NZ711569B2

NZ711569B2 - Single high dose of mva induces a protective immune response in neonates and infants

Info

Publication number: NZ711569B2
Application number: NZ711569A
Authority: NZ
Inventors: Paul Chaplin; Cedric Cheminay; Mark Suter; Ariane Volkmann
Original assignee: Bavarian Nordic A/S
Priority date: 2013-03-15
Filing date: 2014-03-14
Publication date: 2021-06-29

Abstract

The invention relates to compositions and methods for inducing a protective immune response against a poxvirus in a human neonate or infant of less than 6 months of age. The invention encompasses administering a single high dose of at least 10^8 TCID50 of an MVA to a human neonate or infant of less than 6 months of age, wherein the administration induces protective T- and B-cell responses against a poxvirus in the human neonate or infant. than 6 months of age, wherein the administration induces protective T- and B-cell responses against a poxvirus in the human neonate or infant.

Description

SINGLE HIGH DOSE OF MVA INDUCES A PROTECTIVE IMMUNE RESPONSE IN NEONATES AND INFANTS The t invention relates to a method for inducing a protective immune response against a poxvirus in a human neonate or infant of less than 6 months of age comprising administering a dose of at least 108 TCleo of an MVA to a human neonate.

Background of the Invention There are only three vaccines that are licensed globally for immunization at birth: Bacille Calmette-Guérin (BCG) to prevent tuberculosis, oral Polio vaccine (OPV), and tis B vaccine (HBV). Sanchez-Schmitz et al., Sci. Trans]. Med. 3, 90ps27 (2011). BCG is a single-dose vaccine of freeze-dried, live Mycobacterium bovis. Id.

OPV is a single-dose vaccine of a live-attenuated poliovirus. Id. HBV vaccine is a recombinant hepatitis B surface antigen expressed in yeast that is stered with Alum in three-doses, starting at birth. Id. Thus, two of these are live, replicating vaccines, and the other is a recombinant protein given in three doses.

The immaturity of the immune system in newborns has been a major bottleneck to p safe and effective vaccines at this age. Under the current vaccination schedule for infants, only the tis B e is recommended at birth, while others are given later during infancy (first 12 months, e.g. rotavirus, inactivated poliovirus vaccine), or are only ended at 12 months or older (e.g. measles/mumps/rubella vaccine), although in all cases multiple vaccinations are required during infancy I childhood to induce high levels of protection. Sanchez- Schmitz et al., Sci. there is a time span of six to nine months after birth with increased susceptibility to diseases that could be prevented by vaccines. Id.

Smallpox, AIDS, malaria, tuberculosis, and other es occur in young children with a rapid and often severe disease progression. Even for childhood diseases such as RSV or measles, vaccines do not exist or cannot be administered before 9 months of age. Consequently, vaccination of neonates (within first 4 weeks) and/or a d or more effective schedule in infants would be a major e in reducing mortality and morbidity associated with infectious diseases.

It is generally accepted that newborns mount mainly TH2 biased T-cell responses and produce no or only low levels of antibodies with limited affinity. In on, these responses are of shorter on than in adults. Adkins et al., Nat. Rev. Immunol. 4, 553-564 (2004); Marshall—Clarke et al., Immunol. Today 21, 35-41 (2000); Siegrist,C.A., Vaccine 19, 3331-3346 (2001).

However, under certain circumstances, such as activation of pattern recognition receptors or during certain viral infections, newborn mice can mount protective T-cell responses over time, indicating the potential for neonatal immunization. Forsthuber et al., Science 271, 1728-1730 (1996); ti et al., Science 271, 728 (1996).

Parallel to the development of adjuvants improving existing es (Gracia et al., Vaccine 29, 1595-1604 (2011); Kamath et al., PLoS. One. 3, e3683 (2008)), new antigen delivery systems like DNA vaccines (Hassett et al.,J. Virol. 74, 2620—2627 (2000); Rigato et al., Virology 406, 37-47 ) and the three attenuated replicating ial strains Salmonella enteric ez et al., Vaccine 28, 075 (2010)), Listeria togenes (Kollmann et al., J. Immunol. 178, 3695-3701 (2007)), and ECG (Nascimento et al., Microbes. Infect. 10, 198-202 (2008); Ranganathan et al., Vaccine 28, 152-161 (2009)) were shown to induce efficient immune responses when administered in one week old mice or even at birth. However, only live attenuated replicating vaccines induced protection against lethal infections, and were lly effective only after several immunizations and thus at a stage with a progressed immunological maturity. Hence, replicative vaccines require substantial time to induce successful protection, and the risk of uncontrolled disseminated infections of live attenuated replicating vaccines still represent major limitations (Galen et al., Immunol.

Cell Biol. 87, 400-412 (2009); Johnson et al., Microbiol. Immunol. 55, 304-317 (2011); Li et al., Zhonghua Er. Ke. Za Zhi. 48, 65-68 (2010); Liu et al., Immunol. Rev. 239, 62—84 (201 1)).

Modified Vaccinia virus Ankara (MVA) has been administered to over 100,000 individuals during the smallpox ation campaign without any complications. r, MVA still represents a complex mixture of s with different levels of 3O attenuation and immunogenicity. Suter et al., Vaccine 27, 7442-7450 . The plaque-purified MVA developed by Bavarian Nordic (MVA-BN) completely fails to replicate in mammals including humans and is safe even in immune—compromised hosts. Id. s its excellent safety e, MVA is highly immunogenic in humans (Vollmar et al., e 24, 2065-2070 (2006)) and its efficacy has been proven in several smallpox animal models such as Ectromelia virus (ECTV), rabbitpox or monkeypox (Garza et al., Vaccine 27, 5496-5504 (2009); sson et al., J. Clin.

Invest 118, 1776-1784 (2008); Stittelaar et al., J. Virol. 79, 7845—7851 (2005)).

