Effect of the antioxidant ionol on proteolytic apparatus of aging coleoptiles of wheat seedlings grown in light

The dynamics of changes in total proteolytic activity and activities of various groups of proteases in the coleoptiles of 3- to 12-day-old wheat seedlings grown in light with and without antioxidant BHT (2,6-di-tert-butyl-4-methylphenol) was studied. It was established that the specialized proteases that easily hydrolyze specific synthetic substrates and the enzymes actively hydrolyzing histone H1 dominate in young coleoptiles of 3- to 4-day-old seedlings. Proteases that degrade equally well the majority of the studied substrates are accumulated in the cells of old coleoptiles of 11- to 12-day-old seedlings. Under the effect of BHT, the plants grown in light (in comparison with etiolated seedlings) demonstrated a somewhat changed dynamics of proteolytic activity in young coleoptiles and the disappearance of proteases active toward histone H1. An inhibitory analysis revealed a relative domination of cysteine proteases in young coleoptiles at the initial development stage of seedlings, whereas the fraction of serine proteases markedly increased in old coleoptiles. We presume that the revealed quantitative and qualitative changes in the proteolytic apparatus of the coleoptile cells induced by BHT may be largely responsible for the retardant and geroprotective effect of this antioxidant in plants.     

Effect of Antioxidant BHT on the Proteolytic Apparatus of Aging Coleoptiles of Wheat Seedlings Grown in Light

The dynamics of changes in total proteolytic activity and activities of various groups of proteases in the coleoptiles of 3- to 12-day-old wheat seedlings grown in light with and without antioxidant BHT (2,6-di-tert-butyl-4-methylphenol) was studied. It was established that the specialized proteases that easily hydrolyze specific synthetic substrates and the enzymes actively hydrolyzing histone H1 dominate in young coleoptiles of 3- to 4-day-old seedlings. Proteases that degrade equally well the majority of the studied substrates are accumulated in the cells of old coleoptiles of 11- to 12-day-old seedlings. Under the effect of BHT, the plants grown in the light (in comparison with etiolated seedlings) demonstrated a somewhat changed dynamics of proteolytic activity in young coleoptiles and the disappearance of proteases active toward histone H1. An inhibitory analysis revealed a relative domination of cysteine proteases in young coleoptiles at the initial development stage of seedlings, whereas the fraction of serine proteases markedly increased in old coleoptiles. We presume that the revealed quantitative and qualitative changes in the proteolytic apparatus of the coleoptile cells induced by BHT may be largely responsible for the retardant and geroprotective effect of this antioxidant in plants.     

Modulation of action of wheat seedling endonucleases WEN1 and WEN2 by histones

Wheat core histones and various subfractions of histone H1 modulate differently the action of endonucleases WEN1 and WEN2 from wheat seedlings. The character of this modulation depends on the nature of the histone and the methylation status of the substrate DNA. The modulation of enzyme action occurs at different stages of processive DNA hydrolysis and is accompanied by changes in the site specificity of the enzyme action. It seems that endonuclease WEN1 prefers to bind with protein-free DNA stretches in histone H1-DNA complex. The endonuclease WEN1 does not compete with histone H1/6 for DNA binding sites, but it does compete with histone H1/1, probably for binding with methylated sites of DNA. Unlike histone H1, the core histone H2b binds with endonuclease WEN1 and significantly increases its action. This is associated with changes in the site specificity of the enzyme action that is manifested by a significant increase in the amount of low molecular weight oligonucleotides and mononucleotides produced as a result of hydrolysis of DNA fragments with 120–140-bp length. The WEN2 endonuclease binds with histone-DNA complexes only through histones. The action of WEN2 is increased or decreased depending on the nature of the histone. Histone H1/1 stimulated the exonuclease activity of WEN2. It is supposed that endonucleases WEN1 and WEN2, in addition to the catalytic domain, should have a regulatory domain that is involved in binding of histones. As histone H1 is mainly located in the linker chromatin areas, it is suggested that WEN2 should attack DNA just in the chromatin linker zones. As differentiated from WEN2, DNA hydrolysis with endonuclease WEN1 is increased in the presence of core histones and, in particular, of H2b. Endonuclease WEN1 initially attacks different DNA sites in chromatin than WEN2. Endonuclease WEN2 activity can be increased or diminished depending on presence of histone H1 subfractions. It seems that just different fractions of the histone H1 are responsible for regulation of the stepwise DNA degradation by endonuclease WEN2 during apoptosis. Modulation of the action of the endonucleases by histones can play a significant role in the epigenetic regulation of various genetic processes and functional activity of genes.     

The involvement of histone H1[0] in chromatin structure.

