X chromosome inactivation and active X upregulation in therian mammals: facts, questions, and hypotheses

X chromosome inactivation is a mechanism that modulates the expression of X-linked genes in eutherian females (XX). Ohno proposed that to achieve a proper balance between X-linked and autosomal genes, those on the active X should also undergo a 2-fold upregulation. Although some support for Ohno's hypothesis has been provided through the years, recent genomic studies testing this hypothesis have brought contradictory results and fueled debate. Thus far, there are as many results in favor as against Ohno's hypothesis, depending on the nature of the datasets and the various assumptions and thresholds involved in the analyses. However, they have confirmed the importance of dosage balance between X-linked and autosomal genes involved in stoichiometric relationships. These facts as well as questions and hypotheses are discussed below.

Dynamic epigenetic states of maize centromeres

The centromere is a specialized chromosomal region identified as the major constriction, upon which the kinetochore complex is formed, ensuring accurate chromosome orientation and segregation during cell division. The rapid evolution of centromere DNA sequence and the conserved centromere function are two contradictory aspects of centromere biology. Indeed, the sole presence of genetic sequence is not sufficient for centromere formation. Various dicentric chromosomes with one inactive centromere have been recognized. It has also been found that de novo centromere formation is common on fragments in which centromeric DNA sequences are lost. Epigenetic factors play important roles in centromeric chromatin assembly and maintenance. Non-disjunction of the supernumerary B chromosome centromere is independent of centromere function, but centromere pairing during early prophase of meiosis I requires an active centromere. This review discusses recent studies in maize about genetic and epigenetic elements regulating formation and maintenance of centromere chromatin, as well as centromere behavior in meiosis.

Engineered minichromosomes in plants

Platforms for the development of synthetic chromosomes in plants have been produced in several species using telomere mediated chromosomal truncation with the simultaneous inclusion of sites that facilitate further additions to the newly generated minichromosome. By utilizing truncated supernumerary or B chromosomes, the output of the genes on the minichromosome can be amplified. Proof of concept experiments have been successful illustrating that minichromosome platforms can be modified in vivo. Engineered minichromosomes can likely be combined with haploid breeding if they are incorporated into inducer lines given that the observations that basically inert chromosomes from haploid inducer lines can be recovered at workable frequencies in otherwise haploid plants. Future needs of synthetic chromosome development are discussed.

Dosage, duplication, and diploidization: clarifying the interplay of multiple models for duplicate gene evolution over time

Requirements to maintain dosage balance shape many genome-scale patterns in organisms, including the resolution of whole genome duplications (WGD), as well as the varied effects of aneuploidy, segmental duplications, tandem duplications, gene copy number variations (CNV), and epigenetic marks. Like neofunctionalization and subfunctionalization, the impact of absolute and relative dosage varies over time. These variations are of particular importance in understanding the role of dosage in the evolution of polyploid organisms. Numerous investigations have found the consequences of polyploidy remain distinct from small-scale duplications (SSD). This observation is significant as all flowering plants have experienced at least two ancient polyploid events, and many angiosperm lineages have undergone additional rounds of polyploidy. Intriguingly, recent studies indicate a link between how epigenetic marks in recent allopolyploids may induce immediate changes in gene expression and the longer-term patterns of biased fractionation and chromosomal evolution. We argue that dosage effects represent one aspect of an emerging pluralistic framework, a framework that will use biophysics, genomic technologies, and systems-level models of cells to broaden our view of how genomes evolve.

Histone phosphorylation: its role during cell cycle and centromere identity in plants

As the main protein components of chromatin, histones can alter the structural/functional capabilities of chromatin by undergoing extensive post-translational modifications (PTMs) such as phosphorylation, methylation, acetylation, ubiquitination, sumoylation, and so on. These PTMs are thought to transmit signals from the chromatin to the cell machinery to regulate various processes. Histone phosphorylation is associated with chromosome condensation/segregation, activation of transcription, and DNA damage repair. In this review, we focus on how different histone phosphorylations mark for chromatin change during the cell cycle, the relationship between histone phosphorylation and functional centromeres, and the candidate kinases that trigger and the phosphatase or kinase inhibitors that alter histone phosphorylation. Finally, we review the crosstalk between different PTMs.

Molecular mechanisms of homologous chromosome pairing and segregation in plants

In most eukaryotic species, three basic steps of pairing, recombination and synapsis occur during prophase of meiosis I. Homologous chromosomal pairing and recombination are essential for accurate segregation of chromosomes. In contrast to the well-studied processes such as recombination and synapsis, many aspects of chromosome pairing are still obscure. Recent progress in several species indicates that the telomere bouquet formation can facilitate homologous chromosome pairing by bringing chromosome ends into close proximity, but the sole presence of telomere clustering is not sufficient for recognizing homologous pairs. On the other hand, accurate segregation of the genetic material from parent to offspring during meiosis is dependent on the segregation of homologs in the reductional meiotic division (MI) with sister kinetochores exhibiting mono-orientation from the same pole, and the segregation of sister chromatids during the equational meiotic division (MII) with kinetochores showing bi-orientation from the two poles. The underlying mechanism of orientation and segregation is still unclear. Here we focus on recent studies in plants and other species that provide insight into how chromosomes find their partners and mechanisms mediating chromosomal segregation.

