Genetic control of susceptibility of mice to Rous sarcoma virus tumorigenesis

Studies with congenic resistant strains of mice indicate that susceptibility to Rous sarcoma virus tumorigenesis is influenced by a gene or genes associated with the major histocompatibility complex (H-2). These genes manifest dominant relative susceptibility. Preliminary studies indicate that the CBA/J strain harbors a gene or genes for relative susceptibility, which are recessive. These results are compared with other studies onH-2-associated genes affecting murine viral oncogenesis.     

Genetic control of susceptibility to mite-associated ulcerative dermatitis

Variable susceptibility to mite-associated ulcerative dermatitis (MAUD) attributable to Myobia musculi infestation was studied in breeding stocks of sixteen inbred strains of mice. Statistical evaluation of 41 occurrences of lesion among 1,517 mice of the various strains indicated that significant differences in the frequency of MAUD were associated with differences in genetic background and in the H-2 type. These findings suggest that the occurrence of an ulcerative skin lesion in inbred mice exposed to M. musculi is controlled by at least two genes. Lesion susceptibility appears to be profoundly affected by a non-H-2 linked gene or gene combination shared by all C57Bl background strains. In addition, a major influence is exerted by one or more genes within the H-2 complex.     

Genetic control of susceptibility to hydroxyproline in Drosophila.

Hydroxyproline (OHP) is known to produce morphological abnormalities in susceptible Drosophila. In some, OHP prevents head eversion during pupation producing a cryptocephal (crc) phenocopy, others fail to fully stretch legs and wings producing a shortened distance between these appendages (LWD). In this paper the genetic basis of susceptibility to OHP is explored and compared to the control of susceptibility to glucosamine (GA) which also produces a crc phenocopy. The data suggest that genes providing resistance to the effects of GA are different from those conferring resistance to OHP. Furthermore, genes providing resistance to the crc effects of OHP appear to be different from those controlling resistance-to the LWD effects. Intrastrain gene coadaptation also seems to be important in resistance to OHP. The relevance of these results to the problem of the genetic control of developmental buffering is briefly discussed.     

Genetic control of susceptibility to experimental allergic encephalomyelitis in mice

The genetic control of susceptibility to experimental allergic encephalomyelitis (EAE) was studied in mice. The results indicate that sensitivity to disease is not inherited in a simple Mendelian dominant way. Susceptibility to EAE is governed by genes located outside of the major histocompatibility complex and not byH-2-linkedIr genes. No correlation was observed between susceptibility to disease and the cellular immune response toward the small encephalitogenic protein.     

Genetic control of macrophage susceptibility to infection by Legionella pneumophila

Abstract Legionella pneumophila readily grows in cultures of thioglycollate (TGC)-induced macrophages (MPs) from A/J mice, but not in MPs from BALB/c mice or other mouse strains. In the present study, the growth of Legionella pneumophila in MPs from A/J and BALB/c mice, as well as hybrids of the two strains and back-crossed mice, was investigated to determine whether the permissiveness of growth of these bacteria was due to an inherited trait of the MPs. The MPs from all A/J mice supported the growth of Legionella , regardless of whether they were obtained from TGC or casein injected donors, but the cells from the mice given TGC supported growth of L. pneumophila much better than cells from mice injected with casein. Furthermore, MPs obtained from all BALB/c mice treated with either TGC or casein were nonpermissive for the growth of L. pneumophila . MPs from approximately 46% of the back-crossed ACF1 to A/J mice were permissive for L. pneumophila growth, while MPs from all ACF1 to back-crossed BALB/c mice were found to be nonpermissive. MPs from approximately 19% of ACF2 mice were permissive for L. pneumophila . Killing activities of MPs using temperature sensitive mutants of Salmonella typhimurium were variable and did not correlate with permissiveness or nonpermissiveness for growth of L. pneumophila . In addition, the number of inflammatory cells in the peritoneal cavity induced in response to TGC did not correlate with the permissiveness or nonpermissiveness of the MPs from various mouse strains to Legionella , indicating the permissive nature of the cells is controlled by genetic mechanisms involving a recessive phenotype but differs from resistance genes such as Ity important for replication of S. typhimurium .     

