Homozygous Null Mutation Research Articles

Abstract 18321: Analysis of a Consanguineous Cohort to Identify and Characterize Human Knockouts

Background: Experimental disruption of both gene copies (“knockout”) in model organisms has proven useful to understand gene function. Identification of “human knockouts” (i.e., individuals in which null mutations disrupt both copies of a given gene) should therefore provide valuable insights to a gene function that could be of direct relevance to humans. Objective and Methods: We leverage naturally-occurring null mutations and consanguinity in the human population in order to: 1) identify humans knocked out for genes; and 2) characterize the phenotypic consequences of complete gene disruption. We performed whole-exome sequencing in 7,078 individuals living in Pakistan, a region of the world with high levels of consanguinity, and tested whether knockouts differed from wild-type participants across a range of >200 cardiometabolic traits. Results: Median length of genome-wide homozygosity among Pakistani participants was 6-7 times higher than participants of European (CEU, TSI), East Asian (CHB, JPT, CHD) and African ancestries (YRI, MKK), respectively. In Pakistanis, we were able to enumerate 47,656 mutations predicted to be null (nonsense, frameshift, or canonical splice-site); variants were further filtered based on MAF, transcript position, splice sites, and conservation to identify 36,850 “high-confidence” null mutations across 12,131 autosomal genes. Across all participants, 961 distinct genes were completely disrupted by homozygous null mutations. 1,306 participants (18.4%) had at least one gene knocked out. In a phenotypic screen, homozygosity for null mutations at APOC3 was associated with absent plasma apolipoprotein C-III levels; at PLAG27 , with absent enzymatic activity of lipoprotein-associated phospholipase A2 in the blood; at CYP2F1 , with higher plasma interleukin-8 concentrations; and at either A3GALT2 or NRG4 , with markedly reduced plasma insulin C-peptide concentrations. After physiologic challenge with oral fat, APOC3 knockouts, when compared to wild-type family members, displayed marked blunting of the usual post-prandial rise in plasma triglycerides. Conclusion: These observations provide a roadmap to understand the consequences of complete disruption of a large fraction of genes in the human genome.

Lipin1 Regulates Skeletal Muscle Differentiation through Extracellular Signal-regulated Kinase (ERK) Activation and Cyclin D Complex-regulated Cell Cycle Withdrawal

Lipin1, an intracellular protein, plays critical roles in controlling lipid synthesis and energy metabolism through its enzymatic activity and nuclear transcriptional functions. Several mouse models of skeletal muscle wasting are associated with lipin1 mutation or altered expression. Recent human studies have suggested that children with homozygous null mutations in the LPIN1 gene suffer from rhabdomyolysis. However, the underlying pathophysiologic mechanism is still poorly understood. In the present study we examined whether lipin1 contributes to regulating muscle regeneration. We characterized the time course of skeletal muscle regeneration in lipin1-deficient fld mice after injury. We found that fld mice exhibited smaller regenerated muscle fiber cross-sectional areas compared with wild-type mice in response to injury. Our results from a series of in vitro experiments suggest that lipin1 is up-regulated and translocated to the nucleus during myoblast differentiation and plays a key role in myogenesis by regulating the cytosolic activation of ERK1/2 to form a complex and a downstream effector cyclin D3-mediated cell cycle withdrawal. Overall, our study reveals a previously unknown role of lipin1 in skeletal muscle regeneration and expands our understanding of the cellular and molecular mechanisms underlying skeletal muscle regeneration.

ALMS1 null mutations: a common cause of Leber congenital amaurosis and early-onset severe cone-rod dystrophy.

In our previous studies, mutations in known candidate genes were detected in approximately 50% of Chinese patients with various forms of retinal degeneration. The next stage, identifying additional causative mutations in patients with various forms of genetic eye diseases based on whole exome sequencing of 1220 samples, revealed frequent homozygous or compound heterozygous null mutations in ALMS1, which are known to associate with Alström syndrome as well as individuals diagnosed with Leber congenital amaurosis (LCA) or early-onset severe cone-rod dystrophy (CORD) without signs of systemic phenotypes except that one had a congenital heart abnormity. Sanger sequencing, co-segregation analysis and analysis of normal individuals identified a total of 13 null mutations in ALMS1 in 11 probands, including 4 probands with homozygous mutations and 7 with compound heterozygous mutations. Follow-up examinations revealed absent or mild systemic manifestations of Alström syndrome in those available: 9 of 15 patients in 11 families. These findings not only expand the spectrum of phenotypes associated with ALMS1 mutations but also suggest that ALMS1 should be regarded as a candidate causative gene in patients diagnosed with isolated LCA and early-onset severe CORD.

