Studies on the immortalisation of rodent embryo fibroblasts by simian virus 40 large tumour antigen

Powell, Andrew Jonathan

January 1995

No description available.

572.8

T antigen

Příprava experimentálního systému pro studium životního cyklu myšího polyomaviru / Experimental system for the mouse polyomavirus life cycle study

Pergner, Jiří

January 2010

Experimental system for the mouse polyomavirus life cycle study Abstract: Murine polyomavirus (MPyV) is the prototype of the Polyomaviridae family. This family includes also some important human pathogens (BKV, JCV, Merkel cell polyomavirus). Due to their specific properties viruses within this family may serve as versatile vectors for gene therapy or recombinant vaccine production. New methodological approaches may help to understand some yet unknown facts about MPyV life cycle. Clarification of some processes during murine polyomavirus life cycle may be also important to fully exploit polyomaviruses for therapeutic purposes. The aim of this diploma thesis was to preparare two innovative experimental systems that extend possibilities of studying the life cycle of MPyV. The first part of the diploma thesis focusses on construction of recombinant MPyV which expresses yellow fluorescent protein (EYFP) in the early stages of infection. Such virus can be very useful for studying the infection spreading by live- cell imaging and Fluorescence-Activated Cell Sorting (FACS) and can be employed for co- localization studies of YFP-tagged LT antigen with certain cellular proteins. Second part of the diploma thesis describes preparation of a hybrid cell line prepared by fusion of mouse and monkey cells. This new cell...

Studium exosomů při polyomavirové infekci / Study of exosomes in polyomavirus infection

Hyka, Lukáš

January 2019

Exosomes are extracellular vesicles of endosomal origin. It was thought, that exosomes are used by cells only as carriers for cellular waste, but it was found out, that exosomes serve in the cellular communication and have a role in viral infections. Exosomes are exploited by viruses for example for the transport of viral protein or viral RNA/DNA. One of the viruses, where the mechanism of exploitation is unknown (if any exists) is murine polyomavirus. Murine polyomavirus belongs to the family Polyomaviridae, to which other human viruses belong for example, JC virus or virus of Merkel cell carcinoma. Murine polyomavirus codes for small, large and middle T antigen and three capsid proteins. Middle T antigen is known to bind to cellular membranes. Exosomes are membrane derived structures, so we investigated a possible transfer of middle T antigen. To this goal the successful isolation of exosomes and their characterization was necessary. Exosomes were isolated by ultracentrifugation and further purified by the density gradient OptiPrep. Exosomes were characterized by electron microscopy, NanoSight and by protein exosomal markers. These markers are for example Alix and flotillin-1. The cells were transfected in order to produce middle T antigen. It was shown, that exosomes isolated from these cells...

Interplay between JCV Large T-antigen and Cullin-7 in Brain Cancer

Marsili, Stefania

January 2011

A convincing body of evidence suggests that ubiquitination and the ubiquitin proteasome degradation pathway play a key role in neoplastic transformation. Ubiquitination, as post-translation modification, is involved both in functional regulation and degradation of specific cellular targets known as proto-oncogenes and tumor suppressors. Oncogenic viral proteins interact both with proto-oncoproteins and tumor suppressors leading to the modulation of their cellular function by several mechanisms including ubiquitination. Interestingly, viral oncoproteins themselves can also be regulated by this post-translation modification. Additionally, viruses can assemble their own E3 ligases or regulate the activity of cellular E3 ligases. E3 ligases, involved in the final step of the ubiquitination process, are the enzymes that provide the specificity for the interaction with target substrates by the means of a large number of proteins. Recent studies on the potential correlation between viral infection and oncogenesis, have addressed the emerging role of the ubiquitination system as a possible mediator for cancer transformation. In this scenario we hypothesized that JCV T-antigen may interfere with the ubiquitination system and we investigated a possible interaction between JCV T-antigen and the E3 ligase Cul7. To prove our hypothesis we performed co-immunoprecipitation and co-immunofluorescence experiments using the glioblastoma cell lines HJC12, U87MG and HJC5. Our results indicate that JCV T-antigen and Cul7 interact in the cytoplasmic compartment. In addition, JCV T-antigen stabilizes Cul7. These observations suggest that JCV T-antigen can modulate Cul7 E3 ligase activity leading to oncogenesis. Further study addressing the biological significance of this interaction will decipher the cellular processes modulated by JCV T-antigen and Cul7 and will indicate new avenues for therapeutic intervention. / Biology

