Immunochemical analysis of IgG subclasses and IgM in South American camelids

Evaluation of three immunological assays to mitigate the risk of transboundary spread of Coxiella burnetii by alpacas

Coxiella burnetii causes coxiellosis in animals and Q fever in humans, a potentially debilitating zoonotic disease commonly transmitted through domestic ruminants. To prevent transboundary spread of C. burnetii, animals may be tested prior to export. In alpacas, this process is complicated by the lack of scientific evidence for C. burnetii infection in the species, and the unique composition of camelid antibodies, which may cause false-positive results in assays developed for ruminants. We evaluated a complement fixation test (CFT; currently recommended for alpacas in New Zealand), an enzyme-linked immunosorbent assay (ELISA) and an immunofluorescence assay (IFA). Positive analytical control samples were generated through vaccination of alpacas with a human Q fever vaccine, whereas negative analytical control samples were sourced from New Zealand (deemed free of C. burnetii). Immunological assays were conducted on 131 alpaca sera submitted for export testing. Test characteristics (sensitivity, specificity, positive and negative predictive values) for CFT, ELISA and IFA were determined using Bayesian latent class analysis. Due to anticomplementary activity, 37 (28.2%) of the CFT results were inconclusive, making CFT unsuitable for routine use. Of the remaining 94 samples, 10.6%, 0% and 7.4% were positive for C. burnetii antibodies based on CFT, ELISA and IFA, respectively, yielding estimated sensitivities of 58%, 26% and 78%, and estimated specificities of 95%, 98% and 95%, with the estimates for sensitivity being imprecise, as evidenced by wide 95% credible intervals. Positive predictive values were similar across assays, albeit very low at the estimated seroprevalence of 5%. Our results indicate that, of the tests available, IFA appears to be the most appropriate for use in alpacas. Higher sensitivity of antibody detection, use of antigen detection assays and availability of samples from individuals with evidence of infection could provide additional insight into the risk of transboundary spread of C. burnetii by alpacas.

Comparison of the nutritional value and fatty acid composition of milk from four South American camelid species

The nutritional value, whey protein, and the fatty acid (FA) composition of milk from four South American camelids (SAC) (vicuna, Vicugna vicugna (Molina, 1782); alpaca, Vicugna pacos (Linnaeus, 1758); guanaco, Lama guanicoe (Müller, 1776); llama, Lama glama (Linnaeus, 1758)) were evaluated and compared with milk from old-world camelids. Samples were collected from healthy animals from the northwest (llama, alpaca, and vicuna) and Patagonia (guanaco) areas of Argentina. Gross composition of milk from SAC showed a higher protein, lactose, and lipid content than camel milk. Serum albumin and α-lactalbumin were the dominant whey proteins, followed by immunoglobulin G (IgG). The FA profile showed from 4:0 to 24:0 FA, with a high level of conjugated fatty acid (CLA; 1.05–1.64 g/100 g of FAME) and its precursor, vaccenic acid. Desaturase activity of C16 and CLA was quite similar between species but was significantly different for C14. Camelid milk showed a lower atherogenicity index than ruminant milk. This is the first time that a comparative study involving four species of SAC was carried out to contribute to the general knowledge of the physiology of new-world camelids. Their milk was determined to be of high nutritional quality, allowing it to be considered an alternative food item for humans in the semi-arid region of South America.

Simple Protocol for immunoglobulin G Purification from Camel “Camelus dromedarius” Serum

The present study aimed to describe and standardize a simple and efficient protocol for purification of camel IgG from serum, which can be applied for Camilidae antibody production in research laboratories, the preindustrial stage. Camel serum IgG was separated with caprylic acid and ammonium sulfate, then the effect of four variables studied: caprylic acid concentration, pH, stirring time, and stirring intensity. Camel IgG prepared by standardized caprylic acid fractionation method for camel serum was compared with commercial anti-sera products. Camel IgG purification from undiluted sera using caprylic acid at concentration of 8% v/v gave the best results. Purification at different pH values using caprylic acid at 8% v/v revealed that pH 5.5 was optimal. Investigating purification at different stirring time intervals using 8% v/v caprylic acid at pH 5.5 demonstrated that stirring for 90 min gave the optimum results. Finally, studying purification at different stirring intensities using 8% v/v caprylic acid at pH 5.5 for 90 min, the best stirring intensity was at 450 rpm. Overall, the results suggest that caprylic acid purification of camel serum IgG is more effective and safe than ammonium sulfate method in simplicity, purity, and lower non-IgG proteins in the final preparation with lower protein aggregates.

