Remembrance of immunology past: conversations with Herman Eisen.

Herman Eisen and Sondra Schlesinger spent several days together in September 2007 in Woods Hole, Massachusetts, talking about immunology, focusing on his remembrances of the field over the more than 60 years of his involvement. This article is an abridged version of those discussions (the full version is available on the Annual Reviews website). It is both an oral history and a written memory of some important but selected areas of immunology.

Increased replicative fitness of a dengue virus 2 clade in native mosquitoes: potential contribution to a clade replacement event in Nicaragua.

UNLABELLED: The four dengue virus (DENV) serotypes (DENV serotype 1 [DENV-1] to DENV-4) are transmitted by Aedes aegypti and A. albopictus mosquitoes, causing up to 390 million DENV infections worldwide each year. We previously reported a clade replacement of the DENV-2 Asian-American genotype NI-1 clade by the NI-2B clade in Managua, Nicaragua. Here, we describe our studies of the replicative ability of NI-1 and NI-2B viruses in an A. aegypti cell line (Aag2) and A. aegypti mosquitoes reared from eggs collected in Managua. In coinfection experiments, several different pairs of NI-1 and NI-2B clinical isolates were used to infect Aag2 cells or blood-fed A. aegypti mosquitoes. Results consistently showed a significant replicative advantage of NI-2B over NI-1 viruses early after infection in vitro, and in mosquitoes, NI-2B viruses attained a higher replicative index than NI-1 isolates 3 to 7 days postinfection (dpi). At 7 dpi, NI-2B viruses displayed a significantly higher replicative index in legs and salivary glands; however, this advantage was lost by 14 and 21 dpi. We also found that the percentage of mosquitoes in which NI-2B viruses were dominant was significantly higher than that in which NI-1 viruses were dominant on day 7 but not at later time points. Taken together, these data demonstrate that clade NI-2B holds a replicative advantage over clade NI-1 early in infection that wanes at later time points. This early fitness advantage of NI-2B viruses over NI-1 viruses in the native vector, A. aegypti, suggests a shorter extrinsic incubation period for NI-2B viruses, which could have contributed to the clade replacement event in Managua. IMPORTANCE: Dengue virus (DENV), one of the most medically important arthropod-borne viruses, is transmitted to humans by Aedes aegypti and A. albopictus mosquitoes in tropical and subtropical regions worldwide. Dengue epidemics continue to increase in frequency, geographic range, and severity and are a major public health concern. This is due to globalization, unplanned urbanization, and climate change, as well as host genetics and immune responses and viral genetic changes. DENV consists of four serotypes, in turn composed of genotypes and genetically distinct clades. What drives the frequent replacement of a previously circulating DENV clade by another is unclear. Here, we investigate the replicative fitness of two clades of DENV serotype 2 in Aedes aegypti cells and mosquitoes collected from the region where the viruses circulated and conclude that increased replicative fitness could have contributed to a DENV clade replacement event in Nicaragua. These findings provide insight into vector-driven evolution of DENV epidemics.

Properties of Sindbis virus vectors produced with a chimeric split helper system.

We have evaluated a chimeric, two-component Sindbis virus packaging system. As expected, use of this combination of two modified helper RNA species prevented formation of infection competent Sindbis viruses as analyzed by serial passaging. We observed, however, that vectors produced using this method were able to spread in BHK cell cultures and formed clusters of transgene positive cells that did not display cytopathic effects for up to 3 days post-transduction. Formation of spreading Sindbis virus vectors required only one of the helper components--the chimera with a deleted Ross River virus capsid and the Sindbis virus envelope glycoproteins. Spreading was also demonstrated in two rat glioma cell lines, 9L and BT4C, showing that this phenomenon was not limited to BHK cells. Our results warrant further characterization of split helper Sindbis virus vectors and imply their utility in gene therapy approaches where spreading of transgene expression and consequently high gene transfer rate could be beneficial.

Sindbis vector SINrep(nsP2S726): a tool for rapid heterologous expression with attenuated cytotoxicity in neurons.

