Genomic DNA Loci Research Articles

Spatially resolved epigenome sequencing via Tn5 transposition and deterministic DNA barcoding in tissue.

Spatial epigenetic mapping of tissues enables the study of gene regulation programs and cellular functions with the dependency on their local tissue environment. Here we outline a complete procedure for two spatial epigenomic profiling methods: spatially resolved genome-wide profiling of histone modifications using in situ cleavage under targets and tagmentation (CUT&Tag) chemistry (spatial-CUT&Tag) and transposase-accessible chromatin sequencing (spatial-ATAC-sequencing) for chromatin accessibility. Both assays utilize in-tissue Tn5 transposition to recognize genomic DNA loci followed by microfluidic deterministic barcoding to incorporate spatial address codes. Furthermore, these two methods do not necessitate prior knowledge of the transcription or epigenetic markers for a given tissue or cell type but permit genome-wide unbiased profiling pixel-by-pixel at the 10 μm pixel size level and single-base resolution. To support the widespread adaptation of these methods, details are provided in five general steps: (1) sample preparation; (2) Tn5 transposition in spatial-ATAC-sequencing or antibody-controlled pA-Tn5 tagmentation in CUT&Tag; (3) library preparation; (4) next-generation sequencing; and (5) data analysis using our customed pipelines available at: https://github.com/dyxmvp/Spatial_ATAC-seq and https://github.com/dyxmvp/spatial-CUT-Tag . The whole procedure can be completed on four samples in 2-3 days. Familiarity with basic molecular biology and bioinformatics skills with access to a high-performance computing environment are required. A rudimentary understanding of pathology and specimen sectioning, as well as deterministic barcoding in tissue-specific skills (e.g., design of a multiparameter barcode panel and creation of microfluidic devices), are also advantageous. In this protocol, we mainly focus on spatial profiling of tissue region-specific epigenetic landscapes in mouse embryos and mouse brains using spatial-ATAC-sequencing and spatial-CUT&Tag, but these methods can be used for other species with no need for species-specific probe design.

Nanopore-Sequencing Metabarcoding for Identification of Phytopathogenic and Endophytic Fungi in Olive (Olea europaea) Twigs.

Metabarcoding approaches for the identification of plant disease pathogens and characterization of plant microbial populations constitute a rapidly evolving research field. Fungal plant diseases are of major phytopathological concern; thus, the development of metabarcoding approaches for the detection of phytopathogenic fungi is becoming increasingly imperative in the context of plant disease prognosis. We developed a multiplex metabarcoding method for the identification of fungal phytopathogens and endophytes in olive young shoots, using the MinION sequencing platform (Oxford Nanopore Technologies). Selected fungal-specific primers were used to amplify three different genomic DNA loci (ITS, beta-tubulin, and 28S LSU) originating from olive twigs. A multiplex metabarcoding approach was initially evaluated using healthy olive twigs, and further assessed with naturally infected olive twig samples. Bioinformatic analysis of basecalled reads was carried out using MinKNOW, BLAST+ and R programming, and results were also evaluated using the BugSeq cloud platform. Data analysis highlighted the approaches based on ITS and their combination with beta-tubulin as the most informative ones according to diversity estimations. Subsequent implementation of the method on symptomatic samples identified major olive pathogens and endophytes including genera such as Cladosporium, Didymosphaeria, Paraconiothyrium, Penicillium, Phoma, Verticillium, and others.

First Report of Colletotrichum gloeosporioides and Colletotrichum siamense, Causing Anthracnose Disease on coffee trees, in Saudi Arabia.