WO 39687 Another major advantage of MVA is its capacity to support the c insertion of several ns (Timm et al., Vaccine 24, 4618-4621 (2006)) that could itantly induce protection against other infectious diseases or cancer ((Harrer et al. Antivir. Ther. 10, 285-300 (2005); Mandl et al., Cancer Immunol.

Immunother.(2011); Meyer et al., Cancer Immunol. ther. 54, 453-467 (2005)).

ECTV (the causative agent of mousepox) in mice is a good model system for human us infection. Esteban et al., Journal of General Virology (2005), 86, 2645— 2659. The course of disease is very r for mousepox and smallpox, including the entry route, the high infectivity at low doses, the development of viremia, the restricted host range, and the d but fatal outcome. Therefore, mousepox can be regarded as a le small animal model for human smallpox and, in general, as a model for acute, fatal viral diseases. Lauterbach et al., PLoS ONE, Volume 5(3 ): e9659 (2010).

The pathogenesis of ECTV infection in mice, with localized replication and systemic spread, is similar to the pathogenesis of Variola virus in humans. Chapman et al., Vet Pathol 2010 47: 852 (2010). A comparison of short-term and postexposure tion in mice infected with VACV-WR and ECTV suggested that ECTV infection more closely resembles human smallpox. Paran et al., The Journal of Infectious Diseases; 199:39—48 (2009).

The vaccination of mice with MVA at birth is safe and induces an increase of FLT3 ligand, leading to an accelerated development of plasmacytoid tic cells (pDC) and activation of conventional (c) DC resulting in ed resistance against heterologous viral infection. (Franchini et al., J. Immunol. 172, 6304-6312 (2004), Vollstedt et al., Eur J Immunol. 34: 1849-1860 (2004) Vollstedt et al., Eur J Immunol. 36: 240 (2006). Vaccination of one or y old mice with 2.5x107 TClD5o of MVA protected most mice against challenge with a lethal dose of herpes simplex virus 1 (HSV—1) at 7-8 days after vaccination and protected most mice against challenge with a lethal dose of vaccinia Western Reserve (W-WR) at 4 weeks after immunization, when the mice were considered adults. WO 03/088994A2. To determine the virus dose needed for maximal induction of CD11c+ cells, graded doses of MVA were tested. Maximal numbers of CD11c+ cells were detected after treatment with 2.5><106 TCID50 of virus; whereas, doses below and above this were less effective. Id. Thus, 2.5x106 TC|D50 was considered to be the optimal dose of MVA for the vaccination of neonates. uently, a need in the art exists for compositions and methods for vaccination of neonates to achieve strong T-cell and antibody ses and protection against pathogens. The invention fulfills this need.

Summary of the invention The invention encompasses itions and methods for ng a protective immune response against a poxvirus in a human neonate or infant of less than 6 months of age. In one embodiment, the invention encompasses administering a dose of at least 108 TC|D50 of an MVA to a human neonate or infant of less than 6 months of age, wherein the administration induces protective T- and B-cell responses against a poxvirus in the human neonate prior to 6 months of age, preferably within 2 weeks of the stration. Most preferably, the immune response is induced in the absence of a second administration of the MVA.

In various embodiments, the administration is administered to a human neonate or infant of less than 2 months of age or within 72 hours after birth.

Preferably, the administration induces protective T- and B-cell responses against a poxvirus. Most preferably, the administration induces protective T- and B-cell responses against smallpox.

In some embodiments, the ion encompasses administering one or more boosting administrations of the MVA.

In some ments, the MVA is a recombinant MVA. In some embodiments, the administration induces T- and B—cell ses against a heterologous antigen encoded by the recombinant MVA.

Brief description of the figures Figures 1a-d show a comparison of the ia-specific immune ses in newborn versus adult mice after a single MVA-BN vaccination. Newborn or adult CS7BL/6 mice were immunized with a high dose (1 X108 TCleo) or a low dose (2X106 TCIDso) of MVA. Animals were bled and sacrificed 1, 2, 3, 4 or 7 weeks post- immunization. (a) Vaccinia-specific lgG in serum was measured by ELISA. Geometric mean titers +/- standard error of the mean (GMT +/- SEM) are shown. (b) tage of B8R-specific lFNy-secreting CD8+ T-cells in spleen was determined by flow cytometry. Mean percentages +/- standard error of the mean (SEM) are shown. (c) Percentage of granzyme B-expressing CD8+ T-cells in spleen was determined by flow cytometry. Mean tages +/- standard error of the mean (SEM) are shown. (d) Distribution (in %) of effector (CD44hi9“CD62L'CD127'), effector memory (CD44“‘9“CD62L'CD127+) and central memory (CD44hi9hcoezL*co127*) cells within the BSR—specific CD8+ T-cell population ed from spleen was measured by flow cytometry. Mean percentages +/— standard error of the mean (SEM) are shown. The distribution was identical in n mice immunized with the two different doses of MVA-BN, only the 1X108 TCID50 dose is shown. Analysis in one week old mice was not possible due to insufﬁcient numbers of CD8+ T-cells in the spleen.

Figures 2a-d show that neonatal immunization with 108 TC|D50 of an MVA induces complete protection against ECTV challenge. C57BL/6 mice were immunized with a high dose (1 ><108 TC|D50) or low dose (2X106 TCID50‘) of MVA or administered TBS at birth. Four weeks after immunization, mice were challenged with 1X104 TClD5o ECTV. (a) Survival and (b) relative body weight change in % (mean +/- SEM) were monitored for 21 days. Similarly, mice zed at birth with 1X108 TCID50 of MVA were nged with (c) 3X104 TC|D50 ECTV 7 weeks post-immunization or (d) 1X102 TC|D50 ECTV 2 weeks post-immunization.

