Partition the natural numbers into countably many sets, $\{S_i\}_{i=0}^\infty$, where each $S_i=\{n_{i_1},n_{i_2},\dots,\}$ is countably infinite. (There are many ways to do this) Since we have countably many mathematicians, we may list them, and assign $S_i$ to the $i^{th}$ mathematician.

If $u_k$ denotes the real number in the $k^{th}$ box, then the $i^{th}$ mathematician will be assigned the sequence of real numbers $u_{n_{i_j}}$, for $j=1,2,3\dots$. Using the axiom of choice, we may chose a representative for each equivalence class of sequences of real numbers under the equivalence relation $\{u_n\}_{n=1}^\infty\equiv\{v_n\}_{n=1}^\infty$ if there exists $M>0$ such that $v_n=u_n$ for all $n>M$. Thus, for the $i^{th}$ mathematician there will exist an integer $M_i$ such that for all $j>M_i$, the sequence $u_{n_{i_j}}$ is equal to the representative of its equivalence class. The goal is to have mathematician $i$ guess an integer $H_i>M_i$ by looking at every box except those in the set $S_i$. If this happens, then mathematician $i$ may look at all of the elements of $u_{n_{i_j}}$ with $j\geq H_i+1$, determine the equivalence class, and guess the box with $j=H_i+1$. Since $H_i>M_i$, his guess will be correct. It follows that we need all but possibly one mathematician to guess an integer $H_i>M_i$. If the sequence $M_i$ is bounded, then the problem is easy. The difficulty is handling an unbounded sequence $M_i$. 

Under the same system of representatives, the sequence $\{M_i\}_{i=0}^\infty$ lies in some equivalence class of real numbers. Since mathematician $i$ knows the value of $M_l$ for all $l\neq i$, each mathematician can determine which equivalence class of the sequence $\{M_i\}_{i=0}^\infty$. Let $\{v_i\}_{i=0}^\infty$ denote the representative of this equivalence class. Then there exists an integer $N$ such that for every $i>N$, $M_i=v_i$. Mathematician $i$ with $i\leq N$ can determine $N$, however each mathematician with $i>N$ only knows that $N\leq i$.  The strategy for guessing is as follows: Assign to mathematician $i$ with $i>N$ the integer $$H_i=1+\max\{v_i,M_{i-1},M_{i-2},\dots,M_1,M_0\},$$ and to each mathematician with $i\leq N$ integer $$H_i=1+\max\{M_{N},M_{N-1},\dots,M_{i+1},M_{i-1},\dots,M_1,M_0\}.$$ Then we must have $H_i>M_i$ for every mathematician except possibly one. Thus we have given a strategy which allows every mathematician except possibly one to guess one of the boxes correctly.