Human_SNP_TATAdb: a database of SNPs that statistically significantly change the affinity of the TATA-binding protein to human gene promoters: genome-wide analysis and use cases.

It was previously shown that the expression levels of human genes positively correlate with TBP affinity for the promoters of these genes. In turn, single nucleotide polymorphisms (SNPs) in human gene promoters can affect TBP affinity for DNA and, as a consequence, gene expression. The Institute of Cytology and Genetics SB RAS (ICG) has developed a method for predicting TBP affinity for gene promoters based on a three-step binding mecha- nism: (1) TBP slides along DNA, (2) TBP stops at the binding site, and (3) the TBP-promoter complex is fixed due to DNA helix bending. The method showed a high correlation of theoretical predictions with measured values during repeated experimental testing by independent groups of researchers. This model served as a base for other ICG web services, SNP_TATA_Z-tester and SNP_TATA_Comparator, which make a statistical assessment of the SNP-induced change in the affinity of TBP binding to the human gene promoter and help predict changes in expression that may be associated with a genetic predisposition to diseases or phenotypic features of the organism. In this work, we integrated into a single database information about SNPs in human gene promoters obtained by automatic extrac- tion from various heterogeneous data sources, as well as the estimates of TBP affinity for the promoter obtained using the three-step binding model and predicting their effect on gene expression for wild-type promoters and promoters with SNPs. We have shown that Human_SNP_TATAdb can be used for annotation and identification of candidate SNP markers of diseases. The results of a genome-wide data analysis are presented, including the distri- bution of genes with respect to the number of transcripts, the distribution of SNPs affecting TBP-DNA affinity with respect to positions within promoters, as well as patterns linking TBP affinity for the promoter, the specificity of the TBP binding site for the promoter and other characteristics of promoters. The results of the genome-wide analysis showed that the affinity of TBP for the promoter and the specificity of its binding site are statistically related to other characteristics of promoters important for the functional classification of promoters and the study of the features of differential gene expression.

A bioinformatic search for correspondence between differentially expressed genes of domestic versus wild animals and orthologous human genes altering reproductive potential.

One of the greatest achievements of genetics in the 20th century is D.K. Belyaev's discovery of destabilizing selection during the domestication of animals and that this selection affects only gene expression regulation (not gene structure) and inf luences systems of neuroendocrine control of ontogenesis in a stressful environment. Among the experimental data generalized by Belyaev's discovery, there are also f indings about accelerated extinc tion of testes' hormonal function and disrupted seasonality of reproduction of domesticated foxes in comparison with their wild congeners. To date, Belyaev's discovery has already been repeatedly conf irmed, for example, by independent observations during deer domestication, during the use of rats as laboratory animals, after the reintroduction of endangered species such as Przewalski's horse, and during the creation of a Siberian reserve population of the Siberian grouse when it had reached an endangered status in natural habitats. A genome-wide comparison among humans, several domestic animals, and some of their wild congeners has given rise to the concept of self-domestication syndrome, which includes autism spectrum disorders. In our previous study, we created a bioinformatic model of human self-domestication syndrome using differentially expressed genes (DEGs; of domestic animals versus their wild congeners) orthologous to the human genes (mainly, nervous-system genes) whose changes in expression affect reproductive potential, i. e., growth of the number of humans in the absence of restrictions caused by limiting factors. Here, we applied this model to 68 human genes whose changes in expression alter the reproductive health of women and men and to 3080 DEGs of domestic versus wild animals. As a result, in domestic animals, we identif ied 16 and 4 DEGs, the expression changes of which are codirected with changes in the expression of the human orthologous genes decreasing and increasing human reproductive potential, respectively. The wild animals had 9 and 11 such DEGs, respectively. This difference between domestic and wild animals was signif icant according to Pearson's χ2 test (p < 0.05) and Fisher's exact test (p < 0.05). We discuss the results from the standpoint of restoration of endangered animal species whose natural habitats are subject to an anthropogenic impact.

Promoters of genes encoding ß-amylase, albumin and globulin in food plants have weaker affinity for TATA-binding protein as compared to non-food plants: in silico analysis.