Figures 3a-d show that protection depends on the T- and B-cell immune responses. (a, b) FLT3 or (c, d) TCRBS knockout mice were immunized at birth with 1X108 TC|D50 of MVA and nged with 1X103 TC|D50 of ECTV 4 weeks later. (a, c) Survival was monitored for 21 days. (b, d) At the time of death or at the end of the observation period, lungs were necropsied, homogenized and the ECTV titer per lung was determined by plaque assay (GMT +/- SEM).

Figures 4a-d show that both T- and B-cell responses are required for complete protection (a, b) [32m knockout or (c, d) T11uMT transgenic mice were immunized at birth with 1x108 TClD5o of MVA and nged with 1x104 TClD5o of ECTV 4 weeks later. (a, c) Survival was monitored for 21 days. (b, d) At the time of death or at the end of the observation period, lungs were necropsied, homogenized and the ECTV titer per lung was determined by plaque assay (GMT +/- SEM). 2014/000693 Figures 5a-b show the immunogenicity of a recombinant MVA-Measles vaccine in newborn and adult mice. (a, b) n or adult BALB/c mice were immunized twice with 1X108 TCID50 of MVA-Measles three weeks apart. (a) In addition, some neonates were immunized only at birth. Adult mice were bled 2, 3, 4 and 5 weeks after the first immunization, whereas newborns could be bled only 3 weeks after birth. Blood was then drawn every two weeks (four times) and again when mice were sacrificed (15 weeks after neonatal immunization). Measles-specific IgG was measured by ELISA (GMT +/— SEM). (b) Two weeks after the second immunization, measles-specific T- cells were measured after in vitro stimulation of splenocytes with a capsid- specific peptide and ecreting cells were detected by ELISpot. (Mean of stimulation indexes +/- SEM).

Figure 6 shows long term vaccinia-specific B-cell responses in newborn mice after a single vaccination with MVA or UV-treated MVA. Newborn C57BL/6 mice were immunized with 1X108 TCID50 of MVA or with 1X108 TC|D50 of UV—treated MVA. s were bled and sacrificed 1, 2, 3, 4, 7 or 16 weeks post-immunization.

Vaccinia-specific lgG in serum was measured by ELISA. Geometric mean titers +/— rd error of the mean (GMT +/— SEM) are shown.

Figure 7 shows long term vaccinia-specific T-cell responses in newborn mice after a single MVA or UV—treated MVA vaccination. Newborn 6 mice were immunized with 1x108 TClD50 of MVA or with 1x108 TClD50 of UV-treated MVA. Animals were sacrificed 1, 2 or 16 weeks post-immunization. Vaccinia-specific T-cells were measured after in vitro stimulation of splenocytes with a B8R-specific peptide and IFNy-secreting cells were detected by ELISpot. (Mean of stimulation indexes +/- SEM) Figure 8 shows CD8+ T-cell frequency in newborn mice compared to adult mice. For 1-, 2-, 3-, 4- and 7-week old newborn mice, the percentage of CD8+ T-cells in spleen was determined by flow cytometry and ed to adult mice. Mean tages +/- standard error of the mean (SEM) are shown Figures 9a-b show that an immunoglobulin class switch is required for viral clearance. Activation-induced cytidine deaminase (AID) knockout mice were immunized at birth with 1x108 TCID50 of MVA and challenged with 1x104 TClD5o of ECTV 4 weeks later. (a) Survival was monitored for 21 days. (b) At time of death or at 2014/000693 the end of the observation period, lungs were necropsied, homogenized and the ECTV titer per lung was determined by plaque assay (GMT +/- SEM).

Detailed description of the invention The threat of a potential bioterrorism attack or emergence of zoonotic poxviruses in the human population has prompted several efforts to develop a safer third tion smallpox vaccine suitable for k populations contraindicated for ACAMZOOOTM, the smallpox vaccine currently licensed in the USA. However, at-risk populations include not only -compromised individuals such as HIV ts or individuals suffering from skin disorders like atopic dermatitis, but also children less than one year old due to the immaturity of their immune system. MVA-BN with its excellent safety profile as a replication-deficient live virus has previously been shown to enhance broad-spectrum resistance to viral infections in the first week of life in mice. Franchini, J. l. 172, 6304-6312 .

Naive es are considered difficult if not impossible to protect t fatal infections shortly after birth. However, by increasing the vaccination dose to a dose of 1X108 TCleo of Modified Vaccinia Ankara (MVA), it was demonstrated that a single zation of mice at birth induced fully functional T- and B-cell responses that rapidly conferred full protection against a lethal orthopoxvirus challenge. singly, protection is induced within 2 weeks and is mainly T-cell-dependent. Furthermore, persisting immunological T-cell memory and neutralizing antibodies were obtained with this single vaccination. Thus, MVA administered as early as at birth induces immediate and erm protection against fatal diseases and appears attractive as a platform for early childhood vaccines.

A single vaccination of mice with MVA at birth not only induces innate, but also ve immune responses including effector and long term memory T-cells as well as neutralizing antibody responses. Importantly, within two weeks after vaccination the adaptive immune response fully protects mice against a lethal intranasal challenge with ECTV.

Here, it is demonstrated that an important role for T—cells exists in newborn mice.

When immunized with a low dose of 2><106 TC|D50 of MVA, a strong cytotoxic T-cell response was induced, which led to partial protection from ECTV challenge in the absence of detectable antibody responses. Complete protection was only achieved after ation with a high dose of 1X108 TCID50 of MVA, a dose that also induces B-cell responses. This was confirmed in T11uMT transgenic mice, in which partial protection showed that B-cells are also ed in order to achieve complete protection after a single ation with MVA at birth.

The invention encompasses compositions and methods for inducing a protective immune response against a us in a human neonate or infant. In one embodiment, the invention encompasses administering a dose of at least 108 TCID50 of an MVA to a human neonate or infant. The MVA can be administered to a human neonate or infant prior to the full maturation of the immune system.

