{"id":97,"date":"2021-10-18T06:42:14","date_gmt":"2021-10-18T03:42:14","guid":{"rendered":"https:\/\/conf.icgbio.ru\/bgrs\/?page_id=97"},"modified":"2022-01-17T09:49:25","modified_gmt":"2022-01-17T06:49:25","slug":"abstract-list","status":"publish","type":"page","link":"https:\/\/conf.icgbio.ru\/bgrs\/abstracts\/abstract-list\/","title":{"rendered":"Abstract list"},"content":{"rendered":"

DATABASES ON REGULATORY GENOMIC SEQUENCES AND REGULATORY PROTEINS<\/h2>\n
    \n
  1. A PROMOTER DATABASE OF YEAST SACCHAROMYCES CEREVISIAE (SCPD)<\/a>.
    \nJIAN ZHU,\u00a0ZHANG MICHAEL Q.<\/i><\/li>\n
  2. DEVELOPMENT OF A RECEPTOR DATABASE<\/a>.
    \nKOTOKO NAKATA,\u00a0TAKAKO TAKAI,\u00a0TSUGUCHIKA KAMINUMA<\/i><\/li>\n
  3. HOX-PRO DB: THE WAYS OF EVOLUTION OF ENSEMBLES OF HOMEOBOX GENES-CONTROLLERS OF DEVELOPMENT<\/a>.
    \nSPIROV A.V.<\/i><\/li>\n
  4. EPOGERD: A DATABASE ON REGULATION OF EUKARYOTIC GENE EXPRESSION<\/a>.
    \nSTOECKERT S.,\u00a0PODKOLODNAYA O.A.,\u00a0KEL A.E.,\u00a0BRUNK B.,\u00a0HAAS J.,\u00a0SALAS F.,\u00a0STEPANENKO I.L.,\u00a0IGNATIEVA E.V.,\u00a0KEL-MARGOULIS O.V.,\u00a0ANANKO E.A.,\u00a0PODKOLODNY N.L.,\u00a0OVERTON G.C.,\u00a0KOLCHANOV N.A.<\/i><\/li>\n
  5. TRANSCRIPTION REGULATORY REGIONS DATABASE (TRRD): NEW POSSIBILITIES PROVIDED BY RELEASE 4.0<\/a>.
    \nKOLCHANOV N.A.,\u00a0IGNATIEVA E.V.,\u00a0KEL-MARGOULIS O.V.,\u00a0KEL A.E.,\u00a0ANANKO E.A.,\u00a0PODKOLODNAYA O.A.,\u00a0STEPANENKO I.L.,\u00a0MERKULOVA T.I.,\u00a0GORYACHKOVSKY T.N.,\u00a0KOLPAKOV F.A.,\u00a0PODKOLODNY N.L.,\u00a0LAVRYUSHEV S.V.,\u00a0GRIGOROVICH D.A.,\u00a0FROLOV A.S.,\u00a0ROMASHCHENKO A.G.<\/i><\/li>\n
  6. PROGRAMS FOR DATA INPUT TO THE TRANSCRIPTION REGULATORY REGIONS DATABASE<\/a>.
    \nANANKO E.A.,\u00a0NAUMOCHKIN A.N.,\u00a0FOKIN O.N.,\u00a0FROLOV A.S.<\/i><\/li>\n
  7. THE GLUCOCORTICOID-CONTROLLED GENE REGULATORY REGIONS DATABASE (GR-TRRD): THE USING FOR THE ELUCIDATION OF THE MECHANISMS OF CHEMICAL HEPATOCARCINOGENS ACTION<\/a>.
    \nMERKULOVA T.I.,\u00a0MERKLOV V.M.,\u00a0KROPATCHEV K.Y.,\u00a0KALEDIN V.I.<\/i><\/li>\n
  8. INTERFERON-INDUCIBLE GENES — TRANSCRIPTION REGULATORY REGIONS DATABASE (IIG-TRRD)<\/a>.
    \nANANKO E.A.,\u00a0BAZHAN S.I.,\u00a0BELOVA O.E.<\/i><\/li>\n
  9. THE ESRG-TRRD: DATABASE OF GENES WITH SPECIFIC TRANSCRIPTION REGULATION IN ERYTHROID CELLS<\/a>.
    \nPODKOLODNAYA O.A.,\u00a0STEPANENKO I.L.<\/i><\/li>\n
  10. THE LIPID METABOLISM TRANSCRIPTION REGULATORY REGIONS DATABASE (LM-TRRD): TRANSCRIPTION REGULATION OF LIPID METABOLISM GENES<\/a>.
    \nIGNATIEVA E.V.<\/i><\/li>\n
  11. PLANT-TRRD DATABASE<\/a>.
    \nGORYACHKOVSKY T.N.,\u00a0ANANKO E.A.,\u00a0PELTEK S.E.<\/i><\/li>\n
  12. COMPEL: A DATABASE ON COMPOSITE REGULATORY ELEMENTS<\/a>.
    \nKEL-MARGOULIS O.V.,\u00a0KEL A.E.,\u00a0FRISCH M.,\u00a0ROMASHCHENKO A.G.,\u00a0KOLCHANOV N.A.,\u00a0WINGENDER E.<\/i><\/li>\n
  13. SAMPLES AND ALIGNED: DATABASES FOR FUNCTIONAL SITE SEQUENCES<\/a>.
    \nVOROBIEV D.G.,\u00a0PONOMARENKO J.V.,\u00a0PODKOLODNAYA O.A.<\/i><\/li>\n
  14. ACTIVITY: A DATABASE FOR ACTIVITIES OF FUNCTIONAL DNA\/RNA SITES<\/a>.
    \nPONOMARENKO J.V.,\u00a0FURMAN D.P.,\u00a0MISHCHENKO T.M.,\u00a0KATOKHINA L.V.,\u00a0VALUEV V.P.,\u00a0PEREGOEDOVA E.L.,\u00a0FROLOV A.S.,\u00a0PODKOLODNY N.L.,\u00a0PONOMARENKO M.P.<\/i><\/li>\n
