Expressão e caracterização da glicoproteína D do HSV-1 geneticamente fusionada às oncoproteínas E6 e E7 do HPV-16 e HPV-18 (gDE7E6) em células de mamífero / Expression and characterization of the genetically fused HSV-1 glycoprotein D to E6 and E7 oncoproteins HPV-16 e HPV-18 (gDE7E6) in mammalian cells

O câncer cervical é um dos tipos de câncer mais comuns entre as mulheres, e a infecção persistente pelos HPV-16 e HPV-18 é responsável por 70% dos casos. As vacinas profiláticas disponíveis possuem alta eficácia na prevenção da infecção pelos tipos mais prevalentes de HPV. No entanto, este tipo de abordagem não beneficia mulheres que já apresentam lesões precursoras ou tumores cervicais avançados, e a busca por abordagens terapêuticas para esse tipo de câncer é considerada uma necessidade. A qualidade do antígeno representa um aspecto fundamental para o sucesso de vacinas terapêuticas baseadas em proteínas recombinantes. Neste sentido, os sistemas de expressão em células eucarióticas, como leveduras e células de mamíferos são considerados adequados para a produção de proteínas com aplicação biotecnológica. O objetivo principal deste trabalho contemplou a expressão das proteínas de fusão gDE7E6 do HPV-16 e do HPV-18 e a oncoproteína E7 do HPV-16 em células da levedura Pichia pastoris e expressão da gDE7E6 do HPV-16 e do HPV-18 em células de mamífero HEK293T e CHODG-44 para obtenção de antígenos purificados com futura aplicação em vacinas terapêuticas contra tumores associados ao HPV-16 e HPV-18. Os genes que codificam as proteínas gDE7E6 dos HPV-16 e HPV-18 e da E7 do HPV-16 foram clonados no vetor pPIC9K, os quais foram linearizados por digestão enzimática e utilizados na transformação da P. pastoris. A expressão das proteínas foi analisada nos tempos de 24, 48, 72 e 96 horas, no entanto, não foi observada a produção das proteínas no sobrenadante e nem no lisado celular. Diante desta constatação, iniciamos a expressão das proteínas gDE7E6 do HPV-16 e gDE7E6 do HPV-18 em células de mamíferos HEK293T e CHODG-44. As sequências genéticas das proteínas gDE7E6 do HPV-16 e do HPV-18 foram clonadas no vetor de expressão pNU1 e analisadas por digestão enzimática. Análises de SDS-PAGE e western blot demonstraram a expressão das proteínas gDE7E6 do HPV-16 e do HPV-18 em até 96 horas em células HEK293T. Em paralelo, realizamos a transfecção estável dos plasmídeos contendo as sequencias da gDE7E6 do HPV-16 e gDE7E6 do HPV-18 em células CHO-DG44. Com o intuito de aumentar a expressão das proteínas de interesse na população mista de CHODG-44, realizamos amplificação genômica com metotrexato (MTX), sendo possível observar aumento da expressão das proteínas, conforme aumento gradativo nas concentrações de MTX. Posteriormente, foram feitas tentativas para isolar um clone produtor das proteínas gDE7E6 HPV-16 e HPV-18, através de clonagem por diluição limitante e sistema automatizado, sendo possível isolar um clone para cada construção através de matriz semisólida, confirmado por western blot e citometria de fluxo. Apesar de demonstrar a expressão das proteínas de interesse em sistema de expressão baseado em células de mamífero, o rendimento obtido após a purificação por afinidade ao níquel foi extremamente baixo, o que dificulta a obtenção dos antígenos para fins vacinais

