The modified vaccination technique designed to prevent and cure acute and chronic disorders.

In spite of enormous efforts there have been no solutions to date for preventing/terminating certain acute and chronic disorders of humans by vaccination or drugs. Yet it is well understood that if the target antigen (ag) could be presented appropriately to the cells of the immune system then solutions could be found. Recently, the Barabas research group has introduced and described the third vaccination method - called modified vaccination technique (MVT) - which has the ability to provide a corrective immune response in experimental animals with an autoimmune kidney disease. Injections of immune complexes - made up of the target ag and specific non-pathogenic IgM antibodies directed against the target ag - achieved downregulation of pathogenic immune responses and tolerance to self was regained. Utilizing the immune system's natural abilities to respond to corrective information, the MVT technique was able to prevent an autoimmune kidney disease from occurring (prophylactic effect) in experimental animals, and when present, terminating it (therapeutic effect) specifically and without measurable side effects.It is predicted that the application of the MVT will have the potential in the future to revolutionize the preventative and therapeutic options for dealing with chronic disorders in humans (such as autoimmune disease, cancer and acute chronic infections) and achieve cures.

The Modified Vaccination Technique.

In addition to active and passive immunizations, there is a third method of immunization, the modified vaccination technique, which is based on injecting a combination of target antigens and antibodies against this antigen. The vaccine is essentially comprised of immune complexes with pre-determined immune-inducing components. When such an immune complex (target antigen × antibody against the target antigen) with a slight antigen excess is administered, it evokes a corrective immune response by the production of the same antibody with the same specificity against the target antigen that is present in the immune complex (pre-determined immune response).

Antibody-initiated beneficial and harmful immune responses.

A critical function of the immune system is to maintain tolerance to self by corrective immune responses throughout life, including preventing or correcting changes that may interfere with organ function and architectural integrity. These changes have two broad categories, namely (1) exogenous antigen-induced mishaps (e.g., due to bacterial, viral or fungal infections) and (2) endogenous antigen-caused ailments initiated by modified self-antigens derived from damaged organs following exposure to smoke, certain drugs, chemicals, infectious agents, radiation, etc., resulting in autoimmune diseases or cancer. In some cases, cells of the immune system are unable to respond with a corrective antibody response. For example, presentation of a modified self-antigen can initiate a pathogenic IgG immune response, thereby causing an autoimmune disease. Furthermore, if cancer-associated antigens are not appropriately presented to the cells of the immune system, there is failure to mount a specific pathogenic lytic IgG autoantibody response for recognition and elimination of cancer-associated antigens, and as a consequence, the cancer continues to proliferate.The third vaccination technique that we have developed and designated a modified vaccination technique (MVT) is able to correct these immunological mishaps. The premise of the MVT is that it can prevent both exogenous (infectious and contagious diseases) and endogenous (autoimmune diseases and cancer) antigen-caused diseases, as well as terminate established diseases. Therefore, by exploiting the immune system's natural abilities to make corrective responses, it has both prophylactic and therapeutic actions, with minimal side effects.

Tolerance, loss of tolerance and regaining tolerance to self by immune-mediated events.

Autoimmunity has both beneficial and harmful aspects. Beneficial aspects include: (1) removal of released intracytoplasmic antigens (ags) (cells at the end of their life span or damaged by outside agents) by specific nonpathogenic IgM autoantibodies and mononuclear cells and (2) recognition and elimination of cancerous cells. In contrast, harmful aspects include: (1) mounting a pathogenic autoimmune response against a tissue-derived ag, a 'modified self,' resulting in autoimmune disease and (2) inability to recognize and eliminate a cancerous clone. The immune system continuously faces internal and external influences; however, even when it is compromised or overwhelmed, it will still endeavor to regain and maintain tolerance to self. To promote this, we developed a 'modified vaccination technique' (MVT) (described as the third vaccination method after active and passive immunizations). It has two components: purified exogenous/endogenous ag (i.e., target ag) and a high-titer-specific antibody (ab) against the target ag made into an immune complex (IC) with predetermined immune-inducing components. The MVT works by ab information transfer (production of same class of immunoglobulin with the same specificity against the target ag that is present in the vaccine), thereby re-establishing tolerance to self (caused by exogenous/endogenous ags) following repeated administration of appropriate ICs. This vaccination technique can be used both prophylactically and therapeutically, and it mimics the immune system's natural abilities to respond to corrective information specifically, rapidly, safely and with minimal side effects and makes this approach a novel solution for many disorders that are difficult or impossible to cure or manage.