  15. B-DNA-VIDEO: AN ACTIVE DATABASE FOR THE SIGNIFICANT B-DNA FEATURES OF TRANSCRIPTION FACTOR BINDING SITES<\/a>.
    \nPONOMARENKO M.P.,\u00a0FROLOV A.S.,\u00a0PONOMARENKO J.V.,\u00a0VOROBIEV D.G.,\u00a0LEVITSKY V.G.,\u00a0PODKOLODNAYA O.A.,\u00a0OVERTON G.C.,\u00a0KOLCHANOV N.A.<\/i><\/li>\n
  16. GENEEXPRESS SYSTEM: DESCRIPTION, ANALYSIS, AND RECOGNITION OF REGULATORY SEQUENCES IN EUKARYOTIC GENOMES<\/a>.
    \nKOLCHANOV N.A.,\u00a0PONOMARENKO M.P.,\u00a0KONDRAKHIN Y.V.,\u00a0FROLOV A.S.,\u00a0KOLPAKOV F.A.,\u00a0KEL A.E.,\u00a0KEL-MARGOULIS O.V.,\u00a0ANANKO E.A.,\u00a0IGNATIEVA E.V.,\u00a0PODKOLODNAYA O.A.,\u00a0STEPANENKO I.L.,\u00a0MERKULOVA T.I.,\u00a0BABENKO V.N.,\u00a0VOROBIEV D.G.,\u00a0LAVRYUSHEV S.V.,\u00a0GRIGOROVICH D.A.,\u00a0PONOMARENKO J.V.,\u00a0KOCHETOV A.V.,\u00a0KOLESOV G.B.,\u00a0PODKOLODNY N.L.,\u00a0WINGENDER E.,\u00a0HAINEMEIER T.,\u00a0MILANESI L.,\u00a0SOLOVYEV V.V.,\u00a0OVERTON G.C.<\/i><\/p>\n

    GENE NETWORKS: DATABASES, COMPUTER ANALYSIS, MODELLING OF METABOLIC PATHWAYS\/RESPONSE<\/h2>\n<\/li>\n
  17. GENET, A DATABASE OF GENETIC NETWORKS<\/a>.
    \nSAMSONOVA M.G.,\u00a0SAVOSTYANOVA E.G.,\u00a0SEROV V.N.,\u00a0SPIROV A.V.,\u00a0REINITZ J.<\/i><\/li>\n
  18. GENE NETWORKS: A DATABASE AND ITS AUTOMATED VISUALIZATION THROUGH THE INTERNET IN THE GENENET COMPUTING SYSTEM<\/a>.
    \nANANKO E.A.,\u00a0KOLPAKOV F.A.,\u00a0KOLESOV G.B.,\u00a0KOLCHANOV N.A.<\/i><\/li>\n
  19. MOLECULAR DATABASE INTEGRATION: ANALYSIS OF METABOLIC NETWORK CONTROL<\/a>.
    \nFREIER A.,\u00a0HODING M.,\u00a0HOFESTADT R.,\u00a0LANGE M,\u00a0SCHOLZ U.<\/i><\/li>\n
  20. THEORY OF MOLECULAR GENETIC REGULATORY SYSTEMS (MGRS): KEY IDEAS AND RESULTS<\/a>.
    \nRATNER V.A.<\/i><\/li>\n
  21. MODELING SIGNAL PATHWAYS<\/a>.
    \nBENTOLILA SIMONE<\/i><\/li>\n
  22. A VIRTUAL CELL WITH 127 GENES<\/a>.
    \nTOMITA MASARU,\u00a0KENTA HASHIMOTO,\u00a0KOUICHI TAKAHASHI,\u00a0TOM SHIMIZU,\u00a0YURI MATSUZAKI,\u00a0FUMIHIKO MIYOSHI,\u00a0KANAKO SAITO,\u00a0SAKURA TANIDA,\u00a0KATSUYUKI YUGI,\u00a0J. CRAIG VENTER,\u00a0CLYDE A. HUTCHISON<\/i><\/li>\n
  23. A THREE-LAYER MODEL FOR DESCRIBING DEVELOPMENT OF C.ELEGANS<\/a>.
    \nTSUGUCHIKA KAMINUMA,\u00a0IGARASHI TAKAKO,\u00a0NAKANO TATSUYA,\u00a0SASAKI SHINYA,\u00a0MIWA JOHJI<\/i><\/li>\n
  24. FLOWER MORPHOGENESIS IN ARABIDOPSIS THALIANA: A LOGICAL ANALYSIS<\/a>.
    \nMENDOZA LUIS,\u00a0ALVAREZ-BUYLLA ELENA,\u00a0THIEFFRY DENIS<\/i><\/li>\n
  25. INTEGRATING OF KNOWLEDGE ON REGULATION OF MX1 PROTEIN INDUCTION AND ANTIVIRAL ACTION BY A MATHEMATICAL MODELING APPROACH<\/a>.
    \nBAZHAN S.I.,\u00a0BELOVA O.E.<\/i><\/li>\n
  26. THE EQUATIONS OF DYNAMICS OF GENES ACTIVITIES IN A GENERAL VIEW<\/a>.
    \nTCHURAEU R.N.<\/i><\/li>\n
  27. REGULATION MECHANISMS IN BIOLOGICAL SYSTEMS<\/a>.
    \nKOLCHANOV N.A.,\u00a0MATUSHKIN Yu.G.,\u00a0FROLOV A.S.<\/i><\/li>\n
  28. GENETIC LEVEL OF BIOPROCESSES REGULATION AND BIOSYSTEMS IN EXTREME CONDITIONS<\/a>.
    \nNEFEDOV V.P.,\u00a0CHEREPANOVA E.Yu.<\/i><\/p>\n

