Kinetics of the antibody response to type III pneumococcal polysaccharide. II. Factors influencing the serum antibody levels after immunization with an optimally immunogenic dose of antigen.

When the number of PFC present in the spleen was measured at 24-hr intervals after immunizing with an optimally immunogenic dose of type III pneumococcal polysaccharide (SSS-III), maximal numbers of PFC were attained 4 days after immunization; thereafter, the number of PFC decreased rapidly. By contrast, serum antibody levels, which were measured in the same mice using a Farr test, reached peak values 5 days after immunization and then declined much more slowly than did the number of PFC. Two factors were found to contribute to this disparity. First, experiments conducted with splenectomized mice showed that extrasplenic antibody synthesis, which began between days 3 and 4 after immunization and peaked on days 6 to 7, accounted for nearly one-third of the total amount of serum antibody produced. Second, the average rate of antibody synthesis by PFC increased through day 6 after immunization and then declined. Antigen-antibody dissociation tests showed that the avidity of the serum antibody obtained 4 to 7 days after immunization was the same. Moreover, during the same interval, all the antibody detected by the Farr test was of the IgM class. Thus, a change in avidity or class of immunoglobulin after day 5 did not account for the disparity observed. The clearance rate of antibody injected i.v. into nonimmune and immunized mice was studied. The data obtained indicated that accelerated clearance of antibody was occurring prior to day 3 after immunization; however, after day 3 the antibody clearance rate was constant and was the same as that found when antibody was injected into nonimmune mice. These findings affirmed the results of previous studies showing that treadmill neutralization was not important in determining the serum antibody levels present after immunization with an optimally immunogenic dose of SSS-III.     

Kinetics of the antibody response to type III pneumococcal polysaccharide (SSS-III). I. Use of 125I-labeled SSS-III to study serum antibody levels, as well as the distribution and excretion of antigen after immunization.

A simple method was described for the preparation of 125I-labeled type III neumococcal polysaccharide (SSS-III) with a high specific radioactivity which retained the physical and immunologic properties of native SSS-III. SSS-III was used to study the serum and tissue levels of antigen, as well as its excretion, after i.p. injection. When an optimally immunogenic dose (0.5 mug) of antigen was given, greater than 90% of the injected antigen was excreted during the first 3 days after injection; however, after day 3, the SSS-III which remained in each mouse was firmly bound to various tissues, and less than 5 ng SSS-III was released into the circulation daily. SSS-III was also used in a Farr test to measure serum antibody levels; the kinetics for the appearance of PFC/spleen and serum antibody levels were measured at 24-hr intervals after immunization with 0.5 mug of antigen. Maximum PFC/spleen were observed on day 4 after immunization whereas the peak serum antibody level was seen on day 5. The decay of serum antibody level from its maximum value was much slower than that of the PFC/spleen. The data describing the distribution of SSS-III in vivo and the measurement of serum antibody levels indicated that treadmill neutralization was not a factor in determining the serum antibody levels after immunization with an optimally immunogenic dose of SSS-III.     

Complement-dependent and -independent pathways of T cell-B cell cooperation.

BDF1 mice treated with CoV had markedly reduced levels (less than 20%) of native serum C3 32 hr later, whereas the frequency of splenic CR+ cells was normal. CoV treatment before immunization reduced the IgM PFC response to a T-dependent antigen (TNP-SRBC) by more than 60%. Inclusion of highly specific anti-C3 antibody had no effect on the T-dependent IgM response of CR- B cells. The residual PFC responses in cultures of unfractionated spleen cells treated with anti-C3 could be largely or completely accounted for by CR- B cells in the cultures. The effect of anti-C3 antibody was not due to cytotoxicity. These data collectively indicate that the effect of CoV on T-dependent antibody responses is due to decreased C3 in serum rather than to interaction of C receptors directly with CoV or with C3 cleavage products. They suggest the existence of at least two distinct pathways of T-B cooperation, one in which C3 is an obligatory participant and another in which it may be uninvolved.     