Cervical cancer is one of the most common cancers among women, and persistent infection with HPV-16 and HPV-18 accounts for 70% of the cases. Available prophylactic vaccines are highly effective in preventing infection by the most prevalent types of HPV. However, this type of approach does not benefit women who already have precursor lesions or advanced cervical tumors, and the search for therapeutic approaches to this type of cancer is considered a necessity. Antigen quality represents a key aspect for the success of therapeutic vaccines based on recombinant proteins. In this sense, expression systems based in eukaryotic cells such as yeast and mammalian cells are considered suitable for the production of proteins with biotechnological applications. The main objective of this work was to express the gDE7E6 fusion proteins HPV-16 and HPV-18 and the E7 oncoprotein HPV-16 in Pichia pastoris and expression of gDE7E6 HPV-16 and HPV-18 in mammalian cells HEK293T and CHODG-44 to obtain purified antigens with future applications in therapeutic vaccines against HPV-16 and HPV-18 associated tumors. The genes encoding the gDE7E6 proteins HPV-16 and HPV-18 and E7 HPV-16 were cloned into the pPIC9K vector, which were linearized by enzymatic digestion and used in the transformation of P. pastoris. Expression of the proteins was analyzed at 24, 48, 72 and 96 hours, however, the production of the proteins in the supernatant and in the cell lysate was not observed. In light of this finding, we initiated the expression of gDE7E6 proteins HPV-16 and HPV-18 in mammalian cells HEK293T and CHODG-44. The genetic sequences of gDE7E6 proteins HPV-16 and HPV-18 were cloned into the pNU1 expression vector and analyzed by enzymatic digestion. SDSPAGE and western blot analyzes demonstrated expression of gDE7E6 proteins HPV-16 and HPV-18 within 96 hours in HEK293T cells. In parallel, we performed stable transfection of plasmids containing gDE7E6 HPV-16 and HPV-18 sequences into CHODG44 cells. In order to increase the expression of the proteins in the mixed population of CHODG-44, we performed genomic amplification with methotrexate (MTX), and it was possible to observe an increase in protein expression, as a gradual increase in MTX concentrations. Therefore, attempts were made to isolate a clone producing gDE7E6 proteins HPV-16 and HPV-18 by limiting dilution and automated system, being possible to isolate one clone for each construct through a semisolid matrix, confirmed by western blot and flow cytometry. Despite observing protein expression in mammalian cell-based expression system, the yield obtained after nickel affinity purification was extremely low, which makes it difficult to obtain the antigens for vaccine purposes

Oncodomains: A protein domain-centric framework for analyzing rare variants in tumor samples.

The fight against cancer is hindered by its highly heterogeneous nature. Genome-wide sequencing studies have shown that individual malignancies contain many mutations that range from those commonly found in tumor genomes to rare somatic variants present only in a small fraction of lesions. Such rare somatic variants dominate the landscape of genomic mutations in cancer, yet efforts to correlate somatic mutations found in one or few individuals with functional roles have been largely unsuccessful. Traditional methods for identifying somatic variants that drive cancer are 'gene-centric' in that they consider only somatic variants within a particular gene and make no comparison to other similar genes in the same family that may play a similar role in cancer. In this work, we present oncodomain hotspots, a new 'domain-centric' method for identifying clusters of somatic mutations across entire gene families using protein domain models. Our analysis confirms that our approach creates a framework for leveraging structural and functional information encapsulated by protein domains into the analysis of somatic variants in cancer, enabling the assessment of even rare somatic variants by comparison to similar genes. Our results reveal a vast landscape of somatic variants that act at the level of domain families altering pathways known to be involved with cancer such as protein phosphorylation, signaling, gene regulation, and cell metabolism. Due to oncodomain hotspots' unique ability to assess rare variants, we expect our method to become an important tool for the analysis of sequenced tumor genomes, complementing existing methods.

Colon cancer associated genes exhibit signatures of positive selection at functionally significant positions.

BACKGROUND: Cancer, much like most human disease, is routinely studied by utilizing model organisms. Of these model organisms, mice are often dominant. However, our assumptions of functional equivalence fail to consider the opportunity for divergence conferred by ~180 Million Years (MY) of independent evolution between these species. For a given set of human disease related genes, it is therefore important to determine if functional equivalency has been retained between species. In this study we test the hypothesis that cancer associated genes have different patterns of substitution akin to adaptive evolution in different mammal lineages. RESULTS: Our analysis of the current literature and colon cancer databases identified 22 genes exhibiting colon cancer associated germline mutations. We identified orthologs for these 22 genes across a set of high coverage (>6X) vertebrate genomes. Analysis of these orthologous datasets revealed significant levels of positive selection. Evidence of lineage-specific positive selection was identified in 14 genes in both ancestral and extant lineages. Lineage-specific positive selection was detected in the ancestral Euarchontoglires and Hominidae lineages for STK11, in the ancestral primate lineage for CDH1, in the ancestral Murinae lineage for both SDHC and MSH6 genes and the ancestral Muridae lineage for TSC1. CONCLUSION: Identifying positive selection in the Primate, Hominidae, Muridae and Murinae lineages suggests an ancestral functional shift in these genes between the rodent and primate lineages. Analyses such as this, combining evolutionary theory and predictions - along with medically relevant data, can thus provide us with important clues for modeling human diseases.

Dissection of the dimerization modes in the DJ-1 superfamily.

