Association between Rare Variants in AP4E1, a Component of Intracellular Trafficking,and Persistent Stuttering

Stuttering is a common, highly heritable neurodevelopmental disorder characterized by deficits in the volitional control of speech. Whole-exome sequencing identified two heterozygous AP4E1 coding variants, c.1549G>A (p.Val517Ile) and c.2401G>A (p.Glu801Lys), that co-segregate with persistent developmental stuttering in a large Cameroonian family, and we observed the same two variants in unrelated Cameroonians with persistent stuttering. We found 23 other rare variants, including predicted loss-of-function variants, in AP4E1 in unrelated stuttering individuals in Cameroon, Pakistan, and North America. The rate of rare variants in AP4E1 was significantly higher in unrelated Pakistani and Cameroonian stuttering individuals than in population-matched control individuals, and coding variants in this gene are exceptionally rare in the general sub-Saharan West African, South Asian, and North American populations. Clinical examination of the Cameroonian family members failed to identify any symptoms previously reported in rare individuals carrying homozygous loss-of-function mutations in this gene. AP4E1 encodes the ε subunit of the heterotetrameric (ε-β4-μ4-σ4) AP-4 complex, involved in protein sorting at the trans-Golgi network. We found that the μ4 subunit of AP-4 interacts with NAGPA, an enzyme involved in the synthesis of the mannose 6-phosphate signal that targets acid hydrolases to the lysosome and the product of a gene previously associated with stuttering. These findings implicate deficits in intracellular trafficking in persistent stuttering.     

Mutations in Grxcr1 Are The Basis for Inner Ear Dysfunction in the Pirouette Mouse

Recessive mutations at the mouse pirouette (pi) locus result in hearing loss and vestibular dysfunction due to neuroepithelial defects in the inner ear. Using a positional cloning strategy, we have identified mutations in the gene Grxcr1 (glutaredoxin cysteine-rich 1) in five independent allelic strains of pirouette mice. We also provide sequence data of GRXCR1 from humans with profound hearing loss suggesting that pirouette is a model for studying the mechanism of nonsyndromic deafness DFNB25. Grxcr1 encodes a 290 amino acid protein that contains a region of similarity to glutaredoxin proteins and a cysteine-rich region at its C terminus. Grxcr1 is expressed in sensory epithelia of the inner ear, and its encoded protein is localized along the length of stereocilia, the actin-filament-rich mechanosensory structures at the apical surface of auditory and vestibular hair cells. The precise architecture of hair cell stereocilia is essential for normal hearing. Loss of function of Grxcr1 in homozygous pirouette mice results in abnormally thin and slightly shortened stereocilia. When overexpressed in transfected cells, GRXCR1 localizes along the length of actin-filament-rich structures at the dorsal-apical surface and induces structures with greater actin filament content and/or increased lengths in a subset of cells. Our results suggest that deafness in pirouette mutants is associated with loss of GRXCR1 function in modulating actin cytoskeletal architecture in the developing stereocilia of sensory hair cells.     

Transformation and inheritance of Bt genes inGossypium hirsutum

Transgenic plants offer many unique opportunities for managing pest populations. However, the inheritance, integration, and expression of multiple transgenes are prerequisite for maintaining sustainable resistance against insects in crops. We took a gene-pyramiding approach to produce Bt cotton expressing two Bt genes,cry1Ac andcry2A. Using sonication-assistedAgrobacterium-mediated transformation (SAAT), we achieved an efficiency of 6.26%. Putative transgenic plants were confirmed via PCR, Southern hybridization, and western-blotting. Those showing mortality of 75 to 100% for the second instar ofHeliothis armigera (compared with 0% for the control) were considered Bt-positive. Transgenes were segregated according to a 3:1 Mendelian inheritance pattern in the T1 generation forHeliothis resistance. In our insect bioassay, the control plants showed >95% leaf damage, and insects reached the 4^th instar stage of larval growth. In contrast, leaf damage on transgenic plants was limited to only a few bites, and insect mortality was 75 to 100%. ELISA confirmed transgene expression, and Bt protein was detected in leaf tissue. This performance was consistent with that of the parent transgenics. PCR and Southern blots verified integration of thecry1Ac andcry2A genes into the progeny. Therefore, this strategy provides a pathway toward cotton improvement and the development of durable resistance against insect damage.     