    REGULATORY GENOMIC SEQUENCES: COMPUTER ANALYSIS AND RECOGNITION, MOLECULAR MECHANISMS OF FUNCTIONING<\/h2>\n<\/li>\n
  29. A MODULAR METAPROFILE-BASED SYSTEM FOR PREDICTION AND ANALYSIS OF EUKARYOTIC PROMOTERS<\/a>.
    \nJUNIER THOMAS,\u00a0KROGH ANDERS,\u00a0BUCHER PHILIPP<\/i><\/li>\n
  30. A NEW METHOD OF SPECTRAL ANALYSIS OF DNA\/RNA AND PROTEIN SEQUENCES<\/a>.
    \nBAJIC V.B.,\u00a0BAJIC I.V.,\u00a0HIDE W.<\/i><\/li>\n
  31. RECOGNITION OF THE SUBSET OF EUKARYOTIC PROMOTERS<\/a>.
    \nKONDRAKHIN Y.V.,\u00a0OVERTON G.C.<\/i><\/li>\n
  32. PROMOTERS: AT\/GC CONTENT AND PROPERTIES OF TATA BOX<\/a>.
    \nKOSAREV P.,\u00a0BABENKO V.N.<\/i><\/li>\n
  33. SPECIFIC FEATURES OF X-LINKED PROMOTER SEQUENCES IN DROSOPHILA<\/a>.
    \nARKHIPOVA IRINA R.<\/i><\/li>\n
  34. DNA STRUCTURE IN HUMAN RNA POLYMERASE II PROMOTERS<\/a>.
    \nPEDERSEN ANDERS GORM,\u00a0BALDI PIERRE,\u00a0CHAUVIN YVES,\u00a0BRUNAK SOREN<\/i><\/li>\n
  35. A PROGRAM FOR CALCULATING GAPPED DINUCLEOTIDE CORRELATIONS IN NUCLEIC ACID SEQUENCES AND ITS APPLICATION TO REVEAL SPECIFIC SEQUENCE FEATURES OF X-LINKED PROMOTERS IN DROSOPHILA<\/a>.
    \nARKHIPOVA IRINA R.,\u00a0POKROVSKI SERGEI V.<\/i><\/li>\n
  36. A SYSTEM FOR ACTIVATION OF THE TRRD DATABASE: FURTHER DEVELOPMENT OF GENEEXPRESS<\/a>.
    \nFROLOV A.S.,\u00a0LAVRYUSHEV S.V.,\u00a0VOROBIEV D.G.,\u00a0GRIGOROVICH D.A.<\/i><\/li>\n
  37. COMBINATORIAL IDENTIFICATION OF PROMOTERS INDUCED UPON IMMUNE CELL ACTIVATION<\/a>.
    \nKEL A.E.,\u00a0KEL-MARGOULIS O.V.,\u00a0BABENKO V.N.,\u00a0WINGENDER E.<\/i><\/li>\n
  38. SEARCH FOR DEGENERATE OLIGONUCLEOTIDE MOTIFS IN TRANSCRIPTION FACTOR BINDING SITES AND EUKARYOTIC PROMOTERS (THE SYSTEM ARGO)<\/a>.
    \nVISHNEVSKY O.V.,\u00a0PODKOLODNAYA O.A.,\u00a0BABENKO V.N.<\/i><\/li>\n
  39. COMPUTER ANALYSIS OF TRANSCRIPTION REGULATORY PATTERNS IN COMPLETELY SEQUENCED BACTERIAL GENOMES<\/a>.
    \nGELFAND M.S.,\u00a0MIRONOV A.A.<\/i><\/li>\n
  40. MOLECULAR MECHANISMS OF PROMOTER-POLYMERASE RECOGNITION. ELECTROSTATIC INTERACTIONS IN PROMOTERS RECOGNIZED BY E.COLI Esigma70<\/a>.
    \nKAMZOLOVA S.G.,\u00a0DZHELYADIN T.R.,\u00a0SOROKIN A.A.,\u00a0IVANOVA N.N.,\u00a0KUTUZOVA G.I.,\u00a0ESIPOVA N.G.,\u00a0POLOZOV R.V.<\/i><\/li>\n
  41. ANALYSIS OF COMPLETED GENOMES SUGGESTS THAT HAIRPIN FORMATION IS NOT A UNIVERSAL MECHANISM FOR PROCARYOTIC TRANSCRIPTION TERMINATION<\/a>.
    \nTAKANORI WASHIO,\u00a0TOMITA MASARU<\/i><\/li>\n
  42. RECOGNITION ACCURACY OF DNA FUNCTIONAL SITES CAN BE INCREASED BY AVERAGING PARTIAL RECOGNITIONS<\/a>.
    \nPONOMARENKO M.P.,\u00a0FROLOV A.S.,\u00a0PONOMARENKO J.V.,\u00a0PODKOLODNAYA O.A.,\u00a0VOROBIEV D.G.,\u00a0KOLCHANOV N.A.,\u00a0OVERTON G.C.<\/i><\/li>\n
  43. OCT PROTEINS AND OCT GENES: DNA RECOGNITION AND TRANSCRIPTIONALREGULATION<\/a>.
    \nPOLANOVSKY O.L.,\u00a0PANKRATOVA E.V.,\u00a0STEPCHENKO A.G.<\/i><\/li>\n
  44. QUANTITATIVE COMPUTER-ASSISTED ANALYSIS OF THE TATA-BINDING PROTEIN AFFINITY FOR COMPLEMENTARY DUPLEXES OF SYNTHETIC OLIGODEOXYRIBONUCLEOTIDES<\/a>.
    \nSAVINKOVA L.K.,\u00a0SOKOLENKO A.A.,\u00a0RAU V.A.,\u00a0KOBZEV V.F.,\u00a0PONOMARENKO M.P.,\u00a0PONOMARENKO J.V.,\u00a0KOLCHANOV N.A.<\/i><\/li>\n
  45. NEW FUNCTIONS OF P53 GENE: REGULATORY AND HYPERSENSITIVE SITES IN EXONS OF MUTANT P53 MRNA FORMS<\/a>.
    \nBLINOV V.M.,\u00a0RESENCHUK S.M.,\u00a0CHIRIKOVA G.B.,\u00a0PETROV N.A.,\u00a0PUZYREV A.A.,\u00a0ORESHKOVA S.F.,\u00a0KUVSHINOV V.N.,\u00a0ILYICHEV A.A.,\u00a0ROMASHCHENKO A.G.,\u00a0RUZANKINA Ya.S.,\u00a0MARTYNOV Yu.A.,\u00a0VINOGRADOV S.S.,\u00a0VOEVODA M.I.,\u00a0VARDASANIDZE K.S.,\u00a0KISSELEV L.L.,\u00a0MARTYNYUK R.A.,\u00a0SANDAKHCHIEV L.S.,\u00a0KARAKIN E.I.<\/i><\/li>\n
