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Biologia Molecular, revisão do conteúdo
Prof Francisco Prosdocimi
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ÁCIDOS NUCLEICOS DNA, RNA Armazenamento da informação genética
Polímeros de nucleotídeos
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DNA E RNA Polímeros de nucleotídeos
Esqueleto de ribose-fosfato ligado às bases nitrogenadas
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REPLICAÇÃO DO DNA O DNA é composto por uma dupla-hélice
Replicação semi-conservativa: as bases presentes em uma das fitas contém toda a informação necessária para a síntese da nova fita A complementaridade das bases A = T, G = C As duas fitas do DNA são antiparalelas
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EVOLUÇÃO POR MUTAÇÕES A modificação das moléculas de DNA ao longo do tempo (mutação) é um dos principais fatores evolutivos
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DOGMA CENTRAL E TRADUÇÃO
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PROTEÍNAS Moléculas mais importantes? Polímeros de aminoácidos
Apenas 20 diferentes aminoácidos estão presentes nas moléculas biológicas Carboxil Amino
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AMINOÁCIDOS
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LIGANDO AMINOÁCIDOS Onde acontece? Quem atua como catalisador?
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ESTRUTURA DAS PROTEÍNAS
Enovelamento de proteínas
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HIERARQUIA ESTRUTURAL
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ALFABETO QUÍMICO Todos os organismos vivos são constituídos a partir das mesmas unidades monoméricas A estrutura das macromoléculas é o que determina a sua função biológica Cada espécie apresenta um conjunto distinto de macromoléculas
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O Sequenciamento de moléculas de DNA