Activity modulation of microbial enzymes by llama (Lama glama) heavy-chain polyclonal antibodies during in vivo immune responses

Since they were first described in 1993, it was found that recombinant variable fragments (rVHHs) of heavy-chain antibodies (HCAbs) from Camelidae have unusual biophysical properties, as well as a special ability to interact with epitopes that are cryptic for conventional Abs. It has been assumed that in vivo raised polyclonal HCAbs (pHCAbs) should behave in a similar manner than rVHHs; however, this assumption has not been tested sufficiently. Furthermore, our own preliminary work on a single serum sample from a llama immunized with a β-lactamase, has suggested that pHCAbs have no special ability to down-modulate catalytic activity. In this work, we further explored the interaction of pHCAbs from four llamas raised against two microbial enzymes and analyzed it within a short and a long immunization plan. The relative contribution of pHCAbs to serum titer was found to be low compared with that of the most abundant conventional subisotype (IgG(1)), during the whole immunization schedule. Furthermore, pHCAbs not only failed to inhibit the enzymes, but also activated one of them. Altogether, these results suggest that raising high titer inhibitory HCAbs is not a straightforward strategy - neither as a biotechnological strategy nor in the biological context of an immune response against infection - as raising inhibitory rVHHs.

Isolation and characterization of Clostridium difficile toxin-specific single-domain antibodies

Camelidae single-domain antibodies (VHHs) are a unique class of small binding proteins that are promising inhibitors of targets relevant to infection and immunity. With VHH selection from hyperimmunized phage display libraries now routine and the fact that VHHs possess long, extended complementarity-determining region (CDR3) loop structures that can access traditionally immunosilent epitopes, VHH-based inhibition of targets such as bacterial toxins are being explored. Toxin A and toxin B are high molecular weight exotoxins (308 kDa and 269 kDa, respectively) secreted by Clostridium difficile that are the causative agents of C. difficile-associated diseases in humans and in animals. Here, we provide protocols for the rapid generation of C. difficile toxin A- and toxin B-specific VHHs by llama immunization and recombinant antibody/phage display technology approaches and for further characterization of the VHHs with respect to toxin-binding affinity and specificity and the conformational nature of their epitopes.

Development of ELISAs for the measurement of IgM and IgG subclasses in sera from llamas (Lama glama) and assessment of the humoral immune response against different antigens

Members of the Camelidae family possess a functional class of antibodies devoid of light chains (known as heavy chain antibodies, HCAbs). Three IgG isotypes have been identified (IgG(1), IgG(2) and IgG(3)); IgG(2) and IgG(3) are HCAbs whereas the IgG(1) has the conventional structure. Different subtypes of IgG(1) (IgG(1a) and IgG(1b)) and IgG(2) (IgG(2a), IgG(2b) and IgG(2c)) have been classified according to variations in the amino acids sequence of the hinge region. The single variable domain of HCAbs has been referred as VHH. Until now, the relative amount of each subclass has been inferred, but the lack of highly specific antibodies against HCAbs has been a limitation for their quantification. In a previous work, we produced specific polyclonal antibodies against IgG(2a), IgG(2b), IgG(2c) and IgG(3) by immunizing rabbits with synthetic and recombinant peptides corresponding to their hinge region. In this work we produced specific antisera against llama IgM and IgG(1). The anti-IgG(1) serum was obtained by immunizing rabbits with a recombinant fusion protein formed by GST fused to the CH(1) domain of the IgG(1). The anti-IgM serum was obtained by immunizing rabbits with IgM heavy chain. All these antisera were useful for the development of ELISAs for the measurement of IgM, total IgG and IgG subclasses. Sera from llamas (n=20) analyzed by ELISA gave the following values of immunoglobulins: IgG(1)=6.168+/-1.628 mg/ml; IgG(2)=0.684+/-0.310 mg/ml; IgG(3)=1.232+/-0.410 mg/ml; total IgG=8.933+/-1.815 mg/ml and IgM=1.027+/-0.308 mg/ml. These results indicate that HCAbs represent almost 25% of total IgG and the IgG(3) subtype is the predominant HCAb. We also analyzed the primary humoral immune response after immunization llamas with different antigens (BSA, BSA-DNP and dextran). Although it has been described that a few VHH clones are very efficient in the interaction with haptens, in this case the response against DNP was characterized by a delayed appearance of HCAbs in comparison with that of IgG(1). No anti-dextran response was observed in any of the isotypes analyzed.