Coffee (Coffea arabica L.) is a promising agricultural commodity in many countries including Saudi Arabia, but crop production is often constrained by diseases. In December 2021, coffee trees had symptoms of anthracnose disease (CAD) were observed in Jazan Province, Saudi Arabia (17°19'00.8"N 43°11'26.8"E), and the incidence was 55%. Affected trees showed dieback and leaves necrosis. On green and ripening berries, slightly sunken and dark brown lesions were occurred; the berries finally become mummified (Fig. S1). For pathogen isolation, symptomatic tissues (4×4mm) of 30 diseased branches and berries samples were surface-sterilized in 1% sodium hypochlorite for 2 min, followed by 70% ethanol for 20 s, rinsed in sterile distilled water and placed on potato dextrose agar (PDA). Cultures were incubated at 26℃ for 8 days in the dark. Eighteen isolates were recovered, and 2 representative single spore isolates (KSU-CgM17, KSU-CsM42) were used for further study. PDA culture of KSU-CgM17 had aerial white mycelium at first and later became gray to grayish black; light salmon to orange conidial masses were observed on the mycelium plate surface as the cultures aged (Fig. S2). Colony produced by KSU-CsM42 was off-white to gray with cottony mycelia and grayish-white on the undersides of the culture after 10 days at 28° (Fig. S2). Conidial shape of these two isolates were both aseptate, cylindrical to nearly straight, hyaline, rounded at both ends. Conidia (n = 50) measurements were 16 to 18.0 µm long × 4.8 to 6.4 µm wide for KSU-CgM17 and 12.6 to 17.5 µm long × 3.2 to 4.5 μm wide for KSU-CsM42. The microscopic and culture features fitted those for Colletotrichum gloeosporioides species complex (Weir et al. 2012). To further identify these isolates, four genomic DNA loci including the partial ITS rDNA region, and CAL, TUB2, and GAPDH genes were amplified and sequenced (Hu et al., 2015). All sequences were deposited into GenBank under accession numbers: OQ791412 & OQ791413 (ITS), OQ786847 & OQ786851 (CAL), OQ786849 & OQ786850 (TUB2), and OQ786848 & OQ786852 (GAPDH) for KSU-CgM17and KSU-CsM42, respectively (Tables S1& S2). A BLAST search of GenBank showed that these pathogens were identified as C. gloeosporioides (KSU-CgM17) and C. siamense (KSU-CsM42). The pathogenicity was tested on detached coffee leaves or green and red berries (Coa et al., 2019). For inoculation, healthy leaves and berries were wounded with a sterilized needle, placed inside petri dishes containing moist filter paper, and then inoculated with a 10-µl droplet of conidial suspension (106 spores/ ml). Sterile distilled water was used as a negative control. Six replicates were tested per isolate and the experiment was repeated once. The inoculated materials were incubated at 25°C and 100% relative humidity for 8 days. Necrotic lesions developed on 100% of the inoculated coffee materials 6 days later, whereas the negative controls were asymptomatic (Fig. S2). Koch's postulates were fulfilled when typical colonies of these species were successfully re-isolated from the from symptomatic tissues. These pathogens were reported previously to affect coffee in Vietnam (Nguyen et al., 2010), China (Cao et al., 2019), and Puerto Rico (Serrato-Diaz et al., 2020). To our knowledge, this is the first record of C. gloeosporioides and C. siamense causing CAD in Saudi Arabia. Further studies on the epidemiology of CAD on arabica coffee plantations as well as effective strategies for managing this disease are needed.

First report of anthracnose on spotted laurel caused by Colletotrichum fructicola in South Korea.

