<?xml version="1.0" encoding="ISO-8859-1"?><article xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance">
<front>
<journal-meta>
<journal-id>1646-107X</journal-id>
<journal-title><![CDATA[Motricidade]]></journal-title>
<abbrev-journal-title><![CDATA[Motri.]]></abbrev-journal-title>
<issn>1646-107X</issn>
<publisher>
<publisher-name><![CDATA[Edições Desafio Singular]]></publisher-name>
</publisher>
</journal-meta>
<article-meta>
<article-id>S1646-107X2017000100010</article-id>
<title-group>
<article-title xml:lang="pt"><![CDATA[Imunometabolismo e Exercício Físico: Uma nova fronteira do conhecimento]]></article-title>
<article-title xml:lang="en"><![CDATA[Immunometabolism and Exercise: New avenues]]></article-title>
</title-group>
<contrib-group>
<contrib contrib-type="author">
<name>
<surname><![CDATA[Antunes]]></surname>
<given-names><![CDATA[Barbara de Moura]]></given-names>
</name>
<xref ref-type="aff" rid="A01"/>
</contrib>
<contrib contrib-type="author">
<name>
<surname><![CDATA[Rossi]]></surname>
<given-names><![CDATA[Fabrício Eduardo]]></given-names>
</name>
<xref ref-type="aff" rid="A01"/>
</contrib>
<contrib contrib-type="author">
<name>
<surname><![CDATA[Inoue]]></surname>
<given-names><![CDATA[Daniela Sayuri]]></given-names>
</name>
<xref ref-type="aff" rid="A01"/>
</contrib>
<contrib contrib-type="author">
<name>
<surname><![CDATA[Neto]]></surname>
<given-names><![CDATA[José Cesar Rosa]]></given-names>
</name>
<xref ref-type="aff" rid="A02"/>
</contrib>
<contrib contrib-type="author">
<name>
<surname><![CDATA[Lira]]></surname>
<given-names><![CDATA[Fábio Santos]]></given-names>
</name>
<xref ref-type="aff" rid="A01"/>
</contrib>
</contrib-group>
<aff id="A01">
<institution><![CDATA[,Universidade Estadual Paulista Faculdade de Ciências e Tecnologia Departamento de Educação física]]></institution>
<addr-line><![CDATA[São Paulo ]]></addr-line>
<country>Brasil</country>
</aff>
<aff id="A02">
<institution><![CDATA[,Universidade de São Paulo Instituto de Ciências Biomédicas Departamento de Biologia Celular e do Desenvolvimento]]></institution>
<addr-line><![CDATA[São Paulo SP]]></addr-line>
<country>Brasil</country>
</aff>
<pub-date pub-type="pub">
<day>00</day>
<month>03</month>
<year>2017</year>
</pub-date>
<pub-date pub-type="epub">
<day>00</day>
<month>03</month>
<year>2017</year>
</pub-date>
<volume>13</volume>
<numero>1</numero>
<fpage>85</fpage>
<lpage>98</lpage>
<copyright-statement/>
<copyright-year/>
<self-uri xlink:href="http://scielo.pt/scielo.php?script=sci_arttext&amp;pid=S1646-107X2017000100010&amp;lng=en&amp;nrm=iso"></self-uri><self-uri xlink:href="http://scielo.pt/scielo.php?script=sci_abstract&amp;pid=S1646-107X2017000100010&amp;lng=en&amp;nrm=iso"></self-uri><self-uri xlink:href="http://scielo.pt/scielo.php?script=sci_pdf&amp;pid=S1646-107X2017000100010&amp;lng=en&amp;nrm=iso"></self-uri><abstract abstract-type="short" xml:lang="pt"><p><![CDATA[Sistema imunológico e metabolismo celular interagem constantemente por meio de proteínas imuno-moduladoras, denominadas citocinas, a fim de manter a dinâmica e a comunicação entre os sistemas sendo, na atualidade, amplamente difundido nas diversas áreas do conhecimento, principalmente no campo da saúde, como Imunometabolismo. As principais doenças do século 21 caracterizam-se por apresentar processos inflamatórios bem definidos os quais favorecem o agravamento da doença e a instalação de co-morbidades associadas à alteração metabólica. Em linhas gerais, a resposta inflamatória está associada a dieta inadequada e sedentarismo, alterando a dinâmica metabólica entre citocinas, ácidos graxos e endotoxina e ativando, assim, fatores de transcrição gênica, como o NF-kB. Por outro lado, a prática regular de exercício físico é amplamente recomendada como potente ferramenta na prevenção e tratamento de distúrbios metabólicos em virtude de seu poder anti-inflamatório e anti-aterogênico por meio da produção de miocinas advindas do músculo-esquelético e com atuação anti-inflamatória, como a IL-6, provenientes dos estímulos gerados pela contração muscular, e ativação de proteínas e fatores de transcrição gênica, como o PPAR. Desta forma, o objetivo da presente revisão é contextualizar e difundir os principais conceitos de uma emergente área do conhecimento, o Imunometabolismo, caracterizando sua função e atuação nos campos da doença e da saúde por meio da prática do exercício físico.]]></p></abstract>
<abstract abstract-type="short" xml:lang="en"><p><![CDATA[Immune system and cell metabolism have been interacted constantly, by synthesis and release of immunomodulatory proteins, recognized as cytokines, in order to maintain the body homeostasis. The “crosstalk” between systems has been widely spread in several areas of knowledge, mainly in the health field, as Immunometabolism. Diseases of the 21st century, which affect world populations, are characterized by inflammatory processes favoring the worsening of the illness itself and the installation of other co-morbidities. In general, the inflammatory response is associated with poor diet and physical inactivity, which modify the metabolic dynamics among cytokines, fatty acids and endotoxin culminating in reaction cascades, activating gene transcription factors, such as NF-kB. Furthermore, regular physical exercise is widely recommended as a powerful tool at the prevention and treatment of several metabolic diseases in virtue of anti-inflammatory and anti-atherogenic capacity, through anti-inflammatory myokine production, such as IL-6, from the stimuli generated by muscle contraction and proteins and gene transcription factors activation, as PPAR, which increase the anti-inflammatory response. Thus, the purpose of this review is to contextualize and disseminate knowledge about an emerging area, the Immunometabolism, featuring its function and performance in the illness and health fields by physical exercise.]]></p></abstract>
