Differential Histone Acetylation in Alfalfa (Medicago sativa) Due to Growth in NaCl : Responses in Salt Stressed and Salt Tolerant Callus Cultures

The steady state distribution of histone variant proteins and their modifications by acetylation were characterized in wild type and salinity stress adapted alfalfa (Medicago sativa). Isotopic labeling detected dynamic acetylation at four sites in the histone H3 variants and five sites in histones H4 and H2B. Histone variant H3.2 was the most highly acetylated histone with 25% higher steady state acetylation and a two- to threefold higher acetylation labeling than histone H3.1. Histone phosphorylation was limited to histone variants H1.A, H1.B, and H1.C and to histone H2A.3, which was also acetylated. Histone variant composition was unaffected by cellular exposure to NaCl. Histone acetylation was qualitatively similar in salt-tolerant and salt-sensitive cells under normal growth conditions. However, short term salt stress in salt sensitive cells or continued growth at 1% NaCl in salt tolerant cells led to major increases in the multiacetylated forms of histone H4 and the two variants of histone H3. These changes were more pronounced in the diploid than in the tetraploid alfalfa strains. The increase in multiacetylation of core histones serves as an in vivo reporter suggesting an altered intranuclear ionic environment in the presence of salt. It may also represent an adaptive response in chromatin structure to permit chromatin function in a more saline intranuclear environment.     

Phosphorylation of Plant H2A Histones

Phosphorylation of wheat (Triticum aestivum) and alfalfa (Medicago sativa) H2A histone variants was examined during early seedling growth. The C-terminal regions of wheat H2A variants contain multiple S-P tetrapeptides (serine-proline adjacent to a pair of basic amino acids) which resemble known phosphorylation sites in histones from other species. Phosphorylation of nucleosomal core histones was assessed by autoradiography of proteins labeled in vivo with ³²Pi and resolved by two-dimensional polyacrylamide gel electrophoresis, and phosphorylation sites were mapped by cleaving in vivo labeled H2A variants with N-bromosuccinimide. Essentially all phosphorylation of nucleosomal core histones in wheat and alfalfa seedlings occurred within the C-terminal peptides obtained from wheat and alfalfa H2A variants. A hypothesis accounting for the presence of large H2A and H2B histone variants in plants and phosphorylation of plant H2A C-terminal regions is proposed. The utility of S-P tetrapeptides for modulation of DNA-protein interactions is discussed.     

Dynamic histone acetylation in alfalfa cells. Butyrate interference with acetate labeling

Dynamic histone acetylation of alfalfa (Medicago sativa) was studied in suspension cultures by short-term labeling with radioactive acetate. The relative labeling rates for the acetylated histones were in order of decreasing incorporation; H3.2 greater than H3.1 greater than H4 greater than H2B.1 greater than H2A.3. Histone H3 showed at least seven sites of acetylation, histone H2B.1 had six sites and histone H4 had five sites. Low numbers of acetylation sites were observed for histone H2B.2 and all histone H2A variants. The mass ratio, steady state acetylation and dynamic acetylation between major variant H3.1 and minor variant H3.2 were approx. 2:1, 1:2 and 2:5, respectively. Treatment of alfalfa cells with 50 mM n-butyrate did not lead to histone hyperacetylation, but instead interfered with histone acetylation labeling by acetate. The extent of apparent inhibition increased with time and concentration of butyrate. It is likely that the conversion of butyrate to acetylCoA results in dilution of the specific radioactivity of [3H]acetate in the acetylCoA pool thereby inhibiting the labeling reaction. This interpretation is supported by 14C-labeling of alfalfa acetylated histones by [1-14C]butyrate.     

Histone variants and acetylated species from the alfalfa plant Medicago sativa

The histones from the alfalfa plant Medicago sativa have been characterized in terms of type variants and levels of acetylation. Histones were isolated directly from total plant tissue (callus), eliminating the need to develop methods for nuclear isolation. An acid-urea-polyacrylamide gel with a transverse Triton X-100 gradient resolved and identified in a single gel at least one type of histone H4, two variant forms of histone H2B, two variant forms of histone H3, and four variant forms of histone H2A from a crude histone preparation. Histone H4 was present 25% in an unmodified state and 75% as monomodified, presumably as monoacetylated histone. Both histone H3 variants displayed five bands, consistent with up to four internal sites of acetylation. The two H3 variants differed in their steady-state level of acetylation, suggesting that they may reside in different chromatin environments. Several histone H1 species were identified by solubility and cross-reactivity with antiserum raised against the globular part of bovine H1(0), indicating conservation of epitopes between histone H1 of mammals and higher plants.     

