Characterization of a murine type IIB procollagen-specific antibody

Type II collagen is the major collagenous component of the cartilage extracellular matrix; formation of a covalently cross-linked type II collagen network provides cartilage with important tensile properties. The Col2a1 gene is encoded by 54 exons, of which exon 2 is subject to alternative splicing, resulting in different isoforms named IIA, IIB, IIC and IID. The two major procollagen protein isoforms are type IIA and type IIB procollagen. Type IIA procollagen mRNA contains exon 2 and is generated predominantly by chondroprogenitor cells and other non-cartilaginous tissues. Differentiated chondrocytes generate type IIB procollagen, devoid of exon 2. Although type IIA procollagen is produced in certain non-collagenous tissues during development, this developmentally-regulated alternative splicing switch to type IIB procollagen is restricted to cartilage cells. Though a much studied and characterized molecule, the importance of the various type II collagen protein isoforms in cartilage development and homeostasis is still not completely understood. Effective antibodies against specific epitopes of these isoforms can be useful tools to decipher function. However, most type II collagen antibodies to date recognize either all isoforms or the IIA procollagen isoform. To specifically identify the murine type IIB procollagen, we have generated a rabbit antibody (termed IIBN) directed to a peptide sequence that spans the murine exon 1–3 peptide junction. Characterization of the affinity-purified antibody by western blotting of collagens extracted from wild type murine cartilage or cartilage from Col2a1^+ ex2 knock-in mice (which generates predominantly the type IIA procollagen isoform) demonstrated that the IIBN antibody is specific to the type IIB procollagen isoform. IIBN antibody was also able to detect the native type IIB procollagen in the hypertrophic chondrocytes of the wild type growth plate, but not in those of the Col2a1^+ ex2 homozygous knock-in mice, by both immunofluorescence and immunohistochemical studies. Thus the IIBN antibody will permit an in-depth characterization of the distribution of IIB procollagen isoform in mouse skeletal tissues. In addition, this antibody will be an important reagent for characterizing mutant type II collagen phenotypes and for monitoring type II procollagen processing and trafficking.     

HLA-DR2-associated Dw subtypes correlate with RFLP clusters: most DR2 IDDM patients belong to one of these clusters

The incidence of arthritis and the antibody response to mouse and to rat type 11 collagen after immunization with native rat type II collagen was studied in different mouse strains, including wild mouse-derived strains belonging to the H-2^p/H-2^q family. High serum levels of antibodies to mouse and rat type II collagen were seen only in H-2^q mice, whereas mice belonging to the p, w3, w5, and w17 haplotypes displayed low type II collagen-specific antibody responses. Mice from three different H-2^q-carrying strains (DBA/1, NFR/N, and B10.G) with different non-major histocompatibility complex genes were all susceptible to collagen arthritis, but they displayed a varying incidence of arthritis and varying clinical features. No arthritis was seen in non-H-2^q mice, except in the B10.CAS2 strain where a few mice developed arthritis despite very low serum levels of type II collagen-specific antibodies. We conclude that small differences in the A chain of class II transplantation antigens are of importance for the development of arthritis and for the stimulation of a high response after immunization with type 11 collagen.Abbreviations used in this paper ELISA enzyme-linked immunosorbent assay - PBS phosphate-buffered saline - Ig immunoglobulin - MHC major histocompatibility complex     

Immune response to the Slp alloantigen in the mouse:H-2-linked qualitative and quantitative control

Immunization of inbred mouse strains lacking the Slp allotype results in the production of Slp antibodies in some strains but elicits no detectable response in other strains. Analysis of standard inbred and congenic resistant strains reveals that both the qualitative and quantitative ability to respond to the Slp allotype is associated with theH-2 haplotype of the recipient. Three different response phenotypes can be identified utilizing complement fixation and quantitative immunodiffusion tests. Strains which carry theH-2 ^q haplotype are high responders,H-2 ^k strains are intermediate in response, whileH-2 ^b andH-2 ^v strains produce no detectable antibody. The characteristic response patterns of high and intermediate responders were manifest by day 35 of immunization and continued as discrete response types after a second booster. Quantitative data in the immune response of the intra-H-2 recombinant B10.A(4R) suggest that the recombination event which established theH-2 ^h4 chromosome disturbs the proper function of the genetic determinant controlling response to Slp.     

