Mitochondrial calcium signaling in non-neuronal cells: Implications for Alzheimer's disease pathogenesis.

Mitochondrial dysregulation is pivotal in Alzheimer's disease (AD) pathogenesis. Calcium governs vital mitochondrial processes impacting energy conversion, oxidative stress, and cell death signaling. Disruptions in mitochondrial calcium (mCa2+) handling induce calcium overload and trigger the opening of mitochondrial permeability transition pore, ensuing energy deprivation and resulting in AD-related neuronal cell death. However, the role of mCa2+ in non-neuronal cells (microglia, astrocytes, oligodendrocytes, endothelial cells, and pericytes) remains elusive. This review provides a comprehensive exploration of mitochondrial heterogeneity and calcium signaling, offering insights into specific differences among various brain cell types in AD.

46,XX aromatase deficiency: A single-center experience with the varied spectrum and recurrent variants, and a systematic review of hormonal parameters.

BACKGROUND: Aromatase deficiency is a rare disorder, with only a few cases reported in India. We describe a single-center experience in western India, with a systematic review of genetically proven 46,XX aromatase deficiency patients to evaluate hormonal parameters. METHODS: Retrospective review of case records, collating phenotypic and genotypic data and molecular modeling. Systematic review of 46,XX aromatase deficiency, analyzing data on gonadotropins, estrogen and androgens. RESULTS: In the seven patients from our center, presentation was frequent in childhood or adolescence (4/7: delayed puberty or hyperandrogenism), with maternal virilization (4/7), predominance of Prader III/IV (5/7), and initial rearing as females (6/7). Three patients had hypoplastic ovaries. One patient had spontaneous regular menses. We report three novel (p.Arg115Pro, p.Arg192Pro, and c.145+1_145+4delins) and two recurrent variants (p.Val370Met, and c.145+1_145+4delins) in western and northern India, respectively. On systematic review (n=43), gonadotropins were elevated (FSH>LH) across ages (except preterm infants), androgens were elevated in about one-third of cases during childhood and puberty, and estradiol was lower than in controls in mini-puberty and puberty. Spontaneous thelarche and streak ovaries were significantly more frequent in patients with non-truncating and truncating variants, respectively. CONCLUSION: We report uncommon presentations with possible founder variants, and highlight hormonal parameters across ages. Serum FSH levels were elevated except in preterms, and can be used as a diagnostic marker.

MD simulation-based screening approach identified tolvaptan as a potential inhibitor of Eg5.

We discovered tolvaptan as a new Eg5 inhibitor using molecular dynamics simulation-based virtual screening. The Eg5-monastrol, Eg5-ispinesib, and Eg5-STLC complexes with "closed" L5 conformation obtained in MD simulation were used to generate a combined pharmacophore model, and this model was used during the process of virtual screening. Further, the MD simulation for 1 µs showed that the binding of tolvaptan to Eg5 was stable due to the closure of the α2/L5/α3 pocket. Tolvaptan belongs to the class of drugs called vaptans which are non-peptide vasopressin receptor antagonists. Since our virtual search for mitotic inhibitors identified tolvaptan as a potential candidate, we were interested in unraveling its antimitotic mechanism. Tolvaptan bound to purified Eg5-437H with a dissociation constant of 27 ± 3.8 µM. Tolvaptan inhibited the growth of HeLa cells through the mitotic block, and around 70% of these mitotic cells exhibited a characteristic monopolar spindle. Tolvaptan bound to goat brain tubulin with a dissociation constant of 103 ± 13 µM. The binding location of tolvaptan on tubulin overlapped with that of colchicine, according to molecular docking analysis. The combination of tolvaptan with STLC augmented mitotic bock with monopolar cells, whereas its combination with vinblastine increased mitotic block with bipolar cells. Since tolvaptan is found to have a significant cytotoxic effect on HeLa cells, it can be developed as a prospective anticancer agent either alone or in combination with other antimitotic drugs. Tolvaptan was identified as an inhibitor of Eg5 in a MD simulation-based virtual screening using a combined pharmacophore model.