Genetic control of susceptibility to bacterial infections in mouse models

Historically, the laboratory mouse (Mus musculus) has been the experimental model of choice to study pathophysiology of infection with bacterial pathogens, including natural and acquired host defence mechanisms. Inbred mouse strains differ significantly in their degree of susceptibility to infection with various human pathogens such as Mycobacterium, Salmonella, Legionella and many others. Segregation analyses and linkage studies have indicated that some of these differences are under simple genetic control whereas others behave as complex traits. Major advances in genome technologies have greatly facilitated positional cloning of single gene effects. Thus, a number of genes playing a key role in initial susceptibility, progression and outcome of infection have been uncovered and the functional characterization of the encoded proteins has provided new insight into the molecular basis of antimicrobial defences of polymorphonuclear leukocytes, macrophages, as well as T and B lymphocytes. The multigenic control of susceptibility to infection with certain human pathogens is beginning to be characterized by quantitative trait locus mapping in genome wide scans. This review summarizes recent progress on the mapping, cloning and characterization of genes and proteins that affect susceptibility to infection with major intracellular bacterial pathogens.     

Genetic control of susceptibility to carcinogen-induced colorectal cancer in mice: The Ccs3 and Ccs5 loci regulate different aspects of tumorigenesis

Colorectal cancer (CRC) is a multistep disease that involves a two-way interaction between a complex genetic pre-disposition component, and a set of poorly understood extrinsic environmental factors. In mice, CRC can be induced by treatment with azoxymethane (AOM). Using a set of AcB/BcA recombinant congenic strains derived from CRC-susceptible A/J and CRC-resistant C57Bl/6J (B6) progenitors, we previously detected the Ccs3 locus (colon cancer susceptibility locus 3) as a major regulator of CRC susceptibility. Phenotyping of additional AcB/BcA strains for susceptibility to AOM-induced CRC has refined the Ccs3 interval to a 6.7 Mb segment on chromosome 3. In addition, the presence of intermediate susceptibility phenotypes in individual AcB/BcA strains suggested additional gene effects regulating CRC susceptibility in A/J and B6 strains. Those were investigated by linkage analysis and whole genome scanning in a set of 208 informative (B6 x A/J)F2 progeny, using tumor multiplicity as a quantitative measure of susceptibility. This analysis validated the important role of Ccs3 in regulating this trait, and additionally detected contribution from a second locus on the distal portion of chromosome 9 (LOD = 3.76), that was given the temporary designation of Ccs5. Ccs5 modulates tumor multiplicity in F2 animals bearing at least one A/J-derived susceptibility allele at Ccs3, with A/J-derived Ccs5 susceptibility alleles being inherited in a recessive manner. There is a strong additive effect of Ccs3 and Ccs5 on tumor multiplicity in F2 mice: mice doubly homozygotes for A/J or B6 alleles at Ccs3 and Ccs5 show tumor numbers similar to those of parental A/J and B6, respectively. Interestingly, the Ccs5 region overlaps several quantitative trait loci previously reported to regulate intestinal homeostasis and susceptibility to intestinal colitis in mice and humans. Our findings identify a novel two-locus system regulating CRC susceptibility in mice, of which the relevance to human CRC can now be tested experimentally.     

Collagenase expression in transgenic mouse skin causes hyperkeratosis and acanthosis and increases susceptibility to tumorigenesis.

In a series of transgenic mice, the human tissue collagenase gene was expressed in the suprabasal layer of the skin epidermis. Visually, the mice had dry and scaly skin which upon histological analysis revealed acanthosis, hyperkeratosis, and epidermal hyperplasia. At the ultrastructural level, intercellular granular materials were absent in the transgenic skin epidermis but contact was maintained through the intact desmosomes. Despite a diversity of underlying etiologies, similar morphological hyperproliferative changes in the epidermis are observed in the human skin diseases of lamellar ichthyosis, atopic dermatitis, and psoriasis. Subsequent experiments demonstrate that when the transgenic mouse skin was treated once with an initiator (7,12-dimethyl-benz[a]anthracene) and then twice weekly with a promoter (12-O-tetradecanoylphorbol-13-acetate), there was a marked increase in tumor incidence among transgenic mice compared with that among control littermates. These experiments demonstrate that by overexpressing the highly specific proteolytic enzyme collagenase, a cascade of events leading to profound morphological changes which augment the sensitivity of the skin towards carcinogenesis is initiated in the epidermis.     

