28 research outputs found
Drosophila piRNA Function in Genome Maintenance, Telomere Protection and Genome Evolution: A Dissertation
Upon fertilization, the early embryo sustains most of the cellular processes using the maternally deposited reserves in the egg itself until the zygotic gene expression takes charge. Among the plethora of essential components provided by the mother are small non-coding RNAs called PIWI-interacting RNAs (piRNAs), which provide immunity to the zygote against transposon challenge. In this thesis, I have presented three different functions of piRNAs in Drosophila melanogaster- in maintenance of genomic integrity, telomere protection and their role as an adaptive immune system against genomic parasites.
In Chapter 2, I have described the phenotypic effects of the loss of piRNA function in early embryos. The mutations affecting the piRNA pathway are known to cause embryonic lethality. To describe this lethality in detail, I have shown that all the characterized piRNA mutants show compromised zygotic genomic integrity during early embryogenesis. In addition, two piRNA pathway components, Aubergine (Aub) and Armitage (Armi) are also required for telomere resolution during early embryogenesis. Aub and Armi recruit telomeric protection complex proteins, HOAP and HP1, to the telomeric ends and thus avoid activation of the Non-homologous end joining (NHEJ) DNA repair pathway at the telomeres.
There are about 120 transposon families in Drosophila melanogaster and piRNA pathway mutations cause activation of many of the resident transposons in the genome. In Chapter 3, I have described the effects of infection by a single transposon, P-element, in naïve strains by introduction through the zygote. Activation of the P-element leads to desilencing of unrelated transposons, causing accumulation of germline DNA damage which is linked to severely reduced fertility in the hybrid females. However, there is partial restoration of fertility as the hybrid progeny age, which correlates with P-element piRNA production and thus P-element silencing.
Additionally, a number of transposons mobilize into piRNA generating heterochromatic clusters in the genome, and these insertions are stably inherited in the progeny. Collectively our data shows that piRNA production can be triggered in the adults in an absence of maternal contribution and that piRNAs serve as an adaptive immune system which helps resolve an internal genetic conflict between the host and the parasite.
In an effort to understand the phenotypic effects of piRNA dysfunction in Drosophila, we have uncovered new exciting roles for piRNAs in development and presented evidence how transposons can act as architects in restructuring the host genome
Distinct Functions for the Drosophila piRNA Pathway in Genome Maintenance and Telomere Protection
Transposons and other selfish DNA elements can be found in all phyla, and mobilization of these elements can compromise genome integrity. The piRNA (PIWI-interacting RNA) pathway silences transposons in the germline, but it is unclear if this pathway has additional functions during development. Here we show that mutations in the Drosophila piRNA pathway genes, armi, aub, ago3, and rhi, lead to extensive fragmentation of the zygotic genome during the cleavage stage of embryonic divisions. Additionally, aub and armi show defects in telomere resolution during meiosis and the cleavage divisions; and mutations in lig-IV, which disrupt non-homologous end joining, suppress these fusions. By contrast, lig-IV mutations enhance chromosome fragmentation. Chromatin immunoprecipitation studies show that aub and armi mutations disrupt telomere binding of HOAP, which is a component of the telomere protection complex, and reduce expression of a subpopulation of 19- to 22-nt telomere-specific piRNAs. Mutations in rhi and ago3, by contrast, do not block HOAP binding or production of these piRNAs. These findings uncover genetically separable functions for the Drosophila piRNA pathway. The aub, armi, rhi, and ago3 genes silence transposons and maintain chromosome integrity during cleavage-stage embryonic divisions. However, the aub and armi genes have an additional function in assembly of the telomere protection complex
piRNAs, transposon silencing, and Drosophila germline development
Transposons are prominent features of most eukaryotic genomes and mobilization of these elements triggers genetic instability. Transposon silencing is particularly critical in the germline, which maintains the heritable genetic complement. Piwi-interacting RNAs (piRNAs) have emerged as central players in transposon silencing and genome maintenance during germline development. In particular, research on Drosophila oogenesis has provided critical insights into piRNA biogenesis and transposon silencing. In this system, the ability to place piRNA mutant phenotypes within a well-defined developmental framework has been instrumental in elucidating the molecular mechanisms underlying the connection between piRNAs and transposon control
