Differential activity of DNA methyltransferase in the life cycle of Chlamydomonas reinhardi

Dynamic Changes in the Transcriptome and Methylome of Chlamydomonas reinhardtii throughout Its Life Cycle

The green alga Chlamydomonas reinhardtii undergoes gametogenesis and mating upon nitrogen starvation. While the steps involved in its sexual reproductive cycle have been extensively characterized, the genome-wide transcriptional and epigenetic changes underlying different life cycle stages have yet to be fully described. Here, we performed transcriptome and methylome sequencing to quantify expression and DNA methylation from vegetative and gametic cells of each mating type and from zygotes. We identified 361 gametic genes with mating type-specific expression patterns and 627 genes that are specifically induced in zygotes; furthermore, these sex-related gene sets were enriched for secretory pathway and alga-specific genes. We also examined the C. reinhardtii nuclear methylation map with base-level resolution at different life cycle stages. Despite having low global levels of nuclear methylation, we detected 23 hypermethylated loci in gene-poor, repeat-rich regions. We observed mating type-specific differences in chloroplast DNA methylation levels in plus versus minus mating type gametes followed by chloroplast DNA hypermethylation in zygotes. Lastly, we examined the expression of candidate DNA methyltransferases and found three, DMT1a, DMT1b, and DMT4, that are differentially expressed during the life cycle and are candidate DNA methylases. The expression and methylation data we present provide insight into cell type-specific transcriptional and epigenetic programs during key stages of the C. reinhardtii life cycle.

Differential methylation of chloroplast DNA regulates maternal inheritance in a methylated mutant of Chlamydomonas

In Chlamydomonas, the maternal inheritance of chloroplast genes correlates with the differential methylation of chloroplast DNA (chlDNA) in females (mt(+)) but not in males (mt(-)). Our previous studies have supported our methylation-restriction model in which the maternal transmission is accounted for by the differential methylation in gametes which protects female but not male chlDNA from degradation during zygote formation. In the mutant me-1 [Bolen, P. L., Grant, D. M., Swinton, D., Boynton, J. E. & Gillham, N. W. (1982) Cell 28, 335-343], chlDNA of vegetative cells of both mating types is heavily methylated even before gametogenesis; nonetheless, maternal inheritance occurs in mutants as in wild type. To investigate the mechanism of maternal inheritance in the me-1 mutant, we have compared restriction fragment patterns after agarose gel electrophoresis of chlDNAs from mutant vegetative cells and gametes with those from wild type, by using a set of 32 restriction enzymes of which 17 were methylation-sensitive in this system. We find that additional methylation occurs during gametogenesis in the mutant female (mt(+)) but not in the corresponding male (mt(-)). Thus, gamete-specific, mating-type-specific methylation occurs in the me-1 mutant as in the wild type, consistent with our methylation-restriction model. In the me-1 mutant, gametic methylation occurs on a background of vegetative cell methylation not present in wild-type cells and irrelevant to the regulation of chloroplast inheritance. Comparison of the me-1 mutation with the mat-1 mutation [Sager, R., Grabowy, C. & Sano, H. (1981) Cell 24, 41-47] provides evidence for the existence of two different chlDNA methylation control systems: mat-1, linked to the mating type locus and regulating the mating-type-specific methylation that correlates with maternal inheritance, and me-1, unlinked to the mating type locus and unrelated to the regulation of maternal inheritance.

Uniparental inheritance of cpDNA and the genetic control of sexual differentiation in Chlamydomonas reinhardtii

An intriguing feature of most eukaryotes is that chloroplast (cp) and mitochondrial (mt) genomes are inherited almost exclusively from one parent. Uniparental inheritance of cp/mt genomes was long thought to be a passive outcome, based on the fact that eggs contain multiple numbers of organelles, while male gametes contribute,at best, only a few cp/mtDNA. However, the process is likely to be more dynamic because uniparental inheritance occurs in organisms that produce gametes of identical sizes (isogamous). In Chlamydomonas reinhardtii,the uniparental inheritance of cp/mt genomes is achieved by a series of mating type-controlled events that actively eliminate the mating type minus (mt-) cpDNA.The method by which Chlamydomonas selectively degrades mt- cpDNA has long fascinated researchers, and is the subject of this review.