Polyploids as a "model system" for the study of heterosis

Heterosis research over the past century has focused primarily on diploid plants and animals. This is despite the fact that most heterotic organisms contain polyploid events in their recent and/or ancient past and various important crop species are heterotic polyploids. We present an argument for the study of heterosis within polyploid systems and give examples of how their study can improve current hypotheses and generate new ones. Polyploid systems allow experiments not possible in diploids but the insights gained must be incorporated into models to explain heterosis at all levels.

Interploidy hybridization barrier of endosperm as a dosage interaction

Crosses between plants at different ploidy levels will often result in failure of endosperm development. The basis of this phenomenon has been attributed to parental gene imprinting of genes involved with endosperm development but a review of the data from maize indicates a dosage interaction between the contributions of the female gametophyte and the primary endosperm nucleus to early endosperm development. However, it is noted that parental imprinting is a non-mutational means that can alter dosage sensitive factors and therefore can contribute to this effect. Operationally, the genes determining ploidy hybridization barrier would qualify for Dobzhansky-Muller incompatibilities that prevent gene flow between species.

Does ectopic cell death cause somatic mutations in the neighboring cells by activating transposons?

Ectopic cell death in Drosophila produces a nonautonomous inhibition of RNA interference (RNAi) in neighboring normal cells. The expression of transposable elements (TE) is increased due to this reduction in the silencing mechanism. New insertions of TE have been documented in mutants for RNAi functions. These observations raise the possibility that persistent environmental insults that produce cell death might increase the frequency of somatic mutations, which might trigger somatic genetic disease.

Meiotic behavior of small chromosomes in maize

The typical behavior of chromosomes in meiosis is that homologous pairs synapse, recombine, and then separate at anaphase I. At anaphase II, sister chromatids separate. However, studies of small chromosomes in maize derived from a variety of sources typically have failure of sister chromatid cohesion at anaphase I. This failure occurs whether there is pairing of two copies of a minichromosome or not. These characteristics have implications for managing the transmission of the first generation artificial chromosomes in plants. Procedures to address these issues of minichromosomes are discussed.

Quantitatively increased somatic transposition of transposable elements in Drosophila strains compromised for RNAi

In Drosophila melanogaster, small RNAs homologous to transposable elements (TEs) are of two types: piRNA (piwi-interacting RNA) with size 23-29nt and siRNA (small interfering RNA) with size 19-22nt. The siRNA pathway is suggested to silence TE activities in somatic tissues based on TE expression profiles, but direct evidence of transposition is lacking. Here we developed an efficient FISH (fluorescence in Situ hybridization) based method for polytene chromosomes from larval salivary glands to reveal new TE insertions. Analysis of the LTR-retrotransposon 297 and the non-LTR retroposon DOC shows that in the argonaut 2 (Ago2) and Dicer 2 (Dcr2) mutant strains, new transposition events are much more frequent than in heterozygous strains or wild type strains. The data demonstrate that the siRNA pathway represses TE transposition in somatic cells. Nevertheless, we found that loss of one functional copy of Ago2 or Dcr2 increases somatic transpositions of the elements at a lower level depending on the genetic background, suggesting a quantitative role for RNAi core components on mutation frequency.

Labeling meiotic chromosomes in maize with fluorescence in situ hybridization

Fluorescence in situ hybridization (FISH) can be used to visualize chromosomal features using repetitive or single gene probes above a minimum target size. When applied to meiosis, each chromosome of the karyotypic complement can be identified, which can facilitate an understanding of the interrelationship of different chromosomes during this process. On the other hand, the pachytene stage of early meiosis is characterized by slightly but not strongly condensed chromosomes that permit more detailed analyses of adjacent features than can be achieved with somatic metaphase chromosomes.

Heritable loss of replication control of a minichromosome derived from the B chromosome of maize

During an accumulation regime of a small telomere-truncated B chromosome, a derivative with large variations in size and multiple punctate centromere loci exhibiting amplified copy numbers was discovered. Multiple centromere satellite loci or transgene signals were documented in amplified chromosomes, suggesting over-replication. Immunolocalization studies revealed multiple foci of biochemical markers characteristic of active centromeres such as CENP-C and phosphorylation of histones H3S10 and H2AThr133. The amplified chromosomes exhibit an absence of chromosome disjunction in meiosis I and an infrequent chromosome disjunction in meiosis II. Despite their unusual structure and behavior these chromosomes were observed in the lineage for seven generations during the course of this study. While severely truncated relative to a normal B chromosome, the progenitor minichromosome is estimated to be at least several megabases in size. Given that the centromere and transgene signals at opposite ends of the chromosome generally match in copy number, the replication control is apparently lost over several megabases.

