Selective release of HMG nonhistone proteins during DNase digestion of Tetrahymena chromatin at different stages of the cell cycle.

The possible role of LG-1, a Tetrahymena specific HMG protein found in the macronuclear chromatin (Hamana, K. and Iwai, K. (1979) J. Biochem. 86, 789-794), was examined in relation to the chromatin structure. The chromatin isolated from cells synchronized at different stages of the cell cycle contained about one molecule of LG-1 per nucleosome. Limited digestion of the chromatin with DNase I or micrococcal nuclease selectively released LG-1 with the nucleosomal core histones and H1 remained insoluble, bound to the resistant DNA. Depending on the cell stages several types of chromatin structure were distinguished by their nuclease sensitivity. However, the chromatin at different stages exhibited the similar behavior of the LG-1 release with the nucleases as a function of the degree of chromatin solubilization. The results suggest that LG-1 proteins play a role in the chromatin organization which is rather independent of the cell stages.     

RanGTPase激活蛋白RanGAP在嗜热四膜虫细胞中的定位及功能

RanGTPase激活蛋白（RanGTPase activating protein,RanGAP）和Ran相互作用,提高了Ran GTPase水解GTP的效率. RanGAP参与细胞内核质运输、纺锤体组装、核膜重建和异染色质的组装．生物进化过程中,不同生物的RanGAP表现出结构和功能的多样性．本研究从嗜热四膜虫大核基因组中鉴定出1个保守的RanGTPase激活蛋白基因RanGAP（TTHERM_00766430）．实时荧光定量PCR表明,RanGAP在四膜虫营养生长、饥饿和有性生殖过程中均有表达,且在有性生殖4～6 h表达水平最高．免疫荧光定位表明,在营养生长期、饥饿期及有性生殖的早期,RanGAP定位于细胞质中| 在有性生殖后期, RanGAP定位于凋亡的大核中．过表达RanGAP的细胞增殖速率下降,大核分裂和胞质缢缩异常, 产生无大核细胞．敲减RanGAP的细胞大核形态异常,细胞增殖速率下降,无丝分裂受到抑制,进而产生无大核细胞．RanGAP的过表达或敲除分别引起四膜虫RAN1,RanBP1和RCC1基因的表达下调或上调．结果表明,RanGAP通过Ran信号通路调控了嗜热四膜虫无性生殖过程中大核的无丝分裂,并可能参与了有性生殖过程中亲本大核的凋亡．     

Release of nucleosomes from nuclei by bleomycin-induced DNA strand scission

Mononucleosomes were released from both isolated mammalian (hog thyroid) and protozoan (Tetrahymena) nuclei by the bleomycin-induced DNA-strand breaking reaction. Trout sperm nuclei, on the other hand, were protected from the bleomycin-mediated DNA degradation. The mononucleosomes released from the bleomycin-treated nuclei contained the core histones H2A, H2B, H3, and H4; while HMG1 and HMG2 proteins, in addition to the core histones, were detected in the mononucleosomes obtained by micrococcal nuclease digestion of nuclei. HMGs, but not H1 histone, were dissociated into the supernatant by cleavage of chromatin DNA with bleomycin, whereas both HMGs and H1 were found in that fraction by digestion of nuclei with micrococcal nuclease. HMG1 and HMG2 were exclusively dissociated from chromatin with 1 mM bleomycin under the solvent condition where the DNA strand-breaking activity of the drug is repressed. These observations suggest the possibility that bleomycin preferentially binds to linker DNA regions not occupied by H1 histone in chromatin and exclusively dissociates HMG proteins and breaks the DNA strand. The results of the effects on bleomycin-induced DNA cleavage of nuclei of various drugs including polyamines, chelating agents, intercalating antibiotics such as mitomycin C or adriamycin, and radical scavengers are also presented.     

Scheduled and unscheduled DNA synthesis during development in conjugating Tetrahymena

Autoradiography has been used to confirm and to extend previous microspectrophotometric studies (Doerder and DeBault, 1975) on the timing of DNA synthesis during conjugation in Tetrahymena thermophila. The majority of DNA synthesis occurs at the expected periods preceding gamete formation and the two postzygotic divisions and during macronuclear development. DNA in new macronuclei is endoreplicated in an extremely discontinuous fashion. Under starvation conditions, the first endoreplication (2C to 4C) occurs immediately after the second postzygotic division when both new macronuclei and new micronuclei replicate. The second endoreplication (4C to 8C) does not occur until after separation of conjugants. If mating cells are kept under prolonged starvation conditions (20-24 hr), refeeding induces a partially synchronous division, after which an unexpectedly high percentage of cells incorporate tritiated thymidine into both macro- and micronuclei. Two previously undescribed periods of DNA synthesis were observed in the micronuclei of conjugating Tetrahymena. The first occurs during the early stages of meiotic prophase, before full crescent elongation. The second takes place in an extended period corresponding to macronuclear anlagen development, before conjugants have separated. CsCl gradient analyses indicate that, in micronuclear fractions, only main band DNA is being synthesized in both of these periods. However, in macronuclear fractions from both stages, a significant fraction (approximately 20%) of the DNA being synthesized has the buoyant density of ribosomal DNA. The finding that macro- and micronuclear DNA can be synthesized simultaneously in a single cell, both during conjugation and after refeeding starved exconjugants, raises interesting questions of how macro- or micronuclear-specific histones are targeted to the appropriate nuclei.     

