Characterization of endonuclease activity from excretory/secretory products of a parasitic nematode, Trichinella spiralis.

Double-stranded endonuclease activity was demonstrated for the first time in the excretory/secretory (ES) products of a parasitic nematode, Trichinella spiralis, which can reorganize host muscle cells. The endonuclease introduced double-stranded breaks to the native DNA. The ES double-stranded endonuclease(s) was sequence nonspecific, with a pH optimum below 6, and required divalent cations as a cofactor. Its activity was inhibited by the Zn2+ ion. It was detected mainly in the ES products of the infective-stage larvae of T. spiralis collected at 37 degrees C and was present in much smaller amounts in samples collected at 43 degrees C and in the products of T. pseudospiralis, a nonencapsulated species. The activity of endonuclease was blocked by antibodies against ES products. Zymographic analysis showed that the endonuclease activity was associated with at least three molecular forms, designated approximately 25, 30 and 58 kDa, respectively.     

Trichinella spiralis: immunization of mice using monoclonal antibody affinity-isolated antigens

An antigen epitope was identified from the excretory-secretory products of Trichinella spiralis first-stage larvae using monoclonal antibodies, and the glycoprotein antigens bearing this epitope (Ts.49 and Ts.53) were isolated from the crude excretory-secretory preparation by affinity chromatography. In immunization experiments carried out in mice, antigen priming with Ts.49 and Ts.53 resulted in a reduction of muscle larvae resulting from a challenge infection at a level comparable to priming with crude excretory-secretory antigens. In addition, antigens Ts.49 and Ts.53 induced an accelerated expulsion of adult worms from the intestines of immunized mice and reduced the fecundity of remaining female worms.     

Differentiation between Trichinella spiralis and T. pseudospiralis infective larvae by a monoclonal antibody

Crude saline extracts of Trichinella spiralis and T. pseudospiralis infective larvae were studied by Western blot analysis using a monoclonal antibody, named ES/TA2 and produced against T. spiralis larvae. This monoclonal antibody recognized seven major antigenic components in T. spiralis larvae with apparent Mr: 45, 48, 50, 68, 70, 92 and 105 kDa and five in T. pseudospiralis larvae: 38, 50, 70, 72 and 92 kDa. SDS-PAGE of both extracts did not reveal appreciable differences in the range of molecular weights recognized by ES/TA2. These facts show the existence of immunological differences among proteins with apparently identical molecular weights.     

Trichinella britovi human infection in Spain: antibody response to surface,excretory/secretory and somatic antigens

A third outbreak of Trichinella britovi with 140 people involved, occurred in Granada Spain (December 1998). The source of infection was sausage made from uninspected wild boar meat. Fifty-two patients agreed to participated in this study. An elevated eosinophil level (> 5%) was detected in 59.6% of patients, and persisted in most of these cases for two months. A moderate IgG response was observed. At the onset of symptoms, Western blot (WB) test detected more positive cases than Enzyme linked immunosorbent assay (ELISA) and indirect immunofluorescence (IIF). Six months from infection, ELISA revealed fewer positive cases than the other two tests. It would appear that the response to somatic antigens starts earlier than those to cuticular and excretory/secretory (ES) antigens and that the response to ES antigens is the first to decrease.     

Trichinella spiralis: strong antibody response to a 49 kDa newborn larva antigen in infected rats