Review of cytological studies on cellular and molecular mechanisms of uniparental (maternal or paternal) inheritance of plastid and mitochondrial genomes induced by active digestion of organelle nuclei (nucleoids)

In most sexual organisms, including isogamous, anisogamous and oogamous organisms, uniparental transmission is a striking and universal characteristic of the transmission of organelle (plastid and mitochondrial) genomes (DNA). Using genetic, biochemical and molecular biological techniques, mechanisms of uniparental (maternal and parental) and biparental transmission of organelle genomes have been studied and reviewed. Although to date there has been no cytological review of the transmission of organelle genomes, cytology offers advantages in terms of direct evidence and can enhance global studies of the transmission of organelle genomes. In this review, I focus on the cytological mechanism of uniparental inheritance by "active digestion of male or female organelle nuclei (nucleoids, DNA)" which is universal among isogamous, anisogamous, and oogamous organisms. The global existence of uniparental transmission since the evolution of sexual eukaryotes may imply that the cell nuclear genome continues to inhibit quantitative evolution of organelles by organelle recombination.

Paternal inheritance of mitochondria in Chlamydomonas

To analyze mitochondrial DNA (mtDNA)inheritance, differences in mtDNA between Chlamydomonas reinhardtii and Chlamydomonas smithii, respiration deficiency and antibiotic resistance were used to distinguish mtDNA origins. The analyses indicated paternal inheritance. However, these experiments raised questions regarding whether paternal inheritance occurred normally.Mitochondrial nucleoids were observed in living zygotes from mating until 3 days after mating and then until progeny formation. However, selective disappearance of nucleoids was not observed. Subsequently, experimental serial backcrosses between the two strains demonstrated strict paternal inheritance. The fate of mt+ and mt- mtDNA was followed using the differences in mtDNA between the two strains. The slow elimination of mt+ mtDNA through zygote maturation in darkness was observed, and later the disappearance of mt+ mtDNA was observed at the beginning of meiosis. To explain the different fates of mtDNA, methylation status was investigated; however, no methylation was detected. Variously constructed diploid cells showed biparental inheritance. Thus, when the mating process occurs normally, paternal inheritance occurs. Mutations disrupting mtDNA inheritance have not yet been isolated. Mutations that disrupt maternal inheritance of chloroplast DNA (cpDNA) do not disrupt inheritance of mtDNA. The genes responsible for mtDNA inheritance are different from those of chloroplasts.

Purification and characterization of rice DNA methyltransferase

Epigenetic modification is essential for normal development and plays important roles in gene regulation in higher plants. Multiple factors interact to regulate the establishment and maintenance of DNA methylation in plant genome. We had previously cloned and characterized DNA methyltransferase (DNA MTase) gene homologues (OsMET1) from rice. In this present study, determination of DNA MTase activity in different cellular compartments showed that DNA MTase was enriched in nuclei and the activity was remarkably increased during imbibing dry seeds. We had optimized the purification technique for DNA MTase enzyme from shoots of 10-day-old rice seedlings using the three successive chromatographic columns. The Econo-Pac Q, the Hitrap-Heparin and the Superdex-200 columns yielded a protein fraction of a specific activity of 29, 298 and 800 purification folds, compared to the original nuclear extract, respectively. The purified protein preferred hemi-methylated DNA substrate, suggesting the maintenance activity of methylation. The native rice DNA MTase was approximately 160-170 kDa and exhibited a broad pH optimum in the range of 7.6 and 8.0. The enzyme kinetics and inhibitory effects by methyl donor analogs, base analogs, cations, and cationic amines on rice DNA MTase were examined. Global cytosine methylation status of rice genome during development and in various tissue culture systems were monitored and the results suggested that the cytosine methylation level is not directly correlated with the DNA MTase activity. The purification and characterization of rice DNA MTase enzyme are expected to enhance our understanding of this enzyme function and their possible contributions in Gramineae plant development.