A novel modified vaccination technique produces IgG antibodies that cause complement-mediated lysis of multiple myeloma cells carrying CD38 antigen.

Objectives were to: 1) induce a lytic IgG antibody (ab) response (via the so called `third vaccination method') against CD38 antigen (ag) residing on the extra-cellular domain of multiple myeloma (MM) cells in recipient rabbits, by combining the CD38 ag with donor-derived anti-CD38 ag lytic IgG ab into an immune complex (IC); and 2) determine whether abs produced would cause complement-mediated lysis (in vitro) of human MM cells containing CD38 ag. The vaccine was created in a two-step process. First, ab (rabbit anti-CD38 ag IgG ab) was raised in donor rabbits by injections of low molecular weight soluble CD38 ag in Freund's complete adjuvant (FCA) and aqueous solution. Second, transfer of pathogenic lytic IgG ab response into recipient rabbits was achieved by injections of ICs composed of CD38 ag and homologous anti-CD38 ag IgG ab. Consequently, recipient rabbits produced the same ab with the same specificity against the target ag as was present in the inoculum, namely agglutinating, precipitating and lytic (as demonstrated in vitro). In an in vitro study, in the presence of complement, donor and recipient rabbits' immune sera caused lysis of CD38 ag associated human MM cells. The most effective lytic ab response causing sera were those from donor rabbits injected with CD38 ag in FCA and those from rabbits injected with ICs, especially when they were administered in adjuvants. These results provided proof of concept that the third vaccination method has good potential as a stand-alone and efficacious method of controlling cancer.

Suppression of tumor growth by a heterologous antibody directed against multiple myeloma dominant CD38 antigen in SCID mice injected with multiple myeloma cells.

Employing passive immunization - using a heterologous anti-CD38 IgG antibody containing serum - in SCID mice injected subcutaneously with human multiple myeloma cells, we have shown that treatments with the antiserum - especially in the presence of complement - significantly decreased cancer growth. However, administered antibody and complement was not sufficient in amount to prevent cancer cell multiplication and cancer growth expansion to a satisfactory degree. Larger volumes of the same components more than likely would have further reduced cancer growth and prolonged the life of mice. In control mice, cancer growth progressed faster proving that lytic immune response against multiple myeloma cells is necessary for cancer cell kill.

Regaining tolerance to a self-antigen by the modified vaccination technique.

Autoimmune diseases are initiated and maintained by complex immunopathological processes in environmental and genetic factor predisposed patients. In certain autoimmune diseases, the etiologies and pathogenesis of the conditions are quite well understood; yet in others, controversy surrounds as to why and how auto-injurious processes start. Clinical and laboratory examinations reasonably well define the state of progression/remission of an autoimmune disease and allow treatment according to observed findings. However, none of the presently employed treatment options are specific. In fact, they are all nonspecific in their actions and have undesirable side effects. Over the years, experiments carried out in animals have shed light on the complex immunopathological processes which contribute to disease development and progression. At least one experimental autoimmune kidney disease-which we shall describe-helps to understand how pathogenic autoimmune responses can be terminated specifically, without side effects. Since the new vaccination method-that we call modified vaccination technique-was successfully implemented in an experimental autoimmune disease model called slowly progressive Heymann nephritis for the termination of pathogenic immune responses by a target antigen-specific treatment modality, we shall highlight its use in providing insight to physicians and autoimmunologists for its future implementation in human autoimmune diseases.

Immunopathological events initiated and maintained by pathogenic IgG autoantibodies in an experimental autoimmune kidney disease.

