TOM22, a core component of the mitochondria outer membrane protein translocation pore, is a mitochondrial receptor for the proapoptotic protein Bax.

The association of Bax with mitochondria is an essential step in the implementation of apoptosis. By using a bacterial two-hybrid assay and crosslinking strategies, we have identified TOM22, a component of the translocase of the outer mitochondrial membrane (TOM), as a mitochondrial receptor of Bax. Peptide mapping showed that the interaction of Bax with TOM22 involved the first alpha helix of Bax and possibly two central alpha helices, which are homologous to the pore forming domains of some toxins. Antibodies directed against TOM22 or an antisense knockdown of the expression of TOM22 specifically inhibited the association of Bax with mitochondria and prevented Bax-dependent apoptosis. In yeast, a haploid strain for TOM22 exhibited a decreased expression of TOM22 and mitochondrial association of ectopically expressed human Bax. Our data provide a new perspective on the mechanism of association of Bax with mitochondria as it involves a classical import pathway.

Thrombospondin 2, a matricellular protein with diverse functions.

Thrombospondin (TSP) 2 is a close relative of TSP1 but differs in its temporal and spatial distribution in the mouse. This difference in expression undoubtedly reflects the marked disparity in the DNA sequences of the promoters in the genes encoding the two proteins. The synthesis of TSP2 occurs primarily in connective tissues of the developing and growing mouse. In the adult animal the protein is again produced in response to tissue injury and in association with the growth of tumors. Despite the abnormalities in collagen fibrillogenesis, fragility of skin, and laxity of tendons and ligaments observed in the TSP2-null mouse, TSP2 does not appear to contribute directly to the structural integrity of connective tissue elements. Instead, emerging evidence supports a mode of action of TSP2 'at a distance', i.e. by modulating the activity and bioavailability of proteases and growth factors in the pericellular environment and, very likely, by interaction with cell-surface receptors. Thus, TSP2 qualifies as a matricellular protein, as defined in the introduction to this minireview series. The phenotype of TSP2-null mice has been very helpful in providing clues to the functions of TSP2. In addition to histological and functional abnormalities in connective tissues, these mice display an increased vascularity of the dermis and subdermal tissues, increased endosteal bone growth, a bleeding defect, and a marked adhesive defect of dermal fibroblasts. Our laboratory has established that TSP2 binds matrix metalloproteinase 2 (MMP2) and that the adhesive defect in TSP2-null fibroblasts results from increased MMP2 activity. The investigation of the basis for the other defects in the TSP2-null mouse is likely to yield equally interesting results.

Early phase collagen synthesis in lungs of rats exposed to bleomycin.

Skin wound healing exhibits type III collagen synthesis occurring transiently as early as 10 h after injury, with subsequent synthesis of type I to form a scar. We hypothesized that similar collagen type switching also occurred in the bleomycin model of lung fibrosis in the rat. We could measure elevated lung collagen synthesis rates as early as 4 days after administration of bleomycin. Collagen type I:III ratios in whole lung remained constant for the first 7 days at the control level of 2:1, then increased to as high as 5:1 at day 21. Procollagen mRNA content, expressed as a ratio of type I:III mRNAs, was consistent with the protein synthesis data and the observed ratio of collagen types being made by the lungs at the various time points evaluated. We conclude that a transient increase in type III relative to type I collagen does not occur in the bleomycin rat lung model. Therefore, the sequence of type-specific collagen expression and deposition in the skin wound healing model is not entirely analogous to this widely used animal model of pulmonary fibrosis.

Thrombospondin 2 modulates collagen fibrillogenesis and angiogenesis.

Thrombospondin 2 (TSP2)-null mice, generated by targeted disruption of the Thbs2 gene, display a complex phenotype that is characterized, in part, by a variety of connective tissue abnormalities and increased vascular density in skin and subcutaneous tissues. In this paper we summarize the evidence that TSP2 functions as a matricellular protein to influence cell function by modulating cell-matrix interactions, rather than acting as an integral component of the matrix. Thus, the structurally abnormal collagen fibrils detected in skin appear to be the consequence of the defective adhesion demonstrated by dermal fibroblasts in culture that, in turn, result from increased matrix metalloproteinase 2 (MMP2, gelatinase A) production by these cells. Corroborating evidence for such a mode of action comes from transmission electron microscopic images of developing flexor muscle tendons that show distinct abnormalities in fibroblast-collagen fibril interactions in TSP2-null tissue. The increased vascular density seen in skin of TSP2-null mice can be reproduced in a number of models of injury, including subcutaneous implantation of polyvinyl alcohol sponges and silicone rubber discs, and excisional skin wounds. Experiments are proposed to distinguish between a primarily endothelial cell versus an extracellular matrix origin for the increased angiogenesis in TSP2-null mice.

