IKAP/Elp1 Is Required In Vivo for Neurogenesis and Neuronal Survival, but Not for Neural Crest Migration

Familial Dysautonomia (FD; Hereditary Sensory Autonomic Neuropathy; HSAN III) manifests from a failure in development of the peripheral sensory and autonomic nervous systems. The disease results from a point mutation in the IKBKAP gene, which encodes the IKAP protein, whose function is still unresolved in the developing nervous system. Since the neurons most severely depleted in the disease derive from the neural crest, and in light of data identifying a role for IKAP in cell motility and migration, it has been suggested that FD results from a disruption in neural crest migration. To determine the function of IKAP during development of the nervous system, we (1) first determined the spatial-temporal pattern of IKAP expression in the developing peripheral nervous system, from the onset of neural crest migration through the period of programmed cell death in the dorsal root ganglia, and (2) using RNAi, reduced expression of IKBKAP mRNA in the neural crest lineage throughout the process of dorsal root ganglia (DRG) development in chick embryos in ovo. Here we demonstrate that IKAP is not expressed by neural crest cells and instead is expressed as neurons differentiate both in the CNS and PNS, thus the devastation of the PNS in FD could not be due to disruptions in neural crest motility or migration. In addition, we show that alterations in the levels of IKAP, through both gain and loss of function studies, perturbs neuronal polarity, neuronal differentiation and survival. Thus IKAP plays pleiotropic roles in both the peripheral and central nervous systems

Paramagnetic Rim Lesions in Pediatric Multiple Sclerosis and Their Association With Brain Tissue Atrophy

Background and objectives Paramagnetic rim lesions (PRLs), visible on susceptibility-based imaging (SbI), reflect chronic active inflammation in multiple sclerosis (MS). In adult-onset MS, PRLs are associated with a more aggressive disease course.The objectives of this study were to assess the prevalence of PRLs in children with MS and to examine how baseline PRL count relates to clinical disability and brain tissue volume loss, both cross-sectionally and over short-term follow-up.MethodsWe retrospectively analyzed pediatric patients from 4 UK tertiary neuroimmunology centers who met the 2017 McDonald diagnostic criteria and had 3D T1-weighted, T2-weighted, fluid-attenuated inversion recovery, and SbI MRI available. PRLs were identified per North American Imaging in MS criteria and anatomically classified. Brain volumes were segmented using Mindglide, with z-scores derived from NIH normative data. Associations between baseline PRL burden, clinical variables, and brain volumes were assessed using univariable and multivariable stepwise regression. Linear mixed-effects models evaluated the predictive value of baseline PRL burden on longitudinal brain volume changes.ResultsFifty-four patients (mean age 14.0 ± 2.2 years; 75.9% female) were included. At least 1 PRL was seen in 74.1% of patients, with a median number of 2 PRLs (interquartile range [IQR] = 0-6), predominantly in periventricular regions, and accounting for 25% of total T2-weighted hyperintense lesions. In multivariable Poisson regression, at baseline, shorter disease duration (incidence rate ratio [IRR] = 0.987, 95% CI 0.975-0.999, p = 0.035), and greater number (IRR 1.045, 95% CI 1.035-1.054, p < 0.001) and volume (IRR 1.018, 95% CI 1.004-1.032, p = 0.012) of T2-hyperintense lesions were associated with higher PRL count. Cross-sectionally, a higher PRL count was associated with lower cortical (β = -0.139, 95% CI -0.231 to -0.047, p = 0.016) and deep (β = -0.096, 95% CI -0.166 to -0.026, p = 0.032) gray matter volume z-scores. No significant association was observed between clinical disability and PRL count. In 45 patients followed up for a median 17 months (IQR 12-24), a higher baseline PRL count predicted greater deep gray matter volume loss over time (β = -0.020, 95% CI -0.034 to -0.006, p = 0.036).DiscussionPRLs are common in pediatric MS and are linked to greater lesion burden and gray matter atrophy. These findings suggest that PRLs are promising imaging biomarkers of more severe brain tissue damage although their ability to predict future disability requires confirmation in longer term studies

A Systematic Study of the Synthesis of Silver Nanoplates: Is Citrate a “Magic” Reagent?

In this work we have carried out systematic studies and identified the critical role of hydrogen peroxide instead of the generally believed citrate in the well-known chemical reduction route to silver nanoplates. This improved understanding allows us to develop consistently reproducible processes for the synthesis of nanoplates with high efficiency and yields. By harnessing the oxidative power of H2O2, various silver sources including silver salts and metallic silver can be directly converted to nanoplates with the assistance of an appropriate capping ligand, thus significantly enhancing the reproducibility of the synthesis. Contrary to the previous conclusion that citrate is the key component, we have determined that the group of ligands with selective adhesion to Ag (111) facets can be expanded to many di- and tricarboxylate compounds whose two nearest carboxylate groups are separated by two or three carbon atoms. We have also found that the widely used secondary ligand polyvinylpyrrolidone can be replaced by many hydroxyl group-containing compounds or even removed entirely while still producing nanoplates of excellent uniformity and stability. In addition to the general understanding of NaBH4 as a reducing agent, it has also been found to act as a capping agent to stabilize the silver nanoparticles, prolong the initiation time required for nanoplate nucleation, and contribute to the control of the thickness as well as the aspect ratio of silver nanoplates. The improved insight into the specific roles of the reaction components and significantly enhanced reproducibility are expected to help elucidate the formation mechanism of this interesting nanostructure

A Systematic Study of the Synthesis of Silver Nanoplates: Is Citrate a “Magic” Reagent?

