Zika virus infection during pregnancy protects against secondary infection in the absence of CD8+ cells.

While T cell immunity is an important component of the immune response to Zika virus (ZIKV) infection generally, the efficacy of these responses during pregnancy remains unknown. Here, we tested the capacity of CD8 lymphocytes to protect from secondary challenge in four macaques, two of which were depleted of CD8+ cells prior to rechallenge with a heterologous ZIKV isolate. The initial challenge during pregnancy produced transcriptional signatures suggesting complex patterns of immune modulation as well as neutralizing antibodies that persisted until rechallenge, which all animals efficiently controlled, demonstrating that the primary infection conferred adequate protection. The secondary challenge promoted activation of innate and adaptive immune cells, possibly suggesting a brief period of infection prior to clearance. These data confirm that ZIKV infection during pregnancy induces sufficient immunity to protect from a secondary challenge and suggest that this protection is not dependent on CD8 T cells.

Immune outcomes of Zika virus infection in nonhuman primates.

Although the Zika virus (ZIKV) epidemic is subsiding, immune responses that are important for controlling acute infection have not been definitively characterized. Nonhuman primate (NHP) models were rapidly developed to understand the disease and to test vaccines, and these models have since provided an understanding of the immune responses that correlate with protection during natural infection and vaccination. Here, we infected a small group of male rhesus (Macaca mulatta) and cynomolgus (Macaca fascicularis) macaques with a minimally passaged Brazilian ZIKV isolate and used multicolor flow cytometry and transcriptional profiling to describe early immune patterns following infection. We found evidence of strong innate antiviral responses together with induction of neutralizing antibodies and T cell responses. We also assessed the relative importance of CD8 T cells in controlling infection by carrying out CD8 T cell depletion in an additional two animals of each species. CD8 depletion appeared to dysregulate early antiviral responses and possibly increase viral persistence, but the absence of CD8 T cells ultimately did not impair control of the virus. Together, these data describe immunological trends in two NHP species during acute ZIKV infection, providing an account of early responses that may be important in controlling infection.

A Zika virus primary isolate induces neuroinflammation, compromises the blood-brain barrier and upregulates CXCL12 in adult macaques.

Zika virus (ZIKV) is a flavivirus that can cause neuropathogenesis in adults and fetal neurologic malformation following the infection of pregnant women. We used a nonhuman primate model, the Indian-origin Rhesus macaque (IRM), to gain insight into virus-associated hallmarks of ZIKV-induced adult neuropathology. We find that the virus causes prevalent acute and chronic neuroinflammation and chronic disruption of the blood-brain barrier (BBB) in adult animals. ZIKV infection resulted in specific short- and long-term augmented expression of the chemokine CXCL12 in the central nervous system (CNS)of adult IRMs. Moreover, CXCL12 expression persists long after the initial viral infection is apparently cleared. CXCL12 plays a key role both in regulating lymphocyte trafficking through the BBB to the CNS and in mediating repair of damaged neural tissue including remyelination. Understanding how CXCL12 expression is controlled will likely be of central importance in the definition of ZIKV-associated neuropathology in adults.

Postnatal Zika virus infection of nonhuman primate infants born to mothers infected with homologous Brazilian Zika virus.

Recent data in a nonhuman primate model showed that infants postnatally infected with Zika virus (ZIKV) were acutely susceptible to high viremia and neurological damage, suggesting the window of vulnerability extends beyond gestation. In this pilot study, we addressed the susceptibility of two infant rhesus macaques born healthy to dams infected with Zika virus during pregnancy. Passively acquired neutralizing antibody titers dropped below detection limits between 2 and 3 months of age, while binding antibodies remained detectable until viral infection at 5 months. Acute serum viremia was comparatively lower than adults infected with the same Brazilian isolate of ZIKV (n = 11 pregnant females, 4 males, and 4 non-pregnant females). Virus was never detected in cerebrospinal fluid nor in neural tissues at necropsy two weeks after infection. However, viral RNA was detected in lymph nodes, confirming some tissue dissemination. Though protection was not absolute and our study lacks an important comparison with postnatally infected infants born to naïve dams, our data suggest infants born healthy to infected mothers may harbor a modest but important level of protection from postnatally acquired ZIKV for several months after birth, an encouraging result given the potentially severe infection outcomes of this population.

