Penetrance of Hypertrophic Cardiomyopathy in At-Risk Children and Young Adults

Meyer, Tyler J.

January 2018

No description available.

Genetics

Hypertrophic Cardiomyopathy

Penetrance

Pediatrics

Genetic Testing

Autosomal Dominant

Amyotrophic lateral sclerosis (ALS) associated with superoxide dismutase 1 (SOD1) mutations in British Columbia, Canada : clinical, neurophysiological and neuropathological features

Stewart, Heather G.

January 2005

Amyotrophic lateral sclerosis (ALS) is a neurodegenerative disorder characterized by loss of motor neurons and their supporting cells in the brain, brainstem and spinal cord, resulting in muscle paresis and paralysis including the bulbar (speech, chewing, swallowing) and respiratory muscles. The average age at onset is 55 years, and death due to respiratory failure occurs 2-5 years after symptom onset in ~ 85% of cases. Five to 10% of ALS is familial, and about 20% of familial cases are associated with mutations in the superoxide dismutase 1 (SOD1) gene. To date, 118 SOD1 mutations have been reported worldwide (www alsod.org). All are dominantly inherited, except for the D90A mutation, which is typically recessively inherited. D90A homozygous ALS is associated with long (~14 years) survival, and some atypical symptoms and signs. The reason for this is not known. In contrast, most other SOD1 mutations are associated with average survival, while some are associated with aggressive disease having lower motor neuron predominance and survival less than 12 months. The A4V mutation, which is the most frequently occurring SOD1 mutation in the United States, is an example of the latter. Understanding the pathogenic mechanisms of SOD1 mutants causing widely different disease forms like D90A and A4V is of paramount importance. Overwhelming scientific evidence indicates that mutations in the SOD1 gene are cytotoxic by a “gain of noxious” function, which although not fully understood results in protein aggregation and loss of cell function. This thesis explores different ALS-SOD1 gene mutations in British Columbia (BC), Canada. Two hundred and fifty-three ALS patients were screened for SOD1 mutations, and 12 (4.7%) unrelated patients were found to carry one of 5 different SOD1 mutations: A4V (n=2); G72C (n=1); D76Y (n=1); D90A (n=2); and 113T (n=6). Incomplete penetrance was observed in 3/12 families. Bulbar onset disease was not observed in the SOD1 mutation carriers in this study, but gender distribution was similar to previously reported studies. Age at symptom onset for all patients enrolled, with or without SOD1 mutations, was older than reported in previous studies. On average, patients with SOD1 mutations experience a longer diagnostic delay (22.6 months) compared to patients without mutations (12 months). Two SOD1 patients were originally misdiagnosed including the G72C patient who’s presenting features resembled a proximal myopathy. Neuropathological examination of this patient failed to reveal upper motor neuron disease. The I113T mutation was associated with variable age of onset and survival time, and was found in 2 apparently sporadic cases. The D76Y mutation was also found in an apparently sporadic case. I113T and D76Y are likely influenced by other genetic or environmental factors in some individuals. Two patients were homozygous for the D90A mutation, with clinical features comparable to patients originally described in Scandinavia. Clinical and electrophysiological motor neuron abnormalities were observed in heterozygous relatives of one D90A homozygous patient. The A4V patients were similar to those described in previous studies, although one had significant upper motor neuron disease both clinically and neuropathologically. Clinical neurophysiology is essential in the diagnosis of ALS, and helpful in monitoring disease progression. A number of transcranial magnetic stimulation (TMS) studies may detect early dysfunction of upper motor neurons when imaging techniques lack sensitivity. Peristimulus time histograms (PSTHs), which assess corticospinal function via recording of voluntarily activated single motor units during low intensity TMS of the motor cortex, were used to study 19 ALS patients having 5 different SOD1 mutations (including 8 of the 12 patients identified with SOD1 mutations from BC). Results were compared with idiopathic ALS cases, patients with multiple sclerosis (MS), and healthy controls. Significant differences were found in corticospinal pathophysiology between ALS patients with SOD1 mutations, idiopathic ALS, and MS patients. In addition, different SOD1 mutants were associated with significantly different neurophysiologic abnormalities. D90A homozygous patients show preserved if not exaggerated cortical inhibition and slow central conduction, which may reflect the more benign disease course associated with this mutant. In contrast, A4V patients show cortical hyper-excitability and only slightly delayed central conduction. I113T patients display a spectrum of abnormalities. This suggests mutant specific SOD1 pathology(s) of the corticospinal pathways in ALS.