The experimental models of Heymann nephritis (HN) and slowly progressive Heymann nephritis (SPHN) give us rare opportunities to investigate the etiologies and pathogenesis of two immunopathological processes in rats leading to: (1) autoimmune disease, where the autoimmune disease HN and SPHN is initiated and maintained by cross-reactive pathogenic IgG autoantibodies (aabs) directed against the renal proximal convoluted tubules' brush border (BB) cells - where the nephritogenic antigen (ag) is produced and localized - damaging and releasing BB associated nephritogenic ag into the circulation which in turn contributes to continuation of the autoimmune disease; and (2) immune complex glomerulonephritis, where the glomerular injury is initiated, proceeding into a chronic progressive disease by depositing immune complexes (ICs) - made up of a glomerular epithelial cell produced endogenous nephritogenic ag and the developing pathogenic IgG aab directed against the nephritogenic ag, and complement components - on the epithelial side of the glomerular basement membrane. We also observed how the normally functioning immune system is able to avert autoimmune disease developments by circulating specific non-pathogenic IgM aabs clearing the system of intracytoplasmic ags released from cells at the end of their life spans or following damage by toxic agents. We also described how an autoimmune disease SPHN can be prevented and when present terminated by the implementation of a new vaccination technique we have developed and call modified vaccination technique. By increasing the specific IgM aab production against the native nephritogenic ag - by injecting ICs made up of: [nephritogenic ag X homologous anti-nephritogenic ag IgM ab] in slight ag excess into SPHN rats - pathogenic IgG aab producing native and modified nephritogenic ags were removed from the circulation and termination of the autoimmune disease causing immune events was achieved. Even though HN and SPHN are not well-known disease models, their studies are important because the etiologies and pathogenesis of two conditions - that can also occur in humans, namely autoimmune diseases and membranous glomerulonephritis - can be simultaneously investigated.

Production of heterologous IgG antibody against Heymann nephritis antigen by injections of immune complexes.

Heterologous IgG antibody (ab) can be produced against Heymann nephritis (HN) antigen (ag) in rabbits by administering it in Freund's complete adjuvant. The developing abs reacted at high titre with rat kidney brush border (BB) regions of the renal proximal tubules in an indirect fluorescence ab test. A single IV injection of the heterologous ab into a susceptible strain of rat resulted in the localization of IgG ab to glomerular fixed ags, producing immune complex glomerular nephritis. The injected ab also reacted with the BB region of the renal proximal tubules. The aim of this experiment was to find out whether heterologous IgG ab against the HN ag can also be produced in recipient rabbits by injecting immune complexes (ICs) composed of a rat kidney tubular preparation [rat kidney fraction 3 (rKF3)] and donor rabbit-derived rabbit anti-rKF3 IgG ab. We found that anti-rKF3 IgG ab--against the BB region of the renal proximal tubules--could be induced in rabbits injected with ICs, and the resulting ab was able to initiate passive HN in rats. This was the first time a pathogenic IgG ab was produced against HN ag in rabbits without the use of adjuvant. Ab responses in recipient rabbits were achieved by ab information transfer. Recipient rabbits injected with the IC produced the same class of immunoglobulin with the same specificity against the target ag rKF3, as was present in the innoculum, namely rabbit anti-rKF3 IgG ab.

The role of autoimmunologists in investigating and treating autoimmune disorders.

The role of an autoimmunologist is to investigate and cultivate knowledge of normal and abnormal immune responses against self, which includes developing practical know-how to manipulate autoimmune activity and direct positive autoimmune outcomes. Where a subject develops an abnormal immune response directed against normal self, resulting in an autoimmune disease, the specialist should be able to diagnose the problem and institute an appropriate treatment. Obversely, where a subject lacks an immune response against cells bearing antigens that are abnormal or not quite self, i.e., cancer cells, the specialist should ideally be able to institute a specific cancer cell killing regimen. Essentially there are two beneficial and two harmful aspects of autoimmunity autoimmunologists should be familiar with. The beneficial aspects are the immune responses that assist in the clearance of cellular breakdown products and the elimination of cancer cells. The harmful aspects consist of immune responses, or lack thereof, that manifest in autoimmune disorders, i.e., autoimmune diseases and cancer. Recent medical discoveries, especially the modified vaccination technique developed by the Barabas research group, show great promise in both preventing and curing autoimmune disorders by utilizing the immune system's natural abilities to re-establish normal health.

