Mechanism of Reduction in Titers with Vectors Flanked by Chromatin Insulator Elements

Blood ◽  
2007 ◽  
Vol 110 (11) ◽  
pp. 3734-3734
Author(s):  
Fabrizia Urbinati ◽  
Paritha Arumugam ◽  
Tomoyasu Higashimoto ◽  
Ping Xia ◽  
Punam Malik
Keyword(s):  
Gene Therapy ◽  
Viral Genome ◽  
Tandem Repeats ◽  
Full Length ◽  
Beta Thalassemia ◽  
Similar Degree ◽  
Core Element ◽  
Position Effects ◽  
Variable Expression ◽  
Chs4 Insulator

Abstract Random integration of viral vectors can result in undesirable activation of surrounding genes by enhancers in the vectors (vector genotoxicity), or result in variable expression due to effects of surrounding chromatin on the vector transgene (position effects). Vector genotoxicity has become an area of intense study since the occurrence of gene therapy related leukemias in patients in the French X-SCID trial. Additionally, variability in expression has been shown to compromize therapeutic efficacy in gene therapy for beta-thalassemia, where a high consistent level of expression is necessary. Vectors flanked by the cHS4 insulator, one of the best characterized insulator element, can reduce vector genotoxicity (Neinhuis et al, 2007) and chromatin position effects in γ-retrovirus (Rivella et al, 2000; Yannaki et al, 2002) and lentivirus vectors (Arumugam et al, 2007). Despite these favorable features, the full-length cHS4 insulator, necessary for optimal insulator activity, is infrequently used because it lowers vector infectious titers by 10–15 fold (Ramezani et al, 2003). This reduction in titers is especially limiting with vectors carrying large inserts. We analyzed mechanisms by which this occurred. Insertion of an additional 1.2kb internal cassette to the large human β-globin-LCR (hβ-LCR) lentiviral (LV) vectors did not reduce vector infectious titers. However, insertion of the 1.2Kb cHS4 element reduced titers by more than an order of magntude; showing that reduction in titers by cHS4 was not secondary to a further lengthening of vector genome but this occurred either due to a large insert in the 3′LTR or specific cHS4 sequences that bind cellular factors and hinder viral genome transcription. We then inserted varying sized fragments of cHS4, tandem repeats of the cHS4 core element, or inert DNA spacers in the 3′LTR of the hβ-LCR LV vector, sBG, resulting in vectors with 3′LTR inserts of 0, 250, 400, 500, 650, 800 and 1200bp. After a threshold length of 650bp, infectious titers fell proportional to the size of the insert into the LTR. The same effect was seen with inert DNA spacer elements, showing that this phenomenon was not sequence-specific. We next examined the stage of the vector life-cycle affected by large LTR inserts: lengthening of the 3′LTR did not increase viral readthrough transcription, as measured by northern blot analysis and an enzyme-based assay for readthrough transcription (Higashimoto et al, 2007). Equal amounts of full-length viral genomic transcripts were produced in the packaging cells with vectors with and without the insulator. Similar degree of viral genome encapsidation occurred, as measured by p24 ELISA, virus associated reverse transcriptase and viral RNA analysis, demonstrating that similar amounts of intact viral particles were produced with insulated and uninsulated vector plasmids. However, the insulated vector was inefficiently processed following target cell entry, resulting in less integrated vector; and thus lowers infectious titers. Of note, a vector carrying tandem repeats of the cHS4 core (two 250bp repeats) resulted in increased rate of recombination, with deletion of the insulator core at a high frequency. Thus, we found that large inserts in the viral 3′LTR are packaged efficiently, but have inefficient post-entry viral mRNA processing. These studies have important implications in the design of γ-retrovirus and LV vectors with insulator and other transgene/promoter/enhancer inserts into the LTR.

A Novel Combination of Chicken Hypersensitive Site-4 Insulator Elements Improves Titers and Restores Full Insulator Activity.

