x \in [0,1]: \quad
{f_{\alpha}}(x) \stackrel{\text{def}}{=}
\begin{cases}
1 & \text{if $ x = \phi(\beta) $ for some $ \beta \leq_{\mathbf{On}} \alpha $}; \\
0 & \text{elsewhere}.
\end{cases}
$$
Consider an ordinal $ \alpha < \omega_{1} $. As $ \alpha $ is countable, it follows that $ f_{\alpha} $ assumes the value $ 1 $ for at most countably many arguments and the value $ 0 $ everywhere else. Hence, $ f_{\alpha} $ is Lebesgue measurable and is zero almost everywhere. We thus have
$$
\forall \alpha < \omega_{1}: \quad
\int_{[0,1]} f_{\alpha} ~ \mathrm{d}{\mu} = 0.
$$
However, we have $ \displaystyle \lim_{\alpha \to \omega_{1}} f_{\alpha} = 1_{[0,1]} $, which yields
\begin{align}
\lim_{\alpha \to \omega_{1}} \int_{[0,1]} f_{\alpha} ~ \mathrm{d}{\mu}
& = \lim_{\alpha \to \omega_{1}} 0 \\
& = 0 \\
& \neq 1 \\
& = \int_{[0,1]} 1_{[0,1]} ~ \mathrm{d}{\mu} \\
& = \int_{[0,1]}
\left( \lim_{\alpha \to \omega_{1}} f_{\alpha} \right)
\mathrm{d}{\mu}.
\end{align}
