The present invention relates to means and methods to protect against disease caused by bacteria belonging to the genus Chlamydia. In particular, the present invention relates to isolated B- and T-cell epitopes derived from the major outer membrane protein of Chlamydia psittaci which can be used against an infection with a species of the genus Chlamydia. More in particular, the invention provides a vaccine which can be used against chlamydiosis caused by Chlamydia psittaci in birds and man. In addition, the invention relates to a diagnostic method to diagnose the latter infections.
The genus Chlamydia comprises the species Chlamydia abortus, Chlamydia pneumoniae, Chlamydia psittaci, Chlamydia pecorum, Chlamydia felis, and Chlamydia caviae. Diseases caused by bacteria belonging to the genus Chlamydia are the following. Chlamydia pneumoniae causes acute or chronic bronchitis and pneumonia in humans and in some cases otitis media, obstructive pulmonary disease and pulmonary exacerbation of cystic fibrosis. It has also been associated with Alzheimer's disease, atherosclerosis, asthma, erythema nodosum, reactive airway disease, Reiter's syndrome and sarcoidosis in humans. Morever, Chlamydia pneumoniae causes respiratory disease in koalas. Chlamydia pecorum strains characterized so far have been limited to mammals, but not to a specific host family. They are serologically and pathologically diverse. The organism has been isolated from ruminants, a marsupial and swine. In koalas, C. pecorum causes reproductive disease, infertility and urinary tract disease. It has been a major threat to the Australian koala population. In other animals C. pecorum causes abortion, conjunctivitis, encephalomyelitis, enteritis, pneumonia and polyarthritis. Chlamydia felis is endemic among house cats worldwide. It causes primarily conjunctivitis and rhinitis. Chlamydia caviae comprises five known isolates, all isolated from guinea pigs. The natural infection site is the mucosal epithelium of the conjunctiva where a non-invasive infection is established. However, it is possible to infect the genital tract of guinea pigs eliciting a disease that is very similar to human genital infection. Chlamydia abortus strains are endemic among ruminants and efficiently colonize the placenta. Chlamydia abortus is the most common infectious cause of abortion in sheep, where the disease is known as ovine enzootic abortion (OEA) or enzootic abortion of ewes (EAE) in countries of Northern, Central and Western Europe. Enzootic abortion in goats is similar in severity to that occurring in sheep, although the spread and economical impact across Europe is less clear because of the lack of epidemiological data. The disease can also affect cattle, swine and horses but this is thought to occur to a much lesser extent. Sporadic zoonotic abortion due to C. abortus has been confirmed by analysis of isolates from women who work with sheep and goats. Chlamydia psittaci produces avian respiratory infections and is a serious threat to industrial poultry production. Additionally, it causes epizootic outbreaks in mammals and respiratory psittacosis or parrot fever in humans.
Protective immunity to Chlamydiaceae (Including the genus Chlamydia) that is observed in animals previously exposed to the pathogen is believed to be effected primarily through the action of CD4+ T helper type 1 (Th1) lymphocytes, CD8+ T lymphocytes, mononuclear phagocytes, and cytokines secreted by these cells (Cotter et al., 1995; Su and Caldwell, 1995; Beatty et al., 1997; Cotter et al., 1997; Johansson et al., 1997; Su et al., 1997; Wiliams et al., 1997; reviewed by Kelly et al., 2003).
Initial attempts to develop an effective vaccine for controlling both animal and human chlamydial infections began with the use of inactivated or live whole organism preparations in the 1950s, e.g. for C. abortus in sheep. In general, such preparations offered a reasonable level of protection, although they have been more successful in protecting animal infections than human infections (Vanrompay et al., 2005).
During the 1960s unsuccessful attempts were made to develop inactivated and live vaccines against C. trachomatis using both human and non-human primates. These vaccines reduced disease in some individuals but they enhanced disease in others resulting from stimulation of enhanced delayed-type hypersensitivity (DTH) response. Therefore, the use of whole organisms for developing human chlamydial vaccines was essentially abandoned.
In the early 1980s an attenuated strain of C. abortus was developed as a live vaccine and is one of the 5 commercially available vaccines in Europe and the USA, the other four being inactivated whole organism based vaccines (Longbottom and Livingstone, 2006). These commercial live-attenuated and inactivated vaccines offer good protection against OEA and significantly reduce the shedding of infective organisms, a factor important in limiting the spread of infection to other animals. However, concerns remain over the safety of using live-attenuated vaccines. There may also be a risk of the attenuated strain reverting to virulence, thus having the potential to cause disease and abortion in the vaccinated animal. Furthermore, the vaccine cannot be administered during pregnancy or to animals being treated with antibiotics limiting its use. In contrast, the inactivated vaccines can be administered to pregnant ewes, although care must be taken in handling and administering these vaccines as they are adjuvanted with mineral oils, which have the potential to cause tissue necrosis if accidentally self-injected. The only other animal chlamydial vaccines, which are commercially available are for C. felis infection in cats (Longbottom and Livingstone, 2006). Although vaccination is successful in reducing acute disease, it does not, however, prevent shedding of the organism and therefore chlamydial spreading in the population nor does it prevent re-infection. Following the identification of the major outer membrane protein (MOMP) as a structurally and immunologically dominant protein vaccine research largely focused on this protein. A certain level of protection has been achieved with COMC (chlamydial outer membrane complex) preparations, in which MOMP constitutes 90% or more of the protein content, using the guinea pig and mouse models for C. trachomatis genital tract infection, and in a mouse toxicity test for C. felis infection (Sandbulte et al., 1996; Pal et al., 1997). Studies on MOMP of C. psittaci were performed e.g. by Tan et al., 1990, Sandbulte et al., 1996 and Verminnen et al., 2005.
DNA vaccination, mimicking a live vaccine, creates protective CD4+ as well as CD8+ responses but antibody responses are low (Verminnen et al., 2010). Moreover DNA vaccines are still too expensive (especially for poultry) and the public is not (yet) ready to consume products from DNA vaccinated animals (in the case of C. psittaci eggs/meat).
Until now, completely safe and effective Chlamydia vaccines are still not available.
The present invention comprises an innovative vaccine that creates both optimal humoral and cellular immune responses by combining B cell and CD4 Th2 cell epitopes (humoral) and CD4 Th1 and CD8+ cytotoxic T cell epitopes (cellular) in a vaccine. In contrast, former and current studies on Chlamydia vaccine development are focusing on cellular responses only (CD8 and CD4 Th1), as they are believed to be crucial to protection against this obligate intracellular pathogen (Su and Caldwell, 1995; Morrison et al., 2000). Moreover, due to the Th1/Th2 paradigm (both responsible for different types of protective responses) vaccine development against infectious agents focuses on creating either a Th1 or Th2 response (Th1 or Th2 polarized vaccines). Thus, the construction of a non-polarized vaccine, deliberately inserting Th1 as well as Th2 epitopes is highly unusual and new as Th1 and Th2 cells act differently and even opposing.
The present invention relates to selected protective B- and T- (Th1 and Th2) cell epitopes of an immunodominant protein (the major outer membrane protein or MOMP). Such protein-based vaccines can be used against an infection with a species of the genus Chlamydia. These peptide sequences do not cause immunopathological reactions nor immunosuppressive T cell responses. Reversion to virulence is not applicable, thus enhancing the safety for both animals and humans. The epitopes can be used in any suitable vector, preferably a vector which: a) can be used in the presence of species-specific maternal antibodies and b) allows easy and cost effective vaccine mass production. Moreover, and surprisingly, the present invention demonstrates that both the cellular- and humoral immune response are required to protect against an infection with a species of the genus Chlamydia.
Lines: 1) Chlamydia trachomatis (Ctra), 2) Chlamydia muridarum (Cmur), 3) Chlamydia pneumoniae (Cpn), 4) Chlamydia felis (Cfel), 5) Chlamydia caviae (Ccav), 6) Chlamydia abortus (Cabo). Lines 7 till 18: Chlamydia psittaci strains 84/2334, 6BC, CP3, GD, NJ1, 92/1293, Cal10, VS225, WSRTE30, M56 and WC. The ompA and MOMP sequence of reference strain 92/1293 used for vaccine design is underlined.
