$\newcommand{\R}{\mathbb R}\newcommand{\Z}{\mathbb Z}\newcommand{\de}{\delta}\newcommand{\al}{\alpha}$The answer is no. 

Indeed, take any $\al\in(0,1)$ and suppose that $d=1$,
\begin{equation*}
	f=\sum_{j\in\Z}(-1)^j\,1_{[j\de,(j+1)\de)} \tag{10}\label{10}
\end{equation*}
for some real $\de>0$, and $\ell$ is the standard normal density, Then all your conditions hold for some universal constant $c>0$. 

Take any $t\in(0,1)$ and note that 
\begin{equation*}
	I_t=\int_\R dz\,(1+|z|)H(z)\ell(z+hZ),
\end{equation*}
where 
\begin{equation*}
	H(z):=E|f(z+hZ)-f(z)|,\quad h:=\sqrt{2t}
\end{equation*}
and $Z\sim N(0,1)$. 
Let 
\begin{equation*}
	J_t:=\int_\R dz\,(1+|z|)H(z)\ell(z).
\end{equation*} 
Since $|f|=1$, we get 
\begin{equation*}
	|I_t-J_t|\le K_t:=2\int_\R dz\,(1+|z|)E|\ell(z+hZ)-\ell(z)|=2(K_{1,t}+K_{2,t}), 
\end{equation*}
where 
\begin{equation*}
	K_{1,t}:=\int_\R dz\,(1+|z|)E|\ell(z+hZ)-\ell(z)|\,1(h|Z|\le1+|z|/2),
\end{equation*}
\begin{equation*}
	K_{2,t}:=\int_\R dz\,(1+|z|)E|\ell(z+hZ)-\ell(z)|\,1(h|Z|>1+|z|/2). 
\end{equation*}
Next, 
\begin{equation*}
	K_{1,t}\le\int_\R dz\,(1+|z|)Eh|Z|m(z)=Ch,
\end{equation*}
where $m(z):=\max\{|\ell'(u)|\colon|u|\ge|z|/2-1\}$. Here and in what follows, $C$ denotes various positive universal constants, possibly different even within one expression. 
Next, 
\begin{equation*}
	K_{2,t}\le\int_\R dz\,(1+|z|)E1(h|Z|>1+|z|/2)\le C\sqrt h. 
\end{equation*}
So, 
\begin{equation*}
	|I_t-J_t|\le C\sqrt h, \tag{20}\label{20}
\end{equation*}

Next, for any real $z$ with $f(z)=-1$, 
\begin{equation*}
	H(z)\ge2\sum_{m\in\Z}P(z+hZ\in[2m\de,(2m+1)\de))\to1
\end{equation*}
uniformly in $z$; here and in what follows, $\de\downarrow0$; this holds because $P(Z-\de\in B)-P(Z\in B)\to0$ uniformly over all Borel subsets $B$ of $\R$.  
Using this, we similarly get 
\begin{equation*}
	J_t\ge\int_\R dz\,1(f(z)=-1)(1+|z|)(1-o(1))\ell(z)\to A:=\frac12\int_\R dz\,(1+|z|)\ell(z). 
\end{equation*}

So, by \eqref{20},
\begin{equation}
	I_t\ge A-o(1)-C\sqrt h>A/2
\end{equation}
eventually (that is, for all small enough $\de>0$) assuming that $t>0$ is small enough so that $C\sqrt h<A/3$. Assume also that $t>0$ is small enough so that $c_1 t^{\al/2}<A/2$. Then we get a contradiction with the desired inequality $I_t\le c_1 t^{\al/2}$. $\quad\Box$