Molecular basis for stereoselective transport of fenoterol by the organic cation transporters 1 and 2.

Stereoselectivity is important in many pharmacological processes but its impact on drug membrane transport is scarcely understood. Recent studies showed strong stereoselective effects in the cellular uptake of fenoterol by the organic cation transporters OCT1 and OCT2. To provide possible molecular explanations, homology models were developed and the putative interactions between fenoterol enantiomers and key residues explored in silico through computational docking, molecular dynamics simulations, and binding free energy calculations as well as in vitro by site-directed mutagenesis and cellular uptake assays. Our results suggest that the observed 1.9-fold higher maximum transport velocity (vmax) for (R,R)- over (S,S)-fenoterol in OCT1 is because the enantiomers bind to two distinct binding sites. Mutating PHE355 and ILE442, predicted to interact with (R,R)-fenoterol, reduced the vmax ratio to 1.5 and 1.3, respectively, and to 1.2 in combination. Mutating THR272, predicted to interact with (S,S)-fenoterol, slightly increased stereoselectivity (vmax ratio of 2.2), while F244A resulted in a 35-fold increase in vmax and a lower affinity (29-fold higher Km) for (S,S)-fenoterol. Both enantiomers of salbutamol, for which almost no stereoselectivity was observed, were predicted to occupy the same binding pocket as (R,R)-fenoterol. Unlike for OCT1, both fenoterol enantiomers bind in the same region in OCT2 but in different conformations. Mutating THR246, predicted to interact with (S,S)-fenoterol in OCT2, led to an 11-fold decreased vmax. Altogether, our mutagenesis results correlate relatively well with our computational predictions and thereby provide an experimentally-corroborated hypothesis for the strong and contrasting enantiopreference in fenoterol uptake by OCT1 and OCT2.

Structural facets of POU2F1 in light of the functional annotations and sequence-structure patterns.

POU domain class 2 homebox 1 or POU2F1 is broadly known as an important transcription factor. Due to its association with different types of malignancies, POU2F1 became one of the key factors in pancancer analysis. However, in spite of considering this protein as a potential drug target, none of the drug targeting POU2F1 has been designed as of yet due to the extreme structural flexibility of this protein. In this article, we have proposed a three-level comprehensive framework for understanding the structural conservation and co-variation of POU2F1. First, a gene regulatory network based on the normal and pathological functions of POU2F1 has been created for better understanding the strong association between POU2F1 deregulation and cancers. After that, based on the evolutionary sequence space analysis, the comparative sequence dynamics of the protein members of POU domain family has been studied mostly between non-human and human species. Subsequently, the reciprocity effect of the residual co-variation has been identified through direct coupling analysis. Along with that, the structure of POU2F1 has been analyzed depending on quality assessment and normal mode-based structure network. Comparing the sequence and structure space information, the most significant set of residues viz., 3, 9, 13, 17, 20, 21, 28, 35, and 36 have been identified as structural facet for function. This study demonstrates that the structural malleability of POU2F1 serves as one of the prime reason behind its functional multiplicity in terms of protein moonlighting. Communicated by Ramaswamy H. Sarma.

Comprehensive in-silico analysis of damage associated SNPs in hOCT1 affecting Imatinib response in chronic myeloid leukemia.

Non-synonymous single nucleotide polymorphisms (nsSNPs) in hOCT1 (encoded by SLC22A1 gene) are expected to affect Imatinib uptake in chronic myeloid leukemia (CML). In this study, sequence homology-based genetic analysis of a set of 270 coding SNPs identified 18 nsSNPs to be putatively damaging/deleterious using eight different algorithms. Subsequently, based on conservation of amino acid residues, stability analysis, posttranscriptional modifications, and solvent accessibility analysis, the possible structural-functional relationship was established for high-confidence nsSNPs. Furthermore, based on the modeling results, some dissimilarities of mutant type amino acids from wild-type amino acids such as size, charge, interaction and hydrophobicity were revealed. Three highly deleterious mutations consisting of P283L, G401S and R402G in SLC22A1 gene that may alter the protein structure, function and stability were identified. These results provide a filtered data to explore the effect of uncharacterized nsSNP and find their association with Imatinib resistance in CML.

