The amount of heterochromatic proteins in the egg is correlated with sex determination in <Emphasis Type="Italic">Planococcus citri</Emphasis> (Homoptera,Coccoidea)

In the mealybug Planococcus citri, there are no identifiable sex chromosomes. Early in the development of embryos destined to become males, the genome contributed by the sperm undergoes heterochromatization and, following an inverted type of meiosis, will be eliminated. Only two vital sperms are therefore produced, both carrying the same maternally derived genome. A differential distribution observed on the two spermatids during male germline cyst formation of chromatin remodeling factors such as HP1 and methylated K9 histone H3 prompted us to propose an imprinting/sex determination model in which the imprinted sperm is the one to undergo heterochromatization at syngamy. The sex ratio is normally 1:1, but aged females are known to produce almost exclusively male progeny, suggesting that the imprinting pattern of the male gamete in P. citri, though necessary, is apparently not sufficient for sex determination. We report here that egg cells of aged females show larger amounts of HP1 and Su(Var)3–9 than egg cells of young females. These data suggest that a determinant of sex may be the amount of maternally derived heterochromatic proteins.     

Epigenetic marks for chromosome imprinting during spermatogenesis in coccids

The establishment of sex-specific epigenetic marks during gametogenesis is one of the key feature of genomic imprinting. By immunocytological analysis, we thoroughly characterized the chromatin remodeling events that take place during gametogenesis in the mealybug Planococcus citri, in which an entire haploid set of (imprinted) chromosomes undergoes facultative heterochromatinization in male embryos. Building on our previous work, we have investigated the interplay of several epigenetic marks in the regulation of this genome-wide phenomenon. We characterized the germline patterns of histone modifications, Me(3)K9H3, Me(2)K9H3, and Me(3)K20H4, and of heterochromatic proteins, PCHET2 (HP1-like) and HP2-like during male and female gametogenesis. We found that at all stages in oogenesis chromatin is devoid of any detectable epigenetic marks. On the other hand, spermatogenesis is accompanied by a complex pattern of redistribution of epigenetic marks from euchromatin to heterochromatin, and vice versa. At the end of spermatogenesis, sperm heads are decorated by all the molecules we tested, except for PCHET2. However, only Me(3)K9H3 and Me(2)K9H3 are still detectable in the male pronucleus. We suggest that the histone H3 lysine 9 methylation is the signal used to establish the male-specific imprinting on the paternal genome, thus allowing it to be distinguished from the maternal genome in the developing embryo. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Imprinted facultative heterochromatization in mealybugs

In lecanoid Coccids, or mealybugs, the male development is accompanied by the facultative heterochromatization of the entire, paternally derived, haploid chromosome set. This epigenetic phenomenon occurs in all the cells of mid-cleavage male embryos. Consequently, the Coccid chromosome system offers a powerful tool for gaining insights into the structure of facultative heterochromatin, and into the epigenetic mechanisms of its imprinted, developmentally regulated formation. This paper will present new data and summarize recent studies on genomic imprinting and facultative heterochromatization in mealybugs. First, the existence and the possible role of DNA methylation as an epigenetic modification that fulfills the requisites of the imprinting process in mealybugs will be considered. The second part of this paper will focus on proteins involved in the facultative heterochromatization process. In particular, the involvement of an HP-1-like protein in the silencing of the paternally derived haploid chromosome set and its interaction with the lysine 9 methylated isoform of histone H3 will be discussed.     

Germline histone dynamics and epigenetics

Germ cells have the same DNA sequence as somatic cells, but the processes that act on their chromatin are different. Germline chromatin undergoes a series of dramatic remodeling events during the life cycle of an organism. Different aspects of germline chromatin have been dissected in recent years, such as differences between the sex chromosomes and autosomes in histone variants and modifications. Excitingly, histone dynamics have recently been implicated in imprinted X inactivation and genomic imprinting processes that are independent of DNA methylation. Taken together with observations of core histone retention in mature sperm of diverse animals, histones have become prime candidates for mediating germline epigenetic inheritance.     

Cathepsin L stabilizes the histone modification landscape on the Y chromosome and pericentromeric heterochromatin

Posttranslational histone modifications and histone variants form a unique epigenetic landscape on mammalian chromosomes where the principal epigenetic heterochromatin markers, trimethylated histone H3(K9) and the histone H2A.Z, are inversely localized in relation to each other. Trimethylated H3(K9) marks pericentromeric constitutive heterochromatin and the male Y chromosome, while H2A.Z is dramatically reduced at these chromosomal locations. Inactivation of a lysosomal and nuclear protease, cathepsin L, causes a global redistribution of epigenetic markers. In cathepsin L knockout cells, the levels of trimethylated H3(K9) decrease dramatically, concomitant with its relocation away from heterochromatin, and H2A.Z becomes enriched at pericentromeric heterochromatin and the Y chromosome. This change is also associated with global relocation of heterochromatin protein HP1 and histone H3 methyltransferase Suv39h1 away from constitutive heterochromatin; however, it does not affect DNA methylation or chromosome segregation, phenotypes commonly associated with impaired histone H3(K9) methylation. Therefore, the key constitutive heterochromatin determinants can dynamically redistribute depending on physiological context but still maintain the essential function(s) of chromosomes. Thus, our data show that cathepsin L stabilizes epigenetic heterochromatin markers on pericentromeric heterochromatin and the Y chromosome through a novel mechanism that does not involve DNA methylation or affect heterochromatin structure and operates on both somatic and sex chromosomes.     