The invention further encompasses MVA for use in inducing a protective immune response against a poxvirus in a human neonate or infant.

The invention also encompasses MVAs for use in vaccinating a human e or infant. The invention also encompasses the use of MVAs as vaccines for treating a human neonate or infant and the use of MVAs in the preparation of vaccines or medicaments for treating or ating a human neonate or infant.

Human Neonates and Infants Within the context of this invention, the term “human neonate" refers to a n human less than 1 month of age and the term "human infant” refers to a human between birth and 1 year of age. Preferably, the human neonate is less than 4 weeks of age, less than 3 weeks of age, less than 2 weeks of age, or less than 1 week of age. More preferably, the human neonate is less than 6, 5, 4, 3, 2, or 1 days of age.

In one embodiment, a dose of MVA is administered to a human neonate. In various embodiments, a dose of MVA is administered to a human e of less than 4 weeks of age, less than 3 weeks of age, less than 2 weeks of age, or less than 1 week of age. In various embodiments, a dose of MVA is administered to a human neonate of less than 6, 5, 4, 3, 2, or 1 days of age. In preferred embodiments, a dose of MVA is administered to a human neonate within 3, 2, or 1 days of birth.

In one embodiment, a dose of MVA is administered to a human infant of less than 6, , 4, 3, 2, or 1 months of age. In various embodiments, a dose of MVA is administered to a human infant of less than 8 weeks of age, less than 7 weeks of age, less than 6 weeks of age, or less than 5 weeks of age. In preferred embodiments, a dose of MVA is administered to a human infant of less than 2 months of age.

Modified Vaccinia Ankara (MVA) Viruses The invention encompasses any and all MVA viruses. Preferred MVA viruses include MVA variant strains such as MVA-BN (deposited at the European tion of Animal Cell Cultures,Vaccine Research and Production Laboratory, Public Health Laboratory Service, Centre for Applied iology and Research, Porton Down, Salisbury, Wiltshire SP4 OJG, United Kingdom (ECACC) on August 30, 2000, under Accession No. V00083008), MVA-575 (deposited at ECACC on December 7, 2000, under Accession No. V00120707), and MVA-572 (deposited at ECACC on January 27, 1994 under Accession No. V94012707). Derivatives of the deposited strain are also preferred.

Preferably, the MVA has the capability of uctive ation in vitro in chicken embryo fibroblasts (CEF) or other avian cell lines or in vivo in embryonated eggs, but no capability of reproductive replication in human cells in which MVA 575 or MVA 572 can reproductively replicate. Most preferably, the MVA has no capability of uctive replication in the human keratinocyte cell line HaCaT, the human embryo kidney cell line 293 (also referred to as HEK293), the human bone osteosarcoma cell line 1438, and the human cervix adenocarcinoma cell line HeLa.

In red embodiments, the d vaccinia virus Ankara (MVA) virus is characterized by having the capability of reproductive replication in vitro in chicken embryo ﬁbroblasts (CEF) and by being more attenuated than MVA-575 in the human keratinocyte cell line HaCaT, in the human bone osteosarcoma cell line 1438, and in the human cervix adenocarcinoma cell line HeLa. Preferably, the MVA virus is capable 3O of an amplification ratio of r than 500 in CEF cells. The “amplification ratio” of a virus is the ratio of virus produced from an infected cell t) to the amount originally used to infect the cells in the first place (Input). A ratio of “1” between Output and Input s an amplification status wherein the amount of virus produced from the infected cells is the same as the amount initially used to infect the cells.

WO 39687 Recombinant MVAs The invention encompasses recombinant MVA s generated with any and all MVA viruses. In one embodiment, the recombinant MVA virus is a inant MVA-BN virus. The recombinant MVA virus comprises at least one heterologous nucleic acid sequence. In the context of this ion, the term “heterologous” c acid sequence refers to a nucleic acid sequence that is not naturally found in the MVA.

Preferably, the heterologous nucleic acid sequence is a sequence coding for at least one antigen, antigenic epitope, and/or a therapeutic compound. The antigenic epitopes and/or the antigens can be antigenic epitopes and/or antigens of an infectious agent. The infectious agents can be viruses, fungi, pathogenic unicellular eukaryotic or prokaryotic organisms, and parasitic organisms. In some embodiments, the infectious agent is a virus selected from any of the following: Rotavirus, Rubella virus, irus, Influenza virus, Flavivirus (particularly Dengue virus and Yellow Fever virus), Paramyxovirus (particularly measles virus, mumps virus, and respiratory syncytial virus (RSV)), Hepatitis virus (particularly tis A, B, and C viruses), Human immunodeficiency virus (particularly HIV- 1), Filovirus (particularly Ebola virus and Marburg virus) or from other viruses causing hagic fever. in some embodiments, the infectious agent is a bacterium selected from any of the following: Bacillus anthracis, meningococcus, pneumococcus, Haemophilus influenza, Corynebacterium diphtheriae, Clostridium tetani, Burkholderia, Francisella tularensis, Coxiella ii, or Bordetella pertussis.

Any antigen, including those that induce a T-cell response, can be expressed by the recombinant MVA of the ion. Viral, bacterial, fungal, and cancer antigens are preferred. Preferred antigens are antigens of any of the viruses or bacteria decribed above. HIV-1 antigens, Dengue virus antigens, x antigens, measles virus antigens, nza virus antigens, picornavirus antigens, coronavirus antigens and atory syncytial virus antigens are particularly preferred antigens. Preferably, . the n is a foreign antigen or neoantigen. Within the context of this invention, the term "neoantigen” refers to an antigen not naturally expressed by the poxviral vector.

In some embodiments, the administration induces T- and/or B-cell responses against a heterologous antigen encoded by the recombinant MVA. The T-cell response can be an effector and/or long term memory T-cell response. The B-cell response can be a neutralizing antibody response.

