Cdc2 protein kinase is complexed with both cyclin A and B: evidence for proteolytic inactivation of MPF

In the clam, Spisula, two previously described proteins known as cyclin A and B display the unusual property of selective proteolytic degradation at the end of each mitosis. We show here that clam oocytes and embryos contain a cdc2 protein kinase. This protein kinase is a component of the M phase promoting factor (MPF) in frog eggs and the M phase-specific histone H1 kinase in starfish. Clam cdc2 is found in association with both cyclin A and B, probably not as a trimolecular association, but as separate cdc2/cyclin A and cdc2/cyclin B complexes. Clam cdc2 and the associated cyclins bind to p13suc1-Sepharose. The p13-bound complex, and also anti-cyclin A or B immunoprecipitates, each display cell cycle-dependent histone H1 kinase activity. We suggest that in addition to the cdc2 protein kinase, the cyclins are further components of the M phase promoting factor and that cyclin proteolysis provides the mechanism of MPF inactivation and thus exit from mitosis.     

Accessibility and structural role of histone domains in chromatin. biophysical and immunochemical studies of progressive digestion with immobilized proteases

The accessibility and role of histone regions in chromatin fibres were investigated using limited proteolysis with enzymes covalently bound to collagen membranes. The changes in chromatin conformation and condensation monitored by various biophysical methods, were correlated to the degradation of the histone proteins revealed by antibodies specific for histones and histone peptides. Upon digestion with trypsin and subtilisin, chromatin undergoes successive structural transitions. The cleavage of the C-terminal domains of H1, H2A and H2B, and of the N-terminal tail of H3 led to a decondensation of chromatin fibres, indicated by increases in electric birefringence and orientational relaxation times. It corresponds to a 15% increase in linear dimensions. The degradation of the other terminal regions of histones H3, H2A and H2B resulted in the appearance of hinge points between nucleosomes without alteration of the overall orientation of polynucleosome chains. Despite the loss of all the basic domains of H1, H3, H2A and H2B, no significant change in DNA-protein interactions occurred, suggesting that most of these protease-accessible regions interact weakly, if at all, with DNA in chromatin. Further proteolysis led to H4 degradation and other additional cleavages of H1, H2B and H3. This caused the relaxation of no more than 8% of the total DNA but resulted in changes in the ability of chromatin to condense at high ionic strength. More extensive digestion resulted in a total unravelling of nucleosomal chains which acquired properties similar to those of H1-depleted chromatin, although the globular part of H1 was still present. The data suggest that histone-histone interactions between H1 and core histone domains play a central role in stabilizing the chromatin fibres, and cuts in H3, H2A and H2B as well as H1, seem necessary for chromatin expansion. On the contrary, H4 might be involved in the stabilization of nucleosomes only.     

Proteinase activity of nuclei from various tissues towards endogenous histones]

The proteinase activities of nuclei isolated from tissues differing in their mitotic activities (brain, thymus, liver, ascite lymphoma) towards the histones and non-histone acid -- extractable proteins were studied. The sensitivity of different histone fractions to nuclear proteinase depends on temperature and time of nuclei incubation under conditions providing for complete dissociation of chromatin proteins from DNA (2 M NaCl--5 M urea). The proteinase activity in the brain and thymus nuclei is revealed only under prolonged (43 hrs) incubation of the nuclei at 25 degrees C, which is accompanied by partial proteolysis of histone H1. Histone H4 from brain nuclei and histone H2a from thymus nuclei are preferably degraded. In the nuclei isolated from the mice ascite cell lymphoma NK/ly and from rat liver the enzyme activity is revealed mainly towards the arginine-enriched histones H3 and H4. The proteolysis of the arginine-enriched histones in tumour cell nuclei is more complete. A high sensitivity to proteolysis was observed for non-histone acid-extractable proteins with low electrophoretic mobility, which were found in brain and tumour cell nuclei.     

