Stress resistance is one of the hallmarks for longevity and is known to be genetically governed. Here, we developed an unbiased high-throughput method to screen for mutations that confer stress resistance in ES cells with which to develop mouse models for longevity studies.
Phenotype-driven genetic screens in mice is a powerful technique to uncover gene functions, but are often hampered by extremely high costs, which severely limits its potential. We describe here the use of mouse embryonic stem (ES) cells as surrogate cells to screen for a phenotype of interest and subsequently introduce these cells into a host embryo to develop into a living mouse carrying the phenotype. This method provides (1) a cost effective, high-throughput platform for genetic screen in mammalian cells; (2) a rapid way to identify the mutated genes and verify causality; and (3) a short-cut to develop mouse mutants directly from these selected ES cells for whole animal studies. We demonstrated the use of paraquat (PQ) to select resistant mutants and identify mutations that confer oxidative stress resistance. Other stressors or cytotoxic compounds may also be used to screen for resistant mutants to uncover novel genetic determinants of a variety of cellular stress resistance.
Longevity has an intimate relationship with stress resistance. In general, long-lived species often demonstrate increased resistance toward multiple stressors, such as hydrogen peroxide, paraquat (PQ), UV, heat, and heavy metals 1,2. In contrast, increased sensitivity to stress tends to predict shortened life span and/or a more disease-prone phenotype. The anti-oxidant scavenging pathway has long been speculated to play a major role in conferring stress resistance to the animal. However, with few exceptions, studies from a variety of transgenic animals with manipulations in various anti-oxidant enzymes (e.g., SOD) indicate that increasing the level of oxidant scavenging enzymes does not increase life span or health span 3. These data suggest that the stress resistance trait consistently observed in long-lived animals is mediated by other cellular pathways yet to be uncovered.
We took an unbiased forward genetic approach to identify genes, which upon mutated, could confer a stress resistance phenotype in cultured embryonic stem (ES) cells. ES cells offer two major advantages in this study: (1) sophisticated genetic manipulations are available to modify the genome of ES cells; and (2) any stress resistant ES cells recovered from the screen can be directly used for mouse production, allowing rapid translation into whole animal studies to measure life span and health span.
In this report, we described the use of C9 ES cell line, in which the Blm alleles were under control by a tetracycline responsive element. Treatment of doxycycline (dox) transiently turned off the expression of Blm leading to increased incident of sister chromatid exchange. This short-term Blm knock-out allowed for the generation of homozygous mutations within the heterozygote population so that recessive mutations for stress resistance could be captured in the screening process. We also described the use of piggyBac (PB) transposon as the mutagen to randomly insert a poly-A trap cassette (PB-UPA) to mutate genes in the genome. Cells with disruption of a gene by the poly-A trap became G418 resistant and could be recovered so that a collection of gene-trap mutants (gene-trap library) could be made, and subsequently screened for mutant clones that were stress resistant.
Stress resistant clones recovered from the selection could be characterized rather rapidly by molecular techniques in regard of the number of insertions (qPCR), the site of insertion (splinkerette PCR), the identity of the disrupted gene (BLAST), and its expression level (RT-qPCR). The PB insertion could be remobilized by transient expression of mPB transposase in the clone to restore the wild-type DNA sequence and thus test for the loss of stress resistance. These are powerful ways to confirm causality of the mutation, which should be done prior to expensive mouse production. Previous studies showed that cells exposed to stressors lost their pluripotency 4,5. Thus, in this protocol, the preservation of a replica set of mutant cells, which would not be treated with stressors is critical for successful mouse production.
Our lab has engineered the C9 ES cell line and the PB-UPA vector, both are available to other investigators upon request. The protocol reported here will start by the generation of de novo library of gene-trapped ES cells with PB-UPA (Figure 1A), followed by replica plating and stress selection to isolate stress resistant clones (Figure 1B). We demonstrated the selection with paraquat, a potent free radical generator inside cells. Virtually, any cytotoxic compound or toxin, for instance, ER stressors (e.g., thapsigargin and tunicamycin), neuronal oxidant (e.g., MPP+, 6-hydroxy dopamine, and rotenone), heat, and heavy metals (e.g., Cd, Se), could be adapted to the method to select for respective resistant mutants.
