Alternative splicing generates a novel ferroportin isoform with a shorter C-terminal and an intact iron- and hepcidin-binding property.

Ferroportin (FPN) is a transmembrane protein and is the only known iron exporter that helps in maintaining iron homeostasis in vertebrates. To maintain stable iron equilibrium in the body, ferroportin works in conjunction with a peptide called hepcidin. In this study, we have identified an alternatively spliced novel isoform of the human SLC40A1 gene, which encodes for the FPN protein and is found to be expressed in different tissues. The novel transcript has an alternate last exon and encodes 31-amino acid long peptide sequence that replaces 104 amino acids at C-terminal in the novel transcript. Molecular modelling and molecular dynamics (MD) simulation studies revealed key structural features of the novel isoform (FPN-N). FPN-N was predicted to have 12 transmembrane domains similar to the reported isoform (FPN), despite being much smaller in size. FPN-N was found to interact with hepcidin, a key regulator of ferroportin activity. Also, the iron-binding sites were retained in the novel isoform as revealed by the MD simulation of FPN-N in bilipid membrane. The novel isoform identified in this study may play important role in iron homeostasis. However, further studies are required to characterize the FPN-N isoform and decipher its role inside the cell.

Identification and validation of two alternatively spliced novel isoforms of human α-1-antichymotrypsin.

α-1-antichymotrypsin (ACT) is a serine proteinase inhibitor that controls the activity of proteases like chymotrypsin, cathepsin G and mast cell chymase. Familial variants of ACT results in liver and lung diseases, but it is also reported to be associated with several other disease conditions. ACT is mainly synthesized in the liver using four coding exons, namely E1, E2, E3 and E4 encoding a 423 amino acid protein that also includes a 23 amino acid signal peptide. It is found to be associated with amyloid plaques and is elevated during inflammatory response and modulates cytokine based signal transduction pathways, independent of its anti-protease activity. Therefore, the multispecificity of ACT and its non-inhibitory roles in diseased conditions warrants an assessment of possible existence of the other isoforms. Consequently, scanning of introns, 5' and 3' region of the ACT gene using computational tools like FGENESH and FEX did indicate the presence of coding regions. Using a combined approach of bioinformatics and molecular biology, we have found one novel exon located in the intronic region between exons E1 and E2, that splices with exon E2 and replaces N-terminal exon E1, generating an ACT isoform with a novel 151 base pair N-terminus. This isoform was found to lack the signal sequence and is smaller in size but its reactive centre loop remains intact. A truncated transcript was also confirmed with an extension of the E3 by a 12 nucleotide intronic region including a stop codon. Modelling studies show that due to removal of E4 this isoform lacks the RCL. Novel isoform ACT-N lacks E1 but has a conserved RCL. However, due to loss of strands of ß-sheet A, it may also be inactive, but with ability to bind the target proteases. The novel truncated ACT-T isoform lacks the RCL and may have a non-inhibitory role. These hypothesis will need further work for functional validation.

Interaction of memantine with calf thymus DNA: an in-vitro and in-silico approach and cytotoxic effect on the cancerous cell lines.

Memantine belongs to the class of cognition enhancers that functions as NMDA receptor antagonist, used to treat Alzheimer's disease. The interaction of memantine with DNA was not investigated. In the present study, the interaction of memantine with ct-DNA, as well as its cytotoxicity on cancer cells, was evaluated. UV-visible spectroscopy, steady-state fluorescence spectroscopic studies revealed the interaction between memantine and ct-DNA. The quenching studies, chemical denaturation, (CD), and DNA melting studies showed the groove binding mode of memantine with ct-DNA. The thermodynamic parameters revealed that the interaction between memantine and ct-DNA is enthalpically driven, and the stabilizing forces involved were hydrogen bonding and van der Waals interaction. The groove-binding was also observed by molecular docking studies, which corroborated the findings of spectroscopic investigations. Density function theory calculations confirmed the existence of electron donor and recipient groups. The stability of memantine and DNA interaction, as well as the critical residues involved in the interaction, was identified by molecular dynamics simulations. Memantine showed cytotoxicity towards the cancer cells as compared to normal cells, as observed by MTT assay. Inverted compound microscopy analysis of memantine treated cancer cell lines further confirmed the results obtained by MTT assay.Communicated by Ramaswamy H. Sarma.