Micrococcal nuclease digestion and light scattering are used to compare native chromatins with various histone H1[0] contents. The experimental data show that the higher the H1[0] content, the greater the ability to form compact structures with increasing ionic strength, and the lower the DNA accessibility to micrococcal nuclease. On the contrary, reconstituted samples from H1-depleted chromatin and pure individual H1 fractions behave in such a way that samples reconstituted with pure H1 degree give rise to a looser structure, more accessible to nuclease than samples reconstituted with H1-1. This contradiction suggests that the effect of H1o on chromatin structure must originate from the interaction of this histone with other components in native chromatin among which other histone H1 subfractions are good candidates.     

The distribution of histone H1 subfractions in chromatin subunits.

Rat liver chromatin was digested with micrococcal nuclease to various extents and fractionated into nucleosomes, di and trimers of nucleosomes on an isokinetic sucrose gradient. In conditions under which degradation of linker DNA within the particles was limited, the electrophoretic analysis of the histone content showed that the overall content of H1 histone increased from nucleosomes to higher order oligomers. Moreover, the histone H1 subfractions were found unevenly distributed among the chromatin subunits, one of them, H1--3 showing most variation. A more regular distribution of these subfractions was found in subunits obtained from a more extended digestion level of chromatin. It is suggested that the H1 subfractions differ in the protection they confer upon DNA.     

Superproduction of heavy minicircular mitochondrial DNA in aging wheat coleoptiles.

On incubation of 7-day-old wheat seedlings in the presence of [3H]thymidine, the radioactivity incorporated into coleoptile DNA is found to be localized mainly (greater than 95%) in the fraction of heavy mitochondrial DNA (H-mt DNA; rho = 1.716 gm/cm3). Upon long (48-72 h) incubation of cut-off seedlings in water, the amount of this DNA shows a dramatic increase and corresponds to about 10% of the total coleoptile DNA. H-mtDNA is represented by open circular molecules with a contour length varying from 0.12 to 0.6 microns. The functional role of this DNA is still unknown.     

Changes in Composition of Acid Soluble Proteins and DNA in Chromatin of Rat Liver and Brain Bound and Not Bound to Nuclear Envelope as a Function of Age and under the Influence of Antioxidant Ionol

In two-day rat pups, the histone H1 content in the brain chromatin was higher than in the liver chromatin, as compared to histone of the nucleosome core. The H1 content in the brain chromatin decreased with the age, while in the liver chromatin it increased. At the same time, in the adult brain chromatin bound to the nuclear envelope, a high level of H1 characteristic of chromatin of the newborn rats was preserved, while in a similar chromatin of the adult liver, the H1 content increased, but still remained less than in the chromatin not bound to the nuclear envelope. In both organs, the composition and quantitation of H1 subfractions were different in chromatins bound and not bound to the nuclear envelope. The chromatin from the liver and brain bound to the nuclear envelope differed also in the composition and quantitation of minor acid soluble proteins. In the presence of the antioxidant ionol, the 5-methylcytosine content in DNA of chromatin of the rat liver bound to the nuclear envelope increased while in the chromatin not bound to the nuclear envelope, it remained unchanged. Thus the chromatins bound and not bound to the nuclear envelope differ in the composition and mount of acid soluble proteins, including histone H1, the contents of these proteins in bound and not bound chromatin are different and change with the age in different ways. The antioxidant ionol affects differently the methylation of bound and not bound chromatin.     

Changes in composition of acid soluble proteins and DNA in chromatin of rat liver and brain bound and not bound to nuclear envelope as a function of age and under the influence of antioxidant ionol

In two-day rat pups, the histone H1 content in the brain chromatin was higher than in the liver chromatin, as compared to histone of the nucleosome core. The H1 content in the brain chromatin decreased with the age, while in the liver chromatin it increased. At the same time, in the adult brain chromatin bound to the nuclear envelope, a high level of H1 characteristic of chromatin of the newborn rats was preserved, while in a similar chromatin of the adult liver, the H1 content increased, but still remained less than in the chromatin not bound to the nuclear envelope. In both organs, the composition and quantitation of H1 subfractions were different in chromatins bound and not bound to the nuclear envelope. The chromatin from the liver and brain bound to the nuclear envelope differed also in the composition and quantitation of minor acid soluble proteins. In the presence of the antioxidant ionol, the 5-methylcytosine content in DNA of chromatin of the rat liver bound to the nuclear envelope increased while in the chromatin not bound to the nuclear envelope, it remained unchanged. Thus the chromatins bound and not bound to the nuclear envelope differ in the composition and mount of acid soluble proteins, including histone H1, the contents of these proteins in bound and not bound chromatin are different and change with the age in different ways. The antioxidant ionol affects differently the methylation of bound and not bound chromatin.     