Genetic control of susceptibility to infection with Candida albicans in mice

Candida albicans is an opportunistic pathogen that causes acute disseminated infections in immunocompromised hosts, representing an important cause of morbidity and mortality in these patients. To study the genetic control of susceptibility to disseminated C. albicans in mice, we phenotyped a group of 23 phylogenetically distant inbred strains for susceptibility to infection as measured by extent of fungal replication in the kidney 48 hours following infection. Susceptibility was strongly associated with the loss-of-function mutant complement component 5 (C5/Hc) allele, which is known to be inherited by approximately 40% of inbred strains. Our survey identified 2 discordant strains, AKR/J (C5-deficient, resistant) and SM/J (C5-sufficient, susceptible), suggesting that additional genetic effects may control response to systemic candidiasis in these strains. Haplotype association mapping in the 23 strains using high density SNP maps revealed several putative loci regulating the extent of C. albicans replication, amongst which the most significant were C5 (P value = 2.43×10⁻¹¹) and a novel effect on distal chromosome 11 (P value = 7.63×10⁻⁹). Compared to other C5-deficient strains, infected AKR/J strain displays a reduced fungal burden in the brain, heart and kidney, and increased survival, concomitant with uniquely high levels of serum IFNγ. C5-independent genetic effects were further investigated by linkage analysis in an [A/JxAKR/J]F2 cross (n = 158) where the mutant Hc allele is fixed. These studies identified a chromosome 11 locus (Carg4, Candida albicans resistance gene 4; LOD = 4.59), and a chromosome 8 locus (Carg3; LOD = 3.95), both initially detected by haplotype association mapping. Alleles at both loci were inherited in a co-dominant manner. Our results verify the important effect of C5-deficiency in inbred mouse strains, and further identify two novel loci, Carg3 and Carg4, which regulate resistance to C. albicans infection in a C5-independent manner.     

Genetic control of renal tumorigenesis by the mouse Rtm1 locus

Background

The genetic basis of susceptibility to renal tumorigenesis has not yet been established in mouse strains. Mouse lines derived by bidirectional phenotypic selection on the basis of their maximal (AIRmax) or minimal (AIRmin) acute inflammatory responsiveness differ widely in susceptibility to spontaneous and urethane-induced renal tumorigenesis. To map the functional loci modulating renal tumor susceptibility in these mice, we carried out a genome-wide genetic linkage study, using SNP arrays, in an (AIRmax x AIRmin)F2 intercross population treated with a single urethane dose at 1 week of age and phenotyped for renal tumors at 35 weeks of age.

Results

AIRmax mice did not develop renal tumors spontaneously nor in response to urethane, whereas in AIRmin mice renal tumors formed spontaneously (in 52% of animals) and after urethane induction (89%). The tumors had a papillary morphology and were positive for alpha-methylacyl-CoA racemase and negative for CD10. By analysis of 879 informative SNPs in 662 mice, we mapped a single quantitative trait locus modulating the incidence of renal tumors in the (AIRmax x AIRmin)F2 intercross population. This locus, which we named Renal tumor modifier QTL 1 (Rtm1), mapped to chromosome 17 at 23.4 Mb (LOD score = 15.8), with SNPs rs3696835 and rs3719497 flanking the LOD score peak. The A allele of rs3719497 from AIRmin mice was associated with a 2.5-fold increased odds ratio for renal tumor development. The LOD score peak included the Tuberous sclerosis 2 (Tsc2) gene which has already been implicated in kidney disease: loss of function by germline retroviral insertion is associated with spontaneous renal tumorigenesis in the Eker rat, and heterozygous-null Tsc2^(+/-) mice develop renal cystadenomas.

Conclusions

We mapped Rtm1 as a single major locus modulating renal tumorigenesis in a murine intercross population. Thus, the AIR mouse lines can be considered a new genetic model for studying the role of germline and somatic molecular alterations in kidney neoplastic disease.     

