Intrahepatic DNA vaccination: unexpected increased resistance against murine cysticercosis induced by non-specific enhanced immunity.

Experimental murine cysticercosis caused by Taenia crassiceps has proved to be a useful model with which to test the efficacy of new vaccine candidates and delivery systems against pig cysticercosis. A high level of protection against murine cysticercosis was previously observed by intramuscular or intradermal DNA immunization with the use of the sequence of the recombinant KETc7 antigen cloned in pcDNA3 (pTc-sp7). To determine the effect of KETc7 differential expression in DNA vaccination, KETc7 was cloned in pGEM 11Zf(+) under the control of the tissue-specific regulatory promoter phosphoenolpyruvate carboxykinase (pPc-sp7). A high level of protection was induced by intrahepatic immunization with pPc-sp7, pTc-sp7 and the empty vector in the absence of any specific immunity. The empty vector pGEM 11Zf(+), the plasmid with the highest content of CpG sequences, provided to the most efficient protection. This protection was related to an increased number of splenocytes, enhanced nonspecific splenocyte proliferation, and intensified intrahepatic INF-gamma production. Overall, intrahepatic plasmid CpG-DNA immunization provokes an exacerbated nonspecific immune response that can effectively control Taenia crassiceps cysticercosis.

A combination of a transforming growth factor-beta antagonist and an inhibitor of cyclooxygenase is an effective treatment for murine pulmonary tuberculosis.

Transforming growth factor-beta (TGF-beta) and prostaglandins (PG) regulate the cell-mediated immune response, so it has been proposed that they affect the progression of pulmonary tuberculosis. Here we report that the administration of soluble betaglycan, a potent TGF-beta antagonist, and niflumic acid, a PG synthesis inhibitor, during the chronic phase of experimental murine tuberculosis enhanced Th1 and decreased Th2 cytokines, increased the expression of iNOS and reduced pulmonary inflammation, fibrosis and bacillary load. This immunotherapeutic approach resulted in significant control of the disease comparable to that achieved by anti-microbial treatment alone. Importantly, the combination of immunotherapy and anti-microbials resulted in an accelerated clearance of bacilli from the lung. These results confirm that TGF-beta and PG have a central pathophysiological role in the progression of pulmonary tuberculosis in the mouse and suggest that the addition of immunotherapy to conventional anti-microbial drugs might result in improved treatment of the disease.

Ligand binding and functional properties of betaglycan, a co-receptor of the transforming growth factor-beta superfamily. Specialized binding regions for transforming growth factor-beta and inhibin A.

Betaglycan, also known as the transforming growth factor-beta (TGF-beta) type III receptor, is a membrane-anchored proteoglycan that binds TGF-beta via its core protein. Deletion mutagenesis analysis has revealed two regions of betaglycan ectodomain capable of binding TGF-beta: one at the amino-terminal half, the endoglin-related region (López-Casillas, F., Payne, H., Andres, J. L., and Massagué, J. (1994) J. Cell Biol. 124, 557-568), and the other at the carboxyl-terminal half, the uromodulin-related region (Pepin, M.-C., Beauchemin, M., Plamondon, J., and O'Connor-McCourt, M. D. (1994) Proc. Natl. Acad. Sci. U. S. A 91, 6997-7001). In the present work we have functionally characterized these ligand binding regions. Similar to the wild type receptor, both regions bind TGF-beta2 with higher affinity than TGF-beta1. However, only the endoglin-related region increases the TGF-beta2 labeling of the TGF-beta type II receptor, the so-called "TGF-beta -presentation" function of the wild type receptor. Despite this preference, both regions as well as the wild type receptor mediate the TGF-beta2-dependent Smad2 phosphorylation, indicating that they can function indistinguishably as TGF-beta-enhancing co-receptors. On the other hand, we found that the recently described ability of the wild type betaglycan to bind inhibin A is a property of the core protein that resides in the uromodulin-related region. Binding competition experiments indicate that this region binds inhibin and TGF-beta with the following relative affinities: TGF-beta2 > inhibin A > TGF-beta1. All together, the present results suggest that betaglycan ectodomain is endowed with two bona fide independent ligand binding domains that can perform specialized functions as co-receptors of distinct members of the TGF-beta superfamily.