The DJ-1 superfamily (DJ-1/ThiJ/PfpI superfamily) is distributed across all three kingdoms of life. These proteins are involved in a highly diverse range of cellular functions, including chaperone and protease activity. DJ-1 proteins usually form dimers or hexamers in vivo and show at least four different binding orientations via distinct interface patches. Abnormal oligomerization of human DJ-1 is related to neurodegenerative disorders including Parkinson's disease, suggesting important functional roles of quaternary structures. However, the quaternary structures of the DJ-1 superfamily have not been extensively studied. Here, we focus on the diverse oligomerization modes among the DJ-1 superfamily proteins and investigate the functional roles of quaternary structures both computationally and experimentally. The oligomerization modes are classified into 4 types (DJ-1, YhbO, Hsp, and YDR types) depending on the distinct interface patches (I-IV) upon dimerization. A unique, rotated interface via patch I is reported, which may potentially be related to higher order oligomerization. In general, the groups based on sequence similarity are consistent with the quaternary structural classes, but their biochemical functions cannot be directly inferred using sequence information alone. The observed phyletic pattern suggests the dynamic nature of quaternary structures in the course of evolution. The amino acid residues at the interfaces tend to show lower mutation rates than those of non-interfacial surfaces.

Cytoplasmic ACK1 interaction with multiple receptor tyrosine kinases is mediated by Grb2: an analysis of ACK1 effects on Axl signaling.

ACK1 (activated Cdc42-associated kinase 1), a cytoplsmic tyrosine kinase, is implicated in metastatic behavior, cell spreading and migration, and epidermal growth factor receptor (EGFR) signaling. The function of ACK1 in the regulation of receptor tyrosine kinases requires a C-terminal region that demonstrates a significant homology to the EGFR binding domain of MIG6. In this study, we have identified additional receptor tyrosine kinases, including Axl, leukocyte tyrosine kinase, and anaplastic lymphoma kinase, that can bind to the ACK1/MIG6 homology region. Unlike the interaction between MIG6 and EGFR, our data suggest that these receptor tyrosine kinases require the adaptor protein Grb2 for efficient binding, which interacts with highly conserved proline-rich regions that are conserved between ACK1 and MIG6. We have focused on Axl and compared how ACK1/Axl differs from the ACK1/EGFR axis by investigating effects of knockdown of endogenous ACK1. Although EGFR activation promotes ACK1 turnover, Axl activation by GAS6 does not; interestingly, the reciprocal down-regulation of GAS6-stimulated Axl is blocked by removing ACK1. Thus, ACK1 functions in part to control Axl receptor levels. Silencing of ACK1 also leads to diminished ruffling and migration in DU145 and COS7 cells upon GAS6-Axl signaling. The ability of ACK1 to modulate Axl and perhaps anaplastic lymphoma kinase (altered in anaplastic large cell lymphomas) might explain why ACK1 can promote metastatic and transformed behavior in a number of cancers.

Reviewing the current classification of inhibitor of growth family proteins.

Inhibitor of growth (ING) family proteins have been defined as candidate tumor suppressors for more than a decade. Recent emerging results using siRNA and knockout mice are expanding the previous understanding of this protein family. The results of ING1 knockout mouse experiments revealed that ING1 has a protective effect on apoptosis. Our recent results showed that ING2 is overexpressed in colorectal cancer, and induces colon cancer cell invasion through an MMP13-dependent pathway. Knockdown of ING2 by siRNA induces premature senescence in normal human fibroblast cells, and apoptosis or cell cycle arrest in various adherent cancer cells. Taken together, these results suggest that ING2 may also have roles in cancer progression and/or malignant transformation under some conditions. Additionally, knockdown of ING4 and ING5 by siRNA shows an inhibitory effect on the transition from G(2)/M to G(1) phase and DNA replication, respectively, suggesting that these proteins may play roles during cell proliferation in some context. ING family proteins may play dual roles, similar to transforming growth factor-beta, which has tumor suppressor-like functions in normal epithelium and also oncogenic functions in invasive metastatic cancers. In the present article, we briefly review ING history and propose a possible interpretation of discrepancies between past and recent data.

Identification of functional subclasses in the DJ-1 superfamily proteins.

