Cloning of Insertion Site Flanking Sequence and Construction of Transfer DNA Insert Mutant Library in Stylosanthes Colletotrichum

Abstract Genetics studies of natural variants of the androgen response of mouse β-glucuronidase (GUS) reveal a cis-active element closely linked to the GUS structural gene (Gus-s) that is necessary for this kidney-specific response. Results of our previous studies suggested sequences within or near an androgen-inducible deoxyribonuclease I-hypersensitive site (DH site) located in the ninth intron of Gus-s are associated with the androgen response of GUS. Using transgenic mice, we now demonstrate that at least two regions of sequence within Gus-s are involved in regulating the androgen response of GUS. The first, located within 3.8 kb of Gus-s 5′-flanking sequence, directs the response and its tissue specificity, while the second, located within a 6.4-kb fragment of Gus-s extending from the third through the ninth intron of Gus-s, protects the androgen responsiveness of the transgene from repressive influences of the insertion site.

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A Simplified and Efficient Method for Himar-1 Transposon Sequencing in Bacteria, Demonstrated by Creation and Analysis of a Saturated Transposon-Mutant Library in Mycobacterium abscessus

mSystems ◽

10.1128/msystems.00976-20 ◽

2020 ◽

Vol 5 (5) ◽

Author(s):

Mark Foreman ◽

Moran Gershoni ◽

Daniel Barkan

Keyword(s):

Deep Sequencing ◽

Genomic Library ◽

Insertion Site ◽

Technical Aspect ◽

Mycobacterium Abscessus ◽

Mutant Library ◽

Content Type ◽

Genomic Libraries ◽

Transposon Insertion ◽

Site Identification

ABSTRACT We present a technically simple, easy-to-perform method for generating the genomic libraries for Himar-1 transposon site sequencing (Tn-seq). In addition to being simpler than present methods in the technical aspect, it also allows more robust and straightforward identification of the insertion site, by generating a longer sequence surrounding the insertion TA in the genome. The method makes Tn-seq more user-friendly and accessible to laboratories with more-limited bioinformatic resources. Finally, we created a saturated transposon-mutant library in Mycobacterium abscessus and demonstrated the usefulness of the method in analysis of genes involved in colony morphology, as well as in analysis of the whole Tn-mutant library, with identification of over 8,000 unique mutants. IMPORTANCE Transposon insertion sequencing is a powerful tool, but many researchers are discouraged by the apparent technical complexity of preparing the genomic library for deep sequencing and by the complicated computational analysis needed for insertion site identification. Our proposed method makes the preparation of the library easy and straightforward, relying on well-known molecular biology techniques. In addition, the results obtained from the deep sequencing are easily analyzed in terms of transposon insertion site identification, placing library preparation and analysis within the reach of more researchers in the microbiology community, including those with less computational and bioinformatic resources and experience. This is demonstrated by analysis of the most saturated Tn-mutant library created to date in the emerging pathogen Mycobacterium abscessus.

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Determination of Graft Forces for Cranial Cruciate Ligament Reconstruction in the Dog

Veterinary and Comparative Orthopaedics and Traumatology ◽

10.1055/s-0038-1632524 ◽

1996 ◽

Vol 09 (04) ◽

pp. 165-171 ◽

Cited By ~ 1

Author(s):

D. A. Hulse ◽

M. R. Slater ◽

J. F. Hunter ◽

W. A. Hyman ◽

B. A. Shelley

Keyword(s):

Degrees Of Freedom ◽

Cruciate Ligament ◽

Insertion Site ◽

Graft Fixation ◽

Flexion Angle ◽

Patellar Ligament ◽

Graft Material ◽

Test Apparatus ◽

Cranial Cruciate Ligament ◽

Tibial Insertion

SummaryA test apparatus that allowed the stifle to move in five degrees of freedom was used to determine the effect of graft location, graft preload, and flexion angle at the time of graft fixation on the tensile graft forces experienced by a replacement graft material used to simulate reconstruction of the cranial cruciate ligament deficient stifle. Two graft locations (tibial insertion site of the patellar ligament and tibial insertion site of the cranial cruciate ligament), two graft preloads (5 N and 20 N), and three flexion angles at the time of graft fixation (15°, 30° and 90°) were examined. The tibial insertion site and preload did not have as great an effect on graft force as did the flexion angle of the limb at time of graft fixation. Graft forces were highest when reconstructions were performed with the limb in 90° of flexion (ρ <0.0001). This study supports the notion that intracapsular grafts should be fixed with the limb in a normal standing angle.A five degree of freedom test apparatus was used to evaluate the effect of graft location, graft preload, and limb flexion angle at time of graft fixation on reconstructions of the cranial cruciate ligament deficient stifle. Our results suggest that intracapsular grafts should not be fixed with the limb in 90° of flexion, but in a normal standing angle.

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