It is generally accepted that during the domestication of food plants, selection was focused on their productivity, the ease of their technological processing into food, and resistance to pathogens and environmental stressors. Besides, the palatability of plant foods and their health benefits could also be subjected to selection by humans in the past. Nonetheless, it is unclear whether in antiquity, aside from positive selection for beneficial properties of plants, humans simultaneously selected against such detrimental properties as allergenicity. This topic is becoming increasingly relevant as the allergization of the population grows, being a major challenge for modern medicine. That is why intensive research by breeders is already underway for creating hypoallergenic forms of food plants. Accordingly, in this paper, albumin, globulin, and ß-amylase of common wheat Triticum aestivum L. (1753) are analyzed, which have been identified earlier as targets for attacks by human class E immunoglobulins. At the genomic level, we wanted to find signs of past negative selection against the allergenicity of these three proteins (albumin, globulin, and ß-amylase) during the domestication of ancestral forms of modern food plants. We focused the search on the TATA-binding protein (TBP)-binding site because it is located within a narrow region (between positions -70 and -20 relative to the corresponding transcription start sites), is the most conserved, necessary for primary transcription initiation, and is the best-studied regulatory genomic signal in eukaryotes. Our previous studies presented our publicly available Web service Plant_SNP_TATA_Z-tester, which makes it possible to estimate the equilibrium dissociation constant (KD) of TBP complexes with plant proximal promoters (as output data) using 90 bp of their DNA sequences (as input data). In this work, by means of this bioinformatics tool, 363 gene promoter DNA sequences representing 43 plant species were analyzed. It was found that compared with non-food plants, food plants are characterized by significantly weaker affinity of TBP for proximal promoters of their genes homologous to the genes of common-wheat globulin, albumin, and ß-amylase (food allergens) (p < 0.01, Fisher's Z-test). This evidence suggests that in the past humans carried out selective breeding to reduce the expression of food plant genes encoding these allergenic proteins.

[Candidate SNP-markers altering TBP binding affinity for promoters of the Y-linked genes CDY2A, SHOX, and ZFY are lowering many indexes of reproductive potential in men]. / Кандидатные SNP-маркеры, изменяющие сродство ТВРк промоторам Y-ÑÐ²ÑÐ·Ð°Ð½Ð½Ñ‹Ñ Ð³ÐµÐ½Ð¾Ð² CDY2A, SHOX, ZFY, снижают ряд показателей репродуктивного потенциала мужчин.

Reproductive potential is the most important conditional indicator reflecting the ability of individuals in a population to reproduce, survive and develop under optimal environmental conditions. As for humans, the concept of reproductive potential can include the level of the individual's mental and physical state, which allows them to reproduce healthy offspring when they reach social and physical maturity. Female reproductive potential has been investigated in great detail, whereas the male reproductive potential (MRP) has not received the equal amount of attention as yet. Therefore, here we focused on the human Y chromosome and found candidate single-nucleotide polymorphism (SNP) markers of MRP. With our development named Web-service SNP_TATA_Z-tester, we examined in silico all 35 unannotated SNPs within 70-bp proximal promoters of the three Y-linked genes, CDY2A, SHOX and ZFY, which represent all types of human Y-chromosome genes, namely: unique, pseudo-autosomal, and human X-chromosome gene paralogs, respectively. As a result, we found 11 candidate SNP markers for MRP, which can significantly alter the TATA-binding protein (TBP) binding affinity for promoters of these genes. First of all, we selectively verified in vitro the values of the TBP-promoter affinity under this study, Pearson's linear correlation between predicted and measured values of which were r = 0.94 (significance p < 0.005). Next, as a discussion, using keyword search tools of the PubMed database, we found clinically proven physiological markers of human pathologies, which correspond to a change in the expression of the genes carrying the candidate SNP markers predicted here. These were markers for spermatogenesis disorders (ZFY: rs1388535808 and rs996955491), for male maturation arrest (CDY2A: rs200670724) as well as for disproportionate short stature at Madelung deformity (e. g., SHOX: rs1452787381) and even for embryogenesis disorders (e. g., SHOX: rs28378830). This indicates a wide range of MRI indicators, alterations in which should be expected in the case of SNPs in the promoters of the human Y-chromosome genes and which can go far beyond changes in male fertility.