Prof. Dr. Francisco Prosdocimi >gi| |gb|BC | Homo sapiens hexokinase 1, mRNA (cDNA clone MGC:1724 IMAGE: ), complete cds GGCTGCGGAGGACCGACCGTCCCCACGCCTGCCGCCCCGCGACCCCGACCGCCAGCATGATCGCCGCGCA GCTCCTGGCCTATTACTTCACGGAGCTGAAGGATGACCAGGTCAAAAAGATTGACAAGTATCTGTATGCC ATGCGGCTCTCCGATGAAACTCTCATAGATATCATGACTCGCTTCAGGAAGGAGATGAAGAATGGCCTCT CCCGGGATTTTAATCCAACAGCCACAGTCAAGATGTTGCCAACATTCGTAAGGTCCATTCCTGATGGCTC TGAAAAGGGAGATTTCATTGCCCTGGATCTTGGTGGGTCTTCCTTTCGAATTCTGCGGGTGCAAGTGAAT CATGAGAAAAACCAGAATGTTCACATGGAGTCCGAGGTTTATGACACCCCAGAGAACATCGTGCACGGCA GTGGAAGCCAGCTTTTTGATCATGTTGCTGAGTGCCTGGGAGATTTCATGGAGAAAAGGAAGATCAAGGA CAAGAAGTTACCTGTGGGATTCACGTTTTCTTTTCCTTGCCAACAATCCAAAATAGATGAGGCCATCCTG ATCACCTGGACAAAGCGATTTAAAGCGAGCGGAGTGGAAGGAGCAGATGTGGTCAAACTGCTTAACAAAG(...) TGACAGGCCTTCTGGGCCTCCAAAGCCCATCCTTGGGGTTCCCCCTCCCTGTGTGAAATGTATTATCACC AGCAGACACTGCCGGGCCTCCCTCCCGGGGGCACTGCCTGAAGGCGAGTGTGGGCATAGCATTAGCTGCT TCCTCCCCTCCTGGCACCCACTGTGGCCTGGCATCGCATCGTGGTGTGTCAATGCCACAAAATCGTGTGT CCGTGGAACCAGTCCTAGCCGCGTGTGACAGTCTTGCATTCTGTTTGTCTCGTGGGGGGAGGTGGACAGT CCTGCGGAAATGTGTCTTGTCTCCATTTGGATAAAAGGAACCAACCAACAAACAATGCCATCACTGGAAT TTCCCACCGCTTTGTGAGCCGTGTCGTATGACCTAGTAAACTTTGTACCAATTCAAAAAAAAAAAAAAAAAA
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Bioquímica + Biomol Enzimas são proteínas, portanto:
São formadas por sequências de aminoácidos Derivam de informações dispostas por genes no DNA, que deve ser transcrito e, posteriormente, traduzido Podemos saber a sequência delas, tanto de aminoácidos quanto de nucleotídeos
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>gi| |ref|NM_ | Homo sapiens hexokinase 1 (HK1), nuclear gene encoding mitochondrial protein, transcript variant 1, mRNA GAGGAGGAGCCGCCGAGCAGCCGCCGGAGGACCACGGCTCGCCAGGGCTGCGGAGGACCGACCGTCCCCA CGCCTGCCGCCCCGCGACCCCGACCGCCAGCATGATCGCCGCGCAGCTCCTGGCCTATTACTTCACGGAG CTGAAGGATGACCAGGTCAAAAAGATTGACAAGTATCTCTATGCCATGCGGCTCTCCGATGAAACTCTCA TAGATATCATGACTCGCTTCAGGAAGGAGATGAAGAATGGCCTCTCCCGGGATTTTAATCCAACAGCCAC AGTCAAGATGTTGCCAACATTCGTAAGGTCCATTCCTGATGGCTCTGAAAAGGGAGATTTCATTGCCCTG GATCTTGGTGGGTCTTCCTTTCGAATTCTGCGGGTGCAAGTGAATCATGAGAAAAACCAGAATGTTCACA TGGAGTCCGAGGTTTATGACACCCCAGAGAACATCGTGCACGGCAGTGGAAGCCAGCTTTTTGATCATGT TGCTGAGTGCCTGGGAGATTTCATGGAGAAAAGGAAGATCAAGGACAAGAAGTTACCTGTGGGATTCACG TTTTCTTTTCCTTGCCAACAATCCAAAATAGATGAGGCCATCCTGATCACCTGGACAAAGCGATTTAAAG CGAGCGGAGTGGAAGGAGCAGATGTGGTCAAACTGCTTAACAAAGCCATCAAAAAGCGAGGGGACTATGA TGCCAACATCGTAGCTGTGGTGAATGACACAGTGGGCACCATGATGACCTGTGGCTATGACGACCAGCAC TGTGAAGTCGGCCTGATCATCGGCACTGGCACCAATGCTTGCTACATGGAGGAACTGAGGCACATTGATC