1. Gene-trapped ES Cell Library Construction Using piggyBac Transposon
2. Library Replication
3. Doxycycline-induced Homozygous Mutants
4. Stress Selection and Isolation of Resistant Clones
5. Identification of the PB Insertion Sites and Trapped Genes
6. Genetic Analysis of the Mutant Clones
7. Generation of Mouse Mutants
In a typical mutagenesis experiment, the transfection consists of a total of 3 x 107 ES cells with PB-UPA and mPB transposase. The numbers of gene-trapped ES cells generated in two independent experiments are summarized in Table 1. The efficiency of gene-entrapment is about 0.04%. The combined gene-trap libraries contain 22,400 independent mutants, about a full coverage of the mouse genome (23,000 coding genes). Excessive coverage could be achieved by generating more mutants through repeated mutagenesis and/or scaling up the process.
Because the gene-trap libraries contain random mutations, it is not possible to predict the number of mutants possessing a stress resistance phenotype. Two independent selections for PQ resistance were performed; the combined screening of 22,440 independent gene-trap mutations uncovered 17 mutations that confer cellular resistance to PQ (0.08%) (Table 1).
We have purified 3 mutant clones, the Pigl, Tiam1, and Rffl, from the master plates for further analysis and mouse production. Cells with heterozygous Rffl mutation were successfully induced to produce homozygous progeny by knocking out Blm. However, we failed to produce any homozygous mutants from the Pigl and Tiam1 mutants, presumably due to a homozygosity-linked cell lethality. The stress resistance of these purified clones was confirmed by using 2 different types of stressors: omission of 2-mercaptoethanol (2-ME) and PQ (Figure 2). Upon removing the PB from these clones, the associated stress resistance phenotype was also lost (Figure 2), confirming that the gene-trap mutations are the causal factor. Characterization of clones recovered from the master plates is crucial as it would rule out stochastic lesion during stress selection as the cause of the observed phenotype.
Out of 3 mutant ES cells being introduced into blastocysts for mouse production (Table 2), 2 lines (Pigl and Tiam1) show germline transmission. The Rffl injection produced only one female chimera which was not an optimal number of chimera to begin with. Thus, the failure of germline transmission of Rffl is likely due to one incompetent chimera. We tested the cellular phenotype of skin fibroblasts isolated from the Pigl mutant mice and showed that they maintained the reduced level of endogenous reactive oxygen species (ROS) as well as stress resistance to PQ (Figure 3).
Figure 1. ES cell mutagenesis and stress selection. (A) PB-UPA vector. An unbiased polyA (UPA) trap vector comprising of a splice acceptor (SA), bovine growth hormone poly-adenylate signal (pA), phosphoglycerate kinase (PGK) promoter, neomycin phosphotransferase (neo), internal ribosomal entry site (IRES), and a splice donor (SD) with artificial ATG (in 3 different reading frames) was cloned into the piggyBac transposon, flanked by the 3’ and 5’ long terminal repeat (LTR). (B) Random mutagenesis of ES cells and selection for stress resistant clones. ES cells were co-transfected by electroporation with PB-UPA and mPBase followed by plating onto 96-well plates. Gene trapped clones were selected by G418 resistance; once confluent, they were divided into 2 replica sets. One replica set was further divided into two half for DNA isolation and stress selection by paraquat (PQ); the other replica set (master) was frozen down. The surviving ES cell colonies recovered from the stress treatment were analyzed molecularly for the PB insertion by Sp-PCR. Primers were then designed to screen the replica DNA plate from which the well containing the sibling PQR clone could be located on the master plate. These cells are for stress resistance assay on different stressors and for mouse production. Modified from Chick et al. 7. Please click here to view a larger version of this figure.
Figure 2. Stress resistance in mutant ES cells. (A) Resistance to 2-mercaptoethanol (2-ME) withdrawal. (B) Resistance to paraquat (PQ). Shown are the parental wild-type ES cells (C9: yellow), a stress-resistant control ES cell clone, (4C11: red), recovered from a previous study 5, and three gene-trap clones (grey). Cells were subjected to stress treatment for two days, after which the number of viable cells was counted. Pigl, Tiam1, and Rffl heterozygotes (PB/+: dark grey) exhibit resistance to both of these stressors. Rffl homozygotes (PB/PB: black) exhibit stronger stress resistance compared to the heterozygotes. Resistance to both stressors was lost when the PB insertions were removed (+/+: light grey). Error bars represent SD of mean (n=4). * P < 0.001, # P = 0.01 between the gene-trap clones and the wild-type parental C9, evaluated by Student’s t-test. (C) ES cell colony formation under PQ (10 µM) treatment. Stress-resistant ES clones were able to form colonies in culture under PQ treatment while the number and size of colonies from the wild-type clone were significantly reduced. Modified from Chick et al. 7. Please click here to view a larger version of this figure.
Figure 3. Characterization of Pigl PB/+ fibroblasts. (A) Reactive oxygen species (ROS) level. Tail skin fibroblasts isolated from wild-type (WT) and Pigl PB/+ mice were stained with CM-DCFCA and the fluorescence was normalized against Hoechst. The ROS content was expressed as relative fluorescence unit (RFU). The P value was evaluated by two tailed Student’s t-test (n=8). (B) PQ resistance. Tail skin fibroblasts from wild-type (WT) and PiglPB/+ mice were exposed to 4 mM PQ for 6 hr, after which the viability of the cells were measured by MTT assays. The percentage of live cells after PQ treatment was calculated by the ratio of the absorbance obtained from the PQ-treated cells and that from the un-treated cells. The P value was evaluated by one tailed Student’s t-test (n=8). Modified from Chick et al. 7. Please click here to view a larger version of this figure.
Library | Sub-libraries | ES cell strain | No. of gene trapped clone | No. of PQR clones |
1 | C9PA01 – C9PA10 | C9 (Blm tet/tet) | 9,000 | 7 |
2 | C9PA11 – C9PA20 | C9 (Blm tet/tet) | 13,440 | 10 |
Total | 22,440 | 17 |
Table 1. PiggyBac gene-trap library construction and the recovery of PQ resistant clones. Modified from Chick et al. 7.
ES cell clone injected | No. of chimera recovered | Germline transmission * |
Pigl PB/ Pigl + | 4 | Yes |
Tiam1 PB / Tiam1 + | 2 | Yes |
Rffl PB / Rffl + | 1 | No |
Table 2. Generation of mice. Modified from Chick et al. 7.
* Germline transmission was confirmed by inheritance of the gene-trap allele detected by PCR genotyping.
Forward genetic analysis allows for an unbiased interrogation of the genome for genes responsible for a specific phenotype. This method is very powerful to uncover novel gene functions. It has been widely used in lower organisms but not in mammal, such as the mouse, mainly due to the extremely high cost associated with the infrastructure and logistics that would entail. Here, we moved the genetic screening process to the ES cell culture platform, greatly increasing the efficiency and throughput in generating mutants and identifying mutations.
To effectively select for resistant mutants, a lethal dose of stressor and period of treatment needs to be established such that all of the wild-type cells would be killed. The higher the stringency of the selection, the fewer occurrence of false positive will result. Fibroblast feeders have a higher tolerance to oxidative stress than ES cells; the presence of feeders would rescue the nearby ES cells which would otherwise be killed by the stressor. Thus, omission of feeders during stress selection was very critical for an effective killing. In skin fibroblasts, serum deprivation was necessary to reveal the stress resistance phenotype in long lived mice 10. However, this application was not feasible in ES cells because they cannot survive without serum. As an alternative, we discovered that the use of heat inactivated serum at reduced level (7.5%) achieved a similar result.
In this report, we employed poly-A trap rather than a promoter trap because promoter trap will only trap actively transcribed genes, which is estimated to be 60% of the genome in ES cells, under normal conditions 11. In contrast, a poly-A trap would trap genes regardless of their transcriptional activities, in theory giving us the potential to screen for mutations in all genes in the genome. A major drawback of the conventional poly-A trap is the strong bias towards trapping the last exon, appeared to be mediated by an endogenous nonsense-mediated decay (NMD) mechanism 12. By incorporating the unbiased poly-A trap (UPA) strategy in the PB-UPA transposon to suppresses NMD 13, we were able to eliminate biased trapping.
One distinguishing advantage of using ES cells is that these pluripotent cells make direct derivation of mice possible, speeding up the transition to in vivo studies. For this to happen, the replica plating strategy is critical, preserving a subset of clones sheltered from manipulations that can diminish pluripotency, such as knocking out of Blm and exposure to stressors. We have shown that mutant ES cells recovered from these screens were capable of participating in forming the entire mouse and transmitting the mutations to the germline. Most importantly, consistent with previous studies, the stress resistance phenotype was also transmitted and maintained in the adult mouse.
We and others showed that a variant phenotype observed in ES cells resulting from environmental induced lesion or deliberated engineered mutations was able to transmit to the differentiated progeny cells 4,5,9,14, and probably the whole mouse. This protocol describes the utilization of ES cells as surrogate cells to screen for stress resistance mutations in the mouse. In addition to screening for stress resistance genes, this method may have a broader implication to screen ES cells, identify targets, and to develop a variety of mouse models with a phenotype of interest.
The authors have nothing to disclose.
We would like to thank the Wellcome Trust Sanger Institute for the gifts of piggyBac transposon and piggyBac transposase. This work was supported by the Butcher grant of Colorado and the NIH R01 AG041801 (W.S.C).
Vector | ||
PB-UPA | ||
mPBase | ||
mPBasePuro | ||
Tissue Culture | ||
500-ml Stericup filters | EMD Millipore | SCGPU05RE |
250-ml Stericup filters | EMD Millipore | SCGPU02RE |
50-ml Steriflip-GV filters | EMD Millipore | SE1M179M6 |
KO DMEM | Life Technologies | 10829-018 |
DMEM | Sigma-Aldrich | D6429 |
FBS | Tissue Culture Biologicals | 104 |
Heat Inactivated FBS | Sigma-Aldrich | F4135-500 |
LIF | EMD Millipore | ESG1107 |
Non-essential Amino Acids | Life Technologies | 11140-050 |
GlutaMAX | Life Technologies | 35050-061 |
Pen/Strep | Life Technologies | 15140148 |
β-Mercaptoethanol | Life Technologies | 21985-023 |
Methyl Viologen dichloride (Paraquat) | Sigma-Aldrich | 856177 |
Dimethyl Sulphoxide Hybri-MAX | Sigma-Aldrich | D2650 |
EmbryoMAX 0.1% gelatin | EMD Millipore | ES006B |
DPBS/Modified | HyClone | SH30028.02 |
0.25% Trypsin-EDTA | Life Technologies | 25200-056 |
T25 Flask | Corning | 353108 |
T75 flask | Corning | 353135 |
100-mm plate | Corning | 353003 |
150-mm plate | Corning | 430599 |
96-well plate | Corning | 3585 |
96-well U-bottom plate | Corning | 3799 |
24-well plate | Corning | 3526 |
50-ml reservoir | Corning | 4870 |
15-ml tubes | VWR International, LLC | 82050-276 |
Primary Mouse Embryonic Fibroblasts | EMD Millipore | PMEF-NL |
DR4 Mouse Embryonic Fibroblasts | Applied StemCell | ASF-1001 |
Mitomycin C | Fisher BioReagents | BP25312 |
Geneticin (G418) | Life Technologies | 11811-023 |
Doxycycline | Fisher BioReagents | BP26531 |
Cryotubes | Thermo Scientific | 377267 |
Centrifuge | Eppendorf | Centrifuge 5702 |
TC10 cell counter | Bio-Rad | |
Counting Slides (for TC10) | Bio-Rad | 1450011 |
Electroporation | ||
Gene Pulser Xcell | Bio-Rad | 1652611 |
Gene Pulser Cuvettes (4 mm gap) | Bio-Rad | 1652088 |
分子生物学 | ||
Thermal Cycler | Eppendorf | Mastercylcer ep Gradient S |
Puregene Core kit B | Qiagen | 158745 |
Topo-TA Cloning kit | Life Technologies | 450030 |
High Capacity cDNA synthesis kit | Applied Biosystems | 4368814 |
NaCl | Fisher BioReagents | BP358-212 |
100% ethanol | Decon Laboratories, Inc. | 2716 |
Double Processed Tissue Culture Water | Sigma-Aldrich | W3500 |
Sau3A1 | New England BioLabs | R0169L |
T4 DNA Ligase | New England BioLabs | M0202T |
EcoRV | New England BioLabs | R3195S |
96-well Lysis Buffer (Ramires-Solis et al. 1992) | ||
Trizma Base | Sigma-Aldrich | T1503 |
Hydrochloric Acid | Fisher BioReagents | A144-212 |
EDTA | Sigma-Aldrich | E5134 |
N-Lauroylsarcosine sodium salt | Sigma-Aldrich | L5777 |
Proteinase-K | Fisher BioReagents | BP1700 |
Electrophoresis | ||
Mini-Sub Cell GT | Bio-Rad | 170-4469EDU |
LE Agarose | GeneMate | E3120500 |
Ethidium Bromide | Fisher BioReagents | BP1302 |
100 BP DNA Ladder | New England BioLabs | N3231S |
1Kb DNA Ladder | New England BioLabs | N3232S |
2-log DNA Ladder | New England BioLabs | N3200L |