The present invention relates to the use of isolated peptides comprising B- and T-cell epitopes for producing a vaccine against species of the genus Chlamydia, and more in particular to induce an immunoprotective response against an infection with a species of the genus Chlamydia.
The present invention relates to a composition comprising at least one isolated peptide comprising a B-cell epitope located in a variable amino acid region of the major outer membrane protein (MOMP) of Chlamydia psittaci and at least one isolated peptide comprising a T-cell epitope located in a conserved or variable amino acid region of the MOMP of Chlamydia psittaci. In particular, the invention relates to a composition comprising one or more peptides, each of said peptides comprising one or more epitopes selected from the list consisting of a B-cell epitope, a CD4+ Th2 cell epitope, a CD4+ Th1 cell epitope and a CTL epitope; wherein said composition comprises at least a B-cell epitope, a CD4+ Th2 cell epitope, a CD4+ Th1 cell epitope and a CTL epitope, and wherein the epitopes are located in the major outer membrane protein (MOMP) of Chlamydia psittaci and wherein the composition does not comprise the full-length Chlamydia MOMP protein.
The composition is specifically designed to induce an immunoprotective response against an infection with a species of the genus Chlamydia. In particular, the combination of the B- and T-cell epitope containing peptides is not equal to the complete or full-length MOMP protein, in particular the Chlamydia psittaci MOMP protein. More particular, the B-cell epitope is located in the variable region I, II or IV and the T-cell epitope (including CD8+, CD4+ Th1, and CD4+ Th2 cell epitopes) is located in the conserved region I or IV, or in variable region IV. The MOMP protein of Chlamydia psittaci is described by Vanrompay et al., 1998 (p 5496
With the term “B cell-epitope” is meant a part of an antigen that induces antibody production upon recognition by the host's immune system.
A “T-cell epitope” is a part of an antigen that induces a CD4+ Th1 (T helper, HTL), CD4+ Th2 (T helper, HTL) or CD8+ cell (cytotoxic, CTL) response upon recognition by the host's immune system. T helper (Th) cells are considered major players in the response against infectious organisms. To convey their full function, Th cells secrete a variety of cytokines, which define their distinct actions in immunity. Th cells can be subdivided into three different types based on their cytokine signature, Th1, Th2 and Th17 cells. “Th1 cells” secrete IFN-gamma (pro-inflammatory cytokine), which is the main macrophage-activating cytokine and TNF-β, which also activates macrophages, inhibits B cells and is directly cytotoxic for some cells. Th1 cells allow the production of IgG2a antibodies in mice and of IgM, IgA, IgG1, IgG2 and IgG3 antibodies in humans. “Th2 cells” secrete IL-4, IL-5, IL-6, IL-9 and IL-13 all of which activate B cells, and IL10 (important anti-inflammatory cytokine), which inhibits macrophage activation. Th2 cells induce IgG1 and IgE antibodies in mice and IgM, IgG4 and IgE in humans. Th17 cells secrete the pro-inflammatory cytokine IL-17 (Murphy et al., 2008; Annunziato and Romagnani, 2009).
A peptide comprising a CTL epitope (CD8+) usually consists of 13 or less amino acid residues in length, 12 or less amino acids in length, or 11 or less amino acids in length, preferably from 8 to 13 amino acids in length, most preferably from 8 to 11 amino acids in length (i.e. 8, 9, 10, or 11). A peptide comprising a HTL epitope (CD4+) consists of 50 or less amino acid residues in length, and usually from 6 to 30 residues, more usually from 12 to 25, and preferably consists of 12 to 20 (i.e. 12, 13, 14, 15, 16, 17, 18, 19, or 20) amino acids in length. Peptides comprising B cell epitopes do not have a defined length and can vary from 5 to 30 amino acids in length, preferably from 5 to 15 amino acids in length, i.e. 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, or 15 amino acids.
In a specific embodiment, a peptide comprising a T cell epitope has a length of 6 to 50 amino acids and a peptide comprising a B cell epitope has a length of 5 to 30 amino acids.
Hence, it is to be understood that peptides with a defined length and comprising the epitopes specified herein are part of the present invention and can be used in the compositions and methods as described herein. In a specific embodiment, the peptides are immunogenic peptides, i.e. peptides capable of eliciting an immune response in an organism, including a cellular and/or humoral response. More particular, the present invention comprises an innovative vaccine that creates both humoral and cellular immune responses by combining B cell and CD4 Th2 cell epitopes (humoral) and CD4 Th1 and CD8+ cytotoxic T cell epitopes (cellular) in a composition.
The term “isolated” is used to indicate that a cell, peptide or nucleic acid is separated from its native environment. Isolated peptides and nucleic acids may be substantially pure, i.e. essentially free of other substances with which they may bound in nature.
With the term ‘induction of an immunoprotective response’ is meant a (humoral and/or cellular) immune response that reduces or eliminates one or more of the symptoms of disease, i.e. clinical signs, lesions, bacterial excretion and bacterial replication in tissues in the infected subject compared to a healthy control. Preferably said reduction in symptoms is statistically significant when compared to a control.
Infections with a species of the genus Chlamydia are infections with one or more of the species selected from the group consisting of: Chlamydia abortus, Chlamydia pneumoniae, Chlamydia psittaci, Chlamydia pecorum, Chlamydia felis, and Chlamydia caviae.
In a particular embodiment, the present invention provides peptides suitable for vaccine design. Suitable peptides comprising T-cell epitopes correspond to SEQ ID NO 1, 7, 8, 9, 10, 11, 12, 13, 18, 20, 21, 22, 24, 25, 26, 27, 29, 30, 31, 32, 35, 41, 42, 43, 44, 46, 49, 50, 51, 53, 54, 55, 56, 60, 61, 63, 64, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 84, 85, 86, 87, and 91. As can be derived from the data in Table 1, said peptides are characterized as follows:
In addition, peptides comprising a B-cell epitope correspond to SEQ ID NO 32-33, 45-46 and 90-96.
The composition of the present invention preferably comprises specific combinations of said peptides thereby inducing a humoral as well as a cellular immune response. The composition therefore comprises one or more peptide(s) comprising at least one B cell epitope, at least one CD4 Th2 cell epitope, at least one CD4 Th1 cell epitope and at least one CD8+ cytotoxic T cell epitope.
More specifically, the present invention relates to the composition as indicated above, wherein said isolated B cell epitope consists of the amino acid sequence GTASATT (SEQ ID NO 92), GTDFNN (SEQ ID NO 93) or NPTLLGKA (SEQ ID NO 94), or variants thereof, which are located in the variable domain (VS) I, II and IV, respectively of the MOMP of Chlamydia psittaci serovar D strain 921/1293, and, wherein said isolated T-cell epitope consists of the amino acid sequence
selected from the group consisting of:
or variants thereof, which are located in the conserved region I or IV, or in the variable domain IV, of the MOMP of Chlamydia psittaci serovar D strain 921/1293. Optionally, flanking amino acids or regions of the specified B- and T-cell epitopes can be part of the peptide sequences to be included in the composition.
In a specific embodiment, the invention relates to the composition and use as indicated above, wherein the peptide comprising a B-cell epitope is selected from the group consisting of:
TGTASATT (SEQ ID NO 95), KGTDFNNQ (SEQ ID NO 96) and NPTLLGKA (SEQ ID NO 94), or a variant thereof, and wherein the peptide comprising a T-cell epitope comprises or consist of an amino acid sequence selected from the group consisting of: SEQ ID NO 1, 7-13, 18, 20-22, 24-27, 29-32, 35, 41-44, 46, 49, 50, 51, 53-56, 60, 61, 63-82, 84-87, and 91, or a variant thereof. In a particular embodiment, the peptide comprising the B-cell epitope NPTLLGKA (SEQ ID NO 94) and the CD4 Th2 cell epitopes TAVLDLTTW (SEQ ID NO 116) and TTVDGTNTYSDFL (SEQ ID NO 117) is AQPKLATAVLDLTTWNPTLLGKATTVDGTNTYSDFL (SEQ ID NO 98).
