Absence of histone F1 in a mitotically dividing, genetically inactive nucleus

Recent Advances in Doxorubicin Formulation to Enhance Pharmacokinetics and Tumor Targeting

Doxorubicin (DOX), a widely used drug in cancer chemotherapy, induces cell death via multiple intracellular interactions, generating reactive oxygen species and DNA-adducted configurations that induce apoptosis, topoisomerase II inhibition, and histone eviction. Despite its wide therapeutic efficacy in solid tumors, DOX often induces drug resistance and cardiotoxicity. It shows limited intestinal absorption because of low paracellular permeability and P-glycoprotein (P-gp)-mediated efflux. We reviewed various parenteral DOX formulations, such as liposomes, polymeric micelles, polymeric nanoparticles, and polymer-drug conjugates, under clinical use or trials to increase its therapeutic efficacy. To improve the bioavailability of DOX in intravenous and oral cancer treatment, studies have proposed a pH- or redox-sensitive and receptor-targeted system for overcoming DOX resistance and increasing therapeutic efficacy without causing DOX-induced toxicity. Multifunctional formulations of DOX with mucoadhesiveness and increased intestinal permeability through tight-junction modulation and P-gp inhibition have also been used as orally bioavailable DOX in the preclinical stage. The increasing trends of developing oral formulations from intravenous formulations, the application of mucoadhesive technology, permeation-enhancing technology, and pharmacokinetic modulation with functional excipients might facilitate the further development of oral DOX.

Histone tail cleavage as a novel epigenetic regulatory mechanism for gene expression

Chromatin is an intelligent building block that can express either external or internal needs through structural changes. To date, three methods to change chromatin structure and regulate gene expression have been well-documented: histone modification, histone exchange, and ATP-dependent chromatin remodeling. Recently, a growing body of literature has suggested that histone tail cleavage is related to various cellular processes including stem cell differentiation, osteoclast differentiation, granulocyte differentiation, mammary gland differentiation, viral infection, aging, and yeast sporulation. Although the underlying mechanisms suggesting how histone cleavage affects gene expression in view of chromatin structure are only beginning to be understood, it is clear that this process is a novel transcriptional epigenetic mechanism involving chromatin dynamics. In this review, we describe the functional properties of the known histone tail cleavage with its proteolytic enzymes, discuss how histone cleavage impacts gene expression, and present future directions for this area of study.

Nuclear localization signal targeting to macronucleus and micronucleus in binucleated ciliate Tetrahymena thermophila

Ciliated protozoa possess two morphologically and functionally distinct nuclei: a macronucleus (MAC) and a micronucleus (MIC). The MAC is transcriptionally active and functions in all cellular events. The MIC is transcriptionally inactive during cell growth, but functions in meiotic events to produce progeny nuclei. Thus, these two nuclei must be distinguished by the nuclear proteins required for their distinct functions during cellular events such as cell proliferation and meiosis. To understand the mechanism of the nuclear transport specific to either MAC or MIC, we identified specific nuclear localization signals (NLSs) in two MAC- and MIC-specific nuclear proteins, macronuclear histone H1 and micronuclear linker histone-like protein (Mlh1), respectively. By expressing GFP-fused fragments of these proteins in Tetrahymena thermophila cells, two distinct regions in macronuclear histone H1 protein were assigned as independent MAC-specific NLSs and two distinct regions in Mlh1 protein were assigned as independent MIC-specific NLSs. These NLSs contain several essential lysine residues responsible for the MAC- and MIC-specific nuclear transport, but neither contains any consensus sequence with known monopartite or bipartite NLSs in other model organisms. Our findings contribute to understanding how specific nuclear targeting is achieved to perform distinct nuclear functions in binucleated ciliates.

Proteolytic clipping of histone tails: the emerging role of histone proteases in regulation of various biological processes

Chromatin is a dynamic DNA scaffold structure that responds to a variety of external and internal stimuli to regulate the fundamental biological processes. Majority of the cases chromatin dynamicity is exhibited through chemical modifications and physical changes between DNA and histones. These modifications are reversible and complex signaling pathways involving chromatin-modifying enzymes regulate the fluidity of chromatin. Fluidity of chromatin can also be impacted through irreversible change, proteolytic processing of histones which is a poorly understood phenomenon. In recent studies, histone proteolysis has been implicated as a regulatory process involved in the permanent removal of epigenetic marks from histones. Activities responsible for clipping of histone tails and their significance in various biological processes have been observed in several organisms. Here, we have reviewed the properties of some of the known histone proteases, analyzed their significance in biological processes and have provided future directions.

