Gamma irradiation of intravenous immunoglobulin.

This paper describes gamma irradiation of a biotherapeutic product under conditions (the Clearant Process") that protect proteins and foster inactivation of viruses and other pathogens. The treated product was immunoglobulin paste from cold ethanol fractionation of human plasma, a process intermediate in the production of intravenous immunoglobulin (IGIV). The frozen paste was irradiated on dry ice to 45 kGy, conditions that inactivate > or = 4 log10 of non-enveloped viruses and > or = 6 log10 of enveloped viruses. When IGIV purified from the irradiated paste was characterized, no protein aggregation, fragmentation, oxidation or denaturation was detected and Fab functionality remained intact.

Inactivation of viral and prion pathogens by gamma-irradiation under conditions that maintain the integrity of human albumin.

BACKGROUND AND OBJECTIVES: The administration of therapeutic plasma protein concentrates has been associated with the real risk of transmitting viral diseases and the theoretical risks of prion transmission. Our objective was to determine if gamma-irradiation can inactivate viral or prion infectivity without damaging a protein biotherapeutically. MATERIALS AND METHODS: Human albumin 25% solution, spiked with four model viruses (including porcine parvovirus) or with brain homogenate from scrapie-infected hamsters, was gamma-irradiated at constant low-dose rates and assayed for viral and prion infectivity or for albumin integrity. RESULTS: At a radiation dose of 50 kGy, viruses were inactivated by >/= 3.2 to >/= 6.4 log10 and scrapie by an estimated 1.5 log10, whereas albumin was only moderately aggregated and fragmented. CONCLUSIONS: gamma-Irradiation can preferentially inactivate viral and prion pathogens without excessive damage to albumin structure.

Environmental cues and gene expression in Porphyromonas gingivalis and Actinobacillus actinomycetemcomitans.

Microorganisms typically adapt to environmental cues by turning on and off the expression of virulence genes which, in turn, allows for optimal growth and survival within different environmental niches. This adaptation strategy includes sensing and responding to changes in nutrients, pH, temperature, oxygen tension, redox potential, microbial flora, and osmolarity. For a bacterium to adhere to, penetrate, replicate in, and colonize host cells, it is critical that virulence genes are expressed during certain periods of the infection process. Thus, throughout the different stages of an infection, different sets of virulence factors are turned on and off in response to different environmental signals, allowing the bacterium to effectively adapt to its varying niche. In this review, we focus on the regulation of virulence gene expression in two pathogens which have been implicated as major etiological agents in adult and juvenile periodontal diseases: Porphyromonas gingivalis and Actinobacillus actinomycetemcomitans. Understanding the mechanisms of virulence gene expression in response to the local environment of the host will provide crucial information in the development of effective treatments targeted at eradication of these periodontal disease pathogens.

Mutations in the retinoblastoma protein-binding LXCXE motif of rubella virus putative replicase affect virus replication.

The rubella virus (RV)-encoded protein NSP90, which contains the retinoblastoma protein (Rb)-binding motif LXCXE, interacts with Rb and RV replication is reduced in cells lacking Rb. Whether the LXCXE motif of RV NSP90 itself is essential for Rb binding and virus replication is not known. Therefore, in the present study, the functional role of this motif was investigated by site-directed mutagenesis in a plasmid from which infectious RV RNA can be produced. Three critical mutations in the motif, two substitutions at the conserved cysteine residue (C --> G and C --> R) and a deletion of the entire motif, were created. A cell-free translated NSP90 C terminus polypeptide containing the deletion did not bind to Rb and a polypeptide carrying the C --> R substitution had barely detectable binding affinity for Rb. Rb binding by the C --> G mutant was reduced significantly compared to that of wild-type protein. Correlating with the binding results, mutant viruses containing the LXRXE and LXGXE motifs had a reduction in replication to < 0.5% and 47% of the wild-type, respectively, while deletion of the motif was found to be lethal. By the first serial passage, replication of the LXRXE-carrying virus had increased from < 0.5% to 2% of the wild-type. Sequencing of the genome of this virus revealed a nucleotide change that altered the motif from LXRXE to LXSXE, which is a known Rb-binding motif in two protein phosphatase subunits. Thus, our results clearly demonstrate that the LXCXE motif is required for efficient RV replication.

The rubella virus putative replicase interacts with the retinoblastoma tumor suppressor protein.

In utero fetal infection of rubella virus (RV), a positive-stranded RNA virus, frequently induces birth defects if contracted in the first trimester of pregnancy. The underlying mechanism of RV-induced birth defects is not known. Birth defects are also common in certain DNA viral infections such as human cytomegalovirus (HCMV). During HCMV infection, one of its proteins interacts with a cell growth regulatory protein, the retinoblastoma protein (Rb) and stimulates DNA synthesis which is associated with chromosomal damage and cellular mitotic arrest. These affects have been implicated in HCMV induced teratogenesis. Since RV and HCMV both cause teratogenesis, we postulated that during RV infection, a virus-encoded protein might interact with Rb and affect fetal cell growth. In the present study, we have identified a known Rb-binding motif, L x C x E (LPCAE) in the carboxy-terminal half of the putative replicase (NSP90) of RV and demonstrated that the C-terminal region specifically binds to GST-Rb in vitro. Further, by coimmunoprecipitating NSP90 and Rb using specific antibodies to respective proteins, we have confirmed that NSP90 specifically binds to Rb in vivo as well. In addition, RV replication was shown to be less in null-mutant (Rb-/-) mouse embryonic fibroblast cells than in wild-type (Rb+/+) cells, suggesting a possible physiological role for this interaction. Thus, in facilitating RV replication, binding of NSP90 to Rb potentially alters the cell growth regulatory property of Rb, and this could be one of the initial steps in RV-induced teratogenesis.