In this work, we analyzed the kinetics of anti-Trichinella spiralis newborn larva (NBL) antibodies (Ab) and the antigenic recognition pattern of NBL proteins and its dose effects. Wistar rats were infected with 0, 700, 2000, 4000 and 8000 muscle larvae (ML) and bled at different time intervals up to day 31 post infection (p.i.). Ab production was higher with 2000 ML dose and decreased with 8000, 4000 and 700 ML. Abs were not detected until day 10, peaked on day 14 for the 2000 ML dose and on day 19 for the other doses and thereafter declined slowly from 19 to 31 days p.i. In contrast, Abs to ML increased from day 10, peaked on day 19 and remained high until the end of the study. Abs bound strongly at least to three NBL components of 188, 205 and 49 kDa. NBL antigen of 188 and 205 kDa were recognized 10-26 days p.i. and that of 49 kDa from day 10 to day 31 p.i. A weak recognition towards antigens of 52, 54, 62 and 83 kDa was also observed during the infection. An early recognition of 31, 43, 45, 55, 68 and 85 kDa ML antigens was observed whereas the response to those of 43, 45, 48, 60, 64 and 97 kDa (described previously as TSL-1 antigens) occurred late in the infection. A follow-up of antigen recognition up to day 61 with the optimal immunization dose (2000 ML) evidenced a decline of Ab production to the 49 kDa NBL antigen 42 days p.i., which suggested antigenic differences with the previously reported 43 kDa ML antigen strongly recognized late in the infection. To analyze the stage-specificity of the 49 kDa NBL antigen, polyclonal antibodies (PoAb) were obtained in rats immunized with 49 kDa NBL antigen. PoAb reacted strongly with the 49 kDa NBL component in NBL total soluble extract but no reactivity was observed with soluble antigen of the other T. spiralis stages. Albeit with less intensity, the 49 kDa component was also recognized by PoAb together with other antigens of 53, 97 and 107 kDa, in NBL excretory-secretory products (NBL-ESP). Thus, our results reveal differences in the kinetics of anti-NBL and ML Ab responses. While anti-NBL Abs declined slowly from day 19 until the end of the experiment, Abs to ML antigen remained high in the same period. It is remarkable the optimal Ab response to NBL antigens with 2000 ML infective dose and the reduced number of NBL antigens identified throughout the experimental T. spiralis infection, standing out the immunodominant 49 kDa antigen. Interestingly, this antigen, which was prominently expressed in NBL somatic proteins, was also detected in NBL-ESP.     

Trichinella spiralis: newborn larval migration route in rats reexamined

The route by which Trichinella spiralis newborn larvae migrate from the small intestine to striated muscle was studied in inbred AO and random-bred Sprague-Dawley rats. Newborn larvae were quantitatively recovered from the thoracic duct lymph, peritoneal cavity, and hepatic portal vein blood during the course of a primary infection with 4000 muscle larvae. The total recovery of newborn larvae assessed in this manner was compared with the number of muscle larvae in control rats receiving the same infection. In both strains of rats, most of the newborn larvae were recovered from hepatic portal vein blood, fewer than 3% of newborn larvae were recovered from the thoracic duct lymph and peritoneal cavity combined. Long-term drainage of thoracic duct lymph (greater than 24 hr) significantly increased newborn larval recovery over short-term drainage (less than 24 hr). We conclude that there are several natural pathways of newborn larval migration that result in muscle larval establishment. These include direct invasion of capillaries and lymphatics in the intestine as well as migration through the intestinal serosa to the peritoneal cavity. In both AO and Sprague-Dawley rats, greater than or equal to 97% of newborn larvae migrate via the hepatic portal vein blood to the general circulation.     

Trichinella spiralis: immunization of pigs with newborn larval antigens

The potential of crude Trichinella spiralis newborn larval antigens for pig immunization was investigated. A preparation of whole newborn larvae killed by freezing and thawing, and combined with Freund's complete adjuvant, induced a high level of protection against challenge (78%), compared to a 40% resistance level in pigs immunized with excretory secretory antigens of muscle larvae. Sera from pigs immunized with newborn larvae contained antibodies which bound to the surface of the newborn larvae, as determined by immunofluorescence. In a second trial, the freeze thawed newborn larvae preparation was compared with a soluble and insoluble fraction prepared by sonication of whole newborn larvae. Pigs receiving whole newborn larvae or the insoluble fraction developed strong immunity to challenge (88.2 and 85.5%, respectively); the soluble fraction was ineffective. Immunization with all preparations induced antibody to newborn larval antigens, but not to adult or muscle larvae excretory secretory antigens. Polyacrylamide gel electrophoresis of the soluble and insoluble fractions indicated that sonication was ineffective in solubilizing the larger molecular weight components. These results demonstrate that newborn larval antigens are highly protective in pigs, but that their further development as a vaccine will require more efficient procedures for antigen solubilization and large-scale production.     

Enhancement of human neutrophil functions by a monoclonal antibody directed against a 19-kDa antigen.