<kwd-group>
<kwd lng="pt"><![CDATA[Inflamação]]></kwd>
<kwd lng="pt"><![CDATA[Metabolismo]]></kwd>
<kwd lng="pt"><![CDATA[Imunometabolismo]]></kwd>
<kwd lng="pt"><![CDATA[Citocinas]]></kwd>
<kwd lng="pt"><![CDATA[Exercício Físico]]></kwd>
<kwd lng="en"><![CDATA[Inflammation]]></kwd>
<kwd lng="en"><![CDATA[Metabolism]]></kwd>
<kwd lng="en"><![CDATA[Immunometabolism]]></kwd>
<kwd lng="en"><![CDATA[Cytokines]]></kwd>
<kwd lng="en"><![CDATA[Physical activity]]></kwd>
</kwd-group>
</article-meta>
</front><body><![CDATA[ <p align="right"><b><font size="2" face="Verdana">ARTIGO DE REVIS&Atilde;O</font></b></p>  <font face="Verdana" size="2">    <p>&nbsp;</p> </font>     <p><font size="4" face="Verdana"><b>Imunometabolismo   e Exercício Físico: Uma nova fronteira do conhecimento</b></font></p> <font face="Verdana" size="2">     <p>&nbsp;</p> </font>     <p><font size="3" face="Verdana"><b>Immunometabolism   and Exercise: New avenues</b></font></p> <font face="Verdana" size="2">     <p>&nbsp;</p>     <p>&nbsp;</p>     <p><b>Barbara de Moura Antunes<sup>1,</sup><a href="#end"><sup>*</sup></a><a name="topo"></a>; Fabrício Eduardo Rossi<sup>1</sup>; Daniela Sayuri Inoue<sup>1</sup>; José Cesar Rosa Neto<sup>2</sup>; Fábio Santos Lira<sup>1</sup></b></p>     <p><sup>1</sup> <i>Grupo de   ImunoMetabolismo e Exercício, Departamento de Educação física, Universidade   Estadual Paulista, UNESP, Faculdade de Ciências e Tecnologia, Campus de Presidente Prudente, São Paulo, Brasil    <br> </i><i><sup>2</sup> Laboratório de ImunoMetabolismo,   Departamento de Biologia Celular e do Desenvolvimento, Instituto de Ciências Biomédicas, Universidade de São Paulo, USP, São Paulo, SP, Brasil </i></p>     ]]></body>
<body><![CDATA[<p>&nbsp;</p>     <p>&nbsp;</p> </font> <hr noshade size="1"> <font face="Verdana" size="2">     <p><b>RESUMO</b></p>     <p>Sistema   imunológico e metabolismo celular interagem constantemente por meio de   proteínas imuno-moduladoras, denominadas citocinas, a fim de manter a dinâmica   e a comunicação entre os sistemas sendo, na atualidade, amplamente   difundido nas diversas áreas do conhecimento, principalmente no campo da saúde,   como Imunometabolismo. As principais doenças do século 21 caracterizam-se por   apresentar processos inflamatórios bem definidos os quais favorecem o   agravamento da doença e a instalação de co-morbidades associadas à alteração   metabólica. Em linhas gerais, a resposta inflamatória está associada a dieta   inadequada e sedentarismo, alterando a dinâmica metabólica entre citocinas,   ácidos graxos e endotoxina e ativando, assim, fatores de transcrição gênica,   como o NF-kB. Por outro lado, a prática regular de exercício físico é   amplamente recomendada como potente ferramenta na prevenção e tratamento de   distúrbios metabólicos em virtude de seu poder anti-inflamatório e   anti-aterogênico por meio da produção de miocinas advindas do   músculo-esquelético e com atuação anti-inflamatória, como a IL-6, provenientes   dos estímulos gerados pela contração muscular, e ativação de proteínas e   fatores de transcrição gênica, como o PPAR. Desta forma, o objetivo da presente   revisão é contextualizar e difundir os principais conceitos de uma emergente   área do conhecimento, o Imunometabolismo, caracterizando sua função e atuação nos campos da doença e da saúde por meio da prática do exercício físico.</p>     <p><b>Palavras-chave:</b> Inflamação, Metabolismo, Imunometabolismo, Citocinas, Exercício Físico</p> </font> <hr noshade size="1"> <font face="Verdana" size="2">     <p><b>ABSTRACT</b></p>     <p>Immune system and   cell metabolism have been interacted constantly, by synthesis and release of   immunomodulatory proteins, recognized as cytokines, in order to maintain the   body homeostasis. The “<i>crosstalk</i>” between systems has been widely spread   in several areas of knowledge, mainly in the health field, as Immunometabolism.   Diseases of the 21<sup>st</sup> century, which affect world populations, are   characterized by inflammatory processes favoring the worsening of the illness   itself and the installation of other co-morbidities. In general, the inflammatory   response is associated with poor diet and physical inactivity, which modify the   metabolic dynamics among cytokines, fatty acids and endotoxin culminating in   reaction cascades, activating gene transcription factors, such as NF-kB.   Furthermore, regular physical exercise is widely recommended as a powerful tool   at the prevention and treatment of several metabolic diseases in virtue of   anti-inflammatory and anti-atherogenic capacity, through anti-inflammatory   myokine production, such as IL-6, from the stimuli generated by muscle   contraction and proteins and gene transcription factors activation, as PPAR,   which increase the anti-inflammatory response. Thus, the purpose of this review   is to contextualize and disseminate knowledge about an emerging area, the   Immunometabolism, featuring its function and performance in the illness and health fields by physical exercise.</p>     <p><b>Keywords: </b>Inflammation, Metabolism, Immunometabolism, Cytokines, Physical activity</p> </font> <hr noshade size="1"> <font face="Verdana" size="2">     <p>&nbsp;</p>     <p>&nbsp;</p> </font>     ]]></body>