Genetic control of T-cell proliferative responses to poly(glu40ala60) and poly(glu51lys34tyr15): Subregion-specific inhibition of the responses with monoclonal Ia antibodies

The relationship betweenIr genes and Ia antigens was studied in the T-cell proliferative responses to two synthetic polypeptides poly(glu⁴⁰ala⁶⁰) (GA) and poly(glu⁵¹lys³⁴tyr¹⁵) (GLT¹⁵). The response to GA was found to be controlled by anIr gene in theI-A subregion, whereas the anti-GLT¹⁵ response was shown to be under dual control, oneIr gene mapping probably in theI-A subregion, and the other in theI-E subregion. We obtained two different lines of evidence suggesting identity ofIr and Ia genes. First, the presence of certain serologically identified allelic forms of the I-A-encoded A molecule correlated with the responder status to GA both in inbred strains and in B10.W lines, the latter carrying wild-derivedH-2 haplotypes. Thus the Ir and Ia phenotypes were not separable in strains of independent origin. Second, the anti-GA response was completely inhibited by monoclonal antibodies against determinants on the A molecule (Ia.8, 15, and 19), but not by a monoclonal antibody against a determinant on the E molecule (Ia.7). In contrast, the anti-GLT¹⁵ response was only inhibited by a monoclonal antibody against the E molecule, but not by antibodies against the A molecule. Our data support the hypothesis that Ia antigens, as restriction elements for T-cell recognition, may in fact be the phenotypic manifestation ofIr genes.     

H-2-linked recessiveIr gene regulation of high antibody responsiveness to TNP hapten conjugated to autogenous albumin

The antibody response to the hapten 2,4,6-trinitrophenyl (TNP) conjugated to autogenous mouse serum albumin (MSA) is regulated by anIr gene(s) located within the major histocompatibility complex (MHC). Both the qualitative and quantitative ability of congenic strains to produce TNP-specific antibodies are functions of theH-2 haplotype. Thus, mouse strains may be classified as high (H-2 ^d), intermediate (H-2 ^b,H-2 ^s), and low responders (H-2 ^a,H-2 ^k,H-2 ⁿ,H-2 ^p,H-2 ^q). Antibody responses, as measured by antigen-binding capacities in modified Farr assays, were compared among strains carrying recombinantH-2 haplotypes and their hybrid progenies. Distinct high- and low-responder phenotypes were evident throughout the time course of both primary and secondary antibody responses. The gene locus controlling specific responsiveness to TNP-MSA, now designatedIr-6, was mapped within theI-B subregion of theH-2 complex. Recessive inheritance of high responsiveness was confirmed in hybrid progenies of three different low × high-responder crosses.     

The T-Cell factor specific for poly(Tyr,Glu)-Poly(Pro)-Poly(Lys) is an I-Region gene product

The nature of a T-cell factor specific for poly(Tyr,Glu)-poly(Pro)-poly(Lys) [(T,G)-pro-L] was established in the present study. The activity of the (T,G)-Pro-L-specific factor was not removed by anti-mouse immunoglobulin Sepharose columns, suggesting that it is not a classical immunoglobulin. On the other hand, the factor lost its activity after passage through immunoadsorbents prepared with anti-H-2 sera raised against theH-2 haplotypes of the mouse strains in which the factor was prepared. Furthermore, this factor was adsorbed byI region-specific antisera but not by antisera directed against theI-J andI-C subregions as well as theK andD regions of theH-2 complex. Thus, the (T,G)-Pro-L-specific T-cell factor is most probably anI-A subregion gene product.     

Multigenic regulation of the primary immune response to ovalbumin in mice

At least four genes regulate the primary immune response to ovalbumin in mice. The ability to be sensitized to transfer delayed type hypersensitivity to ovalbumin is controlled by two genes. One gene,OVA-, is linked to theH-2 complex and maps to the left ofI-E. The linkage of the other gene,OVA-Bg1, has not been determined, but it segregates independently of theLy M locus, of the heavy chain allotype genes and of certain genes controlling coat color. At least two genes regulate the ability to respond with a primary antiovalbumin antibody response. One gene,OVA-, is linked to theH-2 complex and maps to the right ofI-E. Discordance of the minimum dose of antigen needed to elicit delayed type hypersensitivity response and antibody suggests that non-H-2 gene(s) regulating the primary antibody response are different fromOVA-Bg1.Abbreviations used in this paper BSA bovine serum albumin - DTH delayed type hypersensitivity - H-2 major histocompatibility complex of mouse - Ir gene — immune response gene - OVA ovalbumin - SRBC sheep red blood cells     