Miscarriage and stillbirth following maternal Zika virus infection in nonhuman primates.

Zika virus (ZIKV) infection is associated with congenital defects and pregnancy loss. Here, we found that 26% of nonhuman primates infected with Asian/American ZIKV in early gestation experienced fetal demise later in pregnancy despite showing few clinical signs of infection. Pregnancy loss due to asymptomatic ZIKV infection may therefore be a common but under-recognized adverse outcome related to maternal ZIKV infection.

Fetal demise and failed antibody therapy during Zika virus infection of pregnant macaques.

Zika virus (ZIKV) infection of pregnant women is associated with pathologic complications of fetal development. Here, we infect pregnant rhesus macaques (Macaca mulatta) with a minimally passaged ZIKV isolate from Rio de Janeiro, where a high rate of fetal development complications was observed. The infection of pregnant macaques with this virus results in maternal viremia, virus crossing into the amniotic fluid (AF), and in utero fetal deaths. We also treated three additional ZIKV-infected pregnant macaques with a cocktail of ZIKV-neutralizing human monoclonal antibodies (nmAbs) at peak viremia. While the nmAbs can be effective in clearing the virus from the maternal sera of treated monkeys, it is not sufficient to clear ZIKV from AF. Our report suggests that ZIKV from Brazil causes fetal demise in non-human primates (NHPs) without additional mutations or confounding co-factors. Treatment with a neutralizing anti-ZIKV nmAb cocktail is insufficient to fully stop vertical transmission.

Influenza infection modulates vesicular trafficking and induces Golgi complex disruption.

Influenza A virus (IFV) replicates its genome in the nucleus of infected cells and uses the cellular protein transport system for genome trafficking from the nucleus to the plasma membrane. However, many details of the mechanism of this process, and its relationship to subsequent cytoplasmic virus trafficking, have not been elucidated. We examined the effect of nuclear transport inhibitors Leptomycin B (LB), 5,6 dichloro-1-ß-d-ribofuranosyl-benzimidazole (DRB), the vesicular transport inhibitor Brefeldin A (BFA), the caspase inhibitor ZWEHD, and microtubule inhibitor Nocodazole (NOC) on virus replication and intracellular trafficking of viral nucleoprotein (NP) from the nucleus to the ER and Golgi. Also, we carried out complementary studies to determine the effect of IFV on intracellular membranes. Inhibition of the CRM1 and TAP-P15 nuclear transport pathways by DRB and LB blocked completely the export of virus. Inhibition of vesicular trafficking by BFA, NOC, and ZWEHD also affected influenza infection. Interestingly, IFV infection induced fragmentation of the Golgi complex resulting in diffuse distribution of large and small vesicles throughout the cytoplasm. Live-cell microscopy revealed expansion of Golgi localization signals indicating progressive dispersion of Golgi positive structures, resulting in the disassembly of the Golgi ribbon structure. Other vesicular components (Rab1b, ARF1 and GBF1) were also found to be required for IFV infection. Furthermore, the exact step at which IFV infection disrupts vesicle trafficking was identified as the ER-Golgi intermediate compartment. These findings suggest that IFV NP is trafficked from the nucleus via the CRM1 and TAP pathways. IFV modulates vesicular trafficking inducing disruption of the Golgi complex. These studies provide insight on the ways in which IFV affects intracellular trafficking of different host proteins and will facilitate identification of useful pharmaceutical targets to abrogate virus replication.

Acute Viral Escape Selectively Impairs Nef-Mediated Major Histocompatibility Complex Class I Downmodulation and Increases Susceptibility to Antiviral T Cells.

