Let AC denote the axiom of choice. The proof of the implication AC $\implies$ (2) is somewhat nontrivial. Inasmuch as the equivalence AC $\iff$ (1) is quite trivial, it seems unlikely that any "direct" proof of the implication (1) $\implies$ (2) will be much simpler than (1) $\implies$ AC $\implies$ (2). The rest of this answer is devoted to exhibiting simple proofs of AC $\implies$ (1) and (1) $\implies$ AC.

**AC $\implies$ (1):** Let $G=(V,E)$ be a connected graph. Choose a vertex $v_0\in V.$ For each vertex $v\in V\setminus\{v_0\},$ choose a vertex $v'\in V$ so that $v'$ is adjacent to $v$ and $d(v',v_0)\lt d(v,v_0).$ The set of all edges $\{v',v\}$ is a spanning tree.

**(1) $\implies$ AC:** Let $A_i (i\in I)$ be a family of nonempty sets, and let $A=\bigcup_{i\in I}A_i.$ We may assume that $I\cap A=\emptyset.$ Consider the graph $G=(V,E)$ where $V=I\cup A$ and
$$E=\{\{u,v\}:u,v\in A,u\ne v\}\cup\{\{i,v\}:i\in I,v\in A_i\}.$$
Let $T$ be a spanning tree for this connected graph. Choose $a\in A.$ For each $i\in I$ the tree $T$ contains a unique path $P_i$ from $i$ to $a,$ and $P_i$ contains a unique edge $\{i,v_i\}$ where $v_i\in A_i.$ Now $i\mapsto v_i$ is a choice function for the family $A_i (i\in I).$