Genetic susceptibility to prostate cancer

Prostate cancer is the most frequent malignant tumor among men over 50 years old. Its incidence varies according to countries and ethnic group. Known risk factors are race and positive family history of the disease. Familial aggregation (at least 2 cases in the family) is observed in about 20% of cases and an hereditary form of prostate cancer in 5%. This proportion increases with younger age at diagnosis. Six putative loci are already identified but undoubtedly, others will be found in forthcoming studies. The genetic heterogeneity observed in hereditary prostate cancer reflects variety of origins of the studied families. In some families, aggregation of prostate cancer and other cancers suggests the involvement of common predisposing genes. In other familial and in sporadic cases, the genetic component should be polygenic: prostate cancer wouldn't result to segregation of a major gene mutations transmitted according to a monogenic inheritance, but rather to sharing of alleles at many loci, each contributing to a small increase in cancer risk. Indeed, several genetic polymorphism were associated with an increased risk of developing prostate cancer and could explain the variations of prostate cancer incidence observed between populations.     

Genetic susceptibility to ankylosing spondylitis

Ankylosing spondylitis is a highly heritable, common rheumatic condition, primarily affecting the axial skeleton. The association with HLA-B27 has been demonstrated worldwide, and evidence for a role of HLA-B27 in disease comes from linkage and association studies in humans, and transgenic animal models. However, twin studies indicate that HLA-B27 contributes only 16% of the total genetic risk for disease. Furthermore, there is compelling evidence that non-B27 genes, both within and outwith the major histocompatability complex, are involved in disease aetiology. In this post-genomic era we have the tools to help elicit the genetic basis of disease. This review describes methods for genetic investigation of ankylosing spondylitis, and summarises the status of current research in this exciting area.     

Genetic susceptibility to Alzheimer disease

Alzheimer disease (AD) is the leading cause of dementia in the elderly. Less than a decade ago, it was questioned as to whether or not genes were even involved in anything but rare early onset AD. Since that time, using a variety of genetic epidemiological and molecular biological techniques, four loci have been identified that play a role in the genetic susceptibility of AD, AD presents as a prototype of the power of genetic techniques in defining the etiology of a complex disease.     

Genetic susceptibility to ageing-associated diseases

The constant and rapid increase of life expectancy in western countries is associated with a major ageing of our populations. In these conditions, we can expect an epidemic progression of most chronic diseases, especially cardiovascular, neurodegenerative and metabolic disorders, the main causes of death in the world. The global burden of these diseases will have a dramatic impact on the health and on the socio-economical context of our societies. From a global point of view, the occurrence and progression of these multifactorial diseases rely upon the nature and intensity of the environmental determinants we are exposed to all life long, but also to our individual genetic susceptibility. Through the determination of this higher susceptibility to an environmental risk factor and the understanding of its mechanisms of action, prevention and management efforts will be better focused. In such multifactorial affections, the development and the transmission of the disease do not follow the simple laws of monogenic Mendelian models. The complexity of this transmission is associated with the influence, at various degrees, of several genes and of a close interaction between this particular genetic susceptibility and environmental risk factors. With the recent development of automated and high throughput molecular biology techniques and their use in epidemiological studies, gene expression regulation and post genomic studies, the determination of sub-groups facing a higher individual genetic susceptibility has begun. This determination will offer new clues for a better-targeted disease management.     

Genetic differences in bone marrow-derived lymphoid lineages control susceptibility to experimental autoimmune myocarditis

Bone marrow (BM) transplantation has been used to study the cellular basis of genetic control of autoimmune diseases, but conclusions remain elusive due to the contradictory findings in different animal models. In the current study, we found that BM cells from myocarditis-susceptible A.SW mice can render irradiated, myocarditis-resistant B10.S recipient mice susceptible to myosin-induced myocarditis, indicating that hematopoietic cells express the genetic differences controlling susceptibility to autoimmune myocarditis. We then sought to differentiate the role of lymphoid vs nonlymphoid components of BM in the pathogenesis of myocarditis by comparing mixed chimeras receiving BM from A.SW wild-type or RAG(-/-) mice mixed with BM from B10.S wild-type mice. This experiment clearly demonstrated that T and B lymphocytes were indispensable for transferring the susceptible phenotype to disease-resistant recipients. Our findings significantly narrow the cellular expression of genetic polymorphisms controlling the EAM phenotype.     

Genetic susceptibility to chronic periodontal disease

Evidence suggests that there is a significant genetic component to susceptibility and resistance to chronic periodontal disease. Data from both clinical studies and studies using animal models are reviewed here. Also outlined are the genomic methods that are now available for identifying susceptibility and resistance loci.     