CUL4-DDB1 ubiquitin ligase interacts with multiple WD40-repeat proteins and regulates histone methylation

The CUL4-DDB1-ROC1 ubiquitin E3 ligase regulates cell-cycle progression, replication and DNA damage response. However, the substrate-specific adaptors of this ligase remain uncharacterized. Here, we show that CUL4-DDB1 complexes interact with multiple WD40-repeat proteins (WDRs) including TLE1-3, WDR5, L2DTL (also known as CDT2) and the Polycomb-group protein EED (also known as ESC). WDR5 and EED are core components of histone methylation complexes that are essential for histone H3 methylation and epigenetic control at K4 or K9 and K27, respectively, whereas L2DTL regulates CDT1 proteolysis after DNA damage through CUL4-DDB1 (ref. 8). We found that CUL4A-DDB1 interacts with H3 methylated mononucleosomes and peptides. Inactivation of either CUL4 or DDB1 impairs these histone modifications. However, loss of WDR5 specifically affects histone H3 methylation at K4 but not CDT1 degradation, whereas inactivation of L2DTL prevents CDT1 degradation but not histone methylation. Our studies suggest that CUL4-DDB1 ligases use WDR proteins as molecular adaptors for substrate recognition, and modulate multiple biological processes through ubiquitin-dependent proteolysis.     

Accessibility and Structural Role of Histone Domains in Chromatin. Biophysical and Immunochemical Studies of Progressive Digestion with Immobilized Proteases

Abstract

The accessibility and role of histone regions in chromatin fibres were investigated using limited proteolysis with enzymes covalently bound to collagen membranes. The changes in chromatin conformation and condensation monitored by various biophysical methods, were correlated to the degradation of the histone proteins revealed by antibodies specific for histones and histone peptides.

Upon digestion with trypsin and subtilisin, chromatin undergoes successive structural transitions. The cleavage of the C-terminal domains of Hl, H2A and H2B, and of the N-terminal tail of H3 led to a decondensation of chromatin fibres, indicated by increases in electric birefringence and orientational relaxation times. It corresponds to a 15% increase in linear dimensions. The degradation of the other terminal regions of histones H3, H2A and H2B resulted in the appearance of hinge points between nucleosomes without alteration of the overall orientation of polynucleosome chains. Despite the loss of all the basic domains of HI, H3, H2A and H2B, no significant change in DNA-protein interactions occurred, suggesting that most of these protease-accessible regions interact weakly, if at all, with DNA in chromatin. Further proteolysis led to H4 degradation and other additional cleavages of Hl, H2B and H3. This caused the relaxation of no more than 8% of the total DNA but resulted in changes in the ability of chromatin to condense at high ionic strength. More extensive digestion resulted in a total unravelling of nucleosomal chains which acquired properties similar to those of Hl- depleted chromatin, although the globular part of HI was still present.

The data suggest that histone-histone interactions between HI and core histone domains play a central role in stabilizing the chromatin fibres, and cuts in H3, H2A and H2B as well as HI, seem necessary for chromatin expansion. On the contrary, H4 might be involved in the stabilization of nucleosomes only.     

Cyclin B2/cyclin-dependent kinase1 dissociation precedes CDK1 Thr-161 dephosphorylation upon M-phase promoting factor inactivation in Xenopus laevis cell-free extract