  46. IN SILICO IDENTIFICATION OF MARS\/SARS IN DNA SEQUENCES<\/a>.
    \nGLAZKO G.V.,\u00a0ROGOZIN I.B.,\u00a0GLAZKOV M.V.<\/i><\/li>\n
  47. SOME POSSIBLE ELEMENTS OF TRANSCRIPTION REGULATION OF RICE CHLOROPLAST ENCODED GENES<\/a>.
    \nSHAHMURADOV I.A.,\u00a0MUSTAFAYEV N.Sh.,\u00a0ALIEV J.A.<\/i><\/li>\n
  48. ANALYSIS OF FUNCTIONAL SITE MOTIFS OF MOBILE GENETIC ELEMENTS RELATIVE TO THEIR POSSIBLE MOLECULAR FUNCTIONS<\/a>.
    \nAMIKISHIEV V.G.,\u00a0RATNER V.A.<\/i><\/li>\n
  49. TOWARDS UNDERSTANDING OF REGULATION OF NON-LTR RETROTRANSPOSONS: RTE-1 ELEMENT OF THE NEMATODE CAENORHABDITIS ELEGANS<\/a>.
    \nBEREZIKOV E.,\u00a0BLINOV A.,\u00a0BERGTROM G.<\/i><\/li>\n
  50. LARGE SCALE SCREENING FOR TRANSCRIPTION REGULATORY SEQUENCES RECOGNISED BY HOX HOMEODOMAIN PROTEINS<\/a>.
    \nJAKT L.M.,\u00a0SHAM M.H.<\/i><\/li>\n
  51. FUNCTIONAL ACTIVITY OF A NOVEL GCC-ELEMENT FOUND IN HOMOLOGOUS REGULATORY REGIONS OF SOME HUMAN GENES<\/a>.
    \nPEREVOZCHIKOV A.,\u00a0ORLOV S.<\/i><\/li>\n
  52. REVEALING THE CONFORMATIONAL AND PHYSICO-CHEMICAL DNA PROPERTIES APPLICABLE FOR PREDICTING THE ACTIVITY OF DNA FUNCTIONAL SITES<\/a>.
    \nPONOMARENKO M.P.,\u00a0KOLCHANOV N.A.,\u00a0PONOMARENKO J.V.,\u00a0FROLOV A.S.,\u00a0PODKOLODNAYA O.A.,\u00a0VOROBIEV D.G.,\u00a0PODKOLODNY N.L.,\u00a0OVERTON G.C.<\/i><\/li>\n
  53. CLASSIFICATION OF EUKARYOTIC TRANSCRIPTION FACTORS BASED ON SIGNIFICANT B-DNA CONFORMATIONAL AND PHYSICO-CHEMICAL PROPERTIES OF THEIR BINDING SITES<\/a>.
    \nPONOMARENKO J.V.<\/i><\/li>\n
  54. FINE STRUCTURE OF THE PROFILE OF BENDING STIFFNESS ENERGY OF NUCLEOSOMAL DNA<\/a>.
    \nLEVITSKY V.G.<\/i><\/li>\n
  55. A NEW CUT-OFF ESTIMATING ALGORITHM FOR TRANSCRIPTION FACTOR BINDABILITY ON DNA<\/a>.
    \nTSUNODA T.,\u00a0TAKAGI T.<\/i><\/li>\n
  56. IDENTIFYING DNA AND PROTEIN PATTERNS WITH STATISTICALLY SIGNIFICANT ALIGNMENT MATRICES<\/a>.
    \nHERTZ GERALD Z.,\u00a0STORMO GARY D.<\/i><\/li>\n
  57. CONTEXT-FREE METHOD OF PATTERN RECOGNITION IN THE GENETIC TEXTS<\/a>.
    \nAKBEROVA N.,\u00a0KOLPAKOV A.,\u00a0LEONTIEV A.<\/i><\/li>\n
  58. SOME PECULIARITIES OF LONG-RANGE INTERACTION BETWEEN NUCLEOTIDES IN THE INTRACELLULAR LIQUIDS<\/a>.
    \nPINCHUK A.O.,\u00a0VYSOTSKII V.I.<\/i><\/li>\n
  59. STRUCTURAL AND COMPOSITIONAL FEATURES OF 5\u2019 UNTRANSLATED REGIONS OF HIGHER PLANT MRNAS<\/a>.
    \nKOCHETOV A.V.,\u00a0PILUGIN M.V.,\u00a0KOLPAKOV F.A.,\u00a0BABENKO V.N.,\u00a0KVASHNINA E.V.,\u00a0SHUMNY V.K.<\/i><\/li>\n
  60. EUKARYOTIC MRNAS ENCODING ABUNDANT AND SCARCE PROTEINS ARE DISSIMILAR IN MANY STRUCTURAL FEATURES OF 5\u2019-UNTRANSLATED LEADERS<\/a>.
    \nKOCHETOV A.V.,\u00a0PONOMARENKO M.P.,\u00a0VOROBIEV D.G.,\u00a0FROLOV A.S.,\u00a0KISSELEV L.L.,\u00a0KOLCHANOV N.A.<\/i><\/li>\n
  61. EXTRACTING KOZAK CONSENSUS SEQUENCE USING KLEISLI<\/a>.
    \nJING CHEN,\u00a0NAM-HAI CHUA,\u00a0DAPHNA STRAUSS,\u00a0LIMSOON WONG<\/i><\/li>\n
  62. ON NEGATIVE SELECTION AGAINST ATG TRIPLETS NEAR START CODONS IN EUCARYOTIC AND PROCARYOTIC GENOMES<\/a>.
    \nRINTARO SAITO,\u00a0TOMITA MASARU<\/i><\/li>\n
  63. COMPUTER ANALYSIS OF BASE PAIRING FREE-ENERGY BETWEEN SHINE-DALGARNO SEQUENCE AND 16S RRNA SEQUENCE IN VARIOUS PROCARYOTES<\/a>.
    \nOSADA YUKO,\u00a0RINTARO SAITO,\u00a0TOMITA MASARU<\/i><\/li>\n
  64. CONSERVED RNA STRUCTURES REGULATE INITIATION OF TRANLSATION OF ESCERICHIA COLI AND HAEMOPHILUS INFLUENZAE RIBOSOMAL PROTEIN OPERONS<\/a>.