Chromatin regulators of genomic imprinting

Genomic imprinting is an epigenetic phenomenon in which genes are expressed monoallelically in a parent-of-origin-specific manner. Each chromosome is imprinted with its parental identity. Here we will discuss the nature of this imprinting mark. DNA methylation has a well-established central role in imprinting, and the details of DNA methylation dynamics and the mechanisms that target it to imprinted loci are areas of active investigation. However, there is increasing evidence that DNA methylation is not solely responsible for imprinted expression. At the same time, there is growing appreciation for the contributions of post-translational histone modifications to the regulation of imprinting. The integration of our understanding of these two mechanisms is an important goal for the future of the imprinting field. This article is part of a Special Issue entitled: Chromatin and epigenetic regulation of animal development.     

How imprinting centres work

Imprinted genes tend to be clustered in the genome. Most of these clusters have been found to be under the control of discrete DNA elements called imprinting centres (ICs) which are normally differentially methylated in the germline. ICs can regulate imprinted expression and epigenetic marks at many genes in the region, even those which lie several megabases away. Some of the molecular and cellular mechanisms by which ICs control other genes and regulatory regions in the cluster are becoming clear. One involves the insulation of genes on one side of the IC from enhancers on the other, mediated by the insulator protein CTCF and higher-order chromatin interactions. Another mechanism may involve non-coding RNAs that originate from the IC, targeting histone modifications to the surrounding genes. Given that several imprinting clusters contain CTCF dependent insulators and/or non-coding RNAs, it is likely that one or both of these two mechanisms regulate imprinting at many loci. Both mechanisms involve a variety of epigenetic marks including DNA methylation and histone modifications but the hierarchy of and interactions between these modifications are not yet understood. The challenge now is to establish a chain of developmental events beginning with differential methylation of an IC in the germline and ending with imprinting of many genes, often in a lineage dependent manner.     

piRNAs, transposon silencing, and germline genome integrity

Integrity of the germline genome is essential for the production of viable gametes and successful reproduction. In mammals, the generation of gametes involves extensive epigenetic changes (DNA methylation and histone modification) in conjunction with changes in chromosome structure to ensure flawless progression through meiotic recombination and packaging of the genome into mature gametes. Although epigenetic reprogramming is essential for mammalian reproduction, reprogramming also provides a permissive window for exploitation by transposable elements (TEs), autonomously replicating endogenous elements. Expression and propagation of TEs during the reprogramming period can result in insertional mutagenesis that compromises genome integrity leading to reproductive problems and sporadic inherited diseases in offspring. Recent work has identified the germ cell associated PIWI Interacting RNA (piRNA) pathway in conjunction with the DNA methylation and histone modification machinery in silencing TEs. In this review we will highlight these recent advances in piRNA mediated regulation of TEs in the mouse germline, as well as mention the repercussions of failure to properly regulate TEs.     

Genomic imprinting mechanisms in mammals

Genomic imprinting is a form of epigenetic gene regulation that results in expression from a single allele in a parent-of-origin-dependent manner. This form of monoallelic expression affects a small but growing number of genes and is essential to normal mammalian development. Despite extensive studies and some major breakthroughs regarding this intriguing phenomenon, we have not yet fully characterized the underlying molecular mechanisms of genomic imprinting. This is in part due to the complexity of the system in that the epigenetic markings required for proper imprinting must be established in the germline, maintained throughout development, and then erased before being re-established in the next generation's germline. Furthermore, imprinted gene expression is often tissue or stage-specific. It has also become clear that while imprinted loci across the genome seem to rely consistently on epigenetic markings of DNA methylation and/or histone modifications to discern parental alleles, the regulatory activities underlying these markings vary among loci. Here, we discuss different modes of imprinting regulation in mammals and how perturbations of these systems result in human disease. We focus on the mechanism of genomic imprinting mediated by insulators as is present at the H19/Igf2 locus, and by non-coding RNA present at the Igf2r and Kcnq1 loci. In addition to imprinting mechanisms at autosomal loci, what is known about imprinted X-chromosome inactivation and how it compares to autosomal imprinting is also discussed. Overall, this review summarizes many years of imprinting research, while pointing out exciting new discoveries that further elucidate the mechanism of genomic imprinting, and speculating on areas that require further investigation.     