Biology

Cellular Biology

Neurosciences

Brain

Cancer

Cul7

Jcv

T-antigen

Ubiquitination

Induction of Genomic Instability During Transformation of Human Cells with SV40 Large T Antigen

Woods, Caroline

08 1900

Human cells transformed by SV40 large T antigen achieve an extended lifespan and continue to grow and divide past the normal growth limit. This extended lifespan often ends at crisis when the cells die through fatal cell division. A few cells will survive this crisis and continue to proliferate indefinitely and are therefore considered immortal. Transformation of cells by SV40 large T antigen is associated with the induction of genomic instability at early times. This instability may contribute to a cells surviving crisis and becoming immortal through the chance disruption of genes involved in cell proliferation and regulation of cell death. Genetic instability is also observed in human tumours and the mechanisms by which it occurs both in tumour cells and SV40 transformed cells may be similar. In order to investigate these mechanisms, human and rodent cells were transfected with wild type and mutant forms of SV40 large T antigen and analyzed cytogenetically. The results of this study demonstrate that the amino terminal 147 amino acids of SV40 large T antigen are sufficient for the induction of genomic instability and at least three regions within this amino terminal fragment are necessary. One between amino acids 17 and 27. A second being the retinoblastoma protein binding site, and the third between amino acids 130 and 147. Finally, binding of T antigen to p53 appears to not be required for the induction of genomic instability, but may be necessary for the survival of aberrant cells. There is an apparent correspondence between the ability of T antigen mutants to induce genomic instability, and their abilities to induce cellular DNA synthesis and to transform and immortalize cells. / Thesis / Master of Science (MS)

genome

instability

human

cell

SV40

antigen

transform

SV40 large T antigen

The Role of GRB2 and GRB7 in Polyomavirus Middle T Antigen- and Neu-Mediated Mammary Tumorigenesis / GRB2 and GRB7 in Mammary Tumorigenesis

Tortorice, Christopher

09 1900

Activated protein tyrosine kinases, which have been implicated in the genesis of a number of human cancers, rely on a variety of protein-protein interactions to transmit their proliferative signals within the cell. These interactions are often mediated by Src homology 2 and 3 (SH2 and SH3) domains. A class of proteins which are mainly composed of such domains, termed adaptor proteins, has been identified. The Growth factor receptor bound proteins Grb2 and Grb7 are SH2 domain adaptor proteins which have been shown to associate directly or in complex with many tyrosine kinases, including the c-ErbB-2/Neu receptor tyrosine kinase. While overexpression of either protein alone in rat fibroblasts is not transforming, human breast cancer cell lines exhibit Grb2 and Grb7 gene amplification, and mRNA and protein overexpression. The role of Grb2 in polyomavirus middle T antigen-mediated mammary tumorigenesis has been examined utilizing gene targeting and transgenic approaches. Initial characterization of the progeny of matings involving Grb2+/mice and MMTV/middle T transgenic mice indicated that delayed tumor kinetics may be the result of Grb2 dosage differences between mT+;Grb2+/-and mT+;Grb2+/+ animals. Transgenic animals expressing a dominant negative version of Grb2 in the mammary epithelium have been generated to explore an alternate method for disrupting signaling from middle T antigen. The role of Grb2 and Grb7 in Neu-mediated mammary tumorigenesis is also being examined. Both MMTV/Grb2 and MMTV/Grb7 transgenic mice that express the transgene in the mammary epithelium have been identified by ribonuclease protection analysis. Matings involving these strains and MMTV/neu mice should aid in determining the effects of overexpressing Grb2 or Grb7 on Neu-mediated mammary tumorigenesis. / Thesis / Master of Science (MS)