    \nVITRESCHAK A.,\u00a0BANSAL A.K.,\u00a0GELFAND M.S.<\/i><\/p>\n

    GENE RECOGNITION AND ANALYSIS, GENERAL PROBLEMS OF COMPUTATIONAL GENOMICS<\/h2>\n<\/li>\n
  65. SOME PROBLEMS OF GENE RECOGNITION IN PROTIST DNA<\/a>.
    \nASTAKHOVA T.V.,\u00a0GELFAND M.S.,\u00a0ROYTBERG M.A.<\/i><\/li>\n
  66. THE STRUCTURAL ANALYSIS OF THE DNA FRAGMENTS ASSOCIATED WITH THE NUCLEAR LAMINS IN DROSOPHILA MELANOGASTER<\/a>.
    \nLIKHACHEVA E.,\u00a0PONOMARENKO M.P.,\u00a0BOGACHEV S.,\u00a0KOKOZA E.,\u00a0FISHER P.,\u00a0PONOMARENKO J.V.,\u00a0VOROBIEV D.G.,\u00a0KOLESOV G.B.,\u00a0KOLCHANOV N.A.<\/i><\/li>\n
  67. GENE RECOGNITION USING EST DATA: UNEXPECTEDLY FREQUENT ALTERNATIVE SPLICING OF HUMAN GENES<\/a>.
    \nMIRONOV A.A.,\u00a0GELFAND M.S.<\/i><\/li>\n
  68. WEBGENE: INTERACTIVE TOOLS FOR PREDICTION AND ANALYSIS OF PROTEIN-CODING GENES STRUCTURE IN INTERNET<\/a>.
    \nMILANESI L.,\u00a0ROGOZIN I.B.,\u00a0D\u2019ANGELO D.<\/i><\/li>\n
  69. ASYMMETRICAL CODING SEQUENCE REPARTITION AND CODON ADAPTATION INDEX VALUES BETWEEN LEADING AND LAGGING STRANDS IN SEVEN BACTERIAL SPECIES<\/a>.
    \nPERRIERE G.,\u00a0LOBRY J.R.<\/i><\/li>\n
  70. TRIPLET PERIODICITY OF THE DNA CODING AND NONCODING REGIONS<\/a>.
    \nRUDENKO V.M.,\u00a0KOROTKOV E.V.<\/i><\/li>\n
  71. A PROBABLE MUTUAL RELATIONSHIP BETWEEN LATENT PERIODIC GENE STRUCTURE AND PERIODIC CONFORMATION OF THE PROTEIN<\/a>.
    \nCHALEY M.B.,\u00a0KOROTKOV E.V.<\/i><\/li>\n
  72. SELF-ORGANIZING NEURAL NETWORKS HIGHLIGHT POSSIBLE FUNCTIONALLY RELEVANT REGIONS IN THE C-DNA CODING SEQUENCES OF G-PROTEIN COUPLED RECEPTORS<\/a>.
    \nCASADIO R.,\u00a0ARRIGO P.,\u00a0FARISELLI P.<\/i><\/li>\n
  73. HOW BASICS OF PROTEIN EVOLUTION COULD HELP THE GENE FINDING<\/a>.
    \nTRIFONOV E.N.<\/i><\/li>\n
  74. MGL-PROT: THE ANTHOLOGY-BASED QUERY LANGUAGE FOR THE USER SEARCH FOR THE 3D STRUCTURES AND FUNCTIONS OF PROTEINS IN THE WWW-AVAILABLE DATABASES<\/a>.
    \nKOLPAKOV F.A.,\u00a0FROLOV A.S.,\u00a0PONOMARENKO M.P.,\u00a0PODKOLODNY N.L.<\/i><\/li>\n
  75. PRE-MRNA SPLICING IN EUKARYOTES — INTRON STRUCTURE, INTRON DETECTION, ALGORITHMS AND DATA STRUCTURES<\/a>.
    \nCHEKMENEV D.S.<\/i><\/li>\n
  76. SELECTIVE MODELS FOR MAPPING OF GENES IDENTIFIED IN RADIATION HYBRIDS<\/a>.
    \nSVISCHEVA G.R.<\/i><\/li>\n
  77. MINIMUM ENTROPY PRINCIPLE AND CLASSIFICATION OF SYMBOLS FOR REVEALING STATISTICAL REGULARITIES IN A TEXT<\/a>.
    \nBUGAENKO N.N.,\u00a0GORBAN A.N.,\u00a0SAPOZHNIKOV A.N.<\/i><\/li>\n
  78. MAXIMUM ENTROPY PRINCIPLE AND MEASUREMENT OF INFORMATION CONTENT OF GENETIC TEXT<\/a>.
    \nBUGAENKO N.N.,\u00a0GORBAN A.N.,\u00a0SADOVSKY M.G.<\/i><\/li>\n
  79. SEGMENTATION OF YEAST DNA USING HIDDEN MARKOV MODELS<\/a>.
    \nPESHKIN L.,\u00a0GELFAND M.S.<\/i><\/li>\n
  80. CHARACTERIZATION OF THE COMPACT MODEL GENOME OF THE JAPANESE PUFFER FISH (FUGU RUBRIPES) USING A COSMID SEQUENCE SCANNING APPROACH<\/a>.
    \nELGAR G.,\u00a0CLARK M.S.,\u00a0EDWARDS Y.J.K.,\u00a0MEEK S.,\u00a0SMITH S.,\u00a0UMRANIA Y.,\u00a0WARNER S.,\u00a0WILLIAMS G.,\u00a0BISHOP M.J.<\/i><\/li>\n
  81. PREDICTING RNA FOLDING BY GENETIC ALGORITHM WITH LOCAL EXHAUSTION<\/a>.
    \nTITOV I.I.,\u00a0IVANISENKO V.A.,\u00a0KOLCHANOV N.A.<\/i><\/li>\n
  82. STATISTICAL MODEL OF DOUBLE HELIX GROWTH<\/a>.
    \nTITOV I.I.<\/i><\/li>\n
  83. RAPID ESTIMATES OF STATISTICAL SIGNIFICANCE OF THE PAIRWISE NUCLEOTIDE SEQUENCE ALIGNMENT<\/a>.
    \nSELEDTSOV I.A.,\u00a0KOLPAKOV F.A.<\/i><\/p>\n

    COMPARATIVE AND EVOLUTIONARY GENOMICS<\/h2>\n<\/li>\n
  84. THEATRE: A NOVEL TOOL FOR THE COMPARATIVE INVESTIGATION AND DISPLAY OF EVOLUTIONARY DIVERSITY OF FUNCTIONAL AND STRUCTURAL FEATURES IN DNA SEQUENCES<\/a>.
