Modeling neuro-immune interactions during Zika virus infection.

Although Zika virus (ZIKV) infection is often asymptomatic, in some cases, it can lead to birth defects in newborns or serious neurologic complications in adults. However, little is known about the interplay between immune and neural cells that could contribute to the ZIKV pathology. To understand the mechanisms at play during infection and the antiviral immune response, we focused on neural precursor cells (NPCs)-microglia interactions. Our data indicate that human microglia infected with the current circulating Brazilian ZIKV induces a similar pro-inflammatory response found in ZIKV-infected human tissues. Importantly, using our model, we show that microglia interact with ZIKV-infected NPCs and further spread the virus. Finally, we show that Sofosbuvir, an FDA-approved drug for Hepatitis C, blocked viral infection in NPCs and therefore the transmission of the virus from microglia to NPCs. Thus, our model provides a new tool for studying neuro-immune interactions and a platform to test new therapeutic drugs.

A betabaculovirus encoding a gp64 homolog.

BACKGROUND: A betabaculovirus (DisaGV) was isolated from Diatraea saccharalis (Lepidoptera: Crambidae), one of the most important insect pests of the sugarcane and other monocot cultures in Brazil. RESULTS: The complete genome sequence of DisaGV was determined using the 454-pyrosequencing method. The genome was 98,392 bp long, which makes it the smallest lepidopteran-infecting baculovirus sequenced to date. It had a G + C content of 29.7% encoding 125 putative open reading frames (ORF). All the 37 baculovirus core genes and a set of 19 betabaculovirus-specific genes were found. A group of 13 putative genes was not found in any other baculovirus genome sequenced so far. A phylogenetic analysis indicated that DisaGV is a member of Betabaculovirus genus and that it is a sister group to a cluster formed by ChocGV, ErelGV, PiraGV isolates, ClanGV, CaLGV, CpGV, CrleGV, AdorGV, PhopGV and EpapGV. Surprisingly, we found in the DisaGV genome a G protein-coupled receptor related to lepidopteran and other insect virus genes and a gp64 homolog, which is likely a product of horizontal gene transfer from Group 1 alphabaculoviruses. CONCLUSION: DisaGV represents a distinct lineage of the genus Betabaculovirus. It is closely related to the CpGV-related group and presents the smallest genome in size so far. Remarkably, we found a homolog of gp64, which was reported solely in group 1 alphabaculovirus genomes so far.

Variability of the conserved v3 loop tip motif in hiv-1 subtype B isolates collected from brazilian and French patients.

The diversity of the V3 loop tip motif sequences of HIV-1 subtype B was analyzed in patients from Botucatu (Brazil) and Montpellier (France). Overall, 37 tetrameric tip motifs were identified, 28 and 17 of them being recognized in Brazilian and French patients, respectively. The GPGR (P) motif was predominant in French but not in Brazilian patients (53.5% vs 31.0%), whereas the GWGR (W) motif was frequent in Brazilian patients (23.0%) and absent in French patients. Three tip motif groups were considered: P, W, and non-P non-W groups. The distribution of HIV-1 isolates into the three groups was significantly different between isolates from Botucatu and from Montpellier (P < 0.001). A higher proportion of CXCR4-using HIV-1 (X4 variants) was observed in the non-P non-W group as compared with the P group (37.5% vs 19.1%), and no X4 variant was identified in the W group (P < 0.001). The higher proportion of X4 variants in the non-P non-W group was essentially observed among the patients from Montpellier, who have been infected with HIV-1 for a longer period of time than those from Botucatu. Among patients from Montpellier, CD4+ cell counts were lower in patients belonging to the non-P non-W group than in those belonging to the P group (24 cells/µL vs 197 cells/µL; P = 0.005). Taken together, the results suggest that variability of the V3 loop tip motif may be related to HIV-1 coreceptor usage and to disease progression. However, as analyzed by a bioinformatic method, the substitution of the V3 loop tip motif of the subtype B consensus sequence with the different tip motifs identified in the present study was not sufficient to induce a change in HIV-1 coreceptor usage.

Molecular characterization of human erythrovirus B19 strains obtained from patients with several clinical presentations in the Amazon region of Brazil.

BACKGROUND: Human erythrovirus B19, endemic in the Amazon region since 1990, is associated with a wide spectrum of clinical presentations. OBJECTIVES: To assess the prevalence of erythrovirus B19 infection and the relative frequency of erythrovirus B19 genotypes in patients in the Amazon region with various clinical presentations. STUDY DESIGN: A total of 487 clinical samples obtained from patients with symptoms suggestive of erythrovirus infection were tested using specific IgM and IgG antibody assays (ELISA) and PCR for viral DNA detection. Partial VP1 and VP2 regions were sequenced and genotyped by phylogenetic reconstruction. RESULTS: B19 DNA was detected in 117 (24%) of 487 samples. Of these, 106 (91%) isolates were genotype 1 and 11 (9%) were genotype 3. No genotype 2 was found. Genotype 1 had three clusters (A1, A2 and B) and all genotype 3 sequences were subtype 3b. All patients with hematological disorders within cluster B of genotype 1 were infected by the same B19 lineage, suggesting that this lineage of B19 may have been transmitted via transfusion of blood products. CONCLUSION: We reported two genotypes, 1 and 3b, with three genotype 1 clusters co-circulating in the Amazon region during the past 10 years.

A deep phylogeny of viral and cellular right-hand polymerases.