<body><![CDATA[<p><font size="3" face="Verdana"><b>INTRODU&Ccedil;&Atilde;O</b></font></p> <font face="Verdana" size="2">     <p>O comportamento sedentário e os maus hábitos alimentares estão   associados com o desenvolvimento da inflamação crônica de baixo grau, a qual é   um processo metabólico característico de diversas doenças crônicas   degenerativas e/ou não transmissíveis (DCNTs), como obesidade (Ghigliotti et   al., 2014), resistência insulínica e diabetes <i>mellitus</i> tipo 2 (Chen,   Chen, Wang, &amp; Liang, 2015), dislipidemias (Antunes et al., 2015), câncer   (Seelaender, Batista, Lira, Silverio, &amp; Rossi-Fanelli, 2012), aterosclerose   (Husain, Hernandez, Ansai, &amp; Ferder, 2015), entre outras, que modifica   drasticamente o funcionamento das células imunológicas bem como o metabolismo energético do organismo. </p>     <p>Clinicamente, o quadro inflamatório relacionado com as DCNTs está   associado com elevada síntese e liberação de marcadores pró-inflamatórios, como   proteína C-reativa, fator de necrose tumoral-alfa (TNF-&#945;) e interleucinas   (IL-6, IL-1&#946;) (Lira, Neto, &amp; Seelaender, 2014),   simultaneamente à diminuição nas concentrações circulantes de marcadores   anti-inflamatórios como adiponectina, interleucina 10 (IL-10) e recetor antagonista da interleucinas (IL-1ra) (Ohashi, Shibata, Murohara, &amp; Ouchi, 2014).</p>     <p>O comportamento sedentário é apontado como fator determinante para a   instalação e desenvolvimento das doenças supracitadas e, frente ao exposto, há   um consenso na área da saúde de que a prática regular de exercício físico   possui efeitos protetivos à saúde por sua capacidade indutiva de efeitos   anti-inflamatórios e anti-aterogênicos por prevenir ou diminuir o risco à   formação de ateromas nas paredes arteriais (Nimmo, 2013; Petersen, 2005). Os   benefícios do exercício físico estão diretamente associados com a produção de   miocinas (Pedersen, 2011; Pedersen, 2012), advindas da contração muscular, que   atuam de maneira autócrina e parácrina (Atuação autócrina=Sinalização celular   na qual um fator liberado atua a função da própria célula produtora; Atuação   parácrina= Sinalização celular na qual um fator liberado pela célula secretora   atua em outras estruturas do mesmo ambiente local), bem como potencializam a   síntese e liberação de outros marcadores anti-inflamatórios como a IL-10 e   IL-1ra (Steensberg, Fischer, Keller, Møller, &amp; Pedersen, 2003).     </p>     <p>No âmbito da saúde ou da doença é evidente a constante e direta   interação entre células imunológicas, marcadores inflamatórios e metabolismo,   originando uma emergente área de investigação denominada de Imunometabolismo, e   frente a este panorama o objetivo desta revisão é contextualizar, mediante a   busca e utilização principais estudos indexados em bases de dados nacionais e   internacionais, e difundir os conhecimentos sobre a área de Imunometabolismo   caracterizando sua função e atuação no campo da doença e saúde por meio da prática do exercício físico.</p>     <p><b>Imunometabolismo: da origem a atualidade </b></p>     <p>A saúde do organismo é constantemente assegurada pela fundamental   interação entre sistema imunológico e processos metabólicos, onde as células   imunológicas compõem uma importante linha de defesa contra agentes estressores   e, frente à resposta imunológica, significantes alterações no metabolismo   celular ocorrem para o reestabelecimento da homeostase corporal. A partir   destas relações, deu-se o termo Imunometabolismo, que pode ser definido como um   <i>crosstalk</i> constante entre o sistema imunológico e a atuação do metabolismo celular.</p>     <p>Em 2011, em um artigo de revisão, teve-se a primeira menção do termo   Imunometabolismo por Mathis e Shoelson, evidenciando a necessidade de   investigações acerca da interação entre imunologia e metabolismo no contexto,   neste caso, da obesidade, tendo em vista que esta doença afeta a resposta   imunológica em virtude do desenvolvimento e instalação da inflamação crônica de   baixo grau provocando significantes alterações metabólicas. Conceitualmente, a   inflamação crônica de baixo grau corresponde ao aumento de duas a quatro vezes   das concentrações séricas basais de mediadores inflamatórios que atuam como preditores de mortalidade (Candore, Caruso, &amp; Colonna-Romano, 2010).</p>     <p>Atualmente, diversos estudos caracterizam os padrões morfofuncionais do   tecido adiposo e elucidam a presença de inúmeras células imunológicas   residentes (Mraz &amp; Haluzik, 2014; Schipper, Prakken, Kalkhoven, &amp; Boes,   2012), como macrófagos e linfócitos, que sofrem alterações metabólicas e   funcionais em resposta à obesidade (Lee &amp; Lee 2014; Lumeng, Bodzin, &amp;   Saltiel, 2007). Por outro lado, outras doenças advindas do comportamento   sedentário, como dislipidemia, diabetes <i>mellitus</i> tipo 2, hipertensão   arterial, câncer, entre outras, também apresentam impactantes modificações   metabólicas, reconhecidas atualmente como “<i>doençoma” (do inglês diseasome)</i>   da inatividade física (Pedersen, 2009), e um quadro inflamatório crônico de   baixo grau com elevada atividade das células imunes (McNelis &amp; Olefscky,   2014) e produção de citocinas inflamatórias como TNF-&#945;, IL-6, IL-1&#946; e proteínas   quimioatraentes de células imunológicas, como a proteína quimiotáctica de monócitos-1 (MCP-1) (Olefscky &amp; Glass, 2010).</p>     <p>Um dos principais elos de comunicação entre as células imunológicas e o   metabolismo são as citocinas, as quais podem ser caracterizadas como proteínas   sinalizadoras e/ou imuno-moduladoras com atuação autócrina, parácrina e   endócrina, sintetizadas principalmente por linfócitos, monócitos e macrófagos,   e que são capazes de receber e enviar estímulos para os mais diversos tecidos e órgãos (Pillon, Bilan, Fink, &amp; Klip, 2013). </p>     ]]></body>