ALS

SOD1

complete penetrance

incomplete penetrance

mis-diagnosis

upper motor neuron

clinical neurophysiology

transcranial magnetic stimulation

peristimulus time histogram

corticospinal pathway

cortical inhibition

cortical hyper-excitability

Finding new genes causing motor neuron diseases

Gopinath, Sumana

January 2007

Doctor of Philosophy / Abstract Neurodegenerative disorders are a diverse group of disorders that affect specific subsets of neurons. Motor neuron diseases, neurodegenerative disorders of motor neurons, are seen commonly as sporadic cases and less frequently as familial disease forms. The familial forms show genetic and phenotypic heterogeneity. Clinically motor neuron diseases may be seen as rapidly progressive disorders like amyotrophic lateral sclerosis, ALS or slowly progressive disorders like hereditary motor neuropathies, HMN. The only proven causes for motor neuron diseases are gene mutations that lead to motor neuron degeneration in familial disease forms. Only some of these genes have been identified and have contributed greatly to our understanding of the neurobiology of familial and sporadic disease forms. Identification of additional disease causing genes would help enhance our knowledge of the pathophysiological mechanisms underlying all forms of motor neuron disorders, which would lead to early diagnoses, effective prophylaxis and efficient therapies for these disorders. This study aimed to find gene mutations that cause rapid and slowly progressive familial motor neuron disorders in Australian families and to determine their relevance to sporadic forms of motor neuron disease. The familial forms of ALS show reduced disease penetrance, that is, not all gene mutation carriers manifest the disease. This study examines ALS penetrance in a group of Australian families. The most frequently observed mutations in ALS families are cytosolic superoxide dismutase/SOD1 gene mutations. In a collection of ALS families in our centre, families without the common SOD1 gene mutations were genotyped for other ALS genes and loci and studied using genetic linkage and haplotype analyses. Studies in a large Australian ALS family further confirmed genetic heterogeneity in non-SOD familial ALS, all known autosomal dominant ALS genes and chromosomal loci were excluded as cause of disease in this family. Such families can be studied further to identify additional disease genes and loci mapped in other ALS families. These families represent powerful resources for identification of additional ALS genes. Identifying the pathogenic genes in families with reduced disease penetrance may be more relevant to sporadic forms of disease. dHMN is a chronic neurodegenerative disorder predominantly affecting motor neurons. In a large Australian dHMN family, all the known dHMN genes and chromosomal loci were excluded as cause of disease. A genome wide microsatellite screen was performed in this family and genetic linkage was established to a novel 12.98 Mb locus on chromosome 7q34.2-q36. Candidate genes in this large interval will be screened based on their function and expression profile. Identification of a new dHMN locus provides the basis for future identification of a novel gene involved in motor neuron degeneration. Genes in dHMN have been shown to be pathogenic in ALS and Charcot Marie Tooth syndromes. The new locus for dHMN mapped in this project would lead to identification of a novel dHMN gene, which may elucidate the pathogenesis underlying a wide range of neurodegenerative disorders.

linkage

motor neuron disease, MND

Amyotrophic lateral sclerosis, ALS

Hereditary motor neuropathy, HMN

incomplete penetrance

Characterization of AtSUVR3 functions in Arabidopsis thaliana using RNA interference