Right-hand polymerases are important players in genome replication and repair in cellular organisms as well as in viruses. All right-hand polymerases are grouped into seven related protein families: viral RNA-dependent RNA polymerases, reverse transcriptases, single-subunit RNA polymerases, and DNA polymerase families A, B, D, and Y. Although the evolutionary relationships of right-hand polymerases within each family have been proposed, evolutionary relationships between families remain elusive because their sequence similarity is too low to allow classical phylogenetic analyses. The structure of viral RNA-dependent RNA polymerases recently was shown to be useful in inferring their evolution. Here, we address evolutionary relationships between right-hand polymerase families by combining sequence and structure information. We used a set of 22 viral and cellular polymerases representing all right-hand polymerase families with known protein structure. In contrast to previous studies, which focused only on the evolution of particular families, the current approach allowed us to present the first robust phylogenetic analysis unifying evolution of all right-hand polymerase families. All polymerase families branched into discrete lineages, following a fairly robust adjacency pattern. Only single-subunit RNA polymerases formed an inner group within DNA polymerase family A. RNA-dependent RNA polymerases of RNA viruses and reverse transcriptases of retroviruses formed two sister groups and were distinguishable from all other polymerases. DNA polymerases of DNA bacteriophages did not form a monophyletic group and are phylogenetically mixed with cellular DNA polymerase families A and B. Based on the highest genetic variability and structural simplicity, we assume that RNA-dependent RNA polymerases are the most ancient group of right-hand polymerases, in agreement with the RNA World hypothesis, because RNA-dependent RNA polymerases are enzymes that could serve in replication of RNA genomes. Moreover, our results show that protein structure can be used in phylogenetic analyses of distantly related proteins that share only limited sequence similarity.

Tracing the origin and northward dissemination dynamics of HIV-1 subtype C in Brazil.

Previous studies indicate that the HIV-1 subtype C epidemic in southern Brazil was initiated by the introduction of a single founder strain probably originating from east Africa. However, the exact country of origin of such a founder strain as well as the origin of the subtype C viruses detected outside the Brazilian southern region remains unknown. HIV-1 subtype C pol sequences isolated in the southern, southeastern and central-western Brazilian regions (n = 209) were compared with a large number (n ~ 2,000) of subtype C pol sequences of African origin. Maximum-likelihood analyses revealed that most HIV-1 subtype C Brazilian sequences branched in a single monophyletic clade (CBR-I), nested within a larger monophyletic lineage characteristic of east Africa. Bayesian analyses indicate that the CBR-I clade most probably originated in Burundi and was introduced into the Paraná state (southern region) around the middle 1970s, after which it rapidly disseminated to neighboring regions. The states of Paraná and Santa Catarina have been the most important hubs of subtype C dissemination, and routine travel and spatial accessibility seems to have been the major driving forces of this process. Five additional introductions of HIV-1 subtype C strains probably originated in eastern (n = 2), southern (n = 2) and central (n = 1) African countries were detected in the Rio de Janeiro state (southeastern region). These results indicate a continuous influx of HIV-1 subtype C strains of African origin into Brazil and also unveil the existence of unrecognized transmission networks linking this country to east Africa.

Genomic comparison of Neodiprion sertifer and Neodiprion lecontei nucleopolyhedroviruses and identification of potential hymenopteran baculovirus-specific open reading frames.

Genomic comparison of Neodiprion sertifer nucleopolyhedrovirus (NeseNPV) and Neodiprion lecontei nucleopolyhedrovirus (NeleNPV) showed that the hymenopteran baculoviruses had features in common and were distinct from other, fully sequenced lepidopteran and dipteran baculoviruses. Their genomes were small in size (86,462 and 81,755 bp, respectively), had low G+C contents (33.8 and 33.3 mol%, respectively) and contained fewer open reading frames (ORFs) (90 and 89, respectively) than other baculoviruses. They shared 69 ORFs (48.6% mean amino acid identity overall), 43 of which were previously identified baculovirus homologues. The remaining shared ORFs could be common to other baculoviruses, but low amino acid identities precluded identifying them as such. Some may also be unique to hymenopteran baculoviruses. These included a trypsin-like protease, a zinc-finger protein, regulator of chromosome condensation proteins, a densovirus capsid-like protein and a phosphotransferase. Structural analysis, the presence of conserved domains and phylogenetic studies suggested that some of these ORFs may be functional and could have been transferred horizontally from an insect host. ORFs found only in NeseNPV and NeleNPV may play a role in host specificity and/or tissue tropism, as hymenopteran baculoviruses are restricted to the midgut. The genomes were basically collinear, but contained non-syntenic regions (NSRs) with large numbers of repeats between their polyhedrin and dbp genes. They differed from each other in the number of ORFs and the G+C content of their NSRs and the presence of homologous regions in the NeseNPV genome. NeleNPV also had a short inversion relative to NeseNPV. NeseNPV contained 21 ORFs not found in NeleNPV and NeleNPV had 20 ORFs not found in NeseNPV.

Identification and characterization of a baculovirus from Lonomia obliqua (Lepidoptera: Saturniidae).

A baculovirus has been isolated from larvae of Lonomia obliqua, a Saturniidae of medical importance due to a potent toxin found in their spines. Electron Microscopy analysis of the occlusion body obtained from diseased larvae showed polyhedra of approximately 1 microm in diameter containing multiple nucleocapsids per envelope. This baculovirus was thus named Lonomia obliqua multicapsid nucleopolyhedrovirus (LoobMNPV). Restriction endonuclease profiles of viral DNA digested with three restriction enzymes were obtained and the genome size was estimated to be 95.52 +/- 2.3 kbp. The polyhedrin gene of LoobMNPV was identified and its DNA sequence was determined. Phylogenetic analysis of the polyhedrin gene showed that the LoobMNPV polyhedrin belongs to group I NPV and that it is closely related to the polyhedrin of the NPV of Amsacta albistriga.