Assessment of Interaction of Human OCT 1-3 Proteins and Metformin Using Silico Analyses.

Metformin, a drug frequently used by diabetic patients as the first-line treatment worldwide, is positively charged and is transported into the cell through human organic cation transporter (hOCT 1-3) proteins. We aimed to mimic the cellular uptake of metformin by hOCT1-3 with various bioinformatics methods and tools. 3D structure of OCT1-3 proteins was predicted by considering the structures and function of these proteins. We predicted functional regions (active and ligand binding sites) of OCT1-3 and performed comparative bioinformatics analysis. The predicted structure of hOCT1-3 was then analyzed in the Blind Docking server and the results were confirmed with predicted binding site residues and conserved domain regions. We simulated the OCT1-3 and metformin docking and also validated the docking procedure with other substrates of HOCT1-3 proteins. We selected the best poses of metformin docking simulations as per binding energy (-5.27 to -4.60 kcal/mol). Lastly, we validated the static description of protein-ligand (OCT-Metformin) interactions by performing molecular dynamics simulation. Eventually, we obtained stable simulation of OCT-metformin interaction.

Transcriptional co-repressor CtBP2 orchestrates epithelial-mesenchymal transition through a novel transcriptional holocomplex with OCT1.

The epithelial to mesenchymal transition (EMT) is a cell intrinsic program controlling cellular morphological and phenotypic remodeling in a wide range of biological processes. Despite the accumulating evidence, the transcriptional networks regulating EMT still remain to be elucidated. In this study, we demonstrate that C-terminal binding protein 2 (CtBP2), a critical transcriptional co-repressor harboring pyridine nucleotide sensing capability, orchestrates the EMT program at least in part through a novel transcriptional interaction with an octamer transcription factor, OCT1 (POU2F1, POU class 2 homeobox 1). We identified novel interactions of CtBP2 with several octamer transcription factors, and CtBP2 exhibits a direct interaction with OCT1 in particular. OCT1 accelerates the EMT program as reported, which is diminished by the mutation of the CtBP-binding motif in OCT1, suggesting OCT1 represses epithelial gene expression through recruiting the co-repressor CtBP2. In accordance with these findings, a canonical EMT activator transforming growth factor-ß (TGF-ß) promotes the formation of the CtBP2/OCT1 complex. Our observations illustrate the role of CtBP2 to orchestrate the EMT program through the interaction with OCT1 and highlight the potential of therapeutic exploitation of this new transcriptional system for a wide range of diseases.

[Multiple Interactions of the Oct-1 (POU2F1) Transcription Factor with PORE and MORE Sites].

The Oct-1 (POU2F1) transcription factor is one of the most important regulatory proteins in humans and other mammals. An increase in Oct-1 aids the resistance to oxidative and cytotoxic stresses and radiation exposure. A high level of Oct-1 is found in many human tumors and correlates with low survival. Oct-1 interacts with its binding sites as a monomer, a homodimer, or a multimer. The nucleotide sequence of the Oct-1 binding site determines the character of interaction and the conformation of Oct-1 on target DNA, thus influencing the binding of Oct-1 co-repressors and co-activators. Nucleotide substitutions were introduced in all positions of the PORE and MORE sequences and tested for effect on the Oct-1 capability of forming monomeric and dimeric DNA-protein complexes. The position and nature of nucleotide substitutions were found to affect the type of Oct-1 binding to DNA. Several substitutions suppressed the formation of dimers, while others stimulated the process. Certain nucleotide substitutions completely prevented the binding of both monomers and dimers. The Oct-1 concentration in the cell is another factor that affects the character of DNA-protein interactions. Based on the results, the nature and affinity of interaction with Oct-1 is possible to predict from the nucleotide sequence for PORE and MORE sites of the human genome.

