Genetics of sex determination in man and mouse

The cytological evidence has revealed a visible mechanical basis for the production of males and females in equal numbers and irrespective of external conditions (Wilson, 1909).     

Genetics of cell-mediated lympholysis in man.

Cell-mediated lympholysis (CML) was studied in a family containing two siblings in who genetic recombinaiton had occurred in the HLA comples. In one sibling, recombination occurred between the HLA-A locus and the HLA-B locus. In the second sibling recombination occurred between the HLA-B locus and the HLA-D locus. Strong CML activity was generated in mixed lymphocyte cultures (MLC) when stimulator and responder cells differed in HLA-A, B, and D antigens. MLC involving HLA-D differences alone did not generate CML. Weak, but definite CML activity was generated during MLC with cells differing at HLA-A and HLA-B but sharing HLA-D. HLA-B antigens were good targets for lysis in all combinations studied. HLA-A antigens were poor targets in some but not in all combinations. However, combinations where HLA-A antigens seemed to be good targets could have involved HLA-B differences due to polymorphism of HLA-B7 antigens each inherited from a different parent. HLA-D antigens did not serve as targets for lysis. In three cell experiments, excellent CML activity was generated when responder cells were stimulated by HLA-D antigens and by HLA-A and B antigens present on separate stimulator cells.     

Genetics of the apolipoprotein E-system in man

The polymorphism of apolipoprotein E (Apo E) in man is controlled by two codominant alleles, Apo Eⁿ and Apo E^d, at the Apo E-N/D locus and by two alleles, the dominant, Apo E4⁺, and the recessive, Apo E4^o, at the Apo E4 locus.

Frequency distribution analysis of Apo E phenotypes demonstrated a highly significant association between both systems (P ~ 1%). The Apo E4-(+) variant was about twice as frequent in phenotype Apo E-N (30.1%) than in phenotype Apo E-ND (16.4%). The phenotypic combination Apo E-D/-E4(+) was not observed. The segregation of Apo E phenotypes in informative matings is consistent with a close linkage of both loci.

The results may be explained by different models. On the basis of the present data, these models cannot be distinguished by formal genetic criteria. (1) Haplotypes Apo Eⁿ/E4⁺, Apo Eⁿ/E4^o, and Apo E^d/E4^o determine the different phenotypes, and a linkage disequilibrium exists of Δ = .0147 between the E-N/D and E4 loci. (2) The fourth haplotype, Apo E^d/E4⁺, exists, but the gene E4⁺ is not expressed in coupling with Apo E^d. The four-haplotype model seems more attractive in view of Apo E-N/D polymorphism's quantitative character and of biochemical results, which show that phenotypes Apo E-N and Apo E-D differ in the apparent molecular weight (M_r) of the respective major Apo E polymorphic form. Hence, the Apo E-N/D locus may control structural genes involved in the posttranslational modification of Apo E. (3) Finally, there may exist only one Apo E structural gene locus but with mutations at two sites susceptible to posttranslational modification.

     

Genetics and bone. Using the mouse to understand man

The rationale for use of inbred strains of mice in bone research is well recognized and includes: a) practical factors (economics of scale, rapid development of adult status, pre-existing knowledge, down-sized technologies) and b) proven methodologies for genetic studies (polygenic trait analyses, mapping tools, genomic sequencing, methods for gene manipulation). Initial investigations of inbred strains of mice showed that femoral and lumbar vertebral volumetric bone mineral density (BMD, mg/mm(3)) by pQCT varied in excess of 50% for femurs and 9% in vertebral BMD. Two strains - low BMD C57BL/6J (B6) mice and high BMD C3H/HeJ (C3H) - were investigated for insights to their BMD diversity. B6C3F2 females derived from intercrossing B6C3F1s were raised to adult skeletal status at 4 months, then necropsied for phenotyping of bone and genotyping of genomic DNA. 1000 F2 females were genotyped for PCR product polymorphisms on all 19 autosomes at approximately 15 cM. Genome wide analyses for genotype-phenotype correlations showed 10 chromosomes (Chrs) carried genes for femoral and 7 Chrs for vertebral BMD. LOD scores ranged from 2.90 to 24.4, and percent of F2 variance accounted for ranged from 1 to 10%. Analyses of main effects revealed both dominant-recessive and additive inheritance patterns. Both progenitor strains carried alleles with positive and negative effects on BMD of each bone sites. A remarkable array of additonal skeletal phenotypes (femur and vertebral geometry, strength measures, serum markers) also proved polygenic in nature, with complex segregation patterns. Verification of BMD quantitative trait loci (QTLs) was undertaken by creating congenic B6 strains carrying individual QTL regions from C3H. Following 6 cycles of backcrossing a QTL-containing region from C3H to the B6 strain, N6F2 congenic strain mice were aged to 4 months, then genotyped for the QTL region and phenotyped for skeletal traits. Comparison of mice homozygous for C3H alleles versus homozygous for B6 alleles in the QTL regions showed that femoral BMD increased or decreased significantly in congenic strains, as was predicted from F2 data. Gender differences specific to BMD QTLs have been revealed, as have more than 30 additional phenotypes associated with cortical and trabecular structural parameters and biomechanical properties.     

