Literatura académica sobre el tema "Cytomegaloviruses – Molecular aspects"

Human cytomegalovirus infection of the developing fetus is a leading cause of neurodevelopmental disorders in infants and children, leading to long-term neurological sequela in a significant number of infected children. Current understanding of the neuropathogenesis of this intrauterine infection is limited because of the complexity of this infection, which includes maternal immunological responses that are overlaid on virus replication in the CNS during neurodevelopment. Furthermore, available data from human cases are observational, and tissues from autopsy studies have been derived from only the most severe infections. Animal models of this human infection are also limited by the strict species specificity of cytomegaloviruses. However, informative models including non-human primates and small animal models have been developed. These include several different murine models of congenital HCMV infection for the study of CMV neuropathogenesis. Although individual murine models do not completely recapitulate all aspects of the human infection, each model has provided significant information that has extended current understanding of the neuropathogenesis of this human infection. This review will compare and contrast different murine models in the context of available information from human studies of CNS disease following congenital HCMV infections.

Clinical and experimental data indicate that a subset of innate lymphocytes, natural killer (NK) cells, plays a crucial role in the response against herpesviruses, especially cytomegaloviruses (CMV). Indeed, in mice, NK cells, due to the expression of germline encoded Ly49 receptors, possess multiple mechanisms to recognize CMV infection. Classically, this results in NK cell activation and the destruction of the infected cells. More recently, however, this unique host-pathogen interaction has permitted the discovery of novel aspects of NK cell biology, implicating them in the regulation of adaptive immune responses as well as in the development of immunological memory. Here, we will concisely review the newly acquired evidence pertaining to NK cell Ly49-dependent recognition of MCMV-infected cell and the ensuing NK cell regulatory responses.

Cytomegaloviruses (CMVs) are highly adapted to their host species resulting in strict species specificity. Hence, in vivo examination of all aspects of CMV biology employs animal models using host-specific CMVs. Infection of rhesus macaques (RM) with rhesus CMV (RhCMV) has been established as a representative model for infection of humans with HCMV due to the close evolutionary relationships of both host and virus. However, the only available RhCMV clone that permits genetic modifications is based on the 68–1 strain which has been passaged in fibroblasts for decades resulting in multiple genomic changes due to tissue culture adaptations. As a result, 68–1 displays reduced viremia in RhCMV-naïve animals and limited shedding compared to non-clonal, low passage isolates. To overcome this limitation, we used sequence information from primary RhCMV isolates to construct a full-length (FL) RhCMV by repairing all mutations affecting open reading frames (ORFs) in the 68–1 bacterial artificial chromosome (BAC). Inoculation of adult, immunocompetent, RhCMV-naïve RM with the reconstituted virus resulted in significant viremia in the blood similar to primary isolates of RhCMV and furthermore led to high viral genome copy numbers in many tissues at day 14 post infection. In contrast, viral dissemination was greatly reduced upon deletion of genes also lacking in 68–1. Transcriptome analysis of infected tissues further revealed that chemokine-like genes deleted in 68–1 are among the most highly expressed viral transcripts both in vitro and in vivo consistent with an important immunomodulatory function of the respective proteins. We conclude that FL-RhCMV displays in vitro and in vivo characteristics of a wildtype virus while being amenable to genetic modifications through BAC recombineering techniques.

Congenital viral infectious diseases are characterized by polyetiologic pathology holding an important place in the structure of perinatal losses. Due to the wide distribution and lack of specific prophylaxis, the problem of herpesvirus infections is of greatest interest, namely of herpes infection caused by herpes simplex virus type 1 and 2, human herpes simplex virus type 6 and cytomegalovirus infection, as well as parvovirus infection B19. The opportunities to investigate a relation between manifestations of the infectious process and host molecular genetic characteristics have been expanded after developing full genome sequencing methods and creating genetic data international banks. It has been proven that herpes virus genetic variations can account for related neurovirulence, showing that diverse cytomegalovirus genotypes are associated with hepatosplenomegaly, hearing impairment and the symptoms of the central nervous system diseases. Nevertheless, the data on correlation between genotypes and clinical manifestations are still scarce and contradictory, whereas high level of variability becomes extremely evident while comparing genomic sequences of viral strains. The herpesvirus type 6 has been proven to integrate into germ cells with potential for subsequent vertical transmission of chromosomally integrated virus to the offspring and its further intergeneration inheritance. А direct relationship between B19V genospecies and disease manifestations including congenital infections has not yet been identified. Taking into account possible differences in the geographical distribution of such viruses on the territory of the Russian Federation, ethnic populational characteristics, and high frequency of related congenital infectious diseases with a wide range of clinical manifestations, it seems promising to expand scientific research on the genotyping of herpes simplex viruses, cytomegalovirus, herpes viruses type 6 and parvovirus B19V in Russia. The results of such studies will be demanded by practical healthcare in order to develop and use more effective etiotropic drugs and specific prophylaxis in the light of trends to develop personalized and preventive medicine.