Cyclin-dependent kinase 1 (CDK1) is the enzymatic subunit of M-phase Promoting Factor (MPF). It is positively regulated by phosphorylation on Thr-161 and association with a cyclin B molecule. The role of Thr-161 dephosphorylation upon MPF inactivation remains unclear; nevertheless, degradation of cyclin B is thought to be a direct cause of MPF inactivation. However, MPF inactivation actually precedes cyclin B degradation in Xenopus cell-free extracts. Here we study in details the temporal relationship between histone H1 kinase (reflecting MPF activity) inactivation, Thr-161 dephosphorylation, CDK1-cyclin B2 dissociation and cyclin B2 proteolysis in such extracts. We show an asynchrony between inactivation of histone H1 kinase and degradation of cyclin B2. CDK1 dephosphorylation on Thr 161 is an even later event than cyclin B2 degradation, reinforcing the hypothesis that cyclin B dissociation from CDK1 is the key event inactivating MPF. Cyclins synthesized along with MPF inactivation could deliver shortly living active MPF molecules, potentially increasing the asynchrony between histone H1 kinase inactivation and cyclin B2 degradation. We confirm this by showing that in the absence of protein synthesis, such a tendency is lower, but nevertheless, still detectable. Finally, to characterise better CDK1/cyclin B dissociation, we show that CDK1 begins to dissociate from cyclin B2 before the very beginning of cyclin B2 degradation and that the diminution in CDK1-associated cyclin B2 is faster than the decline of its total pool. Thus, neither cyclin B2 degradation nor Thr-161 dephosphorylation participates directly in CDK1 inactivation as measured by histone H1 kinase decline upon the exit from mitotic M-phase in Xenopus embryo extract.     

Basal c-Jun N-terminal kinases promote mitotic progression through histone H3 phosphorylation

Phosphorylation of histone H3 at serine 10 (S10) is essential for the onset of mitosis. Here, we show that basal c-Jun N-terminal kinases (JNKs) are required for mitotic histone H3 S10 phosphorylation in human primary fibroblast IMR90 cells. Inhibition of JNKs by specific pharmacologic inhibitors, expression of dominant-negative JNK1 and 2 mutants, or RNAi of JNK1 and 2 prevented phosphorylation of histone H3 at S10 in vivo. The JNK-specific inhibitor SP600125 blocked mitotic entry, as shown by its ability to prevent CDK1 dephosphorylation and cyclin A degradation. Basal JNK phosphorylation increased at G2/M-phase, although total JNK protein levels remained unchanged. In addition, basal JNKs were localized in nuclei and centrosomes during this time, suggesting that the nuclear localization of JNKs during G2/M is tightly coupled with histone H3 phosphorylation. Basal JNKs were able to phosphorylate histone H3 in vitro and co-precipitation of histone H3 and JNKs was only detected at G2/M. Taken together, these data strongly suggest that basal JNKs play a key role in controlling histone H3 phosphorylation for mitotic entry at G2/M-phase.     

Inhibition of nuclear histone proteolysis by nucleotides]

Effects of nucleotides on the proteolysis of histones in nuclei incubated at 37 degrees C during 1, 3 and 20 h were studied. It has been shown that the H1 histone is removed first during proteolysis and then the H3 and H2B histones are digested. The H4 histone is not cleaved even after 20 h incubation. PMSF and ATP inhibit the H1 cleavage when its structure was not disturbed before ATP, CTP, ADP, NAD+, AMP and NADH inhibit the partial cleavage of the core histones H3 and H2B. ATP, CTP, AMP and NADH prevent the total digestion of H2B. ATP and, at lower extent, CTP prevent the H3 digestion. ATP, CTP, ADP and NAD+ inhibit the cleavage of the H2A histone in the experiments with 20 h incubation, when H4 is only resistant in the absence of nucleotides. The data obtained suggest an important role of ATP and other nucleotides in maintaining the structure of histones and chromatin.     

Specific degradation of histones H1 and H3

It is shown that acid treated histones H1 and H3 are susceptible to specific degradation by an associated acid resistant protease. Dialysis against distilled water (pH 5.5–6) of the acid treated histones enhances proteolysis. On the other hand, no degradation is observed in nucleohistone either in the presence of Ca⁺⁺ or Na⁺⁺ ions. The conditions required to avoid degradation during nucleohistone and histone manipulation are described.     