<body><![CDATA[<p>As citocinas, na década de 70, eram intituladas como “linfocinas”, pois   se acreditava que eram sintetizadas exclusivamente por linfócitos,   posteriormente, foram renomeadas para “monocinas” ao verificar-se que os   monócitos e macrófagos também possuíam a capacidade de produção e liberação;   entretanto, após a verificação que tecidos e outras estruturas celulares também   apresentavam esta capacidade, adotou-se a nomenclatura citocina (Abbas,   Lichtman, &amp; Pober, 1998; Cordova-Martinez &amp; Alvarez-Mon, 1999). Neste   contexto, é relevante ressaltar que o local de origem de sua produção é   determinante para a nomenclatura, por exemplo, as proteínas sinalizadoras   quando sintetizadas e liberadas por miócitos são denominadas de miocinas (Pedersen, Akerström, Nielsen,   &amp; Fisher, 2007; Pedersen 2011) e pelos adipócitos como adipocinas (Trayhurn, Drevonm, &amp; Eckel, 2011; Trayhurn &amp; Wood, 2004).</p>     <p>As miocinas são sintetizadas e   liberadas para a corrente sanguínea por estímulo da contração muscular (Iizuka,   Machida, &amp; Hirafuji, 2014) e, sob esta perspetiva, a prática regular de exercício físico possui suma importância na regulação   do Imunometabolismo, uma vez que o mesmo é capaz de induzir significantes   alterações metabólicas, pois durante a execução dos exercícios há aumento da   demanda energética e modificações hormonais para que haja a regulação e   manutenção da atividade muscular e, consequentemente, pelo aumento do aporte   energético para as células musculares. Frente a este panorama, uma das   pesquisas pioneiras que demonstraram a interação entre o sistema imune e   metabolismo durante exercício foi conduzida por Bjorn Ahlborg e Gunvor Ahlborg   (1970); estes autores associaram a elevação das quantidades das células imunes   no sangue durante a sessão de exercício físico com o aumento da resposta   adrenérgica, via estímulo simpático do sistema nervoso central, resultando na   síntese e liberação de catecolaminas, estas capazes de estimular e   disponibilizar substratos para a musculatura esquelética em contração, levando também a uma modulação imunológica local e sistêmica. </p>     <p>Desta forma, fica evidente que em distintos campos, seja na doença ou   prática de exercício físico, há íntima comunicação entre sistema imunológico e   metabolismo celular, tornando a vertente do Imunometabolismo uma promissora   linha de investigação no âmbito do entendimento dos fenômenos que compõe o   organismo humano frente a diferentes condições de estímulos estressores. Na   <a href="/img/revistas/mot/v13n1/13n1a10f1.jpg">figura 1</a> estão ilustradas as principais descobertas no campo do   imunometabolismo que fortaleceram e corroboraram para a formação e consolidação desta área de pesquisa em expansão.</p>     
<p><b>Interação entre Metabolismo, Células Imunológicas e Vias Energéticas </b></p>     <p>As células do sistema imunológico   desempenham papel fundamental na proteção do organismo e manutenção da   homeostase corporal compondo uma linha de defesa amplamente mobilizada frente   alterações metabólicas, tais como em situações de doença e frente à realização   de exercício físico, sendo este último estímulo um agente estressor dependente   de sua intensidade, volume e duração. Neste contexto, em meados dos anos 90 foi   observado que o exercício físico quando realizado de forma intensa contribuía   no aumento da incidência de infeção do trato respiratório superior, enquanto   que o exercício de   intensidade moderada teria um efeito protetor ao risco de infeções (Nieman, 1994).</p>     <p>Mediante a suscetibilidade às   infeções e processos inflamatórios associado com a prática de exercício físico,   buscou-se compreender quais possíveis mecanismos modulavam a resposta   imunológica, e segundo Costa Rosa e Vaisberge (2002) são mobilizadas do sistema imunológico componentes   celulares e humorais em resposta as alterações mecânicas (hipóxia, hipertermia   e lesão muscular), metabólicas (glutamina) e hormonais (adrenalina, cortisol, entre outros) impostas pelo exercício. </p>     <p>Frente às alterações impostas pelo esforço físico, diversos ajustes   imuno-metabólicos ocorrem a fim de manter o equilíbrio dos sistemas e a   execução dos esforços, uma vez que, durante a contração muscular há aumento da   demanda energética fazendo-se necessário o aumento da disponibilidade de   substratos energéticos, tais como a glutamina, para as células musculares,   entretanto, a captação e utilização da glutamina como aporte energético gerou a   hipótese de uma competição de substrato entre o músculo esquelético e o sistema   imune. De acordo com Pedersen et al. (1998) o músculo esquelético, assim como   as células imunes, também utiliza da glutamina como fonte de energia, e em   situações nas quais há necessidade de maior substrato energético, como em   quadros de sepsemia e exercício físico extenuante em alta intensidade, ocorrerá   redução na função de algumas células do sistema imunológico, discutiremos este quadro nos tópicos a seguir.</p>     <p><b>Metabolismo Energético das Células Imunes</b></p>     <p>O sistema imunológico possui importância fundamental, não somente para   prevenir ou combater uma infeção, mas também na reparação de lesões,   proliferação e biossíntese de células e atividade secretória (Calder,   Dimitriads, &amp; Newsholme, 2007). Neutrófilos, linfócitos e   monócito/macrófagos possuem importantes papeis na resposta imune e inflamatória aguda e crônica. </p>     <p>Os linfócitos são ativados em quadros crônicos de infeção, sendo que os   linfócitos T são requeridos para ativar macrófagos, enquanto linfócitos B   produzem e secretam anticorpos em resposta ao estímulo antigênico. Já os   neutrófilos, constituem 60% dos leucócitos circulantes e atua na fase aguda da   infeção, sendo considerados como linha de frente na defesa do organismo por   meio da fagocitose e degradação de patógenos. Os macrófagos, assim como os   neutrófilos, realizam a fagocitose de patógenos, porém são apresentadores de   antígeno por meio do complexo de histocompatibilidade maior II (MHC II) (Newsholme, 2001). </p>     ]]></body>