Blood ◽  
2009 ◽  
Vol 114 (22) ◽  
pp. 3566-3566
Author(s):  
Paritha Arumugam ◽  
Fabrizia Urbinati ◽  
Chinavenmeni S. Velu ◽  
Tomoyasu Higashimoto ◽  
H. Leighton Grimes ◽  
...  
Keyword(s):  
Gene Therapy ◽  
Transgene Expression ◽  
Viral Vectors ◽  
Full Length ◽  
Hypersensitive Site ◽  
Position Effects ◽  
Insulator Activity ◽  
Insulator Elements ◽  
Chs4 Insulator

Abstract Abstract 3566 Poster Board III-503 Chromatin insulators separate active transcriptional domains and block the spread of heterochromatin in the genome. A prototypic insulator, the 1.2Kb chicken hypersensitive site-4 (cHS4) element utilizes CTCF and USF-1/2 motifs in the proximal 250bp. This smaller “core” cHS4 element provides enhancer blocking activity and reduces position effects. However, the cHS4 core sequences alone do not insulate viral vectors effectively. Two copies of the core, while effective in plasmid based systems, are unstable in viral vectors. In contrast, the full-length cHS4 has excellent insulating properties, but its large size severely compromises vector titers (Urbinati et al, Mol Ther 2009). Therefore, we performed a structure-function analysis of the full-length cHS4 in the context of self inactivating lentivirus-vectors to identify minimal insulator elements required for optimal insulation. Specifically, we analyzed transgene expression in the clonal progeny of primary murine hematopoietic stem cells using the secondary bone marrow transplant assay, and analyzed epigenetic changes in cHS4 and the transgene promoter in vitro in clonal integrants. As expected, the full length cHS4 insulator reduced clonal variegation in transgene expression, reduced position effects and blocked silencing-associated epigenetic modifications over the insulator core and the transgene promoter. However, while either the 5′ cHS4 250bp core or the 3′ cHS4 400bp sequences similarly effected only lower clonal variegation in transgene expression, when they were combined these 650bp sequences recapitulated the activity of the full length 1.2kb insulator, with minimal impact on viral titer. The distal 3′ 400bp fragment contains no consensus sites for USF or CTCF. However, ChIP analysis on proviruses carrying only the 3′ 400bp showed that it binds CTCF. USF-1 binding to the 3′ 400bp, however, only occurred when both the 5′ 250bp core and the 3′ 400bp fragment were present in the proviruses. Indeed, the silencing associated epigenetic marks over the 3′ 400bp region were blocked only when the vector carried both these ends of cHS4 insulator sequences, suggesting that USF-1 bridges the 5′ core and the 3′ 400bp to confer full insulator activity. Furthermore, the 650bp sequences or the full length insulator had the maximal reduction in clonal dominance in the in vitro immortalization assay of lineage negative primary murine hematopoietic cells (Arumugam et al, Mol Ther. In press). Our studies confirm and extend earlier observations on the 5′ 250bp insulator core and identify a new “core-like” insulator activity in the 3′ end of cHS4. The specific elements in the 3′ 400bp sequences that promote interaction with the 5′ 250bp sequences would be important to determine, and may be present in other insulators in and across the genome/s. In the meanwhile, new vector systems flanked by this optimized ‘650bp’ cHS4 sequences, can provide excellent insulation of the transgene without significant loss in viral titers and have important safety and efficacy implications for gene therapy. Our data have important implications in understanding the molecular basis of insulator function and design of gene therapy vectors. Disclosures: No relevant conflicts of interest to declare.