GRB2

GRB7

polyomavrius

T antigen

neu-mediated mammary tumorigenesis

mammary tumorigenesis

DNA Unwinding by Helicases Investigated on the Single Molecule Level

Klaue, Daniel

01 November 2012

Each organism has to maintain the integrity of its genetic code, which is stored in its DNA. This is achieved by strongly controlled and regulated cellular processes such as DNA replication, -repair and -recombination. An essential element of these processes is the unwinding of the duplex strands of the DNA helix. This biochemical reaction is catalyzed by helicases that use the energy of nucleoside triphophate (NTP) hydrolysis. Although all helicases comprise highly conserved domains in their amino acid sequence, they exhibit large variations regarding for example their structure, their function and their target nucleic acid structures. The main objective of this thesis is to obtain insight into the DNA unwinding mechanisms of three helicases from two different organisms. These helicase vary in their structures and are involved in different pathways of DNA metabolism. In particular the replicative, hexameric helicase Large Tumor-Antigen (T-Antigen) from Simian virus 40 and the DNA repair helicases RecQ2 and RecQ3 from Arabidopsis thaliana are studied. To observe DNA unwinding by these helicases in real-time on the single molecule level, a biophysical technique, called magnetic tweezers, was applied. This technique allows to stretch single DNA molecules attached to magnetic particles. Simultaneously one can measure the DNA end-to-end distance. Special DNA hairpin templates allowed to characterize different parameters of the DNA unwinding reaction such as the unwinding velocity, the length of unwound DNA (processivity) or the influence of forces. From this mechanistic models about the functions of the helicases could be obtained. T-Antigen is found to be one of the slowest and most processive helicases known so far. In contrast to prokaryotic helicases, the unwinding velocity of T-Antigen shows a weak dependence on the applied force. Since current physical models for the unwinding velocity fail to describe the data an alternative model is developed. The investigated RecQ helicases are found to unwind and close short stretches of DNA in a repetitive fashion. This activity is shown for the first time under external forces. The experiments revealed that the repetitive DNA unwinding is based on the ability of both enzymes to switch from one single DNA strand to the other. Although RecQ2 and RecQ3 perform repetitive DNA unwinding, both enzymes differ largely in the measured DNA unwinding properties. Most importantly, while RecQ2 is a classical helicase that unwinds DNA, RecQ3 mostly rewinds DNA duplexes. These different properties may reflect different specific tasks of the helicases during DNA repair processes. To obtain high spatial resolution in DNA unwinding experiments, the experimental methods were optimized. An improved and more stable magnetic tweezers setup with sub-nanometer resolution was built. Additionally, different methods to prepare various DNA templates for helicase experiments were developed. Furthermore, the torsional stability of magnetic particles within an external field was investigated. The results led to selection rules for DNA-microsphere constructs that allow high resolution measurements. / Jeder Organismus ist bestrebt, die genetischen Informationen intakt zu halten, die in seiner DNA gespeichert sind. Dies wird durch präzise gesteuerte zelluläre Prozesse wie DNA-Replikation, -Reparatur und -Rekombination verwirklicht. Ein wesentlicher Schritt ist dabei das Entwinden von DNA-Doppelsträngen zu Einzelsträngen. Diese chemische Reaktion wird von Helikasen durch die Hydrolyse von Nukleosidtriphosphaten katalysiert. Obwohl bei allen Helikasen bestimmte Aminosäuresequenzen hoch konserviert sind, können sie sich in Eigenschaften wie Struktur, Funktion oder DNA Substratspezifität stark unterscheiden. Gegenstand der vorliegenden Arbeit ist es, die Entwindungsmechanismen von drei verschieden Helikasen aus zwei unterschiedlichen Organismen zu untersuchen, die sich in ihrer Struktur sowie ihrer Funktion unterscheiden. Es handelt sich dabei um die replikative, hexamerische Helikase Large Tumor-Antigen (T-Antigen) vom Simian-Virus 40 und die DNA-Reparatur-Helikasen RecQ2 und RecQ3 der Pflanze Arabidopsis thaliana. Um DNA-Entwindung in Echtzeit zu untersuchen, wird eine biophysikalische Einzelmolekültechnik, die \"Magnetische Pinzette\", verwendet. Mit dieser Technik kann man ein DNA-Molekül, das an ein magnetisches Partikel gebunden ist, strecken und gleichzeitig dessen Gesamtlänge messen. Mit speziellen DNA-Konstrukten kann man so bestimmte Eigenschaften der Helikasen bei der DNA-Entwindung, wie z.B. Geschwindigkeit, Länge der entwundenen DNA (Prozessivität) oder den Einfluß von Kraft, ermitteln. Es wird gezeigt, dass T-Antigen eine der langsamsten und prozessivsten Helikasen ist. Im Gegensatz zu prokaryotischen Helikasen ist die Entwindungsgeschwindigkeit von T-Antigen kaum kraftabhängig. Aktuelle Modelle sagen dieses Verhalten nicht vorraus, weshalb ein alternatives Modell entwickelt wird. Die untersuchten RecQ-Helikasen zeigen ein Entwindungsverhalten bei dem permanent kurze Abschnitte von DNA entwunden und wieder zusammengeführt werden. Dieses Verhalten wird hier zum ersten Mal unter dem Einfluß externer Kräfte gemessen. Es wird gezeigt, dass die permanente Entwindung auf die Fähigkeit beider Helikasen, von einem einzelen DNA-Strang auf den anderen zu wechseln, zurückzuführen ist. Obwohl RecQ2 und RecQ3 beide das Verhalten des permanenten Entwindens aufzeigen, unterscheiden sie sich stark in anderen Eigenschaften. Der gravierendste Unterschied ist, dass RecQ2 wie eine klassische Helikase die DNA entwindet, während RecQ3 eher bestrebt ist, die DNA-Einzelstränge wieder zusammenzuführen. Die unterschiedlichen Eigenschaften könnten die verschieden Aufgaben beider Helikasen während DNA-Reparaturprozessen widerspiegeln. Weiterhin werden die experimentellen Methoden optimiert, um möglichst hohe Auflösungen der Daten zu erreichen. Dazu zählen der Aufbau einer verbesserten und stabileren \"Magnetischen Pinzette\" mit sub-nanometer Auflösung und die Entwicklung neuer Methoden, um DNA Konstrukte herzustellen. Außerdem wird die Torsions\\-steifigkeit von magnetischen Partikeln in externen magnetischen Feldern untersucht. Dabei finden sich Auswahlkriterien für DNA-gebundene magnetische Partikel, durch die eine hohe Auflösung erreicht wird.

