The Conserved miR-51 microRNA Family Is Redundantly Required for Embryonic Development and Pharynx Attachment in Caenorhabditis elegans

A major question about cytokinesis concerns the role of the septin proteins, which localize to the division site in all animal and fungal cells but are essential for cytokinesis only in some cell types. For example, in Schizosaccharomyces pombe, four septins localize to the division site, but deletion of the four genes produces only a modest delay in cell separation. To ask if the S. pombe septins function redundantly in cytokinesis, we conducted a synthetic-lethal screen in a septin-deficient strain and identified seven mutations. One mutation affects Cdc4, a myosin light chain that is an essential component of the cytokinetic actomyosin ring. Five others cause frequent cell lysis during cell separation and map to two loci. These mutations and their dosage suppressors define a signaling pathway (including Rho1 and a novel arrestin) for repairing cell-wall damage. The seventh mutation affects the poorly understood RNA-binding protein Scw1 and severely delays cell separation when combined either with a septin mutation or with a mutation affecting the septin-interacting, anillin-like protein Mid2, suggesting that Scw1 functions in a pathway parallel to that of the septins. Taken together, our results suggest that the S. pombe septins participate redundantly in one or more pathways that cooperate with the actomyosin ring during cytokinesis and that a septin defect causes septum defects that can be repaired effectively only when the cell-integrity pathway is intact.THE fission yeast Schizosaccharomyces pombe provides an outstanding model system for studies of cytokinesis (McCollum and Gould 2001; Balasubramanian et al. 2004; Pollard and Wu 2010). As in most animal cells, successful cytokinesis in S. pombe requires an actomyosin ring (AMR). The AMR begins to assemble at the G₂/M transition and involves the type II myosin heavy chains Myo2 and Myp2 and the light chains Cdc4 and Rlc1 (Wu et al. 2003). Myo2 and Cdc4 are essential for cytokinesis under all known conditions, Rlc1 is important at all temperatures but essential only at low temperatures, and Myp2 is essential only under stress conditions. As the AMR constricts, a septum of cell wall is formed between the daughter cells. The primary septum is sandwiched by secondary septa and subsequently digested to allow cell separation (Humbel et al. 2001; Sipiczki 2007). Because of the internal turgor pressure of the cells, the proper assembly and structural integrity of the septal layers are essential for cell survival.Septum formation involves the β-glucan synthases Bgs1/Cps1/Drc1, Bgs3, and Bgs4 (Ishiguro et al. 1997; Le Goff et al. 1999; Liu et al. 1999, 2002; Martín et al. 2003; Cortés et al. 2005) and the α-glucan synthase Ags1/Mok1 (Hochstenbach et al. 1998; Katayama et al. 1999). These synthases are regulated by the Rho GTPases Rho1 and Rho2 and the protein kinase C isoforms Pck1 and Pck2 (Arellano et al. 1996, 1997, 1999; Nakano et al. 1997; Hirata et al. 1998; Calonge et al. 2000; Sayers et al. 2000; Ma et al. 2006; Barba et al. 2008; García et al. 2009b). The Rho GTPases themselves appear to be regulated by both GTPase-activating proteins (GAPs) and guanine-nucleotide-exchange factors (GEFs) (Nakano et al. 2001; Calonge et al. 2003; Iwaki et al. 2003; Tajadura et al. 2004; Morrell-Falvey et al. 2005; Mutoh et al. 2005; García et al. 2006, 2009a,b). In addition, septum formation and AMR function appear to be interdependent. In the absence of a normal AMR, cells form aberrant septa and/or deposit septal materials at random locations, whereas a mutant defective in septum formation (bgs1) is also defective in AMR constriction (Gould and Simanis 1997; Le Goff et al. 1999; Liu et al. 1999, 2000). Both AMR constriction and septum formation also depend on the septation initiation network involving the small GTPase Spg1 (McCollum and Gould 2001; Krapp and Simanis 2008). Despite this considerable progress, many questions remain about the mechanisms and regulation of septum formation and its relationships to the function of the AMR.One major question concerns the role(s) of the septins. Proteins of this family are ubiquitous in fungal and animal cells and typically localize to the cell cortex, where they appear to serve as scaffolds and diffusion barriers for other proteins that participate in a wide variety of cellular processes (Longtine et al. 1996; Gladfelter et al. 2001; Hall et al. 2008; Caudron and Barral 2009). Despite the recent progress in elucidating the mechanisms of septin assembly (John et al. 2007; Sirajuddin et al. 2007; Bertin et al. 2008; McMurray and Thorner 2008), the details of septin function remain obscure. However, one prominent role of the septins and associated proteins is in cytokinesis. Septins concentrate at the division site in every cell type that has been examined, and in Saccharomyces cerevisiae (Hartwell 1971; Longtine et al. 1996; Lippincott et al. 2001; Dobbelaere and Barral 2004) and at least some Drosophila (Neufeld and Rubin 1994; Adam et al. 2000) and mammalian (Kinoshita et al. 1997; Surka et al. 2002) cell types, the septins are essential for cytokinesis. In S. cerevisiae, the septins are required for formation of the AMR (Bi et al. 1998; Lippincott and Li 1998). However, this cannot be their only role, because the AMR itself is not essential for cytokinesis in this organism (Bi et al. 1998; Korinek et al. 2000; Schmidt et al. 