Spotted laurel (Aucuba japonica) is a popular ornamental bush (it has two-colored leaves and red berries) and is used outdoors and indoors for decoration in South Korea. Anthracnose reduces the aesthetic value of spotted laurel leaves. In August 2022, anthracnose symptoms were observed on leaves in a park at Jeju Island, South Korea. Approximately 55% of bushes were infected by this disease. Symptoms consisted of round or irregular lesions that initially appeared as black spots and coalesced into larger, black lesions covering whole leaves and twigs. Entire leaves wither and finally die. To identify the putative causal agent, 12 affected leaves were collected, placed in a plastic box containing moist tissue, and incubated at 25 ºC in the dark to obtain conidial mass. Conidial masses were produced on leaf lesions after 2 days, and then 12 morphologically similar fungal isolates were recovered following single the spore isolation technique on solid potato dextrose agar (PDA) (Cai et al. 2009). Ten-day-old colonies were olivaceous gray with immersed perithecia on the upper side and black at the center on the reverse side. Conidia were aseptate, cylindrical with round ends and measured 14.9 - 22.7 × 5.5 - 9.4 μm (n = 80). Appressoria were brown, irregular in shape, and 7.0 - 16.1 × 5.00 - 9.9 μm (n = 50). Asci were eight-spored, banana-shaped, and measuring 60.8 - 123.1 × 13.00 - 18.9 μm (n = 30). Hyaline ascospores were single-celled, curved or straight with round ends, and ranged in size was 15.5 - 23.3 × 5.1 - 11.8 μm (n = 50). The morphological characteristics of the isolates overlapped with those of Colletotrichum species within the C. gloeosporioides complex, including Colletotrichum fructicola (Weir et al. 2012). Five genomic DNA loci of the isolates, including the partial ITS rDNA region, ACT, GAPDH, TUB, and ApMat genes, were amplified and sequenced using ITSF1/ITS4, ACT-512F/ACT-783R, GDF/GDR, T1/Bt2b, and AM-F/AM-R, respectively (Silva et al. 2012; Weir et al. 2012). The resulting consensus sequences were deposited in the GenBank and the accession numbers (ITS = LC739331- LC739334, TUB = LC739335- LC739338, GAPDH = LC739339- LC739342, ACT = LC739343 -LC739346, ApMat = LC742925 - LC742928) were obtained. A maximum phylogenetic tree was constructed based on the combined data sets of ITS, ACT, GAPDH, TUB, ApMat sequences. The isolates were clustered with reference isolates of C. fructicola (isolates ICMP18581). The pathogenicity test was performed on uninfected, healthy spotted laurel cuttings in the pot. Five leaves per seedling were selected, surface sterilized with 70% ethanol, and rinsed with sterile distilled water (SDW). A sterile pin was used to make 3 to 4 wounds on each side of the leaf from the midrib. 10 μl of spore suspension per wound spot (1 × 106 spores/ml) was applied on the wounds of one site from midrib, and SDW was placed on the wounds of other site as a control. The treated seedlings were covered with sterile plastic bag and kept in a 12-h fluorescent light/dark cycle under greenhouse conditions at 25 ± 2°C and 80% relative humidity. Two seedlings were inoculated with a single isolate, and this experiment was repeated twice. Circular or irregular lesions appeared after 5 days of inoculation, while the control remained asymptotic. Koch's postulates were fulfilled by reisolating and reidentifying the causal agent from the lesions of inoculated leaves. Colletotrichum fructicola has been reported as the causal agent of anthracnose on mango (Joa et al. 2016), apple (Kim et al. 2018), grapes (Lim et al. 2019), peaches (Lee et al. 2020), and hybrid pear (Choi et al. 2021) in South Korea. To the best of our knowledge, it is the first report of C. fructicola causing anthracnose on spotted laurel. This study will be helpful to develop effective management strategies to minimize leaf lesions.

Screening Sperm for the Rapid Isolation of Germline Edits in Zebrafish.

The advent of targeted CRISPR-Cas nuclease technologies has revolutionized the ability to perform precise genome editing in both established and emerging model systems. CRISPR-Cas genome editing systems use a synthetic guide RNA (sgRNA) to target a CRISPR-associated (Cas) endonuclease to specific genomic DNA loci, where the Cas endonuclease generates a double-strand break. The repair of double-strand breaks by intrinsic error-prone mechanisms leads to insertions and/or deletions, disrupting the locus. Alternatively, the inclusion of double-stranded DNA donors or single-stranded DNA oligonucleotides in this process can elicit the inclusion of precise genome edits ranging from single nucleotide polymorphisms to small immunological tags or even large fluorescent protein constructs. However, a major bottleneck in this procedure can be finding and isolating the desired edit in the germline. This protocol outlines a robust method for screening and isolating germline mutations at specific loci in Danio rerio (zebrafish); however, these principles may be adaptable in any model where in vivo sperm collection is possible.

Determining On‐Target, Off‐Target, and Copy Number Status of Transgenic Events After CRISPR/Cas9 Targeted AAVS1 Safe‐Harbor Modification of iPSCs Using Double‐Control Quantitative Copy Number PCR