The draft assembly of the radically organized Stylonychia lemnae macronuclear genome

Stylonychia lemnae is a classical model single-celled eukaryote, and a quintessential ciliate typified by dimorphic nuclei: A small, germline micronucleus and a massive, vegetative macronucleus. The genome within Stylonychia’s macronucleus has a very unusual architecture, comprised variably and highly amplified “nanochromosomes,” each usually encoding a single gene with a minimal amount of surrounding noncoding DNA. As only a tiny fraction of the Stylonychia genes has been sequenced, and to promote research using this organism, we sequenced its macronuclear genome. We report the analysis of the 50.2-Mb draft S. lemnae macronuclear genome assembly, containing in excess of 16,000 complete nanochromosomes, assembled as less than 20,000 contigs. We found considerable conservation of fundamental genomic properties between S. lemnae and its close relative, Oxytricha trifallax, including nanochromosomal gene synteny, alternative fragmentation, and copy number. Protein domain searches in Stylonychia revealed two new telomere-binding protein homologs and the presence of linker histones. Among the diverse histone variants of S. lemnae and O. trifallax, we found divergent, coexpressed variants corresponding to four of the five core nucleosomal proteins (H1.2, H2A.6, H2B.4, and H3.7) suggesting that these ciliates may possess specialized nucleosomes involved in genome processing during nuclear differentiation. The assembly of the S. lemnae macronuclear genome demonstrates that largely complete, well-assembled highly fragmented genomes of similar size and complexity may be produced from one library and lane of Illumina HiSeq 2000 shotgun sequencing. The provision of the S. lemnae macronuclear genome sets the stage for future detailed experimental studies of chromatin-mediated, RNA-guided developmental genome rearrangements.

Organization and expression of the Paramecium caudatum gene encoding nucleosome assembly protein 1

The complete genomic and partial complementary DNAs encoding the ciliate Paramecium caudatum nucleosome assembly protein 1 (NAP1) have been sequenced. The nap1 gene is situated 1.2 kbp from the hemoglobin (hb) gene, with the 3' end of both genes facing each other. The nap1 gene contains no introns, and encodes a protein of 369 amino acid residues with a calculated molecular weight of 42,627. The P. caudatum NAP1 amino acid sequence shares only 23-27% identity with NAP1 amino acid sequences from other eukaryotes. Although the nap1 transcript was detected in the P. caudatum cells at both the logarithmic and stationary phases, its level increased during the stationary phase. Southern blot analysis and polymerase chain reaction amplification revealed that the P. caudatum macronucleus has a heterogeneous composition at genomic regions around the nap1 gene. The present studies indicate the nap1 and hb genes are closely arranged in the macronucleus with the intergenic region between their sequences heterogeneously composed.

The DNA of ciliated protozoa

Ciliates contain two types of nuclei: a micronucleus and a macronucleus. The micronucleus serves as the germ line nucleus but does not express its genes. The macronucleus provides the nuclear RNA for vegetative growth. Mating cells exchange haploid micronuclei, and a new macronucleus develops from a new diploid micronucleus. The old macronucleus is destroyed. This conversion consists of amplification, elimination, fragmentation, and splicing of DNA sequences on a massive scale. Fragmentation produces subchromosomal molecules in Tetrahymena and Paramecium cells and much smaller, gene-sized molecules in hypotrichous ciliates to which telomere sequences are added. These molecules are then amplified, some to higher copy numbers than others. rDNA is differentially amplified to thousands of copies per macronucleus. Eliminated sequences include transposonlike elements and sequences called internal eliminated sequences that interrupt gene coding regions in the micronuclear genome. Some, perhaps all, of these are excised as circular molecules and destroyed. In at least some hypotrichs, segments of some micronuclear genes are scrambled in a nonfunctional order and are recorded during macronuclear development. Vegetatively growing ciliates appear to possess a mechanism for adjusting copy numbers of individual genes, which corrects gene imbalances resulting from random distribution of DNA molecules during amitosis of the macronucleus. Other distinctive features of ciliate DNA include an altered use of the conventional stop codons.

Mitosis-specific histone H3 phosphorylation in vitro in nucleosome structures

A mechanism of mitosis-specific enhancement of histone H3 phosphorylation was analyzed in vitro in terms of nucleosome structure. The incorporation of [32P]phosphate into DNA-bound H3 was approximately 5-7 times higher than in DNA-free H3 using the catalytic subunit of cAMP-dependent protein kinase. The two major N-terminal serine sites, including the mitosis-specific site (Ser10) and Ser28, were extensively phosphorylated in the DNA-bound forms. These phosphorylation patterns were identical to those of nucleosomal H3. In contrast, the H3 in DNA-free octamers was very slightly phosphorylated. The major site of H3 phosphorylation in DNA-free H3 was Thr118 in the C-terminus. Results indicate that DNA-binding is essential for the high level of mitosis-specific H3 phosphorylation, and that the nucleosome structure promotes H3 N-terminal phosphorylation in vitro. It also suggests the possibility that H1 prevents H3 phosphorylation during interphase of the cell cycle.

