Cold chain and virus‐free oral polio booster vaccine made in lettuce chloroplasts confers protection against all three poliovirus serotypes

To prevent vaccine‐associated paralytic poliomyelitis, WHO recommended withdrawal of Oral Polio Vaccine (Serotype‐2) and a single dose of Inactivated Poliovirus Vaccine (IPV). IPV however is expensive, requires cold chain, injections and offers limited intestinal mucosal immunity, essential to prevent polio reinfection in countries with open sewer system. To date, there is no virus‐free and cold chain‐free polio vaccine capable of inducing robust mucosal immunity. We report here a novel low‐cost, cold chain/poliovirus‐free, booster vaccine using poliovirus capsid protein (VP1, conserved in all serotypes) fused with cholera non‐toxic B subunit (CTB) expressed in lettuce chloroplasts. PCR using unique primer sets confirmed site‐specific integration of CTB‐VP1 transgene cassettes. Absence of the native chloroplast genome in Southern blots confirmed homoplasmy. Codon optimization of the VP1 coding sequence enhanced its expression 9–15‐fold in chloroplasts. GM1‐ganglioside receptor‐binding ELISA confirmed pentamer assembly of CTB‐VP1 fusion protein, fulfilling a key requirement for oral antigen delivery through gut epithelium. Transmission Electron Microscope images and hydrodynamic radius analysis confirmed VP1‐VLPs of 22.3 nm size. Mice primed with IPV and boosted three times with lyophilized plant cells expressing CTB‐VP1co, formulated with plant‐derived oral adjuvants, enhanced VP1‐specific IgG1, VP1‐IgA titres and neutralization (80%–100% seropositivity of Sabin‐1, 2, 3). In contrast, IPV single dose resulted in <50% VP1‐IgG1 and negligible VP1‐IgA titres, poor neutralization and seropositivity (<20%, <40% Sabin 1,2). Mice orally boosted with CTB‐VP1co, without IPV priming, failed to produce any protective neutralizing antibody. Because global population is receiving IPV single dose, booster vaccine free of poliovirus or cold chain offers a timely low‐cost solution to eradicate polio.     

A vision of a world without polio: the OPV cessation strategy.

Once the eradication of wild poliovirus has been confirmed, the public health benefits of routine immunization with OPV will no longer outweigh the burden of disease either due to paralysis caused by OPV (vaccine associated paralytic polio), or by outbreaks caused by circulating vaccine-derived polioviruses. The eventual cessation of OPV use in routine immunization programmes worldwide will become necessary to assure a lasting eradication of polio. As the world moves towards polio eradication and its certification, preparations are therefore being intensified for OPV cessation, and the risk management framework for safe OPV cessation is being put in place. The framework includes bio-containment of all known poliovirus and potentially infected substances, development of an international stockpile of oral polio vaccine, ensuring a mechanism for continued global surveillance and response for polio after eradication has been certified, and national policies if countries decide to continue vaccinating with inactivated polio vaccine (IPV). It is ironic that the vaccine on which the world has depended for polio eradication will itself become a risk to eradication once the transmission of wild poliovirus has been interrupted. Final preparations for the eventual global and simultaneous cessation of OPV will require the same level of international cooperation and coordination that has brought the world to the verge of polio eradication.     

Induction of mucosal immunity by inactivated poliovirus vaccine is dependent on previous mucosal contact with live virus

The inactivated poliovirus vaccine (IPV) is used for protection against poliomyelitis in The Netherlands. It is not clear, however, whether IPV vaccination can lead to priming of the mucosal immune system and the induction of IgA. It has been demonstrated that IPV vaccination is able to induce strong memory IgA responses in the serum of persons who have been naturally exposed to wild-type poliovirus. This has led to the hypothesis that IPV vaccination is able to induce poliovirus-specific IgA at mucosal sites in persons who have been previously primed with live poliovirus at mucosal sites. To test this hypothesis, the kinetics of the IgA response in serum and saliva after IPV vaccination were examined in persons previously vaccinated with oral poliovirus vaccine (OPV) or IPV. ELISA and enzyme-linked immunospot assays were used for the detection of poliovirus-specific IgA responses. In addition, B cell populations were separated on the basis of the expression of mucosal (alpha4beta7 integrin) and peripheral homing receptors (L-selectin). Parenteral IPV vaccination was able to boost systemic and mucosal IgA responses in previously OPV-vaccinated persons only. None of the previously vaccinated IPV recipients responded with the production of IgA in saliva. In agreement with this finding, a large percentage of the poliovirus-specific IgA-producing lymphocytes detected in previous OPV recipients expressed the alpha4beta7 integrin. It is concluded that IPV vaccination alone is insufficient to induce a mucosal IgA response against poliovirus. In mucosally (OPV-) primed individuals, however, booster vaccination with IPV leads to a strong mucosal IgA response.     

