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Objective To analyze the sequence characteristics of Rhipicephalus microplus Enolase gene, and to predict the secondary and tertiary structure and antigenic epitopes of the Enolase protein. Methods Sixty-two engorged female R. microplus were sampled from a yellow cattle breeding farm in Zhijiang County, Huaihua City, Hunan Province in June 25, 2022. Genomic DNA was isolated from R. microplus, and the Enolase gene was amplified using PCR assay, followed by cloning, sequencing and expression of the amplification product. The sequence characteristics of the Enolase gene were analyzed using the software Clustal X, and the gene sequence was translated into amino acid sequences. The secondary and tertiary structures of the Enolase protein were deduced using the software PRABI, and the physicochemical properties of the Enolase protein were analyzed using the software PRABI. In addition, the B- and T-cell epitopes of the Enolase protein were predicted using the software ABCpred Prediction, Scratch, IEDB and NetCTL. Results The R. microplus Enolase gene sequence was 1 323 bp in size, and the contents of A, T, G and C bases were 24.5%, 22.5%, 27.0% and 26.0%,with 47.0% of A + T content and 53.0% of G + C content. The R. microplus Enolase gene encoded 434 amino acids, and the Enolase protein had a molecular weight of 47.12 kDa. The secondary structure of the Enolase protein contained 186 α-helixes (42.86%), 32 β-turns (7.37%), 144 random coils (33.18%) and 72 extended strands (16.59%). The Enolase protein was most probably present in cytoplasm (76.7%), followed by in mitochondrion (39.1%) and nucleus (21.7%), and the Enolase protein had no signal peptide or transmembrane domain. In addition, the Enolase protein had 14 B-cell dominant epitopes and 8 T-cell dominant epitopes. Conclusions The R. microplus Enolase gene sequence exhibits a GC preference, and its encoding Enolase protein is an acidic and hydrophilic protein, with α-helixes and random coils as its primary structure, and presenting B- and T-cell dominant epitopes, which is a potential target for development of vaccines against R. microplus.
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@#In recent years, artificial intelligence (AI) has developed rapidly, with improved computing power and algorithms, which has greatly facilitated the collection and processing of biological, chemical information and clinical data, injecting new vitality into the research and development of new drugs.In this review, we began with a brief overview of the development and the main algorithms of AI in drug discovery.Then we elaborated through several specific cases on the various scenarios of AI application, including target identification, protein structure prediction, hit generation and optimization etc.Finally, we focused on a recent example to discuss the high efficiency of "end-to-end" application of AI.
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@#The Porphyromonas gingivalis type IX secretion system (T9SS) is a recently discovered protein secretion system that is widely distributed in Bacillus cereus. The T9SS is structurally complex and powerful. More than 20 T9SS components have been verified, and more than 30 virulence factors can be secreted by Porphyromonas gingivalis alone, which contributes significant to the pathogenicity of Porphyromonas gingivalis. T9SS is a large protein complex spanning the inner cell membrane, periplasm, and outer cell membrane. Through the structural and functional connections among its components, it forms a sophisticated functional complex that includes power provision, energy transduction, inner and outer membrane translocation, outer membrane modification, and regulatory systems to recognize, translocate, shear, and modify cargo proteins and translocate bacterial intracellular cargo proteins to the cell surface. In recent years, with advancements in X-ray diffraction and in situ cryoelectron microscopy, the exploration of T9SS has evolved from the functional study of single components to the in situ structural study of multiprotein complexes. Still, the structural resolution of the protein still has shortcomings such as low resolution and an inability to capture dynamic functional structures. Future research directions should focus more on exploring how T9SS interacts and functions with cargo proteins. In this paper, we review the research progress on Porphyromonas gingivalis T9SS on X-ray diffraction and cryoelectron microscopy structure resolution in order to gain a deeper understanding of the transport mechanism of T9SS.