Mechanism of Reduction in Titers from Lentivirus Vectors Carrying Chromatin Insulator Elements in the 3′ LTR

Blood ◽  
2008 ◽  
Vol 112 (11) ◽  
pp. 2359-2359
Author(s):  
Fabrizia Urbinati ◽  
Paritha Arumugam ◽  
Tomoyasu Higashimoto ◽  
Anil Perumbeti ◽  
Ping Xia ◽  
...  
Keyword(s):  
Function Analysis ◽  
Regulatory Elements ◽  
Target Cells ◽  
Position Effects ◽  
Variable Expression ◽  
Vector Systems ◽  
Insulator Activity ◽  
Post Entry ◽  
Lentivirus Vectors ◽  
Chs4 Insulator

Abstract Random integration of viral vectors can result in undesirable activation of surrounding genes by enhancers in the vectors (vector genotoxicity), or result in variable expression due to effects of surrounding chromatin on the vector transgene (chromatin position effects). Vector genotoxicity has become an area of intense study since the occurrence of gene therapy related leukemias in 5 patients in the French X-SCID trial. Additionally, we find consistent and therefore 2–3 fold higher expression from vectors insulated by the chicken b-globin hypersensitive site (cHS4) insulator; and these vectors achieve therapeutic correction in human b0-thalassemia major, where a very high transgene expression is necessary. However, vectors that insulate the correcting transgene from position effects and genotoxicity significantly compromise viral titers by an order of magnitude. In order to define the mechanism by which this occurs and improve the titers of insulated vector systems, we placed the 1.2Kb cHS4 insulator or different regions of cHS4 that may have insulator activity and/or inert DNA spacers in the 3′LTR of self-inactivating lentiviruses carrying a large b-globin transgene and regulatory elements. We also lengthened the β-globin lentivirus vector by an additional 1.2Kb, by insertion of an internal transgene cassette. We found that addition of 1.2Kb transgene internally to a large “globin” vector did not reduce vector infectious titers. However, when cHS4 sequences or inert DNA spacers of increasing size were placed in the 3′LTR, infectious titers decreased proportional to the length of the insert. This effect occurred regardless of the type of sequence inserted in the 3′ LTR. Vectors carrying the1.2Kb cHS4 or l-DNA spacer in the 3′ LTR had the lowest titers. We next examined the stage of the vector life-cycle affected by large LTR inserts in packaging cells, the quantity and quality of the virus particles generated, and post-entry viral steps in target cells. Equal amounts of full-length viral genomic transcripts were produced in the packaging cells with vectors with or without the 1.2Kb insulator insert. All insertion in the 3′ LTR are placed in the U3 enhancer deleted region, proximal to the viral polyadenylation signal. Also, self-inactivating vectors have a U3 enhancer deletion that also deletes enhancers of polyadenylation. However, despite the insertion of cHS4 elements in this region, no increase in viral readthrough transcription (as measured by northern blot analysis and an enzyme-based assay) occurred with vectors carrying the large 1.2Kb insert. Packaging efficiency was also identical with insulated and uninsulated vectors. Similar degree of viral genome encapsidation occurred, as measured by p24 ELISA, virus associated reverse transcriptase and viral RNA analysis, demonstrating that similar amounts of intact viral particles were produced with insulated and uninsulated vector plasmids. However, lentiviruses carrying the 1.2Kb insert in the 3′LTR were inefficiently processed following target-cell entry, with reduced reverse transcription and integration efficiency. This primarily occurred from increased homologous recombination resulting in increased 1-LTR circles of the insulated vector viral DNA; resulting in reduced vector integration and hence lower transduction/infectious titers. Thus, we found that large inserts in the viral 3′ LTR are packaged efficiently, but have inefficient post-entry viral mRNA processing. In a parallel study, we also did a structure-function analysis of cHS4 fragments and identified key elements necessary for optimal insulation. Vectors constructed with this minimized 650bp cHS4 sequences had a minimal reduction in titers, yet retained full insulator activity. These studies have important implications in the design of gamma-retrovirus or lentivirus vectors with insulator, transgenes or enhancer inserts into the 3′ LTR. [FU and PA contributed equally to this work]

scholarly journals A New Begomovirus Species Causing Tomato Leaf Curl Disease in Patna, India

Plant Disease ◽  
2009 ◽  
Vol 93 (5) ◽  
pp. 545-545 ◽  
Author(s):  
P. Kumari ◽  
B. Chattopadhyay ◽  
A. K. Singh ◽  
S. Chakraborty
Keyword(s):  
Viral Genome ◽  
Tandem Repeats ◽  
Tomato Leaf ◽  
Begomovirus Species ◽  
Full Length ◽  
Degenerate Primers ◽  
Viral Dna ◽  
Tomato Leaf Curl ◽  
Leaf Curl Disease ◽  
Leaf Curl

