Jacob Giehm Mikkelsen

IFI16 senses DNA forms of the lentiviral replication cycle and controls HIV-1 replication

Significance HIV-1 is a lentivirus and replicates through a replication cycle involving several DNA forms including ssDNA. Here we report that synthetic DNA oligos corresponding to DNA forms of the lentivirus replication cycle as well as viral DNA are detected by the immunological DNA sensor IFN-inducible protein 16 (IFI16) and stimulate innate immune responses through a pathway dependent on stimulator of IFN genes (STING). Moreover, we show that replication of HIV-1 is elevated in cells with decreased expression of IFI16 or STING. We suggest IFI16 is a sensor for lentivirus DNA in macrophages stimulating innate immune responses, which contribute to early control of the virus. Replication of lentiviruses generates different DNA forms, including RNA:DNA hybrids, ssDNA, and dsDNA. Nucleic acids stimulate innate immune responses, and pattern recognition receptors detecting dsDNA have been identified. However, sensors for ssDNA have not been reported, and the ability of RNA:DNA hybrids to stimulate innate immune responses is controversial. Using ssDNAs derived from HIV-1 proviral DNA, we report that this DNA form potently induces the expression of IFNs in primary human macrophages. This response was stimulated by stem regions in the DNA structure and was dependent on IFN-inducible protein 16 (IFI16), which bound immunostimulatory DNA directly and activated the stimulator of IFN genes –TANK-binding kinase 1 - IFN regulatory factors 3/7 (STING–TBK1–IRF3/7) pathway. Importantly, IFI16 colocalized and associated with lentiviral DNA in the cytoplasm in macrophages, and IFI16 knockdown in this cell type augmented lentiviral transduction and also HIV-1 replication. Thus, IFI16 is a sensor for DNA forms produced during the lentiviral replication cycle and regulates HIV-1 replication in macrophages.

Familial Hypercholesterolemia and Atherosclerosis in Cloned Minipigs Created by DNA Transposition of a Human PCSK9 Gain-of-Function Mutant

A transgenic pig model of familial hypercholesterolemia can be used for translational atherosclerosis research. A Model of We hope to inherit our parents’ good features, like blue eyes or musical talent, but not their high cholesterol. Familial hypercholesterolemia, which is passed down in families, results in high levels of “bad” cholesterol [low-density lipoprotein (LDL)] and early onset of cardiovascular disease. To further translational research in this area, Al-Mashhadi and coauthors created a large-animal model of this genetic disease, showing that these pigs develop hypercholesterolemia and atherosclerosis much like people do. The D374Y gain-of-function mutation in the PCSK9 gene (which is conserved between pig and human) causes a severe form of hypercholesterolemia and, ultimately, atherosclerosis. Al-Mashhadi and colleagues engineered transposon-based vectors to express D374Y-PCSK9. After confirming function in human liver cancer cells, the authors cloned minipigs that expressed the mutant gene. On a low-fat diet, these pigs had higher total and LDL cholesterol than their wild-type counterparts. Breeding the male transgenic pigs with wild-type sows produced offspring that also had higher plasma LDL levels compared with normal, healthy pigs. A high-fat, high-cholesterol diet induced severe hypercholesterolemia in these animals as well as accelerated development of atherosclerosis that has human-like lesions. Other large-animal models only develop hypercholesterolemia when placed on the right diet, and small-animal models cannot recapitulate human-like pathology. The PCSK9 transgenic pigs created by Al-Mashhadi et al. develop hypercholesterolemia even on low-fat diets, and thus reflect the inherited human disease. This large-animal model will be important for better understanding the pathogenesis of familial hypercholesterolemia and for testing new therapeutics and imaging modalities before moving into human trials. Lack of animal models with human-like size and pathology hampers translational research in atherosclerosis. Mouse models are missing central features of human atherosclerosis and are too small for intravascular procedures and imaging. Modeling the disease in minipigs may overcome these limitations, but it has proven difficult to induce rapid atherosclerosis in normal pigs by high-fat feeding alone, and genetically modified models similar to those created in mice are not available. D374Y gain-of-function mutations in the proprotein convertase subtilisin/kexin type 9 (PCSK9) gene cause severe autosomal dominant hypercholesterolemia and accelerates atherosclerosis in humans. Using Sleeping Beauty DNA transposition and cloning by somatic cell nuclear transfer, we created Yucatan minipigs with liver-specific expression of human D374Y-PCSK9. D374Y-PCSK9 transgenic pigs displayed reduced hepatic low-density lipoprotein (LDL) receptor levels, impaired LDL clearance, severe hypercholesterolemia, and spontaneous development of progressive atherosclerotic lesions that could be visualized by noninvasive imaging. This model should prove useful for several types of translational research in atherosclerosis.