Effect of bacterial lipopolysaccharides on anti-trinitrophenyl antibody-producing cells. Nonspecific modification of the affinity at the cellular level.

The effect of lipopolysaccharide (LPS) on anti-trinitrophenyl (TNP) direct plaque-forming cells (PFC) in the spleen of mice and the affinity of antibodies produced by these PFC were examined. Simultaneous injection of bacterial LPS and TNP-coupled sheep red blood cells(SRBC) induced an obvious increase in anti-TNP PFC numbers and heightened the antibody affinity at cellular levels. The higher the doses of LPS, the greater the effects. Concomitant injection of LPS in TNP-coupled homologous mouse red blood cells (MRBC) also elicited good anti-TNP PFC response and slightly heightened the affinity. Priming with LPS and SRBC together 7 days prior to immunization did not enhance the anti-TNP PFC response and it was difficult to alter the affinity. Preinjection with small amounts of TNP-MRBC or -rabbit red blood cells and LPS simultaneously did not induce any significant increase in anti-TNP PFC secondary response after reimmunization with TNP-SRBC, but obviously heightened the antibody affinity. Injection of LPS simultaneously with the secondary immunization was effective for both the anti-TNP PFC response and the alteration of antibody affinity. These results suggest that LPS affects the control mechanisms of anti-TNP antibody affinity via the non-thymus-derived helper cell function, and the adjuvant action and alteration of antibody affinity induced by LPS are regulated by different mechanisms.     

Selective improvement of thymus and some T cell dysfunctions in NZB mice by in utero thymulin treatment

NZB mice were treated during gestation with thymulin, a thymus-secreted, zinc-associated nonapeptide. Control pregnant NZB mice received either zinc alone or saline alone. Offspring from all three groups of NZB mothers, and age-matched DBA/2 mice, were tested for the following immunologic parameters: thymulin serum levels at 2 and 5 wk of age; splenic anti-sheep red blood cell (anti-SRBC) plaque-forming cell (PFC) numbers after immunization at birth or at 2 wk of age; anti-human gamma-globulin (anti-HGG) antibody titers after immunization at 2 wk of age, with or without prior tolerance induction at birth with deaggregated HGG; spontaneous IgM serum levels at 2 and 5 wk of age; spontaneous splenic anti-trinitrophenyl (anti-TNP) PFC numbers at 2 wk of age. As compared with DBA/2 mice, young NZB mice exhibited low circulating thymulin titers, high antibody responses to SRBC and to HGG, resistance to tolerance induction by deaggregated HGG, increased spontaneous IgM serum levels, and increased spontaneous anti-TNP PFC numbers. However, marked reductions in anti-SRBC and anti-HGG antibody production, both thymus-dependent responses, were observed in the young NZB offspring of thymulin-treated mothers as compared with NZB controls born from zinc- or saline-treated mothers. A delay in the postnatal decrease of serum thymulin levels was also noted in the offspring of thymulin-treated mothers. Interestingly, these effects of in utero thymulin treatment tended to become more pronounced with advancing age during the postnatal period. Conversely, IgM serum levels, spontaneous anti-TNP PFC and sensitivity to tolerance induction were not affected by thymulin treatment during fetal life. Taken together, the data suggest that in utero exposure to pharmacologic concentrations of thymulin induces a persistent and selective improvement of some thymus and T cell dysfunctions but has no effect on intrinsic B cell abnormalities of NZB mice.     