Biophysik

Helikase

Magnetische Pinzette

Einzelmolekülmethode

DNA Entwindung

DNA Entwindungsmechanismus

T-Antigen

RecQ

DNA Haarnadelschleife

Biophysics

Helicase

Magnetic tweezers

Single-molecule method

DNA unwinding

DNA unwinding mechanism

T-Antigen

RecQ

DNA Hairpin

ddc:570

rvk:WD 3100

rvk:WD 5360

DNA Unwinding by Helicases Investigated on the Single Molecule Level

Klaue, Daniel

06 September 2012

Each organism has to maintain the integrity of its genetic code, which is stored in its DNA. This is achieved by strongly controlled and regulated cellular processes such as DNA replication, -repair and -recombination. An essential element of these processes is the unwinding of the duplex strands of the DNA helix. This biochemical reaction is catalyzed by helicases that use the energy of nucleoside triphophate (NTP) hydrolysis. Although all helicases comprise highly conserved domains in their amino acid sequence, they exhibit large variations regarding for example their structure, their function and their target nucleic acid structures. The main objective of this thesis is to obtain insight into the DNA unwinding mechanisms of three helicases from two different organisms. These helicase vary in their structures and are involved in different pathways of DNA metabolism. In particular the replicative, hexameric helicase Large Tumor-Antigen (T-Antigen) from Simian virus 40 and the DNA repair helicases RecQ2 and RecQ3 from Arabidopsis thaliana are studied. To observe DNA unwinding by these helicases in real-time on the single molecule level, a biophysical technique, called magnetic tweezers, was applied. This technique allows to stretch single DNA molecules attached to magnetic particles. Simultaneously one can measure the DNA end-to-end distance. Special DNA hairpin templates allowed to characterize different parameters of the DNA unwinding reaction such as the unwinding velocity, the length of unwound DNA (processivity) or the influence of forces. From this mechanistic models about the functions of the helicases could be obtained. T-Antigen is found to be one of the slowest and most processive helicases known so far. In contrast to prokaryotic helicases, the unwinding velocity of T-Antigen shows a weak dependence on the applied force. Since current physical models for the unwinding velocity fail to describe the data an alternative model is developed. The investigated RecQ helicases are found to unwind and close short stretches of DNA in a repetitive fashion. This activity is shown for the first time under external forces. The experiments revealed that the repetitive DNA unwinding is based on the ability of both enzymes to switch from one single DNA strand to the other. Although RecQ2 and RecQ3 perform repetitive DNA unwinding, both enzymes differ largely in the measured DNA unwinding properties. Most importantly, while RecQ2 is a classical helicase that unwinds DNA, RecQ3 mostly rewinds DNA duplexes. These different properties may reflect different specific tasks of the helicases during DNA repair processes. To obtain high spatial resolution in DNA unwinding experiments, the experimental methods were optimized. An improved and more stable magnetic tweezers setup with sub-nanometer resolution was built. Additionally, different methods to prepare various DNA templates for helicase experiments were developed. Furthermore, the