Administration The invention encompasses administration of a dose of an MVA to a human neonate or infant via any route. Preferred routes of administration include aneous (s.c.), intradermal , intramuscular (i.m.), in bone marrow (i.bm.) or intravenous (i.v.) injection, oral administration and l administration, especially intranasal administration, or inhalation. The quantity to be administered (dosage) depends on the subject to be treated, considering among other things the condition of the patient, the state of the individual's immune system, the route of administration and the size of the host.

The ion further encompasses MVAs for use as a pharmaceutical composition or vaccine for vaccinating a human neonate or infant, the use of MVAs as pharmaceutical compositions or vaccines for treating a human neonate or infant, and the use of MVAs in the preparation of pharmaceutical compositions or vaccines or medicaments for treating or vaccinating a human neonate or infant.

The pharmaceutical composition, e or medicament can lly e one or more auxiliary substances, such as ceutically acceptable and/or approved carriers, additives, antibiotics, preservatives, adjuvants, diluents and/or stabilizers.

Such auxiliary nces can be water, saline, glycerol, ethanol, oil, wetting or emulsifying agents, pH buffering substances, or the like. Suitable carriers are lly large, slowly metabolized molecules such as proteins, polysaccharides, polylactic acids, ycollic acids, polymeric amino acids, amino acid copolymers, lipid aggregates, or the like.

For the preparation of pharmaceutical compositions or vaccines or medicaments, the MVA according to the invention can be converted into a physiologically acceptable form. This can be done based on ence in the preparation of poxvirus es used for vaccination against smallpox (as described by Stickl et al. 1974).

The purified virus can be stored at -20°C, or -80°C, frozen in a liquid. Preferably, the WO 39687 virus has a titer of 5X108 TClD50/ml, and can be formulated in a buffered solution, for example, in 10 mM Tris, 140 mM NaCl, at pH 7.4.

The virus formulation can contain additional ves such as mannitol, dextran, sugar, glycine, e or polyvinylpyrrolidone or other auxiliary substances, such as antioxidants or inert gas, stabilizers or recombinant proteins (e.g., human serum albumin, or HSA) suitable for in vivo administration.

Alternatively, the vaccine can be produced by stepwise freeze-drying of the virus in a ation. For example, 108 particles of the virus can be lyophilized in 100 pl to 1 ml of phosphate-buffered saline (PBS) in the presence of 2% peptone and 1% HSA in an ampoule, preferably a glass ampoule. The glass ampoule is then sealed and can be stored between 4°C and room temperature for several months. However, as long as no need exists the ampoule is stored preferably at temperatures below - °C.

For vaccination or therapy, the virus can administered either systemically or locally, i.e., parenterally, subcutaneously, intravenously, intramuscularly, intranasally, or by any other path of administration known to the skilled practitioner.

The human neonate or infant can be vaccinated with a single administration of the MVA in the absence of any additional (“boosting”) administrations. In other ments, one or more boosting administrations are administered. In one embodiment, a second administration is given four weeks to eight weeks after the first ation administration. Preferably, the second administration is given at 2, 4, 6, or 8 weeks after the first administration. In other embodiments, a third, fourth, fifth, sixth, seventh, eighth, ninth, tenth, or additional administration is given. 2014/000693 The boosting stration can be administered to increase immune response when the initial se decays or to further increase the initial response. Thus, in some embodiments a boosting administration is provided to augment or reestablish a desired level of immune se.

The time n the first and second administrations and n an administration and a subsequent administration can vary. In one embodiment, the time between administrations is two to six weeks. In s embodiments, the time between administrations is at least 2, 4, 6, 8, 10, 12, 15, 30, or 52 weeks. In various embodiments, the time between administrations is at least 1, 3, 6, 9, 12, 24, 36, or 48 months. In various embodiments, the time between administrations is at least 1, 2, 3, 4, 5, 6, 7, 8, 9, or 10 years.

Protective immune response The invention encompasses the induction of a tive immune response against a poxvirus by administration of a dose of an MVA to a human neonate or .

Preferably the administration induces protective T- and B-cell responses against the poxvirus in the human neonate or infant prior to 6 months of age. Most ably, the immune response is induced in the absence of a second administration of the MVA. Within the context of this invention, the phrase "the immune response is induced in the absence of a second administration of the MV ” means that the immune response does not depend on the administration of a second (i.e., boosting) dose of the MVA. The immune response is induced by the first administration. Thus, within the context of this invention, the phrase “the immune response is induced in the absence of a second administration of the MV ” does not mean that a second administration is not administered; it only means that a second administration is not required to induce the protective immune response. In some embodiments, a second or subsequent administration is administered. The second or subsequent administration can increase the level of the immune response and/or the longevity of the immune response.

The protective immune response can protect at least 75%, 80%, 90%, 95%, 96%, 97%, 98%, 99% or 100% of the neonates or infants to which the MVA is administered from death and/or disease symptoms.

Preferably, the protective immune response is against a poxvirus, particularly an orthopoxvirus. In some embodiments, the poxvirus is a vaccinia virus or a variola virus. Most preferably, the protective immune response is against smallpox.

Preferably, the protective immune response is induced in the human neonate or infant prior to 6 months of age. More preferably, the protective immune response is induced in the human e or infant prior to 5, 4, 3, 2, or 1 months of age. Most preferably, the tive immune se is induced in the human neonate or infant within 4, 3, or 2 weeks of the administration.

Compositions The invention encompasses pharmaceutical compositions and vaccines comprising at least 108 TCleo of an MVA for administration to an infant or e to induce a protective immune response. ably, the composition comprises 108 TCleo, 2x108 TCID50, 3x108 TC|D50, 4x108 TC|D50, 5x108 TCleo, 6x108 TC|D50, 7x108 TCID50, 8x108 TClD5o, 9x108 TC|D50, or 109 TCID5o of an MVA. A particularly preferred dose is 2x108 TCleo, 3x108 , 4x108 TCleo, 5x108 TCleo, 6x108 TCID50, 7x108 TC|D50, 8x108 TClD5o, 9x108 TCleo, or 109 TCID50 of an MVA.

