RESUMO
Despite what its name suggests, the effects of the COVID-19 pandemic causative agent "Severe Acute Respiratory Syndrome Coronavirus-2" (SARS-CoV-2) were not always confined, neither temporarily (being long-term rather than acute, referred to as Long COVID) nor spatially (affecting several body systems). Moreover, the in-depth study of this ss(+) RNA virus is defying the established scheme according to which it just had a lytic cycle taking place confined to cell membranes and the cytoplasm, leaving the nucleus basically "untouched". Cumulative evidence shows that SARS-CoV-2 components disturb the transport of certain proteins through the nuclear pores. Some SARS-CoV-2 structural proteins such as Spike (S) and Nucleocapsid (N), most non-structural proteins (remarkably, Nsp1 and Nsp3), as well as some accessory proteins (ORF3d, ORF6, ORF9a) can reach the nucleoplasm either due to their nuclear localization signals (NLS) or taking a shuttle with other proteins. A percentage of SARS-CoV-2 RNA can also reach the nucleoplasm. Remarkably, controversy has recently been raised by proving that-at least under certain conditions-, SARS-CoV-2 sequences can be retrotranscribed and inserted as DNA in the host genome, giving rise to chimeric genes. In turn, the expression of viral-host chimeric proteins could potentially create neo-antigens, activate autoimmunity and promote a chronic pro-inflammatory state.
RESUMO
The human immunodeficiency virus (HIV-1) modifies the host cell environment to ensure efficient and sustained viral replication. Key to these processes is the capacity of the virus to hijack ATPases, GTPases and the associated proteins that control intracellular protein trafficking. The functions of these energy-harnessing enzymes can be seized by HIV-1 to allow the intracellular transport of viral components within the host cell or to change the subcellular distribution of antiviral factors, leading to immune evasion. Here, we summarize how energy-related proteins deviate from their normal functions in host protein trafficking to aid the virus in different phases of its replicative cycle. Recent discoveries regarding the interplay among HIV-1 and host ATPases and GTPases may shed light on potential targets for pharmacological intervention.
RESUMO
Ureases (EC 3.5.1.5) are Ni(2+) -dependent metalloenzymes produced by plants, fungi and bacteria that hydrolyze urea to produce ammonia and CO2 . The insertion of nickel atoms into the apo-urease is better characterized in bacteria, and requires at least three accessory proteins: UreD, UreF, and UreG. Our group has demonstrated that ureases possess ureolytic activity-independent biological properties that could contribute to the pathogenicity of urease-producing microorganisms. The presence of urease in pathogenic bacteria strongly correlates with pathogenesis in some human diseases. Some medically important fungi also produce urease, including Cryptococcus neoformans and Cryptococcus gattii. C. gattii is an etiological agent of cryptococcosis, most often affecting immunocompetent individuals. The cryptococcal urease might play an important role in pathogenesis. It has been proposed that ammonia produced via urease action might damage the host endothelium, which would enable yeast transmigration towards the central nervous system. To analyze the role of urease as a virulence factor in C. gattii, we constructed knockout mutants for the structural urease-coding gene URE1 and for genes that code the accessory proteins Ure4 and Ure6. All knockout mutants showed reduced multiplication within macrophages. In intranasally infected mice, the ure1Δ (lacking urease protein) and ure4Δ (enzymatically inactive apo-urease) mutants caused reduced blood burdens and a delayed time of death, whereas the ure6Δ (enzymatically inactive apo-urease) mutant showed time and dose dependency with regard to fungal burden. Our results suggest that C. gattii urease plays an important role in virulence, in part possibly through enzyme activity-independent mechanism(s).
Assuntos
Criptococose/microbiologia , Cryptococcus gattii/enzimologia , Cryptococcus gattii/patogenicidade , Urease/metabolismo , Fatores de Virulência/metabolismo , Virulência , Animais , Southern Blotting , Western Blotting , Células Cultivadas , Criptococose/metabolismo , Criptococose/mortalidade , Criptococose/patologia , Feminino , Humanos , Camundongos , Camundongos Endogâmicos BALB C , Fagocitose , Filogenia , RNA Mensageiro/genética , Reação em Cadeia da Polimerase em Tempo Real , Reação em Cadeia da Polimerase Via Transcriptase Reversa , Taxa de Sobrevida , Urease/genética , Fatores de Virulência/genéticaRESUMO
As ORFs I e IV do genoma do HTLV-1 codificam, respectivamente, as proteínas p12/p8 (acessória) e Tax (regulatória). p12/p8, de 99 aminoácidos, pode ser clivada em sua extremidade amino terminal gerando a proteína p8. A primeira clivagem proteolítica de p12 remove o sinal de retenção ao RE, enquanto a segunda clivagem, gera o produto de 8kDa, referido como p8. p12 localiza-se no sistema de endomembranes, residindo em RE e aparato de Golgi, enquanto p8 dirige-se para a membrana plasmática, onde é recrutada para a sinapse imunológica, através da ligação com o receptor de células T (TCR), além de participar da sinapse virológica e da formação de conduítes. A proteína Tax, por outro lado, atua como transativador transcricional do HTLV-1, sendo referida também na indução da expressão de diversos genes celulares, aumentando a proliferação e a migração das células infectadas. Na via de transporte de vesículas secretórias, vesículas produzidas como pós-Golgi são transportadas ao longo do citoesqueleto por motores celulares. A Miosina-Va, um motor não convencional, transporta diversos cargos, incluindo vesículas secretórias, vesículas sinápticas e de retículo endoplasmático. Outra proteína relacionada ao citoesqueleto é a Paxilina, que atua como molécula adaptadora nas adesões focais e cuja expressão está aumentada em indivíduos TSP-HAM...
