Selective depletion of myelin-reactive T cells with the anti-OX-40 antibody ameliorates autoimmune encephalomyelitis.

The OX-40 protein was selectively upregulated on encephalitogenic myelin basic protein (MBP)-specific T cells at the site of inflammation during the onset of experimental autoimmune encephalomyelitis (EAE). An OX-40 immunotoxin was used to target and eliminate MBP-specific T cells within the central nervous system without affecting peripheral T cells. When injected in vivo, the OX-40 immunotoxin bound exclusively to myelin-reactive T cells isolated from the CNS, which resulted in amelioration of EAE. Expression of the human OX-40 antigen was also found in peripheral blood of patients with acute graft-versus-host disease and the synovia of patients with rheumatoid arthritis during active disease. The unique expression of the OX-40 molecule may provide a novel therapeutic strategy for eliminating autoreactive CD4+T cells that does not require prior knowledge of the pathogenic autoantigen.

Identification of proteins involved in intracellular copper metabolism. Low levels of a approximately 48-kDa copper-binding protein in the brindled mouse model of Menkes disease.

Little is known about copper metabolism at the cellular level. The brindled mouse is an animal model of Menkes disease which is an inborn error of copper metabolism. Control and brindled mice were used to identify copper-binding proteins with possible roles in normal copper metabolism that are affected by the defect in the brindled mice. When 64Cu-labeled hepatic or renal cytosols from control mice were applied to Mono Q or Superose columns, a approximately 48-kDa protein coeluted with the protein fractions which contained the radiolabeled copper. Large decreases in copper binding were detected in these fractions from the brindled mice. The same column fractions which showed decreased copper binding showed large decreases in the levels of the approximately 48-kDa protein. Decreased copper binding and approximately 48-kDa protein were not simply secondary to the abnormal hepatic and renal copper levels that are found in the brindled mice since although their liver copper levels are low, their kidney copper levels are high. Elevated levels of an approximately 80-kDa heat shock protein were also detected in the hepatic and renal cytosols from the brindled mice. Consistent with expression of the primary defect in both the liver and kidney, the levels of the approximately 48- and approximately 80-kDa proteins were affected similarly in both organs. Irrespective of how the low levels of the approximately 48-kDa protein may be related to the basic defect in the brindled mice, the data are consistent with an important role for the approximately 48-kDa protein in intracellular copper metabolism.

Transcription of a silkworm tRNA(cAla) gene is directed by two AT-rich upstream sequence elements.

A region within 35 nucleotides upstream of the transcription initiation site of a variety of silkworm Class III templates is absolutely required for transcription in vitro. To determine whether the activity of this region can be attributed to a particular sequence element, we systematically replaced 4-5 bp segments of the region upstream of a silkworm tRNA(cAla) gene. We show that replacement of either of two AT-rich blocks markedly impairs promoter function, whereas replacement of other sequences has little or no effect. Additional mutants were constructed to test whether base composition or sequence is important for function of the AT blocks. We find that some sequences are more effective than others, but that various AT-rich sequences can direct transcription at a high level. Possible mechanisms by which such elements could act are discussed.

Effect of albumin on net copper accumulation by fibroblasts and hepatocytes.

The liver accumulates copper rapidly and preferentially from plasma. The effects of albumin on net copper accumulation by fibroblasts and hepatocytes were compared to determine whether preferential uptake involves hepatocyte-specific sequestering of copper. Although albumin inhibits the initial rates (30 s) of copper transport by fibroblasts and hepatocytes similarly, the effects of albumin on net copper accumulation (4 h) by these cell types were strikingly different. Fibroblasts accumulate only approximately 15% as much copper when equimolar albumin is present as from albumin-free media; hepatocytes accumulate about the same amount of copper with or without extracellular albumin present. Copper efflux data show that the special capacity of hepatocytes to accumulate copper in the presence of extracellular albumin is due to greater copper retention by hepatocytes than fibroblasts. The ability of hepatocytes to accumulate copper does not seem to be due to albumin-receptor-mediated uptake, since albumin was not co-transported with copper. The data are consistent with an equilibrium model of copper accumulation in which intracellular and extracellular copper are in equilibrium with intracellular and extracellular ligands. A high-affinity, copper-binding fraction that was previously identified in cytosols from hepatocytes was low or absent in fibroblasts. This may contain a liver-specific protein(s) that helps hepatocytes sequester and retain copper from albumin or serum-containing media. Irrespective of the exact species involved, the data are consistent with rapid, preferential copper uptake by the liver being due in part to a liver-specific, intracellular copper-binding protein(s) with a high binding affinity for copper.

Cytosolic copper-binding proteins in rat and mouse hepatocytes incubated continuously with Cu(II).

The proteins that bind copper when it first enters cells are likely to play roles in its intracellular distribution and utilization. When hepatocytes were incubated with 64Cu(II), the time-dependence of the subcellular distribution of 64Cu was consistent with one or more cytosolic proteins distributing copper to the mitochondrial and nuclear fractions. Cytosolic copper was reproducibly distributed among four protein fractions from Sephadex G-150 columns at the earliest time (1 min) and at the lowest concentration used [2 microM-64Cu(II)] with both rat and mouse hepatocytes. Copper binding to proteins in these functions was sensitive to copper metabolic status. Hepatocytes from nutritionally copper-deficient rats or neonatal (9-30 days old) developing rats showed an inverse correlation between copper binding to metallothionein and copper binding to proteins in fraction I (approximately 88 kDa apparent) and fraction II (approximately 38 kDa apparent). The distribution of cytosolic 64Cu from the brindled-mouse model of Menkes disease indicated decreased binding by a protein in fraction I. Brindled-mouse hepatocytes also contain decreased levels of a approximately 55 kDa protein or subunit, which most likely represents a liver-specific secondary response to the primary defect. The results are consistent with one or more copper-binding proteins in fractions I and II having significant functions in intracellular copper metabolism.