The use of genome-wide array analysis in parents whose children are suspected of having a genetic disease shows that the parents frequently also have previously undetected genetic abnormalities, a researcher from The Netherlands told the annual conference of the European Society of Human Genetics. Being aware of this is important to parents because it means that their risk of having another affected child is significantly increased.
Dr. Nicole de Leeuw, a clinical laboratory geneticist in the Department of Human Genetics of the Radboud University Nijmegen Medical Centre in Nijmegen, and colleagues performed genome-wide SNP array analysis in 6,500 patients and 1,874 parents. The patients had intellectual disability and/or congenital abnormalities, and the parents of those in whom an aberration was detected were tested in a similar way to determine whether they had the same aberration as their child. Mosaic aberrations, where both genetically normal and abnormal cells are present in an individual, were not only found in one in every 300 patients, but in one in every 270 parents as well. ‘These abnormalities occurred more frequently than we had expected’, said Dr. de Leeuw. ‘Armed with this knowledge, we can try to understand not only why, but also how genetic disease arises in individuals, and this can help us to provide better genetic counselling.’
Analysis of patients’ genomes showed 6.5% de novo (spontaneously arising) genomic imbalances, 9.1% of rare, inherited imbalances, and 0.8% of X-linked abnormalities. Moreover, with the additional data from their SNP array test results, the researchers were able to subsequently find pathogenic mutations in recessive disease genes, uniparental disomies (where a single chromosome is doubled leading to two genetically identical ones), and mosaic aneuploidies (an extra or missing chromosome in some of the cells of the body) in about 30 patients.
‘In at least seven families, these findings meant that what we had thought of as a spontaneously arising, non-inherited genetic abnormality in a child was in fact already present in some form in the parent’, said Dr. de Leeuw. ‘Furthermore, when we tested in different cell lines – for example, DNA from blood and that from a mouth swab – we often found that results varied. This is because mosaic aberrations can occur in cells in some organs and not in others, and underlines the importance of not just relying on one type of cell line for this kind of genetic diagnosis.’
In two cases these tissue-dependent differences changed over time, and the researchers believe that this was due to an attempt by the body to correct and rescue the situation. ‘Such rescue attempts are best known in cases of trisomy, where there are three chromosomes instead of two in a cell, or monosomy, where there is only one. In both these cases, the body may try to correct the situation by respectively deleting or adding (doubling) a chromosome. Such rescue mechanisms may be more common than we expected, and by using genome-wide SNP array analysis it will help us to reveal them. For some patients, it would be particularly interesting if we could test multiple samples of these patients over time’, said Dr. de Leeuw. EurekAlert

Hemimegalencephaly is a rare but dramatic condition in which the brain grows asymmetrically, with one hemisphere becoming massively enlarged. Though frequently diagnosed in children with severe epilepsy, the cause of hemimegalencephaly is unknown and current treatment is radical: surgical removal of some or all of the diseased half of the brain.
A team of doctors and scientists, led by researchers at the University of California, San Diego School of Medicine and the Howard Hughes Medical Institute, say de novo somatic mutations in a trio of genes that help regulate cell size and proliferation are likely culprits for causing hemimegalencephaly, though perhaps not the only ones.
De novo somatic mutations are genetic changes in non-sex cells that are neither possessed nor transmitted by either parent. The scientists’ findings – a collaboration between Joseph G. Gleeson, MD, professor of neurosciences and pediatrics at UC San Diego School of Medicine and Rady Children’s Hospital-San Diego; Gary W. Mathern, MD, a neurosurgeon at UC Los Angeles’ Mattel Children’s Hospital; and colleagues – suggest it may be possible to design drugs that inhibit or turn down signals from these mutated genes, reducing or even preventing the need for surgery.
Gleeson’s lab studied a group of 20 patients with hemimegalencephaly upon whom Mathern had operated, analysing and comparing DNA sequences from removed brain tissue with DNA from the patients’ blood and saliva.
‘Mathern had reported a family with identical twins, in which one had hemimegalencephaly and one did not. Since such twins share all inherited DNA, we got to thinking that there may be a new mutation that arose in the diseased brain that causes the condition,’ said Gleeson. Realising they shared the same ideas about potential causes, the physicians set out to tackle this question using new exome sequencing technology, which allows sequencing of all of the protein-coding exons of the genome at the same time.
The researchers ultimately identified three gene mutations found only in the diseased brain samples. All three mutated genes had previously been linked to cancers.
‘We found mutations in a high percentage of the cells in genes regulating the cellular growth pathways in hemimegalencephaly,’ said Gleeson. ‘These same mutations have been found in various solid malignancies, including breast and pancreatic cancer. For reasons we do not yet understand, our patients do not develop cancer, but rather this unusual brain condition. Either there are other mutations required for cancer propagation that are missing in these patients, or neurons are not capable of forming these types of cancers.’
