Larry L. Deaven

A highly conserved repetitive DNA sequence, (TTAGGG)n, has been isolated from a human recombinant repetitive DNA library. Quantitative hybridization to chromosomes sorted by flow cytometry indicates that comparable amounts of this sequence are present on each human chromosome. Both fluorescent in situ hybridization and BAL-31 nuclease digestion experiments reveal major clusters of this sequence at the telomeres of all human chromosomes. The evolutionary conservation of this DNA sequence, its terminal chromosomal location in a variety of higher eukaryotes (regardless of chromosome number or chromosome length), and its similarity to functional telomeres isolated from lower eukaryotes suggest that this sequence is a functional human telomere.

Histone phosphorylation and chromatin structure were examined in synchronized CHO Chinese hamster cells during progression through mitosis. Cell population distribution in various phases of mitosis was determined by electron microscopy. Entry into mitosis was seen to occur in two stages: (1) the gathering of chromatin into aggregates of dense chromatin clumps during preprophase, followed by (2) the condensation of these aggregates into chromosome structures during prophase. Exit from mitosis was observed essentially as the reverse process, chromosomes first being disorganized into dense chromatin clumps during telophase, followed by dispersion of these aggregates in early G 1 . Correlating these structural changes with histone phosphorylation revealed that interphase‐type histone H1 phosphorylation (H1 I ) involving 1–3 phosphates per molecule existed in interphase and during the chromatin aggregation stages of mitosis (preprophase and telophase). Also, no histone H3 phosphorylation occurred during these periods of the cell cycle. It is proposed that H1 I phosphorylation may be involved with the submicroscopic changes in chromatin organization observed during interphase using molecular probes of chromatin structure. However, during mitosis, histone phosphorylation was correlated with microscopic chromatin structural changes. During the second stage of mitosis (prophase, metaphase, and anaphase), when chromosome structures were fully condensed, virtually all histone H1 existed as superphosphorylated molecules (H1 M ) containing 3–6 phosphates, and all histone H3 molecules were phosphorylated. Exit of cells from anaphase correlated closely with the dephosphorylation of H3 to unphosphorylated H3 and with the dephosphorylation of H1 M to subphosphorylated H1 containing 0–3 phosphates. Further dephosphorylation of subphosphorylated H1 I to unphosphorylated H1 occurred as these cells left telophase and entered G 1 . These experiments demonstrated that H1 M superphosphorylation and H3 phosphorylation are strictly mitotic events which occur only when chromosomes are fully condensed. The absence of Colcemid in some of these experiments eliminates the possibility that H1 M and H3 phosphorylations are artifacts of the Colcemid treatment. It is proposed that histones H1 and H3 may impose a restriction on chromatin structure which prevents chromosome condensation during interphase and that the H1 M and H3 phosphorylations remove this restriction during mitosis.