Genetics of colorectal cancer

Colorectal cancer (CRC) is the second leading cause of cancer-related mortality in the United States. As such, it assumes a significant role in both health policy decision-making and scientific research. CRC has been a model for investigating the molecular genetics of cancer development and progression; this is in part due to the easily detectable, sequential transition of cells from normal colonic epithelium to adenoma and then to adenocarcinoma. In addition, familial syndromes that predispose to CRC, such as familial adenomatous polyposis (FAP) and hereditary nonpolyposis colorectal cancer (HNPCC), have significantly contributed to our understanding of the genetic mechanisms underlying CRC formation. It is now well recognized that hereditary CRC syndromes are due to germline mutations of genes that function as tumor suppressors or, less frequently, oncogenes. Accumulation of subsequent mutations in other genes with related functions results in the stepwise progression to carcinoma. It is important to note that somatic changes in similar genes are involved in the formation of sporadic CRC. The identification of these important CRC-related genes may help facilitate the early diagnosis, prevention, and treatment of CRC. This article reviews the various familial CRC syndromes along with their genetic etiology, as well as discusses the principle of genetic testing for these conditions.     

Genetics of human S-adenosylhomocysteine hydrolase. A new polymorphism in man

Summary A specific staining procedure for the demonstration of S-adenosylhomocysteine hydrolase (SAAH, EC 3.3.1.1) is given. The enzyme has a broad tissue distribution and is also present in erythrocytes. The SAHH gene is polymorphic in the population of southwest Germany with two common alleles: SAHH ^*1=0.96 and SAHH ^*1=0.04. Family studies resulted in the expected segregation ratios. No evidence for close linkage with a total of 25 marker loci was found. But information from human mouse somatic-cell hybrids led to the localization of the SAHH gene to human chromosome 20, thereby confirming the findings of Hershfield and Francke (1982).Dedicated to Professor Dr. P. E. Becker on the occasion of his 75th birthday     

Genetics of colon cancer.

Strikingly rapid advances in the identification of genetic events that are important in colonic carcinogenesis have been made in the past several years. Specific inherited (adenomatous polyposis coli gene) and acquired (ras gene point mutations; c-myc gene amplification; allelic deletion at specific sites on chromosomes 5, 17, and 18) genetic abnormalities appear to be capable of mediating steps in the progression from normal to malignant colonic mucosa. Understanding these genetic factors and how they influence cellular function will have a profound effect on medical practice. High-risk populations will be (and are being) identified by genetic markers, thus allowing prevention and screening to be more precisely targeted to the population at risk; intervention strategies will be designed on the basis of the known cellular defects of neoplastic colonic mucosa; and new molecular preventive and therapeutic approaches can be developed.     

Genetics and epigenetics of renal cell cancer

Renal cell carcinoma (RCC) is not a single disease, but comprises a group of tumors of renal epithelial origin, each with a different histology, displaying a different clinical course and caused by different genetic alterations. Since cure rates are inversely associated with stage and response to the available treatment regimes is limited to a subgroup of patients, diagnostic methods facilitating early detection and new therapeutic modalities are necessary. Increased knowledge of the underlying pathophysiology of RCC has resulted in the identification of genetic alterations involved in renal cell cancer carcinogenesis. Promising agents to target these pathways, especially the angiogenesis pathway, are being developed, some of which are already standard of care. In addition to genetics, knowledge on epigenetics in the process of renal tumorigenesis has been significantly increased in the last decades. Epigenetics will play an increasing role in the development of new therapeutic modalities and may deliver new prognostic and early diagnostic markers. In this review we discuss the background of RCC and the clinical applications of RCC genetics and epigenetics.