The application of modern biochemical techniques has led to a rapid improvement in our knowledge of the molecular biology of CMV. Several coding regions of the DNA genome have been identified with certainty and major virus-coded proteins have been given provisional names. The cascade expression of the CMV genome has been shown to be controlled by mechanisms similar to those found in other herpes viruses, together with novel post-transcriptional controls which remain to be defined. The control of CMV replication by the host involves both non-specific and specific defence mechanisms. The induction of natural killer cells and interferon early after CMV infection appears to be the most important aspects of the non-specific host defence against the virus. The cell-mediated immune response, in particular the generation of Tc cells against CMV early antigens, is probably the most important facet of the specific immune defence against CMV. When intact these defence mechanisms appear to be efficient in restricting viral replication; however, when such immunity is compromised, the balance rapidly swings in favour of the virus. As our understanding of the interaction between the host and the virus increases, it may be possible to redress the balance in such cases in favour of the host.

SUMMARY Cytomegalovirus (CMV) is an important pathogen in transplant recipients and human immunodeficiency virus (HIV)-infected individuals. Major progress has been made in developing quantitative detection methods for CMV in recent years. Due to their high sensitivity, these assays can detect CMV early, and quantitation may be useful in predicting the patient’s risk for disease and in monitoring the effect of antiviral therapy. This review discusses methodological aspects of currently used quantitative assays for CMV (i.e., viral culture techniques, antigen detection assays, DNA detection assays including PCR, branched-DNA assay, and the DNA hybrid capture assay) and addresses the correlation of systemic and site-specific CMV load and CMV disease in different populations of immunosuppressed patients as well as the response to antiviral treatment. To date, direct antigen detection and molecular techniques have largely replaced traditional culture-based techniques for CMV quantitation. In general, a high systemic CMV load is correlated with CMV disease. This correlation is strong in the HIV-infected population and in solid-organ transplant recipients but less clear in allogeneic marrow transplant recipients. Measuring the viral load at specific anatomic sites may be an alternative way to assess disease activity in situations where the systemic viral load correlates poorly with disease activity. A reduction of the systemic CMV load also correlates with a response to antiviral treatment, but more research is needed to evaluate the role of viral load as a surrogate marker for drug resistance. Due to the widespread use of quantitative CMV detection techniques to direct and monitor antiviral treatment, there is a great need for an assessment of the reproducibility of test results and better standardization of the assays.

Cytomegalovirus (CMV) species have been gaining attention as experimental vaccine vectors inducing cellular immune responses of unparalleled strength and protection. This review outline the strengths and the restrictions of CMV-based vectors, in light of the known aspects of CMV infection, pathogenicity and immunity. We discuss aspects to be considered when optimizing CMV based vaccines, including the innate immune response, the adaptive humoral immunity and the T-cell responses. We also discuss the antigenic epitopes presented by unconventional major histocompatibility complex (MHC) molecules in some CMV delivery systems and considerations about routes for delivery for the induction of systemic or mucosal immune responses. With the first clinical trials initiating, CMV-based vaccine vectors are entering a mature phase of development. This impetus needs to be maintained by scientific advances that feed the progress of this technological platform.

HIV infection is commonly associated with activation and dissemination of several other viral pathogens, including herpes simplex virus 1/2, human cytomegalovirus, human herpesvirus 8, Epstein-Barr virus, Varicella Zoster virus, and human papillomavirus, which behave as opportunistic agents and cause various diseases in immunocompromised hosts. The increased frequency and severity of diseases caused by these viruses in HIV-infected individuals is due mainly to dysfunction of both the adaptive and innate immune responses to viral pathogens. In addition, molecular interactions between HIV and these opportunistic viruses are likely to play critical roles in the progression of disease, including neoplasia. This report reviews the critical aspects of HIV interaction with opportunistic viruses, including Epstein-Barr virus, human cytomegalovirus, herpes simplex virus, Varicella Zoster virus, human herpesvirus 8, and human papillomavirus.

