Memory and distribution of virus-specific cytotoxic T lymphocytes (CTLs) and CTL precursors after rotavirus infection.

The gastrointestinal tract is constantly exposed to a variety of potentially invasive bacteria, viruses, and parasites. The first line of defense against these pathogens is the intestinal mucosal surface, which consists of epithelial cells, intraepithelial lymphocytes (IELs), mucus, and secretory immunoglobulins. In addition, the intestine is a rich source of lymphocytes located within Peyer's patches and the lamina propria. Little is known about the function, memory, trafficking, or origin of intestinal T lymphocytes after intestinal infection. We studied the murine cytotoxic T-lymphocyte (CTL) response to the intestinal pathogen rotavirus (simian strain RRV). Adult mice were inoculated orally or via the hind footpad with RRV; virus-specific cytotoxic activities in intestinal and nonintestinal lymphocyte populations were determined by 51Cr release assays. In addition, virus-specific CTL precursor (CTLp) frequencies were determined by limiting-dilution analysis. IELs containing rotavirus-specific cytotoxic activity were detected after oral but not footpad inoculation and expressed alpha/beta but not gamma/delta cell surface protein; virus-specific CTLs did not appear to arise from CTLp among IELs. In addition, the site at which RRV was presented to the immune system determined the site at which RRV-specific CTLp first appeared. Frequencies of rotavirus-specific CTLp detected in Peyer's patches were 25- to 30-fold greater after oral than after footpad inoculation. However, regardless of the route of inoculation, rotavirus-specific CTLp were distributed throughout the lymphoid system 21 days after infection. Implications of these findings for vaccine design are discussed.

Rotavirus-specific cytotoxic T lymphocytes passively protect against gastroenteritis in suckling mice.

Suckling mice are protected against murine rotavirus-induced gastroenteritis after adoptive transfer of splenic lymphocytes from immunized animals. Adoptive transfer of Thy1(+)-depleted or CD8(+)-depleted lymphocytes abrogated protection against challenge. (We previously found that depletion of Thy1+ or CD8+ lymphocytes from rotavirus-immunized mice decreased rotavirus-specific cytotoxic activity in vitro.) Protection against disease occurred in the absence of rotavirus-specific neutralizing antibodies in the sera of suckling mice. Rotavirus-specific cytotoxic T lymphocytes may be important in either amelioration of acute infection or protection against reinfection.

Rotavirus-specific protein synthesis is not necessary for recognition of infected cells by virus-specific cytotoxic T lymphocytes.

We found that rotavirus-specific protein synthesis was not necessary for recognition by virus-specific cytotoxic T lymphocytes (CTLs). In addition, CTLs lysed rotavirus-infected target cells prior to production of infectious virus. Target cell processing of rotavirus antigens for presentation to CTLs was enhanced by treatment of rotavirus with trypsin prior to infection; trypsin-induced cleavage of the viral hemagglutinin (vp4) has previously been found to facilitate rotavirus entry into target cells by direct penetration of virions through the plasma membrane. We conclude that sufficient quantities of exogenous viral proteins may be introduced into the cytoplasm for processing by target cells. The mechanism by which rotavirus proteins are processed for presentation to the target cell surface remains to be determined.

Rotavirus-specific cytotoxic T lymphocytes appear at the intestinal mucosal surface after rotavirus infection.

The gastrointestinal tract is constantly exposed to a variety of potentially invasive bacteria and viruses. The first line of defense of the host against these pathogens is the intestinal mucosal surface, which consists of epithelial cells, intraepithelial lymphocytes (IELs), mucus, and secretory immunoglobulins. Little is known about the function, memory, or trafficking of IELs after intestinal infection. We found that IELs obtained 6 days after oral inoculation of mice with the intestinal pathogen rotavirus (simian strain RRV) lysed rotavirus-infected target cells; cytotoxic T lymphocytes (CTLs) were responsible for rotavirus-specific cytotoxic activity. Rotavirus-specific cytotoxic activity by IELs was (i) eliminated by treatment with Thy 1.2-specific immunoglobulin M plus complement, (ii) restricted by proteins encoded at the major histocompatibility complex, and (iii) absent in mock-infected animals. Oral inoculation of mice with RRV also induced rotavirus-specific CTLs in splenic and intestinal lymphocytes (mesenteric lymph nodes, Peyer's patch). Parenteral inoculation induced rotavirus-specific CTLs in splenic, intestinal (IELs, mesenteric lymph nodes, Peyer's patch), and nonintestinal lymphocytes (inguinal nodes). Therefore, presentation of rotavirus to the intestinal mucosal surface was not necessary to induce IELs with virus-specific cytotoxic activity. At 4 weeks after oral or parenteral inoculation of mice with RRV, rotavirus-specific CTL precursors appeared among splenic, Peyer's patch, inguinal, and mesenteric node lymphocytes, but not among IELs. IELs with rotavirus-specific cytotoxic activity may be generated from precursors at a site other than the intestinal mucosal surface. Part of the response of the host to enteric infection may include surveillance and lysis of virus-infected villus epithelial cells by IELs.

