Regulation of OspE-related, OspF-related, and Elp lipoproteins of Borrelia burgdorferi strain 297 by mammalian host-specific signals.

In previous studies we have characterized the cp32/18 loci in Borrelia burgdorferi 297 which encode OspE and OspF orthologs and a third group of lipoproteins which possess OspE/F-like leader peptides (Elps). To further these studies, we have comprehensively analyzed their patterns of expression throughout the borrelial enzootic cycle. Serial dilution reverse transcription-PCR analysis indicated that although a shift in temperature from 23 to 37 degrees C induced transcription for all nine genes analyzed, this effect was often markedly enhanced in mammalian host-adapted organisms cultivated within dialysis membrane chambers (DMCs) implanted within the peritoneal cavities of rats. Indirect immunofluorescence assays performed on temperature-shifted, in vitro-cultivated spirochetes and organisms in the midguts of unfed and fed ticks revealed distinct expression profiles for many of the OspE-related, OspF-related, and Elp proteins. Other than BbK2.10 and ElpA1, all were expressed by temperature-shifted organisms, while only OspE, ElpB1, OspF, and BbK2.11 were expressed in the midguts of fed ticks. Additionally, although mRNA was detected for all nine lipoprotein-encoding genes, two of these proteins (BbK2.10 and ElpA1) were not expressed by spirochetes cultivated in vitro, within DMCs, or by spirochetes within tick midguts. However, the observation that B. burgdorferi-infected mice generated specific antibodies against BbK2.10 and ElpA1 indicated that these antigens are expressed only in the mammalian host and that a form of posttranscriptional regulation is involved. Analysis of the upstream regions of these genes revealed several differences between their promoter regions, the majority of which were found in the -10 and -35 hexamers and the spacer regions between them. Also, rather than undergoing simultaneous upregulation during tick feeding, these genes and the corresponding lipoproteins appear to be subject to progressive recruitment or enhancement of expression as B. burgdorferi is transmitted from its tick vector to the mammalian host. These findings underscore the potential relevance of these molecules to the pathogenic events of early Lyme disease.

Fetal immunization of baboons induces a fetal-specific antibody response.

Neonates face a high risk of infection because of the immaturity of their immune systems. Although the transplacental transfer of maternal antibodies to the fetus may convey improved postnatal immunity, this transfer occurs late in gestation and may fail to prevent in utero infection. Both fetal immunization and in utero exposure to antigen can result in a state of immunologic tolerance in the neonate. Tolerance induction of fetal and premature infant lymphocytes has become a paradigm for neonatal responsiveness. However, fetal IgM responses have been demonstrated to maternal immunization with tetanus toxoid and to congenital infections such as rubella, toxoplasma, cytomegalovirus and human immunodeficiency virus. Moreover, 1-week-old infants can respond to standard pediatric vaccination, and neonates immunized with polysaccharide antigens do not develop immunologic tolerance. Here, direct immunization of the baboon fetus with recombinant hepatitis B surface antigen produced a specific fetal IgG antibody response. No specific maternal antibody response was detected, eliminating the possibility of vertical antibody transmission to the fetus. Some infants also responded to later vaccinations with hepatitis B surface antigen, indicating that no immunological tolerance was induced by prior fetal immunization. These results characterize the ability of the fetal immune system to respond to in utero vaccination. We demonstrate that active fetal immunization can serve as a safe and efficient vaccination strategy for the fetus and neonate.

Immunoglobulin variable regions as idiotype vaccines.

This article focuses on the use of immunoglobulin variable regions, including Id, anti-Id, anticlonotypes, and Id engineering as putative vaccines and vaccine strategies for infectious diseases; and specific discussion of Id systems involving antigenic determinants associated with potentially pathogenic organisms.