Revision 4f87a2dc-8e22-4065-bfad-23e42c9bc750

$\newcommand\ep\epsilon\newcommand\de\delta\newcommand\1{\mathbf1}\newcommand\R{\mathbb R}\newcommand\U{\mathscr U}$I think that for **any probability distribution** $\mu$ over $\R$ there exists a subset $A$ of $\R^n$ of nonzero Lebesgue measure such that each one-dimensional marginal of the uniform distribution $\U_A$ over $A$ is **exactly** $\mu$. 

First, we may consider the case when $\mu$ has a smooth enough density $p$ (with respect to the Lebesgue measure over $\R$) vanishing at $\pm\infty$. Let the desired set $A$ be of the form
$$A=A^\de:=\{x\in\R^n\colon \|x-(x\cdot\1)\1/n\|\le\de(x\cdot\1)\},\tag1$$ 
where $\cdot$ is the dot product over $\R^n$, $\1:=(1,\dots,1)\in\R^n$, $\de$ is a positive function on $\R$ (which should be thought of as small enough), and $\|\cdot\|$ is a norm on $\R^n$ invariant with respect to all permutations of the coordinates. We want the function $\de$ to be such that 
$$|A^\de_u|=\ep p(u)\tag2$$
for some real $\ep>0$ (which should be thought of as small enough) and all $u\in\R$, where $|A^\de_u|$ is the Lebesgue measure of the $u$-"cross-section"
$$A^\de_u:=\{(u_2,\dots,u_n)\in\R^{n-1}\colon(u,u_2,\dots,u_n)\in A^\de\}$$
of $A^\de_u$. 

If we can find such a function $\de$, then clearly each one-dimensional marginal of the uniform distribution over $A^\de$ is **exactly** the distribution $\mu$ with density $p$. 

In the case $n=2$, we have 
$$A^\de=\{(u,v)\in\R^2\colon|u-v|\le c\de(u+v)\}\tag3$$
for some real $c>0$ depending on the choice of the norm $\|\cdot\|$ on $\R^2$ invariant with respect to the permutation of the two coordinates. 
In this case, (2) is equivalent to the functional equation 
$$g(u)-g^{-1}(u)=\ep p(u)\quad\forall u\in\R$$
for a function $g\colon\R\to\R$ such that $g(u)>u$ for all real $u$. So, the problem here is to solve this functional equation. 

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Below are images of Mathematica's work for the set $A^\de$ as in (3) with $c=1/2$ and $\de(t)\equiv\dfrac1{1 + (t - 2)^2}$. In this case, there are explicit expressions for $g(u)$ and $g^{-1}(u)$.

[![enter image description here][1]][1]
[![enter image description here][2]][2]


  [1]: https://i.sstatic.net/vXnjI.png
  [2]: https://i.sstatic.net/dsNnB.png