Co-delivery of curcumin and Bcl-2 siRNA to enhance therapeutic effect against breast cancer cells using PEI-functionalized PLGA nanoparticles.

PURPOSE: Breast cancer is the second major cause of death worldwide among women. Co-delivery of anticancer drugs and nucleic acids targeting the apoptosis pathway could be a promising new approach. METHODS: In the present study, we synthesized a novel nanostructure for the co-delivery of curcumin and siRNA to breast cancer cells. Curcumin-loaded polylactic-co-glycolic acid (PLGA) was synthesized using an O/W emulsion-solvent diffusion method. It was coated with polyethylenimine (PEI) and subsequently complexed with Bcl-2 siRNA. Also, nanoparticles were characterized such as zeta potential, size distribution and drug encapsulation. Finally, the cytotoxicity of NP and Bcl-2 expression was evaluated. RESULTS: The curcumin-loaded PLGA nanoparticles were 70 nm in size, and increased to 84 nm after incorporation of PEI plus Bcl-2 siRNA. The encapsulation ratio of the drug in our nanoparticle was 78%. Cellular internalization of PLGA-CUR-PEI/Bcl-2 siRNA NPs was confirmed by fluorescence microscopy with the broadcasting of the fluorescence in the cytoplasm and into the nucleus. The results of the cell viability assay revealed that curcumin-loaded PLGA coated with PEI and Bcl-2 siRNA exhibited the highest cytotoxicity against the T47D cell line, while the siRNA decreased the Bcl-2 expression by 90.7%. CONCLUSION: The co-delivery of curcumin plus Bcl-2 siRNA with the PLGA-PEI nanosystem could be a synergistic drug carrier against breast cancer cells.

Defective complex III mitochondrial respiratory chain due to a novel variant in CYC1 gene masquerades acute demyelinating syndrome or Leber hereditary optic neuropathy.

Complex III (CIII) is the third out of five mitochondrial respiratory chain complexes residing at the mitochondrial inner membrane. The assembly of 10 subunits encoded by nuclear DNA and one by mitochondrial DNA result in the functional CIII which transfers electrons from ubiquinol to cytochrome c. Deficiencies of CIII are among the least investigated mitochondrial disorders and thus clinical spectrum of patients with mutations in CIII is not well defined. We report on a 10-year-old girl born to consanguineous Iranian parents presenting with recurrent visual loss episodes and optic nerve contrast enhancement in brain imaging reminiscent of an acquired demyelination syndrome (i.e. optic neuritis or multiple sclerosis), who was ultimately confirmed to have a novel homozygous missense variant of unknown significance, c.949C > T; p.(Arg317Trp) in the CYC1 gene, a nuclear DNA subunit of complex III of the mitochondrial chain. Sanger sequencing confirmed the segregation of this variant with disease in the family. The effect of this variant on the protein structure was shown in-silico. Our findings, not only expand the clinical spectrum due to defects in CYC1 gene but also highlight that mitochondrial respiratory chain disorders could be considered as a potential differential diagnosis in children who present with unusual patterns of acquired demyelination syndromes (ADS). In addition, our results support the hypothesis that mitochondrial disorders might have an overlapping presentation with ADS.

ACER3-related leukoencephalopathy: expanding the clinical and imaging findings spectrum due to novel variants.

BACKGROUND: Leukodystrophies are the main subgroup of inherited CNS white matter disorders which cause significant mortality and morbidity in early years of life. Diagnosis is mostly based on clinical context and neuroimaging findings; however, genetic tools, particularly whole-exome sequencing (WES), have led to comprehending the causative gene and molecular events contributing to these disorders. Mutation in Alkaline Ceramidase 3 (ACER3) gene which encodes alkaline ceramidase enzyme that plays a crucial role in cellular growth and viability has been stated as an uncommon reason for inherited leukoencephalopathies. Merely only two ACER3 mutations in cases of progressive leukodystrophies have been reported thus far. RESULTS: In the current study, we have identified three novel variants in ACER3 gene in cases with new neurological manifestations including developmental regression, dystonia, and spasticity. The detected variants were segregated into family members. CONCLUSION: Our study expands the clinical, neuroimaging, electroencephalographic, and genetic spectrum of ACER3 mutations. Furthermore, we reviewed and compared the findings of all the previously reported cases and the cases identified here in order to facilitate their diagnosis and management.

Novel variants in critical domains of ATP8A2 and expansion of clinical spectrum.

