Abstract

BackgroundDuring mitosis, chromatin engages in a dynamic cycle of condensation and decondensation. Condensation into distinct units to ensure high fidelity segregation is followed by rapid and reproducible decondensation to produce functional daughter cells. Factors contributing to the reproducibility of chromatin structure between cell generations are not well understood. We investigated local metaphase chromosome condensation along mitotic chromosomes within genomic intervals showing differential accessibility (DA) between homologs. DA was originally identified using short sequence-defined single copy (sc) DNA probes of < 5 kb in length by fluorescence in situ hybridization (scFISH) in peripheral lymphocytes. These structural differences between metaphase homologs are non-random, stable, and heritable epigenetic marks which have led to the proposed function of DA as a marker of chromatin memory. Here, we characterize the organization of DA intervals into chromosomal domains by identifying multiple DA loci in close proximity to each other and examine the conservation of DA between tissues.ResultsWe evaluated multiple adjacent scFISH probes at 6 different DA loci from chromosomal regions 2p23, 3p24, 12p12, 15q22, 15q24 and 20q13 within peripheral blood T-lymphocytes. DA was organized within domains that extend beyond the defined boundaries of individual scFISH probes. Based on hybridizations of 2 to 4 scFISH probes per domain, domains ranged in length from 16.0 kb to 129.6 kb. Transcriptionally inert chromosomal DA regions in T-lymphocytes also demonstrated conservation of DA in bone marrow and fibroblast cells.ConclusionsWe identified novel chromosomal regions with allelic differences in metaphase chromosome accessibility and demonstrated that these accessibility differences appear to be aggregated into contiguous domains extending beyond individual scFISH probes. These domains are encompassed by previously established topologically associated domain (TAD) boundaries. DA appears to be a conserved feature of human metaphase chromosomes across different stages of lymphocyte differentiation and germ cell origin, consistent with its proposed role in maintenance of intergenerational cellular chromosome memory.

Highlights

  • During mitosis, chromatin engages in a dynamic cycle of condensation and decondensation

  • Differential hybridization patterns for single copy probes confirmed on normal human metaphase chromosomes by scFISH The genome distributions of differential accessibility (DA) intervals and their extent were addressed by fluorescence in situ hybridization (FISH) hybridization of multiple sc probes (1459–3553 bp) to 7 different chromosomal targets across 5 autosomes

  • It includes 19 probes, 18 scFISH probes with DA developed in this study and a previously developed 1p36 control probe with equivalent accessibility [EA] [14, 17], their chromosomal locations, and genome coordinates

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Summary

Introduction

Chromatin engages in a dynamic cycle of condensation and decondensation. DA was originally identified using short sequence-defined single copy (sc) DNA probes of < 5 kb in length by fluorescence in situ hybridization (scFISH) in peripheral lymphocytes These structural differences between metaphase homologs are non-random, stable, and heritable epigenetic marks which have led to the proposed function of DA as a marker of chromatin memory. Despite constant changes in function and morphology within the cell cycle and during differentiation, new generations of cells are able to accurately re-establish cell (or functional) programming consistent with that of parent cells [6, 7]. The understanding of this mechanism remains incomplete. Identification and characterization of mechanisms of mitotic memory and bookmarking are ongoing with both tissue dependent and independent mechanisms proposed [9,10,11,12,13]

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