Automated circuit fabrication and direct characterization of carbon nanotube vibrations.

Since their discovery, carbon nanotubes have fascinated many researchers due to their unprecedented properties. However, a major drawback in utilizing carbon nanotubes for practical applications is the difficulty in positioning or growing them at specific locations. Here we present a simple, rapid, non-invasive and scalable technique that enables optical imaging of carbon nanotubes. The carbon nanotube scaffold serves as a seed for nucleation and growth of small size, optically visible nanocrystals. After imaging the molecules can be removed completely, leaving the surface intact, and thus the carbon nanotube electrical and mechanical properties are preserved. The successful and robust optical imaging allowed us to develop a dedicated image processing algorithm through which we are able to demonstrate a fully automated circuit design resulting in field effect transistors and inverters. Moreover, we demonstrate that this imaging method allows not only to locate carbon nanotubes but also, as in the case of suspended ones, to study their dynamic mechanical motion.

The Prader-Willi/Angelman imprinted domain and its control center.

The present review focuses on the recent advances towards understanding the mode of operation of the imprinting center (IC) within the Prader-Willi/Angelman syndromes (PWS/AS) domain. Special emphasis is put on the elucidation of the functional interaction between the two parts of the center, AS-IC and PWS-IC. The recent studies, on which the review is based, reveal cis-acting elements and trans-acting proteins that constitute the two parts of the IC and presumably provide the molecular mechanism for this interaction. AS-IC acquires the primary imprint during gametogenesis by establishing the maternal epigenotype. The unmethylated maternal allele of the AS-IC binds, very likely, a trans-acting factor that confers methylation on the PWS-IC maternal allele after fertilization. It is assumed that the PWS-IC paternal epigenotype, once established, spreads across the entire PWS/AS domain in the soma.

The mouse Snrpn minimal promoter and its human orthologue: activity and imprinting.

BACKGROUND: Microdeletions in chromosome 15q13-15 of Prader-Willi (PWS) and Angelman Syndrome (AS) patients suggested that SNRPN promoter/exon 1, together with a short sequence located approximately 35 kb upstream, constitute an imprinting control centre that regulates the entire 2 Mb PWS/AS imprinted domain. We have recently shown that a minitransgene composed of the human upstream sequence and mouse Snrpn promoter/exon 1 harbours all the elements necessary for establishing and maintaining an imprinted state. RESULTS: Here we describe, using transfection experiments, the Snrpn minimal promoter (SMP), being composed of the entire 76 bp exon 1 and 84 bp of upstream sequence. A 7 bp element (SBE) within SMP that, in its unmethylated state binds a specific protein, is absolutely required for promoter activity. The orthologous human sequence, in spite of the fact that it possesses an identical SBE, failed to display promoter activity in transfection experiments and failed to create a methylated state of the maternal allele. Transgenic experiments reveal that a mutation in SBE of the mouse sequence did not completely abolish methylation of the maternal allele, indicating that sequences outside SBE participate in this process. Replacement of human exon 1 with the mouse orthologue replenished promoter activity, but left the maternal allele in the transgenic experiment unmethylated. The reciprocal chimera, in which mouse exon 1 was replaced by the human orthologue resulted in loss of promoter activity and did not support differential methylation. CONCLUSIONS: The observations made by in vitro and in vivo experiments suggest that several cis elements which are involved in Snrpn promoter activity and the imprinting process are present in the mouse promoter and absent in the human orthologous sequence.

The imprinting box of the Prader-Willi/Angelman syndrome domain.

A subset of mammalian genes is monoallelically expressed in a parent-of-origin manner. These genes are subject to an imprinting process that epigenetically marks alleles according to their parental origin during gametogenesis. Imprinted genes can be organized in clusters as exemplified by the 2-Mb domain on human chromosome 15q11-q13 and its mouse orthologue on chromosome 7c (ref. 1). Loss of this 2-Mb domain on the paternal or maternal allele results in two neurogenetic disorders, Prader-Willi syndrome (PWS) or Angelman syndrome (AS), respectively. Microdeletions on the paternal allele share a 4.3-kb short region of overlap (SRO), which includes the SNRPN promoter/exon1, cause PWS and silence paternally expressed genes. Microdeletions on the maternal allele share a 0.88-kb SRO located 35 kb upstream to the SNRPN promoter, cause AS and alleviate repression of genes on the maternal allele. Individuals carrying both AS and PWS deletions on the paternal allele show a PWS phenotype and genotype. These observations suggest that cis elements within the AS-SRO and PWS-SRO constitute an imprinting box that regulates the entire domain on both chromosomes. Here we show that a minitransgene composed of a 200-bp Snrpn promoter/exon1 and a 1-kb sequence located approximately 35 kb upstream to the SNRPN promoter confer imprinting as judged by differential methylation, parent-of-origin-specific transcription and asynchronous replication.