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Starch is composed of glucose units linked by α-1, 4-glucoside bond and α-1, 6-glucoside bond. It is the main component of foods and the primary raw material for starch processing industry. Pullulanase can effectively hydrolyze the α-1, 6-glucoside bond in starch molecules. Combined with other starch processing enzymes, it can effectively improve the starch utilization rate. Therefore, it has been widely used in the starch processing industry. This paper summarized the screening of pullulanase-producing strain and its encoding genes. In addition, the effects of expression elements and fermentation conditions on the production of pullulanase were summarized. Moreover, the progress in crystal structure elucidation and molecular modification of pullulanase was discussed. Lastly, future perspectives on pullulanase research were proposed.
Subject(s)
Glycoside Hydrolases/genetics , Starch/metabolismABSTRACT
BACKGROUND: Opsonization, is the molecular mechanism by which target molecules promote interactions with phagocyte cell surface receptors to remove unwanted cells by induced phagocytosis. We designed an in vitro system to demonstrate that this procedure could be driven to eliminate adipocytes, using peptides mimicking regions of the complement protein C3b to promote opsonization and enhance phagocytosis. Two cell lines were used: (1) THP-1 monocytes differentiated to macrophages, expressing the C3b opsonin receptor CR1 in charge of the removal of unwanted coated complexes; (2) 3T3-L1 fibroblasts differentiated to adipocytes, expressing AQP7, to evaluate the potential of peptides to stimulate opsonization. (3) A co-culture of the two cell lines to demonstrate that phagocytosis could be driven to cell withdrawal with high efficiency and specificity. RESULTS: An array of peptides were designed and chemically synthesized p3691 and p3931 joined bound to the CR1 receptor activating phagocytosis (p < 0.033) while p3727 joined the AQP7 protein (p < 0.001) suggesting that opsonization of adipocytes could occur. In the co-culture system p3980 and p3981 increased lipid uptake to 91.2% and 89.0%, respectively, as an indicator of potential adipocyte phagocytosis. CONCLUSIONS: This in vitro model could help understand the receptorligand interaction in the withdrawal of unwanted macromolecules in vivo. The adipocyte-phagocytosis discussed may help to control obesity, since peptides of C3b stimulated the CR1 receptor, promoting opsonisation and phagocytosis of lipidcontaining structures, and recognition of AQP7 in the differentiated adipocytes, favored the phagocytic activity of macrophages, robustly supported by the co-culture strategy.
Subject(s)
Phagocytosis , Complement System Proteins , Adipocytes , In Vitro Techniques , Opsonin Proteins , Coculture Techniques , Foam Cells , Macrophages , Microscopy, FluorescenceABSTRACT
Methanogens are unique microorganisms for methane production and the main contributor of the biogenic methane in atmosphere. Methyl-coenzyme M reductase (Mcr) catalyzes the last step of methane production in methanogenesis and the first step of methane activation in anaerobic oxidation of methane. The genes encoding this enzyme are highly conserved and are widely used as a marker in the identification and phylogenetic study of archaea. There has been a longstanding interest in its unique cofactor F430 and the underpinning mechanisms of enzymatic cleavage of alkane C-H bond. The recent breakthroughs of high-resolution protein and catalytic-transition-state structures further advanced the structure-function study of Mcr. In particular, the recent discovery of methyl-coenzyme M reductase-like (Mcr-like) enzymes that activates the anaerobic degradation of non-methane alkanes has attracted much interest in the molecular mechanisms of C-H activation without oxygen. This review summarized the advances on function-structure-mechanism study of Mcr/Mcr-like enzymes. Additionally, future directions in anaerobic oxidation of alkanes and greenhouse-gas control using Mcr/Mcr-like enzymes were proposed.