Double-control quantitative copy number PCR (dc-qcnPCR) is a recently described tool that can be used to quantify donor DNA insertions in genetically modified monoclonal cell lines. In conjunction with an insert-confirmation PCR, the technique can quickly and easily identify clones containing on-target heterozygous or homozygous donor DNA integrations and exclude off-target insertions. The genetic manipulation of immortal cell lines is a versatile tool to elucidate cellular signaling pathways and protein functions. Despite recent advances in the precision of genetic engineering tools such as CRISPR/Cas9, transcription-activator-like effector nucleases (TALENs), and zinc-finger nucleases (ZFNs), it is still essential to verify the accurate insertion of the sequence of interest (donor DNA) into the targeted genomic DNA (gDNA) locus. This precise integration into a genetic safe harbor, and exclusion of the donor DNA from functionally relevant genes, can ensure normal cellular functionality. Current methods to analyze the specificity of donor DNA insertions either are cost-prohibitive or create dependency on manufacturers for assay design and production. The dc-qcnPCR method is a simple, yet powerful, approach that can be prepared and carried out in any laboratory equipped with standard molecular biology supplies. Here we provide step-by-step instructions to prepare and perform the dc-qcnPCR, and its companion insert-confirmation PCR, to determine donor DNA insertion numbers in monoclonal cell lines genetically modified through CRISPR/Cas9. © 2023 The Authors. Current Protocols published by Wiley Periodicals LLC. Basic Protocol 1: Genetic modification at AAVS1 safe harbor in induced pluripotent stem cells (IMR90-4) using CRISPR/Cas9: from plasmid design to monoclonal expansion Support Protocol 1: Measurement of Gaussia luciferase activity to verify reporter protein functionality Support Protocol 2: Verification of monoclonal expansion using immunofluorescence. Basic Protocol 2: Insert-confirmation PCR Basic Protocol 3: Design and preparation of double-control quantitative copy number PCR reagents and quantification of donor DNA integrations in genetically modified monoclonal cells.

Treating Transthyretin Amyloidosis via Adeno-Associated Virus Vector Delivery of Meganucleases.

Transthyretin amyloidosis (ATTR) is a progressive and fatal disease caused by transthyretin (TTR) amyloid fibril accumulation in tissues, which disrupts organ function. As the TTR protein is primarily synthesized by the liver, liver transplantation can cure familial ATTR but is not an option for the predominant age-related wild-type ATTR. Approved treatment approaches include TTR stabilizers and an RNA-interference therapeutic, but these require regular re-administration. Gene editing could represent an effective one-time treatment. We evaluated adeno-associated virus (AAV) vector-delivered, gene-editing meganucleases to reduce TTR levels. We used engineered meganucleases targeting two different sites within the TTR gene. AAV vectors expressing TTR meganuclease transgenes were first tested in immunodeficient mice expressing the human TTR sequence delivered using an AAV vector and then against the endogenous TTR gene in rhesus macaques. Following a dose of 3 × 1013 genome copies per kilogram, we detected on-target editing efficiency of up to 45% insertions and deletions (indels) in the TTR genomic DNA locus and >80% indels in TTR RNA, with a concomitant decrease in serum TTR levels of >95% in macaques. The significant reduction in serum TTR levels following TTR gene editing indicates that this approach could be an effective treatment for ATTR.

P456: A LONG READ SEQUENCING AND CRISPR-CAS9 BASED APPROACH FOR RAPID COPY-NUMBER ALTERATION AND STRUCTURAL VARIATION DETECTION IN HEMATOLOGIC MALIGNANCIES

Background: Current standard karyotyping methods are labor-intensive and have severe limitations in terms of resolution and duration to results. For hematologic malignancies, but not restricted to, this represents a relevant obstacle in translating molecular findings into time critical treatment decisions. Aims: To develop a sequencing based approach for rapid and scalable cytogenetics that can be applied to a wide spectrum of hematologic malignancies to detect clinically relevant molecular markers within 48hrs Methods: For copy number alteration detection, whole genome sequencing was performed on a GridION sequencer (Oxford Nanopore Technologies, ONT, using the SQK-LSK109 kit) in a cohort of 53 hematologic neoplasms, including acute myeloid leukemia (AML, n=18), chronic lymphocytic leukemia (CLL, n=8), multiple myeloma (MM, n=17) and pediatric acute lymphocytic leukemia (ALL, n=10) samples. For the identification of balanced alterations, transcriptome sequencing data were generated using ONT (SQK-DCS109 kit), and we applied an in-house developed analysis pipeline based on minimap2 alignment followed by Blast with an ensuing filtering algorithm based on orientation, inter-read distance and length filtering. For targeted sequencing of structural aberrations, we developed a CRISPR-Cas9 based tiling approach using sgRNA pools (Integrated DNA Technologies, IDT). This approach allows to cover AML relevant targets such as t(8;21), the KMT2A (MLL) breakpoint area, and the FLT3-ITD region as well as lymphoma relevant regions such as the immunoglobulin heavy chain locus (library preparation was performed using SQK-CS9109 kit). Results: For copy number profiling a median whole-genome coverage of 2.6 was reached (range 0.27-7 fold). ONT sequencing and conventional karyotyping approaches showed a high concordance with Pearson correlation coefficients >0.95 for copy number alteration comparisons between conventional cytogenetics and ONT sequencing results for all investigated disease entities. Regarding the detection of structural aberrations transcriptome sequencing and fusion gene analysis using the above described analysis and filtering pipeline we could e.g. reliably detect the t(9;22) translocation from the K562 cell line and the t(8;21) translocation from Kasumi-1. Additionally, using this method we were able to correctly identify the primary AML sample harboring a t(8;21) translocation that was among the n=12 AML patient samples. In addition to an RNA-based work-flow, we established a CRISPR-Cas9 based DNA enrichment approach for the detection of recurrent structural aberrations from specified genomic DNA loci. The enrichment of genomic regions of interest using sgRNA libraries led e.g. to a median coverage of 44 reads (range 5-136-fold) of the t(8;21) region-of-interest in primary AML samples, which allow the detection of the exact coordinates of the breakpoints. Summary/Conclusion: Long read based sequencing based copy number alteration and structural variation detection based on combination of different long read sequencing approaches like low-coverage whole genome sequencing, transcriptome sequencing and CRISPR-Cas9 based sequencing of genomic loci of interest represents a highly promising tool for high resolution and high speed cytogenetics that has the potential to overcome many limitations of conventional cytogenetics.