Systematic Review of Mucosal Immunity Induced by Oral and Inactivated Poliovirus Vaccines against Virus Shedding following Oral Poliovirus Challenge

Inactivated poliovirus vaccine (IPV) may be used in mass vaccination campaigns during the final stages of polio eradication. It is also likely to be adopted by many countries following the coordinated global cessation of vaccination with oral poliovirus vaccine (OPV) after eradication. The success of IPV in the control of poliomyelitis outbreaks will depend on the degree of nasopharyngeal and intestinal mucosal immunity induced against poliovirus infection. We performed a systematic review of studies published through May 2011 that recorded the prevalence of poliovirus shedding in stool samples or nasopharyngeal secretions collected 5–30 days after a “challenge” dose of OPV. Studies were combined in a meta-analysis of the odds of shedding among children vaccinated according to IPV, OPV, and combination schedules. We identified 31 studies of shedding in stool and four in nasopharyngeal samples that met the inclusion criteria. Individuals vaccinated with OPV were protected against infection and shedding of poliovirus in stool samples collected after challenge compared with unvaccinated individuals (summary odds ratio [OR] for shedding 0.13 (95% confidence interval [CI] 0.08–0.24)). In contrast, IPV provided no protection against shedding compared with unvaccinated individuals (summary OR 0.81 [95% CI 0.59–1.11]) or when given in addition to OPV, compared with individuals given OPV alone (summary OR 1.14 [95% CI 0.82–1.58]). There were insufficient studies of nasopharyngeal shedding to draw a conclusion. IPV does not induce sufficient intestinal mucosal immunity to reduce the prevalence of fecal poliovirus shedding after challenge, although there was some evidence that it can reduce the quantity of virus shed. The impact of IPV on poliovirus transmission in countries where fecal-oral spread is common is unknown but is likely to be limited compared with OPV.     

Environmental Poliovirus Surveillance during Oral Poliovirus Vaccine and Inactivated Poliovirus Vaccine Use in Córdoba Province,Argentina

