Primary immunization of lymph node cells in millipore chambers by exposure to homograft antigen

Interactions of murine leukemia virus (MuLV) with isolated lymphocytes. I. Virus replication in lymphocytes infected with Friend virus and cultures in diffusion chambers in vivo

A new technique for infection of mature lymphocytes with murine leukemia virus (Friend) MuLV-F) is described. Spleen cells for normal, non-infected donors were placed into diffusion chambers (constructed with 0.22 mum por size Millipore filters) which were then implanted into the peritoneal cavities of normal syngeneic recipient mice. The cells were infected with an injection of MuLV-F into the peritoneal cavity and, in some instances, also by placing virus into the chambers. Cells were recovered by treating the chamber content with elastase and collagenase. The infection was determined in two ways: (1) cells with replicating MuLV were enumerated as infection centers (IC) on S+L- indicator cells; and (2) virus-related cell membrane antigen (MA) was detected by immunofluorescence. Cells recovered from chambers after 2-3 weeks of culture represented about 10% of the original inoculum; viability was approximately 90%. The number of IC in MuLV-F-infected chambers was about 10 times higher than obtained by infection and cultivation of spleen cells in vitro. The kinetics of IC and MA in chamber-cultured. MuLV-F-infected spleen cells was similar to that in the spleen of infected mice during the first 10 days after infection. Later on, the process of infection within the chambers slowed down, reaching about 50% MA-positive and about 10% IC-positive cells, whereas the number of both IC- and MA-positive cells in the spleen reached 80% or more. The infection of splenic lymphocytes in diffusion chambers occurred equally well when chambers were implanted into: (1) syngeneic, virus susceptible hosts; (2) syngeneic, lethally irradiated hosts; and (3) allogeneic, virus-resistant hosts, suggesting that the process within the chamber is independent of MuLV replication in the tissues of the chamber-bearing mouse. The diffusion chamber technique seems to provide an environment in which various types of isolated lymphocytes of different mouse strains can interact with MuLV almost as efficiently as in vivo.

An analysis of the genetic requirements for delayed cutaneous hypersensitivity reactions to transplantation antigens in mice

The experiments reported herein provide ample evidence that mice, like most other mammalian species, are capable of displaying readily observable and reproducible delayed cutaneous hypersensitivity reactions indicative of transplantation immunity. By employing a variety of genetically defined strains, it has been shown that a genetic requirement for the development of a positive normal lymphocyte transfer reaction in mice is a difference between host and cell donor at the H-2 locus. By contrast, the immune lymphocyte transfer reaction consistently reflected the full range of histoincompatibility, both inclusive and exclusive of the H-2. It was incidentally discovered that erythema regularly accompanied delayed cutaneous reactions in the skins of female mice, whereas no local redness accompanied their counterparts in male skins. The influence of cutaneous erythema on the scoring of delayed skin reactions is discussed.