Catalogue of Tetra-Stranded Helical Architectures: Classes, Topological Invariants, and Structural Transitions
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Barack Ndenga
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Abstract
The structural space of nucleic acids is commonly explored through local conformational variants of duplex DNA. However, if a tetra-stranded hereditary polymer such as Q-DNA is considered as a canonical genome-scale state, topology becomes a primary organizing principle rather than a secondary constraint. In this work, I develop a topological classification framework for tetra-stranded helices, introducing a catalogue of admissiblearchitectures defined by strand number, chirality, winding modes, and inter-strand entanglement. I define generalized topological invariants—including multi-strand linking numbers and generalized supercoiling—and analyze their conservation and transformation across structural transitions. I then formalize Q↔D transitions, describing how a tetra-stranded canonical state may interconvert with duplex-dominant states under controlled topological operations. The result is an atlas of tetra-strandedarchitectures and a conceptual phase diagram of topological regimes, providing a foundation for subsequent energetic, kinetic, and evolutionary analyses of Q-DNA.
Keywords: tetra-stranded helices, DNA topology, linking number, supercoiling, genome architecture, Q-DNA, non-canonical nucleic acids.
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This work presents a systematic topological classification of tetra-stranded helical architectures relevant to a canonical four-stranded hereditary polymer (Q-DNA). Rather than treating multistranded DNA conformations as local motifs, this manuscript explores genome-scale tetra-stranded architectures as topological objects, focusing on strand arrangement, chirality, inter-strand entanglement, and admissible structural transitions.
The study introduces generalized topological invariants for tetra-stranded systems, including multi-strand linking matrices and extensions of classical supercoiling concepts beyond duplex DNA. It further analyzes structural transitions between tetra-stranded (Q) and duplex-dominant (D) states, identifying allowed, forbidden, and strand-passage–dependent pathways. The resulting framework yields an atlas of tetra-stranded architectures and a conceptual topological phase diagram that maps regimes of duplex dominance, canonical Q-DNA stability, and topologically protected or kinetically trapped states.
This contribution provides a foundational topological language for evaluating the physical realizability, replicability, and evolvability of tetra-stranded genetic systems, with implications for synthetic genetics, molecular biophysics, and alternative genetic architectures in origins-of-life and astrobiology research.
Resource type: theoretical manuscript / conceptual framework
Intended audience: DNA topology, theoretical biology, synthetic genetics, and genome architecture communities
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