Histone gene expression and chromatin structure in mammalian cell hybrids

DNA isolated from mammalian cell nuclear reveals discrete size patterns when partially digested with micrococcal nuclease. The DNA repeat lengths from different tissues within a species or from different species may vary. These differences have been attributed to the presence of different species of histone H1. To examine the nature of regulation of DNA repeat lengths and their possible relationship to histone H1, we have selected several mouse and human cell lines that differ in their DNA repeat lengths and examined them and their cell hybrids. 24 mouse X human and five mouse X mouse hybrid cell lines were analyzed. All the interspecific hybrids exhibited the repeat pattern characteristic of the murine parent. The mouse intraspecific hybrids had a repeat pattern of only one of the parents. We conclude that the partial human chromosome complements retained in the hybrids assume the repeat lengths exhibited by the mouse cells. Because H1 histones have been implicated in the determination of DNA repeat lengths, we also investigated the regulation of H1 histone expression in these cell hybrids. Purified H1 histones were radioactively labeled in vitro, and individual subfractions were subjected to proteolysis followed by gel electrophoresis. The resulting partial peptide maps off H1 histone subfractions A and B were distinguishable from one another and from different cell lines. In the mouse X human hybrids analyzed, only the mouse H1 histones were detected. These observations were extended to H2b by analysis of the hybrid cell histone by Triton-acid-urea gels. Neither the DNA repeat length nor histone expression is affected by the presence of any specific human chromosome. The fact that human genes are expressed in these hybrids suggests that the H1 histones of one species is able to interact with the chromatin of another species in a biologically funtional conformation. Analysis of the intraspecific PG19 X B82 (mouse X mouse) hybrids reveals the presence of H1 histone subfractions of the B82 mouse cells. Because these hybrids exhibit the nucleosome repeat length only of the PG19 cells, it appears that if histone H1 plays a role in determining the repeat length it does so in consort with other nonhistone chromosomal proteins.     

Necessity of Superoxide Production for Development of Etiolated Wheat Seedlings

It was found that production of superoxide (O₂ ^{– ·}) is crucial for normal morphogenesis of etiolated wheat seedlings in the early stages of plant development. The development of etiolated wheat seedlings was shown to be accompanied with cyclic changes in the rate of O₂ ^{– ·} production both in the entire intact seedling and in its separated organs (leaf, coleoptile). First increase in the rate of O₂ ^{– ·} production was clearly observed in the period from two to four days of seedling development, then the rate of O₂ ^{– ·} production decreased to the initial level, and then it increased again for two days to a new maximum. An increase in O₂ ^{– ·} production in the period of the first four days of seedling development correlates with an increase in DNA and protein contents in the coleoptile. The second peak of increased rate of O₂ ^{– ·} production observed on the sixth or seventh day of seedling development coincides with a decrease in DNA and protein contents and apoptotic internucleosomal nuclear DNA fragmentation in the coleoptile. Incubation of seedlings in the presence of the antioxidant BHT (ionol) strongly affects their development but it does not influence the increase in DNA and protein contents for the initial four days of seedling life, and it slows down the subsequent age-dependent decrease in protein content and fully prevents the age-dependent decrease in DNA content in the coleoptile. A decrease in the O₂ ^{– ·} amount induced by BHT distorts the seedling development. BHT retards seedling growth, presumably by suppression of cell elongation, and it increases the life span of the coleoptile. It seems that O₂ ^{– ·} controls plant growth by cell elongation at the early stages of seedling development but later O₂ ^{– ·} controls (induces) apoptotic DNA fragmentation and protein disintegration.     

Histone H2A subfractions and their phosphorylation in cultured Peromyscus cells

Patterns of histone phosphorylation and histone H2A subfractionation have been compared in cultured cell lines from two species of deer mice, Peromyscus eremicus and Peromyscus boylii, which differ considerably in their content of heterochromatin but which contain essentially the same euchromatin content. DNA measurements by flow microfluorometry indicated that P. eremicus cells contained 34.2% more DNA than P. boylii cells, and C-band chromosome analysis indicated that the extra DNA in P. eremicus was present as constitutive heterochromatin. Subfraction of histone H2A by acid-urea polyacrylamide preparative gel electrophoresis in the presence of non-ionic detergent showed that each cell line contained two H2A subfractions. Incorporation of ³²PO₄ into these histones indicated that the steady state phosphorylation of the two H2A subfractions was not the same, the more hydrophobic H2A being greater than two times more phosphorylated than the less hydrophobic H2A in both cell lines. A comparison of the two cell lines indicated that the cell line with 34.2% greater constitutive heterochromatin contained a similar excess (29%) in its ratio of the more highly phosphorylated, more hydrophobic H2A subfraction to the less hydrophobic H2A subfraction. It is suggested that this enrichment of the more highly phosphorylated, more hydrophobic H2A subfraction may be related to the amount of constitutive heterochromatin present in the genome.     