torsional stability of magnetic particles within an external field was investigated. The results led to selection rules for DNA-microsphere constructs that allow high resolution measurements. / Jeder Organismus ist bestrebt, die genetischen Informationen intakt zu halten, die in seiner DNA gespeichert sind. Dies wird durch präzise gesteuerte zelluläre Prozesse wie DNA-Replikation, -Reparatur und -Rekombination verwirklicht. Ein wesentlicher Schritt ist dabei das Entwinden von DNA-Doppelsträngen zu Einzelsträngen. Diese chemische Reaktion wird von Helikasen durch die Hydrolyse von Nukleosidtriphosphaten katalysiert. Obwohl bei allen Helikasen bestimmte Aminosäuresequenzen hoch konserviert sind, können sie sich in Eigenschaften wie Struktur, Funktion oder DNA Substratspezifität stark unterscheiden. Gegenstand der vorliegenden Arbeit ist es, die Entwindungsmechanismen von drei verschieden Helikasen aus zwei unterschiedlichen Organismen zu untersuchen, die sich in ihrer Struktur sowie ihrer Funktion unterscheiden. Es handelt sich dabei um die replikative, hexamerische Helikase Large Tumor-Antigen (T-Antigen) vom Simian-Virus 40 und die DNA-Reparatur-Helikasen RecQ2 und RecQ3 der Pflanze Arabidopsis thaliana. Um DNA-Entwindung in Echtzeit zu untersuchen, wird eine biophysikalische Einzelmolekültechnik, die \"Magnetische Pinzette\", verwendet. Mit dieser Technik kann man ein DNA-Molekül, das an ein magnetisches Partikel gebunden ist, strecken und gleichzeitig dessen Gesamtlänge messen. Mit speziellen DNA-Konstrukten kann man so bestimmte Eigenschaften der Helikasen bei der DNA-Entwindung, wie z.B. Geschwindigkeit, Länge der entwundenen DNA (Prozessivität) oder den Einfluß von Kraft, ermitteln. Es wird gezeigt, dass T-Antigen eine der langsamsten und prozessivsten Helikasen ist. Im Gegensatz zu prokaryotischen Helikasen ist die Entwindungsgeschwindigkeit von T-Antigen kaum kraftabhängig. Aktuelle Modelle sagen dieses Verhalten nicht vorraus, weshalb ein alternatives Modell entwickelt wird. Die untersuchten RecQ-Helikasen zeigen ein Entwindungsverhalten bei dem permanent kurze Abschnitte von DNA entwunden und wieder zusammengeführt werden. Dieses Verhalten wird hier zum ersten Mal unter dem Einfluß externer Kräfte gemessen. Es wird gezeigt, dass die permanente Entwindung auf die Fähigkeit beider Helikasen, von einem einzelen DNA-Strang auf den anderen zu wechseln, zurückzuführen ist. Obwohl RecQ2 und RecQ3 beide das Verhalten des permanenten Entwindens aufzeigen, unterscheiden sie sich stark in anderen Eigenschaften. Der gravierendste Unterschied ist, dass RecQ2 wie eine klassische Helikase die DNA entwindet, während RecQ3 eher bestrebt ist, die DNA-Einzelstränge wieder zusammenzuführen. Die unterschiedlichen Eigenschaften könnten die verschieden Aufgaben beider Helikasen während DNA-Reparaturprozessen widerspiegeln. Weiterhin werden die experimentellen Methoden optimiert, um möglichst hohe Auflösungen der Daten zu erreichen. Dazu zählen der Aufbau einer verbesserten und stabileren \"Magnetischen Pinzette\" mit sub-nanometer Auflösung und die Entwicklung neuer Methoden, um DNA Konstrukte herzustellen. Außerdem wird die Torsions\\-steifigkeit von magnetischen Partikeln in externen magnetischen Feldern untersucht. Dabei finden sich Auswahlkriterien für DNA-gebundene magnetische Partikel, durch die eine hohe Auflösung erreicht wird.