Subject(s)
Archaea/metabolism , Methane , Oxidation-Reduction , Oxidoreductases/metabolism , PhylogenyABSTRACT
Artificial intelligence (AI) is one of the hottest research topics. The development of AI technology not only brings convenience to people's lives, but also integrates with other frontier fields to aid in data processing and result prediction. Deep learning is one of the emerging technologies that demonstrate outstanding performances. In this paper, the wide application of deep learning technology in many fields of biomedicine was summarized, common methods and models were briefly introduced including artificial neural network, deep neural network, convolutional neural network and recurrent neural network. Besides, the application of deep learning in biomedical image analysis, omics data processing and protein spatial structure prediction was summarized, and its limitations and development prospects in the above applications were briefly discussed.
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Tandemly repeated structural motifs in proteins form highly stable structural folds and provide multiplebinding sites associated with diverse functional roles. The tertiary structure and function of these proteins aredetermined by the type and copy number of the repeating units. Each repeat type exhibits a unique pattern ofintra- and inter-repeat unit interactions that is well-captured by the topological features in the network representation of protein structures. Here we present an improved version of our graph based algorithm, PRIGSA,with structure-based validation and filtering steps incorporated for accurate detection of tandem structuralrepeats. The algorithm integrates available knowledge on repeat families with de novo prediction to detectrepeats in single monomer chains as well as in multimeric protein complexes. Three levels of performanceevaluation are presented: comparison with state-of-the-art algorithms on benchmark dataset of repeat and nonrepeat proteins, accuracy in the detection of members of 13 known repeat families reported in UniProt andexecution on the complete Protein Data Bank to show its ability to identify previously uncharacterizedproteins. A *3-fold increase in the coverage of the members of 13 known families and 3408 noveluncharacterized structural repeat proteins are identified on executing it on PDB. PRIGSA2 is available at http://bioinf.iiit.ac.in/PRIGSA2/.
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Direct massively parallel sequencing of SARS-CoV-2 genome was undertaken from nasopharyngeal andoropharyngeal swab samples of infected individuals in Eastern India. Seven of the isolates belonged to the A2aclade, while one belonged to the B4 clade. Specific mutations, characteristic of the A2a clade, were alsodetected, which included the P323L in RNA-dependent RNA polymerase and D614G in the Spike glycoprotein. Further, our data revealed emergence of novel subclones harbouring nonsynonymous mutations, viz.G1124V in Spike (S) protein, R203K, and G204R in the nucleocapsid (N) protein. The N protein mutationsreside in the SR-rich region involved in viral capsid formation and the S protein mutation is in the S2 domain,which is involved in triggering viral fusion with the host cell membrane. Interesting correlation was observedbetween these mutations and travel or contact history of COVID-19 positive cases. Consequent alterations ofmiRNA binding and structure were also predicted for these mutations. More importantly, the possibleimplications of mutation D614G (in SD domain) and G1124V (in S2 subunit) on the structural stability of Sprotein have also been discussed. Results report for the first time a bird’s eye view on the accumulation ofmutations in SARS-CoV-2 genome in Eastern India.
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2-Haloacid dehalogenases (EC 3.8.1.X) catalyze the hydrolytic dehalogenation of 2-haloacids, releasing halogen ions and producing corresponding 2-hydroxyacids. The enzymes not only degrade xenobiotic halogenated pollutants, but also show wide substrate profile and astonishing efficiency for enantiomer resolution, making them valuable in environmental protection and the green synthesis of optically pure chiral compounds. A variety of 2-haloacid dehalogenases have been biochemically characterized so far. Further studies have been made in protein crystal structures and catalytic mechanisms. Here, we review the recent progresses of 2-haloacid dehalogenases in their source, protein structures, reaction mechanisms, catalytic properties and application. We also suggest further research directions for 2-haloacid dehalogenase.