Testicular Steroidogenic Cells to the Rescue

In this issue of Endocrinology, Padua et al (1) characterize the phenotype of mice lacking both GATA4 and GATA6 in steroidogenic cells. The double-mutant mice are born with adrenal aplasia. The female pups die from adrenocortical insufficiency, but the males survive owing to ectopic corticoid production by adrenal-like cells in the testis. These mutant mice shed new light on the regulation of steroidogenic cell differentiation and may provide a model for the study of testicular adrenal rest tumors (TARTs). Steroidogenic cells in the adrenal cortex and testis arise from a common pool of progenitors in the adrenogonadal primordium (AGP), a specialized group of coelomic epithelial cells in the urogenital ridge (Figure 1) (2). Adrenocortical progenitors migrate medially and combine with sympathoblasts, the precursors of the medulla, to form the nascent adrenal gland, which begins to produce glucocorticoids and other steroids (3). Gonadal progenitors migrate laterally and combine with primordial germ cells to form the bipotential gonad. Expression of Sry in the male gonad triggers the differentiation of Sertoli cells, which nurture germ cells and secrete paracrine factors that promote the differentiation of steroidogenic Leydig cells (4). In addition to producing T that is crucial for masculinization of the male fetus, fetal Leydig cells secrete insulin like-3, a hormone that promotes testicular descent (5). The common developmental origin of the adrenal cortex and testis is reflected in overlapping functional profiles for these organs. For example, the testes of newborn mice contain interstitial cells that express adrenocortical differentiation markers (eg, Cyp21a1, Cyp11b1), and ACTH stimulates androgen and glucocorticoid production by this tissue (6–8). Conversely, the adrenal gland of the adult mouse harbors rare stem/progenitor cells that can differentiate into gonadal-like cells in response to the hormonal changes that accompany gonadectomy (9–11). Among the plethora of transcription factors implicated in the differentiation of adrenal or testicular steroidogenic cells, a few are indispensable (3, 12). The prototype of these is steroidogenic factor-1 (SF1; also called Ad4BP or NR5A1). Sf1 is expressed in the AGP, adrenocortical cells, Sertoli cells, and Leydig cells. Mice lacking SF1 exhibit defects in both adrenal and testicular development (13, 14). Because SF1 is expressed in all steroidogenic tissues, it cannot by itself account for functional differences between steroid-producing cells in the adrenal cortex and testis. Two members of the GATA transcription factor family, GATA4 and GATA6, also regulate steroidogenesis and have been shown to impact the balance between adrenal and gonadal differentiation (11). During fetal mouse development, Gata4 and Gata6 are coexpressed in adrenocortical cells, Sertoli cells, and Leydig cells (15, 16). After birth, Gata6 expression persists in the adrenal cortex and testis, but Gata4 expression wanes in the adrenal gland (15, 16). Mice harboring germline homozygous null mutations in either Gata4 or Gata6 die early in embryonic development, so Cre-LoxP technology has been used to investigate the roles of GATA4 and GATA6 in steroidogenic tissues (15). These studies have shown that GATA4 is required for genital ridge development, testicular morphogenesis, and fetal/adult Sertoli cell function (17–19). In contrast, loss of GATA6 in steroidogenic cells mainly impacts adrenocortical zonation and function (20). As detailed in this issue of Endocrinology, combined loss of GATA4 and GATA6

Congenital hypofibrinogenemia associated with novel homozygous fibrinogen Aα and heterozygous Bβ chain mutations