Measuring the process and rate of exogenous DNA degradation during digestion in mice

This study aimed to perform qualitative and quantitative examination of DNA degradation during the digestion process in the mouse gut through PCR, qPCR and short tandem repeat (STR) analysis. Human blood leukocytes were gavaged into the digestive tract in mice. GAPDH, TH01, TPOX and D7S820 genes in the contents of the stomach and small intestine were analyzed with PCR and qPCR at various times pre- and post-gavage. Through STR analysis, 21 human genomic DNA loci were analyzed. The half-life of DNA degradation, and the relationship between the average peak area and digestion time were determined. The PCR results showed bands of amplified genes at pre-gavage (0 min) and post-gavage (40, 80 and 120 min) from the mouse stomach contents, whereas no DNA bands from small intestinal chyme were observed after gavage. The qPCR results revealed a significant decrease in DNA concentrations during 40–120 min in the mouse stomach after gavage. At 120 min, 85.62 ± 8.10% of the DNA was degraded, and the half-life of exogenous DNA degradation in the mouse stomach was 70.50 ± 5.46 min. At various digestion times, almost no target genes were detected in the mouse small intestinal chyme. STR analysis showed a decrease in allele numbers with bowel advancement in the small intestine in mice. The degradation of exogenous DNA was higher in the mouse stomach during the first 2 h, and almost complete degradation was observed within 40 min after entering the small intestine in mice.

Prospects of Non-Coding Elements in Genomic DNA Based Gene Therapy.

Gene therapy has made significant development since the commencement of the first clinical trials a few decades ago and has remained a dynamic area of research regardless of obstacles such as immune response and insertional mutagenesis. Progression in various technologies like next-generation sequencing (NGS) and nanotechnology has established the importance of non-- coding segments of a genome, thereby taking gene therapy to the next level. In this review, we have summarized the importance of non-coding elements, highlighting the advantages of using full- length genomic DNA loci (gDNA) compared to complementary DNA (cDNA) or minigene, currently used in gene therapy. The focus of this review is to provide an overview of the advances and the future of potential use of gDNA loci in gene therapy, expanding the therapeutic repertoire in molecular medicine.

Genome oligopaint via local denaturation fluorescence in situ hybridization

Cas9 in complex with a programmable guide RNA targets specific double-stranded DNA for cleavage. By harnessing Cas9 as a programmable loader of superhelicase to genomic DNA, we report a physiological-temperature DNA fluorescence in situ hybridization (FISH) method termed genome oligopaint via local denaturation (GOLD) FISH. Instead of global denaturation as in conventional DNA FISH, loading a superhelicase at a Cas9-generated nick allows for local DNA denaturation, reducing nonspecific binding of probes and avoiding harsh treatments such as heat denaturation. GOLD FISH relies on Cas9 cleaving target DNA sequences and avoids the high nuclear background associated with other genome labeling methods that rely on Cas9 binding. The excellent signal brightness and specificity enable us to image nonrepetitive genomic DNA loci and analyze the conformational differences between active and inactive X chromosomes. Finally, GOLD FISH could be used for rapid identification of HER2 gene amplification in patient tissue.