Subject(s)
Catalysis , Halogenation , Hydrolases , Chemistry , Metabolism , Hydrolysis , Research , Substrate SpecificityABSTRACT
In recent years, mass spectrometry has been widely used to study membrane protein structure and function. However, the application of mass spectrometry to study integral membrane protein is limited because there are many hydrophobic amino acids in the trans-membrane domain of integral membrane protein to cause low sequence coverage detected by LC-MS/MS. Therefore, we used vitamin K epoxide reductase (VKORC1), a human integral membrane protein, as a model to optimize the digestion conditions of chymotrypsin, and developed an in-gel digestion method of chymotrypsin to improve sequence coverage of membrane protein by mass spectrometry. By exploring the effects of calcium concentration, pH value and buffer system on the percentage of sequence coverage, number of total detected and types of unique peptide, and the size of unique peptide, sequence coverage and peptide diversity could be considered under condition of Tris-HCl buffer with 5-10 mmol/L calcium ion concentration and pH value 8.0-8.5. This method could make the sequence coverage of membrane protein to reach more than 80%. It could be widely used in the study of membrane protein structure and function, identification of interaction site between membrane proteins, and identification of binding site between membrane protein and small molecular drug.
Subject(s)
Humans , Amino Acid Sequence , Chromatography, Liquid , Chymotrypsin/metabolism , Digestion , Membrane Proteins , Tandem Mass Spectrometry , Trypsin , Vitamin K Epoxide ReductasesABSTRACT
ObjectiveThe role of human tumor-related calcium signal transductor 2 (TACSTD2) in promoting tumorigenesis has been noticed recently. We predicted the molecular structure and biological function of TACSTD2 by bioinformatic methods, in order to provide reference for further study of TACSTD2.MethodsThe homo sapiens TACSTD2 mRNA and protein amino acid sequences were obtained from the National Center for Biotechnology Information (NCBI) database. The bioinformatic methods were used to analyze the open reading frame(ORF) of TACSTD2, physicochemical properties, signal peptide and protein localization, subcellular localization, and prediction of transmembrane structure and secondary structure, tertiary structure, potential protein modification sites, domains, protein modification sites proteins, protein interacting with TACSTD2, biological functions of TACSTD2, and expression of TACSTD2 in human normal tissues and certain tumor types.ResultsAccording to the mRNA sequence of TACSTD2, there are 12 ORFs, and the longest is ORF1, with a total of 972bp, encoding 323 amino acids. The hydrophilic amino acid of TACSTD2 is more than that of hydrophobic amino acid, indicating that TACSTD2 belongs to hydrophilic protein. TACSTD2 is a highly conserved alkaline secreted protein with a transmembrane region both inside and outside the cytoplasm. The presence of nuclear localization signal(NLS) in the amino acid sequence of TACSTD2 suggests that TACSTD2 can locate in cell nucleus. TACSTD2 mainly distribute in cytoplasmic membrane, extracellular, nucleus and cytoplasm. The secondary structure prediction results showed that the main structure of TACSTD2 was random coil, followed by a α helix. TACSTD2 has 15 serine modification sites, 17 threonine modification sites, and 8 tyrosine modification sites. The TACSTD2 has protein interactions with Claudin(CLDN) protein family; and participating in signaling pathway such as cell surface receptor, cell proliferation, negative regulation of epithelial cell migration, and so on. Comparing with normal human tissues, its mRNA expression is up-regulated in most tumor types such as cervical cancer, lung cancer, thyroid cancer, uterine cancer, liver cancer, colorectal cancer.ConclusionAccording to the analysis of the structure and function of TACSTD2, TACSTD2 is highly-expression in multiple malignancies. It can participate in the process of proliferation, migration and adhesion of malignant tumor cells through cell surface receptor signaling pathways. This study provide reference for the further research about the function of TACSTD2.
