Meet Inspiring Speakers and Experts at our 3000+ Global Conference Series Events with over 1000+ Conferences, 1000+ Symposiums
and 1000+ Workshops on Medical, Pharma, Engineering, Science, Technology and Business.

Explore and learn more about Conference Series : World's leading Event Organizer

Back

Henry M. Sobell

Henry M. Sobell

University of Rochester, USA

Title: The centers of premeltons signal the beginning and ends of genes

Biography

Biography: Henry M. Sobell

Abstract

Premeltons are examples of emergent structures (i.e., structural solitons) that  arise  spontaneously  in  DNA  due  to  the  presence  of  nonlinear excitations  in  its  structure.     They  are  of  two  kinds:  B-B  (or  A-A) premeltons  form at specific DNA-regions  to nucleate  site-specific DNA melting.    These  are  stationary  and,  being  globally  nontopological, undergo breather motions that allow drugs and dyes to intercalate into DNA.    B-A  (or  A-B)  premeltons,  on  the  other  hand,  are  mobile,  and being  globally  topological,  act  as  phase-boundaries  transforming  B- into  A-  DNA  during  the  structural  phase-transition.     They  are  not expected to undergo breather-motions.  A key feature of both types of premeltons  is  the  presence  of  an  intermediate  structural-form  in  their central  regions  (proposed  as  being  a  transition-state  intermediate  in DNA-melting and in the B- to A- transition), which differs from either A- or B- DNA. Called beta-DNA, this is both metastable and hyperflexible and   contains   an   alternating   sugar-puckering   pattern   along   the polymer-backbone  combined  with  the  partial-unstacking  (in  its  lower energy-forms)  of  every  other  base-pair.    Beta-DNA  is  connected  to either  B-  or  to  A-  DNA  on  either  side  by  boundaries  possessing  a gradation  of  nonlinear  structural-change,  these  being  called  the  kink and the antikink regions.   The presence of premeltons in DNA leads to a  unifying  theory  to  understand  much  of  DNA  physical-chemistry  and molecular-biology.   In  particular,  premeltons  are  predicted  to  define the  5’  and  3’  ends  of  genes  in  naked-DNA  and  DNA  in  active- chromatin, this having important implications for understanding physical aspects  of  the  initiation,  elongation  and  termination  of  RNA-synthesis during transcription.   For these and other reasons, the model will be of broader interest to the general audience  working in these areas.   The model explains a wide variety of data, and carries within it a number of   experimental   predictions   –   all   readily   testable   –   as   will   be described in my talk.