An E3 ubiquitin ligase prevents ectopic localization of the centromeric histone H3 variant via the centromere targeting domain

Proper centromere function is critical to maintain genomic stability and to prevent aneuploidy, a hallmark of tumors and birth defects. A conserved feature of all eukaryotic centromeres is an essential histone H3 variant called CENP-A that requires a centromere targeting domain (CATD) for its localization. Although proteolysis prevents CENP-A from mislocalizing to euchromatin, regulatory factors have not been identified. Here, we identify an E3 ubiquitin ligase called Psh1 that leads to the degradation of Cse4, the budding yeast CENP-A homolog. Cse4 overexpression is toxic to psh1Δ cells and results in euchromatic localization. Strikingly, the Cse4 CATD is a key regulator of its stability and helps Psh1 discriminate Cse4 from histone H3. Taken together, we propose that the CATD has a previously unknown role in maintaining the exclusive localization of Cse4 by preventing its mislocalization to euchromatin via Psh1-mediated degradation.     

Dephosphorylation of cdc2 on threonine 161 is required for cdc2 kinase inactivation and normal anaphase.

Exit from metaphase of the cell cycle requires inactivation of MPF, a stoichiometric complex between the cdc2 catalytic and the cyclin B regulatory subunits, as well as that of cyclin A-cdc2 kinase. Inactivation of both complexes depends on proteolytic degradation of the cyclin subunit, yet cyclin proteolysis is not sufficient to inactivate the H1 kinase activity of cdc2. Genetic evidence strongly suggests that type 1 phosphatase plays a key role in the metaphase-anaphase transition of the cell cycle. Here we report that inhibition of both type 1 and type 2A phosphatases by okadaic acid allows cyclin degradation to occur, but prevents cdc2 kinase inactivation. Complete inhibition of type 2A phosphatase alone is not sufficient to prevent cdc2 kinase inactivation following cyclin proteolysis. We show further that residue 161 of cdc2 is phosphorylated in active cyclin A or cyclin B complexes at metaphase, whilst unassociated cdc2 is not phosphorylated. Proteolysis of cyclin releases a free cdc2 subunit, which subsequently undergoes dephosphorylation and then migrates more slowly than its Thr161 phosphorylated counterpart in Laemmli gels. Removal of phosphothreonine 161 requires cyclin proteolysis. However, it does not occur even after cyclin proteolysis, when both type 1 and type 2A phosphatases are inhibited. We conclude that both cyclin degradation and dephosphorylation of Thr161 on cdc2, catalysed at least in part by type 1 phosphatase, are required to inactivate either cyclin B- or cyclin A-cdc2 kinases and thus for cells to exit from M phase.     

Effects of DNA and urea on the specificity for H1 histone of the neutral protease B partially-purified from rat liver chromatin

A neutral protease, named protease B in the previous report (Tsurugi, K. & Ogata, K. (1982) J. Biochem. 92, 1369-1381), was partially purified from rat liver chromatin by gel filtration through Sepharose 6B followed by DE-Sephadex column chromatography. The proteolytic activity on total histones of the partially-purified protease B was increased about two fold by addition of DNA and again increased by further addition of 2 M urea. Analysis of the hydrolysed products showed that out of five species of histones, only H1 was degraded in the presence of an amount of DNA equivalent to the amount of histones, whereas core histones were also degraded in the absence or presence of one-tenth amount of DNA. Urea accelerated the selective degradation of H1 histone because H1 histone was preferentially degraded in the presence of even a low amount of DNA. In contrast, core histones became resistant to the protease B in the presence of DNA and/or urea. Heat-denatured DNA stimulated the degradation of H1 histone even in the absence of urea to almost the same extent that native DNA did in the presence of urea. Thus, protease B efficiently degrades H1 histone when its association with DNA is destabilized by either addition of urea or pretreatment of DNA with heat.     

The amino acid sequence of wheat histone H2A(1). A core histone with a C-terminal extension

The complete amino acid sequence (145 residues) of histone variant H2A(1) from wheat germ Triticum aestivum cultivar T4 has been established from Edman degradation of large overlapping fragments. The sequence of histone variant H2A(1) differs from the homologous calf histone in 61 amino acid positions. These differences include an extension of H2A(1) by 19 amino acids at its carboxyl end.     