This study compares the presence of environmental poliovirus in two Argentinean populations using oral poliovirus vaccine (OPV) or inactivated poliovirus vaccine (IPV). From January 2003 to December 2005, Córdoba City used IPV in routine infant immunizations, with the exception of intermittent OPV use in August 2005. Between May 2005 and April 2006, we collected weekly wastewater samples in Córdoba City and the province''s three major towns, which continued OPV use at all times. Wastewater samples were processed and analyzed for the presence of poliovirus according to WHO guidelines. During the months of IPV use in Córdoba City, the overall proportion of poliovirus-positive samples was 19%. During an intermittent switch from IPV to OPV, this proportion increased to 100% within 2 months. During the 3 months when IPV was reintroduced to replace OPV, a substantial proportion of samples (25%) remained positive for poliovirus. In the OPV-using sites, on average, 54% of samples were poliovirus positive. Seventy-seven percent of poliovirus isolates showed at least one mutation in the VP1-encoding sequence; the maximum genetic divergence from the Sabin strain was 0.7%. Several isolates showed mutations on attenuation markers in the VP1-encoding sequence. The frequency or type of virus mutation did not differ between periods of IPV and OPV use or by virus serotypes. This study indicates that the sustained transmission of OPV viruses was limited during IPV use in a middle-income country with a temperate climate. The continued importation of poliovirus and genetic instability of vaccine strains even in the absence of sustained circulation suggest that high poliovirus vaccine coverage has to be maintained for all countries until the risk of reintroduction of either wild or vaccine-derived poliovirus is close to zero worldwide.In the context of the near achievement of poliomyelitis eradication and anticipated cessation of oral poliovirus (PV) vaccine (OPV), the World Health Organization (WHO) has recommended the use of inactivated PV vaccine (IPV) in countries that have IPV production facilities or other countries where immunization programs fulfill certain financial and logistic criteria (37). IPV has been shown to be safe and immunogenic in children in both developed and developing countries.(34) IPV diminishes the excretion of PV by children challenged with the Sabin strain of PV only moderately. The questions of whether and to which extent Sabin PV that is reintroduced into a population immunized with IPV could establish circulation, mutate to vaccine-derived PV (VDPV), and consequently cause poliomyelitis remain important. No such emergence of VDPV in developed countries using IPV has been reported. However, suboptimal hygienic conditions and insufficient vaccine coverage in middle- or low-income countries could favor the establishment of PV circulation after reintroduction, as indicated by recent VDPV outbreaks in populations with low OPV coverage (27, 38).Argentina currently uses OPV in the childhood immunization program according to recommendations from the Pan-American Health Organization. The last case of poliomyelitis due to wild-type PV was reported in Argentina in 1984 and in Córdoba Province in 1971 (24). In Córdoba City, the capital of Córdoba Province, standalone IPV (Imovax Polio; Sanofi Pasteur) replaced OPV (Polioral; Novartis Vaccines) in the routine childhood immunization program (2, 4, and 6 months of age plus a booster at 18 months age) from 1 January 2003 to 31 December 2005, while the surrounding provinces continued to use OPV. Due to an IPV shortage between 10 August and 7 September 2005, OPV was used in the capital during this period. We conducted environmental PV surveillance in Córdoba Province from May 2005 to April 2006 to describe environmental PV circulation and molecular characteristics of PV depending on the vaccine used. In the present evaluation, we also describe the dynamic of PV circulation around the change of IPV-OPV-IPV-OPV in the capital. This observation can contribute evidence regarding the dynamics of PV circulation and its implication for global immunization policy after polio eradication.     

Human Circulating Antibody-Producing B Cell as a Predictive Measure of Mucosal Immunity to Poliovirus

Background

The “gold standard” for assessing mucosal immunity after vaccination with poliovirus vaccines consists in measuring virus excretion in stool after challenge with oral poliovirus vaccine (OPV). This testing is time and resource intensive, and development of alternative methods is a priority for accelerating polio eradication. We therefore evaluated circulating antibody-secreting cells (ASCs) as a potential means to evaluate mucosal immunity to poliovirus vaccine.

Methods

199 subjects, aged 10 years, and previously immunized repeatedly with OPV, were selected. Subjects were assigned to receive either a booster dose of inactivated poliovirus vaccine (IPV), bivalent OPV (bOPV), or no vaccine. Using a micro-modified whole blood-based ELISPOT assay designed for field setting, circulating poliovirus type-specific IgA- and IgG-ASCs, including gut homing α4β7+ ASCs, were enumerated on days 0 and 7 after booster immunization. In addition, serum samples collected on days 0, 28 and 56 were tested for neutralizing antibody titers against poliovirus types 1, 2, and 3. Stool specimens were collected on day 28 (day of bOPV challenge), and on days 31, 35 and 42 and processed for poliovirus isolation.

Results

An IPV dose elicited blood IgA- and IgG-ASC responses in 84.8 to 94.9% of subjects, respectively. In comparison, a bOPV dose evoked corresponding blood ASC responses in 20.0 to 48.6% of subjects. A significant association was found between IgA- and IgG-ASC responses and serum neutralizing antibody titers for poliovirus type 1, 2, 3 (p<0.001). In the IPV group, α4β7⁺ ASCs accounted for a substantial proportion of IgA-ASCs and the proportion of subjects with a positive α4β7⁺ IgA-ASC response to poliovirus types 1, 2 and 3 was 62.7%, 89.8% and 45.8%, respectively. A significant association was observed between virus excretion and α4β7⁺ IgA^- and/or IgG-ASC responses to poliovirus type 3 among immunized children; however, only a weak association was found for type 1 poliovirus.