Side-chain cleavage enzyme deficiency: Systematic review and case series.

OBJECTIVE: P450 side-chain cleavage deficiency (SCCD) patients present with primary adrenal insufficiency (PAI) with or without undervirilized external genitalia. The distinction between classic and nonclassic steroidogenic acute regulatory protein deficiency has been described, whereas in SCCD is unclear. The data on gonadal function and its correlation with SCCD genotype has not been studied. We describe our experience and perform a systematic review of genetically proven SCCD patients to determine the distinct phenotypic and genotypic characteristics of 46,XY SCCD patients with typical male external genitalia (SCCD-TMG) and atypical (SCCD-AG) external genitalia. DESIGN, PATIENTS AND MEASUREMENTS: Retrospective review of three genetically proven SCCD patients from our centre and per-patient data analysis from a systematic review of 52 probands was performed. SCCD-TMG (n = 19) was defined as external genitalia of Sinnecker score 1 with 46,XY  karyotype; the rest (Sinnecker 2-5) were classified as SCCD-AG (n = 15). RESULTS: We report two new Indian cases of SCCD with three novel likely pathogenic variants and pubertal follow-up of a previously reported patient. In systematic review, age at diagnosis of PAI and elevated renin were not different between 46,XY  SCCD-TMG (n = 19) and SCCD-AG (n = 15), whereas spontaneous puberty (9/9 vs. 0/3, p = .0045), normal prepubertal (5/5 vs. 6/6, p = .002), pubertal gonadotropins (2/9 vs. 0/3, p = 1) and normal pubertal testosterone (9/11 vs. 0/3, p = .027) were more common in SCCD-TMG. Testicular adrenal rest tumours were exclusive to SCCD-TMG (n = 4). SCCD-TMG was associated with four particular genotypes [monoallelic p.Glu314Lys with another deleterious variant on the second allele (p.Glu314Lys/X-CHS: X-compound heterozygous state), biallelic p.Arg451Trp, p.Phe215Ser/p.Arg232Ter and monoallelic p.Val79Ile]. 46,XX SCCD  patients with p.Glu314Lys/X-CHS also had normal gonadotropins with spontaneous puberty. CONCLUSION: SCCD-TMG is associated with four specific genotypes and distinct gonadal characteristics from SCCD-AG with overlapping features of PAI.

Vanadocene dichloride induces apoptosis in HeLa cells through depolymerization of microtubules and inhibition of Eg5.

Vanadocene dichloride (VDC), a vanadium containing metallocene dihalide exhibits promising anticancer activity. However, its mechanism of action remains elusive as several diverse targets and pathways have been proposed for its anticancer activity. In this study, we observed that VDC inhibited the proliferation of mammalian cancer cells and induced apoptotic cell death by altering the mitochondrial membrane potential and the expression of bcl2 and bax. Probing further into its anticancer mechanism, we found that VDC caused depolymerization of interphase microtubules and blocked the cells at mitosis with considerable proportion of cells exhibiting monopolar spindles. The reassembly of cold depolymerized microtubules was strongly inhibited in the presence of 10 µM VDC. VDC perturbed the microtubule-kinetochore interactions during mitosis as indicated by the absence of cold stable spindle microtubules in the cells treated with 20 µM VDC. Using goat brain tubulin, we found that VDC inhibited the steady-state polymer mass of microtubules and bound to tubulin at a novel site with a Kd of 9.71 ± 0.19 µM and perturbed the secondary structure of tubulin dimer. In addition, VDC was also found to bind to the mitotic kinesin Eg5 and inhibit its basal as well as microtubule stimulated ATPase activity. The results suggest that disruption of microtubule assembly dynamics and inhibition of the ATPase activity of Eg5 could be a plausible mechanism for the antiproliferative and antimitotic activity of VDC.Graphic abstract.

