This question requires a refinement of Eulerian numbers. Namely, let $A_{n,k,\ell}$ be the number of permutations of order $n$ with $k$ descents and ending in element $\ell$. Under subtracting each element of a permutation from $n+1$, we get a property $A_{n,k,\ell}=A_{n,n-1-k,n+1-\ell}$. Similarly, denoting by $A'_{n,k,\ell}$ the number of permutations of order $n$ with $k$ descents and starting with element $\ell$, we have $A'_{n,k,\ell} = A_{n,n-1-k,\ell}$ (by reading permutations backwards).

Then an answer to the question can be given by the following formula:
$$\sum_{j=0}^t \sum_{\ell=1}^n \sum_{f=\ell+1}^n \sum_{u+v+w=s-1} \binom{\ell-1}u\binom{f-\ell-1}v\binom{n-f}w A_{s,j,u+1} A'_{n-s,k-j,f-1-u-v}$$
$$+\sum_{j=0}^t \sum_{\ell=1}^n \sum_{f=1}^{\ell-1} \sum_{u+v+w=s-1} \binom{f-1}u\binom{\ell-f-1}v\binom{n-\ell}w A_{s,j,u+v+1} A'_{n-s,k-j,f-u},$$
where $\ell$ stands for $\sigma_s$, $f$ stands for $\sigma_{s+1}$, and $u,v,v$ is the number of elements of $\sigma_1,\dots,\sigma_{s-1}$ from the subintervals of $[1,n]$ obtained by removal of $\ell$ and $f$.
As explained above, we have
$$A'_{n-s,k-j,f-1-u-v} = A_{n-s,n-s-1-(k-j),f-1-u-v} = A_{n-s,k-j,n+1-f-w}$$
and
$$A'_{n-s,k-j,f-u} = A_{n-s,n-s-1-(k-j),f-u} = A_{n-s,k-j,n-s+1-f+u}.$$
So, it now amounts to having a formula for $A_{n,k,\ell}$.

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First, we have a recurrence formula for $n\geq\ell>1$:
$$A_{n,k,\ell} = A_{n,k,\ell-1} + A_{n-1,k,\ell-1} - A_{n-1,k-1,\ell-1},$$
which translated into a linear first-order ODE:
$$(1-z)\frac{\partial}{\partial x} F(x,y,z) = z(1-y)F(x,y,z) + yz\frac{y-1}{y - e^{(y-1)x}} - z^2 \frac{y-1}{y - e^{(y-1)xz}}$$
for the generating function:
$$F(x,y,z) := \sum_{n,k,\ell\geq 0} A_{n,k,\ell}\frac{x^n}{n!} y^k z^\ell.$$
From its solution, we obtain the following formula:
$$A_{n,k,\ell} = \begin{cases}
\left\langle n\atop k\right\rangle & \text{if }\ell=n\\
(-1)^{n+k} \sum\limits_{j=1}^n (-1)^j j^{n-\ell} (j-1)^{\ell-1} \bigg( \binom{n}{k+j} + (-1)^{k-1}\binom{n}j\bigg) & \text{if }\ell < n.
\end{cases}
$$