Adaptation to P element transposon invasion in Drosophila melanogaster
Transposons evolve rapidly and can mobilize and trigger genetic instability. Piwi-interacting RNAs (piRNAs) silence these genome pathogens, but it is unclear how the piRNA pathway adapts to invasion of new transposons. In Drosophila, piRNAs are encoded by heterochromatic clusters and maternally deposited in the embryo. Paternally inherited P element transposons thus escape silencing and trigger a hybrid sterility syndrome termed P-M hybrid dysgenesis. We show that P-M hybrid dysgenesis activates both P elements and resident transposons and disrupts the piRNA biogenesis machinery. As dysgenic hybrids age, however, fertility is restored, P elements are silenced, and P element piRNAs are produced de novo. In addition, the piRNA biogenesis machinery assembles, and resident elements are silenced. Significantly, resident transposons insert into piRNA clusters, and these new insertions are transmitted to progeny, produce novel piRNAs, and are associated with reduced transposition. P element invasion thus triggers heritable changes in genome structure that appear to enhance transposon silencing
The Drosophila HP1 homolog Rhino is required for transposon silencing and piRNA production by dual-strand clusters
Piwi-interacting RNAs (piRNAs) silence transposons and maintain genome integrity during germline development. In Drosophila, transposon-rich heterochromatic clusters encode piRNAs either on both genomic strands (dual-strand clusters) or predominantly one genomic strand (uni-strand clusters). Primary piRNAs derived from these clusters are proposed to drive a ping-pong amplification cycle catalyzed by proteins that localize to the perinuclear nuage. We show that the HP1 homolog Rhino is required for nuage organization, transposon silencing, and ping-pong amplification of piRNAs. rhi mutations virtually eliminate piRNAs from the dual-strand clusters and block production of putative precursor RNAs from both strands of the major 42AB dual-strand cluster, but not of transcripts or piRNAs from the uni-strand clusters. Furthermore, Rhino protein associates with the 42AB dual-strand cluster,but does not bind to uni-strand cluster 2 or flamenco. Rhino thus appears to promote transcription of dual-strand clusters, leading to production of piRNAs that drive the ping-pong amplification cycle
Stylonychia lemnae DDE_TNP_is1595 contigs
Contigs in fasta format
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Data from: The Oxytricha trifallax macronuclear genome: a complex eukaryotic genome with 16,000 tiny chromosomes
The macronuclear genome of the ciliate Oxytricha trifallax displays an extreme and unique eukaryotic genome architecture with extensive genomic variation. During sexual genome development, the expressed, somatic macronuclear genome is whittled down to the genic portion of a small fraction (~5%) of its precursor “silent” germline micronuclear genome by a process of “unscrambling” and fragmentation. The tiny macronuclear “nanochromosomes” typically encode single, protein-coding genes (a small portion, 10%, encode 2–8 genes), have minimal noncoding regions, and are differentially amplified to an average of ~2,000 copies. We report the high-quality genome assembly of ~16,000 complete nanochromosomes (~50 Mb haploid genome size) that vary from 469 bp to 66 kb long (mean ~3.2 kb) and encode ~18,500 genes. Alternative DNA fragmentation processes ~10% of the nanochromosomes into multiple isoforms that usually encode complete genes. Nucleotide diversity in the macronucleus is very high (SNP heterozygosity is ~4.0%), suggesting that Oxytricha trifallax may have one of the largest known effective population sizes of eukaryotes. Comparison to other ciliates with nonscrambled genomes and long macronuclear chromosomes (on the order of 100 kb) suggests several candidate proteins that could be involved in genome rearrangement, including domesticated MULE and IS1595-like DDE transposases. The assembly of the highly fragmented Oxytricha macronuclear genome is the first completed genome with such an unusual architecture. This genome sequence provides tantalizing glimpses into novel molecular biology and evolution. For example, Oxytricha maintains tens of millions of telomeres per cell and has also evolved an intriguing expansion of telomere end-binding proteins. In conjunction with the micronuclear genome in progress, the O. trifallax macronuclear genome will provide an invaluable resource for investigating programmed genome rearrangements, complementing studies of rearrangements arising during evolution and disease