2002). Moreover, there is no evidence that the septins are necessary for AMR formation or function in any other organism. A further complication is that in some cell types, including most Caenorhabditis elegans cells (Nguyen et al. 2000; Maddox et al. 2007) and some Drosophila cells (Adam et al. 2000; Field et al. 2008), the septins do not appear to be essential for cytokinesis even though they localize to the division site.S. pombe has seven septins, four of which (Spn1, Spn2, Spn3, and Spn4) are expressed in vegetative cells and localize to the division site shortly before AMR constriction and septum formation (Longtine et al. 1996; Berlin et al. 2003; Tasto et al. 2003; Wu et al. 2003; An et al. 2004; Petit et al. 2005; Pan et al. 2007; Onishi et al. 2010). Spn1 and Spn4 appear to be the core members of the septin complex (An et al. 2004; McMurray and Thorner 2008), and mutants lacking either of these proteins do not assemble the others at the division site. Assembly of a normal septin ring also depends on the anillin-like protein Mid2, which colocalizes with the septins (Berlin et al. 2003; Tasto et al. 2003). Surprisingly, mutants lacking the septins are viable and form seemingly complete septa with approximately normal timing. These mutants do, however, display a variable delay in separation of the daughter cells, suggesting that the septins play some role(s) in the proper completion of the septum or in subsequent processes necessary for cell separation (Longtine et al. 1996; An et al. 2004; Martín-Cuadrado et al. 2005).It is possible that the septins localize to the division site and yet are nonessential for division in some cell types because their role is redundant with that of some other protein(s) or pathway(s). To explore this possibility in S. pombe, we screened for mutations that were lethal in combination with a lack of septins. The results suggest that the septins cooperate with the AMR during cytokinesis and that, in the absence of septin function, the septum is not formed properly, so that an intact system for recognizing and repairing cell-wall damage becomes critical for cell survival.     

Inferring Bacterial Genome Flux While Considering Truncated Genes

Bacterial gene content variation during the course of evolution has been widely acknowledged and its pattern has been actively modeled in recent years. Gene truncation or gene pseudogenization also plays an important role in shaping bacterial genome content. Truncated genes could also arise from small-scale lateral gene transfer events. Unfortunately, the information of truncated genes has not been considered in any existing mathematical models on gene content variation. In this study, we developed a model to incorporate truncated genes. Maximum-likelihood estimates (MLEs) of the new model reveal fast rates of gene insertions/deletions on recent branches, suggesting a fast turnover of many recently transferred genes. The estimates also suggest that many truncated genes are in the process of being eliminated from the genome. Furthermore, we demonstrate that the ignorance of truncated genes in the estimation does not lead to a systematic bias but rather has a more complicated effect. Analysis using the new model not only provides more accurate estimates on gene gains/losses (or insertions/deletions), but also reduces any concern of a systematic bias from applying simplified models to bacterial genome evolution. Although not a primary purpose, the model incorporating truncated genes could be potentially used for phylogeny reconstruction using gene family content.GENE content variation as a key feature of bacterial genome evolution has been well recognized (Garcia-Vallvé et al. 2000; Ochman and Jones 2000; Snel et al. 2002; Welch et al. 2002; Kunin and Ouzounis 2003; Fraser-Liggett 2005; Tettelin et al. 2005) and gained increasing attention in recent years. Various methods have been employed to study the variation of gene content in the form of gene insertions/deletions (or gene gains/losses); there are studies of population dynamics (Nielsen and Townsend 2004), birth-and-death evolutionary models (Berg and Kurland 2002; Novozhilov et al. 2005), phylogeny-dependent studies including parsimony methods (Mirkin et al. 2003; Daubin et al. 2003a,b; Hao and Golding 2004), and maximum-likelihood methods (Hao and Golding 2006, 2008b; Cohen et al. 2008; Cohen and Pupko 2010; Spencer and Sangaralingam 2009). The pattern of gene presence/absence also contains phylogenetic signals (Fitz-Gibbon and House 1999; Snel et al. 1999; Tekaia et al. 1999) and has been used for phylogenetic reconstruction (Dutilh et al. 2004; Gu and Zhang 2004; Huson and Steel 2004; Zhang and Gu 2004; Spencer et al. 2007a,b). All these studies make use of the binary information of gene presence or absence and neglect the existence of gene segments or truncated genes.Bacterial genomes are known to harbor pseudogenes. An intracellular species Mycobacterium leprae is an extreme case for both the proportion and the number of pseudogenes: estimated as 40% of the 3.2-Mb genome and 1116 genes (Cole et al. 2001). In free-living bacteria, pseudogenes can make up to 8% of the annotated genes in the genome (Lerat and Ochman 2004). Many pseudogenes result from the degradation of native functional genes (Cole et al. 2001; Mira et al. 2001). Pseudogenes could also result from the degradation of transferred genes and might even be acquired directly via lateral gene transfer. For instance, in plant mitochondrial genomes, which have an