Histone H1 in G1 arrested, senescent, and Werner syndrome fibroblasts

Histone H1 content and synthesis were examined in normal, Werner-syndrome, and transformed fibroblasts. Analysis of 3H-lysine incorporation indicated that senescent cells, but not G1-arrested young cells, had a lower ratio of molar synthesis of H1 histone to nucleosome histones than did growing young cells or gamma-ray-transformed cells. Furthermore, a biochemical study of histone H1 content plotted as a function of DNA synthesis activity and an immunocytological study using antiserum against histone H1 revealed that senescent cells had a lower histone H1 content than did young cultures at all stages of cell proliferation. Werner syndrome skin fibroblasts at early passage, however, had amounts of histone H1 comparable to those of age-matched normal control fibroblasts. We conclude that a decline, with increasing passage number, in content and synthesis of H1 histone relative to nucleosomal histones (Mitsui et al., 1980) was not simply due to passage-related accumulation of G1-arrested cells, but actually reflected age specific changes of cultured human fibroblasts. The depletion of histone H1 in the chromatin of senescent cells is a possible cause of DNA strand breakage or relaxation of gene repression.

Isopeptidase: a novel eukaryotic enzyme that cleaves isopeptide bonds

In an attempt to clarify the regulatory mechanism that accounts for the shift of protein A24 in the mitotic cycle, we demonstrated the existence of an enzyme, provisionally termed isopeptidase, that cleaves A24 stoichiometrically into histone H2A and ubiquitin. Properties of this enzyme are (i) most eukaryotes, including mammals, amphibia, chicken, and yeast, contain isopeptidase in the cytoplasm; (ii) a significant increase in enzyme binding to chromatin occurs when cells enter mitosis; (iii) Escherichia coli does not contain isopeptidase; (iv) isopeptidase has a molecular weight of 38,000; (v) at an ionic strength that induces globular conformation of H2A, isopeptidase activity is repressed; (vi) a SH group is an essential cofactor; and (vii) most divalent cations (except Mg2+ and Ca2+) are inhibitory. In view of the stoichiometric conversion of A24 into H2A and ubiquitin by isopeptidase in vitro, A24 probably contains a Gly-Gly dipeptide in isopeptide linkage but no other intervening polypeptides. Since ubiquitin in various eukaryotes binds to protein other than H2A, and is proteolytically released, isopeptidase probably acts on isopeptide bonds in general and not uniquely on those of A24. Inasmuch as isopeptidase is present throughout the cell cycle, the level of A24 in chromatin appears to be controlled by a balance between isopeptidase and an as yet unestablished H2A-ubiquitin ligase.

Disappearance of a structural chromatin protein A24 in mitosis: implications for molecular basis of chromatin condensation

A chromatin protein, A24, a conjugate of histone H2A and evolutionally conserved ubiquitin, was virtually the only structural polypeptide that was present in interphase but missing in mitosis of a Chinese hamster cell line (DON). Because a 10% increase in the H2A/DNA ratio observed in interphase-mitosis transition explained the stoichiometric conversion of A24 to H2A, it appears that ubiquitin bound to H2A of nucleosomal surfaces in interphase is released at mitosis whereas the total H2A remains as a structural component of nucleosomes. Regardless of protein synthesis, ubiquitin was again bound to H2A when cells entered the G1 phase. Based on the electrostatic nature of the COOH-terminal region of H2A, where ubiquitin binds, and the mitosis-specific rise of covalently linked phosphates in histones H1 and H3, we propose that an ionic interaction between the positively charged H2A COOH-terminal regions on fibers and negatively charged phosphates linked to serine or threonine of H1 and H3 molecules on adjacent fibers could generate an assembly of chromatin fibers in mitosis.

Micronuclei of Tetrahymena contain two types of histone H3

Evidence is presented that micronuclei of Tetrahymena thermophila contain significant amounts of two types of histone H3. One is indistinguishable from that found in macronuclei and the other is unique to micronuclei. The micronucleus-specific H3 has a slightly faster mobility than the common H3 in three different gel systems (both of these species were artifactually lost during procedures for histone preparation in previous studies). Both micronuclear H3s appear to contain a single cysteine residue and are present in sucrose gradient-purified nucleosomes. Acid extracts from micronuclei also contain three prominent high molecular weight proteins that also were lost during previous procedures. These proteins are present in extracts from oligomers but are not observed in extracts from mononucleosomes, suggesting that they may be associated with linker regions between nucleosomes.