    \nEDWARDS Y.J.K.,\u00a0FRITH M.,\u00a0ELGAR G.,\u00a0BISHOP M.J.<\/i><\/li>\n
  85. SEQUENCE ALIGNMENT WITHOUT GAP PENALTIES<\/a>.
    \nROYTBERG M.A.,\u00a0SEMIONENKOV M.N.,\u00a0TABOLINA O.Yu.<\/i><\/li>\n
  86. AUTHOMATIC CLASSIFICATION OF NUCLEOTIDE SEQUENCES AND ITS RELATION TO NATURAL TAXONOMY AND PROTEIN FUNCTION<\/a>.
    \nGORBAN A.N.,\u00a0POPOVA T.G.,\u00a0SADOVSKY M.G.<\/i><\/li>\n
  87. A NATURAL TAXONOMY OF GENE FAMILIES FROM COMPLETE GENOMES<\/a>.
    \nTATUSOV R.L.,\u00a0KOONIN E.V.,\u00a0LIPMAN D.J.<\/i><\/li>\n
  88. GENOMES DATA IN ENTREZ: REPRESENTATION AND ANALYSIS<\/a>.
    \nTATUSOVA T.A.,\u00a0OSTELL J.<\/i><\/li>\n
  89. INVARIANT SECONDARY STRUCTURE OF ALU REPEATS PREDETERMINES CLUSTERIZATION OF REGULATORY ELEMENTS IN HUMAN GENOME<\/a>.
    \nBLINOV V.M.,\u00a0UVAROV D.L.,\u00a0RESENCHUK S.M.,\u00a0CHIRIKOVA G.B.,\u00a0KISSELEV L.L.<\/i><\/li>\n
  90. IMGT ALGORITHM AND RULES FOR IMMUNOGLOBULIN AND T-CELL RECEPTOR MOTIF RECOGNITION<\/a>.
    \nGIUDICELLI VERONIQUE,\u00a0CHAUME DENYS,\u00a0MENNESSIER GERARD,\u00a0LEFRANC MARIE-PAULE<\/i><\/li>\n
  91. THREE SUBFAMILIES OF SHORT INTERSPERSED ELEMENTS OF THE DOG GENOME: POSSIBLE ORIGIN AND FUNCTIONS<\/a>.
    \nKOLESNIKOV N.N.,\u00a0ROGOZIN I.B.,\u00a0LAVRENTIEVA M.V.,\u00a0ELISAPHENKO E.A.<\/i><\/li>\n
  92. SEARCHING FOR THE IMMUNOGLOBULIN SUPERFAMILY GENES IN C.ELEGANS<\/a>.
    \nTARANIN A.V.,\u00a0ROGOZIN I.B.<\/i><\/li>\n
  93. GENOME HOMOLOGY AND CHROMOSOMAL PHYLOGENETICS-COMPARATIVE COMPUTER ANALYSIS<\/a>.
    \nZAKHAROV I.A.<\/i><\/li>\n
  94. FROM GENOMICS TO EPIGENOMICS: DATA TRANSFERABILITY ACROSS THE EVOLUTIONARY SPECTRUM<\/a>.
    \nGEORGE L. GABOR MIKLOS<\/i><\/li>\n
  95. REGRESSION ANALYSIS OF MUTATIONAL SPECTRA<\/a>.
    \nROGOZIN I.B.,\u00a0BERIKOV V.B.<\/i><\/li>\n
  96. THEORETICAL ANALYSIS OF POSSIBLE EVOLUTIONARY TRENDS IN CODON DISTRIBUTION ALONG THE mRNA<\/a>.
    \nLIKHOSHVAI V.A.,\u00a0MATUSHKIN Yu.G.<\/i><\/li>\n
  97. THEORETICAL ANALYSIS OF MUTATION PATTERN OF THE CYTOCHROME P450 SUPERFAMILY<\/a>.
    \nMATUSHKIN Yu.G.,\u00a0MOROZOVA I.N.,\u00a0MOROZOV P.S.<\/i><\/li>\n
  98. INFOGENE: A DATABASE OF KNOWN GENE STRUCTURES AND PREDICTED GENES AND PROTEINS IN SEQUENCES OF GENOME SEQUENCING PROJECTS<\/a>.
    \nSOLOVYEV V.V.,\u00a0SALAMOV A.A.<\/i><\/li>\n
  99. RECONSTRUCTION OF THE GENOFOND PECULIARITIES OF THE ANCIENT PAZYRYK POPULATION (I-II MILLENIUM BC) FROM GORNY ALTAI ACCORDING TO THE MTDNA STRUCTURE<\/a>.
    \nVOEVODA M.I.,\u00a0SITNIKOVA V.V.,\u00a0ROMASHCHENKO A.G.,\u00a0CHIKISHEVA T.A.,\u00a0POLOS’MAK N.V.,\u00a0MOLODIN V.I.<\/i><\/p>\n