Modified vaccination technique for prophylactic and therapeutic applications to combat endogenous antigen-induced disorders.

Public health can be protected most effectively through vaccination programmes. However, while presently available vaccination techniques protects the individual by provoking immune responses against exogenous antigens (ags), such as those associated with certain bacteria and viruses, they cannot protect against or treat mishaps caused by endogenous ag. Recently, Barabas and colleagues have developed a new vaccination method, called modified vaccination technique (MVT), which allows the presentation of disease causing agents in such a way as to initiate and maintain desired immune response outcomes even in the context of mishaps associated with endogenous ag. For example, in an experimental autoimmune kidney disease, the MVT downregulated/terminated pathogenic immune responses that were causing morphological and functional changes of the kidney. The MVT promises, with appropriate case-specific modifications, both preventative and curative applications for ailments, such as endogenous ag initiated mishaps (i.e. autoimmune diseases and cancer) and diseases caused by chronic infection, that are presently only treatable with drugs. To achieve specific immune responses, purified components of the vaccine (ag and antibodies) must be produced and assembled into immune complexes having the potential of inducing predetermined corrective immune response outcomes.

Correcting autoimmune anomalies in autoimmune disorders by immunological means, employing the modified vaccination technique.

Our research group has developed a new vaccination technique in experimental animals that has the potential of correcting autoimmune anomalies in humans such as autoimmune disorders, cancer, and chronic infections, both prophylactically and therapeutically. The vaccination method is called Modified Vaccination Technique (MVT). The MVT necessitates the introduction of a purified target antigen (ag) and a specific antibody (ab) against the target ag in the form of immune complex (IC) to evoke the desired immune response outcome by ab information transfer in the injected recipient. The injected IC produces the same class of ab in the host, with the same specificity against the target ag, as resides in the inoculum. The MVT promises to provide a means of upregulating beneficial immune events and downregulating undesirable immune responses in individuals, thereby re-establishing normalcy/tolerance to self.

Preventing and treating chronic disorders using the modified vaccination technique.

It is anticipated that the ultimate solution for the prevention and termination of autoimmune disorders will be based on somehow manipulating the cells of the immune system to attain antigen (ag) specific downregulation and termination. In the last few years we have developed a new vaccination technique that we call "modified vaccination technique" (MVT). It has with equal effectiveness both prevented and terminated autoimmune disease causing events in an experimental autoimmune kidney disease model. We expect that our technique will be similarly applicable to the specific treatment and cure of numerous other chronic disorders presently treated only by drugs. The vaccine is composed of two components, an ag and a specific antibody against it. When these are combined at slight ag excess they constitute a vaccine which is capable of treating chronic ailments by redirecting immune response outcomes in the vaccinated host. Both components, like drugs, will have to be produced ex vivo in order to maintain uniformity, safety, efficacy, and specificity.

New vaccination technology for endogenous antigen-derived ailments.

Neither autoimmune disorders nor cancer can be prevented with treatment modalities that are currently available. These diseases are generally treated with immunosuppressive agents and cytotoxic drugs, both of which can cause numerous side effects. However, scientific evidence now exists to suggest that such endogenous antigen-derived ailments can be controlled and even terminated by immunological approaches. Both autoimmune disorders and cancer can progress into chronic, irreversible conditions because of the abnormal presentation of endogenous antigens to the cells of the immune system. By appropriate regulation of the autoimmune system, both types of ailments could be curable. This feature review describes various autoimmune events that may occur both to the benefit and the detriment of the host, and highlights a new vaccination technique against slowly progressive Heymann nephritis. This modified vaccination technique holds promise in the prevention and cure of autoimmune system-related disorders. The vaccination has been employed both against endogenous antigen-induced diseases (autoimmune disorders and cancer) and against exogenous antigens. In each study performed to date, the technique has been demonstrated to induce specific, predetermined immune response outcomes.