TGGTGGAAGGAGACGAGGGGAGGATGTGTATCAATACAGAATGGGGAGCCTTTGGAGACGATGGATCATT AGAAGACATCCGGACAGAGTTTGACAGGGAGATAGACCGGGGATCCCTCAACCCTGGAAAACAGCTGTTT GAGAAGATGGTCAGTGGCATGTACTTGGGAGAGCTGGTTCGACTGATCCTAGTCAAGATGGCCAAGGAGG GCCTCTTATTTGAAGGGCGGATCACCCCGGAGCTGCTCACCCGAGGGAAGTTTAACACCAGTGATGTGTC AGCCATCGAAAAGAATAAGGAAGGCCTCCACAATGCCAAAGAAATCCTGACCCGCCTGGGAGTGGAGCCG TCCGATGATGACTGTGTCTCAGTCCAGCACGTTTGCACCATTGTCTCATTTCGCTCAGCCAACTTGGTGG CTGCCACACTGGGCGCCATCTTGAACCGCCTGCGTGATAACAAGGGCACACCCAGGCTGCGGACCACGGT TGGTGTCGACGGATCTCTTTACAAGACGCACCCACAGTATTCCCGGCGTTTCCACAAGACTCTAAGGCGC TTGGTGCCAGACTCCGATGTGCGCTTCCTCCTCTCGGAGAGTGGCAGCGGCAAGGGGGCTGCCATGGTGA CGGCGGTGGCCTACCGCTTGGCCGAGCAGCACCGGCAGATAGAGGAGACCCTGGCTCATTTCCACCTCAC CAAGGACATGCTGCTGGAGGTGAAGAAGAGGATGCGGGCCGAGATGGAGCTGGGGCTGAGGAAGCAGACG CACAACAATGCCGTGGTTAAGATGCTGCCCTCCTTCGTCCGGAGAACTCCCGACGGGACCGAGAATGGTG ACTTCTTGGCCCTGGATCTTGGAGGAACCAATTTCCGTGTGCTGCTGGTGAAAATCCGTAGTGGGAAAAA GAGAACGGTGGAAATGCACAACAAGATCTACGCCATTCCTATTGAAATCATGCAGGGCACTGGGGAAGAG CTGTTTGATCACATTGTCTCCTGCATCTCTGACTTCTTGGACTACATGGGGATCAAAGGCCCCAGGATGC CTCTGGGCTTCACGTTCTCATTTCCCTGCCAGCAGACGAGTCTGGACGCGGGAATCTTGATCACGTGGAC AAAGGGTTTTAAGGCAACAGACTGCGTGGGCCACGATGTAGTCACCTTACTAAGGGATGCGATAAAAAGG AGAGAGGAATTTGACCTGGACGTGGTGGCTGTGGTCAACGACACAGTGGGCACCATGATGACCTGTGCTT ATGAGGAGCCCACCTGTGAGGTTGGACTCATTGTTGGGACCGGCAGCAATGCCTGCTACATGGAGGAGAT GAAGAACGTGGAGATGGTGGAGGGGGACCAGGGGCAGATGTGCATCAACATGGAGTGGGGGGCCTTTGGG GACAACGGGTGTCTGGATGATATCAGGACACACTACGACAGACTGGTGGACGAATATTCCCTAAATGCTG GGAAACAAAGGTATGAGAAGATGATCAGTGGTATGTACCTGGGTGAAATCGTCCGCAACATCTTAATCGA CTTCACCAAGAAGGGATTCCTCTTCCGAGGGCAGATCTCTGAGACGCTGAAGACCCGGGGCATCTTTGAG ACCAAGTTTCTCTCTCAGATCGAGAGTGACCGATTAGCACTGCTCCAGGTCCGGGCTATCCTCCAGCAGC TAGGTCTGAATAGCACCTGCGATGACAGTATCCTCGTCAAGACAGTGTGCGGGGTGGTGTCCAGGAGGGC CGCACAGCTGTGTGGCGCAGGCATGGCTGCGGTTGTGGATAAGATCCGCGAGAACAGAGGACTGGACCGT CTGAATGTGACTGTGGGAGTGGACGGGACACTCTACAAGCTTCATCCACACTTCTCCAGAATCATGCACC AGACGGTGAAGGAACTGTCACCAAAATGTAACGTGTCCTTCCTCCTGTCTGAGGATGGCAGCGGCAAGGG GGCCGCCCTCATCACGGCCGTGGGCGTGCGGTTACGCACAGAGGCAAGCAGCTAAGAGTCCGGGATCCCC AGCCTACTGCCTCTCCAGCACTTCTCTCTTCAAGCGGCGACCCCCTACCCTCCCAGCGAGTTGCGCTGGG AGACGCTGGCGCCAGGGCCTGCCGGCGCGGGGAGGAAAGCAAAATCCAACTAATGGTATATATTGTAGGG TACAGAATAGAGCGTGTGCTGTTGATAATATCTCTCACCCGGATCCCTCCTCACTTGCCCTGCCACTTTG