Generation of Mouse Model (KI and CKO) via Easi-CRISPR.

Recent development of Easi-CRISPR (Efficient additions with ssDNA inserts-CRISPR) that utilizes long single-stranded DNA (lssDNA) of 0.2-2 kbases in length as donor templates to insert large segments of novel DNA sequences or to replace endogenous genes at precise locations in the genome has enabled CRISPR-assisted genome editing to make strides toward a more simple and rapid workflow. By leveraging the notion that short single-stranded DNA oligo (<200 bases) serves as efficient donor in mouse zygotes for facilitating HDR-mediated genome editing, Easi-CRISPR expands to use lssDNA as the donor which accelerates the timeline to as little as 2 months for creating most types of genetically engineered mouse models (F0). Our lab (CGERC) has adopted Easi-CRISPR for multiple loci to generate mouse models over the past three plus years since its introduction. Here, we use two genes as examples to illustrate a step-by-step protocol for generating two commonly used models, including a knock-in (insertion of a reporter gene plus GOI) as well as a conditional knock-out model (via exon floxing). This protocol will focus more on molecular biology aspect, particularly we demonstrate two recently developed methods for lssDNA procuration: (1) PCR-based Takara Bio kit with modifications; (2) plasmid-retrieval-based CRISPR-CLIP (CRISPR-Clipped LssDNA via Incising Plasmid). Both methods are devised to retain sequence fidelity in lssDNA generated. In addition, CRISPR-CLIP directly retrieves lssDNA from DNA plasmid without using restriction enzymes through a PCR-free system hence carries virtually no restriction on sequence complexity, further mitigating limitations discussed in the original Easi-CRISPR protocol. We have alternated the use between both methods when suitable and successfully generated lssDNA templates via CRISPR-CLIP up to 3.5 kbases patched with multiple highly repetitive sequences, which is otherwise challenging to maneuver. Along with certain other modified workflow presented herein, Easi-CRISPR can be adapted to be more straightforward while applicable to generate mouse models in broader scope. (Certain figures and text passages presented in this chapter are reproduced from Shola et al. (The CRISPR J 3(2):109-122, 2020), published by Mary Ann Libert, Inc).

Using a Time-Driven Activity-Based Costing Model To Determine the Actual Cost of Services Provided by a Transgenic Core.

Laboratory animal programs and core laboratories often set service rates based on cost estimates. However, actual costs may be unknown, and service rates may not reflect the actual cost of services. Accurately evaluating the actual costs of services can be challenging and time-consuming. We used a time-driven activity-based costing (ABC) model to determine the cost of services provided by a resource laboratory at our institution. The time-driven approach is a more efficient approach to calculating costs than using a traditional ABC model. We calculated only 2 parameters: the time required to perform an activity and the unit cost of the activity based on employee cost. This method allowed us to rapidly and accurately calculate the actual cost of services provided, including microinjection of a DNA construct, microinjection of embryonic stem cells, embryo transfer, and in vitro fertilization. We successfully implemented a time-driven ABC model to evaluate the cost of these services and the capacity of labor used to deliver them. We determined how actual costs compared with current service rates. In addition, we determined that the labor supplied to conduct all services (10,645 min/wk) exceeded the practical labor capacity (8400 min/wk), indicating that the laboratory team was highly efficient and that additional labor capacity was needed to prevent overloading of the current team. Importantly, this time-driven ABC approach allowed us to establish a baseline model that can easily be updated to reflect operational changes or changes in labor costs. We demonstrated that a time-driven ABC model is a powerful management tool that can be applied to other core facilities as well as to entire animal programs, providing valuable information that can be used to set rates based on the actual cost of services and to improve operating efficiency.

Dissection and function of autoimmunity-associated TNFAIP3 (A20) gene enhancers in humanized mouse models.

Enhancers regulate gene expression and have been linked with disease pathogenesis. Little is known about enhancers that regulate human disease-associated genes in primary cells relevant for pathogenesis. Here we use BAC transgenics and genome editing to dissect, in vivo and in primary immune cells, enhancers that regulate human TNFAIP3, which encodes A20 and is linked with autoimmune diseases. A20 expression is dependent on a topologically associating subdomain (sub-TAD) that harbors four enhancers, while another >20 enhancers in the A20 locus are redundant. This sub-TAD contains cell- and activation-specific enhancers, including an enhancer (termed TT>A) harboring a proposed causal SLE-associated SNV. Deletion of the sub-TAD or the TT>A enhancer results in enhanced inflammatory responses, autoantibody production, and inflammatory arthritis, thus establishing functional importance in vivo and linking enhancers with a specific disease phenotype. These findings provide insights into enhancers that regulate human A20 expression to prevent inflammatory pathology and autoimmunity.

Construction noise decreases reproductive efficiency in mice.

Excessive noise is well known to impair rodent health. To better understand the effect of construction noise and to establish effective noise limits during a planned expansion of our vivarium, we analyzed the effects of construction noise on mouse gestation and neonatal growth. Our hypothesis was that high levels of construction noise would reduce the number of live births and retard neonatal growth. Female Swiss Webster mice were individually implanted with 15 B6CBAF1/J embryos and then exposed to 70- and 90-dBA concrete saw cutting noise samples at defined time points during gestation. In addition, groups of mice with litters were exposed to noise at 70, 80, or 90 dBA for 1 h daily during the first week after parturition. Litter size, birth weight, incidence of stillborn pups, and rate of neonatal weight gain were analyzed. Noise decreased reproductive efficiency by decreasing live birth rates and increasing the number of stillborn pups.

Strain-dependent differences in the efficiency of transgenic mouse production.

Transgenic mouse production via pronuclear microinjection is a complex process consisting of a number of sequential steps. Many different factors contribute to the effectiveness of each step and thus influence the overall efficiency of transgenic mouse production. The response of egg donor females to superovulation, the fertilization rate, egg survival after injection, ability of manipulated embryos to implant and develop to term, and concentration and purity of the injected DNA all contribute to transgenic production efficiency. We evaluated and compared the efficiency of transgenic mouse production using four different egg donor mouse strains: B6D2/F1 hybrids, Swiss Webster (SW) outbred, and inbred FVB/N and C57BL/6. The data included experiments involving approximately 350 DNA transgene constructs performed by a high capacity core transgenic mouse facility. Significant influences of particular genetic backgrounds on the efficiency of different steps of the production process were found. Except for egg production, FVB/N mice consistently produced the highest efficiency of transgenic mouse production at each step of the process. B6D2/F2 hybrid eggs are also quite efficient, but lyze more frequently than FVB/N eggs after DNA microinjection. SW eggs on the other hand block at the 1-cell stage more often than eggs from the other strains. Finally, using C57BL/6 eggs the main limiting factor is that the fetuses derived from injected eggs do not develop to term as often as the other strains. Based on our studies, the procedure for transgenic mouse production can be modified for each egg donor strain in order to overcome any deficiencies, and thus to increase the overall efficiency of transgenic mouse production.