Imprinted methylation and its effect on expression of the mouse Zfp127 gene.

The Zfp127 gene is located on mouse chromosome 7 in an imprinted region that is homologous to the 2-Mb Prader-Willi and Angelman Syndromes region on human chromosome 15q11-q13. Here, we show that the gene is differentially methylated, the maternal allele being methylated and the paternal allele being unmethylated. This maternal methylation is established promptly after fertilization prior to syngamy. We also provide data that demonstrate the significance of methylation in the paternal expression of the gene. The expression of the Zfp127 gene in methyltransferase-deficient mice is significantly higher, suggesting that the gene is biallelically expressed in these mice. The data presented here will help to understand the mechanism by which the monoallelic expression of the entire 2-Mb Prader-Willi and Angelman Syndrome region is regulated.

The imprinting box of the mouse Igf2r gene.

Genomic imprinting is a phenomenon characterized by parent-of-origin-specific expression. The imprint is a mark established during germ-cell development to distinguish between the paternal and maternal copies of the imprinted genes. This imprint is maintained throughout embryo development and erased in the embryonic gonads to set the stage for a new imprint. DNA methylation is essential in this process as shown by the presence of differentially methylated regions (DMRs) in all imprinted genes and by the loss of imprinting in mice that are deficient in DNA methylation or upon deletion of DMRs. Here we show that a DMR in the imprinted Igf2r gene (which encodes the receptor for insulin-like growth factor type-2) that has been shown to be necessary for imprinting includes a 113-base-pair sequence that constitutes a methylation imprinting box. We identify two new cis-acting elements in this box that bind specific proteins: a de novo methylation signal and an allele-discrimination signal. We propose that this regulatory system, which we show to be involved in the establishment of differential methylation in the Igf2r DMR, represents a critical element in the imprinting process.

CpG methylation, chromatin structure and gene silencing-a three-way connection.

The three-way connection between DNA methylation, gene activity and chromatin structure has been known for almost two decades. Nevertheless, the molecular link between methyl groups on the DNA and the positioning of nucleosomes to form an inactive chromatin configuration was missing. This review discusses recent experimental data that may, for the first time, shed light on this molecular link. MeCP2, which is a known methylcytosine-binding protein, has been shown to possess a transcriptional repressor domain (TRD) that binds the corepressor mSin3A. This corepressor protein constitutes the core of a multiprotein complex that includes histone deacetylases (HDAC1 and HDAC2). Transfection and injection experiments with methylated constructs have revealed that the silenced state of a methylated gene, which is associated with a deacetylated nucleosomal structure, could be relieved by the deacetylase inhibitor, trichostatin A. Thus, methylation plays a pivotal role in establishing and maintaining an inactive state of a gene by rendering the chromatin structure inaccessible to the transcription machinery.

Migration and pension.

"Migration has important implications for the financial soundness of the pension system.... While it is common sense to expect that young migrants, even if low-skilled, can help society pay the benefits to the currently elderly, it may nevertheless be reasonable to argue that these migrants would adversely affect current young since, after all, the migrants are net beneficiaries of the welfare state. In contrast to the adverse effects of low skilled migration in a static model, [the authors] show that in a Samuelsonian overlapping generations model...migration is a Pareto-improving measure. All the existing income (low and high) and age (young and old) groups living at the time of the migrant's arrival would be better off."

Structure of the imprinted mouse Snrpn gene and establishment of its parental-specific methylation pattern.