Wang, Tao

15 May 2009

Variability of transgene expression levels resulting from gene silencing is considered as ahindrance to the successful application of plant genetic engineering. Towards alleviatinggene silencing, I decided to screen for novel genes involved in transgene silencing and toinvestigate how these genes regulate plant development. Genes encoding putative chromatinremodeling factors, especially those including a SET domain, were selected as candidatetargets. A bioinformatic analysis of the Arabidopsis SET genes (AtSET) was performed andthese genes were classified into 6 groups based on the domain architecture. RNA interference (RNAi) vectors were constructed for ~ 20 AtSET genes and wereintroduced into both wild type lines and transgenic lines silenced for a GFP reporter gene.Surprisingly, altered developmental phenotypes were only observed for three constructs,raising questions as to the effectiveness of the RNAi approach for the chosen Arabidopsissystem. To assess this situation, I targeted a phytoene desaturase (PDS) gene using the sameRNAi approach. Inactivation of PDS renders plant a readily identifiable phenotype. Whereasthe RNAi penetrance in Arabidopsis can be very high, the expressivity of RNAi in varioustissues and among different plants can vary dramatically. Contradictory to previous reports,I found that there is correlation between transcript level and silencing phenotype. Possiblereasons for this discrepancy are discussed. No apparent correlation between transgene copynumber and RNAi phenotypes was observed. Among the three RNAi constructs that caused an abnormal development inArabidopsis, K-23 which targets SuvR3 has the highest expressivity and could reactivate asilenced GFP locus. SuvR3 RNAi lines were selfed for six generations and were screenedfor morphological phenotypes. Abnormal number of flower organs, loss of viability of malegametophytes, and decreased seedling germination percentage were found in SuvR3 RNAilines. A progressive increase in both severity and frequency of abnormal phenotypes wereseen in subsequent generations, suggesting an epigenetic regulatory mechanism involvedwith SuvR3. Alternative splicing of SuvR3 was also observed in most of Arabidopsis tissues.One of the protein isoforms, SuvR3, lacks 16 amino acids within the highly conserved SETdomain. Possible effects of isoform interaction are proposed.

RNA interference

RNAi penetrance

RNAi expressivity

gene silencing

SET domain

alternative splicing

The Consequences of stochastic gene expression in the nematode Caenorhabditis elegans

Burga Ramos, Alejandro Raúl, 1985-

20 July 2012

Genetically identical cells and organisms growing in homogenous environmental conditions can show significant phenotypic variation. Furthermore, mutations often have consequences that vary among individuals (incomplete penetrance). Biochemical processes such as those involved in gene expression are subjected to fluctuations due to their inherent probabilistic nature. However, it is not clear how these fluctuations affect multicellular organisms carrying mutations and if stochastic variation in gene expression among individuals could confer any advantage to populations. We have investigated the consequences of stochastic gene expression using the nematode Caenorhabditis elegans as a model. Here we show that inter-individual stochastic variation in the induction of both specific and more general buffering systems combine to determine the outcome of inherited mutations in each individual. Also, we demonstrate that genetic and environmental robustness are coupled in C. elegans. Individuals with higher induction of stress response are more robust to the effect of mutations, however they incur a fitness cost, thus suggesting that variation at the population level could be beneficial in unpredictable environments. / Células y organismos genéticamente idénticos y creciendo en un ambiente homogéneo pueden mostrar diferencias en sus fenotipos. Además, una misma mutación puede afectar de un modo distinto a individuos de una misma población. Es sabido que los procesos bioquímicos responsables de la expresión de genes están sujetos a fluctuaciones debido a su inherentemente naturaleza probabilística. Sin embargo, el rol que juegan estas fluctuaciones en individuos portadores de mutaciones ha sido poco estudiado, así cómo si la expresión estocástica de genes puede conferir alguna ventaja al nivel poblacional. Para investigar las consecuencias de la expresión estocástica de genes usamos como modelo al nemátodo Caenorhabditis elegans. En este trabajo demostramos que existe variación entre individuos en la inducción de mecanismos (tanto gen-específicos como globales) que confieren robustez al desarrollo. En consecuencia, diferencias fenotípicas entre mutantes están determinadas por su variación. También, demostramos que la robustez a perturbaciones genéticos y ambientales están estrechamente ligadas en C. elegans. Individuos que inducen estocásticamente una mayor respuesta a stress, están fenotípicamente mejor protegidos al efecto de mutaciones pero incurren en un costo reproductivo importante. Eso sugiere, que variaciones estocásticas al nivel poblacional pueden ser benéficas cuando las poblaciones afrontan ambientes impredecibles.