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ObjectiveThe role of human tumor-related calcium signal transductor 2 (TACSTD2) in promoting tumorigenesis has been noticed recently. We predicted the molecular structure and biological function of TACSTD2 by bioinformatic methods, in order to provide reference for further study of TACSTD2.MethodsThe homo sapiens TACSTD2 mRNA and protein amino acid sequences were obtained from the National Center for Biotechnology Information (NCBI) database. The bioinformatic methods were used to analyze the open reading frame(ORF) of TACSTD2, physicochemical properties, signal peptide and protein localization, subcellular localization, and prediction of transmembrane structure and secondary structure, tertiary structure, potential protein modification sites, domains, protein modification sites proteins, protein interacting with TACSTD2, biological functions of TACSTD2, and expression of TACSTD2 in human normal tissues and certain tumor types.ResultsAccording to the mRNA sequence of TACSTD2, there are 12 ORFs, and the longest is ORF1, with a total of 972bp, encoding 323 amino acids. The hydrophilic amino acid of TACSTD2 is more than that of hydrophobic amino acid, indicating that TACSTD2 belongs to hydrophilic protein. TACSTD2 is a highly conserved alkaline secreted protein with a transmembrane region both inside and outside the cytoplasm. The presence of nuclear localization signal(NLS) in the amino acid sequence of TACSTD2 suggests that TACSTD2 can locate in cell nucleus. TACSTD2 mainly distribute in cytoplasmic membrane, extracellular, nucleus and cytoplasm. The secondary structure prediction results showed that the main structure of TACSTD2 was random coil, followed by a α helix. TACSTD2 has 15 serine modification sites, 17 threonine modification sites, and 8 tyrosine modification sites. The TACSTD2 has protein interactions with Claudin(CLDN) protein family; and participating in signaling pathway such as cell surface receptor, cell proliferation, negative regulation of epithelial cell migration, and so on. Comparing with normal human tissues, its mRNA expression is up-regulated in most tumor types such as cervical cancer, lung cancer, thyroid cancer, uterine cancer, liver cancer, colorectal cancer.ConclusionAccording to the analysis of the structure and function of TACSTD2, TACSTD2 is highly-expression in multiple malignancies. It can participate in the process of proliferation, migration and adhesion of malignant tumor cells through cell surface receptor signaling pathways. This study provide reference for the further research about the function of TACSTD2.
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In Brazil and in other tropical areas Zika virus infection was directly associated with clinical complications as microcephaly in newborn children whose mothers were infected during pregnancy and the Guillain-Barré syndrome in adults. Recently, research has been focused on developing new vaccines and drug candidates against Zika virus infection since none of those are available. In order to contribute to vaccine and drug development efforts, it becomes important the understanding of the molecular basis of the Zika virus recognition, infection and blockade. To this purpose, it is essential the structural determination of the Zika virus proteins. The genome sequencing of the Zika virus identified ten proteins, being three structural (protein E, protein C and protein prM) and seven non-structural proteins (NS1, NS2A, NS2B, NS3, NS4A, NS4B and NS5). Together, these proteins are the main targets for drugs and antibody recognition. Here we examine new discoveries on high-resolution structural biology of Zika virus, observing the interactions and functions of its proteins identified via state-of-art structural methodologies as X-ray crystallography, nuclear magnetic resonance spectroscopy and cryogenic electronic microscopy. The aim of the present study is to contribute to the understanding of the structural basis of Zika virus infection at an atomic level and to point out similarities and differences to others flaviviruses.(AU)
Subject(s)
Pharmaceutical Preparations , Vaccines , Magnetic Resonance Spectroscopy , Zika Virus , Zika Virus Infection , Crystallography, X-RayABSTRACT
Abstract Experimental information from small angle X-ray scattering (SAXS) is conjugated with nuclear magnetic resonance (NMR) spectroscopy data for the improvement of protein structure determination, particularly for flexible, multidomain or intrinsically disordered proteins. Individually, each of these techniques presents capabilities and limitations: NMR excels in local information, providing atomic resolution, but is limited by protein size, whereas SAXS yields a global envelope of the protein with lower resolution, but revealing domain positions. Different conjugation methodologies use the complementarity of both technique´s independent constraints to accomplish a comprehensive protein structure determination and dynamics understanding at a moderate computational expense.