<body><![CDATA[<p>O metabolismo energético das   células do sistema imunológico é extremamente refinando, utilizando   principalmente glicose, glutamina, ácidos graxos e corpos cetónicos. A   glutamina, embora seja um aminoácido não-essencial, exibe fundamental   importância nas condições inflamatórias, especialmente para a proliferação e   estimulação das funções celulares, inclusive aumentando da produção de citocinas de acordo com o fenótipo de cada célula (Newsholme, 2001).</p>     <p>O linfócito, em um estado   quiescente, utiliza o metabolismo oxidativo pela via do ciclo do ácido   tri-carboxílico (Ardawi &amp; Newshole, 1984; Norata et al., 2016), entretanto,   sob uma determinada ativação, o seu metabolismo sofre mudança brusca, por   necessitar de grande demanda energética imediata, ao sair do seu estado de   repouso para um estado de proliferação, e passam a produzir energia por meio da   glicólise mesmo na presença de oxigênio, o que é chamado de glicólise aeróbia.   Ardawi e Newsholme (1984) também verificaram que a glutamina é um substrato   importante para proliferação de linfócitos. Desta forma, tanto a glicose, que é   convertida em lactato, como a glutamina, que é convertida em glutamato,   aspartato e lactato, são os principais substratos dessa célula, embora corpos   cetônicos e ácidos graxos também sejam utilizados em menor escala,   especialmente em condição homeostática (Ardawi &amp; Newsholme, 1984; Yaqoob,   Newsholme, &amp; Calder, 1994). Vale destacar alguns hormônios, como a insulina   e hormônios da tireoide, que auxiliam na função dos linfócitos, estimulando a   glicólise aeróbica, o consumo de glutamina e estimulação do metabolismo aeróbio (Wasinki et al., 2014).</p>     <p>Nos neutrófilos, a glicose parece ser a principal fonte energética, sendo   que a sua oxidação parece ser aumentada durante a fagocitose. Entretanto, a   glutamina também exibe importante papel na função desta célula, especialmente   quando o fornecimento de glicose é restrito. A carência desses substratos pode   prejudicar drasticamente a função dos neutrófilos (Healy, Watson, &amp; Newsholme, 2002).</p>     <p>Os macrófagos, por sua vez, utilizam glicose para a produção de NADPH e   precursores de lipídios. Já a glutamina é utilizada para a produção de ATP e a   sua escassez pode prejudicar a função dos macrófagos, uma vez que ela   potencializa a expressão do MHC II. Os ácidos graxos de cadeia longa são   essenciais para gerar intermediários do ciclo do ácido tricarbolxílico (Newsholme, Costa Rosa, Newsholme, &amp; Curi, 1996). </p>     <p>Assim, é nítido que a função do sistema imune está intimamente   relacionada com o metabolismo energético. Entretanto é preciso considerar que   as funções das diferentes células imunes são associadas com configurações   metabólicas distintas (Norata et al., 2015), destacam-se os diferentes fenótipos   de macrófagos, sendo os macrófagos do tipo 1 (M1) realizam altas taxas de   glicólise e síntese de ácidos graxos, enquanto o fenótipo tipo 2 dos macrófagos   (M2) exerce alta demanda na oxidação de ácidos graxos (Mills &amp; O’Neil, 2016). </p>     <p>Além disso, a condição metabólica das células imunes pode sofrer   reprogramação direcionando para mudanças das propriedades funcionais e   viabilizando a alteração do fenótipo celular. Neste contexto, a disponibilidade   de nutrientes e sinais induzidos por metabólitos regulam a sua diferenciação   fenotípica, por exemplo, o M1/M2 (Norata et al., 2015) e T helper 1/T helper 2   (Caris et al., 2014). Essa mudança do <i>status</i> metabólico sofre influência   do seu meio extracelular, que por sua vez, representa alterações sistêmicas   advindas de diversas situações, desde estados de doenças à resposta ao exercício físico.</p>     <p><b>Doenças crônicas e alterações Imunometabólicas </b></p>     <p>O quadro de doença pode ser   caracterizado como um estresse metabólico que culmina em um desequilíbrio das   funções do organismo. Desta forma, Norata et al. (2015) consideram que as   doenças podem fornecer um profundo entendimento sobre o <i>crosstalk</i>   imunometabólico, uma vez que o <i>milieu</i> metabólico está completamente alterado o que impacta todo o sistema imunológico.</p>     <p>As doenças crônicas não transmissíveis (DCNTs) são doenças   multifatoriais, as quais destacam-se as doenças cardiovasculares (hipertensão   arterial, arterosclerose, infarto do miocárdio), diabetes <i>mellitus </i>do   tipo 2, os diversos tipos de câncer e doenças respiratórias crônicas que   possuem como fatores de riscos intermediários outras DCNT, como a hipertensão   arterial sistêmica, dislipidemia, obesidade e resistência à insulina (Ouchi, Parker, Lugus, &amp; Walsh, 2011; WHO, 2015). </p>     <p>&nbsp;</p>     ]]></body>
<body><![CDATA[<p align="center"><a href="/img/revistas/mot/v13n1/13n1a10f2.jpg">Figura 2</a></p>     