During December of 2007, a severe leaf curl disease of tomato (ToLCD) occurred in tomato-growing areas in the Patna District of Bihar, India. Viral DNA was isolated from symptomatic tomato plants (2) and begomovirus association was confirmed by PCR using DNA-A degenerate primers (3). Isolated viral DNA was restricted with KpnI and full-length genome was cloned in pUC18. DNA-β was amplified using degenerate primers (1) and cloned in pTZ57RT. Partial tandem repeats of viral genome and DNA-β could infect Nicotiana benthamiana and tomato through Agrobacterium-mediated inoculation. Infected test plants exhibited typical symptoms characteristic of ToLCD. Full-length viral genome (GenBank Accession No. EU862323) consists of 2,752 nt and showed the highest identity (85.8%) with Tomato leaf curl Laos virus-[Laos] (GenBank Accession No. AF195782). The satellite DNA-β component (GenBank Accession No. EU862324) consists of 1,349 nt and showed the highest identity (75.8%) with Tomato leaf curl Joydebpur betasatellite (GenBank Accession No. AJ966244). On the basis of the ICTV species demarcation criteria of 89% of DNA-A sequence identity, the present isolate was considered as a new begomovirus species and named Tomato leaf curl Patna virus (ToLCPaV). Since the isolated DNA-β satellite shares less than 78% identity, it is considered a new species of betasatellite and the name, Tomato leaf curl Patna betasatellite (ToLCPaB) is proposed. These results show that severe ToLCD in Patna is caused by a newly identified species of begomovirus and betasatellite. References: (1) R. W. Briddon et al. Mol. Biotechnol 20:315, 2002. (2) S. Chakraborty et al. Phytopathology 93:1485, 2003. (3) S. D. Wyatt and J. K. Brown. Phytopathology 86:1288, 1996.

scholarly journals Latest Advances of Virology Research Using CRISPR/Cas9-Based Gene-Editing Technology and Its Application to Vaccine Development

Viruses ◽  
2021 ◽  
Vol 13 (5) ◽  
pp. 779
Author(s):  
Man Teng ◽  
Yongxiu Yao ◽  
Venugopal Nair ◽  
Jun Luo
Keyword(s):  
Biological Sciences ◽  
Gene Therapy ◽  
Genetic Engineering ◽  
Gene Function ◽  
Viral Genome ◽  
Gene Editing ◽  
Vaccine Development ◽  
Future Prospects ◽  
Dna Viruses ◽  
Viral Genomes

In recent years, the CRISPR/Cas9-based gene-editing techniques have been well developed and applied widely in several aspects of research in the biological sciences, in many species, including humans, animals, plants, and even in viruses. Modification of the viral genome is crucial for revealing gene function, virus pathogenesis, gene therapy, genetic engineering, and vaccine development. Herein, we have provided a brief review of the different technologies for the modification of the viral genomes. Particularly, we have focused on the recently developed CRISPR/Cas9-based gene-editing system, detailing its origin, functional principles, and touching on its latest achievements in virology research and applications in vaccine development, especially in large DNA viruses of humans and animals. Future prospects of CRISPR/Cas9-based gene-editing technology in virology research, including the potential shortcomings, are also discussed.

scholarly journals Genome Editing Strategies to Treat Beta-Hemoglobinopathies

Blood ◽  
2017 ◽  
Vol 130 (Suppl_1) ◽  
pp. SCI-16-SCI-16
Author(s):  
Mitchell J Weiss
Keyword(s):  
Gene Therapy ◽  
Genome Editing ◽  
Conflicts Of Interest ◽  
Gene Mutations ◽  
Fetal Hemoglobin ◽  
Beta Thalassemia ◽  
Great Promise ◽  
Globin Genes ◽  
Hematopoietic Stem ◽  
Medical Therapies

