Tethering Domain Research Articles

Molecular Characterization of a cDNA That Encodes Six Isoforms of a Novel Murine A Kinase Anchor Protein

We have cloned cDNA that encodes six novel A kinase anchor proteins (collectively named AKAP-KL). AKAP-KL diversity is generated by alternative mRNA splicing and utilization of two translation initiation codons. AKAP-KL polypeptides are evident in lung, kidney, and cerebellum, but are absent from many tissues. Different isoforms predominate in different tissues. Thus, AKAP-KL expression is differentially regulated in vivo. All AKAP-KL isoforms contain a 20-residue domain that avidly binds (Kd approximately 10 nM) regulatory subunits (RII) of protein kinase AII and is highly homologous with the RII tethering site in neuronal AKAP75. The distribution of AKAP-KL is strikingly asymmetric (polarized) in situ. Anchor protein accumulates near the inner, apical surface of highly polarized epithelium in tubules of nephrons. Both RII and AKAP-KL are enriched at an intracellular site that lies just below the plasma membrane of alveolar epithelial cells in lung. AKAP-KL interacts with and modulates the structure of the actin cytoskeleton in transfected cells. We also demonstrate that the tethering domain of AKAP-KL avidly ligates RII subunits in intact cells. AKAP-KL may be involved in (a) establishing polarity in signaling systems and (b) physically and functionally integrating PKAII isoforms with downstream effectors to capture, amplify, and precisely focus diffuse, trans-cellular signals carried by cAMP.

Proteolysis That Is Inhibited by Hedgehog Targets Cubitus interruptus Protein to the Nucleus and Converts It to a Repressor

Cell–cell communication at anterior/posterior compartment borders in Drosophila involves Hedgehog (Hh), a protein secreted by posterior cells, and Cubitus interruptus (Ci), a protein in the Hh response pathway in anterior cells. Although Ci is thought to have roles as a transcription factor repressing hh expression and activating target genes, it localizes in the cytoplasm of anterior cells. We report here the identification of a domain that tethers Ci in the cytoplasm and show that in some anterior cells, Ci is cleaved to generate a form that lacks the tethering domain. This form translocates to the nucleus where it represses hh and other target genes. Hh inhibits proteolysis of Ci, and we suggest that this inhibition leads to the observed patterns of expression of key target genes at the compartment border.

Functional dissection of a human Dr1-DRAP1 repressor complex.

The heterotetrameric Dr1-DRAP1 transcriptional repressor complex was functionally dissected. