The murine hepatic sequelae of long-term ethanol consumption are sex-specific and exacerbated by Aldh1b1 loss.

Disease progression in alcoholic and non-alcoholic fatty liver disease shows sex-specific differences and is influenced by mechanisms linked to oxidative stress. Acetaldehyde plays a critical pathogenic role but its effects are mitigated by the activity of aldehyde dehydrogenases. Aldehyde dehydrogenase 1b1 (Aldh1b1) is the aldehyde dehydrogenase isoform with the second highest affinity for acetaldehyde after Aldh2, and is highly expressed in the intestine and liver. We examined sex differences and the effect of Aldh1b1 depletion in a murine model of chronic alcohol-induced liver disease. Male and female wild-type and Aldh1b1-depleted mice received either ethanol (10-20% v/v) in drinking water or water alone for one year, and livers were examined histopathologically, histochemically and by immunohistochemistry. A significant increase in hepatic steatosis was observed in female mice after one year of ethanol consumption, and expression of ethanol-metabolising enzymes and up-regulation by ethanol was also sex-dependent. Ethanol-induced hyperproliferation of hepatocytes was observed in female and male wild-type mice, and Aldh1b1 depletion enhanced this effect in males. Further, one ethanol-treated, Aldh1b1-depleted male developed a steatohepatitic hepatocellular carcinoma. These sex-specific differences in susceptibility to hepatic steatosis and disease progression may be related to differences in expression of ethanol-metabolising enzymes, informing the clinically significant differences. Aldh1b1 plays a role in protection from ethanol-induced hepatocellular hyperproliferation and may protect from tumour development.

Effects of long-term ethanol consumption and Aldh1b1 depletion on intestinal tumourigenesis in mice.

Ethanol and its metabolite acetaldehyde have been classified as carcinogens for the upper aerodigestive tract, liver, breast, and colorectum. Whereas mechanisms related to oxidative stress and Cyp2e1 induction seem to prevail in the liver, and acetaldehyde has been proposed to play a crucial role in the upper aerodigestive tract, pathological mechanisms in the colorectum have not yet been clarified. Moreover, all evidence for a pro-carcinogenic role of ethanol in colorectal cancer is derived from correlations observed in epidemiological studies or from rodent studies with additional carcinogen application or tumour suppressor gene inactivation. In the current study, wild-type mice and mice with depletion of aldehyde dehydrogenase 1b1 (Aldh1b1), an enzyme which has been proposed to play an important role in acetaldehyde detoxification in the intestines, received ethanol in drinking water for 1 year. Long-term ethanol consumption led to intestinal tumour development in wild-type and Aldh1b1-depleted mice, but no intestinal tumours were observed in water-treated controls. Moreover, a significant increase in DNA damage was detected in the large intestinal epithelium of ethanol-treated mice of both genotypes compared with the respective water-treated groups, along with increased proliferation of the small and large intestinal epithelium. Aldh1b1 depletion led to increased plasma acetaldehyde levels in ethanol-treated mice, to a significant aggravation of ethanol-induced intestinal hyperproliferation, and to more advanced features of intestinal tumours, but it did not affect intestinal tumour incidence. These data indicate that ethanol consumption can initiate intestinal tumourigenesis without any additional carcinogen treatment or tumour suppressor gene inactivation, and we provide evidence for a role of Aldh1b1 in protection of the intestines from ethanol-induced damage, as well as for both carcinogenic and tumour-promoting functions of acetaldehyde, including increased progression of ethanol-induced tumours. Copyright © 2016 Pathological Society of Great Britain and Ireland. Published by John Wiley & Sons, Ltd.

Feasibility for a large scale mouse mutagenesis by injecting CRISPR/Cas plasmid into zygotes.

The recombinant clustered regulatory interspaced short palindromic repeats (CRISPR)/Cas system has opened a new era for mammalian genome editing. Here, we constructed pX330 plasmids expressing humanized Cas9 (hCas9) and single guide RNAs (sgRNAs) against mouse genes and validated them both in vitro and in vivo. When we randomly chose 291 target sequences within protein coding regions of 73 genes, an average number of off-target candidates (exact match 13 nucleotides from 3' target and NGG) found by Bowtie software was 9.2 ± 21.0 (~1.8 times more than the estimated value, 5.2). We next validated their activity by observing green fluorescence reconstituted by homology dependent repair (HDR) of an EGFP expression cassette in HEK293T cells. Of the pX330 plasmids tested, 81.8% (238/291) were found to be functional in vitro. We finally injected the validated pX330 plasmids into mouse zygotes in its circular form against 32 genes (including two genes previously tested) and obtained mutant mice at a 52.9 ± 22.3% (100/196) mutation frequency. Among the pups carrying mutations on the autosomes, 43.6% (47/96) carried the mutations in both alleles. When off-target candidate sites were examined in 63 mutant mice, 0.8% (3/382) were mutated. We conclude that our method provides a simple, efficient, and cost-effective way for mammalian gene editing that is applicable for large scale mutagenesis in mammals.

Rapid Knockout and Reporter Mouse Line Generation and Breeding Colony Establishment Using EUCOMM Conditional-Ready Embryonic Stem Cells: A Case Study.

As little as a decade ago, generation of a single knockout mouse line was an expensive and time-consuming undertaking available to relatively few researchers. The International Knockout Mouse Consortium, established in 2007, has revolutionized the use of such models by creating an open-access repository of embryonic stem (ES) cells that, through sequential breeding with first FLP1 recombinase and then Cre recombinase transgenic mice, facilitates germline global or conditional deletion of almost every gene in the mouse genome. In this Case Study, we describe our experience using the repository to create mouse lines for a variety of experimental purposes. Specifically, we discuss the process of obtaining germline transmission of two European Conditional Mouse Mutagenesis Program (EUCOMM) "knockout-first" gene targeted constructs and the advantages and pitfalls of using this system. We then outline our breeding strategy and the outcomes of our efforts to generate global and conditional knockouts and reporter mice for the genes of interest. Line maintenance, removal of recombinase transgenes, and cryopreservation are also considered. Our approach led to the generation of heterozygous knockout mice within 6 months of commencing breeding to the founder mice. By describing our experiences with the EUCOMM ES cells and subsequent breeding steps, we hope to assist other researchers with the application of this valuable approach to generating versatile knockout mouse lines.

Design and Generation of Gene-Targeting Vectors.

This unit provides an overview of the major types of mutant alleles that can be generated by gene targeting in ES cells. It presents the growing public resources of premade gene targeting vectors, modified ES cells, and mutant mice. General guidelines for the design of targeting vectors are followed by protocols for the construction of vectors to generate knockout (KO), conditional KO, and subtle mutant alleles. Curr. Protoc. Mouse Biol. 1:199-211. © 2011 by John Wiley & Sons, Inc.