In a preferred embodiment the peptide comprising a T-cell epitope is selected from the group consisting of the amino acids at position:
30-44, 35-49, 36-50, 37-51, 257-271, 262-276, 263-278, 264-279, 266-280, 267-281, 268-282, 269-283, 279-293, 280-294, 281-295, 282-296, 287-302, and 326-340 of the 356 amino acids MOMP of Chlamydia psittaci serovar D strain 921/1293, or variants thereof. The Chlamydia psittaci serovar D strain 921/1293 is described by Vanrompay et al., 1998 and in
The compositions and methods of the present invention also encompass variants of the above specified peptides comprising the epitopes. “Variants” of the B and T-cell epitopes on the corresponding peptide sequences of the different strains or species are also part of the invention, i.e. those peptide sequences at corresponding amino acid positions when aligned to a reference sequence (e.g.
The invention more specifically relates to the composition and use as indicated above, wherein said isolated B-cell epitopes and T-cell (Th2) epitopes are part of a fragment of the 356 amino acid MOMP of Chlamydia psittaci serovar D strain 92/1293 which is encoded by the nucleic acid sequence GCT AGC GAA CCA AGT TTA TTA ATC GAT GGC ACT ATG TGG GAA GGT GCT TCA GGA GAT CCT TGC GAT CCT TGC ACA GGA ACA GCA AGT GCT ACT ACT AAA GGA ACT GAT TTC AAT AAT CAA GCT CAG CCT AAA TTA GCC ACT GCT GTT TTA GAT TTA ACC ACT TGG AAC CCA ACA CTT TTA GGA AAG GCC ACA ACT GTC GAC GGC ACC AAT ACT TAC TCT GAC TTC TTA GGT ACC (SEQ ID NO 100), and/or, wherein said T cell (Th1) epitopes are part of the amino acid sequence corresponding to amino-acids 257-301 of the 356 amino acid MOMP of Chlamydia psittaci serovar D strain 92/1293.
The present invention relates, even more specifically, to the composition or use as indicated above wherein said species of the genus Chlamydia is Chlamydia psittaci. As such, the present invention relates to the prevention of morbidity or mortality, or to treatment of morbidity due to infection with Chlamydia psittaci in subjects. Subjects are humans or animals, but preferably are birds and more preferably poultry, including but not limited to chickens, ducks, geese and turkeys.
A preferred means of administration of the peptides of the present invention is mucosal delivery, more preferably administration by aerosol or inhalation. Other means of administration are all other systemic and mucosal administration routes as well as in ovo administration methods, well known to the skilled person.
The composition of the present invention can further comprise a pharmaceutically acceptable excipient conventional in the art. Non limiting examples of suitable excipients include starch, glucose, lactose, sucrose, gelatin, malt, rice, flour, chalk, silica gel, sodium stearate, glycerol monostearate, talc, sodium chloride, dried skim milk, glycerol, propylene, glycol, water, ethanol and the like.
In the composition, also referred to as polyepitope vaccine, the peptides can be present as a mixture of individual peptides and/or (part of) the peptides can be linked to each other and/or are part of vector/carrier construct. In a specific embodiment, the composition comprises a polyepitope construct. The term polyepitope vaccine as used herein denotes a composition that does not occur as such in nature. Hence, the “polyepitope vaccine” of the present invention does not encompass a wild-type full-length protein but includes two or more isolated epitopes of the present invention, not necessarily in the same sequential order or number (repetitions might be used) as in nature. The polyepitope vaccine of the present invention preferably comprises 2 or more, 5 or more, 10 or more, 13 or more, 15 or more, 20 or more, or 25 or more epitopes of the present invention. More specific, the polyepitope vaccine comprises 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12. 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, or more epitopes. The epitopes of the polyepitope vaccine can be prepared as synthetic peptides or recombinant peptides. These synthetic peptides or recombinant peptides can be used either individually or directly or indirectly linked to one another. Optionally, two or more of the epitopes (either B-cell and/or T-cell epitopes) can be linked in a construct, referred to herein as a polyepitope construct, and are either contiguous or are separated by a linker or one or more spacer amino acids. “Link” or “join” refers to any method known in the art for functionally connecting epitopes. More particular, the polyepitope vaccine of the present invention is a synthetic or recombinant string of two or more peptides harbouring (part of) the epitopes as described herein. Methods for preparing a polypeptide, which may comprise a polyepitope (polyepitope vaccine/construct), are known in the art and are described in for example the book Molecular Cloning; a laboratory manual by Joseph Sambrook and David William Russell—2001.
According to a specific embodiment, the composition or polyepitope vaccine of the present invention comprises the following B-cell epitopes: GTASATT (SEQ ID NO 92), GTDFNN (SEQ ID NO 93) and NPTLLGKA (SEQ ID NO 94), or a variant thereof, and the following T-cell epitopes: SEQ ID NO 20 and 101-117, or a variant thereof. In a particular embodiment said B-cell epitopes are comprised in the following peptide sequences: SEQ ID NO 94-96, and said T-cell epitopes in the composition are comprised in the following peptide sequences: SEQ ID NO 7-8, 70, 71, 73, 75-77, 79-81 and 91, or a variant thereof.
In a preferred embodiment, the composition or polyepitope vaccine of the present invention comprises the following peptide sequences:
AA sequence 30-51 (EPSLLIDGTMWEGASGDPCDPC, CD4Th2 epitope in CS1; SEQ ID NO 97), AA sequence 93-100 (TGTASATT, immunodominant B cell epitope in VS1; SEQ ID NO 95), AA sequence 163-170 (KGTDFNNQ, serovar D B-cell epitope in VS2; SEQ ID NO 96), AA sequence 305-340 (AQPKLATAVLDLTTWNPTLLGKATTVDGTNTYSDFL, CD4Th2 and immunodominant B cell epitope in VS4; SEQ ID NO 98) (the CD4Th2—B cell cluster), and AA sequence 257-301
(AATDTKSATLKYHEWQVGLALSYRLNMLVPYIGVNWSRATFDADT) (CD4Th1—CD8 cluster in CS4; SEQ ID NO 99), or variants thereof
In a further preferred embodiment, the composition or polyepitope vaccine of the present invention comprises the following peptide sequences: AA sequence 53-67 (TWCDAISIRAGYYGD, CD4Th1 and CD8 epitope; SEQ ID NO 20), AA221-235 (EMLNVTSSPAQFVIH, CD4Th2 epitope; SEQ ID NO 62), and AA163-170 KGTDFNNQ, B-cell epitope; SEQ ID NO 96).
The present invention further includes an isolated nucleic acid encoding the epitopes, peptides or polyepitope construct as described herein. Particular nucleic acids encoding the peptides of the invention are the following.
Further embodiments of the present invention are a vector which comprises a nucleic acid encoding at least the polyepitope vaccine or construct as described herein, and which is capable of expressing the respective peptides. A host cell comprising the expression vector and a method of producing and purifying the herein described peptides are also part of the invention. Suitable vectors that can be used in the present invention are known to the skilled in the art and include a plasmid, a bacterial, a viral vector or a yeast vector. Examples of bacterial vectors are Salmonella typhi, BCG (Bacille Calmette Guerin) and Listeria. Examples of viral vectors are poxvirus, Alphaviruses (Semliki Forest Virus, Sindbis Virus, Venezuelan Equine Encephalitis Virus (VEE), Herpes simplex Virus (HSV), Kunjin virus, Vesicular Stomatitis Virus (VSV) replication-deficient strains of Adenovirus (human or simian), polyoma vectors (such as SV40 vectors, bovine polyoma), CMV vectors, papilloma virus vectors, influenza virus, measles virus, and vectors derived from Epstein Barr virus. A wide variety of other vectors useful for therapeutic administration or immunization, e.g. lentiviral vectors, retroviral vectors, and the like, will be apparent to those skilled in the art. Examples of yeast vectors are a Hansenula cell or Saccharomyces cerevisiae cell. The composition according to the present invention can further comprise an antigen delivery system, which optimizes the presentation of the antigen. In a specific embodiment, the antigen delivery system is an enzymatically inactive recombinant adenylate cyclase (CyaA) originating from Bordetella pertussis (the causative agent of whooping cough) (Ladant et al., 1999; and in EP1576967).
