Similar questions are this one and this one.
The integral depends on the variable $z$ only, because $z'$ is a dummy variable. So you want to find the derivative of the integral and not its partial derivative. This is a special case of the following more general rule (Leibniz rule):
If $I(z)=J(u(z),v(z),z)=\int_{u(z)}^{v(z)} f(z,z')dz',\tag{1}$
i.e. $\ J(a,b,z)=\int_{a}^{b} f(z,z')dz',\qquad \text{ with }a=u(z),b=v(z),$
then, under suitable conditions, we have
$I^{\prime }(z)=\displaystyle\int_{u(z)}^{v(z)}\dfrac{\partial f(z,z')}{\partial z}dz'+f(z,v(z))v^{\prime }(z)-f(z,u(z))u^{\prime }(z).\tag{2}$
It is a consequence of
$\frac{dI}{dz}=\frac{\partial J}{\partial z}+\frac{\partial J}{\partial u} \frac{du}{dz}+\frac{\partial J}{\partial v}\frac{dv}{dz}.$
The first term is the differentiation under the integral sign
$\frac{\partial J}{\partial z}=\int_{u(z)}^{v(z)}\dfrac{\partial f(z,z')}{\partial z}dz'$ and the other two are a consequence of the Fundamental Theorem of Calculus:
$\frac{\partial J}{\partial v} =f(z,v(z)),\qquad\frac{\partial J}{\partial u} =-f(z,u(z)).$
In your case you want do find $\frac{d }{d z}\int_{-z_{0}}^{z}g(z,z')dz',$ where $g(z,z^{\prime })=(z-z^{\prime })f(z^{\prime }).$ Since the lower limit of integration is constant, we have two terms only
$\frac{d }{d z}\int_{-z_{0}}^{z}g(z,z^{\prime })dz'=\int_{-z_{0}}^{z}\frac{\partial g(z,z^{\prime })}{\partial z}dz^{\prime }+g(z,z)=\int_{-z_{0}}^{z}f(z')dz^{\prime },$
because $g(z,z)=0$ and $\frac{\partial g(z,z^{\prime })}{\partial z}=f(z').$