Nef-specific CD8(+) T lymphocytes (CD8TL) are associated with control of simian immunodeficiency virus (SIV) despite extensive nef variation between and within animals. Deep viral sequencing of the immunodominant Mamu-B*017:01-restricted Nef165-173IW9 epitope revealed highly restricted evolution. A common acute escape variant, T170I, unexpectedly and uniquely degraded Nef's major histocompatibility complex class I (MHC-I) downregulatory capacity, rendering the virus more vulnerable to CD8TL targeting other epitopes. These data aid in a mechanistic understanding of Nef functions and suggest means of immunity-mediated control of lentivirus replication.

The triplet repeats of the Sin Nombre hantavirus 5' untranslated region are sufficient in cis for nucleocapsid-mediated translation initiation.

Hantavirus nucleocapsid protein (N) can replace the cellular cap-binding complex, eukaryotic initiation factor 4F (eIF4F), to mediate translation initiation. Although N can augment translation initiation of nonviral mRNA, initiation of viral mRNA by N is superior. All members of the Bunyaviridae family, including the species of the hantavirus genus, express either three or four primary mRNAs from their tripartite negative-sense genomes. The 5' ends of the mRNAs contain nonviral heterologous oligonucleotides that originate from endonucleolytic cleavage of cellular mRNA during the process of cap snatching. In the hantaviruses these caps terminate with a 3' G residue followed by nucleotides arising from the viral template. Further, the 5' untranslated region (UTR) of viral mRNA uniformly contains, near the 5' end, either two or three copies of the triplet repeat sequence, UAGUAG or UAGUAGUAG. Through analysis of a panel of mutants with mutations in the viral UTR, we found that the sequence GUAGUAG is sufficient for preferential N-mediated translation initiation and for high-affinity binding of N to the UTR. This heptanucleotide sequence is present in viral mRNA containing either two or three copies of the triplet repeat.

Identification of a region of hantavirus nucleocapsid protein required for RNA chaperone activity.

Sin Nombre hantavirus (SNV) is a New World hantavirus and causes hantavirus cardiopulmonary syndrome. The viral nucleocapsid protein (N) is an RNA chaperone and has multiple functions important in virus replication. The three negative sense RNA segments of hantaviruses form panhandle structures through imperfect hydrogen bonding of the 5' and 3' termini, and the chaperone activity of N can mediate correct panhandle formation. N also functions during transcription and translation initiation and the chaperone activity of N is likely to be involved in aspects of these processes. Using a series of mutations in the N gene we identified a region of N required for chaperone activity. The N-terminal 100 amino acids of N contain a domain that is both necessary and sufficient for RNA chaperone activity. We propose that this region of N may reside in one of two potential states. First, the region may be highly disordered and function in N-mediated RNA chaperone activity. Alternatively, in trimeric form, the region likely becomes ordered and serves in high affinity vRNA panhandle recognition.

Bunyavirus N: eIF4F surrogate and cap-guardian.

Hantaviruses comprise a genus of the bunyavirus family of viruses. Viruses of this family, along with the arenaviruses, and the orthomyxoviruses, including influenza, contain a negative sense, segmented RNA genome. Viral nucleocapsid proteins play a well-established role in the formation of intracellular and virion-associated nucleocapsids that harbor and shield viral genomic RNA. However, recent observations indicate that hantavirus nucleocapsid protein (N) has additional unexpected biological activities that interface with both the cellular mRNA translation and mRNA degradation apparatus. N has an activity that mimics or circumvents the cellular cap-binding complex, eIF4F, in the initial stages of translation initiation. As a consequence of its translation initiation activity, N can augment translational expression. In addition to its ability to enhance translation initiation, N co-localizes with the cellular peptides that mediate mRNA decay. mRNA decay often takes place in cytoplasmic processing bodies (P-bodies), and N is abundant in P bodies. The association of N with P bodies enables cap-snatching for viral transcription initiation. It is likely that these two surprising new activities of N function in concert during bunyavirus gene expression. All these activities of N revolve around the ability of N to recognize RNA in a correct, context-dependent manner.

A protein that replaces the entire cellular eIF4F complex.