The composition of the present invention can further comprise an adjuvant. Suitable adjuvants are 1) receptor specific (mucosal) adjuvants such as for instance adjuvants binding to pathogen recognition receptors (PRRs) and ganglioside receptor binding toxins, 2) antigen presenting cell targeting (mucosal) adjuvants such as for instance the ones described by Gerdts et al., (2006). Further examples of adjuvants include, but are not limited to, tensoactive compounds (such as Quil A), mineral salts (such as aluminium hydroxide), micro-organism derived adjuvants (such as muramyl dipeptide), oil-in-water and water-in-oil emulsions (such as Freund's incomplete adjuvant), particulate antigen delivery systems (such as liposomes, polymeric atmospheres, nanobeads, ISCOMATRIX), polysaccharides (such as micro-particulate inulin), nucleic acid based adjuvants (such as CpG motivs), cytokines (such as interleukins and interferons), activators of Toll-like receptors and eurocine L3 en N3 adjuvantia. In a specific embodiment, the adjuvant is an ISCOM™ (ISCOTEC AB, Uppsala, Sweden).
The composition of the present invention can be used as a medicament, and more specific against an infection with a species of the genus Chlamydia, preferably wherein said species of the genus Chlamydia is Chlamydia psittaci. In a further embodiment, the composition is a vaccine. With the term ‘vaccine’ is meant a biological preparation that elicits a protective immune response in a subject to which the vaccine has been administered. Preferably, the immune response confers some beneficial, protective effect to the subject against a subsequent challenge with the infectious agent. More preferably, the immune response prevents the onset of or ameliorates at least one symptom of a disease associated with the infectious agent, or reduces the severity of at least one symptom of a disease associated with the infectious agent upon subsequent challenge.
Individual and isolated peptides comprising B- and/or T-cell epitopes and comprising the amino acid sequences as described herein (resp. characterized by SEQ ID NO 89, 90, 92-96, and 98; and by SEQ ID NO 1, 7, 8, 9, 10, 11, 12, 13, 18, 20, 21, 22, 24, 25, 26, 27, 29, 30, 31, 32, 35, 41, 42, 43, 44, 46, 49, 50, 51, 53, 54, 55, 56, 60, 61, 63, 64, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 84, 85, 86, 87, 91, 97, and 99) are also part of the present invention, as well as the nucleic acids encoding them. As demonstrated, said peptides are particular useful for the development of a vaccine against a species of the genus Chlamydia, and more specific C. psittaci. Hence, any combination of two or more of these peptides for producing a polyepitope vaccine and for use in developing a composition or vaccine is part of the present invention. In a specific embodiment, the polyepitope vaccine comprises or consists of a combination of two or more peptides comprising a T cell epitope as described herein. In a further embodiment, the polyepitope vaccine comprises or consists of a combination of two or more peptides comprising a B-cell epitope of the present invention.
In a further aspect of the current invention, administration of the composition as described herein, and in particular a vector comprising the peptides or nucleic acids of the invention, can overcome the inactivating (i.e. neutralizing) effects of maternal antibodies. It is well-known in the art that maternally-transmitted antibodies interfere with the efficacy of early vaccination programs in young subjects. Accordingly, the present invention provides a composition and the use thereof for effectively vaccinating a subject infected with a species of the genus Chlamydia that has maternal antibodies against said species. For birds, the composition can be administered according to the present invention in ovo and to hatchlings. In bird embryos, maternal antibodies are deposited in the yolk and are taken up by the embryo as the yolk is resorbed. Typically, maternal antibodies can be detected in the embryo by embryonic day 15. Accordingly, the present invention is useful in increasing the efficacy of vaccines administered after embryonic day 15, more preferably after embryonic day 17, to birds in ovo. Additionally, the methods disclosed herein may be carried out to vaccinate a young bird soon after hatch. In young chickens, maternal antibodies generally disappear by three weeks after hatch. Accordingly, in young birds, the composition of the present invention is administered within about four weeks post-hatch, preferably within about three weeks post-hatch, more preferably within about two weeks post-hatch, still more preferably, within about one week post-hatch, and most preferably within about the first three days post-hatch. Typically, vaccination will be carried out at the time that the birds are transferred from the hatcher (usually one or two days post-hatch).
In an even further embodiment, the invention includes a prime-boost immunization or vaccination against a species of the genus Chlamydia. The priming can be done with the composition, peptides or nucleic acids as described herein. Equally, boosting can be done with the composition, peptides or nucleic acids as described herein.
The invention thus also relates to a method of immunizing a subject against a species of the genus Chlamydia, more specific C. psittaci, comprising administering to the subject the composition as described herein in a prime-boost regimen. In its broadest sense, the term of “prime-boost” refers to the successive administrations of two different vaccine types or immunogenic composition types having at least one epitope or immunogen in common. The priming administration is the administration of a first vaccine or composition type and may comprise one, two or more administrations. The boost administration is the administration of a second vaccine or composition type and may comprise one, two or more administrations, and, for instance, may comprise or consist essentially of annual administrations. The “boost” may be administered from about 2 weeks to about 6 months after the “priming”, such as from about 2 to about 8 weeks after the priming, and advantageously from about 2 to about 6 weeks after the priming, and more advantageously, about 2, 3 or 4 weeks after the priming. In a specific embodiment, the prime and boost compositions are the same, and in particular the same peptide composition as described herein.
The present invention further relates to an in vitro method to diagnose an infection with Chlamydia psittaci in a subject comprising:
Such methods are well-known to the skilled person and can be performed by a variety of standard procedures, such as detection of radioactivity, fluorescence, luminescence, chemiluminescence, absorbance, or by microscopy, imaging, etc.
The present invention further encompasses a diagnostic kit comprising at least one peptide comprising a B-cell epitope as described herein. Examples of diagnostic kits include but are not limited to immunoassays including immunohistochemistry, enzyme-linked immunosorbent assay (ELISA), western blotting, immunoradiometric assay (IRMA), lateral flow, dipstick tests, immuno histo/cyto-chemistry and other assays known to those of skill in the art. Immunoassays can be used to determine presence or absence of an antibody in a sample as well as the amount of an antibody in a sample.
A “sample” may include fluid (e.g. blood, serum, saliva, urine, cerebral spinal fluid, pleural fluid, milk, lymph, meat juice, sputum and semen), solid (e. g., stool) or tissue (e.g. cervical tissue) sections taken (isolated) from a subject.
In a particular embodiment, the peptides comprising a B-cell epitope used in the diagnostic method and kit comprises or consists of the following amino acid sequence: 1) TGTASATT (SEQ ID NO 95; immnodominant B cell epitope in VS1), 2) KGTDFNNQ (SEQ ID NO 96; serovar D epitope in VS2) and/or 3) NPTLLGKA (SEQ ID NO 94; immunodominant B cell epitope in VS4), or a variant thereof. Even more particular, the peptide has a length of 5 to 30 amino acids.
The present invention is illustrated by the following Examples, which should not be understood to limit the scope of the invention to the specific embodiments therein.
We performed B- and T cell epitope mapping of the C. psittaci ‘major outer membrane protein’ (MOMP) and used B- and T cell epitopes to create a C. psittaci subunit (polyepitope) vaccine, which was validated in a pre-clinical trial in specific pathogen free (SPF) chickens. C. psittaci strain 92/1293, isolated from a severe outbreak of respiratory disease in a commercial broiler turkey farm in the Netherlands, was used (Vanrompay et al., 1993). The strain was isolated from a pooled homogenate of the lungs, the cloacae and the spleens of diseased turkeys and was characterized as serovar D and genotype D (Geens et al., 2005). Bacteria were grown in Buffalo Green Monkey (BGM) cells as previously described (Vanrompay et al., 1992) and the titration was performed by the method of Spearman and Kaerber (Mayr et al., 1974).
1. B Cell Epitope Mapping
For B cell epitope identification, overlapping synthetic peptides of 8 amino acids (7 amino acids overlap) of the variable domains I to IV of the MOMP sequence were coupled on pins via an extra C-terminal cysteine (Pin-peptides, Pepscan Systems, Lelystad, The Netherlands). A total amount of 100 nmol peptide was coupled to each pin.
The results of the pin-peptide ELISAs for B cell epitope mapping of the MOMP of C. psittaci serovar D strain 92/1293, a highly virulent genotype D strain infecting poultry, are presented in
When using serum of SPF turkeys immunized with recombinant MOMP of strain 92/1293, peptide 23 gave a weak signal (
Moreover the B-cell epitopes 12 and 43 induce sero-neutralizing antibodies by immunizing SPF chickens with peptide 12 or 43 coupled to the carrier protein KLH (keyhole limpet hemocyanin).