IgG-specific helper activity of t lymphocytes from mice lacking theIr-IgG gene

Cooperative interactions between T and B cells from the congenic inbred mouse strains B10.A(2R) and B10.A(4R) in antibody responses controlled byIr genes have been studied. Within theI region of the MHC, these strains share only theI-A subregion. TheIr gene controlling responsiveness to IgA maps in theI-A subregion, both strains being responders to IgA. T cells from 2R mice collaborate effectively with B cells from 2R or 4R mice for antihapten antibody responses to DNP-IgA. TheIr gene controlling responses to IgG maps in theI-B subregion, and 2R mice are nonresponders for this antigen. Nevertheless, 2R T cells primed with IgG can help responder (4R) B cells -but not syngeneic nonresponder (2R) B cells -in responding to DNP-IgG. These results indicate that mice lacking theIr-IgG gene nonetheless may develop helper T lymphocytes specific for myeloma proteins. In addition, they indicate that cells from congenic mice sharing only theA subregion of theI region can collaborate efficiently.     

Genetic control and fine specificity of the immune response to a synthetic peptide of influenza virus hemagglutinin.

The immune response to a synthetic peptide, H3 HA1(305-328), representing the C'-terminal 24 amino acid residues of the HA1 chain of the hemagglutinin of the H3 subtype of influenza virus is controlled by genes in the I region of the major histocompatibility complex. Mice of the H-2d haplotype are high responders and produce antibody for several months after a single injection of peptide without carrier. Mice of the H-2b, H-2k, and H-2q haplotypes are low antibody responders. Investigation of recombinant and congenic mouse strains revealed that high responsiveness requires the genes that encode the I-Ed molecule. Immunoassays, involving direct binding to analogs of this peptide and inhibition by both these analogs and synthetic epitopes, were used to analyze the specificity of the polyclonal response. In BALB/c mice, the primary antibody response is directed principally against the antigenic site 314-LKLAT-318, whereas the secondary response after a boost is predominantly directed to a distinct site, 320-MRNVPEKQT-328. The T-cell response to the peptide H3 HA1(305-328), as measured by antigen-induced proliferation of primed T cells in vitro, is also I-Ed restricted in high-responder H-2d mice and is directed against an antigenic site that does not require the four C-terminal residues unique to the H3 influenza subtype. A different epitope appears to be recognized by T cells from CBA (H-2k) mice, which proliferate to a moderate extent on exposure to the peptide but, nevertheless, do not provide help for an antibody response.     

Polymorphism of the major histocompatibility locus in the wild Norway rat

Specific alloantisera against the eight Ag-B groups found in inbred strains of rats were capable of reacting with all wild Norway rats (Rattus norvegicus) tested. Absorption studies, antisera production, and progeny testing involving wild rats showed that the antigenic specificities detected in the wild rat population were similar, if not identical, to the Ag-B antigens present in inbred strains. Xenoantisera prepared in rabbits against rat erythrocyte antigens (Ag-C1 and/or C2) reacted with erythrocytes from each wild rat tested. Progeny testing involving these erythrocyte antigens was identical to that observed in inbred strains. The restricted genetic polymorphism of theAg-B alleles in the wild rat population suggests that the functional and evolutionary significance of the major histocompatibility complex in the rat may not depend upon a high degree of genetic variability.     