[Truncated abstract] The design and development of effective anti-viral immunotherapies requires a comprehensive understanding of the cellular and molecular processes that are involved in the generation and regulation of immune responses. The fundamental objective of the immune system is to successfully complete the task of eliminating/controlling the invading pathogen without causing overt pathology. Cytomegaloviruses (CMVs) are large DNA viruses that are able to evade immune attack and persist lifelong within the host. In a healthy host, CMV causes an asymptomatic infection, but in instances of decreased immune functions, such as in newborns, acquired immunodeficiency syndrome (AIDS) patients and transplant recipients, the infection can result in serious morbidity and mortality. Thus, human CMV (HCMV) is a clinically important pathogen and an understanding of the pathogenesis, mechanisms of immune subversion and, importantly the cascade of immune events that ensue following infection is highly relevant. The studies presented in this thesis have provided useful insight into various aspects of viral immunity and it is hoped that they will assist in the design of more effective therapies against viruses of clinical importance. Genetic variability in humans can greatly influence anti-viral immune responses and the outcome of viral infection. ... Furthermore, these studies provide novel evidence that NK cells are also crucial for the control of virus in some organs of susceptible mice during early acute infection. The data reveals that both NK cells and CD8+ T cells utilise perforin- and IFN-? dependent control of MCMV. Furthermore, these studies provide novel evidence that protection mediated by Ly49H+ NK cells in resistant mice is dependent on perforin. Chapter 3 focuses on the biological relevance of Grz during MCMV infection. These studies found that GrzA and GrzB are essential components of the machinery involved in limiting MCMV during acute infection. These analyses also provide the first evidence suggesting that GrzM plays a role, albeit minor, in controlling MCMV replication. Furthermore, the current studies suggest that Grz can mediate direct antiviral activities independent of the induction of cell death in conjunction with perforin. Interestingly, in the absence of both GrzA and GrzB (GrzAB), mice were as susceptible to MCMV infection as perforin-deficient mice. However, unlike perforin-deficient mice, GrzAB-deficient mice controlled and survived the infection. In Chapter 4 the roles of perforin, GrzA and GrzB in anti-viral immunity and immunopathology during MCMV infection were examined. These studies show that NK cell-derived perforin is required to eliminate infected targets as well as activated effector cells, suggesting that NK cells are crucial not only in defensive immunity but also in limiting the immune activation that follows MCMV infection. In summary, the studies presented in this thesis define the significant role played by specific effector molecules in limiting MCMV replication during different stages of this viral infection. Furthermore, these studies provide novel evidence that perforin, GrzA and GrzB play distinct roles in defensive immunity and limiting immunopathology during MCMV infection.

Cytomegaloviruses (CMVs) are ubiquitous in nature, having evolved over many millenia with their hosts. While in healthy hosts most infections with CMV are asymptomatic, the virus can cause severe disease in immunocompromised hosts. Thus, the increase in organ transplantation and the HIV/AIDS pandemic have established human CMV (HCMV) as a clinically important pathogen. Indeed, HCMV infections are now the major cause of morbidity and mortality among immunocompromised patients, which has led to more research targeting CMV for effective anti-viral treatment. The discovery that cytomegaloviruses encode several genes which are involved in immune escape has prompted a new area of research, aimed at understanding immune escape mechanisms for exploitation as potential anti-viral therapeutics. By targeting the viral proteins directly, or their receptors in the host, it may be possible to treat CMV disease by agonistic/antagonistic therapy. The first part of this thesis describes the first demonstration of anti-NK1.1 staining in situ to identify NK cells using a modified in vivo perfusion/fixation method. Using this method, we have compared the acute NK1.1+ cellular response to wild-type MCMV infection in the visceral organs of genetically susceptible intra-NK complex recombinant BALB.B6-CT6 (Cmv1s, NK1.1+) mice with resistant C57B⁄J (Cmv1r, NK1.1+) and BALB.B6-Cmv1r mice (Cmv1r, NK1.1+). Expression of viral antigens and the consequences of infection on other cellular subsets, were also analyzed in this study. The data show that in susceptible mice (Cmv1s) MCMV infection is predominent in the marginal zone of splenic white pulp, resulting in local changes in various cellular constituents, including macrophages, NK cells and DC. In the liver, distinct foci of infection were comprised of large numbers of macrophages and NK1.1+ cells surrounding infected cytomegalic cells. In resistant mice (Cmv1r), 6 MCMV infection predominantly affected the red-pulp of the spleen and was associated with increased accumulation of NK1.1+ cells and macrophages at sites of viral infection