Especially preferred is a dose of 108 TCID50.

Examples The ing examples will further illustrate the present invention. It will be well understood by a person skilled in the art that the provided examples in no way may be interpreted in a way that limits the ability of the technology provided by the present invention to this examples.

Example 1: Mice Time-mated C578L/6J and BALB/c female mice were obtained from Harlan Winkelmann, whereas B-cell or/T11uMT transgenic, tion—induced cytidine deaminase-deficient (AID-deficient), MHC class |/B2m—deficient, T-cell receptor BSdeficient and FLT3-deficient mice on a CS7BL/6 background were obtained from the animal facilities of the University Ziirich or Bavarian Nordic-Munich. Litters were of mixed gender. Pups were weaned at 4 weeks of age.

Example 2: Vaccines and challenge virus.

The MVA used was MVA-BN, developed by Bavarian Nordic and deposited at ECACC under Accession No. V00083008 (see . The recombinant MVA- measles vaccine MVA-mBN85B encodes 3 measles genes: the Fusion-, Hemagglutinin- and Nucleo-proteins. The gene sequences were derived from RNA of measles strain Khartoum SUD/34.97 (Genotype B3). Both viruses were propagated and titrated on primary n embryo fibroblasts that were prepared from 11-day— old embryonated, en-free hen eggs (Charles River, Massachusetts, USA) and cultured in 64O medium. ECTV strain Moscow was obtained from the an Type Culture Collection (ATCC) under Accession No. VR-1372, and was propagated and titered on Vero C1008 cells (ECACC Accession No. 85020206), ined in Dulbecco’s Modified Eagle’s Medium (DMEM; Invitrogen) supplemented with 10% FCS without otics. All viruses were purified through a sucrose cushion.

Example 3: Immunization and challenge.

Mice were immunized subcutaneously within 6-24 hours after birth with 50 pl of viral suspension. 8-weeks old animals were used for the comparison of newborns to adults (i.e., adults were 8-weeks old). 1X108 TC|D50 MVA or MVA-mBN85B was applied, except for some s that received either a lower dose 6 TCleo) or 1X108 TC|D50 of UV-inactivated MVA. Samuelsson et al., J. Clin. Invest. 118, 1776-1784 (2008). Control animals were treated with TRIS-buffered saline, pH 7.7. For MVA- mBN85B, mice were zed twice three weeks apart. For immunogenicity studies, animals were bled and sacrificed at different time points and spleens were processed for flow cytometric analyses.

For ECTV challenge, mice were anaesthetized with ketamine/xylamine and virus was 3O applied asally in a volume of 25 pl, except for 2-week old animals, which received virus in a volume of 12.5ul. For each age group and mice strain, the optimal dose inducing 100% death within 2 weeks and with approximately a viral load of 8 Logo pfu in necropsied lung was determined. For 29-day old mice, the optimal dose was 1><104 TClD50 (4 times the LD50 determined for adult C57BL/6J mice; Samuelsson et al., J. Clin. Invest 118, 1776-1784 (2008)), except for the FLT3- deficient and TCRBS-deficient mice. In these highly susceptible mice, 1X103 TC|D50 of ECTV was sufficient. For - and 7week-old mice, the challenge dose was 1X102 TCID50 and 3X104 TC|D50, respectively. After challenge, weight loss sickness and death were monitored daily for 21 days. 5 to 7 pups were included in each group and data are representative of two or three experiments.

Example 4: ECTV plaque assay.

ECTV plaque assay was used to determine the viral load in necropsied lung. Lungs were homogenized and titered on Vero C1008 cells using four-fold serial dilutions starting at 1:100. After 3 days of incubation and a crystal violet staining (Sigma Aldrich), the titer was calculated from the first dilution step that revealed a mean plaque number s 150. e 5: ELISA.

Vaccinia-specific serum lgG titers were measured by direct ELISA as described previously. Garza et al., Vaccine 27, 5496-5504 (2009). Briefly, 96—well plates were coated overnight with MVA antigen. Test sera were titrated using twofold serial dilutions starting at 1:50. A sheep anti-mouse lgG-HRP (AbD Se'rotec) was used as detection antibody. The antibody titers were ated by linear regression and d as the serum dilution that resulted in an optical y of 0.30 at OD450.

Measles-specific serum lgG titers were measured with the Enzygnost® ELISA kit (Dade Behring), but using the sheep anti—mouse lgG conjugated to horseradish peroxidase.

Example 6: Plaque reduction neutralization test (PRNT) assay.

Vaccinia-based PRNT assay was performed as bed in Garza et al. Vaccine 27, 5496-5504 (2009). Briefly, nactivated sera were serially diluted and incubated with vaccinia virus Western Reserve (Advanced Biotechnologies lnc.). After 3O incubation the mixtures were allowed to adsorb on Vero cells for 70 minutes. Then, y medium was added and plates were ted for 24 hours. After staining with Crystal Violet, the neutralizing titer was determined as the serum on which was able to neutralize 50% of the mature virus.

Example 7: Flow cytometry and ELlSpot.