Genetic control of two independently segregating loci in mice to the sequential polypeptide (Tyr-Ala-Glu-Gly)n

Immune responses to the sequential helical polypeptide (Tyr-Ala-Glu-Gly)_n [(T-A-G-Gly)_n] in mice is under the control of at least two separate genes. One gene,Ir-(T-A-G-Gly)-1, which is linked, toH-2 haplotypesb, f, andr, controls the ability to respond and maps to theIA subregion. A non-H-2-linked locus,Ir-(T-A-G-Gly)-2. is responsible for the magnitude of the antibody response, which is expressed as a high, intermediate, or low level of antibody production. The antibody produced is of the IgG class, and does not crossreact even with the closely related sequential helical polymer (Tyr-Glu-Ala-Gly)_n [(T-G-A-Gly)_n]. Immune responsiveness is a dominant trait,i.e., the F₁ generations of responder x nonresponder crosses are responders. However, the data obtained with both backcross populations are not easily interpretable. The contribution of the B-cell mitogenic activity of the sequential polymer to activation of suppressor T cells is considered as a possible explanation for the backcross results. The possible role of the Ia. W29 specificity present in the mouse strains responding to both (T-A-G-Gly)_n and calf skin collagen type I in modulating responses to the polymers is discussed.     

Genetic control of IgM responses to (T,G)-A — L

The primary antibody response to aqueous immunization with a low molecular-weight lot of (T,G)-A — L (#420) was studied in congenic pairs of inbred mouse strains. Two new genetic controls were identified, both of which quantitatively regulate the production of IgM anti-(T,G)-A — L antibody. Testing of F₁ and F₂ progeny demonstrated that one of these genes is linked to the major histocompatibility (H-2) complex, and that high response is dominant over low response. Whether this gene is identical toIr-1A is not yet known. The other gene, designatedIg-TGAL _M , is linked to the immunoglobulin heavy-chain allotype locus (Ig-1) and is expressed in a genedose dependent manner. Following secondary challenge with (T,G)-A — L 420, quantitative differences in IgG antibody response were observed inIr-1A high-responder congenics differing only at theIg-1 locus. Breeding studies, however, failed to demonstrate any linkage between this locus and the quantitative control of IgG anti-(T,G)-A — L antibody. These data demonstrate thatH-2-linked immune response genes can regulate IgM as well as IgG antibody responses, that genetic control of the IgM response to (T,G)-A — L is linked toIg-1, and that bothH-2-linked andIg-1-linked genes may simultaneously affect an IgM antibody response to the same antigen.Abbreviations used in this paper are (T,G)-A — L poly-l-(Tyr,Glu)-poly-d,l-Ala-poly-l-Lys - NMS normal mouse serum - SRBC sheep red blood cells - i.p. intraperitoneal - PBS phosphate-buffered saline - RAMG polyvalent rabbit anti-mouse globulin - 2-Me 2-Mercaptoethanol - 2-MeS 2-Me-sensitive - PFC plaque-forming cells - ABC antigen-binding cells     

Susceptibility to a mouse acquired immunodeficiency syndrome is influenced by theH-2

The development of a mouse acquired immunodeficiency syndrome (MAIDS) induced following LP-BM5 MuLV infection depends on host genetic factors. Susceptible mice, such as C57BL/6J mice, develop a profound impairment of lymphoproliferative response to mitogens and hyperplasia of lymphoid organs and succumb to infection within 6 months. These changes do not occur in resistant mice, such as A/J mice. Resistance to MAIDS is a dominant trait since (C57BL/6JxA/J)F₁ hybrid mice did not develop any immune dysfunctions following infection. Genetic regulation of the trait of resistance/susceptibility to MAIDS was determined in AXB/BXA recombinant inbred (RI) mouse strains (derived from resistant A/J and susceptible C57BL/6J progenitors). Two different criteria were used to determine their resistance or susceptibility to developing MAIDS: the gross pathologic evaluation of lymphoid organs at 13–15 weeks of infection, and survival. RI mouse strains segregated into two non-overlapping groups. The first group did not develop any significant pathology, and these mouse strains were considered as resistant to MAIDS. The second group showed the virus-induced pathological changes as well as an immunological dysfunction as seen in C57BL/6J progenitor mice, and these strains were thus considered as susceptible to MAIDS. This bimodal strain distribution pattern of resistance/susceptibility to MAIDS among the RI strains suggests that this phenotype is controlled by a single gene. Linkage analysis with other allelic markers showed a strong association between resistance/susceptibility to MAIDS and theH-2 complex. Possession of theH-2 ^b haplotype derived from C57BL/6J mice was associated with susceptibility to MAIDS, while theH-2 ^a haplotype conferred resistance to the disease. This finding was confirmed by demonstrating thatH-2 ^a congenics on the susceptible C57BL/10 background were as resistant to MAIDS as A/J mice which donated theH-2 ^a locus. Gene(s) within theH-2 complex thus represent the major regulatory mechanism of resistance/susceptibility to MAIDS.     