A modified vaccination technique for the prevention and treatment of an experimental autoimmune kidney disease.

The main purpose of this article is to introduce a promising new vaccination technique and to outline its efficacy and safety as demonstrated in an experimental autoimmune kidney disease. We have found that antigen (AG)-specific downregulation and/or upregulation of immune responses can be achieved by injections of immune complexes (ICs) which contain prepackaged information. This result is attained with the new vaccination method, a method developed in our laboratory which we have called "modified vaccination technique" (MVT). This MVT not only enables the prevention of pathogenic autoimmune events leading to the development of an experimental autoimmune kidney disease; it also allows, with equal effectiveness, therapeutic intervention to terminate the disease. With an injected IC containing predetermined immune response-inducing components, the process effectuates a specific antibody information transfer conferring advantages that go beyond its prophylactic and therapeutic applicability. Its specificity can induce a precise immune response to correct mishaps, for example, in conditions where the immune system overreacts to an autologous antigen or fails to recognize unwanted self (as in autoimmune disorders, cancer, etc.) Preformed ICs are nontoxic and nonirritant, evoke a predetermined antibody response without the use of adjuvants, cause no disturbance in the overall regulatory function of the immune system, and produce no side effects. We firmly believe that proper implementation of the MVT will be able to induce and maintain specific preventive and/or curative responses in a way that is both natural and more effective in patients with chronic ailments presently treatable only with drugs.

Elevated antibody response by antigen presentation in immune complexes.

BACKGROUND: Active immunization techniques against exogenous source antigens (ags - such as bacteria, virus) proved to be successful in preventing many acute infectious diseases from occurring in a susceptible population. However, an active immunization technique that could be employed both prophylactically and therapeutically has so far not been described. We have developed a new vaccination technique that employs specific immune complex (IC) containing components which is able to redirect immune-response outcomes in both preventative and curative regimens in an experimental autoimmune kidney disease. The technique with appropriate modifications was assessed using an exogenous ag in our present experiment. MATERIAL/METHODS: We prepared an exogenous ag on a HiTrap affinity column and injected it by five different vaccination techniques into rats. Antibody (ab) responses against the ag were evaluated by ELISA. Statistical analysis assessed possible significant differences in ab responses. RESULTS: The most powerful immune response was initiated following intraperitoneal (IP) injections of normal rabbit immunoglobulin G (nRIgG) in Freund's complete adjuvant (FCA). The second most powerful immune response was evoked when the same ag (nRIgG) was injected in the form of IC at ag excess. CONCLUSIONS: 1. Induction of a powerful ab response, without the use of an adjuvant, can be achieved in rats injected with ICs. 2. IC is non-toxic, non-irritant, and able to initiate the production of the same class of immunoglobulin with the same specificity/function that resides in the inoculum.

Preventative and therapeutic vaccination to combat an experimental autoimmune kidney disease.

We describe a new vaccination method called modified vaccination technique (MVT). The technique is able to achieve downregulation of pathogenic autoimmune events leading to a chronic progressive disorder in rats called slowly progressive Heymann nephritis. Downregulation of immunopathological events is achieved by injections of immune complex (IC) made up of the target native antigen (ag) and specific naturally occurring immunoglobulin M (IgM) antibody (ab) directed against it. Repeated injections of IC maintain high levels of specific circulating IgM autoantibodies (aabs) against the kidney ag. The developing physiologic IgM aabs assist in the catabolism of both modified and unmodified renal ags from the circulation. No disease-causing renal ags in the circulation results in no stimulation of pathogenic immunoglobulin G aab producing cell lines. Such specific targeted therapy leads to termination of disease-causing processes and reestablishment of tolerance. The MVT can be employed both prophylactically and therapeutically with equal effectiveness. A redirected immune response is achieved by specifically stimulating the animals' own IgM-producing cell lines with the injected ICs, resulting in a natural cure. Such ICs are nontoxic and nonirritant and cause no side effects. We surmise that the MVT, employing the appropriate components in each instance, can also be used to treat human ailments.