Hybrid Lentivirus-transposon Vectors With a Random Integration Profile in Human Cells

Gene delivery by human immunodeficiency virus type 1 (HIV-1)-based lentiviral vectors (LVs) is efficient, but genomic integration of the viral DNA is strongly biased toward transcriptionally active loci resulting in an increased risk of insertional mutagenesis in gene therapy protocols. Nonviral Sleeping Beauty (SB) transposon vectors have a significantly safer insertion profile, but efficient delivery into relevant cell/tissue types is a limitation. In an attempt to combine the favorable features of the two vector systems we established a novel hybrid vector technology based on SB transposase-mediated insertion of lentiviral DNA circles generated during transduction of target cells with integrase (IN)-defective LVs (IDLVs). By construction of a lentivirus-transposon hybrid vector allowing transposition exclusively from circular viral DNA substrates, we demonstrate that SB transposase added in trans directs efficient transposon mobilization from DNA circles in vector-transduced cells. Both transfected plasmid DNA and transduced IDLVs can serve as the source of active transposase. Most important, we demonstrate that the SB transposase overrides the natural lentiviral integration pathway and directs vector integration less frequently toward transcriptional units, resulting in a random genomic integration profile. The novel hybrid vector system combines the attractive features of efficient gene delivery by viral transduction and a safer genomic integration profile by DNA transposition.

Pig transgenesis by Sleeping Beauty DNA transposition

Modelling of human disease in genetically engineered pigs provides unique possibilities in biomedical research and in studies of disease intervention. Establishment of methodologies that allow efficient gene insertion by non-viral gene carriers is an important step towards development of new disease models. In this report, we present transgenic pigs created by Sleeping Beauty DNA transposition in primary porcine fibroblasts in combination with somatic cell nuclear transfer by handmade cloning. Göttingen minipigs expressing green fluorescent protein are produced by transgenesis with DNA transposon vectors carrying the transgene driven by the human ubiquitin C promoter. These animals carry multiple copies (from 8 to 13) of the transgene and show systemic transgene expression. Transgene-expressing pigs carry both transposase-catalyzed insertions and at least one copy of randomly inserted plasmid DNA. Our findings illustrate critical issues related to DNA transposon-directed transgenesis, including coincidental plasmid insertion and relatively low Sleeping Beauty transposition activity in porcine fibroblasts, but also provide a platform for future development of porcine disease models using the Sleeping Beauty gene insertion technology.

Postintegrative Gene Silencing within the Sleeping Beauty Transposition System

ABSTRACT The Sleeping Beauty (SB) transposon represents an important vehicle for in vivo gene delivery because it can efficiently and stably integrate into mammalian genomes. In this report, we examined transposon expression in human cells using a novel nonselective fluorescence-activated cell sorter-based method and discovered that SB integrates ∼20 times more frequently than previously reported within systems that were dependent on transgene expression and likely subject to postintegrative gene silencing. Over time, phenotypic analysis of clonal integrants demonstrated that SB undergoes additional postintegrative gene silencing, which varied based on the promoter used for transgene expression. Molecular and biochemical studies suggested that transposon silencing was influenced by DNA methylation and histone deacetylation because both 5-aza-2′-deoxycytidine and trichostatin A partially rescued transgene silencing in clonal cell lines. Collectively, these data reveal the existence of a multicomponent postintegrative gene silencing network that efficiently targets invading transposon sequences for transcriptional silencing in mammalian cells.

miRNA sponges: soaking up miRNAs for regulation of gene expression

MicroRNAs (miRNAs) are small regulatory RNAs that act in an entangled web of interactions with target mRNAs to shape the cellular protein landscape by post‐transcriptional control of mRNA decay and translation. miRNAs are themselves subject to numerous regulatory mechanisms that adjust their prevalence and activity. Emerging evidence suggests that miRNAs are themselves targeted by regulatory RNA species, and the identification of several classes of noncoding RNA molecules carrying miRNA binding sites has added a new intricate dimension to miRNA regulation. Such miRNA ‘sponges’ bind miRNAs and competitively sequester them from their natural targets. Endogenous miRNA sponges, also termed competing endogenous RNAs (ceRNAs), act to buffer the activity of miRNAs on physiologically relevant targets. This class of sponges includes endogenously transcribed pseudogenes, long noncoding RNAs, and recently discovered circular RNAs and may act in large complex networks in conjunction with miRNAs to regulate the output of protein. With the growing demand of regulating miRNA activity for experimental purposes and potential future clinical use, naturally occurring miRNA sponges are providing inspiration for engineering of gene vector‐encoded sponges as potent inhibitors of miRNA activity. Combined with potent and versatile vector technologies, expression of custom‐designed sponges provides new means of managing miRNAs and soaking up miRNAs for therapeutic regulation of gene expression.