Studying the interaction of scopolamine with calf-thymus DNA: An in-vitro and in-silico approach and genotoxicity.

Scopolamine is used to treat various CNS disorder like urinary incontinence, motion sickness, spasmic movements. Despite its pharmaceutical properties, its interaction with DNA is not yet reported. In this article, the interaction between scopolamine and ct-DNA is reported using a combination of biophysical techniques. UV-visible and steady-state fluorescence spectroscopy were used to study interaction and complex formation. Competitive displacement assays and potassium iodide quenching confirmed the mode of binding between scopolamine and DNA. Structural changes induced in the ct-DNA in the presence of scopolamine were evaluated by CD spectroscopy. The plasmid nicking and NBT assay confirmed the genotoxic effect of scopolamine. In-silico study by molecular docking and molecular dynamics simulation revealed the mode of interaction, major stabilizing forces as well as the nucleotide sequences to which the scopolamine binds.

Whole-Exome Sequencing Reveals a Rare Variant of OTOF Gene Causing Congenital Non-syndromic Hearing Loss Among Large Muslim Families Favoring Consanguinity.

Non-syndromic hearing loss (NSHL) is one of the most frequent auditory deficits in humans characterized by high clinical and genetic heterogeneity. Very few studies have reported the relationship between OTOF (Locus: DFNB9) and hereditary hearing loss in India. We aimed to decipher the genetic cause of prelingual NSHL in a large affected Muslim consanguineous families using whole-exome sequencing (WES). The study was performed following the guidelines and regulations of the Indian Council of Medical Research (ICMR), New Delhi. The population was identified from Jammu and Kashmir, the Northernmost part of India. Near about 100 individuals were born deaf-mute in the village of 3,000 inhabitants. A total of 103 individuals (with 52 cases and 51 controls) agreed to participate in this study. Our study revealed a rare non-sense homozygous mutation NC_000002.11:g.2:26702224G>A; NM_001287489.2:c.2122C>T; NP_001274418.1:p.(Arg708∗) in the 18th exon of the OTOF gene. Our study provides the first insight into this homozygous condition, which has not been previously reported in ExAC, 1,000 Genome and genomAD databases. Furthermore, the variant was confirmed in the population cohort (n = 103) using Sanger sequencing. In addition to the pathogenic OTOF variant, the WES data also revealed novel and recurrent mutations in CDH23, GJB2, MYO15A, OTOG, and SLC26A4 genes. The rare pathogenic and the novel variants observed in this study have been submitted to the ClinVar database and are publicly available online with the accessions SCV001448680.1, SCV001448682.1 and SCV001448681.1. We conclude that OTOF-related NSHL hearing loss is prevalent in the region due to successive inbreeding in its generations. We recommend premarital genetic testing and genetic counseling strategies to minimize and control the disease risk in future generations.

Alternative exon splicing and differential expression in pancreatic islets reveals candidate genes and pathways implicated in early diabetes development.