Complete displacement of somatic histones during transformation of spermatid chromatin: a model experiment.

Displacement of histones from calf thymus chromatin has been studied in an attempt to postulate the mechanisms involved in the total removal of somatic-type histones during transformation of spermatid chromatin. When chromatin is saturated with protamine (protamine/DNA, 0.5), histone I becomes displaceable at 0.15-0.3 M NaCl, suggesting that direct replacement by highly basic sperm histone could be a mechanism for its removal. While histone I is the only histone which is extensively degraded upon incubation of chromatin and, therefore, proteolysis might provide an additional mechanism for the removal of this histone, acetylation of chromatin by acetic anhydride greatly increases suscpetibility of histones IIb1, IIb2, and III to the chromosomally associated protease. These histones are extensively degraded and displaced from the DNA upon incubation of the acetylated chromatin. Although histone IV is not appreciably degraded, the proteolytic removal of acetylated histone III from chromatin weakens the interaction of acetylated histone IV to the DNA, and this histone becomes dissociable at 0.3 M NaCl. A comparison of the extent of chemical acetylation of individual histones observed in this investigation with that of enzymatic acetylation which can be achieved in vivo suggests that acetylation and proteolysis could be a mechanism for the removal of histone IIb2 and III. The displacement of histones IIb1 and IV could be explained on the basis of decreased binding to DNA as a result of their acetylation together with the proteolytic removal of their respective partner histones, IIb2 and III.     

Regulation of H2a-specific proteolysis by the histone H3:H4 tetramer

We have studied the limited cleavage of H2a in the H2a:H2b histone dimer by the H2a-specific protease under physiological conditions (neutral pH, 0.1 M NaCl) using a variety of histone-DNA reconstitutes as substrates and/or regulators of the partially purified enzyme. Under these conditions the protease cleaves H2a in "native" dimer-DNA reconstitutes but not in "native" octamer-DNA reconstitutes. Treatment of the enzyme with saturating amounts of H3:H4 tetramer-DNA prior to addition of dimer-DNA substrate results in complete inhibition of H2a-specific proteolysis. Sucrose gradient sedimentation experiments indicate that the protease binds reversibly to tetramer-DNA and that this leads to the reversible inhibition of enzymatic activity. Using three different tetramer-DNA complexes, we found native tetramer-DNA to be a more effective inhibitor than either trypsin-treated tetramer-DNA or acetylated tetramer-DNA. We conclude that under physiological conditions, the H2a-specific protease binds primarily to the highly basic amino-terminal domain of the H3:H4 tetramer, and this binding lowers the effective concentration of enzyme available to cleave H2a. Although no cleaved H2a is produced when protease is mixed with native octamer-DNA, incubation of the enzyme with acetylated octamer-DNA results in H2a-specific proteolysis. This is the first demonstration that the H2a-specific protease activity can be modulated by a physiologically relevant process (e.g. histone acetylation). We propose that the sequestered protease may be functionally regulated in vivo through reversible post-translational modifications to the NH2-terminal domains of the histone H3:H4 tetramer.     

Catalytic subunit of the polycation-stimulated protein phosphatase. Effect of proteolysis on polycation stimulation