Genetic forms of anemia caused by HBB gene mutations that impair beta globin production are extremely common worldwide. The resultant disorders, mainly sickle cell disease (SCD) and beta-thalassemia, cause substantial morbidity and early mortality. Treatments for these diseases include medical therapies and bone marrow transplantation (BMT), which can be curative. However, medical therapies are suboptimal and BMT is associated with serious toxicities, particularly because HLA-matched allogeneic sibling donors are not available for most patients. Thus, new therapies are urgently needed for millions of affected individuals. Gene therapy offers great promise to cure SCD and beta thalassemia and emerging genome editing technologies represent a new form of gene therapy. Approaches to cure SCD and beta-thalassemia via genome editing include: 1) Correction of HBB mutations by homology directed repair (HDR); 2) use of non-homologous end joining (NHEJ) to activate gamma globin production and raise fetal hemoglobin (HbF) levels; 3) NHEJ to disrupt alpha-globin genes (HBA1 or HBA2) and thereby alleviate globin chain imbalance in intermediately severe forms of beta thalassemia. Challenges for these approaches include selection of the most effective genome editing tools, optimizing their delivery to hematopoietic stem cells (HSCs), improving specificity and better understanding potential off target effects, particularly those that are biologically relevant. Technologies for genome editing are advancing rapidly and being tested in preclinical models for HBB-mutated disorders. Ultimately, however, the best strategies can only be identified in clinical trials. This will require close collaborations between basic/translational researchers who study genome editing, clinical hematologists and collaboration between experts in academia and the bio-pharmaceutical industry. Disclosures No relevant conflicts of interest to declare.

scholarly journals Genome Size Estimation and Full-Length Transcriptome of Sphingonotus tsinlingensis: Genetic Background of a Drought-Adapted Grasshopper

2021 ◽  
Vol 12 ◽  
Author(s):  
Lu Zhao ◽  
Hang Wang ◽  
Ping Li ◽  
Kuo Sun ◽  
De-Long Guan ◽  
...  
Keyword(s):  
Genome Size ◽  
Genetic Background ◽  
Tandem Repeats ◽  
Full Length ◽  
Arid Environments ◽  
Size Estimation ◽  
Sequencing Data ◽  
Protein Coding ◽  
Grasshopper Species ◽  
Hsp Genes

Sphingonotus Fieber, 1852 (Orthoptera: Acrididae), is a grasshopper genus comprising approximately 170 species, all of which prefer dry environments such as deserts, steppes, and stony benchlands. In this study, we aimed to examine the adaptation of grasshopper species to arid environments. The genome size of Sphingonotus tsinlingensis was estimated using flow cytometry, and the first high-quality full-length transcriptome of this species was produced. The genome size of S. tsinlingensis is approximately 12.8 Gb. Based on 146.98 Gb of PacBio sequencing data, 221.47 Mb full-length transcripts were assembled. Among these, 88,693 non-redundant isoforms were identified with an N50 value of 2,726 bp, which was markedly longer than previous grasshopper transcriptome assemblies. In total, 48,502 protein-coding sequences were identified, and 37,569 were annotated using public gene function databases. Moreover, 36,488 simple tandem repeats, 12,765 long non-coding RNAs, and 414 transcription factors were identified. According to gene functions, 61 cytochrome P450 (CYP450) and 66 heat shock protein (HSP) genes, which may be associated with drought adaptation of S. tsinlingensis, were identified. We compared the transcriptomes of S. tsinlingensis and two other grasshopper species which were less tolerant to drought, namely Mongolotettix japonicus and Gomphocerus licenti. We observed the expression of CYP450 and HSP genes in S. tsinlingensis were higher. We produced the first full-length transcriptome of a Sphingonotus species that has an ultra-large genome. The assembly characteristics were better than those of all known grasshopper transcriptomes. This full-length transcriptome may thus be used to understand the genetic background and evolution of grasshoppers.

Sign in / Sign up

Export Citation Format

Share Document