Recombinant soluble betaglycan is a potent and isoform-selective transforming growth factor-beta neutralizing agent.

Betaglycan is an accessory receptor of members of the transforming growth factor-beta (TGF-beta) superfamily, which regulates their actions through ligand-dependent interactions with type II receptors. A natural soluble form of betaglycan is found in serum and extracellular matrices. Soluble betaglycan, prepared as a recombinant protein using the baculoviral expression system, inhibits the actions of TGF-beta. Because of its potential use as an anti-TGF-beta therapeutic agent, we have purified and characterized baculoviral recombinant soluble betaglycan. Baculoviral soluble betaglycan is a homodimer formed by two 110 kDa monomers associated by non-covalent interactions. This protein is devoid of glycosaminoglycan chains, although it contains the serine residues, which, in vertebrate cells, are modified by these carbohydrates. On the other hand, mannose-rich carbohydrates account for approximately 20 kDa of the mass of the monomer. End-terminal sequence analysis of the soluble betaglycan showed that Gly(24) is the first residue of the mature protein. Similarly to the natural soluble betaglycan, baculoviral soluble betaglycan has an equilibrium dissociation constant (K(d)) of 3.5 nM for TGF-beta1. Ligand competition assays indicate that the relative affinities of recombinant soluble betaglycan for the TGF-beta isoforms are TGF-beta2>TGF-beta3>TGF-beta1. The anti-TGF-beta potency of recombinant soluble betaglycan in vitro is 10-fold higher for TGF-beta2 than for TGF-beta1. Compared with a commercial pan-specific anti-TGF-beta neutralizing antibody, recombinant soluble betaglycan is more potent against TGF-beta2 and similar against TGF-beta1. These results indicate that baculoviral soluble betaglycan has the biochemical and functional properties that would make it a suitable agent for the treatment of the diseases in which excess TGF-beta plays a central physiopathological role.

Two epitopes shared by Taenia crassiceps and Taenia solium confer protection against murine T. crassiceps cysticercosis along with a prominent T1 response.

Taenia crassiceps recombinant antigens KETc1 and KETc12 have been shown to induce high level of protection against experimental murine T. crassiceps cysticercosis, an experimental model successfully used to test candidate antigens for use in vaccination against porcine Taenia solium cysticercosis. Based on the deduced amino acid sequence, KETc1 and KETc12 were chemically synthesized in linear form. Immunization with KETc1 induced 66.7 to 100% protection against murine cysticercosis, and immunization with KETc12 induced 52.7 to 88.1% protection. The elicited immune response indicated that both peptides contain at least one B-cell epitope (as demonstrated by their ability to induce specific antibodies) and one T-cell epitope that strongly stimulated the proliferation of T cells primed with either the free peptide or total cysticercal T. crassiceps antigens. The high percentage of spleen cells expressing inflammatory cytokines points to the likelihood of a T1 response being involved in protection. The protective capacity of the peptides and their presence in all developmental stages of T. solium point to these two epitopes as strong candidates for inclusion in a polyepitopic synthetic vaccine against T. solium pig cysticercosis.

Taenia crassiceps cysticercosis: protective effect and immune response elicited by DNA immunization.

The nucleotide sequence of a protective recombinant antigen of Taenia crassiceps cysticerci present in all stages of Taenia solium (KETc7), cloned into pcDNA3 plasmid with the signal peptide sequence of the beta-glycan receptor (pTc-sp7), has been shown to be effective in protecting mice against experimental infection of T. crassiceps. To explore further the possibilities of this form of immunization and the immune response induced, mice were injected intramuscularly (i.m.) or intradermally (i.d.) with 3 doses of pTc-sp7. Similar levels of resistance were found using either i.m. or i.d. immunization. Spleen cells from i.d. and i.m. DNA immunized mice induced a specific T-cell response to T. crassiceps antigens and to a synthetic peptide from the immunogen itself (GK-1). Proliferated cells were especially enriched in CD8+ CD4- T-lymphocytes. A clear increase in the percentage of CD3+ cells that produce gamma-interferon and interleukin-2 was detected when measuring the intracellular cytokine production, an indication of the pTc-sp7 capacity to induce an effective cellular response. These results provide encouraging information on the use of KETc7 in the prevention of cysticercosis as well as a first insight into the characterization of the immune response induced by pTc-sp7 that hints to the relevance of cellular immunity in protection.

