Distribution and function of AP-1 clathrin adaptor complexes in polarized epithelial cells.

Expression of the epithelial cell-specific heterotetrameric adaptor complex AP-1B is required for the polarized distribution of many membrane proteins to the basolateral surface of LLC-PK1 kidney cells. AP-1B is distinguished from the ubiquitously expressed AP-1A by exchange of its single 50-kD mu subunit, mu1A, being replaced by the closely related mu1B. Here we show that this substitution is sufficient to couple basolateral plasma membrane proteins, such as a low-density lipoprotein receptor (LDLR), to the AP-1B complex and to clathrin. The interaction between LDLR and AP-1B is likely to occur in the trans-Golgi network (TGN), as was suggested by the localization of functional, epitope-tagged mu1 by immunofluorescence and immunoelectron microscopy. Tagged AP-1A and AP-1B complexes were found in the perinuclear region close to the Golgi complex and recycling endosomes, often in clathrin-coated buds and vesicles. Yet, AP-1A and AP-1B localized to different subdomains of the TGN, with only AP-1A colocalizing with furin, a membrane protein that uses AP-1 to recycle between the TGN and endosomes. We conclude that AP-1B functions by interacting with its cargo molecules and clathrin in the TGN, where it acts to sort basolateral proteins from proteins destined for the apical surface and from those selected by AP-1A for transport to endosomes and lysosomes.

Bcs1p, an AAA-family member, is a chaperone for the assembly of the cytochrome bc(1) complex.

Bcs1p, a mitochondrial protein and member of the conserved AAA protein family, is involved in the biogenesis of the cytochrome bc(1) complex. We demonstrate here that Bcs1p is directly required for the assembly of the Rieske FeS and Qcr10p proteins into the cytochrome bc(1) complex. Bcs1p binds to a precomplex in the assembly pathway of the cytochrome bc(1) complex. Binding of Bcs1p to and release from this assembly intermediate is driven by ATP hydrolysis. We propose that Bcs1p acts as an ATP-dependent chaperone, maintaining the precomplex in a competent state for the subsequent assembly of the Rieske FeS and Qcr10p proteins.

A novel clathrin adaptor complex mediates basolateral targeting in polarized epithelial cells.

Although polarized epithelial cells are well known to maintain distinct apical and basolateral plasma membrane domains, the mechanisms responsible for targeting membrane proteins to the apical or basolateral surfaces have remained elusive. We have identified a novel form of the AP-1 clathrin adaptor complex that contains as one of its subunits mu1B, an epithelial cell-specific homolog of the ubiquitously expressed mu1A. LLC-PK1 kidney epithelial cells do not express mu1B and missort many basolateral proteins to the apical surface. Stable expression of mu1B selectively restored basolateral targeting, improved the overall organization of LLC-PK1 monolayers, and had no effect on apical targeting. We conclude that basolateral sorting is mediated by an epithelial cell-specific version of the AP-1 complex containing mu1B.

C- to N-terminal translocation of preproteins into mitochondria.

Nuclear-encoded mitochondrial matrix proteins in most cases contain N-terminal targeting signals and are imported in a linear N- to C-terminal (N-->C) fashion. We asked whether import can also occur in a C- to N-terminal direction (C-->N). We placed targeting signals at the C-terminus of passenger proteins. Import did occur in this 'backwards' fashion. It paralleled that of the 'normal' N-->C mechanism in terms of efficiency, rate, energetic requirements and ability to mediate unfolding and refolding during and following import of protein containing a folded domain. Furthermore, this reaction was mediated by the TIM17-23 machinery. The import pathway taken by certain inner-membrane proteins contains elements of such a C-->N translocation pathway, as they are targeted to mitochondria by internal targeting signals. These internal targeting signals appear to form loop structures together with neighbouring transmembrane segments, and penetrate the inner membrane in a membrane-potential-dependent manner. The dimeric TIM17-23 complex, together with mt-Hsp70, acts on both sides of the loop structure to facilitate their translocation into the matrix. On one side of the loop import occurs in the common N-->C direction, whereas the translocation of the other side involves the novel C-->N import direction. We conclude therefore that the mitochondrial import machinery displays no preference for the directionality of the import process.

Carrier protein import into mitochondria mediated by the intermembrane proteins Tim10/Mrs11 and Tim12/Mrs5.

Import of nuclear-encoded precursor proteins into mitochondria and their subsequent sorting into mitochondrial subcompartments is mediated by translocase enzymes in the mitochondrial outer and inner membranes. Precursor proteins carrying amino-terminal targeting signals are translocated into the matrix by the integral inner membrane proteins Tim23 and Tim17 in cooperation with Tim44 and mitochondrial Hsp70. We describe here the discovery of a new pathway for the transport of members of the mitochondrial carrier family and other inner membrane proteins that contain internal targeting signals. Two related proteins in the intermembrane space, Tim10/Mrs11 and Tim12/Mrs5, interact sequentially with these precursors and facilitate their translocation across the outer membrane, irrespective of the membrane potential. Tim10 and Tim12 are found in a complex with Tim22, which takes over the precursor and mediates its membrane-potential-dependent insertion into the inner membrane. This interaction of Tim10 and Tim12 with the precursors depends on the presence of divalent metal ions. Both proteins contain a zinc-finger-like motif with four cysteines and bind equimolar amounts of zinc ions.

Two distinct and independent mitochondrial targeting signals function in the sorting of an inner membrane protein, cytochrome c1.

Proteins of the mitochondrial inner membrane display a wide variety of orientations, many spanning the membrane more than once. Some of these proteins are synthesized with NH2-terminal cleavable targeting sequences (presequences) whereas others are targeted to mitochondria via internal signals. Here we report that two distinct mitochondrial targeting signals can be present in precursors of inner membrane proteins, an NH2-terminal one and a second, internal one. Using cytochrome c1 as a model protein, we demonstrate that these two mitochondrial targeting signals operate independently of each other. The internal targeting signal, consisting of a transmembrane segment and a stretch of positively charged amino acid residues directly following it, initially directs the translocation of the preprotein into the intermembrane space. It then inserts into the inner membrane from the intermembrane space side in a delta psi-dependent manner and thereby determines the orientation the protein attains in the inner membrane. Analysis of a number of other presequence-containing protein of the inner membrane suggest that they too contain such internal targeting signals.

Internal targeting signal of the BCS1 protein: a novel mechanism of import into mitochondria.

The BCS1 protein is anchored in the mitochondrial inner membrane via a single transmembrane domain and has an N(out)-C(in) topology. Unlike the majority of nuclear encoded mitochondrial preproteins, the BCS1 protein does not contain an N-terminal targeting sequence. A positively charged segment of amino acids which is located immediately C-terminal to the transmembrane domain acts as an internal targeting signal. In order to function, we postulate that this sequence co-operates with the transmembrane domain to form a tight hairpin loop structure. This loop is translocated across the inner membrane via the MIM/mt-Hsp70 machinery in a membrane potential-dependent manner. This novel mechanism of import and sorting of the BCS1 protein is proposed to represent a more general mechanism used by a number of inner membrane proteins.