FACS-array gene expression analysis during early development of mouse telencephalic interneurons

Cortical interneuron dysfunction has been implicated in multiple human disorders including forms of epilepsy, mental retardation, and autism. Although significant advances have been made, understanding the biologic basis of these disorders will require a level of anatomic, molecular, and genetic detail of interneuron development that currently does not exist. To further delineate the pathways modulating interneuron development we performed fluorescent activated cell sorting (FACs) on genetically engineered mouse embryos that selectively express green fluorescent protein (GFP) in developing interneurons followed by whole genome microarray expression profiling on the isolated cells. Bioinformatics analysis revealed expression of both predicted and unexpected genes in developing cortical interneurons. Two unanticipated pathways discovered to be up regulated prior to interneurons differentiating in the cortex were ion channels/neurotransmitters and synaptic/vesicular related genes. A significant association of neurological disease related genes to the population of developing interneurons was found. These results have defined new and potentially important data on gene expression changes during the development of cortical interneurons. In addition, these data can be mined to uncover numerous novel genes involved in the generation of interneurons and may suggest genes/pathways potentially involved in a number of human neurological disorders.     

Genetics of familial melanoma: 20 years after CDKN2A

Twenty years ago, the first familial melanoma susceptibility gene, CDKN2A, was identified. Two years later, another high‐penetrance gene, CDK4, was found to be responsible for melanoma development in some families. Progress in identifying new familial melanoma genes was subsequently slow; however, with the advent of next‐generation sequencing, a small number of new high‐penetrance genes have recently been uncovered. This approach has identified the lineage‐specific oncogene MITF as a susceptibility gene both in melanoma families and in the general population, as well as the discovery of telomere maintenance as a key pathway underlying melanoma predisposition. Given these rapid recent advances, this approach seems likely to continue to pay dividends. Here, we review the currently known familial melanoma genes, providing evidence that most additionally confer risk to other cancers, indicating that they are likely general tumour suppressor genes or oncogenes, which has significant implications for surveillance and screening.     

Heritability of X chromosome--inactivation phenotype in a large family.

One of the two X chromosomes in each somatic cell of normal human females becomes inactivated very early in embryonic development. Although the inactivation of an X chromosome in any particular somatic cell of the embryonic lineage is thought to be a stochastic and epigenetic event, a strong genetic influence on this process has been described in the mouse. We have attempted to uncover evidence for genetic control of X-chromosome inactivation in the human by examining X chromosome-inactivation patterns in 255 females from 36 three-generation pedigrees, to determine whether this quantitative character exhibits evidence of heritability. We have found one family in which all seven daughters of one male and the mother of this male have highly skewed patterns of X-chromosome inactivation, suggesting strongly that this quantitative character is controlled by one or more X-linked genes in some families.     

Molecular-genetic analysis of torsion dystonia in Russia

For the first time in Russia, analysis of the GCH-I and DYT1 genes was carried out for the purpose of direct DNA diagnostics in families with various forms of hereditary torsion dystonia (TD). Four new missense mutations (Met102Lys, Thr94Lys, Cys141Trp, and Ser176Thr) in the GCH-I gene were found in patients with dopa-responsive dystonia (DRD), testifying to a genetic heterogeneity of this clinical form of TD. The distribution of the major del GAG mutation in exon 5 of the DYT1 gene was studied in patients with non-dopa-responsive dystonia (NDRD). In total, the mutation was found in 68% of the patients. The frequency of this mutation in Ashkenazi Jews with NDRD was 100% (twice higher than in Slavonic families), suggesting the founder effect reported for NDRD in this ethnic group. Mutations of the GCH-I and DYT1 genes were also found in patients with atypical and questionable cases of TD, which are difficult to diagnose with methods other than DNA analysis. The data obtained made it possible to extend the spectrum of clinical signs of DRD and NDRD and to revise the views on true penetrance of the corresponding mutant genes, which is important for medical genetic counseling in affected families.     

Imprinting mechanisms and genes involved in Prader-Willi and Angelman syndromes

Prader-Willi (PWS) and Angelman (AS) syndromes illustrate a disease paradigm of genomic imprinting, an epigenetic modification of DNA that results in parent-of-origin specific expression during embryogenesis and in the adult. From genetic data, at least two imprinted genes may be required for the classical PWS phenotype, whereas AS probably involves a single imprinted gene, and rare familial forms of both disorders involve imprinting mutations. In addition, the nonimprinted P gene is associated with pigmentation disorders in PWS, AS and oculocutaneous albinism. Identification of new genes, delineation of small deletions in unique patients, and direct screening for imprinted sequences, should soon identify candidate genes for PWS and AS. The mechanism of imprinting involves DNA methylation and replication timing, and appears to include multiple imprinted genes within a large imprinted domain. Imprinting of these genes may be regulated in cis, by an imprinting control element (ICE). Future studies can be expected to unravel the gene identities and imprinting mechanisms involved in these fascinating disorders; ultimately it may be possible to reactivate imprinted gene expression as a therapeutic approach.     

