Transcription regulatory elements (TREs) have been extensively studied on the biochemical level with respect to their interactions with transcription factors (TFs), other DNA segments, and larger protein complexes. In this review, we describe concepts and preliminary experimental evidence for positional changes of TREs within a dynamic, functional nuclear architecture. We suggest a multilayered shell-like chromatin organization of chromatin domain clusters with increasing chromatin compaction levels from the periphery toward the interior with a decondensed transcriptionally active peripheral layer and compact repressed chromatin typically located in the interior. This model organization of nuclear architecture implies a differential accessibility of TFs to targets located in co-aligned active and inactive nuclear compartments (ANC and INC). It is based on evidence that active, easily accessible chromatin (perichromatin region, PR) lines a network of channels (interchromatin compartment, IC) involved in nuclear import-export functions. The IC and PR constitute the ANC, whereas transcriptionally noncompetent chromatin with higher compactness is part of the likely less accessible INC. Preliminary experimental evidence shows an enrichment of active TREs in the ANC and of inactive TREs in the INC suggesting positional changes of TREs between the ANC and INC depending on changes in their functional state.