α-proteobacterial ancestry, most, if not all, of the laterally transferred genes are pseudogenes (Richardson and Palmer 2007). Furthermore, evidence has been documented that gene transfer could take place at the subgenic level in a wide range of organisms, e.g., among bacteria (Miller et al. 2005; Choi and Kim 2007; Chan et al. 2009), between ancient duplicates in archaea (Archibald and Roger 2002), between different organelles (Hao and Palmer 2009; Hao 2010), and between eukaryotes (Keeling and Palmer 2001). A large fraction of pseudogenes have been shown to arise from failed lateral transfer events (Liu et al. 2004) and most of them are transient in bacterial genomes (Lerat and Ochman 2005). Zhaxybayeva et al. (2007) reported that genomes with truncated homologs might erroneously lead to false inferences of “gene gain” rather than multiple instances of “gene loss.” This raises the question of how a false diagnosis of gene absence affects the estimation of insertion/deletion rates. Recently, we showed that the effect of a false diagnosis of gene absence on estimation of insertion/deletion rates is not systematic, but rather more complicated (Hao and Golding 2008a). To further address the problem, a study incorporating the information of truncated genes is highly desirable. This will not only yield more accurate estimates of the rates of gene insertions/deletions, but also provide a quantitative view of the effect of truncated genes on rate estimation, which has been understudied in bacterial genome evolution.In this study, we developed a model that considers the information of truncated genes and makes use of a parameter-rich time-reversible rate matrix. Rate variation among genes is allowed in the model by incorporating a discrete Γ-distribution. We also allow rates to vary on different parts of the phylogeny (external branches vs. internal branches). Consistent with previous studies, the rates of gene insertions/deletions are comparable to or larger than the rates of nucleotide substitution and the rates of gene insertions/deletions are further inflated in closely related groups and on external branches, suggesting high rates of gene turnover of recently transferred genes. The results from the new model also suggest that many recently truncated genes are in the process of being rapidly deleted from the genome. Some other interesting estimates in the model are also presented and discussed. One implication of the study, though not primary, is that the state of truncated genes could serve as an additional phylogenetic character for phylogenetic reconstruction using gene family content.     

Distinct Regulation of Mlh1p Heterodimers in Meiosis and Mitosis in Saccharomyces cerevisiae

Mlh1p forms three heterodimers that are important for mismatch repair (Mlh1p/Pms1p), crossing over during meiosis (Mlh1p/Mlh3p), and channeling crossover events into a specific pathway (Mlh1p/Mlh2p). All four proteins contain highly conserved ATPase domains and Pms1p has endonuclease activity. Studies of the functional requirements for Mlh1p/Pms1p in Saccharomyces cerevisae revealed an asymmetric contribution of the ATPase domains to repairing mismatches. Here we investigate the functional requirements of the Mlh1p and Mlh3p ATPase domains in meiosis by constructing separation of function mutations in Mlh3p. These mutations are analogous to mutations of Mlh1p that have been shown to lead to loss of ATP binding and/or ATP hydrolysis. Our data suggest that ATP binding by Mlh3p is required for meiotic crossing over while ATP hydrolysis is dispensable. This has been seen previously for Mlh1p. However, when mutations that affect ATP hydrolysis by both Mlh3p and Mlh1p are combined within a single cell, meiotic crossover frequencies are reduced. These observations suggest that the function of the Mlh1p/Mlh3p heterodimer requires both subunits to bind ATP but only one to efficiently hydrolyze it. Additionally, two different amino acid substitutions to the same residue (G97) in Mlh3p affect the minor mismatch repair function of Mlh3p while only one of them compromises its ability to promote crossing over. These studies thus reveal different functional requirements among the heterodimers formed by Mlh1p.CROSSING over during meiosis not only generates variation but is also important for providing the necessary interactions between homologous chromosomes that ensure correct segregation at division I of meiosis. Recombination is initiated by the production of programmed double-strand breaks (DSBs), catalyzed by the covalently attached Spo11p (Bergerat et al. 1997; Keeney et al. 1997), aided by a number of proteins (reviewed in Keeney and Neale 2006). DSBs are made at a much higher frequency than crossovers, and designation of only a subset to yield crossovers is thought to occur during early stages of DSB repair (Borner et al. 2004). At least two distinct pathways contribute to the production of crossover events in Saccharomyces cerevisiae. The major pathway is dependent on Msh4p/Msh5p and the mismatch repair proteins Mlh1p and Mlh3p (Ross-MacDonald and Roeder 1994; Hollingsworth et al. 1995; Hunter and Borts 1997; Wang et al. 1999; Abdullah et al. 2004) and the second pathway is dependent on Mus81p/Mms4p endonuclease (de los Santos et al. 2001, 2003).Mitotic mismatch repair (MMR) is the process by which mutations that arise during DNA replication and recombination are recognized and removed (reviewed in Kolodner 1996; Harfe and Jinks-Robertson 2000). Msh2p forms a heterodimer