We report the molecular characterisation of two novel cases of inherited hypofibrinogenemia. After sequencing all coding regions and intron-exon boundaries of the three fibrinogen genes (FGA, FGB, and FGG), two different novel mutations were found, one homozygous and one heterozygous. The first patient, with a mild bleeding history and mild discrepancy between functional and immunological fibrinogen, showed a novel homozygous nonsense mutation in exon 5 of FGA (p.Trp373*, p.Trp354* according to the mature protein) caused by a G>A transition at nucleotide position 1,119. The resulting truncation in the Aα chain is likely to reduce the efficiency of fibrinogen assembly and secretion. The second patient, referred after ischemic stroke (functional fibrinogen 77mg/dL), had a novel heterozygous splicing mutation in intron 5 of FGB (IVS5+2T>A or c.832+2T>A), which we demonstrated to cause either exon 5 skipping or the inclusion of 75bp belonging to intron 5. Neither splicing defect alters the reading frame: one results in a 38-residue deletion and the other in a 25-residue insertion in the D domain of fibrinogen Bβ chain. This report confirms that genetically determined partial deficiencies of fibrinogen with levels greater than 50mg/dL are rarely associated with significant bleeding symptoms and that homozygous null mutations removing a significant portion of the Aα chain may be associated with mild fibrinogen deficiency.

An Rtf2 Domain-Containing Protein Influences Pre-mRNA Splicing and Is Essential for Embryonic Development in Arabidopsis thaliana.

Alternative splicing is prevalent in plants, but little is known about its regulation in the context of developmental and signaling pathways. We describe here a new factor that influences pre-messengerRNA (mRNA) splicing and is essential for embryonic development in Arabidopsis thaliana. This factor was retrieved in a genetic screen that identified mutants impaired in expression of an alternatively spliced GFP reporter gene. In addition to the known spliceosomal component PRP8, the screen recovered Arabidopsis RTF2 (AtRTF2), a previously uncharacterized, evolutionarily conserved protein containing a replication termination factor 2 (Rtf2) domain. A homozygous null mutation in AtRTF2 is embryo lethal, indicating that AtRTF2 is an essential protein. Quantitative RT-PCR demonstrated that impaired expression of GFP in atrtf2 and prp8 mutants is due to inefficient splicing of the GFP pre-mRNA. A genome-wide analysis using RNA sequencing indicated that 13-16% of total introns are retained to a significant degree in atrtf2 mutants. Considering these results and previous suggestions that Rtf2 represents an ubiquitin-related domain, we discuss the possible role of AtRTF2 in ubiquitin-based regulation of pre-mRNA splicing.

New cardiac and skeletal protein aggregate myopathy associated with combined MuRF1 and MuRF3 mutations.

Protein aggregate myopathies (PAMs) define muscle disorders characterized by protein accumulation in muscle fibres. We describe a new PAM in a patient with proximal muscle weakness and hypertrophic cardiomyopathy, whose muscle fibres contained inclusions containing myosin and myosin-associated proteins, and aberrant distribution of microtubules. These lesions appear as intact A- and M-bands lacking thin filaments and Z-discs. These features differ from inclusions in myosin storage myopathy (MSM), but are highly similar to those in mice deficient for the muscle-specific RING finger proteins MuRF1 and MuRF3. Sanger sequencing excluded mutations in the MSM-associated gene MYH7 but identified mutations in TRIM63 and TRIM54, encoding MuRF1 and MuRF3, respectively. No mutations in other potentially disease-causing genes were identified by Sanger and whole exome sequencing. Analysis of seven family members revealed that both mutations segregated in the family but only the homozygous TRIM63 null mutation in combination with the heterozygous TRIM54 mutation found in the proband caused the disease phenotype. Both MuRFs are microtubule-associated proteins localizing to sarcomeric M-bands and Z-discs. They are E3 ubiquitin ligases that play a role in degradation of sarcomeric proteins, stabilization of microtubules and myogenesis. Lack of ubiquitin and the 20S proteasome subunit in the inclusions found in the patient suggested impaired turnover of thick filament proteins. Disruption of microtubules in cultured myotubes was rescued by transient expression of wild-type MuRF1. The unique features of this novel myopathy point to defects in homeostasis of A-band proteins in combination with instability of microtubules as cause of the disease.