DNA微阵列技术及其在肿瘤生物学中的应用

人类基因组测序工作的完成使人们可以方便地调用任何基因序列,但仅有基因序列并不能解释众多的生物学问题,这要求发展一种高通量的技术用于研究基因的生物学功能以及基因的相互作用。DNA微阵列技术以其高通量的特点,已经在肿瘤生物学的研究中逐渐被采用。由于癌症是源于基因表达谱改变的基因疾病,通过DNA微阵列技术研究癌症细胞和对应的正常细胞的基因表达差异,将会使人们更好地了解肿瘤的形成和发展过程。     

Genetic factors and a polygenic model of Alzheimer's disease

Genetic factors are responsible, to a certain degree, for many, if not all, Alzheimer's disease (AD) cases. A certain proportion of early-onset (below 65 years of age) AD cases follows an autosomal dominant mode of inheritance. Three genes were identified whose mutations account for 50-70% of early-onset monogenic AD cases in AD pedigrees. These are the genes of the amyloid precursor protein (APP) and two presenilins (PS I and PS II). The polymorphic variant of apolipoprotein E, APOE epsilon 4, is a genetic causative factor in familial and sporadic cases of various early- and late-onset AD forms (it is found, in general, in 20-50% of all AD cases). The action of the epsilon 4 allele is codominant, with the AD risk increased in homozygotes (epsilon 4/epsilon 4 > epsilon 4 > epsilon 3 or epsilon 2). In contrast to the mutations in the PS I and APP genes, the APOE epsilon 4 allele is not a necessary and sufficient condition for AD development. Mutations in these genes have not been found in a proportion of familial early-onset AD cases and are not causative factors in the majority of late-onset familial and sporadic forms. The genes determining AD are evolutionarily conservative and are expressed in all human tissues as early as at initial ontogenetic stages. This raises the question as to why AD is a progressive disorder affecting certain cerebral regions only at middle or old age. A hypothesis and model are suggested to explain the interaction between evolutionary, ontogenetic, and epigenetic factors of the development of the central nervous system and the products of genes whose mutations result in AD. Findings of different mutant genes indicate that AD is a set of genetic disorders (ADs) with a common pathological manifestation.     

Genetic predisposition and environmental risk factors to pancreatic cancer: A review of the literature

Some cases of pancreatic cancer (PC) are described to cluster within families. With the exception of PALLD gene mutations, which explain only a very modest fraction of familial cases, the genetic basis of familial PC is still obscure. Here the literature was reviewed in order to list the known genes, environmental factors, and health conditions associated with PC or involved in the carcinogenesis of the pancreas. Most of the genes listed are responsible for various well-defined cancer syndromes, such as CDKN2A (familial atypical mole-multiple melanoma, FAMMM), the mismatch repair genes (Lynch Syndrome), TP53 (Li-Fraumeni syndrome), APC (familial adenomatous polyposis), and BRCA2 (breast–ovarian familial cancer), where PC is part of the cancer spectrum of the disease. In addition, in this review I ranked known/possible risk factors extending the analysis to the hereditary pancreatitis (HP), diabetes, or to specific environmental exposures such as smoking. It appears that these factors contribute strongly to only a small proportion of PC cases. Recent work has revealed new genes somatically mutated in PC, including alterations within the pathways of Wnt/Notch and DNA mismatch repair. These new insights will help to reveal new candidate genes for the susceptibility to this disease and to better ascertain the actual contribution of the familial forms.     

Chromosome 3 translocations and familial renal cell cancer

Renal cell carcinomas (RCCs) occur in both sporadic and familial forms. In a subset of families the occurrence of RCCs co-segregates with the presence of constitutional chromosome 3 translocations. Previously, such co-segregation phenomena have been widely employed to identify candidate genes in various hereditary (cancer) syndromes. Here we survey the translocation 3-positive RCC families that have been reported to date and the subsequent identification of its respective candidate genes using positional cloning strategies. Based on allele segregation, loss of heterozygosity and mutation analyses of the tumors, a multi-step model for familial RCC development has been generated. This model is relevant for (i) understanding familial tumorigenesis and (ii) rational patient management. In addition, a high throughput microarray-based strategy is presented that will enable the rapid identification of novel positional candidate genes via a single step procedure. The functional consequences of the (fusion) genes that have been identified so far, the multi-step model and its consequences for clinical diagnosis, the identification of persons at risk and genetic counseling in RCC families are discussed.     