Different N-terminal isoforms of Oct-1 control expression of distinct sets of genes and their high levels in Namalwa Burkitt's lymphoma cells affect a wide range of cellular processes.

Oct-1 transcription factor has various functions in gene regulation. Its expression level is increased in several types of cancer and is associated with poor survival prognosis. Here we identified distinct Oct-1 protein isoforms in human cells and compared gene expression patterns and functions for Oct-1A, Oct-1L, and Oct-1X isoforms that differ by their N-terminal sequences. The longest isoform, Oct-1A, is abundantly expressed and is the main Oct-1 isoform in most of human tissues. The Oct-1L and the weakly expressed Oct-1X regulate the majority of Oct-1A targets as well as additional sets of genes. Oct-1X controls genes involved in DNA replication, DNA repair, RNA processing, and cellular response to stress. The high level of Oct-1 isoforms upregulates genes related to cell cycle progression and activates proliferation both in Namalwa Burkitt's lymphoma cells and primary human fibroblasts. It downregulates expression of genes related to antigen processing and presentation, cytokine-cytokine receptor interaction, oxidative metabolism, and cell adhesion, thus facilitating pro-oncogenic processes.

On the origin of POU5F1.

BACKGROUND: Pluripotency is a fundamental property of early mammalian development but it is currently unclear to what extent its cellular mechanisms are conserved in vertebrates or metazoans. POU5F1 and POU2 are the two principle members constituting the class V POU domain family of transcription factors, thought to have a conserved role in the regulation of pluripotency in vertebrates as well as germ cell maintenance and neural patterning. They have undergone a complex pattern of evolution which is poorly understood and controversial. RESULTS: By analyzing the sequences of POU5F1, POU2 and their flanking genes, we provide strong indirect evidence that POU5F1 originated at least as early as a common ancestor of gnathostomes but became extinct in a common ancestor of teleost fishes, while both POU5F1 and POU2 survived in the sarcopterygian lineage leading to tetrapods. Less divergent forms of POU5F1 and POU2 appear to have persisted among cartilaginous fishes. CONCLUSIONS: Our study resolves the controversial evolutionary relationship between teleost pou2 and tetrapod POU2 and POU5F1, and shows that class V POU transcription factors have existed at least since the common ancestor of gnathostome vertebrates. It provides a framework for elucidating the basis for the lineage-specific extinctions of POU2 and POU5F1.

Development of a plasmid display system with an Oct-1 DNA-binding domain suitable for in vitro screening of engineered proteins.

Owing to simple mechanism of linking and efficient display of proteins, plasmid display system in which proteins are physically linked to plasmids, has been considered as a promising emerging tool in protein engineering. We used human Oct-1 DNA-binding domain (DBD) which can bind to octameric DNA sequence (5'-ATGCAAAT-3') with high affinity, as a potential anchoring motif for plasmid display system. Using three model proteins, histidine hexamer (His6), glutathione S-transferase (GST) and antibody fragment, we confirmed that Oct-1 DBD fused proteins were strongly linked to plasmids and their linking were conserved for entire process of in vitro selection. Also, the feasibility of this display system was examined using several enrichment experiments from binary libraries. Using Oct-1 plasmid display system, the GST-displayed plasmids were successfully enriched 8500-fold from a large excess (104 fold) of negatives (non-GST plasmid). From the results, Oct-1 DBD-based plasmid display system allows the rapid and facile in vitro selection and can be a useful tool in discovering functional proteins from large libraries.

Gap junctions mediate STAT5-independent ß-casein expression in CID-9 mammary epithelial cells.