Salt Induces Expression of RH3.2A, Encoding an H3.2-type Histone H3 Protein in Rice (Oryza sativa L.)

Histone H3 is one of the four histones, along with H2A, H2B, and H4, which form the eukaryotic nucleosome octamer core. In this study, a new gene RH3.2A encoding an H3.2-type histone H3 protein from rice (Oryza sativa L.) was reported. RH3.2A was cloned through RT-PCR from salt-treated rice seedlings. This gene encoded a protein of 136 amino acid residues that were similar to some plant histone H3 proteins reported previously. However, the cDNA sequence of RH3.2A and other rice H3 genes were different. Alignment of RH3.2A encoding protein with other plant histone H3 proteins revealed that three amino acid residues (32, 88, and 91) were markedly different between H3.1-type and H3.2-type proteins. The mRNA expression analysis of RH3.2A revealed that RH3.2A gene was upregulated by salt stress in rice roots and ABA treatment in seedlings. The potential role of RH3.2A during salt stress was discussed.     

Histone variant H2B.Z acetylation is necessary for maintenance of Toxoplasma gondii biological fitness

Through regulation of DNA packaging, histone proteins are fundamental to a wide array of biological processes. A variety of post-translational modifications (PTMs), including acetylation, constitute a proposed histone code that is interpreted by “reader” proteins to modulate chromatin structure. Canonical histones can be replaced with variant versions that add an additional layer of regulatory complexity. The protozoan parasite Toxoplasma gondii is unique among eukaryotes in possessing a novel variant of H2B designated H2B.Z. The combination of PTMs and the use of histone variants are important for gene regulation in T. gondii, offering new targets for drug development. In this work, T. gondii parasites were generated in which the 5 N-terminal acetylatable lysines in H2B.Z were mutated to either alanine (c-Myc-A) or arginine (c-Myc-R). The c-Myc-A mutant displayed no phenotype over than a mild defect in its ability to kill mice. The c-Myc-R mutant presented an impaired ability to grow and an increase in differentiation to latent bradyzoites. The c-Myc-R mutant was also more sensitive to DNA damage, displayed no virulence in mice, and provided protective immunity against future infection. While nucleosome composition was unaltered, key genes were abnormally expressed during in vitro bradyzoite differentiation. Our results show that regulation of the N-terminal positive charge patch of H2B.Z is important for these processes. We also show that acetylated N-terminal H2B.Z interacts with some unique proteins compared to its unacetylated counterpart; the acetylated peptide pulled down proteins associated with chromosome maintenance/segregation and cell cycle, suggesting a link between H2B.Z acetylation status and mitosis.     

Phylogenomics of Unusual Histone H2A Variants in Bdelloid Rotifers

Rotifers of Class Bdelloidea are remarkable in having evolved for millions of years, apparently without males and meiosis. In addition, they are unusually resistant to desiccation and ionizing radiation and are able to repair hundreds of radiation-induced DNA double-strand breaks per genome with little effect on viability or reproduction. Because specific histone H2A variants are involved in DSB repair and certain meiotic processes in other eukaryotes, we investigated the histone H2A genes and proteins of two bdelloid species. Genomic libraries were built and probed to identify histone H2A genes in Adineta vaga and Philodina roseola, species representing two different bdelloid families. The expressed H2A proteins were visualized on SDS-PAGE gels and identified by tandem mass spectrometry. We find that neither the core histone H2A, present in nearly all other eukaryotes, nor the H2AX variant, a ubiquitous component of the eukaryotic DSB repair machinery, are present in bdelloid rotifers. Instead, they are replaced by unusual histone H2A variants of higher mass. In contrast, a species of rotifer belonging to the facultatively sexual, desiccation- and radiation-intolerant sister class of bdelloid rotifers, the monogononts, contains a canonical core histone H2A and appears to lack the bdelloid H2A variant genes. Applying phylogenetic tools, we demonstrate that the bdelloid-specific H2A variants arose as distinct lineages from canonical H2A separate from those leading to the H2AX and H2AZ variants. The replacement of core H2A and H2AX in bdelloid rotifers by previously uncharacterized H2A variants with extended carboxy-terminal tails is further evidence for evolutionary diversity within this class of histone H2A genes and may represent adaptation to unusual features specific to bdelloid rotifers.     

