A barley stripe mosaic virus-based guide RNA delivery system for targeted mutagenesis in wheat and maize

Plant RNA virus-based guide RNA (gRNA) delivery has substantial advantages compared to that of the conventional constitutive promoter-driven expression due to the rapid and robust amplification of gRNAs during virus replication and movement. To date, virus-induced genome editing tools have not been developed for wheat and maize. In this study, we engineered a barley stripe mosaic virus (BSMV)-based gRNA delivery system for clustered regularly interspaced short palindromic repeat (CRISPR)/Cas9-mediated targeted mutagenesis in wheat and maize. BSMV-based delivery of single gRNAs for targeted mutagenesis was first validated in Nicotiana benthamiana. To extend this work, we transformed wheat and maize with the Cas9 nuclease gene and selected the wheat TaGASR7 and maize ZmTMS5 genes as targets to assess the feasibility and efficiency of BSMV-mediated mutagenesis. Positive targeted mutagenesis of the TaGASR7 and ZmTMS5 genes was achieved for wheat and maize with efficiencies of up to 78% and 48%. Our results provide a useful tool for fast and efficient delivery of gRNAs into economically important crops.     

Genome and stresses: Reactions against aggressions,behavior of transposable elements

The action of stresses on the genome can be considered as responses of cells or organisms to external aggressions. Stress factors are of environmental origin (climatic or trophic) or of genomic nature (introduction of foreign genetic material, for example). In both cases, important perturbations can occur and modify hereditary potentialities, creating new combinations compatible with survival; such a situation may increase the variability of the genome, and allow evolutive processes to take place. The behavior of transposable elements under stress conditions is thus of particular interest, since these sequences are sources of mutations and therefore of genetic variability; they may play an important role in population adaptation. The survey of the available experimental results suggests that, although some examples of mutations and transposable elements movements induced by external factors are clearly described, environmental injuries or introduction of foreign material into a genome are not systematically followed by drastic genomic changes.     

Biology,dynamics, and applications of transposable elements in basidiomycete fungi

Applied Microbiology and Biotechnology - The phylum Basidiomycota includes filamentous fungi and yeast species with different ecological and genomic characteristics. Transposable elements (TEs) are...     

Acquisition and loss of modules: the construction set of transposable elements

Phylogenetic analysis of transposable elements (TEs) allows us to define the relationships between the domains or gene(s) that compose them. Moreover, modules of a few amino-acids can be detected within gag, pol, env genes or within the integrase domain of retrotransposons and transposase of DNA elements. The combination of these observations clearly shows that the evolutionary history of TEs is the outcome of the acquisition and loss of modules with differing origins and histories. This raises the question of the origin of TEs: are they derived from viruses? Are they where viruses come from? Do the basic building bricks come from the prokaryotes, and can they be assembled in the eukaryotes? Are the TEs found in prokaryotes the result of the disintegration of complex elements such as retroelements? Do they evolve from the simplest to the more complex, or are they opportunistic sequences evolving by acquiring and/or losing modules which may be either important or superfluous to their fitness (i.e., their ability to transpose). These are some of the questions that are addressed and discussed in the light of the comparative structures of TEs.     

Characterization and application of small RNAs and RNA silencing mechanisms in fungi

Although extensively cataloged and functionally diverse in plants and animals, the role and targets of small RNAs remain mostly uncharacterized in filamentous fungi. To date, much of the knowledge of small RNAs in filamentous fungi has been derived from studies of a limited group of fungi, most notably in Neurospora crassa. While most of the recently discovered classes of small RNAs appear to be unique to fungi some are commonly found in eukaryotes. It is noteworthy that the RNA silencing protein machinery involved in small RNA biogenesis has also diverged greatly, particularly within filamentous fungi, and may explain the diversity of small RNA classes. In this review, we summarize important classes of eukaryotic small RNAs and provide a current analysis of the RNA silencing machinery based on available fungal genome sequences. Finally, we discuss opportunities for exploiting knowledge of small RNAs and RNA silencing for practical application such as engineering plants resistant to fungal pathogens.     