Promoter mapping and transcriptional regulation of the iron-regulated Neisseria gonorrhoeae fbpA gene.

In this study, we have mapped the promoter region of the Neisseria gonorrhoeae ferric iron binding protein-encoding gene fbpA, determined the start point of transcription, and examined the accumulation of fbpA mRNA Primer extension analysis of the fbpA promoter region indicated a single transcriptional start site located 51 bp upstream of the ATG translational start site. Northern blot analysis with a 200-bp fbpA structural gene probe detected one transcript of 1.0 kb in RNAs extracted from gonococcal cultures grown under iron-restricted conditions; the 1.0-kb transcript was observed to accumulate at a steady rate throughout the growth cycle. In comparison, in cultures grown under iron-sufficient conditions, the intensity of the 1.0-kb transcript was reduced considerably. Isolation of total RNA from rifampin-treated cells indicated that the half-life of the 1.0-kb fbpA transcript in cells grown under iron-restricted conditions was 1.2 +/- 0.2 min, while that of the 1.0-kb fbpA transcript obtained from cultures grown under iron-sufficient conditions was 0.5 +/- 0.1 min. Taken together, our results indicate that the fbpA promoter is regulated by iron and that transcription and translation of FbpA are closely linked.

Analysis of the insertion characteristics of Tn4351 during high frequency transposition of Porphyromonas gingivalis.

In this study, we characterized the high frequency transfer of the Bacteroides fragilis transposon Tn4351 into the chromosome of Porphyromonas gingivalis using a system developed by Genco, et al. Using this system, transconjugants were isolated and genomic sequences analyzed using both Ava-I and EcoR1 to determine the insertion characteristics of Tn4351 into the genome of P. gingivalis. Although previous evidence pointed to the possibility of random insertion, this study shows that, in fact, the insertion characteristics of Tn4351 into the genome of P. gingivalis are nonrandom and predictable.

Characterization of a Tn4351-generated hemin uptake mutant of Porphyromonas gingivalis: evidence for the coordinate regulation of virulence factors by hemin.

The ability of Porphyromonas gingivalis to acquire iron in the iron-limited environment of the host is crucial to the colonization of this organism. We report here on the isolation and characterization of a transpositional insertion mutant of P. gingivalis A7436 (designated MSM-3) which is defective in the utilization and transport of hemin. P. gingivalis MSM-3 was selected on the basis of its nonpigmented phenotype on anaerobic blood agar following mutagenesis with the Bacteroides fragilis transposon Tn4351. P. gingivalis MSM-3 grew poorly when supplied with hemin as a sole source of iron; however, growth was observed with hemoglobin or inorganic iron. P. gingivalis MSM-3 grown in either hemin-replete or hemin-depleted conditions bound and transported less [14C]hemin or [59Fe]hemin than did the parent strain. At 4 h, P. gingivalis MSM-3 grown in hemin-replete conditions transported only 10,000 pmol of hemin per mg of protein, or 14% of the amount transported by P. gingivalis A7436. Unlike P. gingivalis A7436, hemin binding and transport by P. gingivalis MSM-3 were not tightly regulated by hemin or iron. Examination of P. gingivalis MSM-3 cultures by electron microscopy revealed an overproduction of membrane vesicles, and determination of the dry weight of purified vesicles indicated that P. gingivalis MSM-3 produced twice as much membrane vesicles as did strain A7436. Extracellular vesicles isolated from P. gingivalis MSM-3 also were found to express increased hemolytic and trypsin-like protease activities compared with the parent strain. When inoculated into subcutaneous chambers implanted in mice, P. gingivalis MSM-3 was highly infectious and more invasive than the parent strain, as indicated by secondary lesion formation and death. Taken together, these results indicate that the decreased transport of hemin by P. gingivalis MSM-3 results in the increased expression of several virulence factors which may be coordinately regulated by hemin.

Resistance of a Tn4351-generated polysaccharide mutant of Porphyromonas gingivalis to polymorphonuclear leukocyte killing.