A mouse IgG mAb termed P1C3 was raised against A23187-treated human peripheral blood neutrophils and has been shown to recognize an Ag with an apparent molecular mass of 19 kDa, herein named p19. This p19 Ag was weakly expressed at the cell surface of resting human peripheral blood neutrophils and monocytes, but its cell surface expression was dramatically increased upon activation of these cell types with different secretagogues, including FMLP, PMA, and the calcium ionophores A23187 and ionomycin. A large latent pool of p19 molecules became accessible by immunofluorescence flow cytometry after cell permeabilization of resting neutrophils. A practically total translocation of the intracellular pool of this p19 molecule to the plasma membrane was achieved under appropriate cell stimulation, which induced an almost total degranulation of neutrophil secretory granules. The p19 Ag was absent from platelets, PBL, as well as from the human promyelocytic cell line HL-60, the human promonocytic cell line U937, and the human lymphoid cell lines Daudi and Jurkat. The p19 Ag was also expressed by circulating and/or interstitial neutrophils and monocytes in distinct tissues examined. The mAb P1C3 was found to enhance several neutrophil responses, such as chemotaxis, cell adhesion, phagocytosis, and respiratory burst. These data indicate that the mAb P1C3 recognizes an intracellular Ag in human resting mature neutrophils and monocytes, which upon cell activation is translocated to the cell surface and is able to affect cell functionality.     

Detection and characterization of excretory/secretory proteins from Toxoplasma gondii by monoclonal antibodies

Excretory/secretory proteins (ESP) from Toxoplasma gondii were analyzed to define the function in the penetration process into host cells. Whole ESP obtained at 37 degrees C were composed of 15 bands with molecular mass of 110, 97, 86, 80, 70, 60, 54, 42, 40, 36, 30, 28, 26, 22, and 19 kDa. Five ESP of 86, 80, 42, 36, and 28 kDa were reacted with monoclonal antibodies (mAb), named as Tg386 (microneme), Tg485 (surface membrane), Tg786 (rhoptry), Tg378, and Tg556 (both dense granules), respectively. The ESP was released by a temperature-dependent/-independent manner and all at once whenever ready to pour out except Tg786. Each ESP was not exhausted within the parasite but the amount was limited. Tg786 was released continuously with increment, whereas Tg378 and Tg556 were ceased to release after 3 and 4 hr. Dense granular Tg378 and Tg556 were released spontaneously and constitutively before the entry into host cells also. The entry of T. gondii was inhibited by all the mAbs differentially. And the parasite deprived of ESP was inhibited to enter exponentially up to 90.1%. It is suggested that ESP play an essential function to provide appropriate environment for the entry of the parasite into host cells.     

Analysis of a 43-kDa glycoprotein from the intracellular parasitic nematode Trichinella spiralis.

The L1 larvae of the parasitic nematode Trichinella spiralis invade skeletal muscle and initiate a process that has been interpreted to represent skeletal muscle dedifferentiation. In this process, the infected region of the muscle cell is converted into a unique structure, called the Nurse cell. The nematode T. spiralis can survive for tens of years within the cytoplasm of the Nurse cell and secretes proteins into the cytoplasm that are believed to play a role in mediating the Nurse cell formation or maintenance. We have cloned a cDNA encoding the T. spiralis-derived, 43-kDa secreted protein. Structural analysis of the predicted 344-amino acid sequence revealed an N terminally located signal peptide and a potential helix-loop-helix motif in the main body of the protein. Antibodies raised against the 43-kDa recombinant protein were used in immunocytolocalizations of T. spiralis-infected skeletal muscle sections. These antibodies strongly stained the Nurse cell nuclei and the nematode itself. Specific, though slightly weaker staining also occurred in the Nurse cell cytoplasm. In Western blots, the antibodies react with the 43-kDa protein but also detected at least two other T. spiralis-secreted proteins. DNA hybridizations reveal at least one additional 43-kDa-related sequence encoded in the T. spiralis genome. We conclude that either the 43-kDa protein and/or a closely related 43-kDa family member is secreted into the muscle and translocates to the muscle-derived nuclei. This model may provide insights into the mechanisms involved in Nurse cell formation.     

Entamoeba histolytica: specific antigen recognized by a monoclonal antibody

Specific antigenic determinants on the membrane surface of Entamoeba histolytica that distinguish it from other Entamoeba species were demonstrated. Evidence for these antigenic determinants was obtained with a monoclonal antibody to E. histolytica which showed not only specificity but also sensitivity as demonstrated in enzyme linked immunosorbent assay. Immunofluorescence microscopy showed that the monoclonal antibody recognized an epitope present on the membrane surface of E. histolytica trophozoites. The epitope detected by the monoclonal antibody was present in three components of different molecular weight. These components may have a common precursor or may be the result of enzymatic degradation under the conditions tested.     