Crosstalk between gap junction intracellular communication (GJIC), STAT5 and OCT-1 in gap junction (GJ)-dependent ß-casein expression was investigated. CID-9 mammary cells plated with prolactin on non-adherent substratum (poly-HEMA) expressed ß-casein independent of STAT5 only in the presence of the GJIC inducer, cAMP. Nuclear STAT5 levels were not detectable. By contrast, cells on EHS-drip expressed ß-casein in a STAT5-dependent manner and nuclear STAT5 levels were up-regulated. A 75 kDa OCT-1 isoform was detected in conditions that induced ß-casein expression regardless of substratum. Interestingly, 40 and 28 kDa OCT-1 isoforms were induced in cells on polyHEMA with cAMP. Electrophoretic mobility shift assays (EMSA) for OCT-1 revealed two band shifts in cells on polyHEMA with cAMP and on EHS-drip, which were repressed by the GJIC inhibitor, 18α-GA. These studies demonstrated that mammary cells on polyHEMA expressed ß-casein in response to prolactin in a pathway that involves GJIC and OCT-1 and is independent of STAT5 nuclear translocation.

Dynamic regulation of Oct1 during mitosis by phosphorylation and ubiquitination.

BACKGROUND: Transcription factor Oct1 regulates multiple cellular processes. It is known to be phosphorylated during the cell cycle and by stress, however the upstream kinases and downstream consequences are not well understood. One of these modified forms, phosphorylated at S335, lacks the ability to bind DNA. Other modification states besides phosphorylation have not been described. METHODOLOGY/PRINCIPAL FINDINGS: We show that Oct1 is phosphorylated at S335 in the Oct1 DNA binding domain during M-phase by the NIMA-related kinase Nek6. Phospho-Oct1 is also ubiquitinated. Phosphorylation excludes Oct1 from mitotic chromatin. Instead, Oct1(pS335) concentrates at centrosomes, mitotic spindle poles, kinetochores and the midbody. Oct1 siRNA knockdown diminishes the signal at these locations. Both Oct1 ablation and overexpression result in abnormal mitoses. S335 is important for the overexpression phenotype, implicating this residue in mitotic regulation. Oct1 depletion causes defects in spindle morphogenesis in Xenopus egg extracts, establishing a mitosis-specific function of Oct1. Oct1 colocalizes with lamin B1 at the spindle poles and midbody. At the midbody, both proteins are mutually required to correctly localize the other. We show that phospho-Oct1 is modified late in mitosis by non-canonical K11-linked polyubiquitin chains. Ubiquitination requires the anaphase-promoting complex, and we further show that the anaphase-promoting complex large subunit APC1 and Oct1(pS335) interact. CONCLUSIONS/SIGNIFICANCE: These findings reveal mechanistic coupling between Oct1 phosphorylation and ubquitination during mitotic progression, and a role for Oct1 in mitosis.

Facilitated DNA search by multidomain transcription factors: cross talk via a flexible linker.

More than 70% of eukaryotic proteins are composed of multiple domains. However, most studies of the search for DNA focus on individual protein domains and do not consider potential cross talk within a multidomain transcription factor. In this study, the molecular features of the DNA search mechanism were explored for two multidomain transcription factors: human Pax6 and Oct-1. Using a simple computational model, we compared a DNA search of multidomain proteins with a search of isolated domains. Furthermore, we studied how manipulating the binding affinity of a single domain to DNA can affect the overall DNA search of the multidomain protein. Tethering the two domains via a flexible linker increases their affinity to the DNA, resulting in a higher propensity for sliding along the DNA, which is more significant for the domain with the weaker DNA-binding affinity. In this case, the domain that binds DNA more tightly anchors the multidomain protein to the DNA and, via the linker, increases the local concentration of the weak DNA-binding domain (DBD). The tethered domains directly exchange between two parallel DNA molecules via a bridged intermediate, where intersegmental transfer is promoted by the weaker DBD. We found that, in general, the relative affinity of the two domains can significantly affect the cross talk between them and thus their overall capability to search DNA efficiently. The results we obtained by examining various multidomain DNA-binding proteins support the necessity of discrepancies between the DNA-binding affinities of the constituent domains.

A general mechanism for transcription regulation by Oct1 and Oct4 in response to genotoxic and oxidative stress.