Metaxin 1 interacts with metaxin 2, a novel related protein associated with the mammalian mitochondrial outer membrane.

A recently described protein, metaxin 1, serves as a component of a preprotein import complex in the outer membrane of the mammalian mitochondrion. A yeast two-hybrid screen with metaxin 1 as bait has now identified a novel protein, which we have termed metaxin 2, as a metaxin 1-binding protein. Metaxin 2 shares 29% identity with metaxin 1 at the amino acid level, but metaxin 2, unlike metaxin 1, lacks a C-terminal mitochondrial outer membrane signal-anchor domain. Two C. elegans hypothetical proteins, CelZC97.1 and CelF39B2.i, share high sequence similarity with metaxin 2 and metaxin 1, respectively, and likely represent the C. elegans orthologs. Affinity-purified antibodies against metaxin 2 were prepared against the recombinant protein produced in E. coli and were used to analyze the subcellular distribution of metaxin 2. In subcellular fractions of mouse liver, a 29 kD immunoreactive protein, consistent in size with the predicted translation product of metaxin 2 cDNA, was found solely in mitochondria. Alkali extraction of mitochondria indicated that metaxin 2 is peripherally associated with mitochondrial membranes. Metaxin 2 in intact mitochondria was susceptible to digestion with proteinase K, indicating that metaxin 2 is located on the cytosolic face of the mitochondrial outer membrane. Finally, baculoviruses encoding a His6-tagged metaxin 2 and an untagged metaxin 1 lacking its C-terminal transmembrane domain were produced and used separately or in combination to infect Sf21 insect cells. Metaxin 1 bound to a Ni2+-chelate affinity column only in the presence of metaxin 2, indicating that metaxin 1 and metaxin 2 interact when overexpressed in insect cells. These results suggest that metaxin 2 is bound to the cytosolic face of the mitochondrial outer membrane by means of its interaction with membrane-bound metaxin 1, and that this complex may play a role in protein import into mammalian mitochondria.

Metaxin is a component of a preprotein import complex in the outer membrane of the mammalian mitochondrion.

Metaxin, a novel gene located between the glucocerebrosidase and thrombospondin 3 genes in the mouse, is essential for survival of the postimplantation mouse embryo. In this study, the subcellular location, domain structure, and biochemical function of metaxin were investigated. Anti-recombinant metaxin antibodies recognized 35- and 70-kDa proteins in mitochondria from various tissues; the 35-kDa protein is consistent in size with the predicted translation product of metaxin cDNA. When metaxin cDNA was transfected into COS cells, immunofluorescence staining demonstrated that the protein is located in mitochondria. Metaxin contains a putative mitochondrial outer membrane signal anchor domain at its C terminus, and a truncated form of metaxin lacking this signal anchor domain had a reduced association with mitochondria. In addition, metaxin was highly susceptible to proteases in intact mitochondria. We therefore conclude that metaxin is a mitochondrial protein that extends into the cytosol while anchored into the outer membrane at its C terminus. In its N-terminal region, metaxin shows significant sequence identity to Tom37, a component of the outer membrane portion of the mitochondrial preprotein translocation apparatus in Saccharomyces cerevisiae, but important structural differences, including apparently different mechanisms of targeting to membranes, also exist between the two proteins. Given the similar subcellular locations of metaxin and Tom37, the possible role of metaxin in mitochondrial preprotein import was investigated. Antibodies against metaxin, when preincubated with mitochondria, partially inhibited the uptake of radiolabeled preadrenodoxin into mitochondria. Metaxin is therefore the second mammalian component of the protein translocation apparatus of the mitochondrial outer membrane to be characterized at the molecular level and the first for which an inherited mutation has been described. The early embryonic lethal phenotype of mice lacking metaxin demonstrates that efficient import of proteins into mitochondria is crucial for cellular survival. The characterization of metaxin provides an opportunity to elucidate similarities and possible differences in the mechanisms of protein import between fungi and mammals and in the phenotypes of fungi and mammals lacking mitochondrial import receptors.

Rat lysyl hydroxylase: molecular cloning, mRNA distribution and expression in a baculovirus system.

