Beate Krämer

The rapid fluorescent focus inhibition test is a suitable method for batch potency testing of inactivated rabies vaccines.

The European Pharmacopoeia proposes two methods for potency determination of inactivated rabies vaccines for veterinary use: The first one is a classical mouse challenge test, which is imprecise, time-consuming, and causes severe distress to the test animals. Alternatively, the potency may be determined serologically by measuring the neutralizing antibody titers induced after vaccination of mice by using a rapid fluorescent focus inhibition test (RFFIT). Although this method is faster and less painful for the animals, it is not widely used yet, and only little data exist concerning the comparability of both methods. We have therefore performed a comparative study, in which we demonstrated a good correlation between the challenge test results and the mean titers determined by RFFIT. Furthermore, all vaccine batches failing the challenge test were also recognized as insufficient in the serological assay. This publication further describes the influence of different vaccine administration routes on the resulting antibody titers, and it proposes various modifications to the serological assay protocol which could improve its overall practicability. Finally, we recommend that the serological assay be used for the potency testing of inactivated rabies vaccines.

In vitro determination of tetanus toxicity by an endopeptidase assay linked to a ganglioside-binding step.

Assays for the detection of tetanus neurotoxin (TeNT) are relevant for research applications as well as for the safety testing of tetanus vaccines. So far, these assays are usually performed as toxicity tests in guinea pigs or mice. The alternative methods described to date were mostly based on the detection of the toxins proteolytic activity. However, these endopeptidase assays turned out to be unreliable because they only measure the enzymatic activity as sole determinant of tetanus toxicity, while not taking into account other parameters like the toxins capacity to bind to target cells. In order to better reflect the in vivo situation of a tetanus infection, we have linked an endopeptidase assay to a ganglioside-binding step. The resulting method, which offers a unique combination of two functionally linked assays, detects those TeNT molecules only which possess both a functional binding domain as well as an active enzymatic domain. Our results demonstrate that this assay is able to reliably detect TeNT, and therefore might provide a basis for the replacement of the animal tests for detection of tetanus toxicity. Moreover, the assay concept could also be useful for in vitro toxicity measurements of other toxins with similar subunit structures.

Residual enzymatic activity of the tetanus toxin light chain present in tetanus toxoid batches used for vaccine production

The light chain of tetanus neurotoxin (TeNT) is a zinc-dependent metalloprotease which specifically cleaves the synaptic vesicle protein synaptobrevin. This crucial mechanism of tetanus toxicity leads to a blockade of inhibitory neurotransmitter release. We recently reported the development of a highly sensitive endopeptidase assay for the specific in vitro detection of active TeNT based on this proteolytic feature. Using this method, we could show that formaldehyde-inactivated TeNT preparations (toxoids), which are used for the production of tetanus vaccines, contain a high residual synaptobrevin-cleaving activity. Such an activity was detected in numerous tetanus toxoid batches obtained from several vaccine manufacturers which did not display any in vivo toxicity in the obligatory animal tests. The enzymatic activity could be attributed to the presence of free TeNT light chains whose function had not been restrained by the formaldehyde treatment, but which lack the functional heavy chain necessary for entering neurons in vivo. To our knowledge, this is the first report describing a residual proteolytic activity in tetanus toxoids.

Inactivated Recombinant Rabies Viruses Displaying Canine Distemper Virus Glycoproteins Induce Protective Immunity against Both Pathogens

ABSTRACT The development of multivalent vaccines is an attractive methodology for the simultaneous prevention of several infectious diseases in vulnerable populations. Both canine distemper virus (CDV) and rabies virus (RABV) cause lethal disease in wild and domestic carnivores. While RABV vaccines are inactivated, the live-attenuated CDV vaccines retain residual virulence for highly susceptible wildlife species. In this study, we developed recombinant bivalent vaccine candidates based on recombinant vaccine strain rabies virus particles, which concurrently display the protective CDV and RABV glycoprotein antigens. The recombinant viruses replicated to near-wild-type titers, and the heterologous glycoproteins were efficiently expressed and incorporated in the viral particles. Immunization of ferrets with beta-propiolactone-inactivated recombinant virus particles elicited protective RABV antibody titers, and animals immunized with a combination of CDV attachment protein- and fusion protein-expressing recombinant viruses were protected from lethal CDV challenge. However, animals that were immunized with only a RABV expressing the attachment protein of CDV vaccine strain Onderstepoort succumbed to infection with a more recent wild-type strain, indicating that immune responses to the more conserved fusion protein contribute to protection against heterologous CDV strains. IMPORTANCE Rabies virus and canine distemper virus (CDV) cause high mortality rates and death in many carnivores. While rabies vaccines are inactivated and thus have an excellent safety profile and high stability, live-attenuated CDV vaccines can retain residual virulence in highly susceptible species. Here we generated recombinant inactivated rabies viruses that carry one of the CDV glycoproteins on their surface. Ferrets immunized twice with a mix of recombinant rabies viruses carrying the CDV fusion and attachment glycoproteins were protected from lethal CDV challenge, whereas all animals that received recombinant rabies viruses carrying only the CDV attachment protein according to the same immunization scheme died. Irrespective of the CDV antigens used, all animals developed protective titers against rabies virus, illustrating that a bivalent rabies virus-based vaccine against CDV induces protective immune responses against both pathogens.