[Hypothetical SNP Markers That Significantly Affect the Affinity of the TATA-Binding Protein to VEGFA, ERBB2, IGF1R, FLT1, KDR, and MET Oncogene Promoters as Chemotherapy Targets].

The following hypothesis has been proposed: IF an SNP can significantly increase the expression of an oncogene by increasing the affinity of the TATA-binding protein (TBP) to its promoter, THEN this SNP can also reduce the apparent bioactivity of inhibitors of this oncogene during antitumor chemotherapy and vice versa. In the context of this hypothesis, the previously proposed method (http://beehive.bionet.nsc. ru/cgi-bin/mgs/tatascan/start.pl) was applied to analyze all SNPs found within the [-70; -20] regions (which harbor all proven TBP-binding sites) of the promoters of VEGFA, EGFR, ERBB2, IGF1R, FLT1, KDR, and MET oncogenes according to the human reference genome, hg19. For 83% of these SNPs, their effect on TBP affinity to the oncogene promoters required for assembly of preinitiation complexes was not significant. rs36208385, rs36208384, rs370995111, rs372731987, rs111811434, rs369547510, rs76407893, rs369728300, and rs72001900 can potentially serve as SNP markers to reduce the apparent bioactivity of oncogene inhibitors, while rs141092704, rs184083669, rs145139616, rs200697953, rs187746433, rs199730913, rs377370642, rs114484350, rs374921120, rs146790957, rs376727645, and rs72001900 can be the markers for enhancing this activity.

[The nucleotide sequence features of the mature microRNA seem to be responsible for the affinity to human Ago2 AND Ago3 proteins].

Mature miRNA of 20-24 nt in length are the endogenous sncRNA. They programs RISC to regulate functioning of mRNA with complimentary sites for these miRNAs. In case of Ago3 protein present in human RISC miRNAs direct inhibition of translation, whereas in case of Ago2 is in RISC, than mRNA cleavage in the middle of miRNA/mRNA heteroduplex is also possible. Using ACTIVITY system, that we developed earlier, we analyzed published data on miRNA affinity to human Ago2 and Ago3 proteins. We found increase in miRNA affinity to both Ago2 and Ago3 with the increase of the YRHB tetranucleotide abundance near 3'-end of these miRNAs (r = 0.613, alpha < 0.025). We also found that miRNA tendency to bind Ago2 in favor of Ago3 increases with the RHHK tetranucleotide abundance near miRNA center (r = 0.501, alpha < 0.05). Using these two findings we proposed two formulas to predict miRNA affinity to Ago2 and Ago3 proteins based on the YRHB and RHHK abundances within this arbitrary miRNA. Thereby we made reliable predictions of miRNA affinity to these proteins in RISC for both canonical (alpha < 0.00025) and non-canonical (alpha < 0.05) miRNAs in comparison with independent experimental data.

[A precise equilibrium equation for four steps of binding between TBP and TATA-box allows for the prediction of phenotypical expression upon mutation].

Among the main events of transcription initiation of TATA-containing genes in eukayotes are the recognition and binding of the TATA-box by the TATA-binding protein (TBP) to start the preinitiation complex formation on the nucleosomal DNA. Using the equilibrium equation for step-by-step TBP/TATA-binding, we have analyzed 69 experimental datasets on the characteristics of biologicacally important features altered by TATA-box mutations. Among these features, the TBP/TATA-complex parameters, the transcription level, the activity of gene products, yeast colony growth at a dose of growth inhibitor (phenotype), and the heterogenity of the response of a population to unspecific environmental stress have been described. Significant correlations were found between in silico prediction for TBP/TATA affinity and experimental data for in vivo and in vitro test-systems based on 15 cell types of 19 species, RNA polymerases II and III, and natural, recombinant or mutant TBP. Such an invariant impact of the step-by-step TBP/TATA-binding on the biological activity of complex systems, from a molecule to a population, might be due to the fact that TBP/TATA-complex formation precedes specific steps of transcription machinery assembly, which provide the multivariant jigsaw puzzle according to the expression pattern of each eukaryotic gene.