CATGGTTTGATTTTGACCTGGTCCCCCACGTGTGAAGTGTAGTGGCATCCATTTCTAATGTATGCATTCA TCCAACAGAGTTATTTATTGGCTGGAGATGGAAAATCACACCACCTGACAGGCCTTCTGGGCCTCCAAAG CCCATCCTTGGGGTTCCCCCTCCCTGTGTGAAATGTATTATCACCAGCAGACACTGCCGGGCCTCCCTCC CGGGGGCACTGCCTGAAGGCGAGTGTGGGCATAGCATTAGCTGCTTCCTCCCCTCCTGGCACCCACTGTG GCCTGGCATCGCATCGTGGTGTGTCAATGCCACAAAATCGTGTGTCCGTGGAACCAGTCCTAGCCGCGTG TGACAGTCTTGCATTCTGTTTGTCTCGTGGGGGGAGGTGGACAGTCCTGCGGAAATGTGTCTTGTCTCCA TTTGGATAAAAGGAACCAACCAACAAACAATGCCATCACTGGAATTTCCCACCGCTTTGTGAGCCGTGTC GTATGACCTAGTAAACTTTGTACCAATTCAAAAAAAAAAAAAAAAAA >gi| |ref|NP_ | hexokinase 1 isoform HKI [Homo sapiens] MIAAQLLAYYFTELKDDQVKKIDKYLYAMRLSDETLIDIMTRFRKEMKNGLSRDFNPTATVKMLPTFVRS IPDGSEKGDFIALDLGGSSFRILRVQVNHEKNQNVHMESEVYDTPENIVHGSGSQLFDHVAECLGDFMEK RKIKDKKLPVGFTFSFPCQQSKIDEAILITWTKRFKASGVEGADVVKLLNKAIKKRGDYDANIVAVVNDT VGTMMTCGYDDQHCEVGLIIGTGTNACYMEELRHIDLVEGDEGRMCINTEWGAFGDDGSLEDIRTEFDRE IDRGSLNPGKQLFEKMVSGMYLGELVRLILVKMAKEGLLFEGRITPELLTRGKFNTSDVSAIEKNKEGLH NAKEILTRLGVEPSDDDCVSVQHVCTIVSFRSANLVAATLGAILNRLRDNKGTPRLRTTVGVDGSLYKTH PQYSRRFHKTLRRLVPDSDVRFLLSESGSGKGAAMVTAVAYRLAEQHRQIEETLAHFHLTKDMLLEVKKR MRAEMELGLRKQTHNNAVVKMLPSFVRRTPDGTENGDFLALDLGGTNFRVLLVKIRSGKKRTVEMHNKIY AIPIEIMQGTGEELFDHIVSCISDFLDYMGIKGPRMPLGFTFSFPCQQTSLDAGILITWTKGFKATDCVG HDVVTLLRDAIKRREEFDLDVVAVVNDTVGTMMTCAYEEPTCEVGLIVGTGSNACYMEEMKNVEMVEGDQ GQMCINMEWGAFGDNGCLDDIRTHYDRLVDEYSLNAGKQRYEKMISGMYLGEIVRNILIDFTKKGFLFRG QISETLKTRGIFETKFLSQIESDRLALLQVRAILQQLGLNSTCDDSILVKTVCGVVSRRAAQLCGAGMAA VVDKIRENRGLDRLNVTVGVDGTLYKLHPHFSRIMHQTVKELSPKCNVSFLLSEDGSGKGAALITAVGVR LRTEASS 917 aminoácidos 917 x 3 = 2751 = 866 3617 bp 3,6 kb
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O método de Sanger, 1975 Polimerização do DNA a ser sequenciado (molde) na presença de: DNA polimerase primer tampão dNTPs (desóxinucleotídeo) ddNTPs (didesóxinucleotídeo) O que faria um nucleotídeo que, ao invés da extremidade 3’OH, tem uma extremidade 3’H? Como acontece a síntese de moléculas de DNA? (dideóxi)
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TACGAAGACCGTCTAGACTTGTCACAATGACTATAACGAA
ATGCTTC 5’ 3’ ||||||| TACGAAGACCGTCTAGACTTGTCACAATGACTATAACGAA 3’ 5’
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TACGAAGACCGTCTAGACTTGTCACAATGACTATAACGAA