Genomics has posed the challenge of determination of protein function from sequence and/or 3-D structure. Functional assignment from sequence relationships can be misleading, and structural similarity does not necessarily imply functional similarity. Proteins in the DJ-1 family, many of which are of unknown function, are examples of proteins with both sequence and fold similarity that span multiple functional classes. THEMATICS (theoretical microscopic titration curves), an electrostatics-based computational approach to functional site prediction, is used to sort proteins in the DJ-1 family into different functional classes. Active site residues are predicted for the eight distinct DJ-1 proteins with available 3-D structures. Placement of the predicted residues onto a structural alignment for six of these proteins reveals three distinct types of active sites. Each type overlaps only partially with the others, with only one residue in common across all six sets of predicted residues. Human DJ-1 and YajL from Escherichia coli have very similar predicted active sites and belong to the same probable functional group. Protease I, a known cysteine protease from Pyrococcus horikoshii, and PfpI/YhbO from E. coli, a hypothetical protein of unknown function, belong to a separate class. THEMATICS predicts a set of residues that is typical of a cysteine protease for Protease I; the prediction for PfpI/YhbO bears some similarity. YDR533Cp from Saccharomyces cerevisiae, of unknown function, and the known chaperone Hsp31 from E. coli constitute a third group with nearly identical predicted active sites. While the first four proteins have predicted active sites at dimer interfaces, YDR533Cp and Hsp31 both have predicted sites contained within each subunit. Although YDR533Cp and Hsp31 form different dimers with different orientations between the subunits, the predicted active sites are superimposable within the monomer structures. Thus, the three predicted functional classes form four different types of quaternary structures. The computational prediction of the functional sites for protein structures of unknown function provides valuable clues for functional classification.

Signalling and functional diversity within the Axl subfamily of receptor tyrosine kinases.

The related Axl, Sky and Mer receptor tyrosine kinases (RTKs) are increasingly being implicated in a host of discrete cellular responses including cell survival, proliferation, migration and phagocytosis. Furthermore, their ligands Gas6 and protein S are characteristically dependent on vitamin K for expression of their functions. The Gas6/Axl system is implicated in several types of human cancer as well as inflammatory, autoimmune, vascular and kidney diseases. Each member of the Axl RTK subfamily possesses distinct expression profiles as well as discrete functions. In this article, we review the knowledge so far on the intracellular signalling interactions and pathways concerning each of the Axl RTKs. In this way, we hope to gain a greater understanding of the mechanisms that set each of them apart, and that relay their associated functions.

Circadian regulator CLOCK is a histone acetyltransferase.

The molecular machinery that governs circadian rhythmicity comprises proteins whose interplay generates time-specific transcription of clock genes. The role of chromatin remodeling in a physiological setting such as the circadian clock is yet unclear. We show that the protein CLOCK, a central component of the circadian pacemaker, has histone acetyltransferase (HAT) activity. CLOCK shares homology with acetyl-coenzyme A binding motifs within the MYST family of HATs. CLOCK displays high sequence similarity to ACTR, a member of SRC family of HATs, with which it shares also enzymatic specificity for histones H3 and H4. BMAL1, the heterodimerization partner of CLOCK, enhances HAT function. The HAT activity of CLOCK is essential to rescue circadian rhythmicity and activation of clock genes in Clock mutant cells. Identification of CLOCK as a novel type of DNA binding HAT reveals that chromatin remodeling is crucial for the core clock mechanism and identifies unforeseen links between histone acetylation and cellular physiology.

The putative oncogene GASC1 demethylates tri- and dimethylated lysine 9 on histone H3.

Methylation of lysine and arginine residues on histone tails affects chromatin structure and gene transcription. Tri- and dimethylation of lysine 9 on histone H3 (H3K9me3/me2) is required for the binding of the repressive protein HP1 and is associated with heterochromatin formation and transcriptional repression in a variety of species. H3K9me3 has long been regarded as a 'permanent' epigenetic mark. In a search for proteins and complexes interacting with H3K9me3, we identified the protein GASC1 (gene amplified in squamous cell carcinoma 1), which belongs to the JMJD2 (jumonji domain containing 2) subfamily of the jumonji family, and is also known as JMJD2C. Here we show that three members of this subfamily of proteins demethylate H3K9me3/me2 in vitro through a hydroxylation reaction requiring iron and alpha-ketoglutarate as cofactors. Furthermore, we demonstrate that ectopic expression of GASC1 or other JMJD2 members markedly decreases H3K9me3/me2 levels, increases H3K9me1 levels, delocalizes HP1 and reduces heterochromatin in vivo. Previously, GASC1 was found to be amplified in several cell lines derived from oesophageal squamous carcinomas, and in agreement with a contribution of GASC1 to tumour development, inhibition of GASC1 expression decreases cell proliferation. Thus, in addition to identifying GASC1 as a histone trimethyl demethylase, we suggest a model for how this enzyme might be involved in cancer development, and propose it as a target for anti-cancer therapy.