The mouse Snrpn gene encodes the Smn protein, which is involved in RNA splicing. The gene maps to a region in the central part of chromosome 7 that is syntenic to the Prader-Willi/Angelman syndromes (PWS-AS) region on human chromosome 15q11-q13. The mouse gene, like its human counterpart, is imprinted and paternally expressed, primarily in brain and heart. We provide here a detailed description of the structural features and differential methylation pattern of the gene. We have identified a maternally methylated region at the 5' end (DMR1), which correlates inversely with the Snrpn paternal expression. We also describe a region at the 3' end of the gene (DMR2) that is preferentially methylated on the paternal allele. Analysis of Snrpn mRNA levels in a methylase-deficient mouse embryo revealed that maternal methylation of DMR1 may play a role in silencing the maternal allele. Yet both regions, DMR1 and DMR2, inherit the parental-specific methylation profile from the gametes. This methylation pattern is erased in 12.5-days postcoitum (dpc) primordial germ cells and reestablished during gametogenesis. DMR1 is remethylated during oogenesis, whereas DMR2 is remethylated during spermatogenesis. Once established, these methylation patterns are transmitted to the embryo and maintained, protected from methylation changes during embryogenesis and cell differentiation. Transfections of DMR1 and DMR2 into embryonic stem cells and injection into pronuclei of fertilized eggs reveal that embryonic cells lack the capacity to establish anew the differential methylation pattern of Snrpn. That all PWS patients lack DMR1, together with the overall high resemblance of the mouse gene to the human SNRPN, offers an excellent experimental tool to study the regional control of this imprinted chromosomal domain.

DNA methylation patterns in tumors derived from F9 cells resemble methylation at the blastula stage.

We show here that the genome of F9 teratocarcinoma cells growing in culture is heavily methylated but undergoes massive demethylation in tumors derived by subcutaneous injection of the cells. This demethylation occurs primarily in single copy gene sequences. As a result imprinted genes acquire their characteristic monoallelic methylation patterns while nonimprinted genes undergo demethylation. The overall methylation pattern in the tumors resembles the pattern observed in the mouse preimplantation embryo. The F9 cells in the tumors apparently recognize imprinted genes, distinguish them from non-imprinted genes and change the methylation of both gene classes to the pattern which characterizes the embryo. These cells therefore have the potential of providing an abundant source of protein factors involved in establishing the methylation pattern during embryo developments.

DNA demethylation in vitro: involvement of RNA.

An in vitro system for studying DNA demethylation has been established using extracts from tissue culture cells. This reaction, which is unusually resistant to proteinase K, takes place through the removal of a 5-methylcytosine nucleotide unit from the DNA substrate and its conversion to an RNase-sensitive form. It is likely that this represents the in vivo mechanism, as well, since extracts from L8 myoblasts specifically demethylate an alpha-actin gene, while extracts from F9 teratocarcinoma cells specifically demodify the Aprt CpG island. After pretreatment with proteinase K, these extracts demethylate both genes equally, suggesting that gene specificity may be controlled by protein factors.

Dynamic methylation adjustment and counting as part of imprinting mechanisms.

Monoallelic expression in diploid mammalian cells appears to be a widespread phenomenon, with the most studied examples being X-chromosome inactivation in eutherian female cells and genomic imprinting in the mouse and human. Silencing and methylation of certain sites on one of the two alleles in somatic cells is specific with respect to parental source for imprinted genes and random for X-linked genes. We report here evidence indicating that: (i) differential methylation patterns of imprinted genes are not simply copied from the gametes, but rather established gradually after fertilization; (ii) very similar methylation patterns are observed for diploid, tetraploid, parthenogenic, and androgenic preimplantation mouse embryos, as well as parthenogenic and androgenic mouse embryonic stem cells; (iii) haploid parthenogenic embryos do not show methylation adjustment as seen in diploid or tetraploid embryos, but rather retain the maternal pattern. These observations suggest that differential methylation in imprinted genes is achieved by a dynamic process that senses gene dosage and adjusts methylation similar to X-chromosome inactivation.

Interaction of M.SssI and M.HhaI with single-base mismatched oligodeoxynucleotide duplexes.

As part of an attempt to elucidate the mode of interaction of the CpG methyltransferase M.SssI with its substrate, we have prepared a series of double-stranded oligodeoxyribonucleotides containing one mismatch in the CpG recognition site. The mismatched duplexes were used to analyze the binding capabilities and enzymatic activity of M.SssI and M.HhaI (recognizes GCGC). We demonstrate here that M.SssI binds specifically to substrates containing either a C/A or G/T mismatch in the recognition sequence, i.e., 5'-GCGC/CACG-5' or 5'-GCGC/CGTG-5', respectively. The enzyme also shows significant enzymatic activity with these mismatched substrates. These results suggest that site recognition and methylation by M.SssI take place on the same strand. M.HhaI bound and methylated the C/A mismatch very efficiently, but recognition of the G/T mismatch was scarcely detectable.