ATGCTTC 5’ 3’ G A ||||||||| TACGAAGACCGTCTAGACTTGTCACAATGACTATAACGAA 3’ 5’
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TACGAAGACCGTCTAGACTTGTCACAATGACTATAACGAA
ATGCTTCTG 5’ 3’ G A |||||||||| TACGAAGACCGTCTAGACTTGTCACAATGACTATAACGAA 3’
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TACGAAGACCGTCTAGACTTGTCACAATGACTATAACGAA
ATGCTTCTGGCAGATCT 5’ 3’ ||||||||||||||||| TACGAAGACCGTCTAGACTTGTCACAATGACTATAACGAA 3’ 5’
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TACGAAGACCGTCTAGACTTGTCACAATGACTATAACGAA
ATGCTTCTGGCAGAT 5’ 3’ ||||||||||||||| TACGAAGACCGTCTAGACTTGTCACAATGACTATAACGAA 3’ 5’
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TACGAAGACCGTCTAGACTTGTCACAATGACTATAACGAA
ATGCTTCTGGCAGAT 5’ 3’ ||||||||||||||| TACGAAGACCGTCTAGACTTGTCACAATGACTATAACGAA 3’ 5’
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TACGAAGACCGTCTAGACTTGTCACAATGACTATAACGAA
ATGCTTCTGGCAGAT 5’ 3’ ||||||||||||||| TACGAAGACCGTCTAGACTTGTCACAATGACTATAACGAA 3’ 5’
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ATGCTTCTGGCAGATCTGAACAGTGTTACTGAT ATGCTTCTGGCAGATCTGAACAGTGT
5’ 3’ ATGCTTCTGGCAGATCTGAACAGTGT ATGCTTCTGGCAGATCTGAACAGTGTTACTGATATTGCTT ATGCTTCTGGCAGATCTGAACAGTGTTACTGATAT ATGCTTCTGGCAGATCTGAACAGTGTTACT ATGCTTCTGGCAGATCTGAACAGT ATGCTTCTGGCAGATCTGAACAGTGTTACTGATATTGCT ATGCTTCTGGCAGATCTGAACAGTGTTACTGATATT ATGCTTCT ATGCTTCTGGCAGATCT População de moléculas Incorporação aleatória do didesóxi Quantidade precisa entre didesóxi e desóxi TACGAAGACCGTCTAGACTTGTCACAATGACTATAACGAA |||||||||||||||||||||||||||||||||||||||| 5’ 3’ ATGCTTCTGGCAGAT ATGCTTCTGGCAGATCTGAACAGTGTTACTGATATTGCTT ATGCTTCTGGCAGATCTGAACAGTGTT
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ATGCTTCTGGCAGAT ATGCTTCTGGCAGATCTGAACAGTGTTACTGAT ATGCTTCTGGCAGATCTGAACAGTGT ATGCTTCTGGCAGATCTGAACAGTGTTACTGATATTGCTT ATGCTTCTGGCAGATCTGAACAGTGTTACTGATAT ATGCTTCTGGCAGATCTGAACAGTGTTACT ATGCTTCTGGCAGATCTGAACAGT ATGCTTCTGGCAGATCTGAACAGTGTTACTGATATTGCT ATGCTTCTGGCAGATCTGAACAGTGTTACTGATATT ATGCTTCT ATGCTTCTGGCAGATCT ATGCTTCTGGCAGATCTGAACAGTGTT
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molde polimerase dNTPs ddGTPs ddATPs ddTTPs ddCTPs G A T C
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G A T C ATGCTTCT ATGCTTCTG ATGCTTCTGG ATGCTTCTGGC ATGCTTCTGGCA