Characterizing the interactions of the antipsychotic drug trifluoperazine with bovine serum albumin: Probing the drug-protein and drug-drug interactions using multi-spectroscopic approaches.

Trifluoperazine is a potent antipsychotic drug used in the treatment of neurological disorders. The usage of trifluoperazine is often found to be associated with more adverse side effects as compared to other low-potency antipsychotic agents. Plasma proteins play an inevitable role in determining the pharmacokinetic properties of a drug. Hence, this study was conducted with an aim to characterize the interactions of trifluoperazine with bovine serum albumin and determine the influence of other small molecules on its interaction with serum albumin. Trifluoperazine bound to BSA at two independent sites with Kd values of 9.5 and 172.6 µM. Förster resonance energy transfer and computational docking analysis revealed that both the binding sites of trifluoperazine were located closer to TRP 213 in subdomain IIA of BSA. Evaluation of trifluoperazine-BSA interactions at three different temperatures indicated that there was a stable complex formation between the two molecules at the ground state and that the static quenching mechanism was predominant behind these interactions. Binding studies in the presence of pharmaceutically relevant drugs indicated that warfarin, paracetamol, and caffeine negatively influenced the binding of trifluoperazine on BSA. Lastly, Fourier transformed infrared spectroscopy and circular dichroism spectroscopy indicated that the binding of trifluoperazine induced a conformational change by reducing the α-helical content of BSA. The study implicates that the small molecules which prefer binding to the Sudlow site I of BSA might compete with trifluoperazine for its binding site thereby increasing the concentration of free trifluoperazine in the plasma which could lead to adverse side effects in patients.

Bioinspired oral insulin delivery system using yeast microcapsules.

Type 1 diabetes mellitus (DM) is a metabolic disorder associated with impaired carbohydrate metabolism. We present a promising bioinspired approach against type 1 DM using yeast microcapsule (YMC). The glucan component in the outer shell of baker's yeast undergoes receptor-mediated uptake by phagocytic cells through M cell-mediated endocytosis. Thus, a drug can be expected to be delivered to the systemic circulation via lymphatic transport if it is attached to the surface of YMC. For the first time, this possibility has been explored by surface loading of insulin onto YMC. The electrostatic interaction between oppositely charged YMC and insulin resulted in the formation of insulin-loaded yeast microcapsule (IYMC) which was confirmed by fluorescence imaging. Alginate coating provided to IYMC protects YMC from the harsh environment of the gastrointestinal tract and prevents the degradation of insulin in IYMC. Cellular uptake of FITC conjugated IYMC by RAW macrophages confirmed the proposed mechanism of insulin uptake. Moreover, an in vitro method using YMC-imprinted gel was developed for insulin release study from the bioinspired system. Molecular docking studies proved the interaction of insulin with ß-glucan and alginate. A significant hypoglycemic effect was observed after oral administration of the alginate coated insulin-loaded yeast microcapsule (AL-IYMC) in diabetic rats. The AL-IYMCs could serve as a promising approach towards the oral delivery of insulin.

Biochemical and toxicological investigation of karanjin, a bio-pesticide isolated from Pongamia seed oil.

Karanjin, a furanoflavonol from Pongamia pinnata L is used in agricultural practices for its pesticidal, insecticidal and acaricidal activities. It is commercially available as a bio-pesticide targeting a wide variety of pests. The present study was intended to evaluate the biochemical interactions of karanjin with bovine serum albumin (BSA) and study its toxicological effects on mammalian and bacterial cell lines. Karanjin bound to BSA at a single site with a dissociation constant of 19.7 µM. Evaluation of BSA-karanjin interactions at three different temperatures indicated the involvement of static mode of quenching. Binding experiments in the presence of warfarin and computational docking analysis indicated that karanjin bound closer to the warfarin binding site located in the Subdomain IIA of BSA. Using Förster resonance energy transfer analysis the distance between TRP 213 of BSA and karanjin was found to be 20 Å. Collective results from synchronous fluorescence spectra analysis, differential scanning calorimetry, and circular dichroism analysis indicated that binding of karanjin induced conformational changes in the secondary structure of BSA. Karanjin exhibited low toxicity against human cervical cancer cells and normal mouse fibroblast L929 cells and modestly inhibited the growth of B. subtilis and E. coli cells. The data presented in this study provides insights for understanding the binding interactions of karanjin with BSA and its possible toxicological effects on mammalian cell lines and bacteria.

