Role of binding of plectin to the integrin beta4 subunit in the assembly of hemidesmosomes.

We have previously shown that plectin is recruited into hemidesmosomes through association of its actin-binding domain (ABD) with the first pair of fibronectin type III (FNIII) repeats and a small part of the connecting segment (residues 1328-1355) of the integrin beta4 subunit. Here, we show that two proline residues (P1330 and P1333) in this region of the connecting segment are critical for supporting beta4-mediated recruitment of plectin. Additional binding sites for the plakin domain of plectin on beta4 were identified in biochemical and yeast two-hybrid assays. These sites are located at the end of the connecting segment (residues 1383-1436) and in the region containing the fourth FNIII repeat and the C-tail (residues 1570-1752). However, in cells, these additional binding sites cannot induce the assembly of hemidesmosomes without the interaction of the plectin-ABD with beta4. Because the additional plectin binding sites overlap with sequences that mediate an intramolecular association of the beta4 cytoplasmic domain, we propose that they are not accessible for binding and need to become exposed as the result of the binding of the plectin-ABD to beta4. Furthermore, these additional binding sites might be necessary to position the beta4 cytoplasmic domain for an optimal interaction with other hemidesmosomal components, thereby increasing the efficiency of hemidesmosome assembly.

Tom22 is a multifunctional organizer of the mitochondrial preprotein translocase.

Mitochondrial preproteins are imported by a multisubunit translocase of the outer membrane (TOM), including receptor proteins and a general import pore. The central receptor Tom22 binds preproteins through both its cytosolic domain and its intermembrane space domain and is stably associated with the channel protein Tom40 (refs 11-13). Here we report the unexpected observation that a yeast strain can survive without Tom22, although it is strongly reduced in growth and the import of mitochondrial proteins. Tom22 is a multifunctional protein that is required for the higher-level organization of the TOM machinery. In the absence of Tom22, the translocase dissociates into core complexes, representing the basic import units, but lacks a tight control of channel gating. The single membrane anchor of Tom22 is required for a stable interaction between the core complexes, whereas its cytosolic domain serves as docking point for the peripheral receptors Tom20 and Tom70. Thus a preprotein translocase can combine receptor functions with distinct organizing roles in a multidomain protein.

Functional complementation analysis of yeast bc1 mutants. A study of the mitochondrial import of heterologous and hybrid proteins.

Previous complementation studies with yeast bc1 mutants, defective in subunit VII or VIII, using heterologous and hybrid subunits, suggested that the requirement for import into mitochondria might significantly restrict the scope of this test for compatible proteins. Prediction algorithms indicate that the N-terminal domain of subunit VII contains all known characteristics of a mitochondrial targeting signal, whereas in subunit VIII such a signal is absent from the N-terminal domain, but possibly present in an internal region of the protein. Despite the fact that the characteristics of a mitochondrial import signal are found in the N-terminus of all known subunit-VII orthologues, in vitro import experiments show that the protein of human origin is not imported into yeast mitochondria. In vitro import can be restored, however, by replacement of the N-terminal part of the human protein by the N-terminus of the Saccharomyces cerevisiae orthologue, indicating a requirement for species-specific elements. Similar experiments were performed with subunit VIII and orthologues thereof, including a hybrid protein in which the N-terminus of the bovine heart orthologue was replaced by that of S. cerevisiae. The ability of yeast mitochondria to import this hybrid protein, in contrast with the bovine subunit-VIII orthologue itself, indicates that for subunit VIII also the N-terminus, in contradiction of theoretical predictions, contributes to the targeting signal, most likely via species-specific elements. Our findings expose the limitations of the currently available criteria for prediction of the presence and location of a mitochondrial targeting sequence and highlight the necessity of performing separate import studies for interpreting complementation studies as long as the species-specific characteristics of the import signals have not been identified.

The preprotein translocase of the mitochondrial inner membrane: function and evolution.

Growing mitochondria acquire most of their proteins by the uptake of mitochondrial preproteins from the cytosol. To mediate this protein import, both mitochondrial membranes contain independent protein transport systems: the Tom machinery in the outer membrane and the Tim machinery in the inner membrane. Transport of proteins across the inner membrane and sorting to the different inner mitochondrial compartments is mediated by several protein complexes which have been identified in the past years. A complex containing the integral membrane proteins Tim17 and Tim23 constitutes the import channel for preproteins containing amino-terminal hydrophilic presequences. This complex is associated with Tim44 which serves as an adaptor protein for the binding of mtHsp70 to the membrane. mtHsp70, a 70 kDa heat shock protein of the mitochondrial matrix, drives the ATP-dependent import reaction of the processed preprotein after cleavage of the presequence. Preproteins containing internal targeting information are imported by a separate import machinery, which consists of the intermembrane-space proteins Tim9, Tim10, and Tim12, and the inner membrane proteins Tim22 and Tim54. The proteins Tim17, Tim22, and Tim23 have in common a similar topology in the membrane and a homologous amino acid sequence. Moreover, they show a sequence similarity to OEP16, a channel-forming amino acid transporter in the outer envelope of chloroplasts, and to LivH, a component of a prokaryotic amino acid permease, defining a new PRAT-family of preprotein and amino acid transporters.

Expression of genes encoding peroxisomal proteins in Saccharomyces cerevisiae is regulated by different circuits of transcriptional control.

In Saccharomyces cerevisiae induction of the FOX3 gene, encoding peroxisomal 3-oxoacyl-CoA thiolase, by growth on oleate as sole carbon source, is exerted via the cis-acting DNA element designated oleate response element (ORE) (Einerhand et al. (1991) Eur. J. Biochem. 200, 113-122). The transcription factor(s) binding to this upstream activation site (UAS) are still unknown, however. Induction of another peroxisomal enzyme, citrate synthase (CIT2) is dependent on the products of two genes called RTG1 and RTG2 (Liao and Butow (1993) Cell 72, 61-71). In the present study we have investigated whether RTG1 controls other genes coding for peroxisomal proteins, and whether such control takes place via the ORE. A number of genes coding for a variety of peroxisomal proteins such as: thiolase and catalase (peroxisomal matrix proteins), PAS3p (a peroxisomal membrane protein) and PAS10p (a protein involved in the import of peroxisomal proteins) were studied in their response to RTG1. Although the RTG1 and 2 products proved to be required for the increase in number and volume of peroxisomes upon induction by oleate, the single promoter output of the chosen set of genes remained practically unchanged in a rtg1 mutant strain. In addition gel retardation experiments indicated that RTG1 does not bind to the ORE. The behavior of genes coding for the various proteins also varied during repression, derepression and induction, indicating that probably a number of proteins are involved in tuning the output of each gene to cellular demand.