The phosphorylase phosphatase activity of the holoenzyme form of phosphatase 2A isolated from extracts of porcine renal cortex or bovine heart was stimulated 600% and 500%, respectively, by the addition of histone H1. After conversion of the phosphatase to the catalytic subunit form by treatment with ethanol at room temperature, histone H1 stimulated activity by about 150% only. Purification of the catalytic subunit from porcine renal cortex yielded two forms of the enzyme which were separated by heparin-Sepharose chromatography. These forms were designated peak 1 and peak 2 according to their order of elution from the column. Peak 1 catalytic subunit was stimulated by more than 400% by histone H1, whereas peak 2 was stimulated by about 50% only. Based on polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate, peak 2 had a slightly higher Mr value than peak 1 (35,500 vs. 35,000). Incubation of the peak 2 phosphatase with trypsin converted it to a form that was similar to peak 1 with respect to Mr and stimulation by histone H1. When the catalytic subunit of phosphatase 2A was purified from bovine heart only one form was obtained. Bovine heart enzyme was similar to renal peak 2 in that it had an apparent Mr of 35,500 and was only slightly stimulated by histone H1. Treatment of the bovine heart catalytic subunit with trypsin, chymotrypsin or type 2 Ca2+-dependent proteinase decreased the apparent Mr by about 500 and increased histone H1 stimulation to about 500%. Thus, when a small peptide was removed by proteolysis, histone H1 stimulation of the 'nicked' catalytic subunit was similar to that obtained with the holoenzyme.     

A study of histone-histone interactions by affinity chromatography

Homologous whole histone from calf thymus was adsorbed on Sepharose 4B columns with covalently coupled histone fractions H2a, H2b, H3 or H4 in 0.01 M phosphate buffer, pH 6.7–1 M NaCl. The adsorbed histones were eluted from the columns with 5 M urea in the same buffer. Electrophoretic analysis has shown that the different columns exhibit selective affinity to the histone fractions: the H2b column to histone H2b and H2a (with only weak affinity to histones H3 and H4), the H2a column to histones H2b and H3 (moderate affinity to histones H2a and H4), the H3 column to histones H3, H4, H2a (moderate affinity to histone H2b), and the H4 column to histone H3, H4 and H2b (weak affinity to histone H2a). Histone H1 displayed no fixation by either of the columns tested.     

Calf liver nuclear N-acetyltransferases. Purification and properties of two enzymes with both spermidine acetyltransferase and histone acetyltransferase activities.

Calf liver contains two nuclear N-acetyltransferases which are separated by chromatography on hydroxylapatite. Both acetyltransferase A and acetyltransferase B will transfer acetate from acetyl-CoA to either histone or spermidine. The same protein catalyzes the reaction with both substrates; this is shown by a constant ratio of spermidine to histone activity over a 5,000-fold purification and identical heat denaturation kinetics for both spermidine and histone acetyltransferase activity with each enzyme. Histone is preferentially acetylated when both acceptors are present. Both enzymes preferentially acetylate polyamines (spermidine, spermine, and diaminodipropylamine) to diamines. Acetyltransferase A acetylates histones in the order: whole histone greater than H4 greater than H2A greater than H3 greater than H2B greater than H1; acetyltransferase B in the order: whole histone greater than H4 = H3 greater than H2A greater than H2B greater than H1. Michaelis constants are 2 X 10(-4)M for spermidine and 9 X 10(-6)M for acetyl-CoA. Acetyltransferase A has a molecular weight of 150,000; acetyltransferase B 175,000. Both enzymes are strongly inhibited by p-chloromercuribenzoate and weakly inhibited by EDTA.     

Chicken liver glutamate dehydrogenase (GDH) demonstrates a histone H3 specific protease (H3ase) activity in vitro

Site-specific proteolysis of the N or C-terminus of histone tails has emerged as a novel form of irreversible post-translational modifications assigned to histones. Though there are many reports describing histone specific proteolysis, there are very few studies on purification of a histone specific protease. Here, we demonstrate a histone H3 specific protease (H3ase) activity in chicken liver nuclear extract. H3ase was purified to homogeneity and identified as glutamate dehydrogenase (GDH) by sequencing. A series of biochemical experiments further confirmed that the H3ase activity was due to GDH. The H3ase clipped histone H3 products were sequenced by N-terminal sequencing and the precise clipping sites of H3ase were mapped. H3ase activity was only specific to chicken liver as it was not demonstrated in other tissues like heart, muscle and brain of chicken. We assign a novel serine like protease activity to GDH which is specific to histone H3.