Cytomegalovirus (CMV) is a ubiquitous pathogen affecting over 95% of the world’s population. While infection is typically asymptomatic in healthy individuals, the virus persists life-long in its host and can be reactivated following withdrawal of immune control. As such, it remains a serious clinical concern in individuals who are immunocompromised, such as newborns and neonates, transplant and/or chemotherapy recipients, and HIV/AIDS patients. CMV also has the ability to cause immunosuppression, the mechanisms of which include defective antigen presentation to T cells and interference with haematopoiesis in the bone marrow (BM). Due to strict species specificity, murine CMV (MCMV) provides a relevant model for the study of CMV modulation of the immune system in vivo in its natural host. The type I interferons (IFNs) represent a major family of cytokines involved in the early response to MCMV infection. Their anti-viral activity and regulation of NK cell activation and cytotoxicity are of significant interest in the context of MCMV infection, as genetic resistance to MCMV is mediated by the ability of Ly49H+ NK cells to directly recognise and lyse infected cells. Chapter 2 comprises an analysis of acute MCMV infection in the absence of type I IFN activity. These studies were conducted in IFNAR1 and IFNAR2 deficient mice, which lack components of the type I IFN receptor. Data obtained from these studies confirmed the essential requirement for type I IFN in controlling viral titres, promoting expansion of splenic Ly49H+ NK cells, and inducing early activation of NK cell cytotoxicity. In addition, our data depicted an accumulation of infected myeloid cells in the absence of effective NK cell-mediated control. This was paralleled by a significant increase in the level of serum TNF-a and IFN-¿, an effect which in some cases has been linked to serious pathological disease. Thus, the data described in this chapter provide an insight into the consequences arising from delayed NK cell responses to MCMV infection in the absence of type I IFN. vii Type I IFN can also potentially affect BM haematopoiesis. BM atrophy and impairment of myelopoiesis are serious consequences of CMV infection. During acute MCMV infection we consistently observed a profound loss of splenic dendritic cells (DCs) in BALB/c mice. Since all DC subsets are derived from BM haematopoietic progenitor cells, the possibility that MCMV might interfere with BM haematopoiesis and DC differentiation was explored. Chapters 3 and 4 describe the impact of acute MCMV infection on BM progenitors, with particular emphasis on the differentiation capabilities of these cells in ex vivo culture systems. Chapter 3 focuses on the effect of MCMV infection on BM cellularity and frequency of specific BM progenitor populations. A thorough analysis of contributing factors, such as viral infection of BM cells, involvement of type I and II IFNs, progenitor cell trafficking and NK cell activity in the BM compartment, was conducted. Our results showed that a severe loss of BM cellularity occurs in MCMV-infected mice. Furthermore, when BM cells from MCMV-infected mice were cultured ex vivo in granulocyte macrophage-colony stimulating factor (GM-CSF), there was an impairment in their ability to differentiate into DCs.