Resumen Se conjuga información experimental proveniente de dispersión de rayos X a ángulos pequeños (SAXS) con la espectroscopía de resonancia magnética nuclear (NMR) para perfeccionar la determinación de la estructura protéica, en particular de proteínas flexibles, de multidominio o intrínsecamente desordenadas. Individualmente, cada una de estas técnicas presenta capacidades y limitaciones: NMR se destaca en la información local, proporcionando resolución atómica, pero está limitada por el tamaño de la proteína, mientras que SAXS produce una envoltura global de la proteína con una resolución menor pero revelando las posiciones de los dominios. Las diferentes metodologías de conjugación utilizan la complementariedad de las restricciones independientes de ambas técnicas para seguir estrategias adecuadas de acuerdo con la proteína, logrando una determinación integral de la estructura y una comprensión de las dinámicas del sistema proteico a un costo computacional moderado.
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A fitting method of calculating local helix parameters of proteins based on dual quaternions registration fitting (DQRFit) is proposed in this paper. First, the C and N atom coordinates of each residue in the protein structure data are extracted. Then the unregistered data and reference data are constructed using the sliding windows. The square sum of the distance of the data points before and after registration is regarded as an optimization goal. We calculate the optimal rotation matrix and the translation vector using the dual quaternion registration algorithm, and get the helix parameters of the secondary structure which contain the number of residues per turn( ), helix radius( )and helix pitch( ). Furthermore, we can achieve the fitting of three-helix parameters of , , simultaneously with the dual quaternion registration, and can adjust the sliding windows to adapt to different error levels. Compared with the traditional helix fitting method, DQRFit has some advantages such as low computational complexity, strong anti-interference, and high fitting accuracy. It is proven that the precision of proposed DQRFit for α helix detection is comparable to that of the dictionary of secondary structure of proteins (DSSP), and is better than that of other traditional methods. This is of great significance for the protein structure classification and functional prediction, drug design, protein structure visualization and other fields in the future.
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Polyamines are a kind of aliphatic amines that exist widely in nearly all organisms. Polyamines interact with biological macromolecules through ionic interactions and hydrogen bonds, thereby they could affect the cell growth via regulating the function of macro-molecules. The impact of polyamines on nucleic acids has been thoroughly studied. However, their effects on protein structure and functions are not well established. This review summarizes the recent progress on how polyamines affect proteins, including metabolic enzymes, ion channel proteins and other important proteins. The interaction between polyamines and proteins is discussed, and the review also summarizes the challenges in studying polyamine-protein interaction as well as the potential application of these studies on the therapy of correlated diseases.
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Apoptosis involves multiple signaling pathways. The intrinsic signaling pathway is the mitochondrial apoptotic pathway, which is caused by a series of processes. First, the pro-apoptotic factors such as Bax are activated by signaling molecules and transfer to the mitochondrial outer membrane forming protein pores, thus the mitochondrial membrane permeability is affected, and then the downstream caspase-9 is activated and the apoptosis initiation is induced by releasing cytochrome C. In order to explore the apoptosis initiation activated by small molecules, the specific structural changes of Bax in apoptosis were studied. The results showed that there is a hydrophobic pocket structure near the C-terminal S184 of the Bax protein. This structure can be combined with certain small molecular substances specifically remove phosphorylation S184, and regulate Bax protein to promote apoptosis activity. At present, the nuclear magnetic structure of Bax protein has been obtained and the crystal structure has not been revealed. The eutectic structure formed by corresponding with other proteins in the Bcl-2 family has been resolved, which can be used to study the interactions between proteins and to understand the specific structural changes in the formation of heterologous dimers during apoptosis, site changes, etc. In this paper, the Bax protein structure resolved by nuclear magnetic structure was reviewed to learn the change of the sites in the induced apoptosis so as to promote the research on apoptosis initiation.