Discussion

Our results suggest that virus-specific blood ASCs, especially for type 3 poliovirus, can serve as surrogate of mucosal immunity after vaccination. Further studies are needed to evaluate the duration of such memory responses and to assess the programmatic utility of this whole blood-based mucosal ASC testing for the polio eradication program.     

Evaluation of poliovirus antibody titers in orally vaccinated semi‐captive chimpanzees in Uganda

Background To understand immunological responses in chimpanzees vaccinated with live‐attenuated vaccine (oral polio vaccine; OPV), serum neutralizing antibodies against poliovirus types 1, 2, and 3 were investigated over time. Methods The neutralizing antibody titers against poliovirus types 1, 2, and 3 were determined by microneutralization test using 100 ID₅₀ of poliovirus types 1, 2, and 3 (Sabin strains). Results Neutralizing antibodies against poliovirus types 1, 2, and 3 were detected in 85.7%, 71.4%, and 65% of the serum from 42 chimpanzees tested 9 years post‐vaccination. The neutralizing antibody titers in chimpanzees were similar to the documented levels in human studies as an indicator of vaccine efficacy. Conclusions This study reveals persistence of neutralizing antibodies in chimpanzees for at least 9 years after vaccination with OPV. This first study in chimpanzees provides useful information for the evaluation of the success of vaccination with OPV in other captive apes.     

Alternative Inactivated Poliovirus Vaccines Adjuvanted with Quillaja brasiliensis or Quil-A Saponins Are Equally Effective in Inducing Specific Immune Responses

Inactivated polio vaccines (IPV) have an important role at the final stages of poliomyelitis eradication programs, reducing the risks associated with the use of attenuated polio vaccine (OPV). An affordable option to enhance vaccine immunogenicity and reduce costs of IPV may be the use of an effective and renewable adjuvant. In the present study, the adjuvant activity of aqueous extract (AE) and saponin fraction QB-90 from Quillaja brasiliensis using poliovirus antigen as model were analyzed and compared to a preparation adjuvanted with Quil-A, a well-known saponin-based commercial adjuvant. Experimental vaccines were prepared with viral antigen plus saline (control), Quil-A (50 µg), AE (400 µg) or QB-90 (50 µg). Sera from inoculated mice were collected at days 0, 28, 42 and 56 post-inoculation of the first dose of vaccine. Serum levels of specific IgG, IgG1 and IgG2a were significantly enhanced by AE, QB-90 and Quil-A compared to control group on day 56. The magnitude of enhancement was statistically equivalent for QB-90 and Quil-A. The cellular response was evaluated through DTH and analysis of IFN-γ and IL-2 mRNA levels using in vitro reestimulated splenocytes. Results indicated that AE and QB-90 were capable of stimulating the generation of Th1 cells against the administered antigen to the same extent as Quil-A. Mucosal immune response was enhanced by the vaccine adjuvanted with QB-90 as demonstrated by increases of specific IgA titers in bile, feces and vaginal washings, yielding comparable or higher titers than Quil-A. The results obtained indicate that saponins from Q. brasiliensis are potent adjuvants of specific cellular and humoral immune responses and represent a viable option to Quil-A.     

Circulation of endemic type 2 vaccine-derived poliovirus in Egypt from 1983 to 1993

From 1988 to 1993, 30 cases of poliomyelitis associated with poliovirus type 2 were found in seven governorates of Egypt. Because many of the cases were geographically and temporally clustered and because the case isolates differed antigenically from the vaccine strain, it was initially assumed that the cases signaled the continued circulation of wild type 2 poliovirus. However, comparison of sequences encoding the major capsid protein, VP1 (903 nucleotides), revealed that the isolates were related (93 to 97% nucleotide sequence identity) to the Sabin type 2 oral poliovirus vaccine (OPV) strain and unrelated (<82% nucleotide sequence identity) to the wild type 2 polioviruses previously indigenous to Egypt (last known isolate: 1979) or to any contemporary wild type 2 polioviruses found elsewhere. The rate and pattern of VP1 divergence among the circulating vaccine-derived poliovirus (cVDPV) isolates suggested that all lineages were derived from a single OPV infection that occurred around 1983 and that progeny from the initiating infection circulated for approximately a decade within Egypt along several independent chains of transmission. Complete genomic sequences of an early (1988) and a late (1993) cVDPV isolate revealed that their 5' untranslated region (5' UTR) and noncapsid- 3' UTR sequences were derived from other species C enteroviruses. Circulation of type 2 cVDPVs occurred at a time of low OPV coverage in the affected communities and ceased when OPV coverage rates increased. The potential for cVDPVs to circulate in populations with low immunity to poliovirus has important implications for current and future strategies to eradicate polio worldwide.     