Novel C8orf37 mutations cause retinitis pigmentosa in consanguineous families of Pakistani origin.

To investigate the molecular basis of retinitis pigmentosa in two consanguineous families of Pakistani origin with multiple affected members. Homozygosity mapping and Sanger sequencing of candidate genes were performed in one family while the other was analyzed with whole exome next-generation sequencing. A minigene splicing assay was used to confirm the splicing defects. In family MA48, a novel homozygous nucleotide substitution in C8orf37, c.244-2A>C, that disrupted the consensus splice acceptor site of exon 3 was found. The minigene splicing assay revealed that this mutation activated a cryptic splice site within exon 3, causing a 22 bp deletion in the transcript that is predicted to lead to a frameshift followed by premature protein truncation. In family MA13, a novel homozygous null mutation in C8orf37, c.555G>A, p.W185*, was identified. Both mutations segregated with the disease phenotype as expected in a recessive manner and were absent in 8,244 unrelated individuals of South Asian origin. In this report, we describe C8orf37 mutations that cause retinal dystrophy in two families of Pakistani origin, contributing further data on the phenotype and the spectrum of mutations in this form of retinitis pigmentosa.

Auxin Binding Protein 1 (ABP1): a matter of fact.

Science is a global community enterprise.Collectively,we contribute to building the knowledge tower by using bricks and mortar that should be strong,solid,and long lasting.A brick with defects may lead this tower,or a part there of,to collapse.When that happens,the community suffers,laying waste countless dedicated hours of work,especially by students and postdoctoral scholars.This is the reason ary

Generation of a conditional knockout allele for the NFAT5 gene in mice.

The osmosensitive transcription factor nuclear factor of activated T-cells 5 (NFAT5), also known as tonicity enhancer element binding protein (TonEBP) plays a crucial role in protection of renal medullary cells against hyperosmotic stress, urinary concentration, the adaptive immune response, and other physiological systems. Since it is also important for development, conventional homozygous-null mutations result in perinatal death, which hinders the analysis of NFAT5 function in specific tissues in vivo. Here we describe the generation of mice with a conditional-null allele, in which loxP sites are inserted around exon 4. Mice harboring the floxed allele (NFAT5flx) were mated to a strain expressing a tamoxifen-inducible derivative of the Cre-recombinase (Cre+) under the control of the ubiqitinC promoter. The resultant homozygous conditional knockout mice (Cre+ NFAT5flx/flx) are viable, fertile, and show normal expression of NFAT5 and NFAT5 target genes, indicating that the conditional alleles retain their wild-type function. Induction of Cre-mediated recombination by administration of tamoxifen in 8-week-old mice resulted in a decrease in NFAT5 expression of about 70–90% in all tested tissues (renal cortex, renal outer medulla, renal inner medulla, heart, lung, spleen, skeletal muscle). Accordingly, the expression of the NFAT5 target genes aldose reductase and heat shock protein 70 in the renal medulla was also significantly decreased. Mice harboring this conditional knockout allele should be useful in future studies for gaining a better understanding of tissue and cell-type specific functions of NFAT5 in adult animals under physiological and pathophysiological conditions.

Impact of glutathione S-transferase M1 and T1 on anti-tuberculosis drug-induced hepatotoxicity in Chinese pediatric patients.

BackgroundAnti-tuberculosis drug induced hepatotoxicity (ATDH) is a major adverse drug reaction associated for anti-tuberculosis therapy. The glutathione S-transferases (GST) plays a crucial role in the detoxification of hepatotoxic metabolites of anti-tuberculosis drugs.An association between GSTM1/GSTT1 null mutations and increased risk of ATDH has been demonstrated in adults. Given the ethnic differences and developmental changes, our study aims to investigate the potential impacts of GSTM1/GSTT1genotypes on the development of ATDH in Han Chinese children treated with anti-tuberculosis therapy.MethodsChildren receiving anti-tuberculosis therapy with or without evidence of ATDH were considered as the cases or controls, respectively. The GSTM1 and GSTT1 genotyping were performed using the polymerase chain reaction.ResultsOne hundred sixty-three children (20 cases and 143 controls) with a mean age of 4.7 years (range: 2 months-14.1 years) were included. For the GSTM1, 14 (70.0%) cases and 96 (67.1%) controls had homozygous null mutations. For the GSTT1, 13 (65.0%) cases and 97 (67.8%) controls had homozygous null mutations. Neither the GSTM1, nor the GSTT1 polymorphism was significantly correlated with the occurrence of ATHD.ConclusionOurresults did not support the GSTM1 and GSTT1 polymorphisms as the predictors of ADTH in Chinese Han children treated with anti-tuberculosis drugs. An age-related association between pharmacogenetics and ATHD need to be confirmed in the further study.