HTLV-1 ORFs I and IV encode respectively p12/p8 (accessory protein) and Tax (regulatory protein). The 99 amino acid p12 protein can be proteolytically cleaved at the amino terminus to generate the p8 protein. The first proteolytic cleavage removes the ER retention/retrieval signal at the amino terminus of p12, while the second cleavage generates the p8 protein. The p12 protein localizes to cellular endomembranes, within the ER and Golgi apparatus, while p8 traffics to lipid rafts at the cell surface and is recruited to the immunological synapse upon T-cell receptor (TCR) ligation, virological synapse and conduits. Tax on the other hand acts as viral transactivator and induces expression of many cellular genes, increasing proliferation and migration of infected cells. In secretory vesicle transport, vesicles produced as post-Golgi are moved along the cytoskeleton by motor proteins. The unconventional myosin motor, Myosin-Va, moves several cargoes including secretory vesicles, synaptic vesicles, and the endoplasmic reticulum. Another cytoskeleton associated protein is Paxillin, an adapter on focal adhesions which expression is increased in TSP-HAM patients...
Assuntos
Humanos , Paxilina/biossíntese , Paxilina/toxicidade , Paxilina/ultraestrutura , Produtos do Gene tax/análise , Produtos do Gene tax/imunologia , Produtos do Gene tax/isolamento & purificação , Produtos do Gene tax/sangue , Produtos do Gene tax/síntese química , Vírus Linfotrópico T Tipo 1 Humano/imunologia , Vírus Linfotrópico T Tipo 1 Humano/patogenicidadeRESUMO
Desde el descubrimiento del virus de inmunodeficiencia humana tipo 1 (VIH-1) como agente etiológico del síndrome de inmunodeficiencia adquirida (SIDA) se han descrito los procesos más importantes que hacen parte del ciclo replicativo del virus y que a su vez participan de la fisiopatología tan compleja que caracteriza a esta infección. A pesar de los avances realizados en el desarrollo de medicamentos antirretrovirales y de los logros alcanzados en el control de la replicación viral, hechos que se reflejan en un aumento en la expectativa y calidad de vida de los individuos infectados, la terapia actual no permite una reconstitución inmunológica total y está acompañada de efectos tóxicos secundarios y de la aparición de resistencia viral. Esto ha obligado a mantener la búsqueda constante de nuevos blancos terapéuticos que ofrezcan alternativas en la lucha contra esta pandemia. Hasta hace pocos años se creía que las proteínas accesorias y reguladoras del VIH1 no ejercían un papel significativo en el ciclo replicativo del virus y en la patogénesis de la infección; sin embargo, estudios recientes indican que estas proteínas ejercen funciones esenciales en diferentes etapas del proceso replicativo y por ende son responsables de muchos efectos asociados a la patogénesis viral. Por estos hallazgos, las proteínas accesorias y reguladoras del VIH-1 constituyen un blanco promisorio en el desarrollo de nuevos medicamentos que complementen los antirretrovirales disponibles en la actualidad. En esta revisión se describe la función de las proteínas reguladoras y accesorias del VIH-1 en el ciclo replicativo viral y su participación en el proceso patogénico de esta infección.
Since the discovery of HIV-1 as the etiological agent of the acquired immunodeficiency syndrome (AIDS), the main processes involved in its replication cycle and responsible for the complex physiopathology of this infection have been described. Despite the advances in the development of new antiretrovirals and their impact in the quality and life expectancy of infected individuals, the current therapy does not allow a complete immune reconstitution and is also associated with deleterious side effects and the appearance of viral resistance. Therefore the search for new therapeutic targets is required to face this pandemic. The role of the accessory and regulatory proteins of the HIV- 1 in the replication cycle and in the pathogenesis of the infection has been ignored for several years now; however, recent studies indicated that these proteins play essential roles in the replication cycle, being responsible for several processes associated to viral pathogenesis. These findings have underlined the importance of these proteins as promissory targets in the development of new therapeutic agents. In this review, we detailed the role of each one of the HIV-1s regulatory and accessory proteins in the replicative cycle and in the pathogenesis of this infection.