Type 2 diabetes (T2D) has a strong genetic component. Most of the gene variants driving the pathogenesis of T2D seem to target pancreatic ß-cell function. To identify novel gene variants acting at early stage of the disease, we analyzed whole transcriptome data to identify differential expression (DE) and alternative exon splicing (AS) transcripts in pancreatic islets collected from two metabolically diverse mouse strains at 6 weeks of age after three weeks of high-fat-diet intervention. Our analysis revealed 1218 DE and 436 AS genes in islets from NZO/Hl vs C3HeB/FeJ. Whereas some of the revealed genes present well-established markers for ß-cell failure, such as Cd36 or Aldh1a3, we identified numerous DE/AS genes that have not been described in context with ß-cell function before. The gene Lgals2, previously associated with human T2D development, was DE as well as AS and localizes in a quantitative trait locus (QTL) for blood glucose on Chr.15 that we reported recently in our N2(NZOxC3H) population. In addition, pathway enrichment analysis of DE and AS genes showed an overlap of only half of the revealed pathways, indicating that DE and AS in large parts influence different pathways in T2D development. PPARG and adipogenesis pathways, two well-established metabolic pathways, were overrepresented for both DE and AS genes, probably as an adaptive mechanism to cope for increased cellular stress. Our results provide guidance for the identification of novel T2D candidate genes and demonstrate the presence of numerous AS transcripts possibly involved in islet function and maintenance of glucose homeostasis.

Detection of truncated isoforms of human neuroserpin lacking the reactive center loop: Implications in noninhibitory role.

Neuroserpin is a serine protease inhibitor expressed mainly in the brain and at low levels in other tissues like the kidney, testis, heart, and spinal cord. It is involved in the inhibition of tissue plasminogen activator (tPA), plasmin, and to a lesser extent, urokinase-type plasminogen (uPA). Neuroserpin has also been shown to plays noninhibitory roles in the regulation of N-cadherin-mediated cell adhesion. It is involved in neuroprotection from seizure and stroke through tPA-mediated inhibition and also through its other protease targets. Mutations in critical domains of neuroserpin lead to its polymerization and neuronal death. In this study, a novel truncated isoform of human neuroserpin was identified in the brain and liver, which was confirmed by reverse transcriptase-PCR and DNA sequencing using exon-specific primers. Structural characterization of novel isoform using MD simulations studies indicated that it lacks the reactive center loop (RCL) but largely maintains its secondary structure fold. The novel truncated variant was cloned, expressed, and purified. A comparative intrinsic fluorescence and 4,4'-bis-1-anilino naphthalene 8-sulfonate studies revealed a decrease in fluorescence emission intensity and a more exposed hydrophobic surface as compared to the reported isoform. However, the novel isoform has lost its ability for tPA inhibition and complex formation. The absence of RCL indicates a noninhibitory role for the truncated isoform, prompting a detailed search and identification of two smaller isoforms in the human brain. With indications of the noninhibitory role of neuroserpin, identifying novel isoforms that appear to be without the tPA recognition domain is significant.

Investigating the mechanism of binding of nalidixic acid with deoxyribonucleic acid and serum albumin: a biophysical and molecular docking approaches.

Nalidixic acid is a bacterial DNA gyrase inhibitor and the first member of the synthetic quinolone antibiotics. It is used in the treatment of various infectious diseases like urinary tract infections, respiratory infections, sexually transmitted diseases, acute bronchitis, and sinusitis. Interactions studies are of great significance as it will be beneficial for designing new therapeutic molecules with preferable plasma solubility and its efficacy. In this paper, we have aim to ascertain the binding mode of nalidixic acid with calf thymus DNA (ct-DNA) and bovine serum albumin (BSA) through various biophysical and in silico method. UV-visible absorption and fluorescence spectroscopic experiments confirmed the formation of a complex between nalidixic acid with ct-DNA. The binding constant is in the range of 103 M-1, indicating the groove binding mode between ct-DNA and nalidixic acid. Groove binding mode was also validated by competitive displacement assay, potassium iodide quenching experiment, circular dichroism, DNA melting studies. In the case of BSA, UV-visible absorption and fluorescence spectroscopic experiments confirmed the formation of a complex between nalidixic acid with BSA. The value of a binding constant in the case of BSA was found to be 1.517 × 105 M-1. The site marker displacement experiment revealed the binding location of nalidixic acid to a site I in BSA. Secondary structural and microenvironmental changes also studied through circular dichroism and three-dimensional fluorescence. Furthermore, the synchronous fluorescence spectra of BSA with nalidixic acid showed that there were changes in the microenvironment around tryptophan residues. In silico molecular docking further confirmed the binding of nalidixic acid to site I in BSA and the minor groove of DNA.Communicated by Ramaswamy H. Sarma.