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O gene floR descrito é descrito pela literatura como o responsável pela resistência ao florfenicol, que é um antimicrobiano amplamente utilizado na aquicultura. Esse gene já foi relatado em muitas espécies de bactérias, inclusive no gênero Aeromonas. Essas bactérias causam alta mortalidade na piscicultura trazendo prejuízos econômicos. É importante que haja estudos sobre esse gene e possíveis mutações que possam levar a alterações na estrutura e função da proteína. Os objetivos desse estudo foram caracterizar o gene floR em isolados de Aeromonas spp. obtidas do Vale do São Francisco e verificar se a presença desse gene está associada com a resistência ao florfenicol. Foram realizadas reações em cadeia da polimerase (PCR) para a presença do gene floR em 27 isolados de Aeromonas spp.. Amostras positivas para a presença do gene foram sequenciadas e analisadas quanto à presença de polimorfismos por meio de alinhamentos. Os diferentes haplótipos detectados foram utilizados para análises com os programas SIFT e PolyPhen para predição de alteração de função proteica. A modelagem estrutural da proteina codificada pelo gene floR foi realizada com o programa Modeller e, os modelos foram avaliados pelo Procheck, Verify3D e Whatif. A similaridade da estrutura tridimensional da proteína referência com as estruturas tridimensionais das proteínas codificadas pelos diferentes haplótipos foi comparada através do TM-align. A resistência das bactérias ao florfenicol foi avaliada através do teste de microdiluição em caldo, o qual também foi realizado na presença do carbonil cianeto m-clorofenil hidrazona para verificar o efeito da inibição da bomba de efluxo sobre tal resistência. Dos vinte e sete isolados avaliados quanto a presença do gene floR, 14 isolados foram positivos e 10 foram sequenciados, o que permitiu a identificação de três polimorfismos no gene floR, que levaram a construção de três haplótipos diferentes (TAA, TTA e CTG). As análises realizadas com os programas SIFT e PolyPhen apontaram que os haplótipos TTA e TAA provavelmente poderiam alterar a estrutura e função da proteína. As proteínas modeladas para os três haplótipos demonstraram possuir praticamente a mesma conformação estrutural entre si. Todos os isolados que apresentaram o gene foram resistentes ao florfenicol e aqueles que não apresentavam foram sensíveis. O teste na presença do Carbonil Cianeto m-Clorofenil Hidrazona foi realizado para três isolados, cada isolado representando um haplótipo, sendo possível observar a inibição do crescimento bacteriano em todas as concentrações independente do haplótipo. Os resultados obtidos nesse estudo mostram que a resistência ao flofenicol em Aeromonas spp. pode ser explicada pela presença do gene floR, e que esse gene está relacionado com uma bomba de efluxo. As mutações verificadas no gene floR, parecem não estar envolvidas com alteração de estrutura e função da proteína codificada por esse gene.(AU)
The floR gene is described in related literature as responsible for resistance to florfenicol, which is a widely used antimicrobial agent in aquaculture. This gene has been reported in many species of bacteria, including the genus Aeromonas. These bacteria cause high mortality in fish farming bringing economic losses. It is important that studies of this gene and possible mutations that can lead to changes in the structure and function of the protein. The aim of this study was to characterize the floR gene in isolates of Aeromonas spp. and check if the presence of this gene is associated with resistance to florfenicol in Aeromonas spp. obtained from the San Francisco Valley. PCR (Polymerase Chain Reaction) were also performed to verify the presence of the floR gene in 27 isolates of Aeromonas spp. Positive samples for the presence of the gene were sequenced and analyzed for the presence of polymorphisms using alignments. Different haplotypes detected were used for analysis with the SIFT and PolyPhen programs for prediction of changes in protein function. The structural modeling of protein encoded by the floR gene was performed using the Modeller software, and the models were evaluated by Procheck, Verify3D and Whatif. The similarity of the dimensional structure of reference protein with the dimensional structures of the proteins encoded by the different haplotypes was compared by TM-align. Bacterial resistance to florfenicol was assessed by the microdilution test, which was also performed in the presence of carbonyl