Indirubin, a bis-indole alkaloid binds to tubulin and exhibits antimitotic activity against HeLa cells in synergism with vinblastine.

Indirubin, a bis-indole alkaloid used in traditional Chinese medicine has shown remarkable anticancer activity against chronic myelocytic leukemia. The present work was aimed to decipher the underlying molecular mechanisms responsible for its anticancer attributes. Our findings suggest that indirubin inhibited the proliferation of HeLa cells with an IC50 of 40 µM and induced a mitotic block. At concentrations higher than its IC50, indirubin exerted a moderate depolymerizing effect on the interphase microtubular network and spindle microtubules in HeLa cells. Studies with goat brain tubulin indicated that indirubin bound to tubulin at a single site with a dissociation constant of 26 ±â€¯3 µM and inhibited the in vitro polymerization of tubulin into microtubules in the presence of glutamate as well as microtubule-associated proteins. Molecular docking analysis and molecular dynamics simulation studies indicate that indirubin stably binds to tubulin at the interface of the α-ß tubulin heterodimer. Further, indirubin stabilized the binding of colchicine on tubulin and promoted the cysteine residue modification by 5,5'-dithiobis-2-nitrobenzoic acid, indicating towards alteration of tubulin conformation upon binding. In addition, we found that indirubin synergistically enhanced the anti-mitotic and anti-proliferative activity of vinblastine, a known microtubule-targeted agent. Collectively our studies indicate that perturbation of microtubule polymerization dynamics could be one of the possible mechanisms behind the anti-cancer activities of indirubin.

DNA Targeting Long-Chain Alkoxy Appended Tin(IV) Porphyrin Scaffolds: Photophysical and Antimicrobial PDT Investigations.

Tin(IV) porphyrin scaffolds having long-chain (C8 and C16) alkoxyphenyl group at one meso position were synthesized with axial dichloro and dihydroxo ligands. Modifications with respect to the alkoxy chain length and the axial ligands were investigated using UV-vis and fluorescence spectroscopy as well as cyclic voltammetry. Significantly higher molar absorption coefficients were noted with dichloro axial ligands whereas higher fluorescence quantum yields were observed for C8 alkoxy chain substituents. Electrochemical redox data revealed that the porphyrin ring became difficult to reduce consequent to the presence of electron donating alkoxy chain. Evaluation of the aggregation behavior in different organic solvents and DMF-water mixture has been carried out. The singlet oxygen production and photostability data are supportive of their suitability for antibacterial photodynamic therapy. The antibacterial studies carried out in Gram negative (E. coli) and Gram positive (B. subtilis) bacteria using agar well diffusion and LB broth assay revealed selective toxicity in B. Subtilis cells. Fluorescence microscopy and competitive DNA binding studies with Hoechst 33342 revealed DNA binding at the minor groove which was further substantiated with molecular docking studies.

Biochemical and Biophysical characterization of curcumin binding to human mitotic kinesin Eg5: Insights into the inhibitory mechanism of curcumin on Eg5.