Characterization and application of small RNAs and RNA silencing mechanisms in fungi

Although extensively cataloged and functionally diverse in plants and animals, the role and targets of small RNAs remain mostly uncharacterized in filamentous fungi. To date, much of the knowledge of small RNAs in filamentous fungi has been derived from studies of a limited group of fungi, most notably in Neurospora crassa. While most of the recently discovered classes of small RNAs appear to be unique to fungi some are commonly found in eukaryotes. It is noteworthy that the RNA silencing protein machinery involved in small RNA biogenesis has also diverged greatly, particularly within filamentous fungi, and may explain the diversity of small RNA classes. In this review, we summarize important classes of eukaryotic small RNAs and provide a current analysis of the RNA silencing machinery based on available fungal genome sequences. Finally, we discuss opportunities for exploiting knowledge of small RNAs and RNA silencing for practical application such as engineering plants resistant to fungal pathogens.     

Genome canalization: the coevolution of transposable and interspersed repetitive elements with single copy DNA

Transposable and interspersed repetitive elements (TIREs) are ubiquitous features of both prokaryotic and eukaryotic genomes. However, controversy has arisen as to whether these sequences represent useless selfish DNA elements, with no cellular function, as opposed to useful genetic units.In this review, we selected two insect species, the Dipteran Drosophila and the Lepidopteran Bombyx mori (the silkmoth), in an attempt to resolve this debate. These two species were selected on the basis of the special interest that our laboratory has had over the years in Bombyx with its well known molecular and developmental biology, and the wealth of genetic data that exist for Drosophila. In addition, these two species represent contrasting repetitive element types and patterns of distribution. On one hand, Bombyx exhibits the short interspersion pattern in which Alu-like TIREs predominate while Drosophila possesses the long interspersion pattern in which retroviral-like TIREs are prevalent. In Bombyx, the main TIRE family is Bm-1 while the Drosophila group contains predominantly copia-like elements, non-LTR retroposons, bacterial-type retroposons and fold-back transposable elements sequences. our analysis of the information revealed highly non-random patterns of both TIRE biology and evolution, more indicative of these sequences acting as genomic symbionts under cellular regulation rather than useless or selfish junk DNA. In addition, we extended our analysis of potential TIRE functionality to what is known from other eukaryotic systems. From this study, it became apparent that these DNA elements may have originated as innocuous or selfish sequences and then adopted functions. The mechanism for this conversion from non-functionality to specific roles is a process of Coevolution between the repetitive element and other cellular DNA often times in close physical proximity. The resulting interdependence between repetitive elements and other cellular sequences restrict the number of evolutionarily successful mutational changes for a given fuction or cistron. This mutual limitation is what we call genome canalization. Well documented examples are discussed to support this hypothesis and a mechanistic model is presented for how such genomic canalization can occur. Also proposed are empirical studies which would support or invalidate aspects of this hypothesis.     

Horizontal transmission, vertical inactivation, and stochastic loss of mariner-like transposable elements

Horizontal transmission has been well documented as a major mechanism for the dissemination of mariner-like elements (MLEs) among species. Less well understood are mechanisms that limit vertical transmission of MLEs resulting in the "spotty" or discontinuous distribution observed in closely related species. In this article we present evidence that the genome of the common ancestor of the melanogaster species subgroup of Drosophila contained an MLE related to the mellifera (honey bee) subfamily. Horizontal transmission, approximately 3-10 MYA, is strongly suggested by the observation that the sequence of the MLE in Drosophila erecta is 97% identical in nucleotide sequence with that of an MLE in the cat flea, Ctenocephalides felis. The D. erecta MLE has a spotty distribution among species in the melanogaster subgroup. The element has a high copy number in D. erecta and D. orena, a moderate copy number in D. teissieri and D. yakuba, and was apparently lost ("stochastic loss") in the lineage leading to D. melanogaster, D. simulans, D. mauritiana, and D. sechellia. In D. erecta, most copies are concentrated in the heterochromatin. Two copies from D. erecta, denoted De12 and De19, were cloned and sequenced, and they appear to be nonfunctional ("vertical inactivation"). It therefore appears that the predominant mode of MLE evolution is vertical inactivation and stochastic loss balanced against occasional reinvasion of lineages by horizontal transmission.      