SOX genes: architects of development.

Development in higher organisms involves complex genetic regulation at the molecular level. The emerging picture of development control includes several families of master regulatory genes which can affect the expression of down-stream target genes in developmental cascade pathways. One new family of such development regulators is the SOX gene family. The SOX genes are named for a shared motif called the SRY box a region homologous to the DNA-binding domain of SRY, the mammalian sex determining gene. Like SRY, SOX genes play important roles in chordate development. At least a dozen human SOX genes have been identified and partially characterized (Tables 1 and 2). Mutations in SOX9 have recently been linked to campomelic dysplasia and autosomal sex reversal, and other SOX genes may also be associated with human disease.     

Genetics of thyroid function and disease

Genetics play a prominent role in both determination of thyroid hormone and thyrotropin (TSH) concentrations, and susceptibility to autoimmune thyroid disease. Heritability studies have suggested that up to 67% of circulating thyroid hormone and TSH concentrations are genetically determined, suggesting a genetic basis for narrow intra-individual variation in levels, perhaps a genetic 'set point'. The search for the genes responsible has revealed several candidates, including the genes for phosphodiesterase 8B, iodothyronine deiodinase 1, F-actin-capping protein subunit beta and the TSH receptor; however, each of these only contributes a small amount to the variability of hormone concentrations, suggesting that further genes and mechanisms of genetic influence are yet to be discovered. Some genes known to influence thyroid function, including iodothyronine deiodinase 2 and the TSH receptor, have been shown to influence a wide range of clinical and developmental phenotypes from bone health to neurological development and longevity; such observations will help us understand the complex action of thyroid hormones on individual tissues. Finally, autoimmune thyroid disease commonly runs in families, and the search for genes which increase susceptibility has identified several good candidates, particularly those involved in immune regulation and thyroid function. However, these genes alone account for only a small percentage of the current prevalence of these disorders. Although the advancement of genetic technology has led to many significant findings in the last decade or two, it is clear that we are only just beginning to understand the role of genetics in thyroid function and disease.     

Thirty years of Alzheimer's disease genetics: the implications of systematic meta-analyses

The genetic underpinnings of Alzheimer's disease (AD) remain largely elusive despite early successes in identifying three genes that cause early-onset familial AD (those that encode amyloid precursor protein (APP) and the presenilins (PSEN1 and PSEN2)), and one genetic risk factor for late-onset AD (the gene that encodes apolipoprotein E (APOE)). A large number of studies that aimed to help uncover the remaining disease-related loci have been published in recent decades, collectively proposing or refuting the involvement of over 500 different gene candidates. Systematic meta-analyses of these studies currently highlight more than 20 loci that have modest but significant effects on AD risk. This Review discusses the putative pathogenetic roles and common biochemical pathways of some of the most genetically and biologically compelling of these potential AD risk factors.     

Analysis of families in the multiple autoimmune disease genetics consortium (MADGC) collection: the PTPN22 620W allele associates with multiple autoimmune phenotypes

Autoimmune disorders constitute a diverse group of phenotypes with overlapping features and a tendency toward familial aggregation. It is likely that common underlying genes are involved in these disorders. Until very recently, no specific alleles--aside from a few common human leukocyte antigen class II genes--had been identified that clearly associate with multiple different autoimmune diseases. In this study, we describe a unique collection of 265 multiplex families assembled by the Multiple Autoimmune Disease Genetics Consortium (MADGC). At least two of nine "core" autoimmune diseases are present in each of these families. These core diseases include rheumatoid arthritis (RA), systemic lupus erythematosus (SLE), type 1 diabetes (T1D), multiple sclerosis (MS), autoimmune thyroid disease (Hashimoto thyroiditis or Graves disease), juvenile RA, inflammatory bowel disease (Crohn disease or ulcerative colitis), psoriasis, and primary Sjogren syndrome. We report that a recently described functional single-nucleotide polymorphism (rs2476601, encoding R620W) in the intracellular tyrosine phosphatase (PTPN22) confers risk of four separate autoimmune phenotypes in these families: T1D, RA, SLE, and Hashimoto thyroiditis. MS did not show association with the PTPN22 risk allele. These findings suggest a common underlying etiologic pathway for some, but not all, autoimmune disorders, and they suggest that MS may have a pathogenesis that is distinct from RA, SLE, and T1D. DNA and clinical data for the MADGC families are available to the scientific community; these data will provide a valuable resource for the dissection of the complex genetic factors that underlie the various autoimmune phenotypes.     