cyanide m-chlorophenyl hydrazone to verify the effect of inhibiting the efflux pump. 14 isolates were positive for the presence of floR gene and 10 were sequenced and allowed the identification of three polymorphisms in the floR gene, which led to construction of three different haplotypes (TAA TTA and CTG). The analyzes carried out with the SIFT and PolyPhen programs showed that the TTA and TAA haplotypes could probably change the protein structure-function. Proteins modeled for the three haplotypes were found to have substantially the same structural conformation with each other. All isolates presenting the gene were resistant to florfenicol and those who did not have were sensitive. The test in the presence of carbonyl cyanide m-chlorophenylhydrazone was conducted for three isolates, representing each single haplotype and was observed inhibition of bacterial growth at all concentrations independent of the haplotype. The results of this study show that resistance to flofenicol in Aeromonas spp. may be explained by the presence of floR gene and that this gene is associated with an efflux pump. Mutations observed in floR gene do not appear to be involved with chenges in structure and function of the protein encoded by gene.(AU)
Subject(s)
Animals , Tilapia/genetics , Tilapia/microbiology , Aeromonas , Gene FlowABSTRACT
RESUMEN El xilema secundario es el componente más abundante de la biomasa vegetal. Por tanto, conocer los genes que regulan su formación ayudaría a diseñar estrategias para el mejoramiento genético de la madera. Así, el objetivo de este trabajo fue realizar el análisis computacional de la estructura primaria y secundaria del factor de transcripción (FT) TgNACO1 de Tectona grandis, además de evaluar su historia evolutiva, dominios conservados y expresión génica en tejidos lignificados de árboles de 12 y 60 años. Para ello, se realizó una evaluación del potencial de interacción ion-electrón (PIIE), mediante el método del espectro de la información (MEI) utilizando la librería SFAPS de R-Project, seguido del modelamiento estructural utilizando el software MODELLER y visualizado mediante PyMol. Además, el análisis de alineamiento de secuencia múltiple y filogenia fue mediante el software Bioedit y MrBayes respectivamente. También se evaluó los niveles de síntesis del FT TgNACO1 mediante qRT-PCR. Como resultados, se evidenció que el FT mantiene una estructura (3-hoja antiparalela retorcida, que se compacta contra una a-hélice en la región N-terminal, teniendo así tres dominios a hélice y siete dominios (3 plegada. Asimismo, mediante el MEI se demostró que tiene alrededor de cinco funciones biológicas y mutaciones sobre los aminoácidos con mayor PIIE, lo que conlleva a evoluciones sobre las redes de regulación genética. Finalmente, el FT TgNACO1 podría presentar un papel fundamental en la organización y desarrollo de las partes que componen la albura, como las células radiales de la zona cambial, los vasos, fibras y los anillos de crecimiento.
ABSTRACT Secondary xylem is the most abundant component of plant biomass. Therefore, knowing the genes that regulate its formation would help to design strategies for wood genetic improvement. Thus, the objective of this work was to perform computational analysis of the primary and secondary structure of the TgNACO1 transcription factor (FT) of Tectona grandis, and to evaluate its evolutionary history, conserved domains and gene expression in lignified tissues of trees with 12 and 60 years old. For this, an ion-electron interaction potential (IEP) was evaluated using the information-spectrum method (IEM) using the R-Project and SFAPS library, followed by structural modeling using the MODELLER software and visualized by PyMol program. In addition, the analysis of multiple sequence alignment and phylogeny was performed using Bioedit and MrBayes software, respectively. We also evaluated the qRT-PCR levels of TgNACO1. As results, it was found that TgNACO1 maintains a twisted antiparallel 3-sheet structure, which is compacted against an a-helix in the N-terminal region, having three a-helix domains and seven folded ((-domains. Also, through the IEM, it was demonstrated that it has about five biological functions, and mutations on amino acids with higher IEP, which leads to evolutions on genetic regulation networks. Finally, the FT TgNACO1 could play an esential role in the organization and development of the parts that make up the sapwood, such as the radial cells of the cambial zone, the vessels, fibers and the growth rings.