Environmental Surveillance of Poliovirus in Sewage Water around the Introduction Period for Inactivated Polio Vaccine in Japan

Environmental virus surveillance was conducted at two independent sewage plants from urban and rural areas in the northern prefecture of the Kyushu district, Japan, to trace polioviruses (PVs) within communities. Consequently, 83 PVs were isolated over a 34-month period from April 2010 to January 2013. The frequency of PV isolation at the urban plant was 1.5 times higher than that at the rural plant. Molecular sequence analysis of the viral VP1 gene identified all three serotypes among the PV isolates, with the most prevalent serotype being type 2 (46%). Nearly all poliovirus isolates exhibited more than one nucleotide mutation from the Sabin vaccine strains. During this study, inactivated poliovirus vaccine (IPV) was introduced for routine immunization on 1 September 2012, replacing the live oral poliovirus vaccine (OPV). Interestingly, the frequency of PV isolation from sewage waters declined before OPV cessation at both sites. Our study highlights the importance of environmental surveillance for the detection of the excretion of PVs from an OPV-immunized population in a highly sensitive manner, during the OPV-to-IPV transition period.     

中国婴儿中脊灰母传抗体水平对两种疫苗免疫效果的影响

为了了解2月龄婴儿中针对脊髓灰质炎病毒的中和抗体水平,并探讨母传抗体对脊髓灰质炎减毒活疫苗(OPV)和灭活疫苗(IPV)免疫效果的影响。对416名2月龄婴儿分别接种OPV和IPV,采集免疫前后血清,用微量中和法检测血清中Ⅰ、Ⅱ、Ⅲ型脊髓灰质炎病毒中和抗体滴度,评价抗体GMT水平及4倍增长情况。检测结果显示,2月龄婴儿母传抗体Ⅰ、Ⅱ、Ⅲ型阳性率分别为45%、38.2%和17.5%,抗体GMT水平为9.0、8.1和5.2。经接种两组疫苗后,母传抗体阳性者与阴性者免后抗体GMT水平相比,OPV组无明显差异,IPV组阳性者略低于阴性者。在免前抗体滴度<1∶32人群中,OPV组免后抗体滴度4倍增长率及几何滴度增长倍数分别为:Ⅰ型93.6%、71.2;Ⅱ型98.2%、43.7;Ⅲ型91.7%、47.9;IPV组免后抗体滴度4倍增长率及几何滴度增长倍数分别为:Ⅰ型82%、9.4;Ⅱ型62.8%、5.1;Ⅲ型95.6%、11.7;在免前抗体滴度1∶32～1∶128人群中,OPV组Ⅰ型92.3%、23;Ⅱ型86.4%、13.9;Ⅲ型55.6%、4.1;IPV组Ⅰ型48%、2.5;Ⅱ型15%、0.9;Ⅲ型55.6%、2.7。目前中国2月龄婴儿免前脊灰抗体阳性率较高,尤其是Ⅰ、Ⅱ型。脊灰母传抗体对两种疫苗免疫效果有一定干扰,对IPV疫苗的影响较为明显。     