In this study we have characterized the biochemical and biophysical interactions of curcumin with the mitotic kinesin Eg5 which plays a pivotal role in the separation of centrosomes during cell division. Curcumin bound to the purified Eg5 (Eg5-437H) with a Kd value of 7.8µM. The temperature dependent binding analysis and evaluation of thermodynamic parameters indicated the involvement of static quenching mechanism in the binding process. Evidences from competition experiment with monastrol indicated that curcumin bound to Eg5 at a novel druggable site. Using Förster resonance energy transfer the distance between curcumin and monastrol binding site from TRP127 on Eg5-437H was found to be 33Å and 17Å respectively. Curcumin inhibited the ATPase activity of Eg5 motor and perturbed the dynamic interactions between Eg5 and microtubules. Results from circular dichroism studies and molecular dynamics simulations suggest that curcumin binding might perturb the Eg5-437H secondary structure which could be the reason behind its inhibitory effects on Eg5. Cell culture studies performed in HeLa cells indicated that curcumin potentiated the mitotic arrest and monopolar spindle formation in synergism with monastrol, indicating that both ligands could bind simultaneously to the same target.

Berberine Induces Toxicity in HeLa Cells through Perturbation of Microtubule Polymerization by Binding to Tubulin at a Unique Site.

Berberine has been used traditionally for its diverse pharmacological actions. It exhibits remarkable anticancer activities and is currently under clinical trials. In this study, we report that the anticancer activity of berberine could be partly due to its inhibitory actions on tubulin and microtubule assembly. Berberine inhibited the proliferation of HeLa cells with an IC50 of 18 µM and induced significant depolymerization of interphase and mitotic microtubules. At its IC50, berberine exerted a moderate G2/M arrest and mitotic block as detected by fluorescence-activated cell sorting analysis and fluorescence microscopy, respectively. In a wound closure assay, berberine inhibited the migration of HeLa cells at concentrations lower than its IC50, indicating its excellent potential as an anticancer agent. In vitro studies with tubulin isolated from goat brain indicated that berberine binds to tubulin at a single site with a Kd of 11 µM. Berberine inhibited the assembly of tubulin into microtubules and also disrupted the preformed microtubules polymerized in the presence of glutamate and paclitaxel. Competition experiments indicated that berberine could partially displace colchicine from its binding site. Results from fluorescence resonance energy transfer, computational docking, and molecular dynamics simulations suggest that berberine forms a stable complex with tubulin and binds at a novel site 24 Å from the colchicine site on the ß-tubulin. Data obtained from synchronous fluorescence analysis of the tryptophan residues of tubulin and from the Fourier transform infrared spectroscopy studies revealed that binding of berberine alters the conformation of the tubulin heterodimer, which could be the molecular mechanism behind the depolymerizing effects on tubulin assembly.

In vitro evaluation of the cytotoxic and bactericidal mechanism of the commonly used pesticide triphenyltin hydroxide.

Triphenyltin hydroxide (TPTH) is a widely used pesticide that is highly toxic to a variety of organisms including humans and a potential contender for the environmental pollutant. In the present study, the cytotoxic mechanism of TPTH on mammalian cells was analyzed using HeLa cells and the antibacterial activity was analyzed using B. subtilis and E. coli cells. TPTH inhibited the growth of HeLa cells with a half-maximal inhibitory concentration of 0.25 µM and induced mitotic arrest. Immunofluorescence microscopy analysis showed that TPTH caused strong depolymerization of interphase microtubules and spindle abnormality with the appearance of colchicine type mitosis and condensed chromosome. TPTH exhibited high affinity for tubulin with a dissociation constant of 2.3 µM and inhibited the in vitro microtubule assembly in the presence of glutamate as well as microtubule-associated proteins. Results from the molecular docking and in vitro experiments implied that TPTH may have an overlapping binding site with colchicine on tubulin with a distance of about 11 Å between them. TPTH also binds to DNA at the A-T rich region of the minor groove. The data presented in the study revealed that the toxicity of TPTH in mammalian cells is mediated through its interactions with DNA and its strong depolymerizing activity on tubulin. However, its antibacterial activity was not through FtsZ, the prokaryotic homolog of tubulin but perhaps through its interactions with DNA.