The identified B cell epitopes TGTASATT and NPTLLGKA can be used in an antibody ELISA for detecting C. psittaci antibodies in both humans and animals. Immunodominant B cell epitopes can be used as pin-peptides in a highly sensitive antibody ELISA. The serovar specific epitope KGTDFNNQ can be used as pin-peptide in a serovar D-specific antibody ELISA.
2. T Cell Epitope Mapping
For T cell epitope identification, overlapping synthetic peptides of 15 amino acids (14 amino acids overlap) of the complete MOMP sequence were produced (Pep-T-Topes, Pepscan Systems) in 96-well flat bottom tissue culture plates (Greiner Bio-one, Wemmel, Belgium) with an amount of 1-2 mg peptide per well.
Pep-T-Topes were used to identify the T cell epitopes on the MOMP of C. psittaci serovar D strain 92/1293. T-cell epitope mapping was based on: a) lymphocyte proliferation assays, b) flow cytometry on proliferating cells using CD4 and CD8 cell surface markers, c) an IFN-γ ELISA on supernatant of proliferating cells and d) an IL-6 bioassay on supernatant of proliferating cells (Lynagh et al., 2000; Zubiaga et al., 1990). Table 1 contains the complete results of B- and T-epitope mapping.
Peptides eliciting one or more of following characteristics are categorized as suitable for vaccine design:
a) Counts per minute (Cpm) in proliferation assay>10000,
b) % CD4≧17.5,
c) % CD8>14.2,
d) IFN-γ>9 pg/ml, and
e) IL-6>1.9 pg/ml.
Peptides comprising T-cell epitopes suitable for vaccine design correspond to SEQ ID NO 1, 7, 8, 9, 10, 11, 12, 13, 18, 20, 21, 22, 24, 25, 26, 27, 29, 30, 31, 32, 35, 41, 42, 43, 44, 46, 49, 50, 51, 53, 54, 55, 56, 60, 61, 63, 64, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 84, 85, 86, 87, and 91. From these, peptides especially useful to include in the composition of the present invention are the following:
From these peptides, a first selection was made to design a polyepitope vaccine.
Many CD4 Th1 epitopes were present on the MOMP and they were found in combination with CD8 epitopes. Especially peptide 281-295 contains a very strong CD4 Th1-CD8 epitope (108.088 cpm). Moreover, these epitopes are located in a large cluster of multiple CD4 Th1 epitopes, one additional CD8 epitope and two CD4 Th2 epitopes present on a peptide, covering amino acids 257 to 296.
1TC (cpm):T-cell proliferation assay (counts per minute)
2GTASATT: the identified immunodominant B-cell epitope.
3GTDFNN: the serovar D- specific B-cell epitope
4NPTLLGKA: the identified immunodominant B-cell epitope
3. C. psittaci Vaccine
Peptides including the identified B and T cell epitopes of the MOMP of C. psittaci strain 92/1293 were synthetically designed.
4. Vaccination Trial 1: Vaccination of SPF Chickens
Experiments were performed in negative pressure isolators (IM 1500, Montair Sevenum, the Netherlands). The experimental design was evaluated and approved by the Ethical Commission for Animal Experiments of Ghent University. To evaluate the polyepitope vaccine, 42 specific pathogen free (SPF) chickens (Lohman, Germany) were divided into 6 groups of 7 animals each. The vaccination scheme and the experimental set-up are presented in Table 3 and 4. The animals were vaccinated by aerosol (Cirrus™ nebulizer; 5 μm aërosol particle size; Laméris, Aartselaar, Belgium) providing a vaccine dose of 500 μg of each synthetic peptide/animal. The control animals each received 60 μg of ISCOMS by aerosol. Primo vaccination was performed in 7 day-old chickens of groups 1 to 6 (Table 3). At the age of 4 weeks, animals of groups 1 to 4 were aerogenically infected using the Cirrus™ nebulizer, while those of groups 5 and 6 received a booster vaccination. At the age of 7 weeks, all animals of groups 1 to 4 were euthanized, while those of groups 5 and (age 6 weeks) were aerogenically infected using the Cirrus™ nebulizer. The experimental infection dose in each isolator was 106 TCID50 of strain C. psittaci 92/1293. Animals of groups 5 and 6 were euthanized at 21 days post infection (p.i.).
4.1. Monitoring and Sampling
Clinical signs were scored daily until necropsy. Pharyngeal and cloacal excretion of C. psittaci was monitored on day 1 of the experiment and on every other day starting at 4 days post infection (p.i.) until necropsy at 21 days p.i., using rayon-tipped, aluminium shafted swabs (Colpan; Fiers, Kuurne, Belgium) provided with C. psittaci transport medium (sucrose 74.6 g/l (Acros Organics, Geel, Belgium); KH2PO4 5.1 g/l and K2HPO4 1.2 g/l (Sigma); L-glutamic acid mono potassium salt 0.9 g/l (Invitrogen, Merelbeke, Belgium) and fetal calf serum 10% v/v (Greiner, Wemmel, Belgium); gentamycin 50 μg/ml (Invitrogen); vancomycin 100 μg/ml and streptomycin 100 μg/ml (Soenen, Merelbeke, Belgium); nystatin 25000 U/ml (Sigma) pH 7). Swabs were stored at −80° C. until processed.
Blood samples for the detection of MOMP-specific serum antibody titres were collected prior to each vaccination, immediately prior to the experimental infection and at euthanasia at 21 days p.i. The samples were stored overnight at room temperature, centrifuged (300×g, 10 min, 4° C.) and afterwards serum was collected. The serum was pretreated with kaolin to remove background activity (Novak et al., 1993) and stored at −80° C.
At the time of euthanasia, 21 days p.i., proliferative responses of peripheral blood lymphocytes and spleen lymphocytes were determined by use of a T cell proliferation assay. Additionally, the amount of immune cells in blood and spleen was determined by flow cytometry. At euthanasia, all chickens were examined for gross lesions. The scoring system for gross pathology is presented in Table 5. Cryostat tissue sections of conchae, the conjunctivae, the trachea, the lungs, thoracic and abdominal airsacs, the pericardium, liver and spleen were prepared for the presence of chlamydial antigen.
4.2. Clinical Signs
Clinical signs could be observed in all animals of the control groups (group 1 and 5) starting from day 4 p.i. until the end of the experiment on day 21 p.i. All control chickens appeared lethargic and showed anorexia, conjunctivitis, rhinitis, respiratory distress and diarrhea. At first, the main symptoms were lethargia, anorexia and conjunctivitis in all. Sometimes, 6 of 7 (85%) animals also shed watery droppings. From day 8 p.i. until day 10 p i rhinitis appeared in all and from day 11 p.i. until day 21 p.i., all animals intermittently showed dyspnee. At euthanasia, 4 of 7 (57%) had large amounts of mucus in their beak.
Clinical signs in group 2 first appeared at day 4 p.i., with 3 of 7 (43%) animals showing rhinitis and conjunctivitis. From day 9 p.i. conjunctivitis and rhinitis were observed in all. The number of animals with conjunctivitis and rhinitis gradually declined towards day 17 p.i. At that time all chickens of group 2 appeared healthy.
On day 4 p.i., 4 animals (67%) of groups 3 and 4 showed conjunctivitis. One day later conjunctivitis started to diminish in those four animals but 3 of them (50%) got rhinitis for the following four (group 3) or two (group 4) days. On day 10 and 8 p.i., chickens of groups 3 and 4, respectively, showed healthy.
All vaccinated animals of group 6 remained very active after the experimental infection and they were eating well. They showed no clinical symptoms.
Thus, regarding the clinical signs, protection was best in group 6, followed by group 4, 3 and 2, respectively.
4.3. Macroscopic Lesions
The results of the pathological examination at euthanasia are presented in
First of all, we need to discuss the observations for the spleen as they are not presented in
Control chickens of group 1 showed gross pathology in all examined tissues but one, namely the trachea. In group 2, gross pathology was observed in 6 of 10 (60%) examined tissues. In group 3, gross pathology was observed in 9 of 10 (90%) examined tissues. However, the lesions in the trachea of some chickens were most probably due to the euthanasia. Thus, in group 3, gross pathology was observed in 8 of 10 (90%) examined tissues.