Field evaluation and risk assessment of transgenic indica basmati rice

We report the first field trial of different transgenic lines of Indica Basmati rice (B-370) expressing cry1Ac and cry2A genes. Different transgenic lines were grown under field conditions for two consecutive years, according to RCBD and Split Plot Design respectively. All the biosafety measures were taken into consideration. Sixty neonate larvae of yellow stem borer were artificially infested into each plant in three installments. Data was recorded in terms of dead hearts and white heads at vegetative and flowering stage respectively. Transgenic lines exhibited inherent ability to protect rice plants from target insects (p<0.01). Natural infestations of rice skipper and rice leaf folder were also observed and transgenic plants were statistically superior to their untransformed counterparts. Green house whole plant bioassays were done by infesting two 2^nd instar larvae of rice leaf folder per tiller. Transgenics were 96% more resistant than untransformed control plants. The presence of cry genes was observed with Dot blot, PCR and Southern blot analysis, while ELISA and Western blot analysis confirmed the expression of Cry proteins. All lines expressed higher level of Cry proteins when compared with commercially released cultivars of Bt cotton, maize and potato. It was also observed that although toxin titer substantially decreased with increasing age of the plants, it remained well within the limits to kill the target insects. Morphological studies showed significant variation for days to maturity, plant height and panicle length. Cooking qualities of seeds harvested from these lines were compared with the untransformed control. The transgenic lines had no effect on non-target insects (insects belonging to orders other than diptera and lepidoptera) and germination of three local varieties of wheat. Chances of gene spread were calculated at a level of 0.18% cross pollination in experimental lines.     

Mutations in TBC1D24, a Gene Associated With Epilepsy,Also Cause Nonsyndromic Deafness DFNB86

Inherited deafness is clinically and genetically heterogeneous. We recently mapped DFNB86, a locus associated with nonsyndromic deafness, to chromosome 16p. In this study, whole-exome sequencing was performed with genomic DNA from affected individuals from three large consanguineous families in which markers linked to DFNB86 segregate with profound deafness. Analyses of these data revealed homozygous mutation c.208G>T (p.Asp70Tyr) or c.878G>C (p.Arg293Pro) in TBC1D24 as the underlying cause of deafness in the three families. Sanger sequence analysis of TBC1D24 in an additional large family in which deafness segregates with DFNB86 identified the c.208G>T (p.Asp70Tyr) substitution. These mutations affect TBC1D24 amino acid residues that are conserved in orthologs ranging from fruit fly to human. Neither variant was observed in databases of single-nucleotide variants or in 634 chromosomes from ethnically matched control subjects. TBC1D24 in the mouse inner ear was immunolocalized predominantly to spiral ganglion neurons, indicating that DFNB86 deafness might be an auditory neuropathy spectrum disorder. Previously, six recessive mutations in TBC1D24 were reported to cause seizures (hearing loss was not reported) ranging in severity from epilepsy with otherwise normal development to epileptic encephalopathy resulting in childhood death. Two of our four families in which deafness segregates with mutant alleles of TBC1D24 were available for neurological examination. Cosegregation of epilepsy and deafness was not observed in these two families. Although the causal relationship between genotype and phenotype is not presently understood, our findings, combined with published data, indicate that recessive alleles of TBC1D24 can cause either epilepsy or nonsyndromic deafness.     

DNA glycosylase enzymes induced during chemical adaptation of M. luteus.

Five peaks of DNA glycosylase activity showing a preference for MNNG alkylated DNA have been identified from extracts of adapted M. luteus. They are numerically designated as GI to GV in order of their decreasing molecular weights. The first two of these peaks have been highly purified. GI, is a constitutive heat labile protein, 35% stimulated by the presence of 50 mM NaCl, acts exclusively on 3 MeA residues in alkylated DNA, 60-70% inhibited by the presence of 2 mM free 3MeA and has been designated as 3MeA DNA glycosylase enzyme. GII, which is an inducible protein, is heat stable, 28% inhibited by the presence of 50 mM NaCl, removes 3MeA, 3MeG, 7MeA & 7MeG with different efficiency, and has been designated as 3,7 methylpurine DNA glycosylase enzyme. The rate of release of 3 methylpurines is 30 times that of 7MeG. There is no activity of either enzyme on O2-MeC, O2-MeT, O4-MeT or O6-MeG. The apparent molecular weights of GI and GII proteins are 28 Kd and 22 Kd respectively.     

Diazoxide preconditioning of endothelial progenitor cells from streptozotocin-induced type 1 diabetic rats improves their ability to repair diabetic cardiomyopathy

Molecular and Cellular Biochemistry - Type 1 diabetes mellitus (DM) is a strong risk factor for the development of diabetic cardiomyopathy (DCM) which is the leading cause of morbidity and...