Wistar大鼠皮内免疫Sabin株脊髓灰质炎灭活疫苗的免疫持久性及加强免疫效果研究

脊髓灰质炎野毒株消灭后,口服脊髓灰质炎减毒活疫苗(Oral polio vaccine,OPV)将被停止使用,脊髓灰质炎灭活疫苗(Inactivated poliovirus vaccine,IPV)将全面替代OPV,但IPV成本过高,难以满足全球需要。皮内免疫可以降低Sabin株脊髓灰质炎灭活疫苗(Inactivated poliovirus vaccine derived from Sabin strain,sIPV)的免疫剂量,本研究将观察sIPV疫苗皮内免疫大鼠后的免疫持久性及加强免疫效果。本研究采用sIPV,设皮内免疫组、全剂量肌肉免疫组和皮内免疫阴性对照组,接种Wistar大鼠,于3剂基础免疫程序完成后第1个月、12个月采血;第12个月采血后加强免疫1剂,并于加强免疫1个月后采血。中和试验检测各血清抗脊灰病毒中和抗体效价,评价皮内免疫sIPV的免疫持久性及加强免疫效果。Wistar大鼠3剂基础免疫后1个月,1/5、1/3剂量皮内免疫组与全剂量肌肉免疫组Ⅰ、Ⅱ、Ⅲ型抗体阳转率均达到了100%,各型别中和抗体几何平均滴度(Geometric mean titer,GMT)均远高于1∶8保护水平。基础免疫后12个月,sIPV全剂量组各型阳转率均维持在80%以上,1/10剂量皮内免疫组在50%以上,1/5剂量皮内免疫组维持在70%以上,1/3剂量皮内免疫组维持在80%以上,除1/10剂量组Ⅱ型外其余各组各型别GMT均维持在1∶8以上。加强免疫后1个月,1/5剂量皮内免疫组、1/3剂量皮内免疫组及全剂量组的Ⅰ型、Ⅱ型、Ⅲ型各组中和抗体阳转率均达到100%,并能够诱导产生远高于1∶8的抗体水平。本研究结果显示sIPV疫苗皮内免疫具有良好的免疫持久性及加强免疫效果。     

Developments in the production and quality control of poliovirus vaccines -- historical perspectives.

Using virus grown in monkey kidney cells, Salk and his colleagues developed an inactivated poliovirus vaccine (IPV) in 1952. A large-scale field trial showed the vaccine to be safe and highly immunogenic in children, but soon after the vaccine became generally available in 1955, cases of paralytic disease were reported in recipients. Investigations showed that almost all the cases occurred in children who had received vaccine from one particular manufacturer. Extensive studies attributed the disaster to problems with inactivation. Addition of a Seitz filtration step midway during formalin inactivation and extension of the inactivation period resulted in a safe vaccine. No further paralytic cases were observed following the use of several hundred million doses of this improved vaccine. Thus, IPV was safe and caused a dramatic decline in the incidence of poliomyelitis in countries where it was used. A second generation IPV is produced in fermentors using well-characterized cell strains or continuous cell lines. The major breakthrough in the development of live poliovirus vaccine was the application of tissue culture methods for virus attenuation. By 1959 several candidate live oral poliovirus vaccines (OPV) had been developed. These were clinically tested in millions of individuals and found to be safe and effective. Since the attenuated virus strains developed by Koprowski and Cox were more neurotropic in monkeys than the Sabin strains, only the latter was licensed in the USA in 1961 and endorsed shortly after by the World Health Organization (WHO). The widespread use of Sabin's OPV in many countries hastened the development of International Requirements by WHO for OPV in 1962 to define the criteria that ensured the uniformity of batches produced by different manufacturers. These have been updated continuously in light of new information and quality control procedures. Extensive field trials have shown the risk of OPV associated polio to be less than 0.3 per million doses administered.     

Combinations of Quality and Frequency of Immunization Activities to Stop and Prevent Poliovirus Transmission in the High-Risk Area of Northwest Nigeria

Background

Frequent supplemental immunization activities (SIAs) with the oral poliovirus vaccine (OPV) represent the primary strategy to interrupt poliovirus transmission in the last endemic areas.

Materials and Methods

Using a differential-equation based poliovirus transmission model tailored to high-risk areas in Nigeria, we perform one-way and multi-way sensitivity analyses to demonstrate the impact of different assumptions about routine immunization (RI) and the frequency and quality of SIAs on population immunity to transmission and persistence or emergence of circulating vaccine-derived polioviruses (cVDPVs) after OPV cessation.