Direct and simultaneous observation of transcription and chromosome architecture in single cells with Hi-M

Simultaneous observation of 3D chromatin organization and transcription at the single-cell level and with high spatial resolution may hold the key to unveiling the mechanisms regulating embryonic development, cell differentiation and even disease. We recently developed Hi-M, a technology that enables the sequential labeling, 3D imaging and localization of multiple genomic DNA loci, together with RNA expression, in single cells within whole, intact Drosophila embryos. Importantly, Hi-M enables simultaneous detection of RNA expression and chromosome organization without requiring sample unmounting and primary probe rehybridization. Here, we provide a step-by-step protocol describing the design of probes, the preparation of samples, the stable immobilization of embryos in microfluidic chambers, and the complete procedure for image acquisition. The combined RNA/DNA fluorescence in situ hybridization procedure takes 4-5 d, including embryo collection. In addition, we describe image analysis software to segment nuclei, detect genomic spots, correct for drift and produce Hi-M matrices. A typical Hi-M experiment takes 1-2 d to complete all rounds of labeling and imaging and 4 additional days for image analysis. This technology can be easily expanded to investigate cell differentiation in cultured cells or organization of chromatin within complex tissues.

A heterodimer of evolved designer-recombinases precisely excises a human genomic DNA locus.

Site-specific recombinases (SSRs) such as the Cre/loxP system are useful genome engineering tools that can be repurposed by altering their DNA-binding specificity. However, SSRs that delete a natural sequence from the human genome have not been reported thus far. Here, we describe the generation of an SSR system that precisely excises a 1.4 kb fragment from the human genome. Through a streamlined process of substrate-linked directed evolution we generated two separate recombinases that, when expressed together, act as a heterodimer to delete a human genomic sequence from chromosome 7. Our data indicates that designer-recombinases can be generated in a manageable timeframe for precision genome editing. A large-scale bioinformatics analysis suggests that around 13% of all human protein-coding genes could be targetable by dual designer-recombinase induced genomic deletion (dDRiGD). We propose that heterospecific designer-recombinases, which work independently of the host DNA repair machinery, represent an efficient and safe alternative to nuclease-based genome editing technologies.

A novel CRISPR/Cas9 associated technology for sequence-specific nucleic acid enrichment.

Massively parallel sequencing technologies have made it possible to generate large quantities of sequence data. However, as research-associated information is transferred into clinical practice, cost and throughput constraints generally require sequence-specific targeted analyses. Therefore, sample enrichment methods have been developed to meet the needs of clinical sequencing applications. However, current amplification and hybrid capture enrichment methods are limited in the contiguous length of sequences for which they are able to enrich. PCR based amplification also loses methylation data and other native DNA features. We have developed a novel technology (Negative Enrichment) where we demonstrate targeting long (>10 kb) genomic regions of interest. We use the specificity of CRISPR-Cas9 single guide RNA (Cas9/sgRNA) complexes to define 5′ and 3′ termini of sequence-specific loci in genomic DNA, targeting 10 to 36 kb regions. The complexes were found to provide protection from exonucleases, by protecting the targeted sequences from degradation, resulting in enriched, double-strand, non-amplified target sequences suitable for next-generation sequencing library preparation or other downstream analyses.

BasePhasing: a highly efficient approach for preimplantation genetic haplotyping in clinical application of balanced translocation carriers