The Schizosaccharomyces pombe JmjC-Protein,Msc1, Prevents H2A.Z Localization in Centromeric and Subtelomeric Chromatin Domains

Eukaryotic genomes are repetitively packaged into chromatin by nucleosomes, however they are regulated by the differences between nucleosomes, which establish various chromatin states. Local chromatin cues direct the inheritance and propagation of chromatin status via self-reinforcing epigenetic mechanisms. Replication-independent histone exchange could potentially perturb chromatin status if histone exchange chaperones, such as Swr1C, loaded histone variants into wrong sites. Here we show that in Schizosaccharomyces pombe, like Saccharomyces cerevisiae, Swr1C is required for loading H2A.Z into specific sites, including the promoters of lowly expressed genes. However S. pombe Swr1C has an extra subunit, Msc1, which is a JumonjiC-domain protein of the Lid/Jarid1 family. Deletion of Msc1 did not disrupt the S. pombe Swr1C or its ability to bind and load H2A.Z into euchromatin, however H2A.Z was ectopically found in the inner centromere and in subtelomeric chromatin. Normally this subtelomeric region not only lacks H2A.Z but also shows uniformly lower levels of H3K4me2, H4K5, and K12 acetylation than euchromatin and disproportionately contains the most lowly expressed genes during vegetative growth, including many meiotic-specific genes. Genes within and adjacent to subtelomeric chromatin become overexpressed in the absence of either Msc1, Swr1, or paradoxically H2A.Z itself. We also show that H2A.Z is N-terminally acetylated before, and lysine acetylated after, loading into chromatin and that it physically associates with the Nap1 histone chaperone. However, we find a negative correlation between the genomic distributions of H2A.Z and Nap1/Hrp1/Hrp3, suggesting that the Nap1 chaperones remove H2A.Z from chromatin. These data describe H2A.Z action in S. pombe and identify a new mode of chromatin surveillance and maintenance based on negative regulation of histone variant misincorporation.     

Human spleen histone H1. Isolation and amino acid sequences of three minor variants, H1a, H1c, and H1d

Following the previous determination of the main variant H1b of human spleen histone H1, we have determined the complete amino acid sequence of another variant, H1d. Limited chymotryptic digestion of H1d produced four fragments, I to IV, and one partial fragment I-II, as in the case of H1b. These fragments were aligned with two overlapping peptides, produced by another enzyme from the intact H1d. We also confirmed the C-terminal sequence of H1d by carboxypeptidase digestion. This H1d has an acetylated N-terminal serine, equimolar alanine or valine residue at 17, and is composed of 212 residues. The molecular weight was 21,233 for the alanine variant and 21,261 for the valine variant in the unmodified form. We also deduced the total sequences of H1a and H1c in a similar way, considering the maximum homology with H1b and H1d. Each N-terminal serine residue is acetylated, too. H1a consists of 222 amino acid residues and has a molecular weight of 22,178 in its unmodified form; the H1c consists of 220 residues and has a molecular weight of 22,218 in that form. The human spleen H1 sequences varied to about the same extent in the N-terminal 40 and C-terminal 110 residues. However, the sequences of the about 70 internal residues are well conserved between the variants. The extent of differences among the human H1 variants is similar to, or rather smaller than, those among the mammalian somatic H1 species. The implications of these differences in the sequence for H1 function are discussed from the evolutionary viewpoint.     

Biochemical Characterization of Hpa2 and Hpa3, Two Small Closely Related Acetyltransferases from Saccharomyces cerevisiae

Based on their sequences, the Saccharomyces cerevisiae Hpa2 and Hpa3 proteins are annotated as two closely related members of the Gcn5 acetyltransferase family. Here, we describe the biochemical characterization of Hpa2 and Hpa3 as bona fide acetyltransferases with different substrate specificities. Mutational and MALDI-TOF analyses showed that Hpa3 translation initiates primarily from Met-19 rather than the annotated start site, Met-1, with a minor product starting at Met-27. When expressed in Escherichia coli and assayed in vitro, Hpa2 and Hpa3 (from Met-19) acetylated histones and polyamines. Whereas Hpa2 acetylated histones H3 and H4 (at H3 Lys-14, H4 Lys-5, and H4 Lys-12), Hpa3 acetylated only histone H4 (at Lys-8). Additionally, Hpa2, but not Hpa3, acetylated certain small basic proteins. Hpa3, but not Hpa2, has been reported to acetylate d-amino acids, and we present results consistent with that. Overexpression of Hpa2 or Hpa3 is toxic to yeast cells. However, their deletions do not show any standard phenotypic defects. These results suggest that Hpa2 and Hpa3 are similar but distinct acetyltransferases that might have overlapping roles with other known acetyltransferases in vivo in acetylating histones and other small proteins.     

Acetylation of rat testis histones H2B and TH2B

The in vivo acetylation of rat testis histones H3 and H4 has been demonstrated in previous studies. In this study, analysis of purified histone fractions revealed the in vivo acetylation of histone H2B, the testis histone variant designated TH2B, and two or more of the histone H2A variants. These findings are quite significant, because it is possible that all of the core histones are acetylated in elongating spermatids at the time of removal of the entire histone complement for replacement by basic spermatidal transition proteins (S.R. Grimes and N. Henderson, 1983, Arch. Biochem. Biophys. 221, 108-116).     

