Quantification of DNA Patchiness Using Long-Range Correlation Measures

G. M. Viswanathan^*, S. V. Buldyrev^*, S. Havlin^*^# and H. E. Stanley^*

Center for Polymer Studies and Department of Physics, Boston University, Boston, Massachusetts 02215 USA
Gonda-Goldschmied Center and Department of Physics, Bar Ilan University, Ramat Gan, Israel

ABSTRACT

We introduce and develop new techniques to quantify DNA patchiness,and to quantify characteristics of its mosaic structure. Thesetechniques, which involve calculating two functions, ${alpha}$ (l) andß(l), measure correlations at length scale l and detectdistinct characteristic patch sizes embedded in scale-invariantpatch size distributions. Using these new methods, we addressa number of issues relating to the mosaic structure of genomicDNA. We find several distinct characteristic patch sizes incertain genomic sequences, and compare, contrast, and quantifythe correlation properties of different sequences, includinga number of yeast, human, and prokaryotic sequences. We excludethe possibility that the correlation properties and the knownmosaic structure of DNA can be explained either by simple Markovprocesses or by tandem repeats of dinucleotides. We find thatthe distinct patch sizes in all 16 yeast chromosomes are similar.Furthermore, we test the hypothesis that, for yeast, patchinessis caused by the alternation of coding and noncoding regions,and the hypothesis that in human sequences patchiness is relatedto repetitive sequences. We find that, by themselves, neitherthe alternation of coding and noncoding regions, nor repetitivesequences, can fully explain the long-range correlation propertiesof DNA.