info:eu-repo/classification/ddc/570

ddc:570

Studies on the Molecular Biology of the Mouse Pneumotropic Polyomavirus

Zhang, Shouting

January 2003

<p>The <i>Murine Pneumotropic Virus </i>(MPtV), in contrast to the other <i>MurinePolyomavirus</i> (MPyV), appears to be non-tumourigenic in its natural host. Instead, MPtV causes acute pneumonia and can serve as a model in studies of polyomavirus-induced disease. In initial experiments, MPtV large T-antigen (LT) was expressed in a heterologous system. LT was characterized with regard to its metabolic stability and cell immortalizing activity and, after purification, to its specific DNA binding. </p><p>The absence of permissive cell culture system for MPtV has hampered its study. We made attempts to widen the host range of the virus by modifying the regulatory and late regions of the genome. The enhancer substitution mutant (KVm1), having a transcriptional enhancer substituted with a corresponding DNA segment from MPyV, was able to replicate in mouse 3T3 cells and form virus particles that were infectious in mice. However, efficient infection of cells in vitro was not achieved with this mutant virus, possibly due to the absence of virus-specific receptors on the cells. The capsid protein substitution mutants, having capsid protein genes of MPyV, for which receptors are present on a variety of cell types, showed also no cytopathic effect, despite an enhanced viral DNA replication and assembly of virus particles. </p><p>MPtV-DNA extracted from virus in lung tissue of infected mice had a heterogeneous enhancer segment. A majority of the DNA molecules had a structure differing from the standard-type. A 220 base-pair insertion at nucleotide position 142 with a concomitant deletion of nucleotides 143 to 148 was a prominent variation. Other genome variants showed complete or partial deletions of the insertion and surrounding sequences in the viral enhancer. In relation to the standard-type, all variant genomes showed differences in the activities of transcriptional promoters and the origin DNA replication. Analysis by DNA reassociation showed that a large number of nucleotide sequences related to the 220 base-pair insert in the MPtV genome were present in mouse and human DNA, but not in <i>Escherichia coli</i> DNA. Together, the data suggest that the 220 base-pair insertion is related to a transposable element of a novel type.</p>

Molecular biology

murine pneumotropic virus

Kilham mouse polyomavirus

large T antigen

enhancer

regulatory region rearrangement

gene expression regulation

DNA replication

transposable elements

Molekylärbiologi

Molecular biology

Molekylärbiologi

Studies on the Molecular Biology of the Mouse Pneumotropic Polyomavirus

Zhang, Shouting

January 2003

The Murine Pneumotropic Virus (MPtV), in contrast to the other MurinePolyomavirus (MPyV), appears to be non-tumourigenic in its natural host. Instead, MPtV causes acute pneumonia and can serve as a model in studies of polyomavirus-induced disease. In initial experiments, MPtV large T-antigen (LT) was expressed in a heterologous system. LT was characterized with regard to its metabolic stability and cell immortalizing activity and, after purification, to its specific DNA binding. The absence of permissive cell culture system for MPtV has hampered its study. We made attempts to widen the host range of the virus by modifying the regulatory and late regions of the genome. The enhancer substitution mutant (KVm1), having a transcriptional enhancer substituted with a corresponding DNA segment from MPyV, was able to replicate in mouse 3T3 cells and form virus particles that were infectious in mice. However, efficient infection of cells in vitro was not achieved with this mutant virus, possibly due to the absence of virus-specific receptors on the cells. The capsid protein substitution mutants, having capsid protein genes of MPyV, for which receptors are present on a variety of cell types, showed also no cytopathic effect, despite an enhanced viral DNA replication and assembly of virus particles. MPtV-DNA extracted from virus in lung tissue of infected mice had a heterogeneous enhancer segment. A majority of the DNA molecules had a structure differing from the standard-type. A 220 base-pair insertion at nucleotide position 142 with a concomitant deletion of nucleotides 143 to 148 was a prominent variation. Other genome variants showed complete or partial deletions of the insertion and surrounding sequences in the viral enhancer. In relation to the standard-type, all variant genomes showed differences in the activities of transcriptional promoters and the origin DNA replication. Analysis by DNA reassociation showed that a large number of nucleotide sequences related to the 220 base-pair insert in the MPtV genome were present in mouse and human DNA, but not in Escherichia coli DNA. Together, the data suggest that the 220 base-pair insertion is related to a transposable element of a novel type.

Molecular biology

murine pneumotropic virus

Kilham mouse polyomavirus

large T antigen

enhancer

regulatory region rearrangement

gene expression regulation

DNA replication

transposable elements

Molekylärbiologi

Molecular biology

Molekylärbiologi