Immunobiological role of llama heavy-chain antibodies against a bacterial β-lactamase

In 1993, a fraction of antibodies (Abs) devoid of L chain was found naturally occurring in the Camelidae. They were found to lack L chains, as well as the first constant heavy-chain domain (CH(1)) and therefore they were named "heavy-chain Abs" (HCAbs). Subsequent studies focused on the functional, structural and biochemical properties of recombinant variable fragments (rVHHs) of HCAbs. It was stated that rVHHs have an augmented capacity to interact with "partially hidden" epitopes, like enzymes active sites, and have an increased stability to thermal and chemical aggression. It has been suggested that these unconventional Abs could represent an evolutionary advantage, being more efficient than conventional Abs to inhibit microbial enzymes, and thus exerting a more protective immune response against pathogens. The present work focuses on the immunobiological role of HCAbs, in their capacity to inhibit microbial enzymes. Two animal models were selected, comprising a model for common vertebrates without HCAbs (rabbits), and a model for vertebrates with both conventional and unconventional Abs (Lama glama). A recombinant bacterial beta-lactamase (CTX-M-2) was selected as the microbial enzymatic antigen. After conventional immunization schedules, neither serum titers nor serum inhibitory capacity showed significant differences when rabbits and llamas were compared. These results indicate that the a priori assumption that the adaptive immune system of camelids could be better "prepared" to respond to bacterial enzymes because of the presence of HCAbs, is not always accurate. Furthermore, when the different llama antibody isotypes and subclasses were purified, it was demonstrated that the inhibitory capacity of total serum was due exclusively to IgG(1). HCAbs not only failed to inhibit CTX-M-2, but instead they activated its enzymatic activity. Altogether, these results indicate that the hypotheses extrapolated from the rVHHs properties need to be revised; the real role of HCAbs in vivo remains unknown, as well as their evolutionary cause.

A novel and easy method for the production of recombinant peptides for use in the generation of monospecific antisera against Lama glama IgG2b and IgG2c subclasses

We describe an easy method for the production of small recombinant peptides of 8 amino acid residues expressed as a fusion peptide with glutathione S-transferase (GST) and employed in an immunisation schedule to obtain polyclonal antibodies. The chosen peptides corresponded to specific fragments of the hinge regions of llama (Lama glama) IgG2 subisotypes b (2bH) and c (2cH). The DNA sequences encoding each peptide were ligated individually into pGEX-5X-2, which encodes GST. Once purified from a bacterial lysate by glutathione affinity chromatography, GST-2bH and GST-2cH were used to immunize rabbits. In parallel, polyclonal antibodies were generated against specific synthetic fragments of the hinge regions of llama IgG2a (2aH) and IgG3 (3H) coupled to keyhole limpet haemocyanin (KLH). Polyclonal antibodies raised against GST-peptides and KLH-peptides were detected by enzyme-linked immunosorbent assay (ELISA), Western blot (WB) and indirect immunofluorescence (IIF). The results obtained by ELISA demonstrated that monospecific anti-IgG2 and anti-IgG3 antisera were obtained using KLH-2aH, GST-2bH, GST-2cH and KLH-3H as antigens. All antisera showed reactivity with their specific IgG isotype by WB and IIF. This simple and novel recombinant DNA methodology for the generation of two monospecific anti-isotype antisera using small peptides expressed as fusion peptides with GST offers the possibility of large scale peptide production as an alternative to chemical peptide synthesis.