The mutations were found in 30 percent of the patients studied, indicating other factors are involved. Nonetheless, the researchers have begun investigating potential treatments that address the known gene mutations, with the clear goal of finding a way to avoid the need for surgery.
‘Although counterintuitive, hemimegalencephaly patients are far better off following the functional removal or disconnection of the enlarged hemisphere,’ said Mathern. ‘Prior to the surgery, most patients have devastating epilepsy, with hundreds of seizures per day, completely resistant to even our most powerful anti-seizure medications. The surgery disconnects the affected hemisphere from the rest of the brain, causing the seizures to stop. If performed at a young age and with appropriate rehabilitation, most children suffer less language or cognitive delay due to neural plasticity of the remaining hemisphere.’
But a less-invasive drug therapy would still be more appealing.
‘We know that certain already-approved medications can turn down the signaling pathway used by the mutated genes in hemimegalencephaly,’ said lead author and former UC San Diego post-doctoral researcher Jeong Ho Lee, now at the Korea Advanced Institute of Science and Technology. ‘We would like to know if future patients might benefit from such a treatment. Wouldn’t it be wonderful if our results could prevent the need for such radical procedures in these children?’ EurekAlert

In a genome-wide association (GWA) study, researchers from Boston University Schools of Medicine (BUSM) and Public Health (BUSPH) have identified several genes which influence degeneration of the hippocampus, the part of the brain most associated with Alzheimer disease (AD). The study demonstrates the efficacy of endophenotypes for broadening the understanding of the genetic basis of and pathways leading to AD.
AD is a progressive neurodegenerative disorder for which there are no prevention methods. Available drugs only marginally affect disease severity and progression, making AD effectively untreatable.
GWA studies using very large samples have increased the number of robust associations to 10 genes, including APOE. However, these genes account for no more than 35 percent of the inherited risk of AD and most of the genetic underpinning of the disorder remains unexplained. According to the researchers, magnetic resonance imaging (MRI) of the brain provides in vivo quantitative measures of neurodegenerative and cerebrovascular brain injury that may represent AD-related changes long before clinical symptoms appear. These measures are more powerful than comparisons of individuals with AD with cognitively healthy persons because they avoid misclassification of normal persons who will develop disease in the future.
BUSM researchers conducted a two-stage GWA study for quantitative measures of hippocampal volume (HV), total cerebral volume (TCV) and white matter hyperintensities (WMH). Brain MRI measures of HV, TCV and WMH were obtained from 981 Caucasian and 419 African-American AD cases and their cognitively normal siblings in the MIRAGE (Multi Institutional Research in Alzheimer’s Genetic Epidemiology) Study. In addition, similar MRI measures were obtained from 168 AD cases, 336 individuals with mild cognitive impairment and 188 controls (all Caucasian) in the AD Neuroimaging Initiative (ADNI) Study. The MIRAGE Caucasian families and ADNI subjects were included in the first stage and the MIRAGE African American families were added in stage two. Results from the two Caucasians data sets were combined by meta-analysis.
In stage two, one genetic marker (i.e. single nucleotide polymorphism or SNP) from each of the gene regions that were most significantly associated with AD in the Caucasian data sets was evaluated in the African-American data set.
Novel genome-wide significant associations were observed for HV with SNPs in the APOE, F5/SELP, LHFP, and GCFC2 gene regions. All of these associations were supported by evidence in each data set.
‘Our two-stage GWAS identified highly significant associations between a measure of degeneration in the brain region most strongly correlated with AD and several genes in both Caucasian and African American samples containing AD, cognitively impaired and cognitively healthy subjects. One of these associations was with the ε4 variant of APOE which is the most well-established genetic risk factor for AD. Other associations were demonstrated with markers in F5/SELP, LHFP, and GCFC2, genes not previously implicated in this disease’ explained senior author Lindsay Farrer, PhD, chief of biomedical genetics at BUSM. He also noted, ‘previous studies showed that blood level of P-selectin (the protein encoded by SELP) has been correlated with rate of cognitive decline in AD patients.’