After erythrolysis, a part of the splenocytes were incubated 5 hours with or without the B8R-peptide (Tscharke et al., J. Exp. Med. 201, 95-104 (2005)) (5ug/ml BBR20_27), Coring) in the presence of GolgiPlugTM (BD Biosciences). Cells were then stained' with anti-CD8+-eF|uorTM-450, anti-CD4+-eFluorTM-780, anti-CD44—FITC, anti-CD62L- PercP-Cy5.5, anti-CD127-APC, anti-lFNy—PE—Cy7 (all eBioscience) and anti- Granzyme B-PE (Invitrogen). Intracellular staining was performed after fixation/permeabilization (BD Cytofix/CytopermTM, BD Biosciences). Flow cytometric analysis was performed using an LSR ll (BD ences). Data were analyzed with FlowJo (Tree Star). The rest of the splenocytes were stimulated 20 hours with or without B8R/vaccinia- or N/measles-specific (Halassy et al., Vaccine 24, 185-194 (2006); Bergen et al., PLoS one 5(4):e10297, 2010) peptides l; aa 335—345; N) and lFNy-secreting cells were detected by ELISpot assay (BD ences). The stimulation index was obtained by subtracting the number of unspecific spots from non-stimulated cells from the number of spots obtained with the specific stimulation. e 8: Neutralizing antibodies as well as effector and long-term memory T- cells are induced by MVA in n mice. n mice were zed at birth with a high dose (1X108 TCIDso) 0r low dose (2X106 TC|D50) of MVA used previously in newborn mice. ini et al., J. Immunol. 172, 6304-6312 (2004). Vaccinia-specific lgG antibody responses were determined by enzyme-linked immunosorbent assay (ELISA) performed 1, 2, 3, 4 and 7 weeks post-immunization (Fig. 1a). In adult mice, vaccinia-specific dies were detectable seven days ing a single immunization with 1><108 TCID50 of MVA and reached a plateau one week later. Surprisingly, specific IgG responses after a single high dose immunization at birth reached comparable antibody levels, albeit with a delay of 1-2 weeks (Fig. 1a). Despite the immaturity of the neonatal immune system, even vaccinia-neutralizing antibodies were induced, gh complete sero- conversion was not observed and titers were approximately 10-fold lower than in adult mice (Table 1).

Table 1: Vaccinia-specific neutralizing dy responses I-Age Treatment weeks postIII-I1 2 3 4 7 .—_EIEIEIEIIWI ' ' 10 ' ' 1.0 116 100.0 a in percent ' geometric mean titer The B-cell response induced by a single immunization with MVA-BN at birth was still detectable 16 weeks after immunization (Fig. 6) and could be d by a second immunization 3 or 4 weeks after birth. As with the B-cell response, a slight delay in the CD8+ T-cell responses induced by immunization with MVA at birth was observed.

The vaccinia-specific T-cell se measured by IFNy intracellular staining 2 weeks post-immunization of newborn mice was similar to the peak response in adult mice observed one week post immunization (Fig. 1b). Whereas no antibody response could be detected after vaccination with the low dose of MVA (Fig. 1a), the same or even higher levels of T-cell responses were induced by ation with the low dose (Fig. 1b). The presence of vaccinia-specific T-cells induced by MVA vaccination at birth was med by enzyme-linked immunospot (ELlSpot) assay, which detected ia-specific lFN-y producing cells already one week post immunization (Fig. 7).

This early time point is even more remarkable when considering the low number of CD8+ s in the spleen of one week old mice (Fig. 8). T-cell activation was also confirmed by analysis of Granzyme B expression in the CD8+ T-cell population. This effector molecule of cytotoxic T-cells was induced by immunization at birth with both doses of MVA at a similar level of expression as that seen in adults, albeit one week delayed (Fig. 10). For a more detailed analysis, the vaccinia-specific CD8+ T-cells were subdivided into effector, effector memory and central memory cells based on the differential expression of CD44, CD62L and CD127 as described by Kaech et al., Nat. Immunol. 4, 1191-1198 (2003). As expected, the majority of the vaccinia-specific T-cells were effector cells at the peak of the T—cell response in both newborn and adult mice (Fig. 1d). During the subsequent contraction phase, they acquired similar effector memory or l memory phenotypes in both age groups (Fig. 1d). As for the B-cell response, T-cells specific for MVA were still able 16 weeks after neonatal immunization (Fig. 7). No antigen-specific B— and T-cell responses were induced after UV treatment of MVA prior to zation (Fig. 6 and 7), revealing the requirement for transcription and protein synthesis of the non-replicating MVA. The lack of antigen-specific B- and T-cell responses after UV treatment was previously shown for Herpex Simplex Virus (Franchini et al. J. Virol. 75, 83-89 (2001)).

Example 9: MVA induces protection against a lethal ECTV challenge in two week old mice.

In order to investigate the functionality of the T- and B-cell responses induced by MVA immunization at birth even further, the intranasal ECTV challenge model was adapted to young mice. Four weeks post-neonatal immunizations with a low or high dose of MVA, s were challenged via the intranasal route with 1><104 TClD50 ECTV. All control mice treated with placebo (Tris-buffered saline, TBS pH 7.7; 1.21 mg/ml TRIS-(hydroxymethyl)-amino-methane, 8.18 mg/ml sodium chloride) died 9 to 12 days post-challenge (Fig. 2a) with imately 8 Log1o ECTV plaque forming units (pfu) in their lungs, s all mice treated with a dose of 108 TC|D50 MVA survived this vise lethal challenge and completely recovered after a minor transient weight loss (Fig. 2a and 2b). All vaccinated mice had cleared ECTV from their lungs confirming complete protection. Immunization with the low dose of MVA afforded protection in 80% of the mice, despite the fact that only T-cell ses but no antibodies could be detected prior to challenge in this group (Fig. 2a). In addition to the reduced survival rate, mice immunized with the low dose showed increased disease symptoms and body weight loss (Fig. 2b) compared to those ated with a dose of 1X108 TCID50 of MVA. The longevity observed for B- and T-cell responses after neonatal immunization with MVA-BN (Fig. 6 and 7) translated into long-term protection in ood: mice were fully protected from challenge with the lethal dose of 3X104 TC|D50 ECTV at the latest time point tested, i.e., 7 weeks after al immunization (Fig. 20). On the other hand, protection could already be demonstrated as early as 2 weeks after neonatal immunization, the earliest time point when ECTV challenge was technically feasible due to animal size. At this age, 102 TC|D50 of ECTV killed naive mice within 6 to 8 days, while MVA immunization at birth conferred 100% tion (Fig. 2d).

