Triplet repeat sequences in human DNA can be detected by hybridization to a synthetic (5'-CGG-3')17 oligodeoxyribonucleotideag]

AbstractThe seemingly autonomous amplification of naturally occurring triplet repeat sequences in the human genome has been implicated in the causation of human genetic disease, such as the fragile X (Martin-Bell) syndrome, myotonic dystrophy (Curshmann-Steinert), spinal and bulbar muscular atrophy (Kennedy's disease) and Huntington's disease. The molecular mechanisms underlying these triplet amplifications are still unknown. We demonstrate here that a synthetic (CGG)17 oligodeoxyribonucleotide can be utilized as hybridization probe to visualize some of the triplet repeats in the human genome. This technique may help in studies aimed at the elucidation of the amplification mechanism

Adenoviral Vector DNA- and SARS-CoV-2 mRNA-Based Covid-19 Vaccines: Possible Integration into the Human Genome-Are Adenoviral Genes Expressed in Vector-based Vaccines?

Vigorous vaccination programs against SARS-CoV-2-causing Covid-19 are the major chance to fight this dreadful pandemic. The currently administered vaccines depend on adenovirus DNA vectors or on SARS-CoV-2 mRNA that might become reverse transcribed into DNA, however infrequently. In some societies, people have become sensitized against the potential short- or long-term side effects of foreign DNA being injected into humans. In my laboratory, the fate of foreign DNA in mammalian (human) cells and organisms has been investigated for many years. In this review, a summary of the results obtained will be presented. This synopsis has been put in the evolutionary context of retrotransposon insertions into pre-human genomes millions of years ago. In addition, studies on adenovirus vector-based DNA, on the fate of food-ingested DNA as well as the long-term persistence of SARS-CoV-2 RNA/DNA will be described. Actual integration of viral DNA molecules and of adenovirus vector DNA will likely be chance events whose frequency and epigenetic consequences cannot with certainty be assessed. The review also addresses problems of remaining adenoviral gene expression in adenoviral-based vectors and their role in side effects of vaccines. Eventually, it will come down to weighing the possible risks of genomic insertions of vaccine-associated foreign DNA and unknown levels of vector-carried adenoviral gene expression versus protection against the dangers of Covid-19. A decision in favor of vaccination against lifethreatening disease appears prudent. Informing the public about the complexities of biology will be a reliable guide when having to reach personal decisions about vaccinations

Essential concepts are missing: Foreign DNA in food invades the organisms' cells and can lead to stochastic epigenetic alterations with a wide range of possible pathogenetic consequences

In this article, a new concept for general pathogenesis has been proposed. Advances in molecular genetics have led to the realization that essential concepts in the framework of molecular biology are still missing. Clinical medicine is plagued by similar shortcomings: The questioning of current paradigms could open new vistas and invite challenging approaches. This article presents an unconventional idea. Foreign DNA which is regularly ingested with the essential food supply is not completely degraded. Small quantities of fragmented DNA rather persist transiently in the gastro-intestinal tract of mice and can be traced to various organ systems, except for cells in the germ line. Foreign DNA entering and persisting in mammalian cells can stochastically lead to genome-wide alterations of transcriptional and CpG DNA methylation profiles. In the course of food-ingested DNA invading somatic cells, completely new cell types can be generated which might be involved in the causation of common ailments. Projects emanating from this perception merit critical analysis and rigorous pursuit

Epigenetic consequences of foreign DNA insertions: de novo methylation and global alterations of methylation patterns in recipient genomes

The insertion of foreign DNA into mammalian or plant genomes is a frequent event in biology. My laboratory has pursued a long-standing interest in the structure of integrated adenovirus genomes and in the mechanism of foreign DNA insertions in mammalian cells. The long-term consequences of the integration of alien DNA are only partly known, and even less well understood are the mechanisms that bring them about. Evidence from viral systems has contributed to the realization that foreign DNA insertions entail a complex of sequelae that have also become apparent in non-viral systems: (i) The de novo methylation of integrated foreign DNA sequences has frequently been observed. (ii) Alterations of DNA methylation patterns in the recipient genome at and remote from the site of foreign DNA insertion have been demonstrated but it remains to be investigated how generally this phenomenon occurs. Many viral genomes find and have found entry into the genomes of present-day organisms. A major portion of mammalian genomes represents incomplete retroviral genomes that frequently have become permanently silenced by DNA methylation. It is still unknown how and to what extent the insertion of retroviral or retrotransposon sequences into established genomes has altered and shaped the methylation and transcription profiles of present day genomes. An additional reason for concern about the effects of foreign DNA integration is the fact that in all fields of molecular biology and medicine, the generation of transgenic or transgenomic cells and organisms has become a ubiquitously applied experimental technique. Copyright (C) 2011 John Wiley & Sons, Ltd

Influence of in vitro manipulation on the stability of methylation patterns in the Snurf/Snrpn-imprinting region in mouse embryonic stem cells

Recent work on embryonic stem (ES) cells showed that stem cell-derived tissues and embryos, cloned from ES cell nuclei, often fail to maintain epigenetic states of imprinted genes. This deregulation is frequently associated with in vitro manipulations and culture conditions which might affect the cells potential to develop into normal fetuses. Usually, epigenetic instability is reported in differentially methylated regions of mostly growth-related imprinted genes. However, little is known about the epigenetic stability of genes that function late in organogenesis. Hence, we set out to investigate the epigenetic stability of neuronal genes and analyzed DNA methylation patterns in the Snurf/Snrpn imprinted cluster in several cultured mouse ES cell lines. We also determined the effects of in vitro stress factors such as consecutive passaging, trypsination, mechanical handling, single cell cloning, centrifugation, staurosporine-induced neurogenesis and the insertion of viral (foreign) DNA into the host genome. Intriguingly, none of these in vitro manipulations interfered with the stability of the methylation patterns in the analyzed neuronal genes. These data imply that, in contrast to growth-related genes like Igf2, H19, Igf2r or Grb10, the methylation imprints of the analyzed neuronal genes in the Snurf/Snrpn cluster may be particularly stable in manipulated ES cells