Towards a Taenia solium cysticercosis vaccine: an epitope shared by Taenia crassiceps and Taenia solium protects mice against experimental cysticercosis.

The Taenia crassiceps recombinant antigen KETc7 has been shown to be effective as a vaccine against experimental murine cysticercosis, a laboratory model used to test potentially promising molecules against porcine Taenia solium cysticercosis. Based on the deduced amino acid sequence of this proline-rich polypeptide, three fragments, GK-1, GK-2, and GK-3, were chemically synthesized in linear form. Of the three peptides, only GK-1 induced sterile protection against T. crassiceps cysticercosis in 40 to 70% of BALB/cAnN male mice. GK-1 is an 18-amino-acid peptide which contains at least one B-cell epitope, as demonstrated by its ability to induce an antibody response to the peptide and T. crassiceps antigen without need of a carrier protein. Immunofluorescence studies revealed that anti-GK1 antibodies strongly react with the native protein in the tegument of T. crassiceps and also with anatomical structures of T. solium eggs, oncospheres, cysticercus, and tapeworm. GK-1 also contains at least one T-cell epitope, capable of stimulating the proliferation of CD8(+) and to a lower extent CD4(+) T cells primed either with the free peptide or T. crassiceps total antigen. The supernatant of the stimulated cells contained high levels of gamma interferon and low levels of interleukin-4. Similar results were obtained with T cells tested for intracellular cytokine production, an indication of the peptide's capacity to induce an inflammatory response. The remarkable protection induced by GK-1 immunization, its physicochemical properties, and its presence in all developmental stages of T. solium point to this synthetic peptide as a strong candidate in the construction of a synthetic vaccine against T. solium pig cysticercosis.

Murine betaglycan primary structure, expression and glycosaminoglycan attachment sites.

The primary structure of murine betaglycan, also known as transforming growth factor beta (TGF-beta) type III receptor, was deduced from the nucleotide sequence of a cDNA clone isolated from a heart library. Murine betaglycan is a single spanning membrane polypeptide of 850 amino acids which is highly similar to betaglycan of other species. Transfection of this cDNA into COS1 cells resulted in the expression of a membrane proteoglycan that binds TGF-beta and is recognized by antibodies raised against rat betaglycan. COS1 cells transfected with the double mutant Ser533Ala; Ser544Ala of the murine betaglycan cDNA produced a TGF-beta type III receptor devoid of glycosaminoglycan chains.

Taenia crassiceps cysticercosis: humoral immune response and protection elicited by DNA immunization.

The purpose of this study was to evaluate DNA vaccination in cysticercosis prevention by using a Taenia crassiceps cDNA of a recombinant antigen (KETc7) that has been reported as protective against murine cysticercosis. The KETc7 cDNA was cloned into the pcDNA3 plasmid alone or with the betaglycan signal peptide sequence (pTc-7 and pTc-sp7, respectively). Positive expression of the pTc-sp7 product was confirmed by transfection of C33 cells and immunofluorescence using sera of mice infected with T. crassiceps. Immunization of mice with 3 injections of pTc-sp7 DNA at the higher dose (200 microg) was the most effective to induce antibody with or without bupivacaine. Immunization with pTc-sp7 induced protection against challenge with T. crassiceps cysticerci as successfully as previously observed with the KETc7 recombinant protein. Antibodies elicited by DNA immunization with pTc-sp7 specifically reacted with the native protein of 56 kDa previously reported, which is immunolocalized in the tegument of T. crassiceps cysticerci. The 56-kDa antigen is also present in Taenia solium oncospheres, cysticerci, and adult tissue. The protection induced in DNA-immunized mice and the observation that the injected plasmid remains as an episomic form within muscle cells, encouraged us to continue testing this procedure to prevent T. solium cysticercosis.

Role of the juxtamembrane domains of the transforming growth factor-alpha precursor and the beta-amyloid precursor protein in regulated ectodomain shedding.