Regulatory mechanisms of mammalian imprinting

Epigenetic modifications, such as monoallelic DNA methylation, covalent histone modifications, nonhistone proteins, chromatin folding, heterochromatinization, spatial nucleus organization are reviewed with regard to establishment and maintenance of imprinting in mammals. Special attention is paid to repeated DNA sequences as intermediates of the above epigenetic modifications. A suggestion is put forward relative to importance of preimplantation development, in particular, to chromosome organization and segregation in the establishment of imprinting. Some futher directions of imprinting mechanisms are also discussed.     

Epigenetic transitions in germ cell development and meiosis

Germ cell development is controlled by unique gene expression programs and involves epigenetic reprogramming of histone modifications and DNA methylation. The central event is meiosis, during which homologous chromosomes pair and recombine, processes that involve histone alterations. At unpaired regions, chromatin is repressed by meiotic silencing. After meiosis, male germ cells undergo chromatin remodeling, including histone-to-protamine replacement. Male and female germ cells are also differentially marked by parental imprints, which contribute to sex determination in insects and mediate genomic imprinting in mammals. Here, we review epigenetic transitions during gametogenesis and discuss novel insights from animal and human studies.     

HP1γ links histone methylation marks to meiotic synapsis in mice

During meiosis, specific histone modifications at pericentric heterochromatin (PCH), especially histone H3 tri- and dimethylation at lysine 9 (H3K9me3 and H3K9me2, respectively), are required for proper chromosome interactions. However, the molecular mechanism by which H3K9 methylation mediates the synapsis is not yet understood. We have generated a Cbx3-deficient mouse line and performed comparative analysis on Suv39h1/h2-, G9a- and Cbx3-deficient spermatocytes. This study revealed that H3K9me2 at PCH depended on Suv39h1/h2-mediated H3K9me3 and its recognition by the Cbx3 gene product HP1γ. We further found that centromere clustering and synapsis were commonly affected in G9a- and Cbx3-deficient spermatocytes. These genetic observations suggest that HP1γ/G9a-dependent PCH-mediated centromere clustering is an axis for proper chromosome interactions during meiotic prophase. We propose that the role of the HP1γ/G9a axis is to retain centromeric regions of unpaired homologous chromosomes in close alignment and facilitate progression of their pairing in early meiotic prophase. This study also reveals considerable plasticity in the interplay between different histone modifications and suggests that such stepwise and dynamic epigenetic modifications may play a pivotal role in meiosis.     

Epimutations of imprinted genes in the human genome: Classification,causes, association with hereditary pathology

Genomic imprinting is an epigenetic phenomenon characterized by monoallelic expression of the genes depending on their parental origin. The molecular basis of this expression is covalent modifications of DNA and histones that are formed during maturation of germline cells. Abnormalities of the establishment of genomic imprinting during gametogenesis or its maintenance at various stages of development, caused by aberrant epigenetic modifications of the chromatin, predominantly disturbance of DNA methylation state, are a form of mutational variability of imprinted genomic loci. In this review, we consider the spectrum of epimutations of imprinted genes, present their classification, and discuss possible causes of their appearance and their role in etiology of hereditary human diseases.     

Parental genomic imprinting in plants: significance for reproduction

Parental genomic imprinting is an epigenetic phenomenon causing the expression of a gene from one of the two parental alleles. Imprinting has been identified in plants and mammals. Recent evidence shows that DNA methylation and histone modifications are responsible for this parent-of-origin dependent expression of imprinted genes. We review the mechanisms and functions of imprinting in plants. We further describe the significance of imprinting for reproduction and discuss potential models for its evolution.     

Paternal imprinting of the SLC22A1LS gene located in the human chromosome segment 11p15.5

Background  

Genomic imprinting is an epigenetic chromosomal modification in the gametes or zygotes that results in a non-random monoallelic expression of specific autosomal genes depending upon their parent of origin. Approximately 44 human genes have been reported to be imprinted. A majority of them are clustered, including some on chromosome segment 11p15.5. We report here the imprinting status of the SLC22A1LS gene from the human chromosome segment 11p15.5     

Etablissement de l’empreinte parentale dans la lignée germinale. Conséquences pour la prise en charge en AMP

Genomic imprinting is an epigenetic phenomenon in eutherian mammals that results in the differential expression of the paternally and maternally inherited alleles of a gene. Imprinted genes are necessary for normal mammalian development. Parental specific epigenetic modifications are imprinted on a subset of genes in the mammalian genome during germ cell maturation. Imprinting involves both cytosine methylation within CpG islands and changes in chromatin structure. All such epigenetic modifications are potentially reversible and can be erased. After the erasure step, new parental imprints are initiated, resulting in reintroduction of sex-specific imprints in the male and female germ line. Although the function of genomic imprinting is not clear, it has been proposed that it evolved in mammals to regulate intrauterine growth and mammalian development. If the epigenotype of individual gametes is directly correlated with their later developmental capacities, genomic imprinting would have important practical implications in reproductive medicine for the use of embryos derived from assisted reproduction.