Mechanisms of antibody formation: I. Early in vivo proliferation of mouse spleen T cells as an initial step in antibody formation

Spleen cultures prepared from mice injected 24 hr earlier with 2 × 10⁶?2 × 10⁸ sRBC and challenged in vitro with sRBC produced 10 times more anti-sRBC IgM PFC than cultures prepared from uninjected mice. The effect was specific for the particular species of foreign RBC injected in vivo. In vitro responses to TNP were also increased in spleen cultures prepared from animals injected 24 or 12 hr earlier with carrier RBC alone, directly implicating carrier-specific T cells in this process. Similar enhancements of PFC formation occurred in cultures prepared from mice which had been injected with sRBC 24 and 48 hr earlier, but which were exposed to lethal irradiation at 1 hr after injection of antigen, if their spleens were shielded extracorporeally during irradiation. This finding indicated that in vivo recruitment of antigen-reactive extrasplenic X-ray-sensitive cells from the circulating lymphocyte pool by the spleen could not account for the observed enhancement.Proliferation in the spleen of antigen-reactive T cells, commencing 12–20 hr after the administration of antigen, was demonstrated by the tritiated thymidine pulse technique. An 8-hr hot-pulse given to spleen cell cultures from normal animals at 20 hr after in vitro challenge with antigen did not affect the rate of generation of IgM-producing cells; however, administration of a similar pulse to cultures which were initiated at 12 or at 20 hr after the in vivo injection of sRBC eliminated the enhanced generation of PFC and delayed the in vitro response to sRBC by 24 hr.Spleen cell cultures were prepared from mice which had been injected in vivo with sRBC at 12, 20, and 70 hr earlier, and 8- to 10-hr hot pulses were given immediately after initiation of the cultures. The cultures were then challenged with sRBC-TNP; antibody responses to TNP were greatly reduced in hot-pulsed cultures prepared from mice injected in vivo with carrier RBC at 12 or 20 hr prior to initiation of the cultures. In contrast, antibody responses to TNP observed in hot-pulsed cultures prepared from mice which had been injected with carrier RBC at 70 hr prior to initiation of the cultures were generally similar to those of nonpulsed 70 hr control cultures. This result suggests that the onset of T helper cell proliferation begins within 12–20 hr after injection of antigen, but subsides in vivo within 70 hr. By that time, the antigen-reactive T cells have already differentiated to perform their helper function.In spite of the triggering of T-cell proliferation during the first 24 hr after injection of antigen, spleen cell cultures prepared from mice which had been injected 24 hr earlier in vivo with 2 × 10⁸ sRBC produced only minimal numbers of anti-sRBC PFC if no antigen was added to the cultures. The presence of unprocessed antigen thus appears to be a requirement for B-cell proliferation in vitro, even after T-cell division has been triggered. This finding is consistent with earlier suggestions that the function of “helper” T cells may not be limited to passive transport of antigenic determinants to B cells. Evidence is also presented to support the contention that the antigen-reactive T cell involved in this process may have to undergo cell division in order to develop “helper” capacity.     

In vitro studies of the rabbit immune system: III. T-cell requirement for initiation but not maintenance of anti-sheep erythrocyte plaque-forming cells

The in vitro anti-sheep erythrocyte plaque-forming-cell (anti-SRBC PFC) response of primed rabbit spleen cells can be abrogated by prior treatment with anti-thymocyte serum plus complement (ATS + C). The direct addition of ATS without C to stimulated cultures also reduces the response 60–90%, if the antiserum is added before the initiation of antigen-stimulated PFC production. However, the PFC response becomes refractory to ATS inhibition by 48 hr. This loss of ATS sensitivity is not caused by T cells themselves becoming refractory to ATS for the following reasons: (i) ATS + C treatment or ATS addition at 48 hr causes cytotoxic effects comparable to similar treatments at 0 hr; (ii) The responsiveness of cells incubated 48 hr before the addition of SRBC remains sensitive to ATS inhibition at that time. The loss of ATS sensitivity is also not the result of soluble T-cell factors which have accumulated in the medium, because the number of PFC in stimulated cultures continues to increase after treating with ATS + C and reculturing in fresh medium at 48 hr. We conclude that T cells are required to initiate the production of antibody by B cells but are not required to maintain the later proliferative events.     

Suppression of the in vitro secondary antibody response of rabbit lymphoid cells by Concanavalin A.