Results

More trivalent OPV use remains critical to avoid serotype 2 cVDPVs. RI schedules with or without inactivated polio vaccine (IPV) could significantly improve population immunity if coverage increases well above current levels in under-vaccinated subpopulations. Similarly, the impact of SIAs on overall population immunity and cVDPV risks depends on their ability to reach under-vaccinated groups (i.e., SIA quality). Lower SIA coverage in the under-vaccinated subpopulation results in a higher frequency of SIAs needed to maintain high enough population immunity to avoid cVDPVs after OPV cessation.

Conclusions

National immunization program managers in northwest Nigeria should recognize the benefits of increasing RI and SIA quality. Sufficiently improving RI coverage and improving SIA quality will reduce the frequency of SIAs required to stop and prevent future poliovirus transmission. Better information about the incremental costs to identify and reach under-vaccinated children would help determine the optimal balance between spending to increase SIA and RI quality and spending to increase SIA frequency.     

Circulation of type 1 vaccine-derived poliovirus in the Philippines in 2001

In 2001, highly evolved type 1 circulating vaccine-derived poliovirus (cVDPV) was isolated from three acute flaccid paralysis patients and one contact from three separate communities in the Philippines. Complete genomic sequencing of these four cVDPV isolates revealed that the capsid region was derived from the Sabin 1 vaccine strain but most of the noncapsid region was derived from an unidentified enterovirus unrelated to the oral poliovirus vaccine (OPV) strains. The sequences of the cVDPV isolates were closely related to each other, and the isolates had a common recombination site. Most of the genetic and biological properties of the cVDPV isolates were indistinguishable from those of wild polioviruses. However, the most recently identified cVDPV isolate from a healthy contact retained the temperature sensitivity and partial attenuation phenotypes. The sequence relationships among the isolates and Sabin 1 suggested that cVDPV originated from an OPV dose given in 1998 to 1999 and that cVDPV circulated along a narrow chain of transmission. Type 1 cVDPV was last detected in the Philippines in September 2001, and population immunity to polio was raised by extensive OPV campaigns in late 2001 and early 2002.     

First decade (1950-1960) of studies and trials with the polio vaccine.

The chronology of the development of polio vaccines following the first human trials of attenuated poliovirus vaccine in 1950 is described by me as a witness to the first decade of trials and tribulations following my discovery of polio vaccine in 1950. Mass vaccination trials are considered to be the most important phase of the discovery of oral polio vaccine (OPV). These took place in the Belgian Congo, Poland, Croatia, Switzerland, and finally in the former Soviet Union. By 1960, approximately 13 million individuals had been vaccinated with the Koprowski oral polio vaccine and over 11 million with the Sabin vaccine.     

Cleavage of VP1 and modification of antigenic site 1 of type 2 polioviruses by intestinal trypsin.

We have exposed 22 independent type 2 poliovirus isolates to human intestinal fluid and purified trypsin. In all cases the virus retained its infectivity, while polyacrylamide gel electrophoresis of viral proteins showed disappearance of the VP1 bands. Concomitantly, the viruses became resistant to antigenic site 1-specific monoclonal antibodies, indicating that the cleavage took place at the antigenic site 1. Sera from persons immunized solely with the inactivated poliovirus vaccine (IPV) neutralized intact type 2 polioviruses more readily than the corresponding trypsin-cleaved virus preparations. The ratio between the neutralization indices for the intact and trypsin-cleaved type 2 polioviruses was not significantly changed by a dose of trivalent oral poliovirus vaccine given to children previously immunized with IPV. These results indicate that while the antigenic site 1 of type 2 poliovirus is immunogenic in humans when IPV is used, the relative role of this antigenic site in human immunity appears to be less critical than that in the case of type 3 polioviruses. Before we obtained these results, only antigenic site 1 had been shown to be immunogenic in type 2 polioviruses.     

