Novel CWF19L1 mutations in patients with spinocerebellar ataxia, autosomal recessive 17.

Spinocerebellar ataxia, autosomal recessive-17 (SCAR17) is a rare hereditary ataxia characterized by ataxic gait, cerebellar signs and occasionally accompanied by intellectual disability and seizures. Pathogenic mutations in the CWF19L1 gene that code for CWF19 like cell cycle control factor 1 cause SCAR17. We report here two unrelated families with the clinical characteristics of global developmental delay, cerebellar ataxia, pyramidal signs, and seizures. Cerebellar atrophy, and T2/FLAIR hypointense transverse pontine stripes were observed in brain imaging. Exome sequencing identified novel homozygous mutations including a splice acceptor site variant c.1375-2 A > G on intron 12 in a male patient and a single nucleotide variant c.452 T > G on exon 5 resulting in a missense variant p.Ile151Ser in the female patient from two unrelated families, respectively. Sanger sequencing confirmed the segregation of these variants in the family members with autosomal recessive inheritance. Transcript analysis of the splice site variant revealed activation of a novel cryptic splice acceptor site on exon 13 resulting in an alternative transcription with a loss of nine nucleotides on exon 13. Translation of this transcript predicted an in-frame deletion of three amino acids p.(459_461del). We also observed a novel exon 13 skipping which results in premature termination of the protein product. Our study expands the phenotype, radiological features, and genotypes known in SCAR17.

Whole exome sequencing and transcript analysis discover a novel pathogenic splice site mutation in DCAF17 gene underlying Woodhouse-Sakati syndrome.

Woodhouse-Sakati syndrome (WSS) is an extremely rare multisystemic disorder with neuroendocrine dysfunctions. It is characterized by hypogonadism, alopecia, diabetes mellitus, intellectual disability and progressive extrapyramidal syndrome along with radiological features of small pituitary gland, progressive frontoparietal white matter changes and abnormal accumulation of iron on globus pallidus. WSS is caused by mutations in DCAF17 gene that encodes for DDB1 and CUL4 associated factor 17. In this study, we report a 17-year-old boy with clinical and radiological features of WSS including mild global developmental delay, mild intellectual disability, sensorineural hearing loss, progressive extrapyramidal syndrome, alopecia, hypogonadotropic hypogonadism and dysmorphic features. Whole exome sequencing analysis revealed a novel potentially pathogenic splice donor site variant (c.458+1G>T) on the intron 4 of DCAF17 gene. Transcript analysis revealed splicing ablation resulting in aberrant splicing of exons 3 and 5 and skipping of exon 4 (c.322_458del). This results in a frameshift and is predicted to cause premature termination of protein synthesis resulting in a protein product of length 120 amino acids (p.[Gly108Ilefs*14]). Our study identified a novel pathogenic variant causing WSS in a patient and expands the spectrum of clinical and genetic characteristics of patients with WSS.

A splice altering variant in NDRG1 gene causes Charcot-Marie-Tooth disease, type 4D.

Charcot-Marie-Tooth disease, type 4D (CMT4D) is a progressive, autosomal recessive form of CMT, characterized by distal muscle weakness and atrophy, foot deformities, severe motor sensory neuropathy, and sensorineural hearing impairment. Mutations in NDRG1 gene cause neuropathy in humans, dogs, and rodents. Here, we describe clinical and genetic features of a 17-year-old male with wasting of hand muscle and foot and severe motor neuropathy. Whole exome sequencing was carried out on the patient and his unaffected parents. We identified a novel deletion of nine nucleotides (c.537 + 2_537 + 10del) on the splice donor site of intron 8 in NDRG1 gene. The Sanger sequencing confirmed the segregation of this mutation in autosomal recessive inheritance. Furthermore, transcript analysis confirmed a splice defect and reveals using of an alternate cryptic splice donor site on the downstream intronic region. It resulted in an insertion of 42 nucleotides to exon 8 of NDRG1. Translation of the resulting transcript sequence revealed an insertion of 14 amino acids in-frame to the existing NDRG1 protein. This insertion is predicted to disrupt an alpha helix which is involved in protein-protein interactions in homologous proteins. Our study expands the clinical and genetic spectrum of CMT4D. The splice defect we found in this patient reveals a novel splice isoform of NDRG1 as the potential cause for the neuropathy observed in this patient.

Effective Visualization and Easy Tracking of Extracellular Vesicles in Glioma Cells.

Extracellular vesicles (EVs) are nano-sized, membrane-bound structures secreted by cells and play critical roles in mediating intercellular signaling. EVs based on their size as well as mechanisms of biosynthesis are categorized as either microvesicles (200-1000 nm) or exosomes (30-200 nm). The EVs carry several biomolecules like proteins, DNAs, RNAs, and lipids into other cells and modulate several cellular functions. Being of very small sizes, it is very challenging to analyze them using conventional microscopes. Here, we report a new method developed by us for visualizing EVs using simple immune-fluorescence based technique, wherein the isolated EVs can be stained with fluorescently tagged antibodies to proteins present in EVs. The stained EVs can then be analyzed by using either confocal or super-resolution microscopes. Our method detailed here is equally effective in staining proteins that are present inside the EVs as well as those localized to the membranes of vesicles. By employing unique staining strategies, we have minimized the background noise and thereby improved the signal strength in confocal microscope. Using electron microscopy, we have ascertained that the structural integrity of the labeled EVs is intact. More importantly, the labeling of EVs does not affect their functionality and their localization can be tracked after its uptake by recipient cells without resorting to any conventional reporter-based strategies or lipophilic dyes. In conclusion, the method described here is a simple, sensitive and efficient immune-fluorescence based method for visualization of molecules within the EVs.

Hydroxyapatite nanorods loaded with parathyroid hormone (PTH) synergistically enhance the net formative effect of PTH anabolic therapy.

Parathyroid hormone (PTH) has been a major contributor to the anabolic therapy for osteoporosis, but its delivery to bone without losing activity and avoiding adverse local effects remain a challenge. Being the natural component of bone, use of hydroxyapatite for this purpose brings a major breakthrough in synergistic anabolism. This study focuses on synthesis, characterization and evaluation of in vitro and in vivo efficacy of PTH (1-34) adsorbed hydroxyapatite nanocarrier for synergistic enhancement in the anabolic activity of PTH for bone regeneration. The negative zeta potential of this nanocarrier facilitated its affinity to the Ca2+ rich bone tissue and solubilization at low pH enhanced specific delivery of PTH to the resorption pits in osteoporotic bone. In this process, PTH retained its anabolic effect and at the same time an increase in bone mineral content indicated enhancement of the net formative effect of the PTH anabolic therapy.