The Effects of Phytohormones and 5-Azacytidine on Apoptosis in Etiolated Wheat Seedlings

The development of etiolated wheat (Triticum aestivum L.) seedlings is necessarily accompanied by apoptosis in their coleoptiles and first leaves. Internucleosome DNA fragmentation, which is characteristic of apoptosis, was detected in the coleoptile as soon as six days after germination. After eight days of germination, DNA fragmentation was clearly expressed in the coleoptile and was noticeable in the apical part of the first-leaf blade. Growing of intact seedlings or incubation of their shoots in the presence of such phytohormones as benzyladenine, gibberellin A₃, fusicoccin C, and 2,4-D at the concentration of 10^–5 M did not essentially affect DNA fragmentation in the coleoptile. As distinct from antioxidants, none of the phytohormones used prevented apoptosis in wheat seedlings. In contrast, ABA (10^–5 M) and an ethylene producer, ethrel (2-chloroethylphosphonic acid, 10^–2–10^–3 M), stimulated sharply DNA fragmentation in the coleoptile. An inhibitor of DNA methylation, 5-azacytidine, was very efficient in the stimulation of DNA fragmentation in the coleoptiles of eight-day-old seedlings at its concentration of 100 g/ml. Thus, some phytohormones can regulate apoptosis, and DNA methylation is involved in this process. Our results indicate that apoptosis activation by some phytohormones may be mediated by their regulation of DNA methylation/demethylation, which is responsible for the induction of genes encoding apoptogenic proteins and/or the repression of antiapoptotic genes.     

Does high-mobility-group non-histone protein HMG 1 interact specifically with histone H1 subfractions?

The interaction of the non-histone chromosomal protein HMG (high-mobility group) 1 with histone H1 subfractions was investigated by equilibrium sedimentation and n.m.r. sectroscopy. In contrast with a previous report [Smerdon & Isenberg (1976) Biochemistry 15, 4242--4247], it was found, by using equilibrium-sedimentation analysis, that protein HMG 1 binds to all three histone H1 subfractions CTL1, CTL2, and CTL3, arguing against there being a specific interaction between protein HMG 1 and only two of the subfractions, CTL1 and CTL2. Raising the ionic strength of the solutions prevents binding of protein HMG 1 to total histone H1 and the three subfractions, suggesting that the binding in vitro is simply a non-specific ionic interaction between acidic regions of the non-histone protein and the basic regions of the histone. Protein HMG 1 binds to histone H5 also, supporting this view. The above conclusions are supported by n.m.r. studies of protein HMG 1/histone H1 subfraction mixtures. When the two proteins were mixed, there was little perturbation of the n.m.r. spectra and there was no evidence for specific interaction of protein HMG 1 with any of the subfractions. It therefore remains an open question as to whether protein HMG 1 and histone H1 are complexed together in chromatin.     

The structural organization and DNA sequence of a wheat histone H4 gene.

Some wheat histone H4 genes have been cloned from a Charon 4 wheat genomic DNA library using sea urchin histone H4 DNA as a probe. DNA sequence analysis of a cloned gene showed that the deduced amino acid sequence of wheat histone H4 protein was identical to that of pea. The 5' end of wheat histone H4 mRNA was mapped on the cloned gene by the S1-procedure. Southern blotting analysis of the genomic DNA indicated that histone H4 genes were reiterated 100 to 125 times per hexaploid wheat genome.     

The structural role of histone H1: properties of reconstituted chromatin with various H1 subfractions (H1-1, H1-2, and H1o).

A previous study on the distribution of histone H1 subfractions in chromatin suggested that these proteins differ in the protection they confer to DNA. To elucidate further this suggestion, reconstitution experiments were carried out with purified H1 subfractions (H1-1, H1-2, H1o) and H1-depleted chromatin. We have studied the structural properties of H1o as compared to those of other H1 fractions by electrophoretic analysis of DNA and mononucleosomes obtained after micrococcal nuclease digestion, thermal denaturation, and electron microscopy. The three fractions studied reassociate to H1-depleted chromatin. However, differences in the extent of DNA protection are observed between H1o and the other fractions: H1o induces a more rapid degradation of long oligomers into mononucleosomes; these mononucleosomes bearing H1o only, have a greater electrophoretic mobility; furthermore, thermal denaturation shows that a small fraction of DNA is less efficiently protected by H1o than by the other fractions. Electron microscopy, on the other hand, shows that these differences are not due to areas of chromatin devoid of H1o in the reconstitute and that the reconstituted samples are able, under proper ionic conditions, to refold in a higher-order structure.