BackgroundPreimplantation genetic testing (PGT) has already been applied in chromosomally balanced translocation carriers to improve the clinical outcome of assisted reproduction. However, traditional methods could not further distinguish embryos carrying a translocation from those with a normal karyotype prior to implantation.MethodsTo solve this problem, we developed a method named “Chromosomal Phasing on Base level” (BasePhasing), which based on Infinium Asian Screening Array-24 v1.0 (ASA) and a specially phasing pipeline. Firstly, by comparing the number of single nucleotide polymorphism (SNP) loci in different minor allele frequencies (MAFs) and in 2Mbp continuous windows of ASA chip and karyomap-12 chip, we verified whether ASA could be adopted for genome-wide haplotype linkage analysis. Besides, the whole gene amplification (WGA) of 3–10 cells of GM16457 cell line was used to verify whether ASA chip could be used for testing of WGA products. Finally, two balanced translocation families were utilized to carry out BasePhasing and to validate the feasibility of its clinical application.ResultsThe average number of SNP loci in each window of ASA (473.2) was twice of that of Karyomap-12 (201.2). The coincidence rate of SNP loci in genomic DNA and WGA products was about 97%. The 5.3Mbp deletion was detected positively in cell line GM16457 of both genomic DNA and WGA products, and haplotype linkage analysis was performed in genome wide successfully. In the two balanced translocation families, 18 blastocysts were analyzed, in which 8 were unbalanced and the other 10 were balanced or normal chromosomes. Two embryos were transferred back to the patients successfully, and prenatal cytogenetic analysis of amniotic fluid was performed in the second trimester. The results predicted by BasePhasing and prenatal diagnosis were totally consistent.ConclusionsInfinium ASA bead chip based BasePhasing pipeline shows good performance in balanced translocation carrier testing. With the characteristics of simple operation procedure and accurate results, we demonstrate that BasePhasing is one of the most suitable methods to distinguish between balanced and structurally normal chromosome embryos from translocation carriers in PGT at present.

Redirecting Metabolic Flux via Combinatorial Multiplex CRISPRi-Mediated Repression for Isopentenol Production in Escherichia coli.

CRISPR interference (CRISPRi) via target guide RNA (gRNA) arrays and a deactivated Cas9 (dCas9) protein has been shown to simultaneously repress expression of multiple genomic DNA loci. By knocking down endogenous genes in competing pathways, CRISPRi technology can be utilized to redirect metabolic flux toward target metabolite. In this study, we constructed a CRISPRi-mediated multiplex repression system to silence transcription of several endogenous genes to increase precursor availability in a heterologous isopentenol biosynthesis pathway. To identify genomic knockdown targets in competing pathways, we first designed a single-gRNA library with 15 individual targets, where 3 gRNA cassettes targeting gene asnA, prpE, and gldA increased isopentenol titer by 18-24%. We then combined the 3 single-gRNA cassettes into a two- or three-gRNA array and observed up to 98% enhancement in production by fine-tuning the repression level through titrating dCas9 expression. Our strategy shows that multiplex combinatorial knockdown of competing genes using CRISPRi can increase production of the target metabolite, while the repression level needs to be adjusted to balance the metabolic network and achieve the maximum titer improvement.

Izražanje transferinskih genov pri postrvih (Salmo sp.)

Salmonidae family combines freshwater and anadromous fish species. Duplicates of numerous genomic DNA loci are characteristic for this family, some as a consequence of tetraploidisation, and others as independent doubling of discrete DNA regions. In the genus <em>Salmo</em>, duplication of transferrin gene in Atlantic salmon, brown and marble trout has been demonstrated. The aim of the study was to characterize the promoter region of both genes (TF1 and TF2) in all three species and to determine the ratio of expression of TF1 and TF2 in Atlantic salmon. Applying qPCR we showed that TF2 is expressed in Atlantic salmon six times weaker than TF1. It has been previously shown that the difference in the expression of both genes in brown and marble trout is even higher. The nucleotide sequence was determined for promoter regions of both genes in all species. In promoter region, microsatellite was found, which differs in length as well within species as between TF1 and TF2 locus, and four SNPs that differentiate TF1 and TF2. For Atlantic salmon, longer sequence of promoter region was determined. In TF1 gene, promoter contains a minisatellite, comprised of 37 bp long motif with over 20 replicates, while in TF2 minisatellite is not present. Analyzing potential binding sites in promoter region, functional elements for regulation of transferrin gene expression were found.

The infectious BAC genomic DNA expression library: a high capacity vector system for functional genomics.

Gene dosage plays a critical role in a range of cellular phenotypes, yet most cellular expression systems use heterologous cDNA-based vectors which express proteins well above physiological levels. In contrast, genomic DNA expression vectors generate physiologically-relevant levels of gene expression by carrying the whole genomic DNA locus of a gene including its regulatory elements. Here we describe the first genomic DNA expression library generated using the high-capacity herpes simplex virus-1 amplicon technology to deliver bacterial artificial chromosomes (BACs) into cells by viral transduction. The infectious BAC (iBAC) library contains 184,320 clones with an average insert size of 134.5 kb. We show in a Chinese hamster ovary (CHO) disease model cell line and mouse embryonic stem (ES) cells that this library can be used for genetic rescue studies in a range of contexts including the physiological restoration of Ldlr deficiency, and viral receptor expression. The iBAC library represents an important new genetic analysis tool openly available to the research community.