<p>&nbsp;</p>     <p>No quadro da obesidade, especialmente o acúmulo de gordura no tecido   adiposo visceral (TAV), é considerada o denominador patogênico comum para as   DCNTs, pois direciona ao aumento da síntese de adipocinas produzidas   principalmente pelos M1 e os diversos fenótipos de linfócitos (T auxiliadores,   T citotóxicos, B) residentes no tecido (Ouchi et al., 2011). Dentre as diversas   adipocinas destacam-se a IL-6, TNF-&#945;, leptina e resistina. Estas citocinas, produzidas em   excesso acarretarão ao aumento da resistência à insulina e lipólise, que em   longo prazo poderá contribuir para instalação e/ou progressão de doenças como diabetes <i>mellitus </i>tipo 2, câncer, doenças respiratórias e aterosclerose.</p>     <p>A aterosclerose representa uma das doenças cardiovasculares mais comuns   apresentando um processo inflamatório característico à doença no qual ocorrem   lesões nos vasos sanguíneos podendo evoluir para a formação de placas fibrosas.   Neste processo as células endoteliais secretam proteínas quimioatraentes, como   IL-8 e MCP-1, que atraem monócitos/macrófagos para o tecido lesionado   estimulando a secreção de outras citocinas pró-inflamatórias, como a IL-1&#946;, IL-3, IL-18 e   TNF-&#945;, a fim de restabelecer os danos locais de tais lesões (Golia et al.,   2014). Além disso, a relação do aumento de neutrófilos e diminuição de   linfócitos tem sido considerada como marcador de eventos cardiovasculares e de   mortalidade, já que os neutrófilos estão relacionados com proteínas de fase   aguda da inflamação e linfócitos com a formação de aterosclerose (Prats-Puig et al., 2015).</p>     <p>Por outro lado, o processo aterosclerótico apresenta íntima relação com   alterações nas concentrações lipídicas circulante, também reconhecida como   dislipidemia, e nesta perspectiva nossas investigações evidenciaram   recentemente que em adolescentes obesos a ingestão de lipídeos e carboidratos   está intimamente associada com a dislipidemia, via alterações nas concentrações   de colesterol total, triacilglicerol e HDL-c, e a inflamação crônica de baixo   grau, via alterações nas concentrações de IL-1ra, IL-6, adiponectina e insulina (Antunes et al., 2015). </p>     <p>Neste contexto, visto que a maioria das DCNTs citadas parece estar   relacionada à inflamação crônica de baixo grau, advinda da inflamação do TAV   que ocorre na obesidade, provavelmente o estilo de vida é visto como um dos   principais gatilhos para as alterações imunometabólicas, estabelecendo um ciclo   vicioso para a inflamação e permanência/manutenção das doenças crônicas (<a href="/img/revistas/mot/v13n1/13n1a10f3.jpg">figura   3</a>). Sendo assim, o exercício físico é uma ferramenta estratégica para a   prevenção e tratamento de DCNTs, bem como, dos processos inflamatórios que circunda cada tipo de doença.</p>     
<p><b>Exercício Físico: implicações práticas na regulação do Imunometabolismo</b></p>     <p>A prática insuficiente de   exercício físico está relacionada com o desenvolvimento de diversas doenças e   alterações metabólicas, tais como diminuição da sensibilidade à insulina,   alterações no metabolismo de lipídios, aumento da adiposidade visceral,   diminuição da massa corporal magra e perda de força muscular, resultando em um quadro de inflamação crônica de baixo grau (Perdersen, 2009). </p>     <p>Por outro lado, a contração   muscular, advinda do exercício físco, pode elevar a produção de miocinas (tais   como miostatina, IL-6, IL-7, IL-8, IL-10, IL-15, LIF) e ativar células do sistema imunológico (monócitos/macrófagos, neutrófilos)   a fim de direcionar células satélites para o local do dano muscular com o   objetivo de iniciar o processo de remodelamento e reparação tecidual (Tidball   &amp; Villalta, 2010) e, desta forma, reverter e equilibrar o possível quadro inflamatório devido sua   potente ação anti-inflamatória (Pedersen &amp; Febbraio, 2012). Além disso, o   gene da miostatina não ativado pode resultar no aumento da hipertrofia muscular   e talvez contribuir para a redução da gordura corporal (Rodgers &amp; Garikipati, 2008).</p>     <p>Em relação à resposta emitida   pelas células imunológicas frente ao exercício físico, os neutrófilos são as   primeiras células a se instalarem no músculo-esquelético após lesão aguda, pois   iniciam o processo de reparação tecidual por meio do aumento na liberação de   ROS ou, ainda, por favorecer o recrutamento de monócitos para ação fagocitária   e/ou aumento na secreção de citocinas na tentativa de recrutar um número maior de células de defesa (Lockhart &amp; Brooks, 2008). </p>     ]]></body>
<body><![CDATA[<p>Os monócitos, após se infiltrarem   no tecido alvo, convergem para macrófagos, os quais aumentam a produção de   citocinas nos espaços intersticiais, atraindo novas moléculas quimioatraentes   de monócitos (Ly-6C<sup>baixa</sup>/ CD11c<sup>intermediaria</sup> /CX3CR1<sup>alta</sup>),   que induzirão a fagocitose de células musculares apoptóticas e necróticas   (Pillon et al., 2013). Os primeiros macrófagos a se acumularem no início da   inflamação são caracterizados como M1; quando passam a atuar no processo de   recuperação tecidual, mediado por citocinas como IL-10 e fatores de crescimento   tumorais (TGF&#946;1), aumentando a proliferação de mioblastos e   crescimento miofibrilar, são polarizados em macrófagos de caráter   anti-inflamatório (M2) (Deng, Wehling-Henricks, Villalta, Wang &amp; Tidball,   2012). Os macrófagos M2 têm também a capacidade de produzir fatores   de crescimento semelhantes à insulina do tipo 1 (IGF-1) e de crescimento   endotelial vascular (VEGF), aumentando o número de vasos sanguíneos, o fluxo de   sangue (Wan et al., 2010) e, novamente, induzindo a proliferação de mioblastos   e diferenciação de células satélites, os quais resultam na formação de novas   miofibrilas (<a href="/img/revistas/mot/v13n1/13n1a10f4.jpg">Figura 4</a>) (Rocheteau, Gayraud-Morel, Siegl-Cachedenier, Blasco, &amp; Tajbakhsh, 2012).</p>     