Germline mutations in RYR1 are associated with foetal akinesia deformation sequence/lethal multiple pterygium syndrome.

IntroductionFoetal akinesia deformation sequence syndrome (FADS) is a genetically heterogeneous disorder characterised by the combination of foetal akinesia and developmental defects which may include pterygia (joint webbing). Traditionally multiple pterygium syndrome (MPS) has been divided into two forms: prenatally lethal (LMPS) and non-lethal Escobar type (EVMPS) types. Interestingly, FADS, LMPS and EVMPS may be allelic e.g. each of these phenotypes may result from mutations in the foetal acetylcholine receptor gamma subunit gene (CHRNG). Many cases of FADS and MPS do not have a mutation in a known FADS/MPS gene and we undertook molecular genetic studies to identify novel causes of these phenotypes.ResultsAfter mapping a novel locus for FADS/LMPS to chromosome 19, we identified a homozygous null mutation in the RYR1 gene in a consanguineous kindred with recurrent LMPS pregnancies. Resequencing of RYR1 in a cohort of 66 unrelated probands with FADS/LMPS/EVMPS (36 with FADS/LMPS and 30 with EVMPS) revealed two additional homozygous mutations (in frame deletions). The overall frequency of RYR1 mutations in probands with FADS/LMPS was 8.3%.ConclusionsOur findings report, for the first time, a homozygous RYR1 null mutation and expand the range of RYR1-related phenotypes to include early lethal FADS/LMPS. We suggest that RYR1 mutation analysis should be performed in cases of severe FADS/LMPS even in the absence of specific histopathological indicators of RYR1-related disease.

NDST1 missense mutations in autosomal recessive intellectual disability.

NDST1 was recently proposed as a candidate gene for autosomal recessive intellectual disability in two families. It encodes a bifunctional GlcNAc N-deacetylase/N-sulfotransferase with important functions in heparan sulfate biosynthesis. In mice, Ndst1 is crucial for embryonic development and homozygous null mutations are perinatally lethal. We now report on two additional unrelated families with homozygous missense NDST1 mutations. All mutations described to date predict the substitution of conserved amino acids in the sulfotransferase domain, and mutation modeling predicts drastic alterations in the local protein conformation. Comparing the four families, we noticed significant overlap in the clinical features, including both demonstrated and apparent intellectual disability, muscular hypotonia, epilepsy, and postnatal growth deficiency. Furthermore, in Drosophila, knockdown of sulfateless, the NDST ortholog, impairs long-term memory, highlighting its function in cognition. Our data confirm NDST1 mutations as a cause of autosomal recessive intellectual disability with a distinctive phenotype, and support an important function of NDST1 in human development.

Intact IL-12 signaling is necessary for the generation of human natural killer cells with enhanced effector function after restimulation

Intact IL-12 signaling is necessary for the generation of human natural killer cells with enhanced effector function after restimulation

Somatic mosaicism and allele complexity induced by CRISPR/Cas9 RNA injections in mouse zygotes

Tyrosinase is the rate-limiting enzyme for the production of melanin pigmentation. In the mouse and other animals, homozygous null mutations in the Tyrosinase gene (Tyr) result in the absence of pigmentation, i.e. albinism. Here we used the CRISPR/Cas9 system to generate mono- and bi-allelic null mutations in the Tyr locus by zygote injection of two single-guide and Cas9 RNAs. Injection into C57BL/6N wild-type embryos resulted in one completely albino founder carrying two different Tyr mutations. In addition, three pigmentation mosaics and fully pigmented littermates were obtained that transmitted new mutant Tyr alleles to progeny in test crosses with albinos. Injection into Tyr heterozygous (B6CBAF1/J×FVB/NJ) zygotes resulted in the generation of numerous albinos and also mice with a graded range of albino mosaicism. Deep sequencing revealed that the majority of the albinos and the mosaics had more than two new mutant alleles. These visual phenotypes and molecular genotypes highlight the somatic mosaicism and allele complexity in founders that occurs for targeted genes during CRISPR/Cas9-mediated mutagenesis by zygote injection in mice.