HMG proteins (1 + 2) form beaded structures when complexed with closed circular DNA.

Structures bearing a resemblance to nucleosomes can be assembled by incubating calf thymus High Mobility Group proteins (1 + 2) with closed circular DNA. These HMG proteins are capable of forming beads and inducing superhelicity when bound to DNA. However, they do not protect from nuclease digestion the discrete DNA fragments characteristic of nucleosomes. The relationship between HMGs (1 + 2) and the "primitive" histone-like DNA-packaging proteins from prokaryotes and mitochondria is discussed.     

Glycosylation, ADP-ribosylation, and methylation of Tetrahymena histones

We have examined some of the postsynthetic modifications that occur in macronuclear histones from Tetrahymena thermophila. When purified macronuclei are incubated with [32P]NAD+, histones H1, H2A, H2B, and H3 are ADP-ribosylated. Furthermore, histones H1, H2A, H2B, and H3 contain fucose and mannose residues as evidenced by the incorporation of [3H]fucose and by the specific binding to these proteins of gorse seed lectin and concanavalin A. Finally, our studies on incorporation of methyl groups into histones show that histone H2A, together with the related nonhistone protein A24, is methylated in Tetrahymena.     

Histone rearrangements accompany nuclear differentiation and dedifferentiation in Tetrahymena

Histone synthesis and deposition into specific classes of nuclei has been investigated in starved and conjugating Tetrahymena. During starvation and early stages of conjugation (between 0 and 5 hr after opposite mating types are mixed), micronuclei selectively lose preexisting micronuclear-specific histones α, β, γ, and H3^F. Of these histones, only α appears to accumulate in micronuclear chromatin through active synthesis and deposition during the mating process. Curiously, α is not observed (by stain or label) in young macronuclear anlagen (4C, 10 hr of conjugation). Thus, young macronuclear anlagen are missing all of the histones which are known to be specific to micronuclei of vegetative cells. By 14–16 hr of conjugation, we observe active synthesis and deposition of macronuclear-specific histones, hv1, hv2, and H1, into new macronuclear anlagen (8C). Thus macronuclear differentiation seems well underway by this time of conjugation. It is also in this time period (14–16 hr) that we first detect significant amounts of micronuclear-specific H1-like polypeptides β and γ in micronuclear extracts. These polypeptides do not seem to be synthesized during this period, which suggests that β and γ are derived from a precursor molecule(s). Since these micronuclear-specific histones do not appear in micronuclear chromatin until after other micronuclei have been selected to differentiate as macronuclei, we suspect that micronuclear differentiation is also an important process which occurs in 10–16 hr mating cells. Our results also suggest that proteolytic processing of micronuclear H3^S into H3^F (which occurs in a cell cycle dependent fashion during vegetative growth) is not operative during most if not all of conjugation. Thus micronuclei of mating cells contain only H3^S which also seems consistent with the fact that some micronuclei differentiate into new macronuclei (micronuclear H3^S is indistinguishable from macronuclear H3). Interestingly, the only H3 synthesized and deposited into the former macronucleus of mating cells is the relatively minor macronuclear-specific H3-like variant, hv2. These results demonstrate that significant histone rearrangements occur during conjugation in Tetrahymena in a manner consistent with the fact that during conjugation some micronuclei eventually differentiate into new macronuclei. Our results suggest that selective synthesis and deposition of specific histones (and histone variants) plays an important role in the nuclear differentiation process in Tetrahymena. The disappearance of specific histones also raises the possibility that developmentally regulated proteolytic processing of specific histones plays an important (and previously unsuspected) role in this system.     

Conservation of sequences adjacent to the telomeric C4A2 repeats of ciliate macronuclear ribosomal RNA gene molecules.

