Eater: a big bite into phagocytosis

The phagocytosis of invading microorganisms by specialized blood cells is a crucial element of innate immunity in both mammals and insects. In this issue of Cell, Kocks et al. (2005) demonstrate that Eater, a scavenger receptor, plays an important role in the recognition and phagocytosis of bacteria in the fruit fly Drosophila.     

Quantification of random mutations in the mitochondrial genome

Mitochondrial DNA (mtDNA) mutations contribute to the pathology of a number of age-related disorders, including Parkinson disease [A. Bender et al., Nat. Genet. 38 (2006) 515,Y. Kraytsberg et al., Nat. Genet. 38 (2006) 518], muscle-wasting [J. Wanagat, Z. Cao, P. Pathare, J.M. Aiken, FASEB J. 15 (2001) 322], and the metastatic potential of cancers [K. Ishikawa et al., Science 320 (2008) 661]. The impact of mitochondrial DNA mutations on a wide variety of human diseases has made it increasingly important to understand the mechanisms that drive mitochondrial mutagenesis. In order to provide new insight into the etiology and natural history of mtDNA mutations, we have developed an assay that can detect mitochondrial mutations in a variety of tissues and experimental settings [M. Vermulst et al., Nat. Genet. 40 (2008) 4, M. Vermulst et al., Nat. Genet. 39 (2007) 540]. This methodology, termed the Random Mutation Capture assay, relies on single-molecule amplification to detect rare mutations among millions of wild-type bases [J.H. Bielas, L.A. Loeb, Nat. Methods 2 (2005) 285], and can be used to analyze mitochondrial mutagenesis to a single base pair level in mammals.     

ROS: really involved in oxygen sensing

The role of reactive oxygen species (ROS) in the cellular response to cellular oxygen sensing has been controversial. Three papers in this issue of Cell Metabolism (Brunelle et al., Guzy et al., 2005; Mansfield et al., 2005) used genetic tools to establish that ROS produced by mitochondria are required for the normal induction of HIF (hypoxia-inducible factor), which is a master regulator of oxygen-sensitive gene expression, by low oxygen.     

118 DNA structure-induced genetic instability in mammals

Naturally occurring repetitive DNA sequences can adopt alternative (i.e. non-B) DNA secondary structures, and often co-localize with chromosomal breakpoint “hotspots,” implicating non-B DNA in translocation-related cancer etiology. We have found that sequences capable of adopting H-DNA and Z-DNA structures are intrinsically mutagenic in mammals. For example, an endogenous H-DNA-forming sequence from the human c-MYC promoter and a model Z-DNA-forming CpG repeat induced genetic instability in mammalian cells, largely in the form of deletions resulting from DNA double-strand breaks (Wang & Vasquez, 2004; Wang et al., 2006). Characterization of the mutants revealed microhomologies at the breakpoints, consistent with a microhomology-mediated end-joining repair of the double-strand breaks (Kha et al., 2010). We have constructed transgenic mutation-reporter mice containing these human H-DNA- and Z-DNA-forming sequences to determine their effects on genomic instability in a chromosomal context in a living organism (Wang et al., 2008). Initial results suggest that both H-DNA- and Z-DNA-forming sequences induced genetic instability in mice, suggesting that these non-B DNA structures represent endogenous sources of genetic instability and may contribute to disease etiology and evolution. Our current studies are designed to determine the mechanisms of DNA structure-induced genetic instability in mammals; the roles of helicases, polymerases, and repair enzymes in H-DNA and Z-DNA-induced genetic instability will be discussed.     

The intestinal heme transporter revealed

The iron-containing porphyrin heme provides a rich source of dietary iron for mammals. The fact that animals can derive iron from heme implies the existence of a transporter that would transport heme from the gut lumen into intestinal epithelial cells. In this issue of Cell, Shayeghi, McKie, and co-workers (Shayeghi et al., 2005) now describe a heme transporter that is expressed in the apical region of epithelial cells in the mouse duodenum. Their identification of heme carrier protein 1 (HCP1) provides a major missing piece in our understanding of iron uptake and mammalian nutrition.     

PKR and eIF2alpha: integration of kinase dimerization, activation, and substrate docking

The antiviral RNA-dependent protein kinase, PKR, binds to viral double-stranded RNA in the cell and halts protein synthesis by phosphorylating the alpha subunit of the translation initiation factor eIF2. In this issue of Cell, two complementary papers Dar et al. (2005) and Dey et al. (2005) address the interaction between PKR and eIF2alpha. The structures of eIF2alpha bound to PKR reveal that PKR forms a dimer, the interface of which is essential for kinase activation, and demonstrate how this protein substrate docks to its kinase. The structures, coupled with mutagenesis analysis, also demonstrate how phosphorylation of the activation loop can allosterically couple two distal regions, the dimerization and substrate recognition interfaces.     

P53 and the defenses against genome instability caused by transposons and repetitive elements

The recent publication by Wylie et al. is reviewed, demonstrating that the p53 protein regulates the movement of transposons. While this work presents genetic evidence for a piRNA‐mediated p53 interaction with transposons in Drosophila and zebrafish, it is herein placed in the context of a decade or so of additional work that demonstrated a role for p53 in regulating transposons and other repetitive elements. The line of thought in those studies began with the observation that transposons damage DNA and p53 regulates DNA damage. The presence of transposon movement can increase the rate of evolution in the germ line and alter genes involved in signal transduction pathways. Transposition can also play an important role in cancers where the p53 gene function is often mutated. This is particularly interesting as recent work has shown that de‐repression of repetitive elements in cancer has important consequences for the immune system and tumor microenvironment.     