Trichinella spiralis: macrophage activity and antibody response in chronic murine infection

The role of macrophages, their products, and the specific antibody response were examined during chronic Trichinella spiralis infection in BALB/c mice. Adult T. spiralis in intestines were detected from 5 to 20 dpi. Muscle larvae numbers peaked at 45 dpi and thereafter a reduction was noted. The highest numbers of macrophages in the peritoneal cavity of infected mice were obtained up to 30 dpi. The production of NO by macrophages in infected mice was suppressed at 5 dpi, and then NO release increased until 45 dpi. The levels of NO in plasma and urine were lower in infected mice during the entire experiment in comparison to control. The production of O(2)(-) in peritoneal macrophages was inhibited during the first two weeks after infection and then increased until 90 dpi. Circulating T. spiralis antigens in plasma and urine were detected from 5 to 30 dpi. Specific IgM and IgA in serum increased until 20 dpi. IgG, IgG(1), and IgG(2) levels in serum increased until 60 dpi.     

Tissue-specific mammary gland antigen identified by monoclonal antibodies

A new antigen of mammary tumor cells has been revealed using monoclonal antibodies. A similar antigen was detected also in certain types of secretory epithelia of oesophagus, stomach, salivary gland, and embryonic large intestine. Upon malignization, antigen persists in invasive ductal cancer of mammary gland and is expressed in cancers of ovary and rectum. The molecular weight of the antigen is greater than 2,000 kD.     

Trichinella spiralis: light microscope monoclonal antibody localization and immunochemical characterization of phosphorylcholine and other antigens in the muscle larva

A panel of monoclonal antibodies was used to examine the structure of the muscle larva of Trichinella spiralis under the light microscope. Immunofluorescence and, in some cases, immunoperoxidase staining were used. All four antibodies reacted with the cuticle of the organism, although differences in the staining pattern were observed for some of these. Interestingly, all the antibodies also reacted with the stichosome. One of the antibodies (Ts2Ab) is specific for the hapten, phosphorylcholine. In a binding assay, this antibody also reacted with extracts of Trichuris suis, Ascaris suum, and Fasciolopsis buski, but not with extracts derived from Cysticercus cellulosae, Candida albicans, Salmonella typhi, or Escherichia coli. This crossreactivity was confirmed microscopically in which the cuticle, oviduct and eggs of T. suis, the cuticle, muscle cells, and eggs of A. suum, and the cuticle and vitelline glands of F. buski were seen to be clearly stained by the antibody. In addition, Ts2Ab also reacted with the cuticle and stichosome of the adult T. spiralis worm. In Western blot analysis, Ts2Ab recognized a 43-kDa antigen from T. spiralis muscle larvae extracts, while a previously studied antibody (7C2C5Ab) identified four major antigens (48.5, 47, 43, and 39 kDa) in this preparation. Similar results were obtained when the 24-hr excretory-secretory (ES) antigens of T. spiralis were immunoblotted with the antibodies, although the reactivity shown by Ts2Ab was relatively weak. With the 72-hr ES material, on the other hand, major antigens of lower mol wt (44, 28, and 25 kDa) were revealed by 7C2C5Ab, and no reactivity was seen with Ts2Ab. However, this antigen preparation reacted well with both antibodies in an enzyme-linked immunoassay. Taken together, the findings suggest that the 72-hr ES antigens probably result from extensive degradation of material originally secreted or excreted by the worm. Similar binding studies on the 24-hr ES preparation indicated that this source may be relatively rich in 7C2C5Ab-reactive epitopes and relatively poor in the antigen identified by Ts2Ab. Other studies performed demonstrated that the antigens recognized by these two antibodies were distinct and physically unassociated.     

Recognition of a genus-wide antigen ofLegionella by a monoclonal antibody

A monoclonal antibody was produced against a cytoplasmic membrane protein that appears to be common to all species of the genusLegionella. The antibody was positive in polyacrylamide gel electrophoresis and Western blotting with extracts of all of 22 species type strains ofLegionella that were tested. The apparent molecular mass of the protein varied from 57.2 to 62.1 kilodaltons for the 23 species type strains ofLegionella. An enzyme-linked immunosorbent assay (ELISA) was developed with the monoclonal antibody to enable rapid screening of clinical and environmental isolates forLegionella. All of 23 species type strains ofLegionella that were tested were strongly positive with the monoclonal antibody in the ELISA. Among 27 other bacterial species and 84 strains that were tested, onlyBordetella ssp. andAcinetobacter lwoffii were cross-reactive in the ELISA. These two cross-reactive species are readily distinguishable fromLegionella by culture characteristics. The monoclonal antibody may also be useful in tests to detect the genus-wide antigen in body fluids of patients with legionellosis.