Example 10: Protection against lethal ECTV nge depends on the adaptive immune response.

It has previously been shown that injection of MVA at birth boosts early development of pDC and leukocyte precursors via an increase of FLT3 ligand (FLT3-L), which led to an increased resistance to viral infections in the first week of life. Franchini et al., J.

Immunol. 172, 6304-6312 (2004); Vollstedt et al., Eur. J. Immunol. 36, 1231-1240 (2006). Therefore, the role of FLT3-L in the protection against lethal ECTV challenge was investigated using FLT3-L knockout mice. These mice have about d less pDC than C57BL/6 wild type mice and are unable to up-regulate pDC. In addition, these mice lack other cell types of the innate immune system. Vollstedt et al., Eur. J.

Immunol. 36, 1231—1240 (2006). FLT3-L knockout mice were immunized with MVA at birth and challenged 4 weeks later with 1X103 TClD5o ECTV. All vaccinated mice survived the infection (Fig. 3a) and completely cleared ECTV from their lungs (Fig. 3b), while all non-vaccinated mice bed to infection. Since FLT3-L knockout mice are more sensitive to viral infection, this lower dose of 1X103 TC|D50 ECTV was chosen (Fig. 3a). Similar results were obtained in 2-week-old FLT3-L knockout mice.

As both B- and T-cell immune ses were not affected by the reduced level of pDC and the lack of other innate cells, it clearly indicates that the innate immune system is not the sole mechanism of protection induced by MVA.

The role of the adaptive immune response in the protection afforded by neonatal zation was investigated. T-cell receptor [38 (TCRBS) knockout mice are devoid of T—cells and are also unable to mount a vaccinia-specific B-cell response'due to the absence of T-helper cells. TCRBS knockout mice vaccinated with MVA at birth succumbed 11 to 12 days after an intranasal nge with 1><103 TCID50 ECTV, arguing for the ement of an adaptive immune response for protection (Fig. 30).

Similar to the FLT3-L knockout mice, this lower challenge dose was chosen based on the 'acute sensibility of TCRBS knockout mice to viral infection. At death, both untreated and MVA immunized mice had a viral load in their lungs comparable to naive wild type mice challenged with 1X104 TCleo ECTV (Fig. 3d). Using these two knockout mouse models, it was shown that the protection afforded by neonatal 3O zation was not due to an unspecific resistance offered by a d innate immunity but that it was afforded by vaccinia-specific adaptive immune responses mounted by a relatively undeveloped immune system.

Example 11: Both T- and B-cell ses are required for complete tion The role of cellular versus humoral immune responses in tion was examined.

The fact that 2-week-old mice were protected at a time when T—cell responses but hardly any antibodies could be detected led to the notion of a dominant role for T- cells in protection of newborn mice. Indeed, in the absence of CD8+ T-cells in [32m knockout mice, immunization with MVA did not induce protection, (Fig. 4a and b), although antibody responses were not affected. To evaluate the need for vaccinia- specific B-cells, T11uMT genetically ed mice were utilized. These mice have a rearranged heavy chain gene specific for a VSV virus and are thus are unable to te specific dies upon vaccination with MVA. In the absence of vaccinia— specific B-cell responses, one T11uMT mouse immunized with MVA died of ECTV infection two days before the end of the observation period (Fig. 4c) and only two- thirds of the mice had cleared ECTV from their lungs at the end of the 21-day observation period (Fig. 4d). Similar observations were made in AID knockout mice able to mount only lgM responses (Fig. 9). Taken together, these results reveal a primary role for cytotoxic s, which requires support by dies to afford complete protection induced by MVA vaccination at birth.

Example 12: inant MVA as vector for vaccines against childhood diseases The fact that a single immunization with MVA at birth induced short and long term protective immunity suggests an opportunity for its use as viral vector to develop childhood vaccines. Therefore the potential of inant MVA as vaccine against childhood disease was analyzed using MVA-Measles in the neonate mouse model.

MVA-Measles encodes three different measles virus proteins within the MVA backbone: the haemagglutinin- and fusion-proteins involved in binding and fusion 'with the host cell, as well as the nucleocapsid-protein associated with the viral single strand RNA. As seen for al vaccination with MVA, recombinant asles also elicited strong vaccinia-specific B- and T—cell responses after immunization at- birth and boost 3 weeks later. More importantly, also Measles-specific B- and T—cell ses were y detectable (Fig. 5a and 5b). The magnitude of the response was comparable to that seen in adult mice vaccinated with MVA-Measles using the same schedule, albeit with the same 1-2 week delay in antibody responses as seen for MVA-induced ia responses. Again, a single vaccination with MVA-Measles at birth led to a strong and sustained measles-specific antibody response with levels only slightly lower compared to those observed in mice receiving a booster vaccination (Fig. 5a).

Claims

1. Use of an Modified Vaccinia Ankara (MVA) in the preparation of a medicament for inducing a tive immune response against a orthopoxvirus in a human neonate or infant of less than 6 months of age, wherein the medicament is formulated for administration of a single dose of at least 108 TCID50 of the MVA to the human neonate or infant of less than 6 months of age, and wherein the medicament is formulated such that administration s protective T- and B-cell responses against a orthopoxvirus in the human neonate or infant prior to 6 months of age in the absence of a second administration of the MVA wherein the MVA is an MVA-BN being capable of reproductive replication in chicken embryo fibroplasts (CEF) but not capable of reproductive replication in a human nocyte cell line HaCaT, a human embryo kidney cell line HEK293, a human bone osteosarcoma cell line 143B or a human cervix adenocarcinoma cell line HeLa.

2. The use of claim 1, wherein the administration is stered to a human neonate within 72 hours after birth.

3. The use of any one of claim 1 or claim 2, wherein the MVA is a recombinant MVA.

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