ATGCTTCTGGCAGAT ATGCTTCTGGCAGATCTGAACAGTGTTACTGAT ATGCTTCTGGCAGATCTGAACAGTGT ATGCTTCTGGCAGATCTGAACAGTGTTACTGATATTGCTT ATGCTTCTGGCAGATCTGAACAGTGTTACTGATAT ATGCTTCTGGCAGATCTGAACAGTGTTACT ATGCTTCTGGCAGATCTGAACAGT ATGCTTCTGGCAGATCTGAACAGTGTTACTGATATTGCT ATGCTTCTGGCAGATCTGAACAGTGTTACTGATATT ATGCTTCT ATGCTTCTGGCAGATCT ATGCTTCTGGCAGATCTGAACAGTGTT ATGCTTCTG ATGCTTCTGG ATGCTTCTGGCAG ATGCTTCTGGCAGATCTG ATGCTTCTGGCAGATCTGAACAG ATGCTTCTGGCAGATCTGAACAGTG ATGCTTCTGGCAGATCTGAACAGTGTTACTG ATGCTTCTGGCAGATCTGAACAGTGTTACTGATATTG ATGCTTCTGGC ATGCTTCTGGCAGATC ATGCTTCTGGCAGATCTGAAC ATGCTTCTGGCAGATCTGAACAGTGTTAC ATGCTTCTGGCAGATCTGAACAGTGTTACTGATATTGC ATGCTTCTGGCA ATGCTTCTGGCAGA ATGCTTCTGGCAGATCTGA ATGCTTCTGGCAGATCTGAA ATGCTTCTGGCAGATCTGAACA ATGCTTCTGGCAGATCTGAACAGTGTTA ATGCTTCTGGCAGATCTGAACAGTGTTACTGA ATGCTTCTGGCAGATCTGAACAGTGTTACTGATA G A T C
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ATGCTTCTGGCAGAT ATGCTTCTGGCAGATCTGAACAGTGTTACTGAT ATGCTTCTGGCAGATCTGAACAGTGT ATGCTTCTGGCAGATCTGAACAGTGTTACTGATATTGCTT ATGCTTCTGGCAGATCTGAACAGTGTTACTGATAT ATGCTTCTGGCAGATCTGAACAGTGTTACT ATGCTTCTGGCAGATCTGAACAGT ATGCTTCTGGCAGATCTGAACAGTGTTACTGATATTGCT ATGCTTCTGGCAGATCTGAACAGTGTTACTGATATT ATGCTTCT ATGCTTCTGGCAGATCT ATGCTTCTGGCAGATCTGAACAGTGTT ATGCTTCTG ATGCTTCTGG ATGCTTCTGGCAG ATGCTTCTGGCAGATCTG ATGCTTCTGGCAGATCTGAACAG ATGCTTCTGGCAGATCTGAACAGTG ATGCTTCTGGCAGATCTGAACAGTGTTACTG ATGCTTCTGGCAGATCTGAACAGTGTTACTGATATTG ATGCTTCTGGC ATGCTTCTGGCAGATC ATGCTTCTGGCAGATCTGAAC ATGCTTCTGGCAGATCTGAACAGTGTTAC ATGCTTCTGGCAGATCTGAACAGTGTTACTGATATTGC ATGCTTCTGGCA ATGCTTCTGGCAGA ATGCTTCTGGCAGATCTGA ATGCTTCTGGCAGATCTGAA ATGCTTCTGGCAGATCTGAACA ATGCTTCTGGCAGATCTGAACAGTGTTA ATGCTTCTGGCAGATCTGAACAGTGTTACTGA ATGCTTCTGGCAGATCTGAACAGTGTTACTGATA
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As máquinas necessárias para o sequenciamento
Primeira etapa: junta-se os reagentes em poços de placas e coloca-se na máquina de PCR para a reação de amplificação interrompida Diferenças com relação ao PCR Utilização de um só primer Utilização dos ddNTPs Uma vez prontas, as sequências de diferentes tamanhos contendo os didesóxi amplificados devem ser enviadas ao sequenciador de DNA mais próximo
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O que faz um sequenciador de DNA?