The effect of various concentrations of concanavalin A (Con A) on the in vitro secondary antibody response of rabbit lymph node and spleen cells to sheep red blood cells (SRBC) was studied. Complete suppression of the IgM plaque-forming cell (PFC) response of both lymph node and spleen cultures was observed when 10 mug/ml of Con A was added at the time of initiation of the cultures whereas only partial suppression was observed when 1 mug/ml of Con A was added. Moreover, marked suppression of the immune responses of both spleen and lymph node cultures was observed when 10 mug/ml of Con A was added at 24 hr after antigenic challenge and to a lesser extent when added at 48 hr. Suppression of the IgM PFC response was also detected when spleen cultures were exposed to 10 mug/ml of Con A for as little as 2 hr after antigenic challenge. However, substantial increases in DNA synthesis were observed only in those cultures which were in contact with Con A for at least 24 hr. Finally evidence is presented that the Con A-induced suppression is mediated by a soluble substance(s).     

Variations in the responses of C57BL and a mice to sheep red blood cells: II. Analysis of plaque-forming cells

The number of direct and indirect plaque-forming cells (PFC) and the serum hemolytic activity was determined for A/He, C57BL/6J, and B6AF1 mice responding to multiple injections of sheep red blood cells (SRBC). Although the kinetics of the primary response differed, all mice had high numbers of both direct and indirect PFC and low-titered 2-mercaptoethanol (2-ME) sensitive serum antibody. Following multiple SRBC injections, the A/He spleens contained predominantly IgG producing PFC. Their serum antibody activity was resistant to 2-ME signifying the presence of IgG. The serum activity of both the C57BL/6J and B6AF1 mice was sensitive to 2-ME (IgM antibody) over the course of immunization, and although there was a definite IgM PFC memory response, the presence of 7S memory PFC was questionable. The results are discussed in terms of the maturation of the antibody response to SRBC and of the question of the postulated IgM and IgG switch.     

Reduced secretory antibody response to live attenuated measles and poliovirus vaccines in malnourished children.

Serum and nasopharyngeal IgA antibody levels were estimated in 20 malnourished children and 20 matched healthy controls after immunization with a single dose of live attenuated measles or poliovirus vaccine. Seroconversion and serum neutralizing antibody titres were comparable in the two groups. Secretory IgA antibody was detected significantly less often in undernourished children; the time of its first appearance was delayed-and its maximum level was significantly lower. Impaired secretory antibody response in malnourished children may contribute to slow inadequate recovery from viral and enterobacterial infections and predispose to lifethreatening complications.     

Receptors for antigen on lymphoid cells. II. The nature of the molecule responsible for plaque-forming cell adherence.

The nature of specific adherence of rat anti-TNP PFC to TNP-GRBC has been investigated with PLL-fixed antigen monolayers as cellular immunoadsorbents and as plaque indicators. The immunoglobulin nature of the molecule responsible for PFC adherence is suggested by the fact that pretreatment of the PFC with rabbit anti-rat Ig antisera, but not anti-histocompatibility antisera, inhibits adherence. Removal of the adherence capacity of early PFC with the proteolytic enzymes papain and pronase, or by "capping" with anti-Ig is followed by slow regeneration of the ability to adhere, suggesting that adherence is due to membrane rather than secreted immunoglobulin, the latter being detectable within minutes after enzyme treatment. Several time-related events relating to PFC adherence were observed. 1) Both direct and indirect PFC are capable of specific adherence; the ability to adhere, however, tends to decline with time, especially after secondary immunization. 2) Although early PFC adherence is unaffected by trypsin treatment, later populations become increasingly sensitive. 3) Pretreatment of PFC at various times after primary immunization with antisera specific for rat mu-chain indicates that IgM and possibly early IgG-secreting PFC have mu heavy chains on their surface. These data suggest that the PFC membrane is progressively changing during the maturation of the antibody response.     