Loss of central auditory processing in a mouse model of Canavan disease.

Canavan Disease (CD) is a leukodystrophy caused by homozygous null mutations in the gene encoding aspartoacylase (ASPA). ASPA-deficiency is characterized by severe psychomotor retardation, and excessive levels of the ASPA substrate N-acetylaspartate (NAA). ASPA is an oligodendrocyte marker and it is believed that CD has a central etiology. However, ASPA is also expressed by Schwann cells and ASPA-deficiency in the periphery might therefore contribute to the complex CD pathology. In this study, we assessed peripheral and central auditory function in the AspalacZ/lacZ rodent model of CD using auditory brainstem response (ABR). Increased ABR thresholds and the virtual loss of waveform peaks 4 and 5 from AspalacZ/lacZ mice, indicated altered central auditory processing in mutant mice compared with Aspawt/wt controls and altered central auditory processing. Analysis of ABR latencies recorded from AspalacZ/lacZ mice revealed that the speed of nerve conduction was unchanged in the peripheral part of the auditory pathway, and impaired in the CNS. Histological analyses confirmed that ASPA was expressed in oligodendrocytes and Schwann cells of the auditory system. In keeping with our physiological results, the cellular organization of the cochlea, including the organ of Corti, was preserved and the spiral ganglion nerve fibres were normal in ASPA-deficient mice. In contrast, we detected substantial hypomyelination in the central auditory system of AspalacZ/lacZ mice. In summary, our data suggest that the lack of ASPA in the CNS is responsible for the observed hearing deficits, while ASPA-deficiency in the cochlear nerve fibres is tolerated both morphologically and functionally.

Assessment of Nogo-66 Receptor 1 Function In Vivo After Spinal Cord Injury

Neuronal Nogo-66 receptor 1 (NgR1) has attracted attention as a converging point for mediating the effects of myelin-associate inhibitory ligands in the central nervous system, establishing the growth-restrictive environment, and limiting axon regeneration after traumatic injury. To investigate the factors that may be contributing to the discrepancy in the importance of NgR1, which has been undermined by several studies that have shown the lack of substantial axon regeneration after spinal cord injury (SCI) in NgR1-knockout or -knockdown animal models. We used mice carrying either a homozygous or heterozygous null mutation in the NgR1 gene and subjected them to either a moderate or severe SCI. Locomotor function assessments revealed that the level of functional recovery is affected by the degree of injury suffered. NgR1 ablation enhanced local collateral sprouting in the mutant mice. Reactive astrocytes and chondroitin sulfate proteoglycans (CSPGs) are upregulated surrounding the injury site. Matrix metalloproteinase-9, which has been shown to degrade CSPGs, was significantly upregulated in the homozygous mutant mice compared with the heterozygous or wild-type mice. However, CSPG levels remained higher in the homozygous compared with the heterozygous mice, suggesting that CSPG-degrading activity of matrix metalloproteinase-9 may require the presence of NgR1. Genetic ablation of NgR1 may lead to significant recovery in locomotor function after SCI. The difference in locomotor recovery we observed between the groups that suffered various degrees of injury suggests that injury severity may be a confounding factor in functional recovery after SCI.