Segunda etapa: realiza a eletroforese capilar O sequenciador executa a eletroforese em géis capilares ultra-finos Um sensor é responsável por emitir um laser e verificar qual o comprimento de onda emitido pelo didesóxi
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A produção de bibliotecas de DNA e cDNA
Projetos Genoma e Transcriptoma A produção de bibliotecas de DNA e cDNA Prof. Dr. Francisco Prosdocimi
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O que é um genoma? Por que haplóide?
Conjunto haplóide de informações presentes no DNA de determinado organismo Genomas bacterianos X Genomas eucarióticos Cromossomos são formados por uma única molécula de DNA Genoma humano: 22 pares de cromossomos autossomos + X + Y O problema da variação – SNPs Estudos genômicos e o método científico A era da pesquisa científica sem hipótese Por que haplóide?
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Biblioteca de DNA e cDNA
Fragmentação Inserção em vetores Transformação mRNA Síntese de cDNA Inserção em vetores Transformação
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Biblioteca transcriptômica
Ou biblioteca de cDNA, DNA complementar Purificação dos mRNAs Oligos dT Retrotranscrição Clonagem
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Análises genômicas e transcriptômicas
Genoma: muito utilizado para produzir sequências completas do DNA de bactérias e vírus, que apresentam genoma compacto Assim é possível saber se o organismo tem as vias bioquímicas completas e como ele deve se alimentar Transcriptoma: classicamente utilizado em estudos de células cancerosas, onde a diferença na expressão dos genes deve mostrar porque a célula é tumoral Comparação entre a expressão gênica em uma célula normal e o tumor Comparações quaisquer entre dois estados celulares
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Expressão gênica
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Bioinformática, formatos de arquivo
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O formato FASTA Fast Alignment: programa de alinhamento da década de 80 Arquivo texto FASTA e multi-FASTA >gi| |ref|NM_ | Homo sapiens hexokinase 1 (HK1), nuclear gene encoding mitochondrial protein, transcript variant 1, mRNA GAGGAGGAGCCGCCGAGCAGCCGCCGGAGGACCACGGCTCGCCAGGGCTGCGGAGGACCGACCGTCCCCA CGCCTGCCGCCCCGCGACCCCGACCGCCAGCATGATCGCCGCGCAGCTCCTGGCCTATTACTTCACGGAG CTGAAGGATGACCAGGTCAAAAAGATTGACAAGTATCTCTATGCCATGCGGCTCTCCGATGAAACTCTCA