Although regulated ectodomain shedding is a well known process that affects a large group of transmembrane molecules, it is not clear how the shedding system selects its substrates. Here we investigate the structural requirements for the regulated shedding of two substrates of the general shedding system, the transforming growth factor-alpha precursor, pro-TGF-alpha, and the beta-amyloid precursor protein, beta-APP. The ability of different regions of pro-TGF-alpha or beta-APP to confer susceptibility to the shedding system was tested using as a reporter a transmembrane molecule that is not a substrate of this shedding system. For this purpose we chose the TGF-beta accessory receptor, betaglycan, since genetic and biochemical evidence showed that betaglycan is not a substrate of the shedding system. We determined that replacement of the 14 extracellular amino acids adjacent to the transmembrane region of betaglycan with the corresponding regions of TGF-alpha or beta-APP rendered betaglycan susceptible to ectodomain shedding. These domain swap constructs were cleaved in response to protein kinase C stimulation, and cleavage was prevented by the metalloprotease inhibitor TAPI, both effects being characteristic of the general shedding system. Domain swap constructs containing the transmembrane and/or the cytoplasmic domains of pro-TGF-alpha did not undergo regulated ectodomain cleavage. We conclude that despite a lack of sequence similarity, the extracellular regions of pro-TGF-alpha and beta-APP immediately preceding their transmembrane domains are key determinants of ectodomain shedding.

Betaglycan can act as a dual modulator of TGF-beta access to signaling receptors: mapping of ligand binding and GAG attachment sites.

Betaglycan, also known as the TGF-beta type III receptor, is a membrane-anchored proteoglycan that presents TGF-beta to the type II signaling receptor, a transmembrane serine/threonine kinase. The betaglycan extracellular region, which can be shed by cells into the medium, contains a NH2-terminal domain related to endoglin and a COOH-terminal domain related to uromodulin, sperm receptors Zp2 and 3, and pancreatic secretory granule GP-2 protein. We identified residues Ser535 and Ser546 in the uromodulin-related region as the glycosaminoglycan (GAG) attachment sites. Their mutation to alanine prevents GAG attachment but does not interfere with betaglycan stability or ability to bind and present TGF-beta to receptor II. Using a panel of deletion mutants, we found that TGF-beta binds to the NH2-terminal endoglin-related region of betaglycan. The remainder of the extracellular domain and the cytoplasmic domain are not required for presentation of TGF-beta to receptor II; however, membrane anchorage is required. Soluble betaglycan can bind TGF-beta but does not enhance binding to membrane receptors. In fact, recombinant soluble betaglycan acts as potent inhibitor of TGF-beta binding to membrane receptors and blocks TGF-beta action, this effect being particularly pronounced with the TGF-beta 2 isoform. The results suggest that release of betaglycan into the medium converts this enhancer of TGF-beta action into a TGF-beta antagonist.

Betaglycan presents ligand to the TGF beta signaling receptor.

Transforming growth factor beta (TGF beta) signals through a heteromeric protein kinase receptor that has a limited ability to bind ligand. This limitation is overcome by the action of betaglycan (TGF beta type III receptor), a separate TGF beta-binding membrane protein of previously unknown function. Betaglycan presents TGF beta directly to the kinase subunit of the signaling receptor, forming a high affinity ternary complex. Membrane betaglycan increases TGF beta binding to the signaling receptor, enhances cell responsiveness to TGF beta, and eliminates marked biological differences between TGF beta isoforms. Thus, betaglycan is a direct regulator of TGF beta access to the signaling receptors.

TGF-beta receptors.

The nature and role of cell surface proteins that bind members of the TGF-beta family has been investigated. TGF-beta, activins, and BMPs each bind to receptors of 55 kDa (type I) and 70 kDa (type II). In the TGF-beta system, these receptors are implicated in the mediation of multiple responses. A member of the type II receptor family has been cloned that encodes four alternatively spliced versions of a transmembrane serine/threonin kinase receptor related to the recently cloned mouse activin receptor and C-elegans daf-1 gene. Inhibitors of serine/threonine kinase activity block transcriptional and growth inhibitory responses to TGF-beta. In addition to the signaling receptors, many cell types express the TGF-beta binding proteoglycan betaglycan. Betaglycan has been purified, molecularly cloned, and shown to bind TGF-beta via its core protein and basic fibroblast growth factor via its heparan sulfate chains. In addition to receptors I and II and betaglycan, some cells express a newly identified set of membrane proteins that specifically bind either TGF-beta 1 or TGF-beta 2. Three of the four isoform-restricted binding proteins are bound to the membrane via phospholipid anchors. Like betaglycan, these proteins might function to regulate the interaction between TGF-beta and their target cells.