Orientador: Sandra Cecilia Botelho Costa
Tese (doutorado) - Universidade Estadual de Campinas, Faculdade de Ciencias Medicas
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Resumo: O Citomegalovírus Humano (HCMV) continua sendo uma causa significante de morbidade em pacientes imunocomprometidos, especialmente em transplantados de medula óssea, e pode manifestar diversas complicações que incluem hepatite, doença gastrointestinal e pneumonia intersticial ou a denominada "Síndrome Viral por HCMV"caracterizada por febre, leucopenia e trombocitopenia. O HCMV pode também ter um efeito imuno-modulador, fazendo da infecção por esse vírus um fator de risco importante para o desenvolvimento de rejeição ao enxerto aguda e crônica e para co-infecção com outras herpesviroses. A detecção do genoma do HCMV pela PCR (Reação em Cadeia da Polimerase) é específica e sensível, e pode ser usada como uma poderosa ferramenta para o diagnóstico precoce da infecção causada por este vírus. Variações em regiões funcionalmente relevantes do genoma do HCMV têm sido utilizadas como marcadores genéticos em diversos estudos clínicos para diferenciar as linhagens do vírus e associá-las com a patogênese viral e com as manifestações clínicas no paciente. A glicoproteína B (gB) é a maior glicoproteína do envelope do HCMV e tem sido relacionada à entrada na célula hospedeira, transmissão célula-a-célula, e conseqüentemente à fusão das células infectadas. A amplificação do gene gB pela PCR combinada com análise de restrição por RFLP em regiões polimórficas deste gene são eficientes para a identificação dos genótipos do HCMV, tornando possível a distinção de pelo menos 4 padrões eletroforéticos. Por outro lado, a determinação da carga viral em pacientes imunologicamente afetados tem sido associada como marcador ou preditor do desenvolvimento de doença por HCMV órgão-específica. Sendo assim, a determinação da carga viral, especificamente nestes pacientes, é fundamental para a supervisão da terapia antiviral. Além disso, os valores da carga viral estão relacionados aos níveis de imunossupressão, à patogênese do HCMV e ao grupo de pacientes e/ou ao tipo de transplante e podem indicar o início da administração da terapia antiviral.O método de real-time PCR (RT-PCR) foi aplicado para a quantificação do genoma do HCMV em amostras clínicas e a detecção e posterior quantificação do DNA do HCMV em amostras de soro por esta técnica é capaz de distinguir entre pacientes com infecções sintomáticas daqueles com infecções inativas ou latente.Avanços têm sido feitos na prevenção da doença por HCMV após o transplante de medula óssea, inclusive a administração profilática, por períodos prolongados, de antivirais como o Acyclovir e o Ganciclovir e como conseqüência, pode originar linhagens resistentes relacionadas principalmente a dois genes virais: a fosfotransferase viral (UL97) e a DNA polimerase viral (UL54). Sabendo-se da importância da identificação das linhagens do HCMV em pacientes transplantados de medula óssea e da possível relação com a infecção e apresentação clínica; da relevância em determinar a carga viral como preditor de doença; e finalmente, da detecção de linhagens resistentes aos agentes antivirais disponíveis, este estudo avaliou, prospectivamente, pacientes transplantados de medula óssea em seguimento no Hemocentro/UNICAMP. Além disso, teve como principais objetivos: determinar a prevalência dos genótipos do HCMV e avaliar uma possível associação com a apresentação clínica nesses pacientes; determinar a carga viral para o monitoramento da terapia antiviral; e identificar e correlacionar mutações que conferem resistência ao Ganciclovir com carga viral e apresentação clínica. Foram incluídas na casuística, 169 amostras de DNA de sangue periférico e 187 amostras de DNA de soro de 22 pacientes transplantados de medula óssea. Dentre as 47 amostras de DNA de sangue periférico HCMV positivas, 42 foram genotipadas e observamos a prevalência do genótipo gB1 (47%) como descrito em literatura, e embora sem comprovação estatística, notamos a tendência deste genótipo com melhor prognóstico. Aplicamos a RT-PCR em 96 amostras de DNA de soro de 12 pacientes transplantados de medula óssea seguidos no Ambulatório de Hematologia, e observamos que o método é adequado para a avaliação da carga viral neste grupo de pacientes. No entanto, é necessário estabelecer um valor de corte a fim de se utilizar esta metodologia para obtenção de um valor que seja preditivo de doença e para o monitoramento do tratamento dos pacientes. Este método mostrou-se mais preciso que a ?nested?-PCR no mesmo tipo de amostra. Além disso, identificamos 8 novas mutações no gene UL97, uma delas pode estar relacionada à resistência viral ao Ganciclovir. Dentre os polimorfismos identificados, 3 parecem estar relacionados ao genótipo gB1 e possivelmente podem ser utilizadas como marcadores genéticos para a genotipagem do HCMV. Para o gene UL54 foram identificadas 5 novas mutações na região IV do gene e que geralmente é relacionada à resistência ao Ganciclovir. Nós concluímos que a determinação da carga viral é importante, mas não é o único modo de avaliar a eficiência do tratamento antiviral. Dessa forma, a avaliação de outros parâmetros moleculares, como a genotipagem e mutações relacionadas à resistência aos antivirais, são informações complementares e devem ser consideradas para o monitoramento da evolução clínica em pacientes transplantados de medula óssea
