Mid-infrared doping tunable transmission through subwavelength metal hole arrays on InSb.

Doping-tunable mid-infrared extraordinary transmission is demonstrated from a periodic metal hole array patterned on n-InSb. The polarization-dependent transmission was measured at room temperature and 77 K. In addition, the extraordinary transmission was measured for incident angles from 0 degrees to 35 degrees in 5 degrees steps. A fundamental resonance shift of approximately 123 cm-1 (1.4 microm) is observed by varying the doping from 1 x 10(16) to 2 x 10(18) cm(-3). The calculated transmission resonances were in good agreement with the experimental results. This suggests that InSb semiconductor-based plasmonic structures may be suitable for a variety of tunable mid-infrared device applications.

Loss mechanisms in mid-infrared extraordinary optical transmission gratings.

The optical properties of periodic arrays of subwavelength apertures in metal films on GaAs substrates are studied. Specifically, geometric and material losses for these plasmonic structures are characterized using angular dependent transmission, normal incidence reflection, and angular dependent diffraction experiments, in addition to a crossed-polarizer transmission experiment. The optical properties of the samples as a function of engineered material losses are studied. Using this comprehensive approach to the characterization of the plasmonic structures, we are able to identify and isolate specific loss mechanisms, as well as identify the effect of free carriers on the optical properties of the structures.

The satellite RNA of barley yellow dwarf virus-RPV is supported by beet western yellows virus in dicotyledonous protoplasts and plants.

The subgroup II luteovirus barley yellow dwarf virus-RPV (BYDV-RPV) acts as a helper virus for a satellite RNA (satRPV RNA). The subgroup II luteovirus beet western yellows virus (BWYV) and the ST9-associated RNA (ST9a RNA), a BWYV-associated RNA that encodes a polymerase similar to those of subgroup I luteoviruses, were assayed for their ability to support replication of satRPV RNA. SatRPV RNA was replicated in tobacco protoplasts in the presence of BWYV RNA or a mixture of BWYV plus the ST9a RNA, but not in the presence of ST9a RNA alone. ST9a RNA stimulated BWYV RNA accumulation which, in turn, increased the accumulation of satRPV RNA. SatRPV RNA was encapsidated in BWYV capsids primarily as circular monomers, which differs from the linear monomers found in BYDV (RPV + PAV) particles. SatRPV RNA was transmitted to Capsella bursa-pastoris plants by aphids only in the presence of BWYV and ST9a RNA. SatRPV RNA reduced accumulation of both BWYV helper and ST9a nonhelper RNAs in plants but did not affect symptoms. The replication of satRPV RNA only in the presence of subgroup II luteoviral RNAs but not in the presence of RNAs with subgroup I-like polymerase genes, in both monocotyledonous and dicotyledonous hosts, suggests that the specificity determinants of satRPV RNA replication are contained within the polymerase genes of supporting viruses rather than in structural genes or host plants.

Trace amount of satellite RNA associated with tobacco ringspot virus: increase stimulated by nonaccumulating satellite RNA mutants.

The small satellite RNA of tobacco ringspot virus (sTRSV RNA) is dependent on tobacco ringspot virus (TRSV) for replication and encapsidation. sTRSV RNA has appeared during serial passage of certain TRSV strains in some hosts. Co-inoculation of bean with TRSV and either of two related, nonaccumulating mutants of sTRSV RNA induced the appearance of sTRSV RNA in a single passage (van Tol et al., 1991, Virology 180, 23-30). The sTRSV RNA obtained after serial passage and after co-inoculation have the same nucleotide sequence, designated the endogenous sequence. The endogenous sTRSV RNA nucleotide sequence differs from that of each of the nonaccumulating sTRSV RNA at three positions. In order to detect possible trace amounts of endogenous satellite RNA in virion RNA preparations, RNA from two TRSV isolates was subjected to reverse transcription and polymerase chain reaction of the transcript (RT-PCR), using primers with sTRSV RNA terminal sequences. The yield of RT-PCR product suggests that the virion RNA preparations contained approximately 0.1 fg of sTRSV RNA per microgram of virion RNA. The nucleotide sequence of the RT-PCR product corresponded to that of the endogenous sTRSV RNA. The endogenous sTRSV RNA of TRSV inocula appears to be latent, being maintained in very small amounts during serial passage of TRSV in some hosts but capable of dramatic increase during serial passage in other hosts or when TRSV was co-inoculated with either of two specific sTRSV RNA mutants. Ten other nonaccumulating sTRSV RNA mutants did not induce a detected increase in sTRSV RNA.