    PROTEIN STRUCTURE ANALYSIS<\/h2>\n<\/li>\n
  100. ON THE NUMBER OF STRUCTURAL FAMILIES IN THE PROTEIN UNIVERSE<\/a>.
    \nALEXANDROV N.,\u00a0GO N.<\/i><\/li>\n
  101. LATENT PERIODICITY OF PROTEIN SEQUENCES<\/a>.
    \nKOROTKOV E.V.,\u00a0KOROTKOVA M.A.<\/i><\/li>\n
  102. DETECTION OF SIMILAR PROTEINS BY THE INVERSE-FOLDING PROTOCOL<\/a>.
    \nOTA MOTONORI,\u00a0NISHIKAWA KEN<\/i><\/li>\n
  103. PROTEIN 3D ALIGNMENT SOFTWARE FOR INTEL COMPUTERS<\/a>.
    \nVTYURIN N.,\u00a0BATURIN V.,\u00a0GULIN V.,\u00a0GORYACHEV N.<\/i><\/li>\n
  104. LIKENESS: A SYSTEM SEARCHING FOR AND ALIGNING SIMILAR PROTEIN CONFORMATIONS<\/a>.
    \nPONOMARENKO M.P.,\u00a0KOLCHANOV N.A.,\u00a0SHINDYALOV I.,\u00a0BOURNE P.<\/i><\/li>\n
  105. STRUCTURAL AND FUNCTIONAL ANNOTATION OF GENOMIC SEQUENCES:ASSIGNMENT OF FOLD FAMILY AND SORTING OF PROTEINS WITH RESPECT TO SUBCELLULAR LOCALIZATION<\/a>.
    \nEISENHABER FRANK,\u00a0BORK PEER,\u00a0HUYNEN MARTIJN,\u00a0ORENGO CHRISTINE,\u00a0SCHULTZ JORG,\u00a0SUNYAEV SHAMIL R.,\u00a0YUAN YANPING<\/i><\/li>\n
  106. FUNCTIONAL RELATIONSHIP BETWEEN AMINO ACID RESIDUES AT N- AND C-TERMINI OF DNA-BINDING REGIONS OF TRANSCRIPTION FACTORS CREB AND AP-1 REVEALED BY ANALYZING THE PAIR CORRELATIONS OF AMINO ACID SUBSTITUTIONS<\/a>.
    \nAFONNIKOV D.,\u00a0TITOV I.I.<\/i><\/li>\n
  107. STATISTICAL RELATION BETWEEN THE POSITIONS OF THE ALPHA-HELIX IN THE ZINC-FINGER DNA-BINDING DOMAIN: RESULTS FROM THE PHAGE DISPLAY DATA ANALYSIS<\/a>.
    \nAFONNIKOV D.,\u00a0WINGENDER E.<\/i><\/li>\n
  108. THE BASIC PRINCIPLES OF DNA RECOGNITION BY SEQUENCE DEPENDENT AND INDEPENDENT ENZYMES<\/a>.
    \nNEVINSKY G.A.,\u00a0VINOGRADOVA N.L.,\u00a0BUGREEV D.V.,\u00a0ISHENKO A.A.,\u00a0VASYUTINA E.L.,\u00a0ULYANOVA N.P.,\u00a0ZAKHAROVA O.D.,\u00a0KOLOCHEVA T.A.<\/i><\/li>\n
  109. STRUCTURE-FUNCTIONAL HOMOLOGY OF THE PROKARYOTIC AND EUKARYOTIC RNA POLYMERASES<\/a>.
    \nSAVINKOVA L.K.,\u00a0SOKOLENKO A.A.,\u00a0SEDOVA V.M.,\u00a0RAU V.A.,\u00a0TULOKHONOV I.I,\u00a0KOBZEV V.F.,\u00a0ARSHINOVA T.V.<\/i><\/li>\n
  110. INTERPRETATION OF X-RAY ANALYSIS DATA OF THE HUMAN DNA TOPOISOMERASE I ON THE BASIS OF THE HUMAN DNA TOPOISOMERASE I ON THE BASIS OF THE ENZYME<\/a>.
    \nBUGREEV D.V.,\u00a0VASYUTINA E.L.,\u00a0BUNEVA V.N.,\u00a0NEVINSKY G.A.<\/i><\/li>\n
  111. AUTOMATIC GENERATION OF RECOGNITION PROGRAMS FOR AMINO ACID SEQUENCES<\/a>.
    \nVALUEV V.P.,\u00a0KUROPATOV D.A.,\u00a0PONOMARENKO M.P.<\/i><\/li>\n
  112. THE SEQUENCE PATTERN FOR THE GLYCOSYLPHOSPHATIDYL-ANCHOR POSTTRANSLATIONAL MODIFICATION AND ITS RECOGNITION IN PROPROTEIN SEQUENCES<\/a>.
    \nEISENHABER BIRGIT<\/i><\/li>\n
  113. DISTURBANCES OF GENOM REGULATION AS THE CONSEQUENCE OF THE STRUCTURAL LIKENESS OF HIV-1 ENV PROTEINS AND HUMAN APOLIPOPROTEIN A-I<\/a>.
    \nPANIN L.E.,\u00a0LUKASHEV V.A.,\u00a0GIMAUTDINOVA O.I.<\/i><\/li>\n
  114. ANALYSIS OF TRANSCRIPTIONAL FACTORS IN E. COLI<\/a>.
    \nPEREZ-RUEDA E.,\u00a0VAN HELDEN J.,\u00a0WODAK S.,\u00a0COLLADO-VIDES J.<\/i><\/li>\n
  115. LACTOFERRIN IS A NEW TRANSCRIPTIONAL FACTOR HAVING MANY DIFFERENT UNIQUE BIOLOGICAL FUNCTIONS<\/a>.
    \nKANYSHKOVA T.G.,\u00a0SEMENOV D.V.,\u00a0BUNEVA V.N.,\u00a0NEVINSKY G.A.<\/i><\/li>\n
  116. USE OF BIOINFORMATICS IN DEVELOPMENT OF PEPTIDE VACCINE<\/a>.
    \nKOLASKAR A.S.,\u00a0URMILA KULKARNI-KALE,\u00a0GORE M.M.<\/i><\/li>\n
  117. ANTIGENIC MIMICRY OF HUMAN IMMUNODEFICIENCY VIRUS TYPE 1 AS A RESULT OF STRUCTURAL SIMILARITY OF PROTEIN GP120 AND HUMAN APOLIPOPROTEIN A-1<\/a>.
    \nLUKASHEV V.A.,\u00a0FROLOV A.S.,\u00a0PANIN L.E.,\u00a0GIMAUTDINOVA O.I.<\/i><\/li>\n
  118. THE LEUCINE MOTIF IN SUBUNITS 6 AND 9 OF PLANT MITOCHONDRIAL ATP SYNTHASE PROVIDING PRESUMABLY THE ASSEMBLY OF THE MEMBRANE PART OF THE ENZYME<\/a>.