The eIF4F cap-binding complex mediates the initiation of cellular mRNA translation. eIF4F is composed of eIF4E, which binds to the mRNA cap, eIF4G, which indirectly links the mRNA cap with the 43S pre-initiation complex, and eIF4A, which is a helicase necessary for initiation. Viral nucleocapsid proteins (N) function in both genome replication and RNA encapsidation. Surprisingly, we find that hantavirus N has multiple intrinsic activities that mimic and substitute for each of the three peptides of the cap-binding complex thereby enhancing the translation of viral mRNA. N binds with high affinity to the mRNA cap replacing eIF4E. N binds directly to the 43S pre-initiation complex facilitating loading of ribosomes onto capped mRNA functionally replacing eIF4G. Finally, N obviates the requirement for the helicase, eIF4A. The expression of a multifaceted viral protein that functionally supplants the cellular cap-binding complex is a unique strategy for viral mRNA translation initiation. The ability of N to directly mediate translation initiation would ensure the efficient translation of viral mRNA.

The bunyavirus nucleocapsid protein is an RNA chaperone: possible roles in viral RNA panhandle formation and genome replication.

Cellular RNA chaperones are crucial for the genesis of correctly folded functional RNAs. Using several complementary in vitro assays we find that the bunyavirus nucleocapsid protein (N) is an RNA chaperone. In the Bunyaviridae genomic RNA is in stable "panhandle" formation that arises through the hydrogen bonding of the terminal nucleotides of the RNA. The RNA chaperone function of N facilitates panhandle formation even though the termini are separated by >2 kb. RNA panhandle formation is likely driven by the exceptionally high base-pairing specificity of the terminal nucleotides as evidenced by P-num analysis. N protein can nonspecifically dissociate RNA duplexes. In addition, following panhandle formation, the RNA chaperone activity of N also appears to be involved in dissociation of the RNA panhandle and remains in association with the 5' terminus of the viral RNA following dissociation. Thus, N likely functions in the initiation of genome replication to allow efficient initiation of RNA synthesis by the viral polymerase. The RNA chaperone activity of N may be facilitated by an intrinsically disordered domain that catalyzes RNA unfolding driven by reciprocal entropy transfer. These observations highlight the essential features that are probably common to all RNA chaperones in which the role of the chaperone is to nonspecifically dissociate higher order structure and formation of functional higher order structure may often be predicted by RNA P-num value. The data also highlight features of N that are probably specifically important during replication of bunyavirus RNA.

Small glutamine-rich protein/viral protein U-binding protein is a novel cochaperone that affects heat shock protein 70 activity.

Molecular chaperone complexes containing heat shock protein (Hsp) 70 and Hsp90 are regulated by cochaperones, including a subclass of regulators, such as Hsp70 interacting protein (Hip), C-terminus of Hsp70 interacting protein (CHIP), and Hsp70-Hsp90 organizing factor (Hop), that contain tetratricopeptide repeats (TPRs), where Hsp70 refers to Hsp70 and its nearly identical constitutive counterpart, Hsc70, together. These proteins interact with the Hsp70 to regulate adenosine triphosphatase (ATPase) and folding activities or to generate the chaperone complex. Here we provide evidence that small glutamine-rich protein/viral protein U-binding protein (SGT/UBP) is a cochaperone that negatively regulates Hsp70. By "Far-Western" and pull-down assays, SGT/UBP was shown to interact directly with Hsp70 and weakly with Hsp90. The interaction of SGT/UBP with both these protein chaperones was mapped to 3 TPRs in SGT/UBP (amino acids 95-195) that are flanked by charged residues. Moreover, SGT/UBP caused an approximately 30% reduction in both the intrinsic ATPase activity of Hsc70 and the ability of Hsc70 to refold denatured luciferase in vitro. This negative effect of SGT/UBP on Hsc70 is similar in magnitude to that observed for the cochaperone CHIP. A role for SGT/UBP in protein folding is also supported by evidence that a yeast strain containing a deletion in the yeast homolog to SGT/UBP (delta SGT/UBP) displays a 50-fold reduction in recovery from heat shock compared with the wild type parent. Together, these results are consistent with a regulatory role for SGT/UBP in the chaperone complex.