Overall, group 4 was significantly better protected than the control group 1. Protection in group 4 was also better than for groups 2 and 3, as gross pathology was only observed in 1 of 10 (10%) examined tissues, namely the lungs. Gross pathology was observed in the lung of 2 of 7 animals of group 4.
Control chickens of group 5 showed gross pathology in all examined tissues but one, namely the trachea. In group 6, gross pathology was only observed in the lung in 1 of 8 animals. Liver lesions were only observed in groups 1, 2, 3 and 5 indicative for septicaemia at the time of euthanasia.
Thus, regarding the autopsy results, protection was best in groups 6 and 4.
4.4. Chlamydia Replication and Excretion
Cryostat tissue sections (5 μm) of the conchae, the conjunctivae, the trachea, the lungs, thoracic and abdominal airsacs, the pericardium, liver and spleen were examined for C. psittaci replication by the IMAGEN™ immunofluorescence staining (IMAGEN™ CHLAMYDIA, Oxoid, Drongen, Belgium), as previously described (Vanrompay et al., 1994a). C. psittaci positive cells were enumerated in five randomly selected microscopic fields (600×, Nikon Eclipse TE2000-E, Japan) and scored between 0 and 5: score 0 indicated no C. psittaci present; score 1 was given when a mean of 1-5 elementary bodies (infectious, non-metabolic morphological form) was present; score 2, 3, 4 and 5 were given when a mean of 1-5, 6-10, 10-20 and >20 inclusion (actively replicating organisms) positive cells was present.
Swabs were examined for C. psittaci excretion by bacterial culture in Buffalo Green Monkey (BGM) cells (Vanrompay et al., 1992) and subsequent chlamydial identification using the IMAGEN™ direct immunofluorescence assay (Vanrompay et al., 1994b). The presence of C. psittaci was scored as for bacterial replication in different tissues. Swabs taken at day 1 of the experiment were negative for C. psittaci. Culture results for swabs taken at 21 days post infection (euthanasia) are presented in Table 6. The results for the remaining swabs are presented in Table 22.
At euthanasia, C. psittaci pharyngeal excretion was significantly higher in groups 1 and 2, as compared to groups 3 and 4. At euthanasia, pharyngeal C. psittaci excretion was significantly higher for group 5 than for group 6. The same was the case for the cloacal excretion. Thus, regarding C. psittaci excretion at 21 days p.i., protection was equally best in groups 3, 4 and 6.
4.5. Antibody Responses
The serum samples (
First the comparison of groups 1 to 4. On day −14, the mean antibody titer of group 1 was significantly lower than the mean antibody titers of groups 3 and 4. At that time, the mean antibody titer for group 1 was statistically the same as for group 2. However, mucosal primo immunization did not result in significant higher serum antibody titers at the day of infection (day −1). At day −1, mean serum antibody titers in groups 2, 3 and 4 were statistically the same as for both control group 1. Infection of groups 1, 2, 3 and 4 resulted in augmenting serum antibody titers in the control group 1 and in the better-protected group 4. At 22 days post infection, the mean serum antibody titer for group 4 was significantly higher than for the control group 1 and than for groups 2 and 3.
Secondly, the comparison of groups 5 and 6. Again, on day −14, the mean serum antibody titer of group 5 was significantly lower than the mean antibody titer of group 6. Again, mucosal primo immunization did not result in significant higher serum antibody titers at the day of infection (day −1). At day −1, the mean serum antibody titer in group 6 was statistically the same as for the control group 5. However, one week prior to the infection, the mean serum antibody titer in group 6 was significantly higher than for the control group 5. The same was true at two days and one week after the experimental infection. Thereafter, serum antibodies in the best-protected group 6 declined rapidly while those in the unprotected control group 5 rapidly augmented till 14 days post infection.
Most relevant information is the significant increase of mean mucosal antibody titers following mucosal primo vaccination in the better-protected groups 4 and 6 (day −1), as compared to the control groups 1 and 5 and the immunized groups 2 and 3. Chickens in groups 4 and 6 received the same vaccine. Infection of groups 1, 2, 3 and 4 at day −1 resulted in augmenting mean mucosal antibody titers in the unprotected group 1 and the less protected groups 2 and 3. The mean mucosal antibody titers in the better-protected group 4 generally declined following infection. Booster vaccination in group 6 had no visible effect on the mean mucosal antibody titer. Infection of groups 5 and 6, first resulted in a rapidly augmenting and a rapidly declining mean mucosal antibody titer in the unprotected group 5 and the best protected group 6, respectively. From 7 days p.i. onwards mean mucosal antibody titers in the best protected group 6 continued to rise till 21 days p.i., while those in the unprotected group 5 declined and even disappeared at 14 days p.i.
4.6. Lymphocyte Proliferative Responses
Peripheral blood leukocytes (PBL) were isolated from heparinized blood samples obtained by venepuncture (V. ulnaris) and from the spleen from each chicken, at 21 days p.i. at euthanasia. Lymphocyte proliferative tests were performed as previously described (Vanrompay et al., 1999b). Briefly, non-adherent cells were grown in duplicate in 96-well tissue culture plates at 106 cells in 150 μl of DMEM (Invitrogen) supplemented with 20% heat-inactivated fetal calf serum (Greiner), 1% nonessential amino acids, 1% sodium pyruvate, 1% L-glutamine, 1% gentamycine and 0.0001% β-mercaptoethanol (all Invitrogen). For antigen proliferation, 20 μg of recombinant MOMP was added to individual wells. Negative and positive controls included cells stimulated with either plain medium or with 10 μg concanavalin A (Con A), respectively. Cells were incubated at 39.5° C. in a humidified incubator with 5% CO2. Con A or antigen-induced proliferation was measured by incorporation of 3H-thymidine (1 μCi/well) during at last 16 h of culture, at days 2 (ConA) and 6, respectively. Cultures were harvested onto glass fiber filter strips with a cell harvester (Skatron, Liers, Norway). The radioactivity incorporated into the DNA was measured with a β-scintillation counter (Perkin-Elmer, Brussels, Belgium). The stimulation index (SI) was defined as the ratio of counts per minute (cpm) of stimulated cultures on medium-only cultures. Results are presented in Table 7.
4.7. Statistical Analysis
The non-parametric Krukal-Wallis and Mann-Whitney tests were employed for statistical analyses. Results were considered to be significantly different at the level of p<0.05.
C. psittaci
C. psittaci
For the primo vaccinated groups 1 to 4, protection was correlated with a significantly higher stimulation index for in vitro restimulation of blood lymphocytes with inactivated C. psittaci whole organisms as well as with recombinant MOMP of C. psittaci. For the primo vaccinated groups 1 to 4, protection was correlated with a significantly higher stimulation index for in vitro restimulation of spleen lymphocytes with recombinant MOMP of C. psittaci. Unfortunately, we could not test inactivated bacteria for group 4.
For groups 5 and 6, protection was correlated with a significantly higher stimulation index for in vitro restimulation of blood and spleen lymphocytes with inactivated C. psittaci whole organisms as well as with recombinant MOMP of C. psittaci.
Protection was correlated with higher CD4/CD8 ratios for peripheral blood lymphocytes at any time point post infection.
Conclusion Vaccination Trial 1
Groups 4 and 6 receiving a combination of B and T cell epitopes were significantly protected against clinical signs, gross pathology and bacterial excretion. Regarding clinical signs, groups 6 was better protected than group 4. Protection was correlated with superior B cell responses upon immunisation (higher mucosal antibody titers post primo vaccination and higher serum antibody titers following booster vaccination), with high proliferative responses of T cells at euthanasia and with a higher CD4/CD8 ratio for peripheral blood lymphocytes at any time point post infection.
5. Vaccination Trial 2: Vaccination of SPF Chickens
From the peptides described herein, a second selection of B-cell, CD4+ Th1, CD4+ Th2 and CD8 T-cell epitopes was made to design a polyepitope vaccine.