Identification and characterization of a novel isoform of heparin cofactor II in human liver.

Heparin cofactor II (HCII) is predominantly expressed in the liver and inhibits thrombin in blood plasma to influence the blood coagulation cascade. Its deficiency is associated with arterial thrombosis. Its cleavage by neutrophil elastase produces fragment that helps in neutrophil chemotaxis in the acute inflammatory response in human. In the present study, we have identified a novel alternatively spliced transcript of the HCII gene in human liver. This novel transcript includes an additional novel region in continuation with exon 3 called exon 3b. Exon 3b acts like an alternate last exon, and hence its inclusion in the transcript due to alternative splicing removes exon 4 and encodes for a different C-terminal region to give a novel protein, HCII-N. MD simulations of HCII-N and three-dimensional structure showed a unique 51 amino acid sequence at the C-terminal having unique RCL-like structure. The HCII-N protein purified from bacterial culture showed a protein migrating at lower molecular weight (MW 55 kDa) as compared to native HCII (MW 66 kDa). A fluorescence-based analysis revealed a more compact structure of HCII-N that was in a more hydrophilic environment. The HCII-N protein, however, showed no inhibitory activity against thrombin. Due to large conformational variation observed in comparison with native HCII, HCII-N may have alternate protease specificity or a non-inhibitory role. Western blot of HCII purified from large plasma volume showed the presence of a low MW 59 kDa band with no thrombin activity. This study provides the first evidence of alternatively spliced novel isoform of the HCII gene.

Alternative splicing of ACE2 possibly generates variants that may limit the entry of SARS-CoV-2: a potential therapeutic approach using SSOs.

Angiotensin-converting enzyme 2 (ACE2) plays an essential role in maintaining the balance of the renin-angiotensin system and also serves as a receptor for the SARS-CoV-2, SARS-CoV, and HCoV-NL63. Following the recent outbreak of SARS-CoV-2 infection, there has been an urgent need to develop therapeutic interventions. ACE2 is a potential target for many treatment approaches for the SARS-CoV-2. With the help of bioinformatics, we have predicted several novel exons of the human ACE2 gene. The inclusion of novel exons located in the 5'UTR/intronic region in the mature transcript may remove the critical ACE2 residues responsible for the interaction with the receptor-binding domain (RBD) of SARS-CoV-2, thus preventing their binding and entry into the cell. Additionally, inclusion of a novel predicted exons located in the 3'UTR by alternative splicing may remove the C-terminal transmembrane domain of ACE2 and generate soluble ACE2 isoforms. Splice-switching antisense oligonucleotides (SSOs) have been employed effectively as a therapeutic strategy in several disease conditions. Alternative splicing of the ACE2 gene could similarly be modulated using SSOs to exclude critical domains required for the entry of SARS-CoV-2. Strategies can also be designed to deliver these SSOs directly to the lungs in order to minimize the damage caused by SARS-CoV-2 pathogenesis.

Structural alteration in hypochlorous acid modified antithrombin indicates generation of neo-epitopes.

Increased tendency of cancer patients to develop venous thromboembolism (VTE) is associated with high rates of mortality. Elevation of procoagulant proteins and down regulation of naturally occurring coagulation inhibitors appears to form the basis of high risk of VTE in malignancy. A reduced level of anticoagulant protein like antithrombin (AT) will influence both coagulation and angiogenesis, as its cleaved and latent conformations show potent antiangiogenic activity. We show a concentration dependent perturbation in the secondary and tertiary structures of AT conformers exposed to hypochlorous acid (HOCl). Modulated under a very narrow concentration range of HOCl, native AT undergoes oligomerization, aggregation and fragmentation based on spectroscopic, SDS and native-PAGE studies. Factor Xa inhibition assay demonstrated a progressive decrease in inhibition activity of AT on modification by HOCl. Bis-ANS result showed that hydrophobic patches were more exposed in the case of HOCl-modified AT when assessed fluorometrically. Dosage of HOCl-modified AT in experimental animals induced high titer antibodies showing more specificity towards modified forms in comparison to unmodified forms. Auto-antibodies isolated from cancer patients also showed enhanced binding with HOCl-modified AT in comparison to native counterpart. Compared to normal AT, structurally and functionally altered conformation of HOCl-modified AT showed increased immunogenic sensitivity. HOCl modified AT can contribute to prothrombotic and angiogenic environment during cancer progression/development.