<p>Os fatores hormonais também estão intimamente relacionados com a   resposta imunometabólica. A adrenalina e o cortisol são dois exemplos de   hormônios que respondem ao exercício físico ao mesmo tempo em que modulam o   metabolismo de linfócitos, além de ser dependentes da intensidade e duração do   estímulo. A adrenalina pode estimular a proliferação de linfócitos além de   aumentar o seu consumo de glicose e glutamina, sendo que em exercícios de alta   intensidade podem gerar efeito de imunossupressão reduzindo a atividade de   enzimas chave que prejudicam o metabolismo de glicose e glutamina. O cortisol,   por sua vez, é considerado um hormônio de imunossupressão, especialmente   também, em exercícios de alta intensidade, prejudicando a capacidade   proliferativa dos linfócitos entre 30 minutos à duas horas após o esforço físico (Wasinki et al., 2014). </p>     <p>Dessa maneira, a   manipulação das variáveis do exercício físico, como tipo de estímulo (aeróbio   ou anaeróbio), frequência do estímulo (agudo ou crônico), intensidade e volume,   contração excêntrica ou concêntrica e intervalos de recuperação, são variáveis   que podem influenciar (positiva ou negativamente) o processo de recrutamento de   células do sistema imunológico (Gjevestad, Holven &amp; Ulven, 2015; Paulsen, Mikkelsen, Raastad &amp; Peake, 2012). </p>     <p>Em relação ao tipo de estímulo<i>,   </i>tem-se observado que os linfócitos circulantes aumentam durante   exercício aeróbio de moderada à alta intensidade (van de Vyver, Engelbrecht, Smith &amp; Myburgh, 2015), no entanto, o exercício de alta   intensidade e longa duração (ex: maratona), pode suprimir o sistema imune e a   quantidade celular pode ficar abaixo dos valores de repouso, como discutido em   revisão conduzia por Hoffman-Goetz e Pedersen (1994). Em estudo   realizado por van de Vyver et al. (2015), o qual verificou a resposta imune   pré, imediatamente pós estímulo e após 4 horas de exercício aeróbio em alta   intensidade (12&#8201;estímulos de&#8201;5&#8201;minutos/cada, 10%   declive, 15&#8201;km/h),   observou-se que monócitos e   neutrófilos aumentaram após 4 horas do término do exercício, além disso, estes   autores sugerem que a presença de monócitos foi responsável pela elevação na concentração de IL-6, via sinalização de STAT-3. </p>     <p>Em relação ao estímulo anaeróbio, que tem como principal tipo o   exercício resistido, Stupka,   Tarnopolsky, Yardley e Phillips (2001) compararam a resposta da infiltração de   células do sistema imune (macrófagos e neutrófilos) e marcador de proteólise   [Creatine Kinase (CK)] de acordo com sexo, por meio de biópsia muscular, após   três séries de 12 repetições no <i>leg press</i>, com três minutos de intervalo   entre as séries, seguida por 10 séries de 10 repetições em cadeira extensora   unilateral, com a mesma perna exercitada no <i>leg press</i> (120% de 1RM) e   observaram que o número de neutrófilos foi significativamente aumentado em   mulheres após 24 horas, mas não no sexo masculino, sendo que os macrófagos   aumentaram em ambos os sexos, demostrando que o a resposta inflamatória pode   ser diferente de acordo com o tempo de estímulo excêntrico e o gênero, no   entanto, ainda não está bem esclarecida a influência do gênero neste desfecho (St. Pierre, Correia &amp; Cannon, 1999).</p>     <p>Nosso grupo investigou, recentemente, os efeitos do treinamento físico   aeróbio de intensidade moderada combinado com o treinamento resistido e concluímos   que, independentemente do tipo de periodização (linear ou ondulatória),   adolescentes obesos apresentaram aumento das concentrações de adiponectina   quando comparados com aqueles que realizaram apenas o treinamento aeróbio,   havendo, portanto, melhora no quadro de resistência à insulina e,   consequentemente, do <i>milieu</i> inflamatório da obesidade (Inoue et al., 2015).</p>     <p>Quando analisada<i> a “frequência   do estímulo (agudo ou crônico)”,</i> observa-se que as células imunes   instalam-se no tecido muscular imediatamente após uma única sessão de exercício   físico. Exercícios de curta duração e de intensidade entre moderada e elevada   (3 séries de 10 repetições e 70% de 1RM ou 30 minutos de corrida a 75% do VO<sub>2max</sub>)   podem resultar em picos na expressão de IL-6, IL-8 e TNF-&#945; RNAm de 2 a 12   horas (Louis, Raue, Yang, Jemiolo, &amp; Trappe, 2007). Simonson e Jackson (2004), analisaram os efeitos de   uma série de exercício resistido sobre a resposta imune em homens ativos (3 séries de 8-10 repetições a 75%   de 1 RM para oito grandes agrupamentos musculares) e concluíram que os   leucócitos, principalmente os monócitos e neutrófilos, aumentaram imediatamente   pós-exercício, exceto basófilos e eosinófilos, e retornaram as concentrações   pré-exercício após 15 e 30 minutos do término da sessão, no entanto, os neutrófilos permaneceram elevados mesmo após 30 minutos pós-exercício.  </p>     <p>Apesar de serem escassos na   literatura estudos que verificaram a resposta imune após longos períodos de   treinamento, Yakeu et al.   (2010) investigaram os efeitos de oito semanas de treinamento leve (caminhada=10.000 passos/dia, três   vezes/semana) em indivíduos sedentários e observaram que até mesmo o exercício   de baixa intensidade tem associação positiva com macrófagos M2, Th2, PGC-1&#945; e PGC-1&#946; e negativa com   macrófagos M1, demonstrando que o exercício em intensidade leve, porém realizado consistentemente, pode polarizar os macrófagos.</p>     <p>Sobre a intensidade e volume<i>, </i>em estudo clássico realizado   por Tvede et al. (1989), o qual verificou a influência de diferentes   intensidades de exercício em ciclo ergómetro (25%, 50% e 75% do VO<sub>2max</sub>)   durante 1 hora, foi observado que algumas células de defesa [<i>Natural Killer</i>   (NK) e células <i>Killer</i> Linfócitos ativadas (LAK)] foram aumentadas em   todas as intensidades de esforço, no entanto, foram suprimidas na carga de 75%   do VO<sub>2max</sub>. Além disso, somente essa intensidade apresentou monócitos   infiltrados após o término do exercício, sugerindo que essa intensidade de   exercício pode potencializar o processo de remodelamento da musculatura esquelética.