Amelioration of Psoriasis by Anti-TNF-α RNAi in the Xenograft Transplantation Model

Tumor necrosis factor-α (TNF-α) is upregulated in psoriatic skin and represents a prominent target in psoriasis treatment. The level of TNF-α-encoding mRNA, however, is not increased in psoriatic skin, and it remains unclear whether intervention strategies based on RNA interference (RNAi) are therapeutically relevant. To test this hypothesis the present study describes first the in vitro functional screening of a panel of short hairpin RNAs (shRNAs) targeting human TNF-α mRNA and, next, the transfer of the most potent TNF-α shRNA variant, as assessed in vitro, to human skin in the psoriasis xenograft transplantation model by the use of lentiviral vectors. TNF-α shRNA treatment leads to amelioration of the psoriasis phentotype in the model, as documented by reduced epidermal thickness, normalization of the skin morphology, and reduced levels of TNF-α mRNA as detected in skin biopsies 3 weeks after a single vector injection of lentiviral vectors encoding TNF-α shRNA. Our data show efficient lentiviral gene delivery to psoriatic skin and therapeutic applicability of anti-TNF-α shRNAs in human skin. These findings validate TNF-α mRNA as a target molecule for a potential persistent RNA-based treatment of psoriasis and establish the use of small RNA effectors as a novel platform for target validation in psoriasis and other skin disorders.Tumor necrosis factor-alpha (TNF-alpha) is upregulated in psoriatic skin and represents a prominent target in psoriasis treatment. The level of TNF-alpha-encoding mRNA, however, is not increased in psoriatic skin, and it remains unclear whether intervention strategies based on RNA interference (RNAi) are therapeutically relevant. To test this hypothesis the present study describes first the in vitro functional screening of a panel of short hairpin RNAs (shRNAs) targeting human TNF-alpha mRNA and, next, the transfer of the most potent TNF-alpha shRNA variant, as assessed in vitro, to human skin in the psoriasis xenograft transplantation model by the use of lentiviral vectors. TNF-alpha shRNA treatment leads to amelioration of the psoriasis phentotype in the model, as documented by reduced epidermal thickness, normalization of the skin morphology, and reduced levels of TNF-alpha mRNA as detected in skin biopsies 3 weeks after a single vector injection of lentiviral vectors encoding TNF-alpha shRNA. Our data show efficient lentiviral gene delivery to psoriatic skin and therapeutic applicability of anti-TNF-alpha shRNAs in human skin. These findings validate TNF-alpha mRNA as a target molecule for a potential persistent RNA-based treatment of psoriasis and establish the use of small RNA effectors as a novel platform for target validation in psoriasis and other skin disorders.

Regulation of pro-inflammatory cytokines TNFα and IL24 by microRNA-203 in primary keratinocytes

Cutaneous homeostasis and innate immunity is procured by a complex circuitry of intercellular cytokine signaling. MicroRNAs are important posttranscriptional regulators of keratinocyte gene expression and assist in modulating the fine balance between cell proliferation and differentiation in skin. A characteristic microRNA profile in inflammatory skin suggests putative functions of microRNAs in perturbed cytokine production and signaling during chronic inflammatory skin conditions such as psoriasis. It remains unclear, however, why certain microRNAs are aberrantly expressed during skin inflammation and if they serve pro- and/or anti-inflammatory functions. In this report, we focus on cytokine regulation by microRNA-203 (miR-203), which is highly abundant in keratinocytes and upregulated in psoriatic lesions. By screening a panel of cytokines that are upregulated in psoriatic skin for regulation by miR-203, we identify the genes encoding the pro-inflammatory cytokines TNFα and IL24 as direct targets of miR-203. Studies of miR-203 overexpression, inhibition, and mutagenesis validate posttranscriptional regulation of TNFα and IL24 by miR-203 in cell lines and primary keratinocytes. Our findings suggest that miR-203 serves to fine-tune cytokine signaling and may dampen skin immune responses by repressing key pro-inflammatory cytokines.

Functional IRF3 deficiency in a patient with herpes simplex encephalitis

Andersen et al. identify a novel genetic etiology of herpes encephalitis in an adult patient carrying a heterozygous loss-of-function mutation in the IRF3 gene. This mutation results in impaired INF production in response to viral infection

Genetic Reassortment and Patch Repair by Recombination in Retroviruses

Retroviral particles contain a diploid RNA genome which serves as template for the synthesis of double-stranded DNA in a complex process guided by virus-encoded reverse transcriptase. The dimeric nature of the genome allows the proceeding polymerase to switch templates during copying of the copackaged RNA molecules, leading to the generation of recombinant proviruses that harbor genetic information derived from both parental RNAs. Template switching abilities of reverse transcriptase facilitate the development of mosaic retroviruses with altered functional properties and thereby contribute to the restoration and evolution of retroviruses facing altering selective forces of their environment. This review focuses on the genetic patchwork of retroviruses and how mixing of sequence patches by recombination may lead to repair in terms of re-established replication and facilitate increased viral fitness, enhanced pathogenic potential, and altered virus tropisms. Endogenous retroelements represent an affluent source of functional viral sequences which may hitchhike with virions and serve as sequence donors in patch repair. We describe here the involvement of endogenous viruses in genetic reassortment and patch repair and review important examples derived from cell culture and animal studies. Moreover, we discuss how the patch repair phenomenon may challenge both safe usage of retrovirus-based gene vehicles in human gene therapy and the use of animal organs as xenografts in humans. Finally, the ongoing mixing of distinct human immunodeficiency virus strains and its implications for antiviral treatment is discussed.