Growth Differentiation Factor 6 As a Putative Risk Factor in Neuromuscular Degeneration

Mutation of Glass bottom boat, the Drosophila homologue of the bone morphogenetic protein or growth/differentiation factor (BMP/GDF) family of genes in vertebrates, has been shown to disrupt development of neuromuscular junctions (NMJ). Here we tested whether this same conclusion can be broadened to vertebrate BMP/GDF genes. This analysis was also extended to consider whether such genes are required for NMJ maintenance in post-larval stages, as this would argue that BMP genes are viable candidates for analysis in progressive neuromuscular disease. Zebrafish mutants harboring homozygous null mutations in the BMP-family gene gdf6a were raised to adulthood and assessed for neuromuscular deficits. Fish lacking gdf6a exhibited decreased endurance (∼50%, p = 0.005) compared to wild type, and this deficit progressively worsened with age. These fish also presented with significantly disrupted NMJ morphology (p = 0.009), and a lower abundance of spinal motor neurons (∼50%, p<0.001) compared to wild type. Noting the similarity of these symptoms to those of Amyotrophic Lateral Sclerosis (ALS) model mice and fish, we asked if mutations in gdf6a would enhance the phenotypes observed in the latter, i.e. in zebrafish over-expressing mutant Superoxide Dismutase 1 (SOD1). Amongst younger adult fish only bigenic fish harboring both the SOD1 transgene and gdf6a mutations, but not siblings with other combinations of these gene modifications, displayed significantly reduced endurance (75%, p<0.05) and strength/power (75%, p<0.05), as well as disrupted NMJ morphology (p<0.001) compared to wild type siblings. Bigenic fish also had lower survival rates compared to other genotypes. Thus conclusions regarding a role for BMP ligands in effecting NMJ can be extended to vertebrates, supporting conservation of mechanisms relevant to neuromuscular degenerative diseases. These conclusions synergize with past findings to argue for further analysis of GDF6 and other BMP genes as modifier loci, potentially affecting susceptibility to ALS and perhaps a broader suite of neurodegenerative diseases.

Sensory-motor behavioral characterization of an animal model of Maroteaux-Lamy syndrome (or Mucopolysaccharidosis VI)

Maroteaux-Lamy disease, also known as mucopolysaccharidosis (MPS) VI, is an MPS disorder caused by mutations in the ARSB gene encoding for the lysosomal enzyme arysulfatase B (ARSB). Deficient ARSB activity leads to lysosomal accumulation of dermatan sulfate in a wide range of tissues and organs. There are various animal models of MPS VI that have been well characterized from a biochemical and morphological point of view. In this study, we report the sensory-motor characterization of MPS VI rats carrying homozygous null ARSB mutations. We show that adult MPS VI rats are specifically impaired in vertical activity and motor endurance. All together, these data are consistent with biochemical findings that show a major impairment in connective tissues, such as joints and bones. The behavioral abnormalities of MPS VI rats represent fundamental endpoints for studies aimed at testing the pre-clinical safety and efficacy of novel therapeutic approaches for MPS VI.

Germline mutations in RYR1 are associated with foetal akinesia deformation sequence/lethal multiple pterygium syndrome

Foetal akinesia deformation sequence syndrome (FADS) is a genetically heterogeneous disorder characterised by the combination of foetal akinesia and developmental defects which may include pterygia (joint webbing). Traditionally multiple pterygium syndrome (MPS) has been divided into two forms: prenatally lethal (LMPS) and non-lethal Escobar type (EVMPS) types. Interestingly, FADS, LMPS and EVMPS may be allelic e.g. each of these phenotypes may result from mutations in the foetal acetylcholine receptor gamma subunit gene (CHRNG). Many cases of FADS and MPS do not have a mutation in a known FADS/MPS gene and we undertook molecular genetic studies to identify novel causes of these phenotypes. After mapping a novel locus for FADS/LMPS to chromosome 19, we identified a homozygous null mutation in the RYR1 gene in a consanguineous kindred with recurrent LMPS pregnancies. Resequencing of RYR1 in a cohort of 66 unrelated probands with FADS/LMPS/EVMPS (36 with FADS/LMPS and 30 with EVMPS) revealed two additional homozygous mutations (in frame deletions). The overall frequency of RYR1 mutations in probands with FADS/LMPS was 8.3%. Our findings report, for the first time, a homozygous RYR1 null mutation and expand the range of RYR1-related phenotypes to include early lethal FADS/LMPS. We suggest that RYR1 mutation analysis should be performed in cases of severe FADS/LMPS even in the absence of specific histopathological indicators of RYR1-related disease.