Immunological aspects of retinoids in humans. II. Retinoic acid enhances induction of hemolytic plaque-forming cells

The effects of retinoic acid (RA) on the induction of antibody-producing cells from human tonsillar lymphocytes sensitized to sheep erythrocytes (SRBC) have been evaluated. Our results indicated that 10(-5) to 10(-7) M RA caused up to a three-fold increase in the number of plaque-forming cells (PFC) and a qualitative increase in the size of the plaques during the induction of PFC in 5- to 7-day cultures. Enhancement also occurred when tonsil cells were preincubated with RA for 24 hr and then washed, or when RA was added any time in the first 4 days after initiation of the culture. When T- and B-cell fractions were pretreated with RA for 24 hr, washed, and recombined with SRBC, RA-induced augmentation of PFC occurred only in conjunction with RA treatment of the B-cell fraction. Pretreatment of the T-cell fraction had no effect on PFC induction or on the RA-enhanced response when the B-cell fraction was simultaneously treated with RA. Other experiments suggested that RA did not modulate PFC induction by influencing regulatory functions of adherent accessory cells. Our study demonstrates that RA can enhance human antibody responses and shows that this effect is not caused by increased activity of T cells or adherent accessory cells, but is instead the result of a direct effect of RA on B-cell populations.     

Effect of concanavalin A on lymphocyte interactions involved in the antibody response to type III pneumococcal polysaccharide. II. Ability of suppressor T cells to act on both B cells and amplified T cells to limit the magnitude of the antibody response.

When administered 2 days after immunization with 0.5 microgram Type III pneumococcal polysaccharide (SSS-III), the T lymphocyte mitogen concanavalin A (Con A) stimulates a 2.6-to 7-fold enhancement of the plaque-forming cells (PFC) response to SSS-III in vivo. This enhancement requires the presence of amplified T cells, which act by driving PFC or their precursors to extra rounds of proliferation. The extra proliferation that can be stimulated by Con A is not seen in the normal primary response to SSS-III; but treatment with anti-lymphocyte serum (ALS) to remove suppressor T cells will permit the additional proliferation to occur. This indicates that in the primary response to SSS-III, suppressor T cells act on amplifier T cells to limit the magnitude of the antibody response. Only suppression of B cells can account for the further suppression induced by Con A given at the time of immunization or by low-dose paralysis of the SSS-III response. The relatively late development of amplified activity compared to suppressor activity appears to account for the absence of amplifier activity after primary immunization with SSS-III. It is apparent that one can explain the regulatory effects observed during the development of an immune response to SSS-III only by considering both T cell- B cell and T cell- T cell interactions, together with the temporal relationships involved in those interactions.     

Rapid changes in the regulatory potential of autologous anti-idiotopic T cells during an antigen-driven primary response

The antibody response of C57BL/6 strain mice to Streptococcus pneumoniae R36a (Pn) is dominated by the T15 idiotype, but the responding cells appear to be idiotypically heterogeneous, in that individual antibody plaque-forming cells (PFC) may express some but not all idiotopes (Id) of the T15 complex. The presence of these distinct Id on the PFC was detected by a plaque-inhibition assay with three different monoclonal anti-Id antibodies, designated AB1-2, MaId5-4, and B36-82. A periodic change in the expression of AB1-2 and MaId5-4 Id was observed during primary (IgM) antibody response to Pn in the spleen. Those two Id were poorly expressed in the log phase of the response between day 2 and day 4 after immunization (few PFC in the spleen bore the Id), but they became detectable on the majority of PFC at the peak of the response, day 5 to day 7. The proportion of the Id-(AB1-2 or MaId5-4) positive PFC declined, again at day 10 after immunization. In contrast, the B36-82 Id was expressed on greater than or equal to 80% PFC throughout the entire primary response. The possibility that the apparent changes in the Pn-reactive cell populations are regulated by autologous anti-Id T cells was tested in vitro. Normal, unimmunized B cells were cultured with Pn, either alone or in the presence of syngeneic T cells isolated from the spleen of mice at the appropriate intervals after immunization: day 2 (T2), day 5 (T5), and days 10 to 14 (T10 to T14); T cells from unimmunized donors (T0) served as a control. The specific response after 4 days in culture was determined in regard to the total PFC as well as the proportion of PFC expressing the Id. Pn-stimulated B cells, alone or with the control T0 cells, produced moderate, variable levels of AB1-2+ and MaId5-4+ PFC. The expression of these two Id in the assay cultures was suppressed by addition of either T2 cells or T10-14 cells, but it was enhanced if T5 cells were added. However, these various T cell populations did not differ in their effect on the total PFC response. Also, the proportion of PFC bearing the third Id, B36-82 was high, and it was not consistently influenced by the added T cells.(ABSTRACT TRUNCATED AT 400 WORDS)     