Sindbis virus-based vectors have been successfully used for transient heterologous protein expression in neurons. Their main limitation arises from infection-associated cytotoxicity, attributed largely to a progressive shut down of host cell protein synthesis. Here we evaluated a modified Sindbis vector, based on a viral strain containing a point mutation in the second nonstructural protein, nsP2 P726S, described to delay inhibition of protein synthesis in BHK cells [Virology 228 (1997) 74], for heterologous expression in neurons in vitro and in vivo. First, we constructed an optimized helper vector, termed DH-BB(tRNA/TE12), for production of SINrep(nsP2S(726)) viral particles with low levels of helper RNA co-packaging and high neurospecificity of infection. Second, we determined that hippocampal primary neurons infected with SINrep(nsP2S(726)) virus expressing EGFP showed a delayed onset of viral induced cytotoxicity and higher levels of EGFP expression in comparison to cells infected with wild type SINrep5 EGFP-expressing virus. However, a strong decrease in protein synthesis still occurred by day 3 postinfection. The SINrep(nsP2S(726)) vector is thus well suited for rapid high level expression within this time window. As an experimental example, we demonstrate the applicability of this system for high-resolution two-photon imaging of dendritic spines in vivo.

Alphaviruses: Semliki forest virus and Sindbis virus vectors for gene transfer into neurons.

Alphaviral vectors based on Semliki Forest virus and Sindbis virus infect many host cell types, causing rapid and high-level transgene expression. In the CNS, Semliki Forest virus and Sindbis virus exhibit an outstanding preference for neurons rather than glial cells, compared to other viruses. Generation of high-titer virus stocks is rapid (less than two days) and typically requires biosafety level 1 or 2 containment. Wild-type vectors are cytotoxic, permitting short-term transgene expression. However, mutant vectors with decreased cytotoxicity, to prolong host cell survival, have been developed. They also increase transgene expression and cellular co-infection, permitting heteromeric protein expression in individual cells. In addition, mutants with temperature-dependent control of transgene expression and altered host cell preference to target interneurons and astrocytes rather than principal neurons are available. Other alphavirus vectors based on Venezuelan equine encephalitis and Eastern equine encephalitis virus replicons have been engineered, too. Alphavirus vectors have been successfully used not only in neuroscience, but also for other applications including drug discovery, structural biology, vaccine development, and cancer therapy.

cis-acting genomic elements and trans-acting proteins involved in the assembly of RNA viruses.

There is now considerable evidence that a specific site (or sites) in the genome of an RNA virus interacts with a viral protein to initiate the assembly of the virus ribonucleoprotein or nucleocapsid. We describe the progress that has been made in defining these elements for a number of different viruses: the togavirus, Sindbis virus; the coronavirus, mouse hepatitis virus; influenza A virus; several retroviruses; and the hepadnavirus, hepatitis B virus. The importance of cis-acting elements in packaging has been established for all of these viruses. For Sindbis virus, specificity in the binding of the RNA element to a region of the viral capsid protein in vitro has also been demonstrated.

Alphavirus cDNA-based expression vectors: effects of RNA transcription and nuclear export.

The construction of layered DNA-RNA replicons has facilitated and expanded the use of alphavirus vectors to vaccine development, construction of packaging cell lines and long-term heterologous gene expression. In these vector systems, the alphavirus replicon is under the control of a strong RNA polymerase II promoter and replicon RNA is transcribed from DNA before transport to the cytoplasm. Efficient RNA amplification catalyzed by the viral replicase results in high levels of mRNA and the recombinant protein. Recently, we developed a temperature-regulated Sindbis replicon-based DNA expression system characterized by a linear increase of expression upon decrease of the temperature from 37 degrees C to 29 degrees C. Modifications known to affect transcription and nuclear export of RNA led to a 5-fold increase in expression in BHK cells and up to over 80-fold increase in CHO cells and BF fibroblasts in transient transfection experiments. Furthermore, reducing cell proliferation resulted in a further 2- to 3-fold higher expression. While increased expression per cell was responsible for some of the enhanced production, it was primarily the number of expressing cells that made the difference in most cell lines. Further experiments indicated that a threshold amount of replicon RNA had to reach the cytoplasm in order for replication to occur. Thus, alterations that improve transcription, nuclear export and stability of the RNA had a significant impact on protein production in the pCytTS expression system and probably in other layered DNA-based viral vectors. Furthermore the results indicate that RNA replication is differentially regulated in DNA layered RNA replicons versus viral infection.