Whether or not quantum physics can account for molecular structure is a matter of considerable controversy. Three of the problems raised in this regard are the problems of molecular structure. We argue that these problems are just special cases of the measurement problem of quantum mechanics: insofar as the measurement problem is solved, the problems of molecular structure are resolved as well. In addition, we explore one consequence of our argument: that claims about the reduction or emergence of molecular structure cannot be settled independently of the choice of a particular resolution to the measurement problem. Specifically, we consider how three standard putative solutions to the measurement problem inform our understanding of a molecule in isolation, as well as of chemistry's relation to quantum physics. 1 Introduction 2 The Problems of Molecular Structure 2.1 Enantiomers and Hund's paradox 2.2 Isomers and the inability of resultant Hamiltonians to determine molecular structure 2.3 Symmetry breaking 3 The Measurement Problem 3.1 Enantiomers and Hund's paradox 3.2 Isomers and the inability of resultant Hamiltonians to determine molecular structure 3.3 Symmetry breaking 4 Interpretations of Quantum Mechanics: Implications for the Ontology of Chemistry 4.1 The Everett interpretation 4.2 De Broglie-Bohm theory 4.3 Spontaneous collapse theories 5 Conclusion * Authors listed in alphabetical order.