Iodination of Xenopus laevis histone F2a1 in chromatin.

The reaction of calf thymus and Xenopus laevis histones with radioactive iodine has been studied under various conditions that affect chromatin structure. All histones from both species contain at least one tyrosine residue and, in a denaturing solvent, all the the histones react with iodine. Histone F2a1 has been studied in detail. Calf thymus F2a1 is known to contain four tyrosyls and all four react with iodine. In high voltage paper electrophoresis, the tyrosine-containing peptides from calf co-migrate with those from Xenopus F2a1, suggesting that the amino acid sequence is strongly conserved between these two species. Therefore, the published calf thymus F2a1 sequence has been used to order the Xenopus F2a1 peptides within the molecules. When gently isolated native chromatin is iodinated in a low ionic strength medium 60% of the radioactivity in F2a1 is in tyrosyl 88, 30% in tyrosyl 51, and tyrosyl 72 and 98 have almost no radioactivity. Reagents which remove the protein from the DNA (2 M NaCl) or partially disrupt protein tertiary structure (5 M urea) increase the reactivity of each of the four tyrosyls five- to tenfold, suggesting that all four are protected about equally by the overall folding of the chromatin. Isolated F2a1 iodinated in the presence of 10 M urea shows uniform labeling in each of the four peptides, suggesting that tyrosyl 72 and 98 are afforded some protection solely by protein-protein interactions. The stepwise removal of histones in increasing NaCl concentrations differentially increases the availability of each F2a1 tyrosyl. The preferential exposure of tyrosyl 88 coincides with the removal of the majority of F1 histones at 0.5 M NaCl while the gradual and stepwise increase in reactivity of tyrosyl 51, 72, and 98 correlates with the gradual removal of histones other than F1. Radioactive iodination of chromatin has been shown to be a sensitive probe for detecting changes in the association state (or conformation) of histone F2a1.