Caenorhabditis elegans

Stochastic gene expression

Genetics

Incomplete penetrance

Redundancy

Robustness

Evolution

575

Characterization of AtSUVR3 functions in Arabidopsis thaliana using RNA interference

Wang, Tao

15 May 2009

Variability of transgene expression levels resulting from gene silencing is considered as ahindrance to the successful application of plant genetic engineering. Towards alleviatinggene silencing, I decided to screen for novel genes involved in transgene silencing and toinvestigate how these genes regulate plant development. Genes encoding putative chromatinremodeling factors, especially those including a SET domain, were selected as candidatetargets. A bioinformatic analysis of the Arabidopsis SET genes (AtSET) was performed andthese genes were classified into 6 groups based on the domain architecture. RNA interference (RNAi) vectors were constructed for ~ 20 AtSET genes and wereintroduced into both wild type lines and transgenic lines silenced for a GFP reporter gene.Surprisingly, altered developmental phenotypes were only observed for three constructs,raising questions as to the effectiveness of the RNAi approach for the chosen Arabidopsissystem. To assess this situation, I targeted a phytoene desaturase (PDS) gene using the sameRNAi approach. Inactivation of PDS renders plant a readily identifiable phenotype. Whereasthe RNAi penetrance in Arabidopsis can be very high, the expressivity of RNAi in varioustissues and among different plants can vary dramatically. Contradictory to previous reports,I found that there is correlation between transcript level and silencing phenotype. Possiblereasons for this discrepancy are discussed. No apparent correlation between transgene copynumber and RNAi phenotypes was observed. Among the three RNAi constructs that caused an abnormal development inArabidopsis, K-23 which targets SuvR3 has the highest expressivity and could reactivate asilenced GFP locus. SuvR3 RNAi lines were selfed for six generations and were screenedfor morphological phenotypes. Abnormal number of flower organs, loss of viability of malegametophytes, and decreased seedling germination percentage were found in SuvR3 RNAilines. A progressive increase in both severity and frequency of abnormal phenotypes wereseen in subsequent generations, suggesting an epigenetic regulatory mechanism involvedwith SuvR3. Alternative splicing of SuvR3 was also observed in most of Arabidopsis tissues.One of the protein isoforms, SuvR3, lacks 16 amino acids within the highly conserved SETdomain. Possible effects of isoform interaction are proposed.

RNA interference

RNAi penetrance

RNAi expressivity

gene silencing

SET domain

alternative splicing

Finding new genes causing motor neuron diseases

Gopinath, Sumana

January 2007

Doctor of Philosophy / Abstract Neurodegenerative disorders are a diverse group of disorders that affect specific subsets of neurons. Motor neuron diseases, neurodegenerative disorders of motor neurons, are seen commonly as sporadic cases and less frequently as familial disease forms. The familial forms show genetic and phenotypic heterogeneity. Clinically motor neuron diseases may be seen as rapidly progressive disorders like amyotrophic lateral sclerosis, ALS or slowly progressive disorders like hereditary motor neuropathies, HMN. The only proven causes for motor neuron diseases are gene mutations that lead to motor neuron degeneration in familial disease forms. Only some of these genes have been identified and have contributed greatly to our understanding of the neurobiology of familial and sporadic disease forms. Identification of additional disease causing genes would help enhance our knowledge of the pathophysiological mechanisms underlying all forms of motor neuron disorders, which would lead to early diagnoses, effective prophylaxis and efficient therapies for these disorders. This study aimed to find gene mutations that cause rapid and slowly progressive familial motor neuron disorders in Australian families and to determine their relevance to sporadic forms of motor neuron disease. The familial forms of ALS show reduced disease penetrance, that is, not all gene mutation carriers manifest the disease. This study examines ALS penetrance in a group of Australian families. The most frequently observed mutations in ALS families are cytosolic superoxide dismutase/SOD1 gene mutations. In a collection of ALS families in our centre, families without the common SOD1 gene mutations were genotyped for other ALS genes and loci and studied using genetic linkage and haplotype analyses. Studies in a large Australian ALS family further confirmed genetic heterogeneity in non-SOD familial ALS, all known autosomal dominant ALS genes and chromosomal loci were excluded as cause of disease in this family. Such families can be studied further to identify additional disease genes and loci mapped in other ALS families. These families represent powerful resources for identification of additional ALS genes. Identifying the pathogenic genes in families with reduced disease penetrance may be more relevant to sporadic forms of disease. dHMN is a chronic neurodegenerative disorder predominantly affecting motor neurons. In a large Australian dHMN family, all the known dHMN genes and chromosomal loci were excluded as cause of disease. A genome wide microsatellite screen was performed in this family and genetic linkage was established to a novel 12.98 Mb locus on chromosome 7q34.2-q36. Candidate genes in this large interval will be screened based on their function and expression profile. Identification of a new dHMN locus provides the basis for future identification of a novel gene involved in motor neuron degeneration. Genes in dHMN have been shown to be pathogenic in ALS and Charcot Marie Tooth syndromes. The new locus for dHMN mapped in this project would lead to identification of a novel dHMN gene, which may elucidate the pathogenesis underlying a wide range of neurodegenerative disorders.

