Cloning and characterization of A-kinase anchor protein 100 (AKAP100). A protein that targets A-kinase to the sarcoplasmic reticulum.

Differential localization of the type II cAMP-dependent protein kinase (PKA) is achieved by interaction of the regulatory subunit (RII) with A-kinase anchor proteins (AKAPs). Anchoring is a likely means to adapt PKA for regulation of cAMP-responsive events through colocalization of the kinase with preferred substrates. Using an interaction cloning strategy with an RII alpha protein probe, we have identified a 655-amino acid protein (named AKAP100). Recombinant AKAP100, expressed in Escherichia coli, binds RII alpha in a solid-phase overlay assay. The cellular and subcellular distribution of AKAP100 was analyzed by various methods. Northern blot analysis with the AKAP100 cDNA as a probe detected an 8-kilobase message in some human tissues including various brain regions; however, the message was predominately expressed in cardiac and skeletal muscle. Anti-AKAP100 antibodies confirmed expression in the rat cardiac and skeletal muscle cell lines, H9c2 and L6P, whereas immunohistochemical analysis revealed that AKAP100 was localized to the sarcoplasmic reticulum of both cell types. RII was also detected in these regions. AKAP100 was detected in preparations of RII purified from L6P cell extracts by cAMP-agarose affinity chromatography. Collectively, these results suggest that AKAP100 functions to maintain the type II PKA at the sarcoplasmic reticulum.

Differential targeting of two glucose transporters from Leishmania enriettii is mediated by an NH2-terminal domain.

Leishmania are parasitic protozoa with two major stages in their life cycle: flagellated promastigotes that live in the gut of the insect vector and nonflagellated amastigotes that live inside the lysosomes of the vertebrate host macrophages. The Pro-1 glucose transporter of L. enriettii exists as two isoforms, iso-1 and iso-2, which are both expressed primarily in the promastigote stage of the life cycle. These two isoforms constitute modular structures: they differ exclusively and extensively in their NH2-terminal hydrophilic domains, but the remainder of each isoform sequence is identical to that of the other. We have localized these glucose transporters within promastigotes by two approaches. In the first method, we have raised a polyclonal antibody against the COOH-terminal hydrophilic domain shared by both iso-1 and iso-2, and we have used this antibody to detect the transporters by confocal immunofluorescence microscopy and immunoelectron microscopy. The staining observed with this antibody occurs primarily on the plasma membrane and the membrane of the flagellar pocket, but there is also light staining on the flagellum. We have also localized each isoform separately by introducing an epitope tag into each protein sequence. These experiments demonstrate that iso-1, the minor isoform, resides primarily on the flagellar membrane, while iso-2, the major isoform, is located on the plasma membrane and the flagellar pocket. Hence, each isoform is differentially sorted, and the structural information for targeting each transporter isoform to its correct membrane address resides within the NH2-terminal hydrophilic domain.

Functional expression of two glucose transporter isoforms from the parasitic protozoan Leishmania enriettii.

The parasitic protozoan Leishmania enriettii contains a family of tandemly repeated genes, designated Pro-1, that encode proteins with significant sequence similarity to mammalian facilitative glucose transporters. Pro-1 mRNAs are expressed almost exclusively in the promastigote or insect stage of the parasite life cycle. The Pro-1 tandem repeat encodes two isoforms of the putative transporter, iso-1 and iso-2, which have identical predicted amino acid sequences except for their NH2-terminal hydrophilic domains. We have now expressed both iso-1 and iso-2 by microinjecting their RNAs into Xenopus oocytes and assaying these oocytes for transport of various radiolabeled ligands. Both iso-1 and iso-2 transport [3H]2-deoxy-D-glucose, confirming that each protein is a bona fide glucose transporter. Each isoform also transports fructose and, to a much lesser degree, mannose. Compounds which inhibit 2-deoxy-D-glucose transport in L. enriettii promastigotes also inhibit transport in the microinjected oocytes expressing each isoform, indicating that the substrate specificities and pharmacological properties of each isoform are similar to those measured for 2-deoxy-D-glucose transport in intact parasites. The Km for transport of 2-deoxyglucose in oocytes expressing iso-1 is similar to that for oocytes expressing iso-2. These results reveal that both transporter isoforms have closely related functional properties and that the difference in their structures may serve some other purpose such as differential subcellular localization.