Cloning and primarily function study of two novel putative N5-glutamine methyltransferase (Hemk) splice variants from mouse stem cells

Methylation is one of epigenetic mechanisms regulating gene expression. The methylation pattern is determined during embryogenesis and passed over to differentiating cells and tissues. Beginning with the ESTs which were highly expressed in undifferentiated human ES cells and using homology research in mouse dbEST database, we cloned two novel putative (N (5))-glutamine methyltransferase (Hemk) splice variants termed mHemk1 and mHemk2 (Genbank accession number AY456393 and AY583759). Sequence analysis revealed that mHemk1 and mHemk2 cDNAs are 1,792 bp and 1,696 bp in length respectively. The deduced proteins have 214 amino acid residues (mHemk1) and 138 residues (mHemk2) in length and both share significant homology with (N (5))-glutamine methyltransferase (Hemk proteins) in database. Northern blot and RT-PCR analysis showed that mHemk mRNAs were abundantly expressed in undifferentiated ES cells, testis and brain, weakly expressed in differentiated ES cells and kidney, and not expressed in muscle, heart, placenta, pancreas, lung and stomach. Immunohistochemical analysis further revealed that the protein was most abundant in undifferentiated ES cells. The green fluorescent protein produced by pEGFP-C3/mHemk1 was detected mainly in the nucleus of COS7 cell lines after 24 h post-transfection. RNA interference (RNAi)-mediated knock-down method was established. Cell cycle analysis suggests that the cell proliferation decreases after RNAi with mHemk1. In vitro bioactivity assay showed that no evidence for a DNA adenine-methyltransferase activity was detected. The accumulating functional information from Hemk homology proteins in bacteria and yeast suggests that it may be an uncharacterized new mammalian N(5)-glutamine methyltransferase.

Role of a nonselective de novo DNA methyltransferase in maternal inheritance of chloroplast genes in the green alga, Chlamydomonas reinhardtii

In the green alga, Chlamydomonas, chloroplast DNA is maternally transmitted to the offspring. We previously hypothesized that the underlying molecular mechanism involves specific methylation of maternal gamete DNA before mating, protecting against degradation. To obtain direct evidence for this, we focused on a DNA methyltransferase, DMT1, which was previously shown to be localized in chloroplasts. The full-length DMT1 protein with a molecular mass of 150 kD was expressed in insect cells, and its catalytic activity was determined. In vitro assays using synthetic DNA indicated methylation of all cytosine residues, with no clear selectivity in terms of the neighboring nucleotides. Subsequently, transgenic paternal cells constitutively expressing DMT1 were constructed and direct methylation mapping assays of their DNA showed a clear nonselective methylation of chloroplast DNA. When transgenic paternal cells were crossed with wild-type maternal cells, the frequency of biparental and paternal offspring of chloroplasts increased up to 23% while between wild-type strains it was approximately 3%. The results indicate that DMT1 is a novel type of DNA methyltransferase with a nonselective cytosine methylation activity, and that chloroplast DNA methylation by DMT1 is one of factors influencing maternal inheritance of chloroplast genes.

EVOLUTION OF HIERARCHICAL CYTOPLASMIC INHERITANCE IN THE PLASMODIAL SLIME MOLD PHYSARUM POLYCEPHALUM

A striking linear dominance relationship for uniparental mitochondrial transmission is known between many mating types of plasmodial slime mold Physarum polycephalum. We herein examine how such hierarchical cytoplasmic inheritance evolves in isogamous organisms with many self-incompatible mating types. We assume that a nuclear locus determines the mating type of gametes and that another nuclear locus controls the digestion of mitochondria DNAs (mtDNAs) of the recipient gamete after fusion. We then examine the coupled genetic dynamics for the evolution of self-incompatible mating types and biased mitochondrial transmission between them. In Physarum, a multiallelic nuclear locus matA controls both the mating type of the gametes and the selective elimination of the mtDNA in the zygotes. We theoretically examine two potential mechanisms that might be responsible for the preferential digestion of mitochondria in the zygote. In the first model, the preferential digestion of mitochondria is assumed to be the outcome of differential expression levels of a suppressor gene carried by each gamete (suppression-power model). In the second model (site-specific nuclease model), the digestion of mtDNAs is assumed to be due to their cleavage by a site-specific nuclease that cuts the mtDNA at unmethylated recognition sites. Also assumed is that the mtDNAs are methylated at the same recognition site prior to the fusion, thereby being protected against the nuclease of the same gamete, and that the suppressor alleles convey information for the recognition sequences of nuclease and methylase. In both models, we found that a linear dominance hierarchy evolves as a consequence of the buildup of a strong linkage disequilibrium between the mating-type locus and the suppressor locus, though it fails to evolve if the recombination rate between the two loci is larger than a threshold. This threshold recombination rate depends on the number of mating types and the degree of fitness reduction in the heteroplasmic zygotes. If the recombination rate is above the threshold, suppressor alleles are equally distributed in each mating type at evolutionary equilibrium. Based on the theoretical results of the site-specific nuclease model, we propose that a nested subsequence structure in the recognition sequence should underlie the linear dominance hierarchy of mitochondrial transmission.