Acetyl-coenzyme A carboxylase mRNA metabolism in the rat liver.

The acetyl-coenzyme A carboxylase (ACC) gene contains two promoters (PI and PII), both of which are active in the liver. Various physiological stimuli affect one, or both of the promoters of the ACC gene, and result in the generation of two classes of ACC mRNAs which differ in the composition of their 5' untranslated regions (5' UTR). We have analyzed the amounts of the two major mRNAs species that are generated from each of these promoters in order to examine the regulation of ACC gene activity in the liver under different physiological conditions. Our findings can be summarized as follows: (1) In liver from normal animals, fed a complete laboratory chow ad libitum, the level of class 2 ACC mRNA species generated by PII is very low. These mRNA species disappear on starvation. Refeeding starved animals with a fat-free diet stimulates both PI and PII with different time courses of induction: PII responds quickly and PII gene products accumulate to maximum levels within 18 hours, while the PI response, as measured by the accumulation of class 1 mRNAs, shows a lag period of 6 hours before reaching maximal levels at the end of a 24-hour refeeding period. The half-lives estimated from the induction kinetics were 4.4 hours for class 2 mRNAs and 11.8 hours for class 1 mRNAs. Reinstatement of starvation causes an almost instantaneous disappearance of class 1 mRNA species, as compared with class 2 mRNA species. This rapid decay of PI transcripts suggests that factors stabilizing this class of ACC mRNAs contribute to the steady-state levels reached after the dietary induction.(ABSTRACT TRUNCATED AT 250 WORDS)

Acetyl-coenzyme A carboxylase messenger ribonucleic acid metabolism in liver, adipose tissues, and mammary glands during pregnancy and lactation.

In the rat, the acetyl-coenzyme A carboxylase gene exists as a single copy per haploid chromosome set. However, multiple forms of acetyl-coenzyme A carboxylase mRNA exist, the relative abundance of which varies in a tissue-specific manner under different physiological conditions. In the mammary gland, the major acetyl-coenzyme A carboxylase mRNA species are of the class 2 type, which are products of promoter II. In parametrial white adipose tissue, the main form of species of acetyl-coenzyme A carboxylase is of the class 1 type, which are produced by promoter I. Pregnancy and lactation affect the amounts of these acetyl-coenzyme A carboxylase mRNA. Although the mammary gland acetyl-coenzyme A carboxylase mRNA species increase dramatically upon parturition, the parametrial white adipose tissue forms decrease precipitously at the same time and are not expressed at all during the lactation period. In the liver of these animals, the only form of acetyl-coenzyme A carboxylase mRNA that is expressed is the FL56 form; this form shows a modest decrease during pregnancy that is slowly reversed during lactation. These observations indicate that the changes in lipogenesis that occur during pregnancy and lactation are determined by the transcriptional activity of the acetyl-coenzyme A carboxylase gene. In order to analyze the complex transcriptional activity of this gene in a meaningful way, it is necessary to examine the metabolism of individual isoforms of acetyl-coenzyme A carboxylase mRNA.

Structure and expression of the membrane proteoglycan betaglycan, a component of the TGF-beta receptor system.

We describe the primary structure of rat betaglycan, a polymorphic membrane-anchored proteoglycan with high affinity for transforming growth factor-beta (TGF-beta). As deduced from its cDNA sequence, the 853 amino acid core protein of betaglycan has an extracellular domain with clustered sites for potential attachment of glycosaminoglycan chains. These chains are dispensable for TGF-beta binding to the core protein. The transmembrane region and the short cytoplasmic tail of betaglycan are very similar to these regions in human endoglin, an endothelial cell membrane glycoprotein involved in intercellular recognition. The ectodomain of betaglycan can be released as a soluble proteoglycan; a potential cleavage site near the transmembrane region is identical to the highly regulated cleavage site of the membrane-anchored transforming growth factor-alpha precursor. The unique features of betaglycan suggest important roles in cell interaction with TGF-beta.