Symptom severity of beet western yellows virus strain ST9 is conferred by the ST9-associated RNA and is not associated with virus release from the phloem.

The ST9 strain of beet western yellows virus (BWYV ST9) is unique among BWYV strains because it encapsidates not only its 5.6-kb genomic RNA but also a 2.8-kb RNA of distinct nucleotide sequence, designated as the ST9-associated RNA. We obtained isolates of BWYV ST9 that are free of the associated RNA by transfecting Nicotiana tabacum protoplasts with transcripts of an ST9 genomic cDNA clone. Aphids were fed on extracts of infected protoplasts and were transferred to young Shepherd's Purse (Capsella bursa-pastoris) plants. When the protoplast inoculum was ST9 genomic transcript or virion RNA of the L-1 strain of BWYV (free of the associated RNA), symptoms were mild and characteristic of BWYV L-1. When ST9-associated RNA was included in the inoculum with genomic RNA of either source, subsequently infected Shepherd's Purse plants showed the severe symptoms that are characteristic of BWYV ST9. Inclusion of ST9-associated RNA in the inoculum with ST9 genomic RNA increased the accumulation of capsid antigen and ST9 genomic RNA, relative to infections initiated with ST9 genomic RNA alone. Using gold-labeled antibody and electron microscopy, we assessed the distribution of virions in Shepherd's Purse plants. Regardless of whether the associated RNA was present, sites showing immunoreactivity above background levels were restricted to the phloem, suggesting that the increased BWYV ST9 titer and symptom severity that are correlated with the presence of the ST9-associated RNA are not due to escape of the infection from phloem limitation.

Beet western yellows virus-associated RNA: an independently replicating RNA that stimulates virus accumulation.

Infections of plants by subviral RNA agents, alone or in association with virus genomic RNA molecules, are well known. The ST9 strain of beet western yellows virus encapsidates not only the 5.6-kilobase genomic RNA that is typical of luteoviruses, but also a 2.8-kilobase-associated RNA that has a distinct nucleotide sequence. The ST9-associated RNA has been postulated to be a satellite RNA, which by definition would be capable of replicating only in coinfections with beet western yellows virus or closely related viruses. To characterize the associated RNA, we inoculated protoplasts and leaves with in vitro transcripts of the virus genomic RNA and the ST9-associated RNA separately and in combination. Surprisingly, the ST9-associated RNA alone replicated efficiently in both protoplasts and leaves, and it stimulated accumulation of the virus genomic RNA in protoplasts. Thus, the ST9-associated RNA is a newly discovered type of plant infectious agent, which depends on its associated virus, beet western yellows virus, for encapsidation but not for replication.

Similar structure and reactivity of satellite tobacco ringspot virus RNA obtained from infected tissue and by in vitro transcription.

The 359 nucleotide residue (nt) satellite RNA of tobacco ringspot virus increases detectably only in association with replicating tobacco ringspot virus and becomes encapsidated in the virus coat protein. Results from previous reports are consistent with participation of rolling circle transcription in replication of the satellite RNA: (i) both the more abundant plus polarity satellite RNA, s(+)RNA and the complementary s(-)RNA occur in multimeric forms that self-cleave to release the unit length, 359 nt satellite RNA, (ii) circles of both s(+)RNA and s(-)RNA are present in extracts of infected tissue, and (iii) s(-)RNA, but not s(+)RNA, spontaneously and efficiently circularizes in vitro. Our analyses of RNA in tissue extracts suggest that s(+)RNA of all forms is about 100-fold more abundant than s(-)RNA. Nucleic acids were purified rapidly to minimize interconversion of linear and circular forms. For s(+)RNA and for s(-)RNA, the circular and the linear forms were detected in about equal amounts in tissue extracts. The linear s(-)RNA from tissue extracts was found to have the same 5'-terminal sequence as previously was found for s(-)RNA self-cleaved from in vitro transcripts. Like s(-)RNA synthesized in vitro, the circular and linear s(-)RNA from tissue extracts spontaneously and readily interconverted during incubation in vitro. In contrast, the bulk of the circular and linear forms of s(+)RNA were stable. The very limited interconversion of s(+)RNA forms in vitro suggests that circulation in vivo is enzymically catalyzed. Encapsidated satellite RNA was found to be composed of linear, unit length and multimeric forms, including previously undocumented s(-)RNA present in approximately the same relative abundance compared to s(+)RNA as was observed for RNA from tissue extracts. Circles were not detected in encapsidated RNA. We interpret our results in the context of a rolling circle model for satellite RNA replication.