In this work we have carried out systematic studies and identified the critical role of hydrogen peroxide instead of the generally believed citrate in the well-known chemical reduction route to silver nanoplates. This improved understanding allows us to develop consistently reproducible processes for the synthesis of nanoplates with high efficiency and yields. By harnessing the oxidative power of H2O2, various silver sources including silver salts and metallic silver can be directly converted to nanoplates with the assistance of an appropriate capping ligand, thus significantly enhancing the reproducibility of the synthesis. Contrary to the previous conclusion that citrate is the key component, we have determined that the group of ligands with selective adhesion to Ag (111) facets can be expanded to many di- and tricarboxylate compounds whose two nearest carboxylate groups are separated by two or three carbon atoms. We have also found that the widely used secondary ligand polyvinylpyrrolidone can be replaced by many hydroxyl group-containing compounds or even removed entirely while still producing nanoplates of excellent uniformity and stability. In addition to the general understanding of NaBH4 as a reducing agent, it has also been found to act as a capping agent to stabilize the silver nanoparticles, prolong the initiation time required for nanoplate nucleation, and contribute to the control of the thickness as well as the aspect ratio of silver nanoplates. The improved insight into the specific roles of the reaction components and significantly enhanced reproducibility are expected to help elucidate the formation mechanism of this interesting nanostructure

Targeted Gene Correction Minimally Impacts Whole-Genome Mutational Load in Human-Disease-Specific Induced Pluripotent Stem Cell Clones

SummaryThe utility of genome editing technologies for disease modeling and developing cellular therapies has been extensively documented, but the impact of these technologies on mutational load at the whole-genome level remains unclear. We performed whole-genome sequencing to evaluate the mutational load at single-base resolution in individual gene-corrected human induced pluripotent stem cell (hiPSC) clones in three different disease models. In single-cell clones, gene correction by helper-dependent adenoviral vector (HDAdV) or Transcription Activator-Like Effector Nuclease (TALEN) exhibited few off-target effects and a low level of sequence variation, comparable to that accumulated in routine hiPSC culture. The sequence variants were randomly distributed and unique to individual clones. We also combined both technologies and developed a TALEN-HDAdV hybrid vector, which significantly increased gene-correction efficiency in hiPSCs. Therefore, with careful monitoring via whole-genome sequencing it is possible to apply genome editing to human pluripotent cells with minimal impact on genomic mutational load

Modelling Fanconi anemia pathogenesis and therapeutics using integration-free patient-derived iPSCs.

Fanconi anaemia (FA) is a recessive disorder characterized by genomic instability, congenital abnormalities, cancer predisposition and bone marrow (BM) failure. However, the pathogenesis of FA is not fully understood partly due to the limitations of current disease models. Here, we derive integration free-induced pluripotent stem cells (iPSCs) from an FA patient without genetic complementation and report in situ gene correction in FA-iPSCs as well as the generation of isogenic FANCA-deficient human embryonic stem cell (ESC) lines. FA cellular phenotypes are recapitulated in iPSCs/ESCs and their adult stem/progenitor cell derivatives. By using isogenic pathogenic mutation-free controls as well as cellular and genomic tools, our model serves to facilitate the discovery of novel disease features. We validate our model as a drug-screening platform by identifying several compounds that improve hematopoietic differentiation of FA-iPSCs. These compounds are also able to rescue the hematopoietic phenotype of FA patient BM cells

Modeling Fanconi anemia pathogenesis and therapeutics using integration-free patient iPSCs

Fanconi anaemia (FA) is a recessive disorder characterized by genomic instability, congenital abnormalities, cancer predisposition and bone marrow (BM) failure. However, the pathogenesis of FA is not fully understood partly due to the limitations of current disease models. Here, we derive integration free-induced pluripotent stem cells (iPSCs) from an FA patient without genetic complementation and report in situ gene correction in FA-iPSCs as well as the generation of isogenic FANCA-deficient human embryonic stem cell (ESC) lines. FA cellular phenotypes are recapitulated in iPSCs/ESCs and their adult stem/progenitor cell derivatives. By using isogenic pathogenic mutation-free controls as well as cellular and genomic tools, our model serves to facilitate the discovery of novel disease features. We validate our model as a drug-screening platform by identifying several compounds that improve hematopoietic differentiation of FA-iPSCs. These compounds are also able to rescue the hematopoietic phenotype of FA patient BM cells.Altres ajuts: Strategic Priority Research Program of the Chinese Academy of Sciences (XDA01020312), National Basic Research Program of China (973 Program,2014CB964600;2014CB910500), NSFC (81271266, 31222039, 81330008, 31201111, 81371342, 81300261, 81300677), Key Research Program of the Chinese Academy of Sciences (KJZD-EW-TZ-L05), Beijing Natural Science Foundation (7141005; 5142016), the Thousand Young Talents program of China, National Laboratory of Biomacromolecules (012kf02, 2013kf05;2013kf11;2014kf02), and State Key Laboratory of Drug Research (SIMM1302KF-17). M.L. and K.S. are supported by CIRM fellowship. N.M was partially supported by La Fundació Privada La Marató de TV3, 121430/31/32. Y.T. was partially supported by an Uehara Memorial Foundation research fellowship. E.N. was partially supported by an F.M. Kirby Foundation postdoctoral fellowship. J.S. was supported by Fundació Marató TV3 (464/C/2012). J.A.B. was supported by grants from La Fundació Privada La Marató de TV3, 121430/31/32. J.C.I.B. was supported by grants from the G. Harold and Leila Y. Mathers Charitable Foundation, The California Institute of Regenerative Medicine, Ellison Medical Foundation, and The Leona M. and Harry B. Helmsley Charitable Trust grant #2012-PG-MED002