A cDNA library from rat lung was screened with a chicken lysyl hydroxylase cDNA, and several overlapping rat lysyl hydroxylase cDNAs were isolated. The complete cDNA was 91 and 77% identical, respectively, to the human and chicken lysyl hydroxylase cDNAs at the protein level. By Northern blot, the rat lysyl hydroxylase cDNA recognized a single 3.2 kb mRNA that was present in a wide variety of rat tissues. In order to further confirm the identity of this cDNA, the cDNA was expressed in insect cells via a baculovirus vector. These cells produced an 85 kDa protein with lysyl hydroxylase activity. The recombinant lysyl hydroxylase had a specific activity and Km values for its substrates that were similar to those of the enzyme isolated from chick embryos. The fact that this single lysyl hydroxylase cDNA encodes a protein sufficient for lysyl hydroxylase activity is consistent with previous biochemical findings that lysyl hydroxylase only requires a single type of subunit for its activity.

Collagen mRNA content and distribution in the lungs of rats exposed to ozone.

cDNAs, synthesized by the polymerase chain reaction (PCR) technique, were used to quantify mRNA concentrations for the alpha 1 (I) and alpha 1 (III) chains of collagen types I and III and for beta-actin in the lungs of rats exposed to either filtered air or to 1.2 ppm of ozone. The alpha 1 (I) procollagen mRNA concentration was increased by about 30% in the lungs of rats exposed to ozone, while the concentrations of the mRNAs for alpha 1 (III) procollagen and for beta-actin were the same in the lungs of control and ozone-exposed animals. The lungs from the rats exposed to 1.2 ppm of ozone preferentially synthesized type I collagen as compared with controls. Sites of increased expression of the alpha 1 (I) procollagen mRNA were detected by in situ hybridization in lung sections embedded in paraffin prepared from rats exposed either to filtered air or to ozone. The lungs from rats treated with ozone focally expressed increased amounts of alpha 1 (I) procollagen mRNA in the lung parenchyma at the septal tips and the bronchiole-alveolar duct junctions. They also showed an apparent diffuse increase in alpha 1 (III) procollagen mRNA expression. We conclude that exposure of rats to high concentrations of ozone causes a specific increase in the lung content of mRNA for the major chain of type I collagen.

Silica increases cytosolic free calcium ion concentration of alveolar macrophages in vitro.

Rat alveolar macrophages were exposed to silica dust (quartz) suspended in culture medium (SiO2, dry particle size less than 5 microns in diameter) and fluctuation in their cytosolic free calcium content ([Ca2+]i) was detected in cell monolayers with a fluorescent calcium probe (Indo-1AM). Cytosolic free calcium content was correlated with lactate dehydrogenase (LDH) release, an index of cell damage. SiO2 induced a concentration- and time-dependent increase of cytosolic free Ca2+ ion concentration and LDH release. [Ca2+]i was increased about fivefold when cells were exposed to 200 micrograms of SiO2 per milliliter (3 ml per dish) for 2 hr. [Ca2+]i changed within 15 min of SiO2 treatment, whereas LDH release was measurably increased only after 30 min. Chelation of extracellular Ca2+ by 2 mM ethylene glycol bis(beta-aminoethyl ether) N,N'-tetraacetate did not prevent SiO2-induced fluctuation of macrophage [Ca2+]i, but did partially prevent the SiO2-induced increase in LDH release (p less than 0.01). We conclude that a very early event in SiO2-induced damage of alveolar macrophages involves mobilization of intracellular calcium pools to increase [Ca2+]i. These results suggest that SiO2-induced macrophage damage, a key event in the development of silicosis, may involve perturbation of intracellular calcium homeostasis.

Hydroxylation of collagen by lungs of rats administered bleomycin.

Collagen synthesized by tissue minces from lungs of rats administered 1 unit of bleomycin by intratracheal instillation 1 or 2 wk earlier contained relatively more hydroxylysine than did collagen made by lungs from saline-instilled control animals. Most, if not all, of the relative increase in lysine hydroxylation could be localized to the alpha 1 (I) chain of type I collagen. Lung homogenates from bleomycin-treated rats showed increased activity of lysyl hydroxylase (EC 1.14.11.4), the enzyme catalyzing the conversion of collagen-bound lysine to hydroxylysine. Thus, the increased hydroxylation of lysine and of lysine-derived cross-links previously observed in collagen of diseased human lungs and in animal models of lung fibrosis is reflected in an in vitro system.

Physician concerns aired at hospital medical staff forum.

When physicians and administrators at Sinai Hospital of Detroit convened at a medical staff forum, the physicians became more familiar with administrators, operational problems were identified, and a monthly newletter on health care issues for physicians was born.