The notations in the question are ambiguous (Bjørn Kjos-Hanssen showed that the other interpretation cannot be correct). I assume that the expression of interest is given by
$$
g(t) = \int_0^t \Sigma(s)\,dW(s)\;,
$$
where $W$ is a $C(\mathbb{R})$-valued Wiener process with covariance $c$ (at time $1$) and $\Sigma(s) \in C(\mathbb{R})^*$ is the finite measure given by $\Sigma(s) f = \int_{T_1}^{T_2}\sigma(s,u)f(u)\,du$. The natural thing here is to interpret $c$ as the bilinear map on $C(\mathbb{R})^*$ such that, for measure $\mu$ and $\nu$,
$$
c(\mu,\nu) = \int c(u,v)\, \mu(du)\,\nu(dv)\;.
$$
Itô isometry then indeed reads 
$$
\mathbb{E} g(t)^2 = \int_0^t \mathbb{E} c(\Sigma(s),\Sigma(s))\,ds \;,
$$
assuming of course that $\Sigma$ is adapted and square integrable.
Regarding references, any book on SPDEs would do, for example "Stochastic Equations in Infinite Dimensions" by Da Prato & Zabczyk or Section 3 of [my lecture notes][1].


  [1]: http://www.hairer.org/notes/SPDEs.pdf