Up-regulation of stress-inducible genes in tobacco and <Emphasis Type="Italic">Arabidopsis</Emphasis> cells in response to abiotic stresses and ABA treatment correlates with dynamic changes in histone H3 and H4 modifications

Animal cells react to mitogenic or stress stimuli by rapid up-regulation of immediate-early (IE) genes and a parallel increase in characteristic modifications of core histones: chromatin changes, collectively termed the nucleosomal response. With regard to plants little is known about the accompanying changes at the chromatin level. We have used tobacco BY-2 and Arabidopsis T87 cell lines to study the nucleosomal response of plant cells to high salinity, cold and exogenous abscisic acid (ABA). When in quiescent stage, both tobacco and Arabidopsis cells show the typical nucleosomal response to high salinity and cold stress, manifested by rapid transient up-regulation of histone H3 Ser-10 phosphorylation, immediately followed by transient up-regulation of H3 phosphoacetylation and histone H4 acetylation. For each of the studied stresses the observed nucleosomal response was strictly correlated with the induction of stress-type specific genes. The dynamics of histone modifications in BY-2 cells in response to exogenous ABA exhibited a more complex pattern than that evoked by the two abiotic stresses, probably due to superposition of the primary and secondary effects of ABA. A rapid increase in H3 Ser-10 phosphorylation was also observed in whole leaves subjected to high salinity; however, the rate of change in this modification was much slower than in cultured cells. Together, these results indicate that the quiescent BY-2 and T87 cell lines show a typical nucleosomal response to abiotic stresses and ABA treatment and may represent suitable models for the study of chromatin-mediated mechanisms of stress tolerance in plants.     

Histone H4 acetylation and DNA methylation dynamics during pollen development

Summary The first pollen mitosis results in generative and vegetative cells which are characterised by a striking difference in their chromatin structure. In this study, histone H4 acetylation and DNA methylation have been analysed during pollen development inLilium longiflorum. Indirect immunofluorescence procedures followed by epifluorescence and laser scanning microscopy enabled a relative quantification of H4 acetylation and DNA methylation in microspores, immature binucleate pollen, mature pollen, and pollen tubes. The results show that histone H4 of the vegetative nucleus, in spite of its decondensed chromatin structure, is strongly hypoacetylated at lysine positions 5 and 8 in comparison with both the original microspore nucleus and the generative-cell nucleus. These H4 terminal lysines in the vegetative nucleus are, however, progressively acetylated during the following pollen tube growth. The DNA methylation analysis inversely correlates with the histone acetylation data. The vegetative nucleus in mature pollen grains is heavily methylated, but a dramatic nonreplicative demethylation occurs during the pollen tube development. Changes neither in H4 acetylation nor in DNA methylation have been found during development of the generative nucleus. The results obtained indicate that the vegetative nucleus enters the quiescent state (accompanied by DNA hypermethylation and H4 underacetylation) during the maturation of pollen grain which enables pollen grains a long-term survival without external source of nutrients until they reach the stigma.     

A glycolytic burst drives glucose induction of global histone acetylation by picNuA4 and SAGA

Little is known about what enzyme complexes or mechanisms control global lysine acetylation in the amino-terminal tails of the histones. Here, we show that glucose induces overall acetylation of H3 K9, 18, 27 and H4 K5, 8, 12 in quiescent yeast cells mainly by stimulating two KATs, Gcn5 and Esa1. Genetic and pharmacological perturbation of carbon metabolism, combined with ¹H-NMR metabolic profiling, revealed that glucose induction of KAT activity directly depends on increased glucose catabolism. Glucose-inducible Esa1 and Gcn5 activities predominantly reside in the picNuA4 and SAGA complexes, respectively, and act on chromatin by an untargeted mechanism. We conclude that direct metabolic regulation of globally acting KATs can be a potent driving force for reconfiguration of overall histone acetylation in response to a physiological cue.     

Developmentally regulated histone modifications in <Emphasis Type="Italic">Drosophila</Emphasis> follicle cells: initiation of gene amplification is associated with histone H3 and H4 hyperacetylation and H1 phosphorylation

We have used gene amplification in Drosophila follicle cells as a model of metazoan DNA replication to address whether changes in histone modifications are associated with replication origin activation. We observe that replication initiation is associated with distinct histone modifications. Acetylated lysines K5, K8, and K12 on histone H4 and K14 on histone H3 are specifically enriched during replication initiation at the amplification origins. Strikingly, H4 acetylation persists at an amplification origin well after replication forks have progressed significantly outward from the origin, indicating that H4 acetylation is associated with origin regulation and not histone deposition at the replication forks. Origin recognition complex subunit 2 (orc2) mutants with severe amplification defects do not abolish H4 acetylation, whereas the dup/cdt1 mutant delays the appearance of acetylation foci, and mutants in rbf result in temporal persistence. These data indicate that core histone acetylation is associated with origin activity. Furthermore, follicle cells undergoing gene amplification exhibit high levels of histone H1 phosphorylation. The patterns of H1 phosphorylation provide insights into cell cycle states during amplification, as H1 kinase activity in follicle cells is responsive to high Cyclin E activity, and it can be abolished by overexpressing the retinoblastoma homolog, Rbf, that represses Cyclin E. These data suggest that amplification origins are able to initiate when the cells are in a late S-phase, when the genome is normally not licensed for replication.