Experiments were performed in negative pressure isolators (IM 1500, Montair Sevenum, the Netherlands). The experimental design was evaluated and approved by the Ethical Commission for Animal Experiments of Ghent University. To evaluate the vaccine, 18 specific pathogen free (SPF) chickens (Lohman, Cuxhaven, Germany) were divided into three groups of 6 animals. The vaccination scheme is presented in Table 9. Group 1 received 500 μg of each peptide X, Y and Z per animal. In group 2, 3 chickens received 500 μg of peptide X (subgroup 2a), while the other 3 chickens received 500 μg of peptide Y and 500 μg of peptide Z (subgroup 2b). The vaccine was administered as an aerosol using the Cirrus™ nebulizer (2-5 μm aërosol particle size; Laméris, Aartselaar, Belgium). The control animals of group 3 received no vaccine. Vaccination was performed at the age of 6 weeks. At the age of 8 weeks, all animals were aerogenically infected using a Cirrus™ nebulizer (2-5 μm aërosol particle size; Laméris, Aartselaar, Belgium). The experimental infection dose in each isolator was 106 TCID50. Animals were euthanized at 10 days post infection (dpi).
5.1. Monitoring and Sampling
Clinical signs were monitored daily until necropsy at 10 dpi.
Blood samples for the detection of MOMP-specific serum antibody titres were collected prior to vaccination, at the day of challenge and at euthanasia at 10 dpi. Blood samples were stored overnight at room temperature, centrifuged (325×g, 10 min, 4° C.) and afterwards serum was collected and stored at −20° C.
At the time of euthanasia, 10 days p.i., all turkeys were examined for gross lesions. Impression smears (cytology) of the lungs and spleen were examined for the presence of chlamydial antigen.
All animals of the control group 3 showed conjunctivitis, rhinitis and moderate dyspnoea. Symptoms were most severe from 8 to 10 dpi. No clinical signs were observed in the vaccinated groups 1 or 2.
The control animals showed severe congestion of the conjunctiva, sometimes only unilaterally, severe congestion of the conchae, moderate congestion of the trachea, bilateral congestion of the lungs with few grew foci surrounded by a hyperaemic zone (pneumonia), opacity of the airsacs and few fibrin cloths in the abdominal airsac, mostly unilateral and hepatosplenomegaly. Group 1, immunized with peptides X, Y and Z showed no macroscopic lesions. Group 2a, immunized with peptide X, showed slight (2 of 3 chickens) to strong (1 of 3 chickens) congestion of the lungs, slight congestion of the serosa of the small intestine (especially the duodenum) and in one of 3 chickens serous pericarditis was observed. The animals of group 2b, immunized with peptides Y and Z only showed slight (1 of 3 chickens) to strong (2 of 3 chickens) congestion of the lungs. No other lesions were observed.
5.2. Chlamydia Replication in Lungs and Spleen
Impression smears (cytology) of the lungs and spleen were examined for C. psittaci replication by the IMAGEN™ immunofluorescence staining (IMAGEN™ CHLAMYDIA, Oxoid, Drongen, Belgium), as previously described (Vanrompay et al., 1992). C. psittaci positive cells were enumerated in five randomly selected microscopic fields (400×, Nikon Eclipse TE2000-E, Japan) and scored between 0 and 5: score 0 indicated no C. psittaci present; score 1 was given when a mean of 1-5 elementary bodies (infectious, non-metabolic morphological form) was present; score 2, 3, 4 and 5 were given when a mean of 1-5, 6-10, 10-20 and >20 inclusion (actively replicating organisms) positive cells was present.
The results for C. psittaci replication in the lungs and spleen, at 10 dpi, are shown in Table 10.
5.3. Antibody Responses
Enzyme-linked immunosorbent assays (ELISA's) were performed on the serum samples that first were pretreated with kaolin to remove background activity (Novak et al., 1993). Antibody titers were determined using standard protocols with rMOMP as antigen coated on the plates (Verminnen et al., 2006). Recombinant MOMP was produced in COS-7 cells, transiently transfected with pcDNA1::MOMP, as described previously (Vanrompay et al., 1998). Dilutions (1/1000) of, anti-chicken/turkey IgG, anti-chicken/turkey IgM and anti-chicken/turkey IgA (Betyl Lab Inc, Montgomery, USA) were used. Anti-MOMP immunoglobulin titers were presented as the reciprocal of the highest serum dilution that gave an optical density (OD405) above the cut-off value (mean OD off sero-negative SPF turkeys±twice the S.D.). Also, a positive and negative control serum, obtained from previous vaccination experiments, was used. Starting dilution was 1/32.
MOMP specific IgA, IgM, IgG serum antibody titers were determined by the recombinant MOMP-based ELISA (Verminnen et al., 2006) (Table 11). All SPF chickens tested sero-negative at the age of 6 weeks, at the beginning of our experiment.
Conclusion Vaccination Trial 2
Chickens immunized with a combination of B cell+CD4Th2 epitopes of MOMP together with a combination of CD8+ a CD4Th1 epitopes of MOMP (group 1) were better protected than non-immunized controls (group 3). Group 1 was also better protected than chickens immunized with either a combination of only B cell+CD4Th2 epitopes (group 2b) or a combination of only CD8+CD4Th1 epitopes (group 2a).
Materials and Methods
Chlamydia psittaci Strain
C. psittaci strain 92/1293, isolated from a severe outbreak of respiratory disease in a commercial broiler turkey farm in the Netherlands, was used (Vanrompay et al., 1993). The strain was isolated from a pooled homogenate of the lungs, the cloacae and the spleens of diseased turkeys and was characterized as serovar D and genotype D (Geens et al., 2005). Bacteria were grown in Buffalo Green Monkey (BGM) cells as previously described (Vanrompay et al., 1992) and the titration was performed by the method of Spearman and Kaerber (Mayr et al., 1974).
Recombinant MOMP Vaccine
Recombinant MOMP was produced in COS-7 cells transfected with the pcDNA1::MOMP plasmid, as previously described (Vanrompay et al., 1998). The plasmid contained the full-length ompA gene of C. psittaci strain 92/1293. After harvesting the recombinant MOMP (rMOMP), the protein concentration was determined using the bicinchoninic acid protein assay (Sigma).
Vaccination Trial
Experiments were performed in negative pressure isolators (IM 1500, Montair Sevenum, the Netherlands). The experimental design was evaluated and approved by the Ethical Commission for Animal Experiments of Ghent University. To evaluate the C. psittaci rMOMP vaccine, 10 specific pathogen free (SPF) turkeys (CNEVA, Ploufragan, France) were divided into two groups. The vaccination scheme is presented in Table 12. The vaccinated group received 500 μg rMOMP per animal. The vaccine was administered as an aerosol using the Cirrus™ nebulizer (2-5 μm aërosol particle size; Laméris, Aartselaar, Belgium). The control animals received no vaccine. Vaccination was performed on day 1 and at the age of 3 weeks. At the age of 5 weeks, all animals were aerogenically infected using a Cirrus™ nebulizer (2-5 μm aërosol particle size; Laméris, Aartselaar, Belgium). The experimental infection dose in each isolator was 106 TCID50.
Monitoring and Sampling
Clinical signs were scored daily until necropsy. Clinical score 0 indicated no clinical signs; score 1: conjunctivitis; score 2: rhinitis; score 3: dyspnoea; score 4: conjunctivitis and rhinitis; score 5: conjunctivitis and dyspnoea; score 6: rhinitis and dyspnoea; score 7: conjunctivitis, rhinitis and dyspnoea.
Pharyngeal and cloacal excretion of C. psittaci was monitored on day 1 and on every other day starting at 5 days post infection (p.i.) until necropsy at 21 days p.i., using rayon-tipped, aluminium shafted swabs (Colpan; Fiers, Kuurne, Belgium) provided with C. psittaci transport medium (sucrose 74.6 g/l (Acros Organics, Geel, Belgium); KH2PO4 5.1 g/l and K2HPO4 1.2 g/1 (Sigma); L-glutamic acid mono potassium salt 0.9 g/l (Invitrogen, Merelbeke, Belgium) and fetal calf serum 10% v/v (Greiner, Wemmel, Belgium); gentamycin 50 μg/ml (Invitrogen); vancomycin 100 μg/ml and streptomycin 100 μg/ml (Soenen, Merelbeke, Belgium); nystatin 25000 U/ml (Sigma) pH 7). Swabs were stored at −80° C. until processed.