</p>     <p>Fragala et al. (2011) analisaram a expressão do recetor adrenérgico de &#946;2 (&#946;2-ADR) em   monócitos, granulócitos e linfócitos e observou-se que em linfócitos houve   aumento da expressão após exercício   resistido severo (6 séries   de 5 RM no agachamento) e concluíram que em monócitos e granulócitos há   diminuição durante o exercício, porém com elevação durante o processo de   recuperação. Em adição, estudos do nosso grupo têm demostrado que exercício   exaustivo pode promover aumento de citocinas (IL-6, IL-10, TNF-&#945;) e assim, via   TLR-4, contribuir para mobilização de substrato energético (Rosa Neto et al.,   2011). Como citado anteriormente no estudo de Yakeu et al. (2010), o exercício   físico leve, realizado sistematicamente, também foi suficiente para induzir   benefícios anti-inflamatórios. Em contrapartida, em uma situação de <i>overtraining</i>,   pode haver aumento exacerbado de citocinas pró-inflamatórias sintetizadas e   liberadas pelo tecido adiposo (adipocinas), induzindo um estado de inflamação tecidual (Lira et al., 2010a).</p>     ]]></body>
<body><![CDATA[<p>Em relação ao intervalo de recuperação, nosso grupo verificou a   influência de 30 e 90 segundos de intervalo em jovens saudáveis submetidos a 4   séries de agachamento seguido por 4 séries de supino horizontal, com 70% de 1RM   até a falha do movimento; concluímos que apesar do desempenho diminuir em ambos   os intervalos, somente o tempo de 90 segundos induziu aumento nas concentrações   de IL-6 e redução de IL-10, porém sem significância estatística nessa última,   assim, intervalos moderados de recuperação poderiam favorecer uma maior   resposta metabólica e benefícios anti-inflamatórios durante o processo de reparação tecidual (Rossi, Gerosa-Neto, Zanchi, Cholewa, &amp; Lira, 2016).</p>     <p>Apesar de o sistema imune e o   metabolismo serem de extrema importância tanto na resolução de um quadro   inflamatório crônico de baixo grau (obesidade, DM2) como no remodelamento da   musculatura esquelética, a relação imunometabolismo e exercício deve ser   interpretada com cautela, uma vez que os níveis de aptidão física dos sujeitos,   faixa etária, gênero, tipo de análise ou técnica empregada diferem   significativamente entre os estudos, entretanto, tanto indivíduos altamente   treinados (Lira et al.,   2010b), moderadamente ativos   (Diniz et al., 2015) ou inclusive que apresentam um quadro de doença, como a   caquexia associada ao câncer (Lira et al., 2014), podem apresentar efeitos   anti-inflamatórios induzidos pelo exercício físico regular e menor risco de dislipidemia em relação a indivíduos sedentários (Lira et al., 2014).</p>     <p><b>Perspetivas futuras</b></p>     <p>A inter-relação entre as respostas   inflamatória e metabólica é determinante para a instalação de diferentes   doenças, por outro lado, a mesma também é determinante para as respostas   anti-inflamatória e anti-aterogênica mediadas pelo exercício físico (Lira et   al. 2014a; Lira et al 2014b). Estudos que explorem os mecanismos envolvidos   nesta inter-relação são fundamentais para o entendimento desta nova área do conhecimento científico. </p>     <p>&nbsp;</p> </font>     <p><font size="3" face="Verdana"><b>CONSIDERA&Ccedil;&Otilde;ES FINAIS</b></font></p> <font face="Verdana" size="2">     <p>Mediante ao exposto acima, podemos   concluir que há uma interação entre sistema imunológico, especialmente a   resposta inflamatória, e o metabolismo celular em diferentes condições, seja   frente às doenças crônicas ou exercício físico. Torna-se de suma importância a   compreensão dos mecanismos de interação entre os sistemas, sendo esta   fundamental para a utilização destas informações em prol da promoção da   qualidade de vida, na elaboração efetiva de programas de prevenção e tratamento de doenças, bem como na melhora do desempenho físico.</p>     <p>&nbsp;</p> </font>     <p><font size="3" face="Verdana"><b>REFERÊNCIAS</b></font></p> <font face="Verdana" size="2">     <!-- ref --><p>Abbas, A. K., Lichtman, A. H., &amp; Pober, J. S. (1998). <i>Citocinas.   In: Imunologia celular e molecular</i> (2<sup>nd</sup> ed.) Rio de Janeiro: Revinter.    &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;[&#160;<a href="javascript:void(0);" onclick="javascript: window.open('/scielo.php?script=sci_nlinks&ref=363306&pid=S1646-107X201700010001000001&lng=','','width=640,height=500,resizable=yes,scrollbars=1,menubar=yes,');">Links</a>&#160;]<!-- end-ref --></p>     <!-- ref --><p>Ahlborg, B., &amp; Ahlborg, G. (1970). 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<body><![CDATA[<br>   </b>Nada a declarar<b>    <br>   Conflito de Interesses:</b>    <br>   Nada a declarar.<b>    <br>   Financiamento:    <br>     </b>Fabio   Santos Lira thanks CNPq for their support (305263/2015-3).</p> </font>     <p><font size="2" face="Verdana">Artigo   recebido a 15.01.2016; Aceite a 05.06.2016 </font></p>     <p>&nbsp;</p> <font face="Verdana" size="2">     <p>&nbsp;</p> <a name="end"></a><a href="#topo">*</a> <i>Autor correspondente</i>: Universidade Estadual Paulista, Departamento de Educa&ccedil;&atilde;o F&iacute;sica, Rua Roberto Simonsen, 305, CEP. 19060-900, Presidente Prudente, SP-Brazil. <i>E-mail</i>: <a href="mailto:ba.antunes2@gmail.com">ba.antunes2@gmail.com</a>     <p>&nbsp;</p> </font>      ]]></body><back>
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