Identification of a novel alternatively spliced isoform of antithrombin containing an additional RCL-like loop.

Antithrombin (AT3) is one of the most important inhibitors of blood coagulation proteases that belong to the serpin family of protease inhibitors. In this study, a novel alternatively spliced isoform of AT3 was identified, both at transcript and protein level. This novel transcript contains an additional region in the continuation of exon 3b that was included in the transcript due to use of an alternate 5' splice site. The existence of the novel transcript was confirmed in human brain and liver through RT-PCR. An analysis of the complete transcript indicated that the native reactive centre loop (RCL) of AT3 is maintained; however the novel amino acid sequence projects out as an additional loop as evident from MD simulation studies. A unique amino acid sequence present in the novel isoform was used for the development of polyclonal antibody. The expression of novel isoform was confirmed in human brain and liver tissue using Western blot analysis. Interestingly an alignment of RCL like domain with other inhibitory serpins showed significant similarity with the neuroserpin RCL. To the best of our knowledge, this is the first evidence of alternatively spliced AT3 sequence containing an additional loop and could have physiological relevance.

Identification and expression of alternatively spliced novel isoforms of cancer associated MYD88 lacking death domain in mouse.

MYD88 is an adaptor protein known to involve in activation of NF-κB through IL-1 receptor and TLR stimulation. It consists of N-terminal death domain and C-terminal Toll/IL-R homology domain that mediates its interaction with IL-1R associated kinase and IL-1R/TLR, respectively. MYD88 contributes to various types of carcinogenesis due to its involvement in oncogene induced inflammation. In the present study, we have recognized two new alternatively spliced variants of MyD88 gene in mouse using bioinformatics tools and molecular biology techniques in combination. The newly identified non-coding exon (NE-1) from 5' upstream region alternatively splices with either exon E-2 or exon E-5 to produce two novel transcript variants MyD88N1 and MyD88N2 respectively. The transcript variant MyD88N1 was expressed in several tissues studied while the variant MyD88N2 was found to be expressed only in the brain. The analysis of the upstream region of novel exon by in silico approach revealed new promoter region PN, which possess potential signature sequences for diverse transcription factors, suggesting complex gene regulation. Studies of post translational modifications of conceptualized amino acid sequences of these isoforms revealed diversity in properties. Western blot analysis further confirmed the expression of protein isoform MYD88N1.

Differentially expressed novel alternatively spliced transcript variant of tumor suppressor Stk11 gene in mouse.

Serine/threonine kinase 11 (STK11) is a protein kinase that is encoded by Stk11 gene located on chromosome 19 and 10 in humans and mouse respectively. It acts as a master kinase of adenine monophosphate-activated protein kinase (AMPK) pathway that coordinates the regulation of cellular energy metabolism and cell division. STK11 exerts effect by activating more than 14 kinases including AMPK and AMPK-related kinases. It is also known to regulate cell polarity and acts as tumor suppressor. Alternative splicing of pre-mRNA is a mechanism which results in multiple transcript variants of a single gene. In human, two STK11 isoforms have been reported, an alternatively spliced isoform which has variation at its C-terminal and mostly expressed in testis (LKB1S). Another isoform exhibiting oncogenic properties lacks few residues at its N-terminal (ΔN-LKB1). In the present study, we report the identification of a new transcript variant Stk11N which is generated through alternative splicing. The new variant was found to have differential and tissue specific expression at Postnatal-7 and adult stages of mouse. As compared to the known variant Stk11C, the conceptually translated amino acid sequences of the new variant differ from exon-E2 onwards. In silico post translational studies of the new and published variant show similarity in some of the properties while differ in properties like nuclear export signals, phosphorylation, glycosylation, etc. Thus, alternative splicing of Stk11 gene generating new variant with heterogeneous properties suggests for complex regulation of these variants in controlling the AMPK pathway and other functions.