Blood samples for the detection of MOMP-specific serum antibody titres were collected prior to each vaccination, 7 days following the booster vaccination, immediately prior to the experimental infection and at 14 and 21 days p.i. Blood samples were stored overnight at room temperature, centrifuged (325×g, 10 min, 4° C.) and afterwards serum was collected and stored at −20° C.
At the time of euthanasia, 21 days p.i., proliferative responses in peripheral blood lymphocytes were examined and characterized. All turkeys were examined for gross lesions. The score system is presented in Table 13. Cryostat tissue sections of the lungs, thoracic and abdominal airsacs, the pericardium, liver and spleen were examined for the presence of chlamydial antigen.
Chlamydia Replication in Tissues and Bacterial Excretion
Cryostat tissue sections (5 μm) of the conchae, the conjunctivae, the trachea, the lungs, thoracic and abdominal airsacs, the pericardium, liver and spleen were examined for C. psittaci replication by the IMAGEN™ immunofluorescence staining (IMAGEN™ CHLAMYDIA, Oxoid, Drongen, Belgium), as previously described (Vanrompay et al., 1994). C. psittaci positive cells were enumerated in five randomly selected microscopic fields (400×, Nikon Eclipse TE2000-E, Japan) and scored between 0 and 5: score 0 indicated no C. psittaci present; score 1 was given when a mean of 1-5 elementary bodies (infectious, non-metabolic morphological form) was present; score 2, 3, 4 and 5 were given when a mean of 1-5, 6-10, 10-20 and >20 inclusion (actively replicating organisms) positive cells was present.
All swabs were examined for C. psittaci excretion by bacterial culture in Buffalo Green Monkey (BGM) cells (Vanrompay et al., 1992) and subsequent chlamydial identification using the IMAGEN™ direct immunofluorescence assay (Vanrompay et al., 1992). The presence of C. psittaci was scored as for bacterial replication in different tissues.
Antibody Responses
Enzyme-linked immunosorbent assays (ELISA's) were performed on the serum samples that first were pretreated with kaolin to remove background activity (Novak et al., 1993). Antibody titers were determined using standard protocols with rMOMP as antigen coated on the plates (Verminnen et al., 2006). Recombinant MOMP was produced in COS-7 cells, transiently transfected with pcDNA1::MOMP, as described previously (Vanrompay et al., 1998). Dilutions of 1/2000 and 1/4000 of, respectively, biotinylated anti-chicken/turkey IgG (H+L) antibody and peroxidase-conjugated streptavidin were used. Anti-MOMP immunoglobulin titers were presented as the reciprocal of the highest serum dilution that gave an optical density (OD405) above the cut-off value (mean OD off sero-negative SPF turkeys±twice the S.D.). Also, a positive and negative control serum, obtained from previous vaccination experiments, was used. Starting dilution was 1/32.
MOMP-specific isotypes in pharyngeal swabs were determined using cross-reactive anti-chicken IgG-, IgM- and IgA specific peroxidase-conjugated polyclonal antibodies (Bethyl Laboratories Inc.). Also, a positive and negative control serum, obtained from previous vaccination experiments, was used. Starting dilution for the mucosal swabs was 1/32.
Lymphocyte Proliferative Responses and Characterization of T Cells
Peripheral blood leukocytes (PBL) were isolated from heparinized blood samples obtained by venepuncture (V. ulnaris) from each turkey, at 21 days p.i. Lymphocyte proliferative tests were performed as previously described (Vanrompay et al., 1999). Briefly, non-adherent cells were grown in duplicate in 96-well tissue culture plates at 1×106 cells in 150 μl of DMEM (Invitrogen) supplemented with 20% heat-inactivated fetal calf serum (Greiner), 1% nonessential amino acids, 1% sodium pyruvate, 1% 1-glutamine, 1% gentamycine and 0.1% β-mercaptoethanol (all Invitrogen). For antigen proliferation, 10 μg of recombinant MOMP was added to individual wells. Negative and positive controls included cells stimulated with either plain medium or with 10 μg concanavalin A (Con A), respectively. Cells were incubated at 39.5° C. in a humidified incubator with 5% CO2. Con A or antigen induced proliferation was measured by incorporation of 3H-thymidine (1 μCi/well) during at last 16 h of culture, at days 2 (ConA) and 5, respectively. Cultures were harvested onto glass fiber filter strips with a cell harvester (Skatron, Liers, Norway). Filters were counted in a Beckman β-scintillation counter (Beckman, Gent, Belgium). The stimulation index was defined as the ratio of counts per minute (cpm) of stimulated cultures on medium-only cultures.
Proliferating cells were also characterized by flow cytometry with a cross reacting chicken anti-CD4 monoclonal antibody and a turkey anti-CD8 monoclonal antibody.
Statistical Analysis
The Mann-Whitney test will be used for statistical analysis. Results will be considered significantly different at the level of P<0.05.
Results
Clinical Signs
Clinical signs in the rMOMP vaccinated group and the control group are presented in Table 14.
Macroscopic Findings
The macroscopic lesions in all animals were evaluated at necropsy (Table 15). Overall, the control animals showed severe congestion of the lungs with inflammatory sites and the air sacs showed a diffuse opacity with large fibrin deposits. Congestion of the conchae and conjunctivae could be observed in these animals and some of them also showed tracheal congestion. Moreover, a serous pericarditis was found in the control animals and also congestion of the liver and the spleen could be visualized.
The vaccinated animals, showed the most severe symptoms in the abdominal air sacs.
Chlamydia Replication and Excretion
The results for C. psittaci replication in the different tissues, at 21 days p.i., are shown in Table 16. The results of the pharyngeal and cloacal swabs that were analysed for C. psittaci excretion are shown in Table 17. All swabs that were taken from the one-day-old turkeys were negative.
Antibody Responses
MOMP IgG (H+L), serum antibody titers were determined performed using our recombinant-MOMP based ELISA (Verminnen et al., 2006). The log10 of the mean values of the antibody titers in function of the age of the turkeys is presented in Table 18.
Mucosal (pharyngeal) swabs taken at the day of the booster vaccination, at the day of the challenge infection and at euthanasia were investigated for the presence of IgG, IgM and IgA antibodies. The results are presented in Table 19.
aBV, booster vaccination.
bPBV, post booster vaccination.
cPC, post challenge
aBV, booster vaccination.
Antigen-Specific Lymphocyte Proliferation and Characterization of T Cells
The proliferative response of the peripheral blood lymphocytes after stimulation with recombinant MOMP of all vaccinated and control animals was determined on day 21 p.i. (Table 20).
The lymphocytes of the rMOMP vaccinated group showed a significant higher proliferative response compared to the control group.
The proliferating cells were also characterized by flow cytometry with a cross-reacting chicken anti-CD4 monoclonal antibody and a turkey anti-CD8 monoclonal antibody. Results are shown in Table 21.
Vaccination with the full-length recombinant MOMP was significantly less protective than the use of a combination of B and T cell epitopes of the MOMP (groups 4 and 6 of vaccination trial 1, and group 1 of vaccination trial 2 (vac.2) of the experiments in example 1) as:
The highest protection (achieved in group 6) level was correlated with a significant higher mucosal IgA titer at the day of challenge and a higher lymphocyte proliferative response of especially spleen lymphocytes at 21 days post infection.
rMOMP vaccination gave no significant difference for the CD4/CD8 ratio in peripheral blood as compared to the controls, while the peptide combination (group 4 and 6) gave a significantly higher CD4/CD8 than the controls at any time point post infection. For group 1 (vac. 2), protection was correlated with a higher number of animals showing IgG serum antibodies at the day of challenge.
Number | Date | Country | Kind |
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11170370 | Jun 2011 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2012/061420 | 6/15/2012 | WO | 00 | 12/13/2013 |
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WO2012/172042 | 12/20/2012 | WO | A |
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5759551 | Ladd et al. | Jun 1998 | A |
6384206 | Caldwell et al. | May 2002 | B1 |
20050037019 | Kousoulas et al. | Feb 2005 | A1 |
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9406827 | Mar 1994 | WO |
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20140242105 A1 | Aug 2014 | US |