Processing of exogenous antigens for presentation by class I MHC molecules involves post-Golgi peptide exchange influenced by peptide-MHC complex stability and acidic pH.

Vacuolar alternate class I MHC (MHC-I) Ag processing allows presentation of exogenous Ag by MHC-I molecules with binding of antigenic peptides to post-Golgi MHC-I molecules. We investigated the role of previously bound peptides and their dissociation in generating peptide-receptive MHC-I molecules. TAP1-knockout macrophages were incubated overnight with an initial exogenous peptide, producing a large cohort of peptide-K(b) complexes that could influence subsequent peptide dissociation/exchange. Initial incubation with FAPGNYPAL, KVVRFDKL, or RGYVYQGL enhanced rather than reduced subsequent binding and presentation of a readout peptide (SIINFEKL or FAPGNYPAL) to T cells. Thus, K(b) molecules may be stabilized by an initial (stabilizing) peptide, enhancing their ability to bind readout peptide and implicating peptide dissociation/exchange. In contrast, incubation with SIINFEKL as stabilizing peptide reduced presentation of readout peptide. SIINFEKL-K(b) complexes were more stable than other peptide-K(b) complexes, which may limit their contribution to peptide exchange. Stabilizing peptides (FAPGNYPAL, KVVRFDKL, or RGYVYQGL) enhanced alternate MHC-I processing of HB101.Crl-OVA (Escherichia coli expressing an OVA fusion protein), indicating that alternate MHC-I Ag processing involves peptide dissociation/exchange. Stabilizing peptide enhanced processing of HB101.Crl-OVA more than presentation of exogenous OVA peptide (SIINFEKL), suggesting that peptide dissociation/exchange may be enhanced in the acidic phagosomal processing environment. Furthermore, exposure of cells to acidic pH increased subsequent binding and presentation of readout peptide. Thus, peptide dissociation/exchange contributes to alternate MHC-I Ag processing and may be influenced by both stability of peptide-MHC-I complexes and pH.

Regulation of hemoglobin synthesis and proliferation of differentiating erythroid cells by heme-regulated eIF-2alpha kinase.

Protein synthesis in reticulocytes depends on the availability of heme. In heme deficiency, inhibition of protein synthesis correlates with the activation of heme-regulated eIF-2alpha kinase (HRI), which blocks the initiation of protein synthesis by phosphorylating eIF-2alpha. HRI is a hemoprotein with 2 distinct heme-binding domains. Heme negatively regulates HRI activity by binding directly to HRI. To further study the physiological function of HRI, the wild-type (Wt) HRI and dominant-negative inactive mutants of HRI were expressed by retrovirus-mediated transfer in both non-erythroid NIH 3T3 and mouse erythroleukemic (MEL) cells. Expression of Wt HRI in 3T3 cells resulted in the inhibition of protein synthesis, a loss of proliferation, and eventually cell death. Expression of the inactive HRI mutants had no apparent effect on the growth characteristics or morphology of NIH 3T3 cells. In contrast, expression of 3 dominant-negative inactive mutants of HRI in MEL cells resulted in increased hemoglobin production and increased proliferative capacity of these cells upon dimethyl-sulfoxide induction of erythroid differentiation. These results directly demonstrate the importance of HRI in the regulation of protein synthesis in immature erythroid cells and suggest a role of HRI in the regulation of the numbers of matured erythroid cells.

Two heme-binding domains of heme-regulated eukaryotic initiation factor-2alpha kinase. N terminus and kinase insertion.

In heme deficiency, protein synthesis in reticulocytes is inhibited by activation of heme-regulated alpha-subunit of eukaryotic initiation factor-2alpha (eIF-2alpha) kinase (HRI). Previous studies indicate that HRI contains two distinct heme-binding sites per HRI monomer. To study the role of the N terminus in the heme regulation of HRI, two N-terminally truncated mutants, Met2 and Met3 (deletion of the first 103 and 130 amino acids, respectively), were prepared. Met2 and Met3 underwent autophosphorylation and phosphorylated eIF-2alpha with a specific activity of approximately 50% of that of the wild type HRI. These mutants were significantly less sensitive to heme regulation both in vivo and in vitro. In addition, the heme contents of purified Met2 and Met3 HRI were less than 5% of that of the wild type HRI. These results indicated that the N terminus was important but was not the only domain involved in the heme-binding and heme regulation of HRI. Heme binding of the individual HRI domains showed that both N terminus and kinase insertion were able to bind hemin, whereas the C terminus and the catalytic domains were not. Thus, both the N terminus and the kinase insertion, which are unique to HRI, are involved in the heme binding and the heme regulation of HRI.

Heme-regulated eIF-2alpha kinase purifies as a hemoprotein.

The regulation of protein synthesis by the availability of heme in reticulocytes is well established. However, the mechanism by which heme regulates translational initiation is not clear. In this study, we have examined the heme regulation directly on the homogeneous heme-regulated eIF-2alpha kinase (HRI), which is activated during heme deficiency. We found that HRI purified as a hemoprotein with the characteristic Soret band of hemoprotein at 424 nm. This HRI was an active autokinase and eIF-2alpha kinase, and its kinase activities were inhibited by submicromolar concentrations of hemin with an apparent Ki of 0.5 microM. Homogeneous HRI was a homodimer, and its activities could not be inhibited by incubation with purified inactive K199R HRI in vitro. Our results suggest that there are two distinct types of heme-binding sites in the HRI homodimer. The binding of heme to the first site is stable, while the binding of heme to the second site is responsible for the rapid downregulation of HRI activity by heme. These results indicate that HRI binds heme and serves as a sensor of the availability of heme to coordinate the balanced synthesis of globins and heme in erythroid cells.

Inhibition of protein synthesis in insect cells by baculovirus-expressed heme-regulated eIF-2 alpha kinase.

To study further the regulation of the heme-regulated eIF-2 alpha kinase (HRI), we have produced functional wild type HRI using the baculovirus expression system. The amount of recombinant HRI protein expressed in insect cells is approximately 10 times higher than levels in reticulocytes. Baculovirus-expressed HRI (BV-HRI) is indistinguishable from HRI purified from rabbit reticulocytes. It is active both as an autokinase and an eIF-2 alpha kinase. BV-HRI is regulated by heme in vitro as well as in intact insect cells. Coexpression of the wild type HRI with the inactive K199R HRI, S51A eIF-2 alpha, or interleukin-1 beta (IL-1 beta) results in diminished expression of these proteins. Expression of wild type HRI also results in severe inhibition of general protein synthesis in Sf9 cells when compared with cells expressing K199R HRI or IL-beta. In addition, the guanine nucleotide exchange activity of eIF-2B is suppressed in Sf9 cells expressing wild type HRI but not in cells expressing the K199R HRI or IL-1 beta. Furthermore, expression of wild type HRI is increased by coexpression with the nonphosphorylatable S51A eIF-2 alpha or by the addition of hemin, which inhibits HRI activity. These results provide evidence that translational regulation by phosphorylation of eIF-2 alpha and sequestration of eIF-2B can operate in insect cells.