Association of H2A b with resistance to collagen-induced arthritis in H2-recombinant mouse strains: an allele associated with reduction of several apparently unrelated responses

HLA class II alleles can protect against immunological diseases. Seeking an animal model for a naturally occurring protective allele, we screened a panel of H2-congenic and recombinant mouse strains for ability to protect against collagen-induced arthritis. The strains were crossed with the susceptible strain DBA/1, and the F₁ hybrids immunized with cattle and chicken type II collagen. Hybrids having the H2A ^b allele displayed a reduced incidence and duration of the disease. They also had a reduced level of pre-disease inflammation, but not of anti-collagen antibodies. The allele is already known to be associated with reduction of other apparently unrelated immune responses, suggesting that some form of functional differentiation may operate that is not exclusively related to epitope-binding. It is suggested that this may reflect allelic variation in the class II major histocompatibility complex promoter region.     

A peptide antibody for rapid screening of Streptomyces species producing phospholipase D

By examining the conserved regions in the protein sequences of eight different Streptomyces phospholipase Ds (PLD) reported so far and the X-ray crystallographic structure of a Streptomyces PLD, we designed a peptide sequence, DPANRGAVGSGGYSQIKSL, for the screening of microorganisms producing PLD. In the enzyme-linked immunosorbent assay using a mouse antibody raised against the designed peptide, we recovered seven producing strains out of 128 soil isolates.     

Type II collagen-induced arthritis in mice. IV. Variations in immunogenetic regulation provide evidence for multiple arthritogenic epitopes on the collagen molecule

Type II collagen from six mammalian species was investigated for the capacity to induce an immune response and collagen-induced arthritis (CIA) in C57/B10 congenic mouse strains. H-2q haplotype mice were susceptible to chick, bovine, deer, rat, and human type II collagen, but were resistant to arthritis induced by porcine type II collagen. H-2r haplotype mice only developed CIA in response to bovine, deer, and porcine collagen. High antibody responses in the absence of disease, directed against a specific type II collagen, were observed in many independent haplotypes. The cross-reactive capacity of different antisera to the various collagen species was studied. The data support the existence of two arthritogenic and multiple nonarthritogenic epitopes on the type II collagen molecule.     

Genetically controlled IgM hyporesponsiveness to aK. pneumoniae polysaccharide

Examination of the immune response to aKlebsiella pneumoniae polysaccharide (K47-PS) has revealed that BALB/c mice demonstrate only a very weak primary response to this antigen. The low response does not result from either a peculiar dose response curve for BALB/c mice or from differing optimal antigen concentrations for high and low responder mice. Genetic analysis indicates that this variability of response is explicable assuming two alleles at a single locus; high responsiveness is dominant. Variability of response is probably not linked to theH-2 complex since the low and high responder mice, BALB/c and B10.D2/Sn new line, respectively, share the sameH-2 haplotype (H- 2_d). Tests of F₂s, backcrosses, and appropriate congenics have not shown evidence of linkage to sex, the albinism gene, the genes controlling coat color (agouti, black, brown), or the allotype-constant-region genes. The hyporesponsiveness is apparent only in the primary (IgM) response; hyperimmunization evokes similar antibody titers in high and low responding strains.     

Antibodies Specific for Carbamylated Proteins Precede the Onset of Clinical Symptoms in Mice with Collagen Induced Arthritis

Objective

The immune response to post-translationally modified antigens is a key characteristic of rheumatoid arthritis. Carbamylation is such a posttranslational modification. Recently, we demonstrated that autoantibodies recognizing carbamylated proteins are present in sera of rheumatoid arthritis. The molecular mechanisms underlying the break of tolerance and hence the induction of anti-CarP antibody responses are unknown as well as their appearance in mouse models for systemic arthritis. Therefore we analyzed their appearance in the mouse collagen-induced arthritis model.

Methods

collagen induced arthritis was induced by immunization with type II collagen in complete Freund''s adjuvant. Arthritis severity was monitored by clinical scoring and anti-CarP antibody levels were determined by ELISA.