Isolation, analysis and marker utility of novel miniature inverted repeat transposable elements from the barley genome

Four previously undescribed families of miniature inverted repeat transposable elements (MITEs) were isolated by searching barley genomic DNA using structure-based criteria. Putative MITEs were confirmed by PCR to determine their insertional polymorphism in a panel of diverse barley germplasm. Copy numbers for all these familes are somewhat low (less than 1,000 copies per family per haploid genome). In contrast to previous studies, a higher proportion of insertions of the new MITEs are found within known transposable elements (27%) than are associated with genes (15%). Preliminary studies were conducted on two of the new MITE families to test their utility as molecular markers. Insertional polymorphism levels for both the families are high and diversity trees produced by both the families are similar and congruent with known relationships among the germplasm studied, suggesting that both the MITE families are useful markers of barley genetic diversity.     

RNA and protein components of maize streak and cassava latent viruses

Polyacrylamide gel electrophoresis indicated that maize streak (MSV) and cassava latent (CLV) viruses each contain one species of protein and two of RNA. The estimated protein mol. wt is 28000 for MSV and 34000 for CLV. The mol. wts obtained for the two RNA species using formamide-containing gels were the same for the two viruses: 17×10⁸ and 1–3 × 10⁶. It is suggested that the viruses have a two-part genome and that the tendency of their nucleoprotein particles to form pairs favours the delivery of complete genomes to sites of infection.     

Environmentally coordinated epigenetic silencing of FLC by protein and long noncoding RNA components

In Arabidopsis, the role of the vernalization pathway is to repress expression of a potent floral repressor, FLOWERING LOCUS C (FLC), after a sufficient period of winter cold has been perceived. Following winter, the lack of FLC expression allows unimpeded operation of the photoperiod pathway and hence rapid flowering of vernalized plants in spring via the activation of floral integrator genes. Molecular studies revealed that regulation of the key floral repressor, FLC, is under the control of the interplay between Trithorax group (TrxG)-mediated activation and Polycomb group (PcG)-mediated repression. On-off switch of genes by TrxG and PcG is an evolutionarily conserved mechanism to coordinate cellular identity in eukaryotes. Regulation of FLC by external cues provides an excellent model system to study mechanisms in which cell identity is influenced by environment. In this review, we discuss coordinated contributions by protein and long noncoding RNA components to this environmentally induced epigenetic switch of a developmental program in plants.     

Comparison of mitochondrial and nucleolar RNase MRP reveals identical RNA components with distinct enzymatic activities and protein components

RNase MRP is a ribonucleoprotein endoribonuclease found in three cellular locations where distinct substrates are processed: the mitochondria, the nucleolus, and the cytoplasm. Cytoplasmic RNase MRP is the nucleolar enzyme that is transiently relocalized during mitosis. Nucleolar RNase MRP (NuMRP) was purified to homogeneity, and we extensively purified the mitochondrial RNase MRP (MtMRP) to a single RNA component identical to the NuMRP RNA. Although the protein components of the NuMRP were identified by mass spectrometry successfully, none of the known NuMRP proteins were found in the MtMRP preparation. Only trace amounts of the core NuMRP protein, Pop4, were detected in MtMRP by Western blot. In vitro activity of the two enzymes was compared. MtMRP cleaved only mitochondrial ORI5 substrate, while NuMRP cleaved all three substrates. However, the NuMRP enzyme cleaved the ORI5 substrate at sites different than the MtMRP enzyme. In addition, enzymatic differences in preferred ionic strength confirm these enzymes as distinct entities. Magnesium was found to be essential to both enzymes. We tested a number of reported inhibitors including puromycin, pentamidine, lithium, and pAp. Puromycin inhibition suggested that it binds directly to the MRP RNA, reaffirming the role of the RNA component in catalysis. In conclusion, our study confirms that the NuMRP and MtMRP enzymes are distinct entities with differing activities and protein components but a common RNA subunit, suggesting that the RNA must be playing a crucial role in catalytic activity.