Snm1-deficient mice exhibit accelerated tumorigenesis and susceptibility to infection

The eukaryotic SNM1 gene family has been implicated in a number of cellular pathways, including repair of DNA interstrand cross-links, involvement in VDJ recombination, repair of DNA double-strand breaks, and participation in cell cycle checkpoint pathways. In particular, mammalian SNM1 has been shown to be required in a mitotic checkpoint that causes arrest of cells in prophase prior to chromosome condensation in response to spindle poisons. Here, we report on the phenotype of a knockout of Snm1 in the mouse. Snm1-/- mice are viable and fertile but exhibit a complex phenotype. Both homozygous and heterozygous mice show a decline in survival compared to wild-type littermates. In homozygous mutant males, this reduction in survival is principally due to bacterial infections in the preputial and mandibular glands and to a lesser extent to tumorigenesis, while in homozygous and heterozygous females, it is due almost solely to tumorigenesis. The high incidence of bacterial infections in the homozygous mutant males suggests an immune dysfunction; however, examinations of T- and B-cell development and immunoglobulin class switching did not reveal a defect in these pathways. Crossing of Snm1 mutant mice with a Trp53 null mutant resulted in an increase in mortality and a restriction of the tumor type to lymphomas, particularly those of the thymus. Taken together, these findings demonstrate that Snm1 is a tumor suppressor in mice that in addition has a role in immunity.     

Loss of hairless confers susceptibility to UVB-induced tumorigenesis via disruption of NF-kappaB signaling

In order to model squamous cell carcinoma development in vivo, researchers have long preferred hairless mouse models such as SKH-1 mice that have traditionally been classified as 'wild-type' mice irrespective of the genetic factors underlying their hairless phenotype. The work presented here shows that mutations in the Hairless (Hr) gene not only result in the hairless phenotype of the SKH-1 and Hr(-/-) mouse lines but also cause aberrant activation of NFκB and its downstream effectors. We show that in the epidermis, Hr is an early UVB response gene that regulates NFκB activation and thereby controls cellular responses to irradiation. Therefore, when Hr expression is decreased in Hr mutant animals there is a corresponding increase in NFκB activity that is augmented by UVB irradiation. This constitutive activation of NFκB in the Hr mutant epidermis leads to the stimulation a large variety of downstream effectors including the cell cycle regulators cyclin D1 and cyclin E, the anti-apoptosis protein Bcl-2, and the pro-inflammatory protein Cox-2. Therefore, Hr loss results in a state of uncontrolled epidermal proliferation that promotes tumor development, and Hr mutant mice should no longer be considered merely hairless 'wild-type' mice. Instead, Hr is a crucial UVB response gene and its loss creates a permissive environment that potentiates increased tumorigenesis.     

Genetic susceptibility to ischemic stroke in Russians

The frequencies of alleles and genotypes for ten functionally significant single-nucleotide polymorphisms were determined in the FGA, FGB, APOE, LPL, ACE, and CMA1 genes for Russian ischemic stroke (IS) patients and for a control group of Russians similar in gender and age distribution. The groups showed no significant differences in the frequencies of individual alleles or genotypes for any polymorphism studied. However, complex analysis of genetic susceptibility by the APSampler algorithm demonstrated that carriership of the APOE (−491A) allele predisposed to IS (p = 0.044, OR 3.8, 95% CI 1.0–15.1). Correspondingly, the APOE (−491T/T) genotype was associated with resistance to IS (p = 0.044, OR 0.26, 95% CI 0.07–1.0). The carriership of FGB (−249C) allele together with this genotype enhanced its protective potential, reducing the p value of the combination twofold (OR 0.17, 95% CI 0.04–0.8). Two more protective combinations were identified: biallelic APOE (−427C) + LPL (1595G) and triallelic APOE (−491C) + LPL (1595G) + CMA1 (−1903G). In both cases, p = 0.0052, OR 0.18, and 95% CI 0.05–0.66. Altogether, involvement in the formation of IS risk in Russians was evidenced for alleles of four genes: APOE, FGB, LPL, and CMA1; the APOE involvement was demonstrated for alleles of two polymorphic loci: −491T and −427C. Linkage analysis suggested that these loci were involved in IS resistance independently of each other.