Results

Anti-CarP antibodies were detectable in mice with collagen induced arthritis. We did not detect ACPA in mice with collagen induced arthritis. The specificity of the antibodies for carbamylated proteins was confirmed by inhibition assays and immunoblotting. Injection with complete Freund''s adjuvant without type II collagen could also induce anti-CarP antibodies, however, in mice with arthritis, the anti-CarP antibody response was stronger and developed more rapidly. The onset of collagen induced arthritis was preceded by an increase of anti-CarP IgG2a levels in the serum.

Conclusion

In mice with collagen induced arthritis we did not observe an immune response against citrullinated antigens, but we did observe an immune response against carbamylated antigens. This anti-CarP response already appeared before disease onset, indicating that collagen induced arthritis can be used as an in vivo model to study anti-CarP antibodies. Our data also indicate that the tolerance to carbamylated proteins, in contrast to the response to citrullinated proteins, is easily broken and that arthritis boosts the immune response against these proteins. The anti-CarP response in mice with CIA can be used as a model for immune responses to post-translationally modified proteins.     

Intracellular features of type II procollagen and chondroitin sulfate proteoglycan synthesis in chondrocytes

The intracellular compartments of chondrocytes involved in the synthesis and processing of type II procollagen and chondroitin sulfate proteoglycan (CSPG) monomer were investigated using simultaneous double immunofluorescence and lectin localization reactions. Type II procollagen was distributed in vesicles throughout the cytoplasm, whereas intracellular precursors of CSPG monomer were accumulated in the perinuclear cytoplasm. In this study, cytoplasmic vesicles that stained intensely with antibodies directed against CSPG monomer but did not react with type II collagen antibodies, also were observed. A monoclonal antibody, 5-D-4, that recognizes keratan sulfate determinants was used to identify the Golgi complex (the site of keratan sulfate chain elongation). Staining with 5-D-4 was restricted to the perinuclear cytoplasm. The vesicles outside the perinuclear cytoplasm that stained intensely with antibodies to CSPG monomer did not react with 5-D-4. Fluorescent lectins were used to characterize further subcellular compartments. Concanavalin A, which reacts with mannose-rich oligosaccharides, did not stain the perinuclear region, but it did stain vesicles throughout the rest of the cytoplasm. Because mannose oligosaccharides are added cotranslationally, the stained vesicles throughout the cytoplasm presumably correspond to the rough endoplasmic reticulum. Wheat germ agglutinin, which recognizes N-acetyl-D-glucosamine and sialic acid (carbohydrates added in the Golgi), stained exclusively the perinuclear cytoplasm. By several criteria (staining with the monoclonal antibody 5-D-4 and with wheat germ agglutinin), the perinuclear cytoplasm seems to correspond to the Golgi complex. The cytoplasmic vesicles that react with anti-CSPG monomer and not with anti-type II collagen contain precursors of CSPG monomer not yet modified by Golgi-mediated oligosaccharide additions (because they are not stained with wheat germ agglutinin or with the anti-keratan sulfate antibody); these vesicles may have a unique function in the processing of CSPG.     

Use ofH-2 mutations to quantitate alloreactivity: Alloreactivity is strongest against H-2 antigens which are closest to self

Lymph-node cells fromH-2 allogeneic, intra-H-2 recombinant andH-2 mutant congenic strains were sensitized in limiting dilution cultures to quantitate the cytotoxic T-lymphocyte precursor frequencies (CTL.Pf) against antigens encoded by different regions of theH-2 complex. When fourH-2K ^b mutants of C57BL/6 (B6) were tested, we observed anti-B6 CTL.Pf that were as high or higher than those of recombinant strains which differ from B6 at theK end of theH-2 complex. Relative to strains completelyH–2 allogeneic to B6, the CTL.Pf inH-2 ^bm1,H-2 ^bm3 andH-2 ^bm5 averaged 40–50 percent, andH-2 ^bm8 averaged 140 percent. Recombinant strains B10.A (4R) and B10.D2 (R103), which differ from B6 at theK end of theH-2 complex, averaged 60 percent of the completelyH-2 allogeneic value. Since the mutant and wild-type gene products have no serological and minimal structural differences relative to other alleles atH-2K, these results indicate that the CTL.Pf does not increase with increasing H-2 antigenic disparity between any two strains. Rather, the data suggests that the T-cell receptor repertoire recognizes those H-2 molecules or determinants closest to self.