Identification and expression analysis of alternatively spliced new transcript isoform of Bax gene in mouse.

Bax, a pro-apoptotic member of Bcl-2 family regulates apoptosis through homodimerization/heterodimerization with Bcl-2. Bax-α is the only product of the Bax gene that has been extensively studied. Bax-α exists in inactive form and several conformational changes are required during apoptosis to activate it. Here, we have identified a novel transcript variant of Bax gene in mouse which contains alternatively spliced new first exon that is different from the first exon of previously reported transcript. Conceptual translation of new transcript encodes a protein (Bax-α1), having different N-terminus. The existence of the new transcript variant was confirmed by reverse transcriptase-PCR, semi-nested PCR using primers designed for the newly identified transcript variant. The identity of PCR product obtained after semi-nested PCR was confirmed by DNA sequencing. Relative expression of new transcript variant with respect to reported transcript was also studied with the help of real time PCR. The existence of new transcript variant was further supported by the presence of clusters of overlapping ESTs from the database. Bax-α1 possibly displays heterogeneous properties as predicted by post-translational modification analysis tools. The differences in post-translational modifications might play important roles in divergent function of the new isoform. The three dimensional structure was generated by homology modelling to visualize the differences at N termini of known and newly identified variant.

Caffeic acid binds to the minor groove of calf thymus DNA: A multi-spectroscopic, thermodynamics and molecular modelling study.

Caffeic acid (CA) is a plant polyphenol which acts as an antioxidant and has various pharmacological effects. DNA is one of the major cellular targets of therapeutic molecules. Thus, studying the interaction of small molecules with DNA is of great importance. In the current article, we have studied the mode of binding of CA with calf thymus DNA (Ct-DNA) using a series of biophysical techniques. Formation of complex between CA and Ct-DNA is ascertained by analyzing the UV-vis absorbance and fluorescence emission spectra of CA upon successive addition of Ct-DNA. Binding constants of CA with Ct-DNA obtained using multiple experiments was in the order of 103 M-1 which is consistent with known groove binders. Analysis of thermodynamic parameters suggest that hydrogen bonding and van der Waal's forces played major role in the binding process. Competitive displacement studies confirmed that CA binds to the minor groove of Ct-DNA. These observations were further validated by KI quenching experiment, DNA melting studies, CD and viscosity measurements. In silico molecular docking further provided insight into the mode of binding of CA with Ct-DNA. Through in vitro experiments and in silico molecular docking studies, it was concluded that CA binds to the minor groove of Ct-DNA.

Identification of two novel isoforms of mouse NUR77 lacking N-terminal domains.

Nur77 is a member of nuclear receptor superfamily that acts as a transcription factor and regulates expression of multiple genes. Subcellular localization of Nur77 protein plays an important role in the survival and cell death. In this study, we have predicted and confirmed alternatively spliced two new transcripts of Nur77 gene in mouse. The newly identified transcripts have their alternatively spliced first exon located upstream of published 5'-UTR of the gene. Transcription factor binding sites in the possible promoter regions of these transcripts were also analyzed. Expression of novel transcript variants was found to be significantly lower than the already published transcript. New transcript variants encode for NUR77 protein isoforms which are significantly smaller in size due to lack of transactivation domain and a part of DNA binding domain. Western blot analysis using NUR77 specific antibody confirmed the existence of these smaller variants in mouse. Localization of these new isoforms was predicted to be majorly outside the nucleus. In silico analysis of the conceptually translated proteins was performed using different bioinformatics tools. The results obtained in this study offer further insight into novel area of research on extensively studied Nur77. © 2017 IUBMB Life, 69(2):106-114, 2017.