with Msh6p (MutSα) to repair base–base mismatches and small insertions and/or deletions and with Msh3p (MutSβ) to repair large insertions and/or deletions (reviewed in Jiricny 2006). Mlh1p forms heterodimers with Pms1p, Mlh2p, and Mlh3p to coordinate the removal of these mismatches (Prolla et al. 1994; Wang et al. 1999). Mlh1p/Pms1p (MutLα) are involved in the repair of all types of mismatches in combination with MutSα and MutSβ, and in the absence of either protein a mutator phenotype is observed (Habraken et al. 1997, 1998). Mlh1p/Mlh2p (MutLβ) and Mlh1p/Mlh3p (MutLγ) are involved in the MutSβ pathway only, which repairs frameshift mutations caused by insertions or deletions. Consequently mlh3Δ mutants only exhibit a weak mutator phenotype, due to a lesser involvement in mismatch repair and a partial overlap in function with Pms1p (Flores-Rozas and Kolodner 1998; Harfe et al. 2000).Although the MutL homologs interact primarily through their C-terminal domains (Pang et al. 1997; Ban and Yang 1998), it is thought that the N-terminal domains must also interact for the complex to be fully functional (Ban and Yang 1998). Binding of ATP causes the proteins to undergo conformational changes, which are essential for the interaction between the N termini (Ban et al. 1999; Tran and Liskay 2000; Sacho et al. 2008). ATP hydrolysis and subsequent release of ADP is required to allow the protein complex to return to its initial state, completing the cycle so that the subunits are ready to bind ATP again if required. Using mutants of MLH1 and PMS1 that are presumed to be defective for ATP binding and/or ATP hydrolysis, it has been shown that both of these functions are essential for fully effective mismatch repair (Tran and Liskay 2000). However, the ATP binding and ATP hydrolysis mutants of PMS1 exhibited lower mitotic mutation rates than the corresponding MLH1 ATPase mutants, suggesting that there is functional asymmetry within the Mlh1p/Pms1p heterodimer (Tran and Liskay 2000; Hall et al. 2002). Another example of the asymmetry in the contributions of these subunits to function can be seen in assays that measure recombination between diverged sequences (homeologous recombination). The Mlh1p ATPase activity has been shown to be more important for the suppression of homeologous recombination than Pms1p ATPase activity (Welz-Voegele et al. 2002). This functional asymmetry is supported by in vitro biochemical analysis that demonstrated Pms1p has a lower ATP binding affinity than Mlh1p (Hall et al. 2002).As mentioned above, Mlh1p/Mlh3p function in the Msh4p/Msh5p pathway for meiotic recombination (Hunter and Borts 1997; Santucci-Darmanin et al. 2000). The Msh4p/Msh5p complex is thought to act in the stabilization of Holliday junction intermediates to allow their resolution in a crossover configuration (Snowden et al. 2004). The Mlh1p/Mlh3p complex has been suggested to act in the resolution of these structures, either directly or indirectly. Human Pms2 and its yeast homolog, Pms1p, have been shown to possess a latent endonuclease activity, conferred by a motif that is conserved among some of the MutL homologs, including Mlh3p (Kadyrov et al. 2006, 2007). Mutations in the DHQA(X)₂E(X)₄E motif in yeast MLH3 cause defects in both mismatch repair and meiotic recombination equivalent to mlh3Δ, suggesting that Mlh3p may also possess an endonuclease activity that is important for the generation of crossovers (Nishant et al. 2008).ATP binding by Mlh1p has been shown to be important for both of its meiotic functions (crossing over and repair of heteroduplex DNA) (Pang et al. 1997; Tran and Liskay 2000; Hoffmann et al. 2003). In contrast, the ATP hydrolysis mutant mlh1-E31A/mlh1-E31A appears to have no effect on meiotic recombination (Tran and Liskay 2000; Hoffmann et al. 2003). This may partly be explained by in vitro studies demonstrating that this mutant exhibits a low level of ATPase activity (Hall et al. 2002).The meiotic functions of MLH1 can be functionally separated as shown by mutating the same residue, G98, to different amino acids (Hoffmann et al. 2003). The residue G98 is situated in the ATPase motif in the GFRGEAL box (GYRGDAL in Mlh3p), which forms the lid of the ATP binding pocket. Mutations in this motif are predicted to affect ATP binding and/or heterodimerization with Pms1p (Ban and Yang 1998; Ban et al. 1999). Mutating the residue G98 in the ATP binding lid to alanine resulted in defective repair of heteroduplex DNA while crossing over was unaffected, but when the same residue was mutated to valine both mismatch repair and crossover functions were defective (Hoffmann et al. 2003). The mlh1-G98V mutant disrupts the interaction of Mlh1p with Pms1p, while mlh1-G98A does not (Pang et al. 1997). This may contribute to the difference observed in the effect on crossing over as Mlh1p is thought to interact with Pms1p and Mlh3p through the same residues (Wang et al. 1999; Kondo et al. 2001). Consequently if the interaction with Pms1p is affected then it is likely that the interaction with Mlh3p is also disrupted.We constructed mlh3 mutants corresponding to the ATP binding and ATP hydrolysis mutants of mlh1 to explore the role of Mlh3p in meiotic recombination. We also constructed mlh3-G97A and mlh3-G97V mutants, equivalent to the mlh1-G98A/V pair that has been shown to differentially affect the mitotic and meiotic functions of Mlh1p. All mutants were assayed for mitotic mismatch repair, meiotic heteroduplex repair, crossing over, and chromosome segregation.     