ATP8A2 is a P4-ATPase that flips phosphatidylserine across membranes to generate and maintain transmembrane phospholipid asymmetry. Loss-of-function variants cause severe neurodegenerative and developmental disorders. We have identified three ATP8A2 variants in unrelated Iranian families that cause intellectual disability, dystonia, below-average head circumference, mild optic atrophy, and developmental delay. Additionally, all the affected individuals displayed tooth abnormalities associated with defects in teeth development. Two variants (p.Asp825His and p.Met438Val) reside in critical functional domains of ATP8A2. These variants express at very low levels and lack ATPase activity. Inhibitor studies indicate that these variants are misfolded and degraded by the cellular proteasome. We conclude that Asp825, which coordinates with the Mg2+ ion within the ATP binding site, and Met438 are essential for the proper folding of ATP8A2 into a functional flippase. We also provide evidence on the association of tooth abnormalities with defects in ATP8A2, thereby expanding the clinical spectrum of the associated disease.

Identification of novel loss of function variants in MBOAT7 resulting in intellectual disability.

The membrane bound O-acyltransferase domain-containing 7 (MBOAT7) gene codes for an enzyme involved in regulating arachidonic acid incorporation in lysophosphatidylinositol. Patients with homozygous nonsense mutations in MBOAT7 have intellectual disability (ID) accompanied with seizure and autism. Accumulating evidences obtained from human genetic studies have shown that MBOAT7 is also involved in fatty liver disease. Here we identified two novel homozygous variants in MBOAT7, NM_024298.5: c.1062C>A; p.(Tyr354*) and c.1135del; p.(Leu379Trpfs*9), in two unrelated Iranian families by means of whole exome sequencing. Sanger sequencing was performed to confirm the identified variants and also to investigate whether they co-segregate with the patients' phenotypes. To understand the functional consequences of these changes, we overexpressed recombinant wild type MBOAT7 and mutants in vitro and showed these mutations resulted in abolished protein synthesis and expression, indicating a complete loss of function. Albeit, we did not trace any liver diseases in our patients, but presence of globus pallidus signal changes in Magnetic Resonance Images might be indicative of metabolic changes as a result of loss of MBOAT7 expression in hepatic cells. These signal changes could also help as an important marker of MBOAT7 deficiency while analyzing the genomic data of patients with similar phenotypes.

A novel variant of ST3GAL3 causes non-syndromic autosomal recessive intellectual disability in Iranian patients.

BACKGROUND: The number of reported genes causing non-syndromic autosomal recessive intellectual disability (NS-ARID) is increasing. For example, mutations in the ST3GAL3 gene have been reported to be associated with NS-ARID. In the present study, we aimed to determine the genetic cause of the NS-ARID in a five-generation consanguineous Iranian family. METHODS: We subjected four patients with an initial diagnosis of NS-ID in an Iranian family. To identify the possible genetic cause(s), whole-exome sequencing was performed on the proband and Sanger sequencing was applied to investigate co-segregation analysis. Using in silico predictive tools, the possible impacts of the variant on the structure and function of ST3Gal-III were predicted. RESULTS: The common clinical features were detected in all affected members who were suffering from a severe ID. Using whole-exome sequencing, a novel variant, c.704C>T or p.(Thr235Met), in exon 9 of the ST3GAL3 gene (NM_001270461.2, OMIM# 606494) was identified and verified by Sanger sequencing. This variant is located next to the VS motif of ST3Gal-III, which is a vital part of the catalytical domains. CONCLUSIONS: In the present study, we identified a novel missense variant, c.704C>T or p.(Thr235Met), in the ST3GAL3. To our knowledge, is the third variant in this gene to be associated with NS-ARID. Our findings highlight the need for further investigations into the mechanisms by which variants in ST3GAL3 contribute to neurological dysfunction.

Homozygous in-frame variant of SCL6A3 causes dopamine transporter deficiency syndrome in a consanguineous family.

The human dopamine transporter (hDAT) participates in dopamine homeostasis by clearing dopamine from the extracellular space using secondary active transport. Dysregulation of hDAT has been reported to be associated with different neuropsychiatric disorders. Dopamine transporter deficiency syndrome (DTDS) is a complex disease caused by defects in dopamine uptake within the synaptic cleft and patients manifest parkinsonian features. The extracellular loops are crucial for DAT activity and defects in these regions disturb dopamine transport. In the present study, a 3.5-year-old female in a consanguineous Iranian family with an initial diagnosis of gait imbalance and speech delay has been identified. We utilized whole-exome sequencing (WES) to identify the possible genetic defect(s). WES identified a novel homozygous in-frame indel variant, c.1139_1150del; p.(Gly380_Lys384delinsGlu), in the SLC6A3 gene (NM_001044.4), as the most likely disease-susceptibility variant. This variant is located in extracellular loop 4 (EL4) of the DAT protein. Our study highlights the role of extracellular loops and shows the EL4 of hDAT as a critical region for the protein activity. The identified variant in the EL4 region of DAT is predicted to compromise DAT function and may lead to DTDS in this case. However, complementary studies are required to confirm.