Abstract: Human Cytomegalovirus (HCMV) remains a significant cause of morbidity in immunocompromised patients, especially in bone marrow transplant recipients. It may manifest severe complications including hepatitis, gastrointestinal disease, and interstitial pneumonitis or as so-called ?HCMV viral syndrome? with fever, leukopenia, and thrombocytopenia. The HCMV may also has an immunomodulatory effect, potentially making HCMV infection an important risk factor for the development of an acute and chronic allograft rejection and for coinfection with other herpesviruses. The detection of the HCMV genome by PCR (Polymerase Chain Reaction) is specific and sensitive. Besides this, it can be used as a powerful tool for the early diagnoses of the infection caused by this virus. Variations in functionally relevant areas of the HCMV genome have been used as genetic markers in numerous clinical studies to differentiate the HCMV strains and to associate them with the viral pathogenesis further with the patients? clinical manifestations. The glycoprotein B (gB) is the major glycoprotein of HCMV?s envelope and it has been implicated in host cell entry, cell-to-cell virus transmission, consequently in the fusion of infected cells. The gB amplification by PCR combined with the restriction analysis by RFLP in polymorphic areas are effective for the identification of the HCMV genotypes, becoming possible the distinction of at least 4 electrophoretic patterns. On the other hand, the determination of the viral load in the immunologically affected patients has been associated as marker or predictor for the development of the organ specific disease by the HCMV. Hence, the determination of the viral load in these specific patients is fundamental for the management of the antiviral therapy. In addition, the viral load values are related to levels of the immune-suppression, the pathogenesis of the HCMV and the group of patients and/or the type of transplant. Furthermore, the viral load values can indicate the beginning of the antiviral therapy administration. A real-time PCR (RT-PCR) assay was applied for quantifying the HCMV genome load in clinical samples and the detection and quantification of HCMV DNA in blood serum through RT-PCR are able to distinguish patients with symptomatic infections among those with latent or inactive infections. Advances have been made in the prevention of HCMV disease after bone marrow transplantation, including prophylactic administration of antivirals such as Acyclovir and Ganciclovir. The HCMV prophylaxis with antiviral in this patients? group is administered for prolonged periods of therapy, consequently it can originate resistant viruses related mainly to two genes: the viral phosphotransferase (UL97) and the viral DNA polymerase (UL54). Ahead the importance of the identification of HCMV strains in bone marrow transplant patients, the HCMV strains performance in the patients? infection and clinical presentation, the relevance of determinating the viral load as a disease predictor, and finally, the detection of the resistant strains to the available antivirals, this study prospectively evaluated bone marrow transplant recipients followed at Hemocentro/UNICAMP. Moreover, it had as main goals: to determine the prevalence of the HCMV gB genotypes, to evaluate a possible gB genotype association with the patients? clinical presentation; to determinate the viral load for monitoring the antiviral therapy, and to correlate Ganciclovir resistant mutations in UL97 and UL54 gene with the viral load and patients? clinical presentation. From 22 bone marrow transplant recipients, DNA samples of peripheral blood (169) and DNA samples of blood serum (187) were included in this casuistic. Among 47 HCMV positive samples, 42 were genotyped. We observed the prevalence of gB1 genotype (47%), as described in the specific literature, however without statistical analysis, the raw data exhibited that gB1 genotype can be related to patients? better prognostics. From 12 followed bone marrow transplant recipients, we applied the RT-PCR in 96 DNA blood serum samples and we observed that the method was accurate for the viral load evaluation in this patients? group. However, it is necessary to establish a crucial cutoff to consider whether a specific value of viral load is a predictive value to cause HCMV disease and to monitor the patients? treatment. This method was more precise than the nested-PCR for blood serum samples. Additionally, we identified 8 new mutations in UL97 gene, one of them can be related to Ganciclovir HCMV resistance. Among all of identified polymorphisms, 3 of them can be related to gB1 genotype and may be used as genetic marker to HCMV genotyping. In the region IV of the UL54 gene, 5 new mutations were identified, and can possibly be related to Ganciclovir HCMV resistance. We concluded that the determination of the patients? viral load is crucial, even so it is not the only way to evaluate the antiviral treatment efficacy. Then, the evaluation of other molecular parameters as genotyping and mutations related to the HCMV antiviral resistance, are complementary information and must be considered to monitor the clinical evolution of bone marrow transplant recipients
Doutorado
Ciencias Basicas
Doutor em Clínica Médica