Deletion of a Novel F-Box Protein,MUS-10, in Neurospora crassa Leads to Altered Mitochondrial Morphology,Instability of mtDNA and Senescence

While mitochondria are renowned for their role in energy production, they also perform several other integral functions within the cell. Thus, it is not surprising that mitochondrial dysfunction can negatively impact cell viability. Although mitochondria have received an increasing amount of attention in recent years, there is still relatively little information about how proper maintenance of mitochondria and its genomes is achieved. The Neurospora crassa mus-10 mutant was first identified through its increased sensitivity to methyl methanesulfonate (MMS) and was thus believed to be defective in some aspect of DNA repair. Here, we report that mus-10 harbors fragmented mitochondria and that it accumulates deletions in its mitochondrial DNA (mtDNA), suggesting that the mus-10 gene product is involved in mitochondrial maintenance. Interestingly, mus-10 begins to senesce shortly after deletions are visualized in its mtDNA. To uncover the function of MUS-10, we used a gene rescue approach to clone the mus-10 gene and discovered that it encodes a novel F-box protein. We show that MUS-10 interacts with a core component of the Skp, Cullin, F-box containing (SCF) complex, SCON-3, and that its F-box domain is essential for its function in vivo. Thus, we provide evidence that MUS-10 is part of an E3 ubiquitin ligase complex involved in maintaining the integrity of mitochondria and may function to prevent cellular senescence.THE mus-10 mutant was isolated from a screen aimed at identifying Neurospora crassa strains that were sensitive to MMS and therefore likely to lack proper DNA repair mechanisms (Kafer and Perlmutter 1980). Epistasis analyses involving mus-10 suggested that it belonged to the uvs-6 epistasis group, which functions in recombination repair (Kafer and Perlmutter 1980; Kafer 1983). However, mus-10 did not display several phenotypes common to other members of the uvs-6 epistasis group: chromosomal instability, a high sensitivity to histidine, and the inability to produce viable ascospores in homozygous crosses (Newmeyer et al. 1978; Newmeyer and Galeazzi 1978; Kafer and Perlmutter 1980; Kafer 1981; Schroeder 1986; Watanabe et al. 1997; Handa et al. 2000; Sakuraba et al. 2000). Furthermore, the frequencies of spontaneous and radiation-induced mutation observed in mus-10 were similar to those of a wild-type strain (Kafer 1981). Past efforts to uncover the nature of these discrepancies or the function of the mus-10 gene product have been uninformative.The majority of cellular ATP is produced in mitochondria through aerobic respiration, which couples electron flow through respiratory complexes within the mitochondrial inner membrane with oxidative phosphorylation. Besides their role in ATP synthesis, mitochondria are also involved in many other cellular processes including beta-oxidation (Bartlett and Eaton 2004), calcium homeostasis (Gunter et al. 2004; Rimessi et al. 2008), production of iron-sulfur clusters (Zheng et al. 1998; Gerber and Lill 2002; Lill and Muhlenhoff 2005; Rouault and Tong 2005), and apoptosis (Green 2005; Antignani and Youle 2006; Xu and Shi 2007). Although virtually all mitochondrial proteins are encoded within the nucleus, a small number of proteins are encoded by mitochondrial DNA (mtDNA). The integrity of the mitochondrial genome may affect cell survival as mutations in mtDNA accumulate in patients suffering from severe neurological diseases including Alzheimer''s, Huntington''s and Parkinson''s, as well as several types of cancer (Chatterjee et al. 2006; Higuchi 2007; Krishnan et al. 2007; Reeve et al. 2008). The number of mtDNA mutations also increases with age, suggesting a link between