Anomalous electrophoretic mobility of Drosophila phosphorylated H1 histone: is it related to the compaction of satellite DNA into heterochromatin?

In embryonic nuclei of Drosophila virilis, 45% of the DNA is satellite, and congruent to 50% of the H1 histone is phosphorylated. In polytene salivary gland nuclei, less than 1% of the DNA is satellite, and less than 10tion. The phosphorylated H1's migrate 4% slower than the unphosphorylated H1's on SDS-acrylamide gels. The mobility difference may arise because the phosphorylated and unphosphorylated H1's have different conformations in SDS. This putative conformational difference could be essential to the compaction of satellite DNA into heterochromatin.

Changes in chromatin properties after partial extraction of non-histone proteins

By treatment with tRNA in the presence of 1 mM MgCl2, a chromatin preparation was obtained containing all five major histone fractions but lacking a considerable portion of non-histone proteins. This chromatin preparation as well as chromatin extracted with 0.6 M NaCl (depleted of H1 histone and some non-histone proteins) were characterized in respect of solubility and chromatin DNA accessibility. Both samples possessed practically the same solubility in the presence of 0.15 M NaCl and 1 mM MgCl2. The solubility of tRNA-treated chromatin in 5 and 10 mM MgCl2 was higher than that of salt-extracted chromation. The accessibility of the DNA of these chromatin preparations was tested with DNA-dependent RNA polymerase of Escherichia coli as a probe, using procedure that permits measurement of binding site frequency. Both tRNA-treated and salt-extracted chromatin contained as many as 33% and untreated chromatin as few as 4% of the number of binding sites found on protein-free DNA. These results demonstrate that at least in part the non-histone proteins are responsible for salt-induced insolubility and low DNA accessibility of chromatin, thus revealing the importance of non-histone proteins in the maintenance of an overall chromatin structure.

Immunofluorescence evidence for the absence of histone H1 in a mitotically dividing, genetically inactive nucleus

Antibodies directed against whole histone and purified lysine-rich histone H1 extracted from isolated macronuclei of the ciliate Tetrahymena were obtained and conjugated to fluorescein isothiocyanate. The fluorescein-antibody conjugates were used to directly label Tetrahymena cells. Both macro- and micronuclei were visibly fluorescent in cells stained with anti-whole histone conjugate. However, the anti-H1 conjugate only labeled macronuclei. This in situ demonstration of the lack of positive immunofluorescent staining of micronuclei with anti-H1 conjugate provide further evidence for the absence of H1 in the genetically inactive, mitotically dividing Tetrahymena micronucleus.

Synthesis of yeast histones in the cell cycle

The yeast, Saccharomyces cerevisiae, contains four types of histones resembling histones H3, H2b, H2a, and H4 of animal cells. These proteins are synthesized primarily, if not exclusively, in the S-phase of the cell cycle. This result is discussed with reference to the insensitivity of ongoing DNA replication in yeast to inhibitors of protein synthesis.

Relationship between chromosome condensation and metaphase lysine-rich histone phosphorylation

Treatment of metaphase HTC cells with ZnCl2 inhibits histone phosphatase activity and leads to an increase in the hyperphosphorylated forms of the lysine-rich (F1) histone. Under normal conditions a massive phosphatase activity is triggered as the cells shift from M into G1 phase. In the presence of ZnCl2 this activity is abolished and thehyperphosphorylated form of F1 persists intact into G1. We have asked the simple question of whether the chromosome can still extend during the M-G1 transition even if the F1 histone is maintained in the hyperphosphorylated form. We observe an apparently normal extension os the chromosomal material under these conditions, though it is evident that high levels of ZnCl2 have rather substantial effects on other cell functions.

Subunit structure of a naturally occurring chromatin lacking histones F1 and F3

Macronuclei of the ciliated protozoan Tetrahymena pyriformis contain at least five classes of histones, including two with properties like those of histones F3 and F1 of higher eukaryotes. Micronuclei isolated under identical conditions contain little or no detectable F3 or F1. Digestion of both macronuclei and micronuclei with staphylococcal nuclease results in DNA fragments of discrete sizes. The electrophoretic mobilities of the larger fragments suggest that they are oligomers of the smallest ones. These results indicate that the periodic subunit structure observed in the chromatin of higher organisms also occurs in protozoans, and that this structure does not depend on the presence of either histone F1 or F3, even in an organism which has the genetic information for synthesizing these proteins.