The final stages of the global eradication of poliomyelitis

The global incidence of poliomyelitis has dropped by more than 99 per cent since the governments of the world committed to eradication in 1988. One of the three serotypes of wild poliovirus has been eradicated and the remaining two serotypes are limited to just a small number of endemic regions. However, the Global Polio Eradication Initiative (GPEI) has faced a number of challenges in eradicating the last 1 per cent of wild-virus transmission. The polio endgame has also been complicated by the recognition that vaccination with the oral poliovirus vaccine (OPV) must eventually cease because of the risk of outbreaks of vaccine-derived polioviruses. I describe the major challenges to wild poliovirus eradication, focusing on the poor immunogenicity of OPV in lower-income countries, the inherent limitations to the sensitivity and specificity of surveillance, the international spread of poliovirus and resulting outbreaks, and the potential significance of waning intestinal immunity induced by OPV. I then focus on the challenges to eradicating all polioviruses, the problem of vaccine-derived polioviruses and the risk of wild-type or vaccine-derived poliovirus re-emergence after the cessation of oral vaccination. I document the role of research in the GPEI''s response to these challenges and ultimately the feasibility of achieving a world without poliomyelitis.     

Intestinal trypsin can significantly modify antigenic properties of polioviruses: implications for the use of inactivated poliovirus vaccine.

It was recently reported that the intestinal protease trypsin cleaves in vitro the VP1 protein of type 3 poliovirus at antigenic site 1 (J. P. Icenogle, P. D. Minor, M. Ferguson, and J. M. Hogle, J. Virol. 60:297-301, 1986). We found that incubation of purified or crude type 3 poliovirus preparations with specimens of human intestinal fluid brings about a similar change in the virion structure. Sera from children immunized solely with the regular inactivated poliovirus vaccine (IPV) neutralized trypsin-cleaved Sabin 3 virus poorly, if at all, despite moderate levels of antibodies to the corresponding intact virus. Sera containing very high titers of the intact virus also neutralized the trypsin-cleaved virus but at a relatively weaker capacity. Most sera from older persons who may have been exposed to a natural poliovirus infection before the introduction of the poliovirus vaccines as well as sera from children infected with type 3 poliovirus during the recent outbreak in Finland were able to neutralize the trypsin-cleaved type 3 polioviruses. Serum specimens collected 1 month after a single dose of live poliovirus vaccine from children previously immunized with IPV were able to neutralize the trypsin-cleaved virus as well. During natural infection and after live poliovirus vaccine administration polioviruses are exposed to proteolytic enzymes in the gut. Our results may offer an alternative explanation for the relatively weak mucosal immunity obtained with IPV. Improvement of IPV preparations by incorporation of trypsin-treated type 3 polioviruses in the vaccine should be studied.     

Induction of toxin‐specific neutralizing immunity by molecularly uniform rice‐based oral cholera toxin B subunit vaccine without plant‐associated sugar modification

Plants have been used as expression systems for a number of vaccines. However, the expression of vaccines in plants sometimes results in unexpected modification of the vaccines by N‐terminal blocking and sugar‐chain attachment. Although MucoRice‐CTB was thought to be the first cold‐chain‐free and unpurified oral vaccine, the molecular heterogeneity of MucoRice‐CTB, together with plant‐based sugar modifications of the CTB protein, has made it difficult to assess immunological activity of vaccine and yield from rice seed. Using a T‐DNA vector driven by a prolamin promoter and a signal peptide added to an overexpression vaccine cassette, we established MucoRice‐CTB/Q as a new generation oral cholera vaccine for humans use. We confirmed that MucoRice‐CTB/Q produces a single CTB monomer with an Asn to Gln substitution at the 4th glycosylation position. The complete amino acid sequence of MucoRice‐CTB/Q was determined by MS/MS analysis and the exact amount of expressed CTB was determined by SDS‐PAGE densitometric analysis to be an average of 2.35 mg of CTB/g of seed. To compare the immunogenicity of MucoRice‐CTB/Q, which has no plant‐based glycosylation modifications, with that of the original MucoRice‐CTB/N, which is modified with a plant N‐glycan, we orally immunized mice and macaques with the two preparations. Similar levels of CTB‐specific systemic IgG and mucosal IgA antibodies with toxin‐neutralizing activity were induced in mice and macaques orally immunized with MucoRice‐CTB/Q or MucoRice‐CTB/N. These results show that the molecular uniformed MucoRice‐CTB/Q vaccine without plant N‐glycan has potential as a safe and efficacious oral vaccine candidate for human use.