Deciphering the Enigma of the Histone H2A.Z-1/H2A.Z-2 Isoforms: Novel Insights and Remaining Questions.

The replication independent (RI) histone H2A.Z is one of the more extensively studied variant members of the core histone H2A family, which consists of many replication dependent (RD) members. The protein has been shown to be indispensable for survival, and involved in multiple roles from DNA damage to chromosome segregation, replication, and transcription. However, its functional involvement in gene expression is controversial. Moreover, the variant in several groups of metazoan organisms consists of two main isoforms (H2A.Z-1 and H2A.Z-2) that differ in a few (3-6) amino acids. They comprise the main topic of this review, starting from the events that led to their identification, what is currently known about them, followed by further experimental, structural, and functional insight into their roles. Despite their structural differences, a direct correlation to their functional variability remains enigmatic. As all of this is being elucidated, it appears that a strong functional involvement of isoform variability may be connected to development.

Protein identification using sequential ion/ion reactions and tandem mass spectrometry.

A method for rapid sequencing of intact proteins simultaneously from the N and C termini (1-2 s) with online chromatography is described and applied to the characterization of histone H3.1 posttranslational modifications and the identification of an additional member of the H2A gene family. Proteins are converted to gas-phase multiply charged positive ions by electrospray ionization and then allowed to react with fluoranthene radical anions. Electron transfer to the multiply charged protein promotes random dissociation of the N-Calpha bonds of the protein backbone. Multiply charged fragment ions are then deprotonated in a second ion/ion reaction with the carboxylate anion of benzoic acid. The m/z values for the resulting singly and doubly charged ions are used to read a sequence of 15-40 aa at both the N and C termini of the protein. This information, with the measured mass of the intact protein, is used to search protein or nucleotide databases for possible matches, detect posttranslational modifications, and determine possible splice variants.