An mt(+) gamete-specific nuclease that targets mt(-) chloroplasts during sexual reproduction in C. reinhardtii

Although the active digestion of mating-type minus (mt-) chloroplast DNA (cpDNA) in young zygotes is considered to be the basis for the uniparental inheritance of cpDNA in Chlamydomonas reinhardtii, little is known about the underlying molecular mechanism. One model of active digestion proposes that nucleases are either synthesized or activated to digest mt- cpDNA. We used a native-PAGE/in gelo assay to investigate nuclease activities in chloroplasts from young zygotes, and identified a novel Ca(2+)-dependent nuclease activity. The timing of activation (approximately 60-90 min after mating) and the localization of the nuclease activity (in mt- chloroplasts) coincided with the active digestion of mt- cpDNA. Furthermore, the activity of the nuclease was coregulated with the maturation of mating-type plus (mt+) gametes, which would enable the efficient digestion of mt- cpDNA. Based on these observations, we propose that the nuclease (designated as Mt(+)-specific DNase, MDN) is a developmentally controlled nuclease that is activated in mt+ gametes and participates in the destruction of mt- cpDNA in young zygotes, thereby ensuring uniparental inheritance of chloroplast traits.

A chloroplast-resident DNA methyltransferase is responsible for hypermethylation of chloroplast genes in Chlamydomonas maternal gametes

Chloroplast DNA of the green alga Chlamydomonas reinhardtii is maternally inherited. Methylation mapping directly revealed that, before mating, chloroplast DNA of maternal (mating type plus; mt(+)) gametes is heavily methylated whereas that of paternal (mating type minus; mt(-)) gametes is not. Indirect immunofluorescence analyses with anti-5-methylcytosine mAbs visually showed methylation to occur exclusively in chloroplast DNA of mt(+) gametes, and not in mt(-) gametes or nuclear DNA of either mt. To clarify the relationship between methylation and maternal inheritance of chloroplast DNA, we have isolated and characterized a cDNA encoding a DNA methyltransferase. The deduced protein, CrMET1, consists of 1,344 aa and contains a conserved catalytic domain at the C terminal and a nonconserved N-terminal region. The predicted N-terminal region has an arginine-rich domain, suggesting CrMET1 is transferred to chloroplasts. This finding could be directly shown by green fluorescent protein epifluorescence microscopy analyses. CrMET1 transcripts were found to be absent in both mt(+) and mt(-) vegetative cells. Upon gametogenesis, however, transcript levels clearly increased in mt(+) but not mt(-) cells. These experiments suggest that the CrMET1 protein is located in chloroplasts and that it specifically methylates cytosine residues of chloroplast DNA in mt(+) gametes. This conclusion was further strengthened by the observation that, during gametogenesis, CrMET1 is expressed in a mt(-) mutant, mat-1, whose chloroplast DNA is heavily methylated in gametes and paternally inherited. The results provide evidence that cytosine methylation plays a critical role in maternal inheritance of chloroplast genes in C. reinhardtii.

The active digestion of uniparental chloroplast DNA in a single zygote of Chlamydomonas reinhardtii is revealed by using the optical tweezer

The non-Mendelian inheritance of organelle genes is a phenomenon common to almost all eukaryotes, and in the isogamous alga Chlamydomonas reinhardtii, chloroplast (cp) genes are transmitted from the mating type positive (mt(+)) parent. In this study, the preferential disappearance of the fluorescent cp nucleoids of the mating type negative (mt(-)) parent was observed in living young zygotes. To study the change in cpDNA molecules during the preferential disappearance, the cpDNA of mt(+) or mt(-) origin was labeled separately with bacterial aadA gene sequences. Then, a single zygote with or without cp nucleoids was isolated under direct observation by using optical tweezers and investigated by nested PCR analysis of the aadA sequences. This demonstrated that cpDNA molecules are digested completely during the preferential disappearance of mt(-) cp nucleoids within 10 min, whereas mt(+) cpDNA and mitochondrial DNA are protected from the digestion. These results indicate that the non-Mendelian transmission pattern of organelle genes is determined immediately after zygote formation.