linkage

motor neuron disease, MND

Amyotrophic lateral sclerosis, ALS

Hereditary motor neuropathy, HMN

incomplete penetrance

<em>TOPBP1</em>, <em>CLSPN</em> and <em>PALB2</em> genes in familial breast cancer susceptibility

Erkko, H. (Hannele)

09 December 2008

Abstract The currently known susceptibility genes account for approximately 25% of familial breast cancer predisposition. Additional factors contributing to the pathogenesis of breast cancer are, therefore, likely to be discovered. Most of the known genes affecting breast cancer predisposition function in the DNA damage response pathway. In this study three genes, TOPBP1, CLSPN and PALB2, involved in this complex process were investigated to reveal potentially pathogenic mutations associated with breast cancer susceptibility. In the analysis of the TOPBP1 gene, one novel putative pathogenic alteration was observed. The Arg309Cys variant was found at an elevated frequency among familial cases (19/125) vs. controls (49/697) (p = 0.002; OR 2.4; 95% CI 1.3–4.2). In addition, altogether 18 other germline alterations were observed in this gene, but they all appeared to be harmless polymorphisms. Investigation of CLSPN alterations among familial breast cancer families revealed altogether seven different changes. No clearly pathogenic alterations were observed. However, a potential modifier effect was discovered for the 1195delGlu change. The obtained results suggest that CLSPN alterations are unlikely to be significant breast cancer susceptibility alleles. In the PALB2 gene, a pathogenic mutation c.1592delT was identified at an elevated frequency among breast cancer patients (0.9%) compared to controls (0.2%) (p = 0.003, OR 3.94, 95% CI 1.5–12.1). Among familial cases the frequency of c.1592delT was even higher (2.7%). This mutation was also functionally deficient. It had a markedly decreased BRCA2-binding affinity and was unable to support homologous recombination or to restore cross link repair in PALB2 knock-down cells. Additionally, this mutation was discovered in a familial prostate cancer family and was found to segregate with the disease, suggesting some association also with prostate cancer. The penetrance and hazard ratio associated with PALB2 c.1592delT were determined in unselected breast cancer families. A substantially increased risk of breast cancer (HR 6.1; 95% CI 2.2–17.2; p = 0.01) was discovered resulting in an estimated 40% (95% CI 17–77) breast cancer risk by age 70 years, comparable to that for carriers of BRCA2 mutations. This markedly increased cancer risk suggests that genetic counselling for carriers is needed and screening for this mutation should be considered.

CLSPN

Genetic predisposition to disease

PALB2

TOPBP1

breast neoplasms

mutation

penetrance

Factors that Influence the Management Recommendations Breast Surgeons Provide to Women with Pathogenic Variants in Moderate Penetrance Breast Cancer Susceptibility Genes

Vanderwal, April

15 June 2020

No description available.

Genetics

Recommendations

Moderate Penetrance Genes

Hereditary Cancer Syndrome

Surgeon

Breast Cancer

Genetic Predisposition

Modulations of Sodium Channel Long QT and Brugada Syndrome Mutations by a Common Sodium Channel Polymorphism

Shinlapawittayatorn, Krekwit

31 January 2012

No description available.

Biomedical Research

Sodium channel

long QT syndrome

brugada syndrome

arrhythmias

polymorphism

incomplete penetrance