mitochondrial dysfunction and ageing (Cortopassi and Arnheim 1990; Corral-Debrinski et al. 1992; Cortopassi et al. 1992; Simonetti et al. 1992; Reeve et al. 2008). Contrary to the single genome in the nucleus, there are several copies of mtDNA in each mitochondrion. Thus, defects in a few mitochondrial genomes do not necessarily lead to mitochondrial dysfunction. Many patients suffering from mitochondrial diseases exhibit heteroplasmy, a phenomenon in which a mixture of wild-type and mutant mtDNAs exist in a single cell. The ratio of wild-type to mutant mtDNAs is critical in determining the penetrance of the genetic defect, where mutant loads >60% are required to cause respiratory chain dysfunction within an individual cell (Boulet et al. 1992; Chomyn et al. 1992; Sciacco et al. 1994).Even though N. crassa strains are generally deemed immortal if they can be subcultured ∼50 times, a wild-type strain was recently reported to senesce after 12,000 hr of growth, implying that this fungus undergoes natural or programmed ageing (Maheshwari and Navaraj 2008; Kothe et al. 2010). However, replicative life span is also influenced by genetic background as certain mutations can cause progressive deterioration of growth, ultimately leading to death. One such example is the nuclear-encoded natural death (nd), which when mutant causes a senescence phenotype correlating with the accumulation of multiple mtDNA deletions (Sheng 1951; Seidel-Rogol et al. 1989). The deletions of mtDNA in nd occurred between two 70- to 701-bp direct repeats, suggesting that the nd gene product regulates recombination, repair, or replication of mtDNA (Bertrand et al. 1993). Another nuclear mutation, senescence (sen), was isolated from N. intermedia and introgressed into N. crassa (Navaraj et al. 2000). Deletions were also observed in the mtDNA of sen mutants, but unlike those occurring in nd were flanked by 6- to 10-bp repeats typically associated with GC-rich palindromic sequences (D''Souza et al. 2005). The nature of the sequences that flanked the mtDNA deletions in these two mutants supported the existence of two distinct systems of mtDNA recombination in N. crassa: a general system of homologous recombination (system I) and a site-specific mechanism (system II), mediated in part by nd and sen, respectively (Bertrand et al. 1993; D''Souza et al. 2005). The nd and sen mutations have been mapped to linkage groups I and V, respectively, but neither gene has been cloned and the precise function of their gene products remains unclear. Two ultraviolet (UV)-sensitive mutants, uvs-4 and uvs-5, are thought to undergo senescence, but unfortunately, these strains have not been studied in great detail (Schroeder 1970; Perkins et al. 1993; Hausner et al. 2006). Premature senescence has also been observed in cytoplasmic mutants of N. crassa including the E35 and ER-3 stopper mutants that harbor large mtDNA deletions, as well as strains that accumulate mitochondrial plasmids capable of inserting into mtDNA through homologous recombination (de Vries et al. 1986; Akins et al. 1989; Myers et al. 1989; Niagro and Mishra 1989; Court et al. 1991; Alves and Videira 1998).While trying to establish the role of MUS-10 in DNA repair, we discovered that the mus-10 mutant exhibited a shortened life span, an abnormal mitochondrial morphology and mtDNA instability. We cloned the mus-10 gene through its ability to complement the MMS sensitivity of the mus-10 mutant and revealed that it encoded a novel F-box protein. This suggested that MUS-10 is part of an Skp, Cullin, F-box containing (SCF) E3 ubiquitin ligase complex that targets proteins for degradation by the 26S proteasome. The data we present in this article offer proof that an SCF complex can regulate both mitochondrial maintenance and cellular senescence.     