We sequenced and compared the telomeric regions of linear rDNAs from vegetative macronuclei of several ciliates in the suborder Tetrahymenina. All telomeres consisted of tandemly repeated C4A2 sequences, including the 5' telomere of the 11 kb rDNA from developing macronuclei of Tetrahymena thermophila. Our sequence of the 11 kb 5' telomeric region shows that each one of a previously described pair of inverted repeats flanking the micronuclear rDNA (Yao et al., Mol. Cell. Biol. 5: 1260-1267, 1985) is 29 bp away from the positions to which telomeric C4A2 repeats are joined to the ends of excised 11 kb rDNA. In general we found that the macronuclear rDNA sequences adjacent to C4A2 repeats are not highly conserved. However, in the non-palindromic rDNA of Glaucoma, we identified a single copy of a conserved sequence, repeated in inverted orientation in Tetrahymena spp., which all form palindromic rDNAs. We propose that this sequence is required for a step in rDNA excision common to both Tetrahymena and Glaucoma.     

Methylation of ribosomal RNA genes in the macronucleus of Tetrahymena thermophila.

We have investigated the occurrence of methylated adenine residues in the macronuclear ribosomal RNA genes of Tetrahymena thermophila. It has been shown previously that macronuclear DNA, including the palindromic ribosomal RNA genes (rDNA), of Tetrahymena thermophila contains the modified base N-6-methyladenine, but no 5-methylcytosine. Purified rDNA was digested with restriction enzymes Sau 3AI, MboI and DpnI to map the positions and levels of N-6-methyladenine in the sequence 5' GATC 3'. A specific pattern of doubly methylated GATC sequences was found; hemimethylated sites were not detected. The patterns and levels of methylation of these sites did not change significantly in different physiological states. A molecular form of the rDNA found in the newly developing macronucleus and for several generations following the sexual process, conjugation, contained no detectably methylated GATC sites. However, both the bulk macronuclear DNA and palindromic rDNA from the same macronuclei were methylated. Possible roles for N-6-methyladenine in macronuclear DNA are discussed in light of these findings.     

The transition from conjugal development to the first vegetative cell division is dependent on RAD51 expression in the ciliate Tetrahymena thermophila

Rad51p, the eukaryotic homolog of the prokaryotic recA protein, catalyzes strand exchange between single- and double-stranded DNA and is involved in both genetic recombination and double-strand break repair in the ciliate Tetrahymena thermophila. We have previously shown that disruption of the Tetrahymena RAD51 somatic macronuclear locus leads to defective germline micronuclear division and that conjugation of two somatic rad51 null strains results in an early meiotic arrest. We have constructed Tetrahymena strains that are capable of RAD51 expression from their parental macronuclei and are homozygous, rad51 nulls in their germline micronuclei. These rad51 null heterokaryons complete all of the early and middle stages of conjugation, including meiosis, haploid nuclear exchange, zygotic fusion, and the programmed chromosome fragmentations, sequence eliminations, and rDNA amplification that occur during macronuclear development. However, the rad51 null progeny fail to initiate the first vegetative cell division following conjugal development. Coincident with the developmental arrest is a disproportionate amplification of rDNA, despite the maintenance of normal total DNA content in the developing macronuclei. Fusion of arrested rad51 null exconjugants to wild-type cells is sufficient to overcome the arrest. Cells rescued by cytoplasmic fusion continue to divide, eventually recapitulating the micronuclear mitotic defects described previously for rad51 somatic nulls.     

嗜热四膜虫异染色质蛋白Tcd1磷酸化位点的突变分析

四膜虫异染色质蛋白Tcd1在有性生殖时期特异表达,在大核基因组重排以及修复过程中发挥作用。磷酸化蛋白质组学分析表明,Tcd1存在3个磷酸化位点：S301,S303和S535。然而,Tcd1磷酸化修饰与其功能的关系并不清楚。本研究对TCD1基因的3个磷酸化位点进行了模拟磷酸化和模拟去磷酸化定点突变,获得模拟磷酸化突变基因TCD1S301D (TCD1S1D)、TCD1S301DS303D (TCD1S2D)与TCD1S301DS303DS535D (TCD1S3D) 和模拟去磷酸化的突变基因TCD1S301A (TCD1S1A)、TCD1S301AS303A (TCD1S2A)与TCD1S301AS303AS535A (TCD1S3A)。分别构建了不同突变体的过表达载体,转化四膜虫细胞并筛选获得不同突变体细胞株。Western印迹分析表明,Tcd1S1D、Tcd1S2D、Tcd1S3D与Tcd1S1A、Tcd1S2A和Tcd1S3A在四膜虫有性生殖期表达。免疫荧光定位分析发现,Tcd1S1D点状定位于细胞质中,Tcd1S2D在有性生殖初期点状定位于细胞质中,在新大核上形成均匀的定位,Tcd1S3D无法定位于亲本大核上,只是均匀定位于新大核上。Tcd1S2A和Tcd1S3A在新大核形成异常的块状定位,并且与异染色质蛋白Pdd1不能共定位。结果表明,Tcd1不同位点的磷酸化和去磷酸化修饰的动态变化决定了其在四膜虫细胞中的定位模式。