Saving the ends for last: the role of pol mu in DNA end joining

At least three DNA polymerases participate in nonhomologous end joining in mammalian cells: pol mu, pol kappa, and TdT. A study in this issue of Molecular Cell (Nick McElhinny et al., 2005) clarifies the role of pol mu in end joining at the kappa light chain locus and also provides a biochemical explanation for the unique polymerization functions of pol mu on DNA ends.     

Where do we stand now? Mouse early embryo patterning meeting in Freiburg, Germany (2005)

Mechanism underlying mammalian preimplantation development has long been a subject of controversy and the central question has been if any "determinants" play a key role in a manner comparable to the non-mammalian "model" system. During the last decade, this issue has been revived (Pearson, 2002; Rossant and Tam, 2004) by claims that the axes of the mouse blastocyst are anticipated at the egg ("prepatterning model"; Gardner, 1997; Gardner, 2001; Piotrowska et al., 2001; Piotrowska and Zernicka-Goetz, 2001; Zernicka-Goetz, 2005), suggesting that a mechanism comparable to that operating in non-mammals may be at work. However, recent studies by other laboratories do not support these claims ("regulative model"; Alarcon and Marikawa, 2003; Chroscicka et al., 2004; Hiiragi and Solter, 2004; Alarcon and Marikawa, 2005; Louvet-Vallee et al., 2005; Motosugi et al., 2005) and the issue is currently under hot debate (Vogel, 2005). Deepening our knowledge of this issue will not only provide an essential basis for understanding mammalian development, but also directly apply to ongoing clinical practices such as intracytoplasmic sperm injection (ICSI) and preimplantation genetic diagnosis (PGD). These practices were originally supported by a classical premise that mammalian preimplantation embryos are highly regulative (Tarkowski, 1959; Tarkowski, 1961; Tarkowski and Wroblewska, 1967; Rossant, 1976), in keeping with the "regulative model". However, if the "prepatterning model" is correct, the latter will require critical reassessment.     

DNA transposons: nature and applications in genomics

Repeated DNA makes up a large fraction of a typical mammalian genome, and some repetitive elements are able to move within the genome (transposons and retrotransposons). DNA transposons move from one genomic location to another by a cut-and-paste mechanism. They are powerful forces of genetic change and have played a significant role in the evolution of many genomes. As genetic tools, DNA transposons can be used to introduce a piece of foreign DNA into a genome. Indeed, they have been used for transgenesis and insertional mutagenesis in different organisms, since these elements are not generally dependent on host factors to mediate their mobility. Thus, DNA transposons are useful tools to analyze the regulatory genome, study embryonic development, identify genes and pathways implicated in disease or pathogenesis of pathogens, and even contribute to gene therapy. In this review, we will describe the nature of these elements and discuss recent advances in this field of research, as well as our evolving knowledge of the DNA transposons most widely used in these studies.     

Expression of various genes is controlled by DNA methylation during mammalian development

Despite thousands of articles about 5-methylcytosine (m(5)C) residues in vertebrate DNA, there is still controversy concerning the role of genomic m(5)C in normal vertebrate development. Inverse correlations between expression and methylation are seen for many gene regulatory regions [Heard et al., 1997; Attwood et al., 2002; Plass and Soloway, 2002] although much vertebrate DNA methylation is in repeated sequences [Ehrlich et al., 1982]. At the heart of this debate is whether vertebrate DNA methylation has mainly a protective role in limiting expression of foreign DNA elements and endogenous transposons [Walsh and Bestor, 1999] or also is important in the regulation of the expression of diverse vertebrate genes involved in differentiation [Attwood et al., 2002]. Enough thorough studies have now been reported to show that many tissue- or development-specific changes in methylation at vertebrate promoters, enhancers, or insulators regulate expression and are not simply inconsequential byproducts of expression differences. One line of evidence comes from mutants with inherited alterations in genes encoding DNA methyltransferases and from rodents or humans with somatically acquired changes in DNA methylation that illustrate the disease-producing effects of abnormal methylation. Another type of evidence derives from studies of in vivo correlations between tissue-specific changes in DNA methylation and gene expression coupled with experiments demonstrating cause-and-effect associations between DNA hyper- or hypomethylation and gene expression. In this review, I summarize some of the strong evidence from both types of studies. Taken together, these studies demonstrate that DNA methylation in mammals modulates expression of many genes during development, causing major changes in or important fine-tuning of expression. Also, I discuss previously established and newly hypothesized mechanisms for this epigenetic control.     

转座子PiggyBac在哺乳动物中的应用

DNA转座子作为一种遗传工程工具已广泛应用于多物种的转基因及产生插入突变等研究。目前,在哺乳动物中有转座活性的转座子可分为三类：1）hAT样转座子;2）Tcl样转座子包括Sleeping Beauty和FrogPrince;3）PiggyBac转座子家族。其中甘蓝蠖度尺蛾（Cabbage looper moth Trichoplusia ni）来源的PiggyBac转座子是目前在哺乳动物中活性最高的转座子,并且可以携带十几kb的外源基因转座而不影响其效率,使其在哺乳动物的转基因、癌基因的发现、基因治疗研究方面具有巨大的应用潜力。此外,PB的无痕迹转座对于无转基因、无遗传物质改变的诱导多潜能干细胞（iPS）研究也具有非常重要的意义。本文主要对针对PB在哺乳动物中的应用现状及前景作一介绍。     

Yos9p: a sweet-toothed bouncer of the secretory pathway

In this issue of Molecular Cell, Bhamidipati et al., (2005) and Kim et al., (2005), and Szathmary et al. (2005), and demonstrate that Yos9p selectively binds to aberrant glycoproteins in the endoplasmic reticulum (ER) and targets them for destruction through the ER-associated protein degradation pathway.