Targeted Genome Modification in Mice Using Zinc-Finger Nucleases

Homologous recombination-based gene targeting using Mus musculus embryonic stem cells has greatly impacted biomedical research. This study presents a powerful new technology for more efficient and less time-consuming gene targeting in mice using embryonic injection of zinc-finger nucleases (ZFNs), which generate site-specific double strand breaks, leading to insertions or deletions via DNA repair by the nonhomologous end joining pathway. Three individual genes, multidrug resistant 1a (Mdr1a), jagged 1 (Jag1), and notch homolog 3 (Notch3), were targeted in FVB/N and C57BL/6 mice. Injection of ZFNs resulted in a range of specific gene deletions, from several nucleotides to >1000 bp in length, among 20–75% of live births. Modified alleles were efficiently transmitted through the germline, and animals homozygous for targeted modifications were obtained in as little as 4 months. In addition, the technology can be adapted to any genetic background, eliminating the need for generations of backcrossing to achieve congenic animals. We also validated the functional disruption of Mdr1a and demonstrated that the ZFN-mediated modifications lead to true knockouts. We conclude that ZFN technology is an efficient and convenient alternative to conventional gene targeting and will greatly facilitate the rapid creation of mouse models and functional genomics research.CONVENTIONAL gene targeting technology in mice relies on homologous recombination in embryonic stem (ES) cells to target specific gene sequences, most commonly to disrupt gene function (Doetschman et al. 1987; Kuehn et al. 1987; Thomas and Capecchi 1987). Advantages of gene targeting in ES cells are selective target sequence modification, the ability to insert or delete genetic information, and the stability of the targeted mutations through subsequent generations. There are also potential limitations, including limited rates of germline transmission and strain limitations due to lack of conventional ES cell lines (Ledermann 2000; Mishina and Sakimura 2007). Moving the targeted allele from one strain to another requires 10 generations of backcrosses that take 2–3 years. A minimum of 1 year is necessary for backcrossing if speed congenics is applied (Markel et al. 1997).Zinc-finger nucleases (ZFNs) are fusions of specific DNA-binding zinc finger proteins (ZFPs) and a nuclease domain, such as the DNA cleavage domain of a type II endonuclease, FokI (Kim et al. 1996; Smith et al. 1999; Bibikova et al. 2001). A pair of ZFPs provide target specificity, and their nuclease domains dimerize to cleave the DNA, generating double strand breaks (DSBs) (Mani et al. 2005), which are detrimental to the cell if left unrepaired (Rich et al. 2000). The cell uses two main pathways to repair DSBs: high-fidelity homologous recombination and error-prone nonhomologous end joining (NHEJ) (Lieber 1999; Pardo et al. 2009; Huertas 2010). ZFN-mediated gene disruption results from deletions or insertions frequently introduced by NHEJ. Figure 1 illustrates the cellular events following the injection of a pair of ZFNs targeting the mouse Mdr1a (also known as Abcb1a) gene.Open in a separate windowFigure 1.—The ZFN targeting mechanism. ZFN pairs bind to the target site, and FokI endonuclease domain dimerizes and makes a double strand break between the binding sites. If a DSB is repaired so that the wild-type sequence is restored, ZFNs can bind and cleave again. Otherwise, nonhomologous end joining (NHEJ) introduces deletions or insertions, which change the spacing between the binding sites so that ZFNs might still bind but dimerization or cleavage cannot occur. Insertions or deletions potentially disrupt the gene function.ZFNs have been successfully applied to generate genome modifications in plants (Shukla et al. 2009; Townsend et al. 2009), fruit flies (Bibikova et al. 2002), Caenorhabditis elegans (Morton et al. 2006), cultured mammalian cells (Porteus and Baltimore 2003; Santiago et al. 2008), zebrafish (Doyon et al. 2008; Meng et al. 2008), and most recently in rats (Geurts et al. 2009; Mashimo et al. 2010). The technology is especially valuable for rats because rat ES cell lines have only become available recently (Buehr et al. 2008; Li et al. 2008), and successful homologous recombination-mediated genome modification has not been reported. Previously, ENU mutagenesis (Zan et al. 2003) or transposons (Kitada et al. 2007) were the two main methods for generating gene knockout rats, both of which are random approaches and require labor-intensive and time-consuming screens to obtain the desired gene disruptions.Although ES cell-based knockout technology is widely used in mice, ZFN technology offers three advantages: (i) high efficiency; (ii) drastically reduced timeline, similar to that of creating a transgene (Gordon et al. 1980); and (iii) the freedom to apply the technology in various genetic backgrounds. In addition, no exogenous sequences need to be introduced because selection is not necessary.Here, we created the first genome-engineered mice using ZFN technology. Three genes were disrupted in two different backgrounds: Mdr1a, Jag1, and Notch3 in the FVB/N strain and Jag1 also in the C57BL/6 strain. All founders tested transmitted the genetic modifications through the germline.     