Effect of rat kidney fraction 3 (rKF3) antigen and specific IgM antibody against rKF3 on the progression of slowly progressive Heymann nephritis.

The aim of the present study was to find out if specific IgM (M) antibody (directed against rat kidney fraction 3 (rKF3)) or rKF3 antigen were able to influence disease progression in an experimental autoimmune kidney disease called slowly progressive Heymann nephritis (SPHN). The level of circulating autoantibodies (aabs) and the morphological and functional changes to the kidney were studied in six groups of rats. All of the treatment components (except post-treatment with M) used in the SPHN pre- and post-treated rats and post-treated-only rats had measurable beneficial effects (even during restimulation with the chemically modified renal antigen, 22 weeks after the induction of the disease) as demonstrated by diminished pathogenic IgG aab production, less severe kidney lesions, and proteinuria reductions. The injected rKF3 minimized progression best in this experiment, especially when administered in a pre- and post-treatment regimen. It is thought that the effect of rKF3 in the reduced progression of SPHN was due to increased production of specific IgM aabs, which in turn limited pathogenic aab production and continuous buildup of immune complexes in the glomeruli by facilitating removal or blockage of nephritogenic autoantigens from the circulation.

Downregulation of a pathogenic autoantibody response by IgM autoantibodies directed against the nephritogenic antigen in slowly progressive Heymann nephritis.

The purpose of the study was to find out if a new modified vaccination technique would be effective in downregulating immunopathological events during the course of an experimental autoimmune kidney disease (which is morphologically and functionally similar to Heymann nephritis) called 'slowly progressive Heymann nephritis' (SPHN). We have shown that the pathogenic IgG autoantibody (aab)-induced experimental autoimmune kidney disease process can be downregulated early on as well as during the chronic progressive phase, when rats were restimulated. The IgM aab, resulting from stimulation by immune complexes made up of rat kidney fraction 3 (rKF3) antigen and rat anti-rKF3 IgM antibody in antigen excess (MIC), can greatly diminish pathogenic aab production by removing or blocking nephritogenic antigens. Reduced IgG aab production limits the formation of damaging immune complexes (IC) in the glomeruli and development of proteinuria. At the end of the experiment 60% and 80% of the MIC-treated groups had no pathogenic IgG aab in their circulation, while all the untreated SPHN rats had high levels of IgG aab associated with disease progression manifesting in increased proteinuria and severe immune complex glomerulonephritis.

Reduced incidence of slowly progressive Heymann nephritis in rats immunized with a modified vaccination technique.

A slowly progressive Heymann nephritis (SPHN) was induced in three groups of rats by weekly injections of a chemically modified renal tubular antigen in an aqueous medium. A control group of rats received the chemically unmodified version of the antigen in an aqueous solution. One group of SPHN rats were pre- and post-treated with weekly injections of IC made up of rKF3 and rarKF3 IgM antibody at antigen excess (MIC) (immune complexes [ICs] containing sonicated ultracentrifuged [u/c] rat kidney fraction 3 [rKF3] antigen and IgM antibodies specific against the antigen, at slight antigen excess). One group of SPHN rats were post-treated with MIC 3 weeks after the induction of the disease and one group of SPHN animals received no treatment. The control group of rats received pre- and post-treatment with sonicated u/c rKF3. The incidence of immune-complex glomerulonephritis (ICGN) in the untreated SPHN rats was 87%, in the pre- and post-treated animals 13%, and in the post-treated-only rats 20%. Rats receiving sonicated ultracentrifuged rKF3 antigen did not develop ICGN. The present experiment demonstrates that the development of SPHN can be not only prevented but also effectively terminated by our newly developed modified vaccination technique.