Interaction of indomethacin with calf thymus DNA: a multi-spectroscopic, thermodynamic and molecular modelling approach.

Indomethacin belongs to the acetic acid derivative class of non-steroidal anti-inflammatory drugs with diverse pharmacological and biological activities. Understanding the mechanism of interaction of drugs with possible target and off-target biomolecules can prove useful in the development of a rational drug designing system. In this paper, we have attempted to ascertain the mode of binding of indomethacin with calf thymus DNA (Ct-DNA) through various biophysical techniques and in silico molecular docking. Analysis of the UV-visible absorbance spectra and fluorescence emission profile of indomethacin upon addition of Ct-DNA indicates the formation of a drug-DNA complex. UV-visible absorbance and steady state fluorescence experiments revealed a binding constant on the order of 103 L mol-1, which is consistent with those of well-known groove binders. Competitive displacement studies with ethidium bromide, acridine orange and Hoechst 33258 further suggested that indomethacin binds to the minor groove of the Ct-DNA. The above observations were further confirmed by KI induced quenching experiments, DNA melting studies, CD spectral analysis and viscosity measurements. The thermodynamic parameters like spontaneous free energy (ΔG < 0) and large favourable enthalpy (ΔH < 0) obtained from isothermal calorimetry indicated the involvement of hydrogen bonding and van der Waals forces in the binding process. Molecular docking further corroborated the experimental results.

A novel exon generates ubiquitously expressed alternatively spliced new transcript of mouse Abcc4 gene.

Abcc4 gene codes for a protein (ABCC4) involved in the transportation of different classes of drugs outside the cells. Various important drugs transported by ABCC4 include antiviral and anticancer drugs as well as endogenous molecules such as bile acids, cyclic nucleotides, folates, prostaglandins and steroids. Alternative splicing generates multiple mRNAs that encode protein isoforms having diverse functions. In this study, we have identified a novel transcript of mouse Abcc4 gene using a combination of bioinformatics and molecular biology techniques. This transcript was found to be different from the reported transcript in having a different first exon that was found to be located on previously identified first intron. Newly identified transcript was found to be expressed across different tissues we studied and in different developmental stages. Expression level of novel and reported transcripts was studied using quantitative real-time PCR. After conceptually translating the novel transcript, various post-translational modifications were studied. Translation efficiency and predicted half life of encoded protein isoforms were analysed in silico. Molecular modelling was performed to compare the structural differences in both isoforms. The diversity at N-termini in these protein isoforms explains the diverse function of ABCC4 in mouse.

Structure elucidation and DNA binding specificity of natural compounds from Cassia siamea leaves: A biophysical approach.

A novel isoflavone, 5,6,7-trimethoxy-3-(3',4',5'-trimethoxyphenyl)-4H-chromen-4-one (1) along with a known pyranocoumarin, Seselin (2) have been isolated from the ethanolic extract of the leaves of Cassia siamea (Family: Fabaceae). Compound 1 has been reported for the first time from any natural source and has not been synthesized so far. Their structures were elucidated on the basis of chemical and physical evidences viz. elemental analysis, UV, FT-IR, (1)H-NMR, (13)C-NMR and mass spectral analysis. Structure of compound (1) was further authenticated by single-crystal X-ray analysis and density functional theory (DFT) calculations. A multi-technique approach employing UV-Visible spectroscopy, fluorescence, KI quenching studies, competitive displacement assay, circular dichroism and viscosity studies have been utilized to probe the extent of interaction and possible binding modes of isolated compounds (1-2) with calf thymus DNA (CT-DNA). Both the compounds were found to interact with DNA via non-intercalative binding mode with moderate proficiencies. Groove binding was the major interaction mode in the case of compound 2 while compound 1 probably interacts with DNA through electrostatic interactions. These studies provide deeper insight in understanding of DNA-drug (natural products) interaction which could be helpful to improve their bioavailability for therapeutic purposes.