Genome-wide association studies and type 2 diabetes

In recent years, the search for genetic determinants of type 2 diabetes (T2D) has changed dramatically. Although linkage and small-scale candidate gene studies were highly successful in the identification of genes, which, when mutated, caused monogenic forms of T2D, they were largely unsuccessful when applied to the more common forms of the disease. To date, these approaches have only identified two loci (PPARG, KCNJ11) robustly implicated in T2D susceptibility. The ability to perform large-scale association analysis, including genome-wide association studies (GWAS) in many thousands of samples from different populations, and subsequently, the shift to form large international collaborations to perform meta-analyses across many studies has taken the number of independent loci showing genome-wide significant associations with T2D to 44. This number includes six loci identified initially through the analysis of quantitative glycaemic phenotypes, illustrating the usefulness of this approach both to identify new disease genes and gain insight into the mechanisms leading to disease. Combined, these loci still only account for ～10% of the observed familial clustering in Europeans, leaving much of the variance unexplained. In this review, we will describe what GWAS have taught us about the genetic basis of T2D and discuss possible next steps to uncover the remaining heritability.     

What transgenic mice tell us about neurodegenerative disease

The recent broad advance in our understanding of human neurodegenerative diseases is based on the application of a new molecular approach. Through linkage analysis, the genes responsible for Huntington's disease, the spinocerebellar ataxias, and familial forms of Alzheimer's disease and amyotrophic lateral sclerosis (ALS) have been identified and cloned. The characterization of pathogenic mutations in such genes allows the creation of informative transgenic mouse models as, without exception, the genetic forms of adult neurodegenerative disease are due to toxicity of the mutant protein. Transgenic models provide insight into the oxidative mechanisms in ALS pathogenesis, the pathogenicity of expanded polyglutamine tracts in CAG triplet repeat disorders, and amyloidogenesis in Alzheimer's disease. Although such models have their limitations, they currently provide the best entry point for the study of human neurodegenerative diseases.     

Parkinson's disease: one biochemical pathway to fit all genes?

Although originally discounted, hereditary factors have emerged as the focus of research in Parkinson's disease (PD). Genetic studies have identified mutations in alpha-synuclein and ubiquitin C-terminal hydrolase as rare causes of autosomal dominant PD and mutations in parkin as a cause of autosomal recessive PD. Functional characterization of the identified disease genes implicates the ubiquitin-mediated protein degradation pathway in these hereditary forms of PD and also in the more common sporadic forms of PD. Subsequent identification of further loci in familial PD and diverse genetic factors modulating the risk for sporadic PD point to substantial genetic heterogeneity in the disease. Thus, new candidate genes are expected to encode proteins either involved in ubiquitin-mediated protein degradation or sequestrated in intracytoplasmic protein aggregations. Future identification of disease genes is required to confirm this hypothesis, thereby unifying the clinical and genetic heterogeneity of PD, including the common sporadic form of the disease, by one biochemical pathway.     

Exome Sequencing Identifies Rare Deleterious Mutations in DNA Repair Genes FANCC and BLM as Potential Breast Cancer Susceptibility Alleles

Despite intensive efforts using linkage and candidate gene approaches, the genetic etiology for the majority of families with a multi-generational breast cancer predisposition is unknown. In this study, we used whole-exome sequencing of thirty-three individuals from 15 breast cancer families to identify potential predisposing genes. Our analysis identified families with heterozygous, deleterious mutations in the DNA repair genes FANCC and BLM, which are responsible for the autosomal recessive disorders Fanconi Anemia and Bloom syndrome. In total, screening of all exons in these genes in 438 breast cancer families identified three with truncating mutations in FANCC and two with truncating mutations in BLM. Additional screening of FANCC mutation hotspot exons identified one pathogenic mutation among an additional 957 breast cancer families. Importantly, none of the deleterious mutations were identified among 464 healthy controls and are not reported in the 1,000 Genomes data. Given the rarity of Fanconi Anemia and Bloom syndrome disorders among Caucasian populations, the finding of multiple deleterious mutations in these critical DNA repair genes among high-risk breast cancer families is intriguing and suggestive of a predisposing role. Our data demonstrate the utility of intra-family exome-sequencing approaches to uncover cancer predisposition genes, but highlight the major challenge of definitively validating candidates where the incidence of sporadic disease is high, germline mutations are not fully penetrant, and individual predisposition genes may only account for a tiny proportion of breast cancer families.