Farrer believes it is very likely that the number and specificity of these associations will increase in future studies using larger samples and focused on additional precise structural and functional MRI measures. ‘These findings will inform experiments designed to increase our understanding of disease-causing mechanism and may lead to new therapeutics targets,’ added Farrer. Boston University Medical Center

Mammalian spermatogenesis is maintained by spermatogonial stem cells (SSCs). However, since evidentiary assays and unequivocal markers are still missing in non-human primates and man, the identity of primate SSCs is unknown. In contrast, in the mouse, germ cell transplantation studies functionally demonstrated the presence of SSCs. LIN28 is an RNA-binding pluripotent stem cell factor, which is also strongly expressed in undifferentiated mouse spermatogonia. By contrast, two recent reports indicated that LIN28 is completely absent from adult human testes. Here, we analysed LIN28 expression in marmoset monkey (Callithrix jacchus) and human testes during development and adulthood and compared it with the mouse. In the marmoset, LIN28 was strongly expressed in migratory PGCs and gonocytes. Strikingly, we found a rare LIN28-positive subpopulation of spermatogonia also in the adult marmoset testis. This was corroborated by western blotting and quantitative RT-PCR. Importantly, in contrast to previous publications, we found LIN28-positive spermatogonia also in normal adult human and additional adult non-human primate testes. Some seasonal breeders exhibit a degenerated (involuted) germinal epithelium during their non-breeding season consisting only of Sertoli cells and SSCs. The latter re-initiate spermatogenesis prior to the next breeding-season. Fully involuted testes from a seasonal hamster and NHP (Lemur catta) exhibited numerous LIN28-positive spermatogonia, indicating a SSC-identity of the labeled cells. We conclude that LIN28 is differentially expressed in mouse and non-human primate spermatogonia and might be a marker for a rare SSC population in non-human primates and man. Further characterization of the LIN28-positive population is required. European Society of Human Reproduction and Embryology

A new genetic mutation that causes familial amyotrophic lateral sclerosis (ALS), a fatal neurological disorder also known as Lou Gehrig’s Disease, has been identified by a team of scientists led by researchers at the University of Massachusetts Medical School (UMMS). Mutations to the profilin (PFN1) gene, which is essential to the growth and development of nerve cell axons, is estimated to account for one to two percent of inherited ALS cases. The finding points to defects in a neuron’s cytoskeleton structure as a potential common feature among diverse ALS genes.
‘This discovery identifies what may possibly be a common biological mechanism involved across familial ALS cases regardless of genetics,’ said John Landers, PhD, associate professor of neurology and senior author of the study. ‘We know of at least three other ALS genes, in addition to PFN1, that adversely impact axon growth. If indeed, this is part of the disease’s mechanism, then it might also be a potential target for therapeutics.’
Robert Brown, MD, DPhil, a co-author on the study and chair of neurology at UMass Medical School, said ‘Dr. Landers has done great work in defining this new pathway for motor neuron death. We are delighted to have identified the defects in families from the U.S., Israel and France that we have been investigating for several years. Our finding is particularly exciting because it may provide new insights into ALS treatment targets.’
ALS is a progressive, neurodegenerative disorder affecting the motor neurons in the central nervous system. As motor neurons die, the brain’s ability to send signals to the body’s muscles is compromised. This leads to loss of voluntary muscle movement, paralysis and eventually respiratory failure. The cause of most cases of ALS is not known. Approximately 10 percent of cases are inherited. Though investigators at UMass Medical School and elsewhere have identified several genes shown to cause inherited or familial ALS, almost 50 percent of these cases have an unknown genetic cause.
The current study details the discovery of the PFN1 gene mutation among two large ALS families. Both families were negative for known ALS-causing mutations and displayed familial relationships that suggested a dominant inheritance mode for the disease. For each family, two affected members with maximum genetic distance were selected for deep DNA sequencing. To identify an ALS-causing mutation, genetic variations between the family members were identified and screened against known databases of human genetic variation, such as the 1000 Genomes Project. This narrowed down the resulting number of candidate, ALS-causing mutations to two within the first family and three within the second. Interestingly, both families contained different mutations within the same gene – PFN1, the likely causative mutation. With additional screening, the team documented that in a total of 274 families sequenced, seven contained a mutation to the PFN1 gene, establishing it as a likely cause for ALS.
While it is not certain how the PFN1 mutation causes ALS, the cellular functions it controls within the motor neurons are responsible for regulation of a number of activities, including the growth and development of the axon, the slender projection through which neurons transmit electrical impulses to neighboring cells, such as muscle. When introduced into motor neuron cells, normal PFN1 protein was found diffused throughout the cytoplasm. Conversely, the mutant PFN1 observed in ALS patients was found to collect in dense aggregates, keeping it from functioning properly. Motor neurons producing mutated PFN1 showed markedly shorter axon outgrowth.
‘The discovery that mutant PFN1 interferes with axon outgrowth was very exciting to us,’ said Claudia Fallini, PhD, a postdoctoral researcher at Emory University School of Medicine who collaborated with the UMass Medical School authors to investigate PFN1’s functions in cultured motor neurons. ‘It suggests that alterations in actin dynamics may be an important mechanism at the basis of motor neuron degeneration.’
‘In healthy neurons, PFN1 acts almost like a railroad tie for fibrous filaments called actin, which make up the axon’ said Landers. ‘PFN1 helps bind these filaments to each other, promoting outgrowth of the axon. Without properly functioning PFN1 these filaments can’t come together. Here we show that mutant PFN1 may contribute to ALS pathogeneses by accumulating in these aggregates and altering the actin dynamics in a way that inhibits axon outgrowth.’ EurekAlert