Noninfectious rotavirus (strain RRV) induces an immune response in mice which protects against rotavirus challenge.

We found that female adult mice parenterally inoculated with noninfectious rotavirus (simian strain RRV) developed virus-specific neutralizing antibodies in the serum; newborn mice from these dams were protected against RRV-induced gastroenteritis. In addition, mice parenterally inoculated with noninfectious RRV developed virus-specific cytotoxic T-lymphocyte precursors in the spleen. Replication of rotavirus in intestinal epithelial cells was apparently not required to induce rotavirus-neutralizing antibodies or rotavirus-specific cytotoxic T lymphocytes. Parenteral immunization of infants and young children with noninfectious rotaviruses may induce an immune response which protects against rotavirus challenge.

The kinetics of generation of influenza-specific cytotoxic T-lymphocyte precursor cells.

A dramatic increase in the number of restimulatable (memory) cytolytic T-cell precursors (CTLps) has been demonstrated to occur 2 to 4 days postimmunization. By 4 or at the latest 6 days following in vivo priming, the frequency of restimulatable influenza-specific CTLps has reached that characteristic of a memory response. This indicates that the proliferative events which give rise to memory CTLps occur earlier than might have been expected and in fact are completed prior to the cessation of othe primary CTL response. Such information may have important significance to future immunomodulatory efforts aimed at perturbing the establishment of T-cell memory in vivo.

Rotavirus-specific cytotoxic T lymphocytes cross-react with target cells infected with different rotavirus serotypes.

Splenocytes from adult C57BL6 (H-2b) mice orally inoculated with nonmurine rotaviruses lysed syngeneic rotavirus-infected target cells. Cytotoxic T lymphocytes (CTLs) were responsible for this cytotoxic activity. Cytotoxic activity was (i) detected 7 days after primary oral inoculation; (ii) not detected in uninoculated animals; (iii) specific for rotavirus-infected target cells; (iv) eliminated by treatment with Thy 1.2-specific immunoglobulin M and complement; and (v) restricted at H-2Db. In addition, rotavirus-specific CTLs cross-reacted with target cells infected with different human or animal rotavirus serotypes. Heterotypic protection against rotavirus challenge may be mediated by cross-reactive CTLs.

Secretion of a chimeric T-cell receptor-immunoglobulin protein.

To produce sufficient quantities of soluble T-cell receptor protein for detailed biochemical and biophysical analyses we have explored the use of immunoglobulin--T-cell receptor gene fusions. In this report we describe a chimeric gene construct containing a T-cell receptor alpha-chain variable (V) domain and the constant (C) region coding sequences of an immunoglobulin gamma 2a molecule. Cells transfected with the chimeric gene synthesize a stable protein product that expresses immunoglobulin and T-cell receptor antigenic determinants as well as protein A binding sites. We show that the determinant recognized by the anticlonotypic antibody A2B4.2 resides on the V alpha domain of the T-cell receptor. The chimeric protein associates with a normal lambda light chain to form an apparently normal tetrameric (H2L2, where H = heavy and L = light) immunoglobulin molecule that is secreted. Also of potential significance is the fact that a T-cell receptor V beta gene in the same construct is neither assembled nor secreted with the lambda light chain, and when expressed with a C kappa region it does not assemble with the chimeric V alpha C gamma 2a protein mentioned above. This indicates that not all T-cell receptor V regions are similar enough to immunoglobulin V regions for them to be completely interchangeable.