Oct1 and Oct4 are homologous transcription factors with similar DNA-binding specificities. Here we show that Oct1 is dynamically phosphorylated in vivo following exposure of cells to oxidative and genotoxic stress. We further show that stress regulates the selectivity of both proteins for specific DNA sequences. Mutation of conserved phosphorylation target DNA-binding domain residues in Oct1, and Oct4 confirms their role in regulating binding selectivity. Using chromatin immunoprecipitation, we show that association of Oct4 and Oct1 with a distinct group of in vivo targets is inducible by stress, and that Oct1 is essential for a normal post-stress transcriptional response. Finally, using an unbiased Oct1 target screen we identify a large number of genes targeted by Oct1 specifically under conditions of stress, and show that several of these inducible Oct1 targets are also inducibly bound by Oct4 in embryonic stem cells following stress exposure.

Global jumping and domain-specific intersegment transfer between DNA cognate sites of the multidomain transcription factor Oct-1.

At high DNA concentration, as found in the nucleus, DNA-binding proteins search for specific binding sites by hopping between separate DNA strands. Here, we use (15)N(z)-exchange transverse relaxation optimized NMR spectroscopy to characterize the mechanistic details of intermolecular hopping for the multidomain transcription factor, human Oct-1. Oct-1 is a member of the POU family of transcription factors and contains two helix-turn-helix DNA-binding domains, POU(HD) and POU(S), connected by a relatively short flexible linker. The two domains were found to exchange between specific sites at significantly different rates. The cotranscription factor, Sox2, decreases the exchange rate and equilibrium dissociation constant for Oct-1 > or = 5-fold and approximately 20-fold, respectively, by slowing the exchange rate for the POU(S) domain. DNA-dependent exchange rates measured at physiological ionic strength indicate that the two domains use both an intersegmental transfer mechanism, which does not involve the intermediary of free protein, and a fully dissociative or jumping mechanism to translocate between cognate sites. These data represent an example of dissecting domain-specific kinetics for protein-DNA association involving a multidomain protein and provide evidence that intersegmental transfer involves a ternary intermediate, or transition state in which the DNA-binding domains bridge two different DNA fragments simultaneously.

DNA recognition mechanism of the ONECUT homeodomain of transcription factor HNF-6.

Hepatocyte nuclear factor-6 (HNF-6), a liver-enriched transcription factor, controls the development of various tissues, such as the pancreas and liver, and regulates the expression of several hepatic genes. This protein belongs to the ONECUT class of homeodomain proteins and contains a bipartite DNA-binding domain composed of a single cut domain and a characteristic homeodomain. This transcription factor has two distinct modes of DNA binding and transcriptional activation that use different coactivators depending on the target gene. The crystal structure of the bipartite DNA-binding domain of HNF-6alpha complexed with the HNF-6-binding site of the TTR promoter revealed the DNA recognition mechanism of this protein. Comparing our structure with the DNA-free structure of HNF-6 or the structure of Oct-1, we discuss characteristic features associated with DNA binding and the structural basis for the dual mode of action of this protein, and we suggest a strategy for variability of transcriptional activation of the target gene.

Compact, universal DNA microarrays to comprehensively determine transcription-factor binding site specificities.

Transcription factors (TFs) interact with specific DNA regulatory sequences to control gene expression throughout myriad cellular processes. However, the DNA binding specificities of only a small fraction of TFs are sufficiently characterized to predict the sequences that they can and cannot bind. We present a maximally compact, synthetic DNA sequence design for protein binding microarray (PBM) experiments that represents all possible DNA sequence variants of a given length k (that is, all 'k-mers') on a single, universal microarray. We constructed such all k-mer microarrays covering all 10-base pair (bp) binding sites by converting high-density single-stranded oligonucleotide arrays to double-stranded (ds) DNA arrays. Using these microarrays we comprehensively determined the binding specificities over a full range of affinities for five TFs of different structural classes from yeast, worm, mouse and human. The unbiased coverage of all k-mers permits high-throughput interrogation of binding site preferences, including nucleotide interdependencies, at unprecedented resolution.