    \nKONSTANTINOV Yu.M.,\u00a0ARZIEV A.Sh.,\u00a0PODSOSONNY V.A.<\/i><\/p>\n

    BIOINFORMATICS AND EDUCATION<\/h2>\n<\/li>\n
  119. BIOINFORMATICS FOR HUMANITARIANS<\/a>.
    \nPONOMARENKO M.P.,\u00a0ISHCHENKO I.V.,\u00a0FROLOV A.S.,\u00a0PONOMARENKO J.V.,\u00a0KOLCHANOV N.A.,\u00a0MIKHAILOV Yu.I.,\u00a0MININA A.V.,\u00a0IVASHIN S.A.<\/i><\/li>\n
  120. BUSINESS GAME EQUILIBRIUM FOR EDUCATION IN ECONOMICS, COMMERCE, AND LAW<\/a>.
    \nPONOMARENKO M.P.,\u00a0ISHCHENKO I.V.,\u00a0FROLOV A.S.,\u00a0MININA A.V.,\u00a0KONEVA E.I.,\u00a0MIKHAILOV Yu.I.,\u00a0IVASHIN S.A.<\/i><\/li>\n
  121. THE PRACTICAL STUDY OF THE BEHAVIOR OF THE COMPLEX DYNAMIC SYSTEMS ON THE BASIS OF THE LIFE GAME FOR EDUCATION IN ECONOMICS, COMMERCE, AND LAW<\/a>.
    \nAFONNIKOV D.,\u00a0KOLESOV G.B.,\u00a0MININA A.V.,\u00a0MIKHAILOV Yu.I.,\u00a0IVASHIN S.A.<\/i><\/li>\n
  122. BUSINESS GAME HUMAN GENOME FOR EDUCATION IN BUSINESS, LAW AND COMMERCE<\/a>.
    \nPONOMARENKO M.P.,\u00a0FROLOV A.S.,\u00a0PONOMARENKO J.V.,\u00a0MININA A.V.,\u00a0IVASHIN S.A.,\u00a0MIKHAILOV Yu.I.<\/i><\/p>\n

    ABSTRACTS SUBMITTED AFTER THE DEADLINE<\/h2>\n<\/li>\n
  123. THE SEQUENCING AND MOLECULAR ANALYSIS OF COXI GENE FRAGMENTS OF WILD PERENNIAL CROP ELYMUS SIBIRICUS L.<\/a>.
    \nFALSHINA I.V.,\u00a0VERBITSKII D.S.,\u00a0ROGOZIN I.B.,\u00a0KONSTANTINOV Yu.M.,\u00a0TAUSON E.L.<\/i><\/li>\n
  124. NEW METHOD FOR THE STUDY OF THE MODULAR STRUCTURE OF TRANSCRIPTION REGULATORY REGIONS<\/a>.
    \nKOLESOV G.B.,\u00a0KOLPAKOV F.A.,\u00a0KOLCHANOV N.A.<\/i><\/li>\n
  125. MGL: AN OBJECT-ORIENTED COMPUTER SYSTEM FOR MOLECULAR GENETIC DATA MANAGEMENT, ANALYSIS, AND VISUALIZATION<\/a>.
    \nKOLPAKOV F.A.,\u00a0BABENKO V.N.<\/i><\/li>\n
  126. THE EFFICIENCY OF AN APPROXIMATION OF THE LIKELIHOOD BY CUTTING: DEPENDANCE ON A SIZE OF LOOPS IN A PEDIGREE<\/a>.
    \nAULCHENKO Yu.S.,\u00a0AXENOVICH T.I.<\/i><\/li>\n
  127. SIGNIFICANT B-DNA CONFORMATIONAL AND PHYSICO-CHEMICAL PROPERTIES OF THE DNA TOPOISOMERASE I SITES<\/a>.
    \nPONOMARENKO M.P.,\u00a0VOROBIEV D.G.,\u00a0PONOMARENKO J.V.,\u00a0KUZIN F.E.,\u00a0GRUZDEV A.D.,\u00a0KOLCHANOV N.A.<\/i><\/li>\n<\/ol>\n","protected":false},"excerpt":{"rendered":"

    DATABASES ON REGULATORY GENOMIC SEQUENCES AND REGULATORY PROTEINS A PROMOTER DATABASE OF YEAST SACCHAROMYCES CEREVISIAE (SCPD). JIAN ZHU,\u00a0ZHANG MICHAEL Q. DEVELOPMENT OF A RECEPTOR DATABASE. KOTOKO NAKATA,\u00a0TAKAKO TAKAI,\u00a0TSUGUCHIKA KAMINUMA HOX-PRO DB: THE WAYS OF EVOLUTION OF ENSEMBLES OF HOMEOBOX GENES-CONTROLLERS … Continue reading →<\/span><\/a><\/p>\n","protected":false},"author":13,"featured_media":0,"parent":246,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"","meta":[],"_links":{"self":[{"href":"https:\/\/conf.icgbio.ru\/bgrs\/wp-json\/wp\/v2\/pages\/97"}],"collection":[{"href":"https:\/\/conf.icgbio.ru\/bgrs\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/conf.icgbio.ru\/bgrs\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/conf.icgbio.ru\/bgrs\/wp-json\/wp\/v2\/users\/13"}],"replies":[{"embeddable":true,"href":"https:\/\/conf.icgbio.ru\/bgrs\/wp-json\/wp\/v2\/comments?post=97"}],"version-history":[{"count":18,"href":"https:\/\/conf.icgbio.ru\/bgrs\/wp-json\/wp\/v2\/pages\/97\/revisions"}],"predecessor-version":[{"id":245,"href":"https:\/\/conf.icgbio.ru\/bgrs\/wp-json\/wp\/v2\/pages\/97\/revisions\/245"}],"up":[{"embeddable":true,"href":"https:\/\/conf.icgbio.ru\/bgrs\/wp-json\/wp\/v2\/pages\/246"}],"wp:attachment":[{"href":"https:\/\/conf.icgbio.ru\/bgrs\/wp-json\/wp\/v2\/media?parent=97"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}