Footprint analysis of M.Sssl and M.Hhal methyltransferases reveals extensive interactions with the substrate DNA backbone.

The interactions of the CpG methyltransferases M.Sssl and M.Hhal (GCGC) with substrate DNA were investigated using three different footprinting techniques. The two structurally related enzymes displayed similar specific and non-specific contacts with DNA while bound to their target sequences. DNase I footprinting implicated a region of 18 to 21 base-pairs with which these enzymes interact. Dimethylsulfate protection experiments mostly revealed specific base interactions; each enzyme was shown to interact predominantly with bases at its recognition site in the major groove. However, hydroxyl radical footprints demonstrated extensive interactions with the sugar-phosphate backbone on both strands of the DNA substrate. Both enzymes protected a 16 nucleotide region, in a staggered fashion, covering 9 to 10 nucleotides on each strand. The protected regions, extending for almost a full turn of DNA on each strand, were offset by 6 to 7 nucleotides in the 5' direction, placing both regions on the same face of the double helix, bracketing the major groove. The results suggest that these methyltransferases straddle the major groove from the backbone, but protrude into the groove only to specifically interact with their recognition sites. The sequence-independent interactions observed on the sugar-phosphate backbone may explain the ability of the enzymes to recognize a small sequence, as well as their processive mode of action.

DNA methylation in early development.

Several lines of evidence strongly suggest that DNA methylation is involved in embryo development. Perhaps the most direct evidence comes from experiments with methyltransferase deficient mice. Embryos that express low levels of the maintenance methyltransferase do not develop to term and die at the 5 to 20 somite stage corresponding to the level of the enzyme. In the mouse, dramatic methylation changes have been observed during the early steps of embryo development. Most genes are subject to a process of active demethylation starting promptly after fertilization. Except for a small number of methylated CpG sites in imprinted genes the vast majority of the sites are unmethylated by the stage of cavitation (16 cell). Such genome-wide demethylation may signify an erasure of epigenetic information originating in the highly differentiated gametes. This erasure may be essential for the establishment of a pluripotent state, before specific cell lineages can be determined. The process of laying down a new developmental program involves, initially, global de novo methylation at the stage of pregastrulation followed by gene specific demethylations associated with the onset of activity of these genes. CpG islands characteristic of housekeeping genes, appear to be protected from the global de novo methylation. An exception to this rule is the hypermethylation of CpG islands in X-linked housekeeping genes on the inactive X chromosome and of specific differentially methylated CpG sites in imprinted genes. Primordial germ cells escape the global de novo methylation which takes place at the pregastrula stage and undergo a very similar de novo methylation process in the differentiated gonads (15.5-18.5 days post coitum), forming the methylation patterns which are specific to the gametes. Specific demethylations then form a terminal methylation pattern which is then clonaly inherited in the soma and erased after fertilization.

Utilitarian tradeoff between population growth and income growth.

"This paper extends the comparison of classical and average utilitarianism from a static to a dynamic and endogenously growing economy. Using a stylised endogenous growth framework, it confirms that the Benthamite population growth rate exceeds the Millian growth rate. In terms of the rate of growth of per capita income, the reverse is true. Having the standard of living often increasing under the Benthamite criterion, our results thereby depart significantly from 'the repugnant conclusion' levelled against classical utilitarianism."

Sp1 elements protect a CpG island from de novo methylation.

Animal somatic cell DNA is characterized by a bimodal pattern of methylation: tissue-specific genes are methylated in most cell types whereas housekeeping genes have 5' CpG islands which are constitutively unmethylated. Because methyl moieties derived from the gametes are erased in the morula and early blastula, this profile must be re-established in every generation; this is apparently accomplished by a wave of non-CpG island de novo methylation that occurs at implantation. Using transfection into embryonic stem cells and transgenic mice as a model system, we now show that Sp1 elements play a key role in protecting a CpG island in the adenine phosphoribosyltransferase (APRT) gene from de novo methylation. This recognition mechanism represents a critical step in embryogenesis, as it is responsible for setting up the correct genome methylation pattern which, in turn, is involved in regulating basal gene expression in the organism.