In Vivo Production of Various Cytokines in Splenocytes of Sheep Erythrocyte-Immunized Mice after Intravenous Administration of Bacterial Lipid A

The effects of an intravenous administration of lipid A from Salmonella minnesota R595 lipopolysaccharide on the in vivo production of interleukin-2 (IL-2), IL-4, IL-5 and IL-6 in the spleens of mice intravenously immunized with sheep red blood cell (SRBC) antigen were investigated. The increased number of antigen-specific IgM antibody-producing cells and the titer of the IgM serum antibody were measured using the plaque-forming cell (PFC) assay and an enzyme-linked immunosorbent assay (ELISA). Simultaneous injections of SRBC antigen and lipid A adjuvant enhanced IgM-PFC number on days 3 and 4 and the serum IgM titer on days 4 and 5 after the immunization. We found that the enhanced IL-4 and IL-5 levels correlated with the PFC number and IgM titer. When lipid A was injected intravenously 2 days after immunization with SRBC, the PFC number in lipid A-treated groups were similar to those in controls 3 and 4 days after the immunization. However, it was found that a twofold increase in the IgM titer in serum was induced by lipid A 5 days after immunization. In relation to this increase, lipid A stimulated the production of only IL-5 among the cytokines tested.     

Inhibition of the in vitro 19S and 7S antibody response by immunoglobulin-binding factor (IBF) from alloantigen-activated T cells

A soluble factor secreted by alloantigen-activated mouse T cells which binds to the Fc fragment of IgG and inhibits complement activation by IgG (immunoglobulin-binding factor, IBF) suppressed the in vitro 19S and 7S antibody response by mouse spleen cells to T-dependent as well as T-independent antigens. IBF inhibited the 19S plaque response best when it was added late during PFC generation (between 48 and 72 hr). On the other hand, when it was left in cultures for up to 60 hr and then removed, antibody synthesis was not inhibited. However, its presence for only 2 hr starting after 72 hr of incubation was sufficient to inhibit PFC formation. The suppressive activity of IFB could be neutralized by adding aggregated mouse IgG prior to the critical stage around 72 hr. These data favour the view that IBF could be a suppressive T cell factor and point to the possibility that IBF may act on already triggered B cells during their final differentiation to active PFC.     

Maintenance of plasma-derived proteins at much lower concentrations in the uterine lumen of the rabbit: a kinetic study of passage.

Human serum albumin (HSA) and human gamma globulin (HGG) in serum and uterine fluid of nonpregnant rabbits at various times after an i.v. injection (100 mg/kg) were measured by a radial immunodiffusion test using specific antisera. The HSA concentration in uterine fluid rose to a peak at 12 hr when it was 11% of the serum concentration and then declined, whereas HGG reached a peak at 18 hr (3.2% of serum level) and decreased thereafter. The HSA passed 2 1/2 times faster than HGG, but both proteins equilibrated with uterine fluid in about 12-18 hr. Steady state levels of HSA and HGG indicated that uterine fluid: serum ratios were 1:10 and 1:20, respectively. Similar ratios were found for total protein and rabbit serum albumin (1:10) and rabbit gamma globulin (1:20). Therefore, except when there is a local immune response, the uterine lumen contains only about 5% of the serum antibody concentration. Available data in the mouse, rat and dog also indicate disparity between serum and uterine fluid protein levels.     