Genetic and Epigenetic Dynamics of a Retrotransposon After Allopolyploidization of Wheat

Allopolyploidy, or the combination of two or more distinct genomes in one nucleus, is usually accompanied by radical genomic changes involving transposable elements (TEs). The dynamics of TEs after an allopolyploidization event are poorly understood. In this study, we analyzed the methylation state and genetic rearrangements of a high copied, newly amplified terminal-repeat retrotransposon in miniature (TRIM) family in wheat termed Veju. We found that Veju insertion sites underwent massive methylation changes in the first four generations of a newly formed wheat allohexaploid. Hypomethylation or hypermethylation occurred in ∼43% of the tested insertion sites; while hypomethylation was significantly predominant in the first three generations of the newly formed allohexaploid, hypermethylation became predominant in the subsequent generation. In addition, we determined that the methylation state of Veju long terminal repeats (LTRs) might be correlated with the deletion and/or insertion of the TE. While most of the methylation changes and deletions of Veju occurred in the first generation of the newly formed allohexaploid, most Veju insertions were seen in the second generation. Finally, using quantitative PCR, we quantitatively assessed the genome composition of Veju in the newly formed allohexaploid and found that up to 50% of Veju LTRs were deleted in the first generation. Retrotransposition bursts in subsequent generations, however, led to increases in Veju elements. In light of these findings, the underlying mechanisms of TRIM rearrangements are discussed.TRANSPOSABLE elements (TEs) are DNA sequences that range in size from several hundred base pairs to >15 kb and that have the ability to move to different locations within the genome. TE movement occurs through either a copy-and-paste mechanism involving RNA intermediates (class 1) or a cut-and-paste mechanism involving DNA intermediates (class 2). Class 1 elements are also called retrotransposons, or retroelements, and comprise two main types: (1) long terminal repeat (LTR) retrotransposons, flanked by LTRs, and (2) non-LTR elements (such as long interspersed nuclear elements and short interspersed nuclear elements).LTR retrotransposons are the most abundant mobile elements in plant genomes (Feschotte et al. 2002), as the replicative mode of retroelement transposition enables the LTR retrotransposon to accrue in high copy number. Indeed, in some grasses, LTR retrotransposons represent up to 90% of the genome (Bennetzen and Kellogg 1997; Feschotte et al. 2002). As such, retrotransposon sequences function well as substrates for illegitimate and unequal recombinations that can lead to a variety of mutations, such as deletions, insertions, translocations, and others (Parisod et al. 2009).The replicative nature of TEs seems to be stimulated by a variety of specific stress conditions (reviewed by Wessler 1996; Capy et al. 2000; Grandbastien et al. 2005), including challenges to the genome such as interspecific hybridization, an idea first proposed by Barbara McClintock 26 years ago (McClintock 1984). Accordingly, allopolyploidization is usually coupled with rapid and reproducible genomic changes, including the elimination of DNA sequences (Liu et al. 1998a,b; Ozkan et al. 2001; Shaked et al. 2001; Adams and Wendel 2005b; Skalicka et al. 2005), gene silencing (Chen and Pikaard 1997; Comai et al. 2000; Kashkush et al. 2002; Simons et al. 2006), alteration of cytosine methylation (Shaked et al. 2001; Madlung et al. 2002; Salmon et al. 2005; Beaulieu et al. 2009; Xu et al. 2009), activation of genes and retrotransposons (Kashkush et al. 2002, 2003; O''Neill et al. 2002), massively altered gene expression patterns (Kashkush et al. 2002; Wang et al. 2006), and organ-specific subfunctionalization, i.e., differential expression of homeoalleles in different tissues and at different developmental stages (Adams et al. 2003; Adams and Wendel 2004). These and other studies (Levy and Feldman 2002; Osborn et al. 2003; Adams and Wendel 2005a; Rapp and Wendel 2005; Chen and Ni 2006; Chen 2007) demonstrate the dynamic nature of allopolyploid plant genomes.Although allopolyploidization has generally been assumed to induce large bursts of TE activity (Matzke and Matzke 1998), several studies that focused on different allopolyploid systems failed to provide any evidence for a transposition burst and offered only limited evidence for the transposition of specific TEs (Madlung et al. 2005; Ainouche et al. 2009; Beaulieu et al. 2009). In newly formed Arabidopsis allopolyploids, no evidence for transposition bursts was reported (Beaulieu et al. 2009), although limited evidence suggested that transposition events occurred in a specific TE called Sunfish (Madlung et al. 2005). Little evidence of TE transposition was found in a natural population of the 150-year-old allopolyploid, Spartina anglica (Ainouche et al. 2009), and no evidence of transposition of Wis 2-1A retrotransposons in a newly formed wheat allotetraploid was present (Kashkush et al. 2003). The results of these works and others indicate that, in the short term, TE proliferation after allopolyploidization may be restricted to a few specific TEs in particular allopolyploidy systems (Parisod et al. 2009).This study entailed a detailed investigation of the methylation patterns and rearrangements of a one terminal-repeat retrotransposon in miniature (TRIM) family in wheat termed Veju. TRIM elements possess the classical structure of LTR retrotransposons, but they are distinguished by their small overall sizes (0.4 to ∼2.5 kb). A nonautonomous retrotransposon, Veju is 2520 bp long with 374 bp of identical LTRs, yet does not contain the proteins required for retrotransposition (Sanmiguel et al. 2002). However, because Veju elements contain polypurine tracts (PPTs) and primer binding sites (PBSs), they are capable of transposing if the retrotransposition proteins are available from another source. In addition, the identical sequences of the Veju 5′ and 3′ LTRs indicate that some members of the Veju family retain retrotransposition activity.In silico analysis of Veju sequences revealed them to be one of the most active and most recently inserted sequences in the wheat genome (Sanmiguel et al. 2002; Sabot et al. 2005a). As such, we have determined and compared the methylation patterns of >880 Veju insertion sites in the first four generations of a newly formed wheat allohexaploid, as well as in the parental lines. We then tested the correlation between the cytosine methylation and genetic rearrangements (i.e., deletions and insertions) of Veju and addressed the precise developmental timing of these rearrangements. Finally, we successfully tested overall changes in the copy numbers of Veju in the newly formed allohexaploid using real-time quantitative PCR.