Coreceptor function of mutant human CD4 molecules without affinity to gp120 of human immunodeficiency virus.

Despite extensive mutational studies on the human CD4 molecule and its affinity to human immunodeficiency virus (HIV) envelope glycoprotein gp120, coreceptor functions of such mutant molecules have only been examined by indirect measurement of their affinity to class II major histocompatibility complex (MHC) molecules. In this report, coreceptor functions of mutant human CD4 molecules, which have no or reduced affinity to an HIV envelope protein, gp120, were assessed in a murine T cell receptor/class II MHC recognition system. The substitution of human C" beta strand with the murine homologous segment resulted in the loss of the coreceptor function as well as in the complete loss of gp120 binding capacity, corroborating the consensus that Phe-43 in C" beta strand plays crucial roles in both situations. However, simultaneous replacement of the C'-C" loop along with the C" beta strand by homologous murine segments rescued the coreceptor function, whereas gp120 binding capacity remained negative. Further analysis indicated that insertion of lysine between Gly-41 and Ser-42 can partially compensate for the coreceptor function lost by the Phe-43 --> Val mutation. Although the coreceptor function of these mutant CD4 molecules in a human T cell recognition system is yet to be determined, these observations necessitate a re-evaluation of the role played by Phe-43 in coreceptor function. Examination of the sensitivities of the mutant CD4 molecules expressed on HeLa cells to infection by a T cell-tropic HIV-1 strain indicated that only those mutants that had completely lost gp120 binding capacity were resistant to the infection. All mutants having whole C" substitution, irrespective of additional substitutions or their coreceptor functions, were resistant to the infection.

Cell death-associated translocation of plasma membrane components induced by CTL.

In the very early stages of target cell apoptosis induced by CTL, we found that fluorescence of labeling probes of the target plasma membrane, such as N-(3-triethylammoniumpropyl)-4-(p-dibutylaminostyryl)pyridin ium dibromide (FM1-43), was translocated into intracellular membrane structures including nuclear envelope and mitochondria. This translocation was associated with the execution of CTL-mediated killing, because neither the CTL-target conjugation alone nor the binding of noncytotoxic Th2 clone with target cell was sufficient to provoke the process. Although FM1-43 translocation was observed in perforin-mediated cytotoxicity, examinations with several other dyes failed to detect the evidence for membrane damages that may cause influx of the dye. Moreover, the translocation was also observed in Fas-dependent apoptosis. These data indicate that the translocation precedes the damage of plasma membrane and intracellular organella in the course of apoptotic cell death and may represent the existence of a membrane trafficking that mediates the translocation of plasma membrane components in the early onset of apoptotic cell death.

Lack of requirement for SHP-1 in both Fas-mediated and perforin-mediated cell death induced by CTL.

The Fas (CD95)-transmitted cell death signal has been reported to involve a protein tyrosine phosphatase, SHP-1. We analyzed the role of SHP-1 in the Fas-dependent as well as the perforin-dependent pathways of CTL-mediated killing using target cells prepared from SHP-1-deficient motheaten mice. Con A blast targets prepared from both a motheaten mouse and a phenotype-normal littermate were equally sensitive to the cytolysis and DNA fragmentation induced by both perforin-deficient Fas-dependent CTL and Fas ligand-deficient perforin-positive CTL. Fas-induced DNA degradation detected by the terminal deoxynucleotide transferase reaction was also observed in the killing of motheaten thymocytes by a Fas-based CTL as well as by anti-Fas mAb. These data cast doubt on the involvement of SHP-1 in Fas-induced lymphoid cell death.