The relationship between immunization and circulating antigen-specific plaque-forming cells

The relationship between the appearance of cells producing antibody to tetanus toxoid (TT) in the circulation and the serum titers of anti-TT IgG following booster immunization has been studied. It was found that cells producing anti-TT antibody can be detected in the circulation in a hemolytic plaque assay using sheep red blood cells (SRBC) coated with TT by the chromic chloride method. In symmetric inhibition studies using cells from TT or keyhole limpet hemocyanin (KLH)-immune donors, the homologous antigen inhibited 100% of the PFC with no cross-inhibition. Thus, the plaque-forming cells (PFC) detected in this assay are specific for the immunizing antigen. No evidence of polyclonal B-cell activation in response to TT was found, as shown by a failure to detect any PFC against unmodified or KLH or human serum albumin-treated SRBC. In addition, the increase in total Ig-secreting cells observed in a staphylococcal protein A reverse hemolytic plaque assay was always accounted for by the number of anti-TT antibody-producing cells observed. The peak number of anti-TT antibody-producing cells varied between donors, but the kinetics of their appearance was highly reproducible--none before Day 5, peak numbers between Days 6 and 8, and a sharp decline with only rare anti-TT Ig-secreting cells in the circulation by Day 15 postimmunization. Anti-TT antibody-producing cells appeared in the circulation prior to any detectable increase in serum anti-TT antibody titers, and following the disappearance of PFC from the circulation, there was no further increase in serum IgG anti-TT levels. These observations demonstrate a marked specificity of B-cell activation on boosting with a recall antigen, and a parallelism between the appearance of activated B cells in the circulation and of IgG anti-TT synthesis by the subject as a whole.     

犬卵透明带3 DNA疫苗在小鼠模型中的避孕效果评价

为了评价犬卵透明带3(CZP3)DNA疫苗的避孕效果,采用6只雌性小鼠Mus musculus肌肉注射50μg pcDNA3-CZP3质粒后30 V电压刺激6次的方法建立实验组,以6只同等注射pcDNA3质粒的雌性小鼠为阴性对照组;初免后每周采血并用ELISA方法检测小鼠的CZP3抗体水平及第6周抗体滴度;第6周与雄鼠合笼,计算产仔数;第24周收集卵巢制成HE染色切片进行观察;最后用小鼠血清进行小鼠及犬卵透明带的间接免疫荧光实验。结果显示,1)实验组小鼠从初免第2周就产生了抗CZP3的抗体,并且与阴性对照组之间的差异有统计学意义(P<0.05);第24周实验组的抗体水平与阴性对照组之间的差异有高度统计学意义(P<0.01)。2)第6周血清中的抗体1∶4 000倍稀释时,实验组与阴性对照组之间的差异有高度统计学意义(P<0.01)。3)小鼠生育率由阴性对照组的100%降低至实验组的50%,平均产仔数由阴性对照组的(6.667±0.422)只降至实验组的(2.500±1.455)只,且实验组的抗体水平与产仔数呈高度负相关。4)卵巢HE染色切片结果显示,CZP3 DNA疫苗...     

Plaque-forming cell response in BALB/c mice to two preparations of LPS extracted from Salmonella enteritidis.

The pattern of development of antibody-forming cells in BALB/c mice after immunization with PW-LPS or TCA-LPS was shown to be different. On days 10 and 20, the primary response to PW-LPS was characterized by a low level of IgM synthesis. The plaque-forming cell (PFC) response to TCA-LPS, however, increased from day 10 to day 20. Initially, IgM was the only detectable antibody synthesized but by day 20 a significant number of IgG-producing spleen cells had developed. After a secondary immunization with the appropriate lipopolysaccharide (LPS) preparation, IgG-producing spleen cells were detected in mice immunized with either PW-or TCA-LPS. Partial removal of the LAP or TCA-LPS with phenol or trypsin and pronase significantly reduced the PFC response, suggesting that the protein moiety played an influential role in the immunogenicity of TCA-LPS. The TCA-LPS contained the same antigenic dterminants as PW-LPS, so any difference observed between PFC response was not due to any associated immunogenic moiety.