In this study, we describe the development of an efficient transpositional mutagenesis system for Porphyromonas gingivalis using the Bacteroides fragilis transposon Tn4351. Using this system, we have isolated and characterized a Tn4351-generated mutant of P. gingivalis A7436, designated MSM-1, which exhibits enhanced resistance to polymorphonuclear leukocyte (PMN) phagocytosis and killing. P. gingivalis MSM-1 was initially selected based on its colony morphology; MSM-1 appeared as a mucoid, beige-pigmented colony. Analysis of P. gingivalis MSM-1 by electron microscopy and staining with ruthenium red revealed the presence of a thick ruthenium red-staining layer that was twice the thickness of this layer observed in the parent strain. P. gingivalis MSM-1 was found to be more hydrophilic than strain A7436 by hydrocarbon partitioning. Analysis of phenol-water extracts prepared from P. gingivalis A7436 and MSM-1 by Western (immunoblot) analysis and immunodiffusion with hyperimmune sera raised against A7436 and MSM-1 revealed the loss of a high-molecular-weight anionic polysaccharide component in extracts prepared from MSM-1. P. gingivalis MSM-1 was also found to be more resistant to PMN phagocytosis and intracellular killing than the parent strain, as assessed in a fluorochrome phagocytosis microassay. These differences were statistically significant (P < 0.05) when comparing PMN phagocytosis in nonimmune serum and intracellular killing in nonimmune and immune sera. P. gingivalis MSM-1 was also more resistant to killing by crude granule extracts from PMNs than was P. gingivalis A7436. These results indicate that the increased evasion of PMN phagocytosis and killing exhibited by P. gingivalis MSM-1 may result from alterations in polysaccharide-containing antigens.

Identification of the rubella virus nonstructural proteins.

Five segments of the rubella virus (RUB) nonstructural protein open reading frame (NSP-ORF) were cloned into pATH (trpE) bacterial fusion protein expression plasmid vectors. Antisera raised in rabbits against these fusion proteins were used to identify RUB nonstructural polypeptides in lysates from RUB-infected Vero cells and from BHK cells transfected with pTM3/nsRUB, a vector from which the RUB NSP-ORF is expressed. In both systems, three polypeptides were immunoprecipitated. A 200-kDa polypeptide (P200) was immunoprecipitated by all of the antisera and therefore is the primary translation product of the ORF. A 150-kDa polypeptide (P150) was immunoprecipitated by antisera against fusion proteins containing N-terminal regions of the ORF, and a 90-kDa polypeptide (P90) was immunoprecipitated by sera against fusion proteins containing C-terminal regions of the ORF. The order of these polypeptides within the NSP-ORF is thus NH2-P150-P90-COOH. It was shown in a previous study that a protease within P200 catalyzes cleavage of P200 (L. D. Marr et al., Virology 198, 586-592, 1994). When hypertonic block was used to synchronize initiation of translation in RUB-infected cells, P200 was detected within 10 min following release of the block, while P150 and P90 were not detected until 20 min, indicating that translation of the precursor is completed before proteolytic cleavage occurs. Pulse-chase experiments showed that cleavage of the P200 precursor was complete within 90 min of synthesis. P150 was stable for 24 hr following processing, while turnover of P90 was detected within 90 min. In immunofluorescence experiments on RUB-infected cells, antisera that recognized P150 stained a perinuclear focus, a thread-like cytoplasmic structure, and the nuclear membrane.

Time course of virus-specific macromolecular synthesis during rubella virus infection in Vero cells.

Virus specific macromolecular synthesis was studied in Vero cells infected with plaque-purified rubella virus under one-step multiplication conditions. Under these conditions, the rate of virus production was found to increase rapidly until 24 hr postinfection after which time the rate of virus production rose more slowly, reaching a peak level at 48 hr postinfection. This peak rate of virus production was maintained through 72 hr postinfection. A majority of the cells remained alive through 96 hr postinfection, although a 20 to 30% decrease in the number of living cells occurred between 24 and 48 hr postinfection, the time period at which cytopathic effect was first observed. The virus structural proteins were first detected intracellularly at 16 hr postinfection. The rate of synthesis of these proteins was already maximal at 16 hr postinfection and remained constant through 48 hr postinfection. By immunofluorescence, cells expressing virus proteins were first observed at 12 hr postinfection. At 24 hr postinfection, 35 to 50% of the cells in the infected culture were exhibiting immunofluorescence, at 36 hr postinfection, 65 to 90% of the cells were exhibiting immunofluorescence, and at 48 hr postinfection, all of the cells were exhibiting immunofluorescence. The virus genomic and subgenomic RNA species were first detectable by 12 hr postinfection. The rate of synthesis of both of these species peaked at 26 hr postinfection. Rubella virus infection was found to have no effect on total cell RNA synthesis. However, a modest inhibition of total cell protein synthesis which reached 40% by 48 hr postinfection was observed. When Northern analysis of RNA extracted from infected cells was performed, a negative-polarity, virus-specific RNA probe hybridized only to the virus genomic and subgenomic RNA species. A positive-polarity, virus-specific RNA probe hybridized predominantly to a negative-polarity RNA of genome length indicating that both the genomic and subgenomic RNAs are synthesized from a genome-length negative-polarity template. Defective interfering (DI) RNAs were not detected in infected cells through 96 hr postinfection or in cells onto which virus released through 96 hr postinfection was passaged. Thus, the generation of DI particles by rubella virus appears to play no role in the slow, noncytopathic replication of this virus or in the ability of rubella virus-infected cells to survive for extended periods of time.