TAGATATCATGACTCGCTTCAGGAAGGAGATGAAGAATGGCCTCTCCCGGGATTTTAATCCAACAGCCAC AGTCAAGATGTTGCCAACATTCGTAAGGTCCATTCCTGATGGCTCTGAAAAGGGAGATTTCATTGCCCTG GATCTTGGTGGGTCTTCCTTTCGAATTCTGCGGGTGCAAGTGAATCATGAGAAAAACCAGAATGTTCACA TGGAGTCCGAGGTTTATGACACCCCAGAGAACATCGTGCACGGCAGTGGAAGCCAGCTTTTTGATCATGT TGCTGAGTGCCTGGGAGATTTCATGGAGAAAAGGAAGATCAAGGACAAGAAGTTACCTGTGGGATTCACG TTTTCTTTTCCTTGCCAACAATCCAAAATAGATGAGGCCATCCTGATCACCTGGACAAAGCGATTTAAAG CGAGCGGAGTGGAAGGAGCAGATGTGGTCAAACTGCTTAACAAAGCCATCAAAAAGCGAGGGGACTATGA TGCCAACATCGTAGCTGTGGTGAATGACACAGTGGGCACCATGATGACCTGTGGCTATGACGACCAGCAC TGTGAAGTCGGCCTGATCATCGGCACTGGCACCAATGCTTGCTACATGGAGGAACTGAGGCACATTGATC TGGTGGAAGGAGACGAGGGGAGGATGTGTATCAATACAGAATGGGGAGCCTTTGGAGACGATGGATCATT >gi| |ref|NM_ | Homo sapiens hexokinase 1 (HK1), nuclear gene encoding mitochondrial protein, transcript variant 1, mRNA CAAGGACATGCTGCTGGAGGTGAAGAAGAGGATGCGGGCCGAGATGGAGCTGGGGCTGAGGAAGCAGACG CACAACAATGCCGTGGTTAAGATGCTGCCCTCCTTCGTCCGGAGAACTCCCGACGGGACCGAGAATGGTG ACTTCTTGGCCCTGGATCTTGGAGGAACCAATTTCCGTGTGCTGCTGGTGAAAATCCGTAGTGGGAAAAA GAGAACGGTGGAAATGCACAACAAGATCTACGCCATTCCTATTGAAATCATGCAGGGCACTGGGGAAGAG CTGTTTGATCACATTGTCTCCTGCATCTCTGACTTCTTGGACTACATGGGGATCAAAGGCCCCAGGATGC CTCTGGGCTTCACGTTCTCATTTCCCTGCCAGCAGACGAGTCTGGACGCGGGAATCTTGATCACGTGGAC AAAGGGTTTTAAGGCAACAGACTGCGTGGGCCACGATGTAGTCACCTTACTAAGGGATGCGATAAAAAGG AGAGAGGAATTTGACCTGGACGTGGTGGCTGTGGTCAACGACACAGTGGGCACCATGATGACCTGTGCTT >gi| |ref|NP_ | hexokinase 1 isoform HKI [Homo sapiens] MIAAQLLAYYFTELKDDQVKKIDKYLYAMRLSDETLIDIMTRFRKEMKNGLSRDFNPTATVKMLPTFVRS IPDGSEKGDFIALDLGGSSFRILRVQVNHEKNQNVHMESEVYDTPENIVHGSGSQLFDHVAECLGDFMEK RKIKDKKLPVGFTFSFPCQQSKIDEAILITWTKRFKASGVEGADVVKLLNKAIKKRGDYDANIVAVVNDT VGTMMTCGYDDQHCEVGLIIGTGTNACYMEELRHIDLVEGDEGRMCINTEWGAFGDDGSLEDIRTEFDRE IDRGSLNPGKQLFEKMVSGMYLGELVRLILVKMAKEGLLFEGRITPELLTRGKFNTSDVSAIEKNKEGLH NAKEILTRLGVEPSDDDCVSVQHVCTIVSFRSANLVAATLGAILNRLRDNKGTPRLRTTVGVDGSLYKTH PQYSRRFHKTLRRLVPDSDVRFLLSESGSGKGAAMVTAVAYRLAEQHRQIEETLAHFHLTKDMLLEVKKR MRAEMELGLRKQTHNNAVVKMLPSFVRRTPDGTENGDFLALDLGGTNFRVLLVKIRSGKKRTVEMHNKIY AIPIEIMQGTGEELFDHIVSCISDFLDYMGIKGPRMPLGFTFSFPCQQTSLDAGILITWTKGFKATDCVG HDVVTLLRDAIKRREEFDLDVVAVVNDTVGTMMTCAYEEPTCEVGLIVGTGSNACYMEEMKNVEMVEGDQ GQMCINMEWGAFGDNGCLDDIRTHYDRLVDEYSLNAGKQRYEKMISGMYLGEIVRNILIDFTKKGFLFRG QISETLKTRGIFETKFLSQIESDRLALLQVRAILQQLGLNSTCDDSILVKTVCGVVSRRAAQLCGAGMAA VVDKIRENRGLDRLNVTVGVDGTLYKLHPHFSRIMHQTVKELSPKCNVSFLLSEDGSGKGAALITAVGVR LRTEASS
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O formato GenBank Comandos LINUX
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