DNA methylation in wheat. Purification and properties of DNA methyltransferase

The origin and function of the large amount of 5-methylcytosine in plant DNA is not well understood. As a tool for in vitro studies of methylcytosine formation in plants we have isolated and characterized the DNA methyltransferase present in germinating wheat embryo. An enzyme fraction enriched 300-fold over the tissue homogenate was obtained by salt extraction of nuclei, chromatography on DEAE-cellulose, Sephadex G-75, blue Sepharose and on DNA immobilized on cellulose. It catalyzes the methylation of cytosine residues in double-stranded DNAs isolated from wheat, maize, calf thymus or bacteria using S-adenosylmethionine as methyl donor. The efficient methylation of both an unmethylated plasmid DNA and its hemimethylated derivative indicate that the wheat DNA methylase can function de novo and in maintenance methylation. A relative molecular mass of 50,000-55,000 was estimated by gel permeation chromatography and sucrose density gradient centrifugation. Polyacrylamide gel electrophoresis showed the presence of a protein of Mr = 50,000 and one other component (Mr = 35,000). The preference for endogenous, double-stranded DNA as substrate and the lower molecular mass distinguish wheat DNA methyltransferase from the DNA methylases obtained from mammalian sources. The properties of the wheat enzyme resemble, however, those of the DNA methylase isolated from the alga Chlamydomonas reinhardii, suggesting that plant cells possess their own type of DNA methyltransferase for the biosynthesis of their high methylcytosine content in DNA.

Loss of chloroplast DNA methylation during dedifferentiation of Chlamydomonas reinhardi gametes

In Chlamydomonas reinhardi the chloroplast DNA (ch;DNA) of mating type plus cells undergoes cyclical methylation and demethylation during the life cycle. Methylation occurs during gametogenesis, and fully differentiated gametes can be dedifferentiated back to vegetative cells which contain nonmethylated chlDNA by the addition of a nitrogen source for growth. We examined the dedifferentiation process and found that the mating ability of gametes was lost rapidly after the start of dedifferentiation at a time when the chlDNA was still methylated. The enzymatic activity of the 200-kilodalton DNA methyltransferase was lost at a rate consistent with the rate of dilution during cell division. Methylation of chlDNA decreased at a slower rate than was expected from cell division alone but was consistent with the continuing activity of the preexisting methyltransferase so long as it was present. These results support the hypothesis that demethylation of chlDNA occurs by dilution out of enzymatic methylating activity rather than by enzymatic demethylation.

Loss of chloroplast DNA methylation during dedifferentiation of Chlamydomonas reinhardi gametes

In Chlamydomonas reinhardi the chloroplast DNA (ch;DNA) of mating type plus cells undergoes cyclical methylation and demethylation during the life cycle. Methylation occurs during gametogenesis, and fully differentiated gametes can be dedifferentiated back to vegetative cells which contain nonmethylated chlDNA by the addition of a nitrogen source for growth. We examined the dedifferentiation process and found that the mating ability of gametes was lost rapidly after the start of dedifferentiation at a time when the chlDNA was still methylated. The enzymatic activity of the 200-kilodalton DNA methyltransferase was lost at a rate consistent with the rate of dilution during cell division. Methylation of chlDNA decreased at a slower rate than was expected from cell division alone but was consistent with the continuing activity of the preexisting methyltransferase so long as it was present. These results support the hypothesis that demethylation of chlDNA occurs by dilution out of enzymatic methylating activity rather than by enzymatic demethylation.