[TATA box polymorphisms in genes of commercial and laboratory animals and plants associated with selectively valuable traits].

Most of more than 11 million experimentally established polymorphisms, accumulated in dbSNP, were identified in the intergenic spacers or coding DNA regions. This fact enables interpretation of the former polymorphisms as neutral, while the latter make clear the biological sense of the associated mutant phenotypes, "the defect of certain proteins". The association of polymorphisms in regulatory DNA regions with mutant phenotypes is poorly studied. Specifically, the defects in certain DNA/protein binding sites were identified in less than 500 cases. In TATA-containing genes of eukaryotes the TATA box, the TBP (TATA-binding protein) binding site, is located about 30 bp upstream from the transcription start site. Interaction between DNA and TBP triggers assemblage of the preinitiation complex. For 37 TATA box polymorphisms in the genes of commercial and laboratory animals and plants, the effect on TBP-binding activity was evaluated using the equilibrium equation for the four subsequent steps of TBP/TATA box binding (nonspecific binding <----> sliding <----> recognition <----> stabilization). According to the GenBank data, these 37 polymorphisms were associated with the changes in a number of selectively valuable traits. Statistically significant congruence of in silico analysis performed with mutant phenotypes (a < 0.05, binomial law) provides suggestion of the mechanism of phenotypic manifestation of these polymorphisms (changing of the TBP-binding activity), as well a validates the possibility of developing the universal test system for experimental-computer prediction of the effects of TATA box mutations in specified genes on selectively valuable traits of the species, varieties, and breeds.

[Prognosis of affinity change of the TATA-binding protein to TATA-boxes upon polymorphisms of the human gene promoter TATA boxes].

TATA-binding protein (TBP) is a subunit of basal transcription factor TFIID that recognizes and binds to the TATA-box on TATA-containing promoters of class II genes, and starts assembling RNA polymerase II basal transcription complex. It is shown in many works that the sequence of TATA-box with its flanking regions affects the level of basal and activated transcription. TATA-box polymorphisms and human hereditary diseases associated with them show that TBP/TATA interaction may indirectly affect gene regulation in vivo. The object of this work is to determine changes in the TBP/TATA affinity upon polymorphisms in TATA-boxes of human gene promoters. We assess changes in TBP/TATA affinities in silico by using our formula of equilibrium TBP/TATA binding upon four consecutive steps: nonspecific binding <--> sliding <--> braking (stopping) <--> stabilization. Our prognoses agree with known examples of TATA-box polymorphisms and human hereditary diseases associated with them.

TATA box polymorphisms in human gene promoters and associated hereditary pathologies.

TATA-binding protein (TBP) is the first basal factor that recognizes and binds a TATA box on TATA-containing gene promoters transcribed by RNA polymerase II. Data available in the literature are indicative of admissible variability of the TATA box. The TATA box flanking sequences can influence TBP affinity as well as the level of basal and activated transcription. The possibility of mediated involvement in in vivo gene expression regulation of the TBP interactions with variant TATA boxes is supported by data on TATA box polymorphisms and associated human hereditary pathologies. A table containing data on TATA element polymorphisms in human gene promoters (about 40 mutations have been described), associated with particular pathologies, their short functional characteristics, and manifestation mechanisms of TATA-box SNPs is presented. Four classes of polymorphisms are considered: TATA box polymorphisms that weaken and enhance promoter, polymorphisms causing TATA box emergence and disappearance, and human virus TATA box polymorphisms. The described examples are indicative of the polymorphism-associated severe pathologies like thalassemia, the increased risk of hepatocellular carcinoma, sensitivity to H. pylori infection, oral cavity and lung cancers, arterial hypertension, etc.