Quantification of Lyssavirus-Neutralizing Antibodies Using Vesicular Stomatitis Virus Pseudotype Particles.

Rabies is a highly fatal zoonotic disease which is primarily caused by rabies virus (RABV) although other members of the genus Lyssavirus can cause rabies as well. As yet, 14 serologically and genetically diverse lyssaviruses have been identified, mostly in bats. To assess the quality of rabies vaccines and immunoglobulin preparations, virus neutralization tests with live RABV are performed in accordance with enhanced biosafety standards. In the present work, a novel neutralization test is presented which takes advantage of a modified vesicular stomatitis virus (VSV) from which the glycoprotein G gene has been deleted and replaced by reporter genes. This single-cycle virus was trans-complemented with RABV envelope glycoprotein. Neutralization of this pseudotype virus with RABV reference serum or immune sera from vaccinated mice showed a strong correlation with the rapid fluorescent focus inhibition test (RFFIT). Importantly, pseudotype viruses containing the envelope glycoproteins of other lyssaviruses were neutralized by reference serum to a significantly lesser extent or were not neutralized at all. Taken together, a pseudotype virus system has been successfully developed which allows the safe, fast, and sensitive detection of neutralizing antibodies directed against different lyssaviruses.

In vitro potency determination of botulinum neurotoxin B based on its receptor-binding and proteolytic characteristics.

Botulinum neurotoxins (BoNTs) are the most potent toxins known. However, the paralytic effect caused by BoNT serotypes A and B is taken advantage of to treat different forms of dystonia and in cosmetic procedures. Due to the increasing areas of application, the demand for BoNTs A and B is rising steadily. Because of the high toxicity, it is mandatory to precisely determine the potency of every produced BoNT batch, which is usually accomplished by performing toxicity testing (LD50 test) in mice. Here we describe an alternative in vitro assay for the potency determination of the BoNT serotype B. In this assay, the toxin is first bound to its specific receptor molecules. After the proteolytic subunit of the toxin has been released and activated by chemical reduction, it is exposed to synaptobrevin, its substrate protein. Finally the proteolytic cleavage is quantified by an antibody-mediated detection of the neoepitope, reaching a detection limit below 0.1mouseLD50/ml. Thus, the assay, named BoNT/B binding and cleavage assay (BoNT/B BINACLE), takes into account the binding as well as the protease function of the toxin, thereby measuring its biological activity.

A multi-dose serological assay suitable to quantify the potency of inactivated rabies vaccines for veterinary use

The mouse vaccination-challenge test, which is the most widely used method for determining the potency of inactivated rabies vaccines, is imprecise, time-consuming, and causes severe distress to the test animals. An alternative single-dose serological method has been implemented in the European Pharmacopoeia Monograph 0451 to replace the mouse challenge test for batch release. This single-dose limit method provides semi-quantitative results, but is not suitable for quantifying potency. We have now extended this serological method to a multi-dose format which allows a quantification of vaccine potency. In studies including all rabies vaccine strains relevant for Europe, we found dose-dependency for all vaccines and standard preparations. We have demonstrated that the multi-dose serological approach provides reliable quantitative potency results and is more precise than the mouse vaccination-challenge test. We have shown that adjuvanted vaccines can be calibrated against non-adjuvanted material, and that reference material can be calibrated against the International Standard. The method is therefore capable of assigning potency with the additional advantage of requiring fewer animals and reducing distress. Once the applicability of the method has been further verified in a collaborative study, it can complement the single-dose assay and eventually eliminate the need for the mouse challenge test.

Potency estimation of vaccine batches remains unaffected by anesthesia for intracerebral injection

Potency testing of rabies and whole-cell pertussis vaccine batches is still performed by an intracerebral (i.c.) challenge test, in conformity with international regulatory requirements. For the i.c. injection, the use of anesthesia is strongly recommended to alleviate the severe pain induced by the procedure. Today, anesthesia is not consistently mentioned in regulatory requirements, in contrast to the times when the potency tests were developed. The introduction of anesthesia is hampered, due to the lack of data on a hypothetical impact of anesthesia on potency estimation. Here, we show the comparative analysis of the extensive batch release data set of a rabies vaccine for human use that was tested in two laboratories of which only one applied anesthesia. In essence, we find that the mean batch test results were similar to each other, demonstrating that anesthesia for i.c. injection does not interfere with potency estimation. Consequently, we recommend the update of regulatory requirements and protocols and support the implementation of anesthesia for i.c. injection.