The persistence of maternal inheritance in Chlamydomonas despite hypomethylation of chloroplast DNA induced by inhibitors

We have used inhibitors of methylation to evaluate the proposal that the extent of methylation of chloroplast DNA ( cpDNA ) of the mating type-plus (mt+) parent occurring during gametogenesis in wild-type Chlamydomonas renhardtii is directly correlated with the uniparental transmission of chloroplast genes by this parent [ Sager , R., Grabowy , C. & Sano , H. (1981) Cell 24, 41-47]. As detected by high-pressure liquid chromatography, the methylation of cpDNA was at its lowest level in the vegetative stage; the mt+ cells had a deoxycytidine methylation index (the percentage of deoxycytidine methylated) of 0.5, while the mating type-minus (mt-) index was lower by at least a factor of 3. This basal level of cpDNA methylation increased more than 20-fold after gametogenesis to give a methylation index of 12.1 and 4.3 for mt+ and mt- gametes, respectively. Another striking increase was detected at the 7-hr-zygote stage, resulting in the methylation of nearly half of the total deoxycytidine residues. The extent of zygotic cpDNA methylation was shown to be dependent on the preexisting methylation level of both parental gametic cpDNAs . L-Ethionine and 5-azacytidine effectively inhibited cpDNA methylation during gametogenesis and ensuing zygotic development as shown by both Hpa II/Msp I digestion patterns and HPLC. The transmission of chloroplast genes was analyzed concomitantly with the inhibitor studies. The two inhibitors produced different patterns of inhibition of methylation in mt- and mt+ cells at a given developmental stage. Our overall results demonstrate that the extent of mating type-specific and gamete-specific methylation during gametogenesis is not correlated with the frequency of maternal transmission of chloroplast genes.

Characterization of DNA methyltransferase from bovine thymus cells

A DNA methyltransferase was partially purified from bovine thymus heavy cells. The enzyme has Mr 130 000, and introduces methyl groups from S-adenosylmethionine into the 5 position of cytosines in DNA. Sequence specificity analysis revealed that about 60% of the total methylation occurred in the 5'd(C-G)3' doublet. Single-stranded and hemi-methylated DNAs were methylated at an elevated rate by the enzyme. The kinetic analysis showed that the reaction obeys a random sequential mechanism. These results suggest that the enzyme serves primarily as a maintenance DNA methyltransferase.

Isolation and Characterization of Chloroplast DNA from Chlorella ellipsoidea

A circular DNA molecule was isolated from chloroplasts of Chorella ellipsoidea. The DNA had a buoyant density of 1.695 grams per cubic centimeter (36% GC) and a contour length of 56 micrometers (175 kilobase pairs). The restriction endonuclease analysis gave the same size. Agarose gel electrophoretic patterns of chloroplast DNA digested by several restriction endonucleases were also presented. The digestion by the restriction enzymes, HpaII, MspI, SmaI, and XmaI revealed no appreciable methylation at CG sites in chloroplast DNA.

Pre-adipocyte determination either by insulin or by 5-azacytidine

CHEF/18 is a diploid Chinese hamster cell line of embryonic origin, which is fibroblastic in structure, but behaves like a mesenchymal stem cell line in its ability to differentiate into adipocytes, myoblasts, and chondrocytes. With these cells, adipocyte formation has been divided experimentally into two stages: (i) determination of pre-adipocytes, which have lost the ability to form other cell types while retaining their fibroblast structure; and (ii) commitment or terminal differentiation, in which lipids accumulate, adipocyte structure develops, and cells lose the ability to divide. This paper reports that the first stage can be induced by exposure to 5-azacytidine or 2'-deoxy-5-azacytidine, drugs that also induce CHEF cells to form other mesenchymal cell types, or by growth with added insulin. Pre-adipocytes are distinguished from CHEF stem cells by (i) their inability to form other mesenchymal cell types; and (ii) their rapid accumulation of lipid in response to added insulin. The possibility is discussed that both insulin and the cytidine analogs promote differentiation by the same mechanism, namely changes in the pattern of DNA methylation.

DNA methylation in eukaryotes

The DNA of higher eukaryotes contains one minor base, namely 5-methylcytosine. The distribution of this minor base between different species and different DNA fractions will be considered together with the actual sequences methylated. The properties of the enzyme responsible for DNA modification will be reviewed, particular note being paid to the efficiency of methylation of different DNA substrates. Various possible functions of the 5-methylcytosine in DNA will be considered and particular attention will be paid to the finding that specific modified bases present in DNA not undergoing transcription are absent in the same genes when these are being actively transcribed.