The rice histone methylation regulates hub species of the root microbiota

Plants have a close relationship with their root microbiota, which comprises a complex microbial network. Histone methylation is an important epigenetic modification influencing multiple plant traits; however, little is known about the role of plant histone methylation in the assembly and network structure of the root microbiota. In this study, we established that the rice (Oryza sativa) histone methylation regulates the structure and composition of the root microbiota, especially the hub species in the microbial network. DJ-jmj703 (defective in histone H3K4 demethylation) and ZH11-sdg714 (defective in H3K9 methylation) showed significant different root microbiota compared with the corresponding wild types at the phylum and family levels, with a consistent increase in the abundance of Betaproteobacteria and a decrease in the Firmicutes. In the root microbial network, 35 of 44 hub species in the top 10 modules in the tested field were regulated by at least one histone methylation-related gene. These observations establish that the rice histone methylation plays a pivotal role in regulating the assembly of the root microbiota, providing insights into the links between plant epigenetic regulation and root microbiota.     

The evolution of hemolytic saponin content in wild and cultivated Alfalfa (Medicago sativa,Fabaceae)

Hemolytic saponin content was determined of the leaves of 1213 plants of different variants ofMedicago sativa s.l. (including wild and cultivated alfalfa), and a close ally,M. papillosa. The latter species had a much higher content than any of the groups ofM. sativa. Medicago sativa ssp. caerulea, the most important ancestor of alfalfa, had a very low content of hemolytic saponins. The most primitive forms of cultivated alfalfa examined, from Turkey, and wildM. sativa ssp. sativa of Turkey, also both had very low contents of hemolytic saponins. This is consistent with, and likely explained by, a direct origin of the two Turkish groups from sympatricM. sativa ssp.caerulea. The second most important ancestor of alfalfa,M. sativa ssp.falcata, had the highest content of any of the examined groups ofM. sativa. Modern “Western” (European, NorthAmerican) cultivars and Western ruderal populations had intermediate levels of hemolytic saponins. This is consistent with, and likely explained by, their origin by hybridization and introgression between the low saponin groups noted above andM. sativa ssp.falcata.     

The role of arbuscular mycorrhizal fungi in alleviating salt stress in Medicago sativa L. var. icon

Medicago sativa L. is the most important forage crop in arid and semi-arid areas, where increased salinity is a major factor limiting plant growth and crop productivity. The role of arbuscular mycorrhizal (AM) fungus Glomus viscosum H.T. Nicolson strain A6 in protecting alfalfa plants from salt stress, induced by sodium chloride (NaCl), was studied in two ways. Firstly, the root systems of 3-month old M. sativa plants, both mycorrhizal (AM+) and non-mycorrhizal (non-AM) (M. sativa L. var. icon), were placed in solutions of increasing salt concentrations (0, 50, 100, 150, 200 mM NaCl) to study the wilting response. G. viscosum improved the tolerance to salinity stress and the benefit was expressed in terms of the time required to reach the T4 stage in the wilting experiment. Secondly, to evaluate the ability of the Glomus-alfalfa symbiosis to tolerate salt, a pot experiment was set up in a glasshouse in which 3-month old alfalfa plants (M. sativa var. icon) were grown in a peat substratum at three salinity levels (0, 100, 150 mM NaCl). The AM symbiosis stimulated plant height, leaf area, root density, fresh and dry plant weight under saline conditions. Furthermore, proline accumulation was higher in mycorrhizal M. sativa plants than in non-mycorrhizal plants under conditions of salt stress. These and other results indicated that the micropropagated selected clone of M. sativa var. icon, when in symbiosis with G. viscosum H.T. Nicolson strain A6, exhibited better growth and physiological activities under saline conditions than non-AM plants. The AM+ plants also had lower sodium and chloride concentrations in tissues than non-AM plants.     

Studies of the subtilin leader peptide as a translocation signal in Escherichia coli K12

In the protozoan Stylonychia lemnae 10 different histone H3 genes were discovered by polymerase chain reaction (PCR) amplification and sequence analysis. One of them is interrupted by a short intron sequence. These genes code for nine divergent histone H3 proteins. The genetic distances between some of these variants are very high. Most of the substitutions, as well as insertions/deletions, were found in the amino-terminal region. One variant shows an extremely elongated and altered N-terminus, which did not allow an unambiguous alignment with other histone H3 variants in this region. Hybridization experiments using the different H3 genes as probes indicate that even more histone H3 variants must exist in this species.