Insights from paleogenomic and population studies into the consequences of dosage sensitive gene expression in plants

Classical studies of plant phenotypes of individuals with whole or partial genome dosage changes led to the concept of genomic balance. Subsequent studies of gene expression in ploidy and aneuploidy series showed a greater number of modulations in aneuploid plants than with whole genome changes leading to the idea that gene expression processes were modulated by stoichiometric changes of interacting regulatory factors. Recent studies of genomic sequences and copy number variants in populations reveal different fates of duplicate genes depending on whole genome or segmental duplication. Following polyploidy formation, members of macromolecular complexes persist in the evolutionary lineage longer than random genes and a complementary pattern is found for segmental duplications in that there is an underrepresentation of members of macromolecular complexes. These and other studies described suggest there are negative fitness consequences when an imbalance occurs for members of macromolecular complexes including regulatory functions.

Messing with Mendel

Paramutation, a phenomenon of epigenetic switching that violates Mendel's Law of Segregation, was first discovered in maize and later observed in other plants. In a recent report in Nature, de Vanssay and colleagues (2012) describe in Drosophila an operationally analogous phenomenon to paramutation that is mediated by piwi-interacting RNAs.

Accumulation of multiple copies of maize minichromosomes

Multiple copies of B chromosomes in maize (Zea mays) can accumulate in the genome using the B chromosome's accumulation mechanism, specifically nondisjunction at the second pollen mitosis and preferential fertilization of the egg. Using this mechanism, we accumulated 4 different-sized minichromosomes derived from the B chromosome to test the chromosome limits of the cell. The accumulation of normal B chromosomes is associated with multiple phenotypes including white stripes and asymmetric leaf blades, but when minichromosomes are accumulated these symptoms are absent. We also found that multiple B chromosome-derived minichromosomes can coexist with A chromosome-derived minichromosomes. During the years that these experiments were conducted, we found many B chromosome rearrangements and fragments, 2 recoverable A chromosome fragments, and observed a minichromosome breakage-fusion-bridge cycle in roots.

Retrotransposon insertion targeting: a mechanism for homogenization of centromere sequences on nonhomologous chromosomes

The centromeres of most eukaryotic organisms consist of highly repetitive arrays that are similar across nonhomologous chromosomes. These sequences evolve rapidly, thus posing a mystery as to how such arrays can be homogenized. Recent work in species in which centromere-enriched retrotransposons occur indicates that these elements preferentially insert into the centromeric regions. In two different Arabidopsis species, a related element was recognized in which the specificity for such targeting was altered. These observations provide a partial explanation for how homogenization of centromere DNA sequences occurs.

Synthetic chromosome platforms in plants

Synthetic chromosomes provide the means to stack transgenes independently of the remainder of the genome. Combining them with haploid breeding could provide the means to transfer many transgenes more easily among varieties of the same species. The epigenetic nature of centromere formation complicates the production of synthetic chromosomes. However, telomere-mediated truncation coupled with the introduction of site-specific recombination cassettes has been used to produce minichromosomes consisting of little more than a centromere. Methods that have been developed to modify genes in vivo could be applied to minichromosomes to improve their utility and to continue to increase their length and genic content. Synthetic chromosomes establish the means to add or subtract multiple transgenes, multigene complexes, or whole biochemical pathways to plants to change their properties for agricultural applications or to use plants as factories for the production of foreign proteins or metabolites.

Inactivation of a centromere during the formation of a translocation in maize

Fluorescence in situ hybridization analysis of a reciprocal translocation in maize between chromosomes 1 and 5 that has been used extensively in maize genetics revealed the presence of an inactive centromere at or near the breakpoints of the two chromosomes. This centromere contains both the satellite repeat, CentC, and the centromeric retrotransposon family, CRM, that are typical of centromere regions in maize. This site does not exhibit any of the tested biochemical features of active centromeres such as association with CENP-C and phosphorylation of serine-10 on histone H3. The most likely scenario for this chromosome arrangement is that a centromere was included in the repair process that formed the translocation but became inactive and has been inherited in this state for several decades. The documentation of an inactive A chromosome centromere in maize extends the evidence for an epigenetic component to centromere function in plants. This case provides an experimental example of how karyotype evolution might proceed via changes in centromere inactivation.

Reflections on the inhibition of RNAi by cell death signaling

Mutations and most transgenes that induce ectopic cell death in Drosophila will produce an inhibitory effect on RNA interference (RNAi) in adjacent cells. When extensive cell death is sporadically induced using a heat shock promoted-head involution defective (hs-hid) transgene, molecular attributes of this inhibition can be studied. For a Green Fluorescent Protein (GFP) RNAi construct, cell death causes a greater accumulation of the mature mRNA and the double stranded RNA with an accompanying reduction in the homologous siRNAs. Endogenous transposable element expression is increased and there is an overall reduction in their corresponding siRNAs. The implications of this finding for the conduct of RNAi and potential reasons for its existence are discussed.