469. Improved Protocol and Use of Mitochondrial DNA as Reference for qPCR Quantification of Integrase-Defective Lentiviral Vectors (IDLVs)

Integrase defective lentiviral vectors (IDLVs) are attractive tools for genetic manipulation and are increasingly being tested as recombinant viral vaccines against infectious pathogens and cancer. IDLVs remain mostly as extrachromosomal/episomal DNA circles in the infected cells, hence with reduced risk of genotoxicity mediated by insertional mutagenesis. We have demonstrated in our previous work the production and characterization of a tricistronic IDLV (packaged with the D64V mutation in the integrase and co-expressing GM-CSF, IFN-alpha and the CMV pp65 antigen) and IDLV-mediated monocyte transduction achieved under Good Manufacturing Process (GMP) compliant conditions (Sundarasetty et al., JTM 2015). One of the main criteria for batch release of the cell vaccine is to confirm and quantify IDLV copies in the thawed cell product. Currently used DNA extraction methods are not efficient in isolating small molecular weight episomal DNA from cells. In addition, genomic DNA loci used as reference controls are not informative regarding quantification of episomal DNAs. Mitochondrial DNA (mtDNA) is an episomal small molecular weight circular DNA (16.5 kb) that can serve as a reference for IDLV quantification. In order to maximize recovery of episomal DNAs, we explored the total DNA (tDNA) extraction described for mtDNA isolation (Badralmaa et al., J Vir. Meth. 2013), based on dehydration and precipitation of proteins and subsequent tDNA precipitation from the supernatants by isopropanol. As a reference for the qPCR quantification, we constructed and validated a plasmid containing a sequence homologous to a regulatory region of transfer vector (wPRE), a sequence for a genomic house-keeping gene (PTBP2) and a sequence for a mitochondrial house-keeping gene (Cytochrome B). The amplification of three target regions was validated by generating a standard curve with the reference plasmid ranging from 5 x10 to 5×105 copies (n=3). As a reference, we used an in-house generated 293T cell line (B5) containing three LV genomic copies. Total DNA extracted form B5 was serially diluted in non-transduced 293T DNA in order to result into 0.25, 0.5, 1, 2, 3 LV copies and the assay linearity was assessed in three independent runs. The reliable detection limit of the qPCR assay was 0.5 LV copies/cell and 0.9 copies/ng of genomic DNA. Having assessed the linearity, we assessed if this method could be used to quantify IDLV in transduced monocytes. The tricistronic IDLV was used to transduce monocytes of different donors in triplicates at increasing multiplicities of infection (MOI: 1, 2.5, 5 and 10). After thawing each cryopreserved batch, tDNA was extracted and analyzed. Our results showed a direct correlation between the IDLV copies per cell and ng of DNA used for the assay and MOI, whereas detection of the genomic and mtDNA references remained constant. Thus, this simple methodological adaptation provided an internal mtDNA control to better quantify episomal vector copies, which can be also used for qPCR quantification of other types of non-integrating vectors.

Gene expression and molecular evolution of sxtA4 in a saxitoxin producing dinoflagellate Alexandrium catenella

Dinoflagellates of the genus Alexandrium produce the neurotoxin saxitoxin (STX), responsible for paralytic shellfish poisoning (PSP) and accumulates in marine invertebrates. The recent identification of STX biosynthesis genes allowed us to investigate the expression of sxtA4 at different growth stages in Alexandrium catenella Group IV. We found no significant differences in expression of sxtA4, despite significant differences in STX levels at different growth stages (P < 0.023). Three reference genes were tested for normalisation: actin, cytochrome b (cob), and the large subunit ribosomal RNA (LSU rDNA). cob was most stably expressed but the combination of two reference genes, actin and cob, resulted in the best stability factor. Most genomic sequences of sxtA4 from A. catenella were in a clade that included sequences from Alexandrium fundyense Group I, however, one paralogue was not related to the others, suggesting recombination or lateral transfer. A comparison of the sxtA4 cDNA sequences with genomic DNA sequences indicated the possibility of transcript editing and the preferential transcription of certain genomic DNA loci. The results show that, in dinoflagellates, post-transcriptional mechanisms play a major role in the regulation of saxitoxin biosynthesis.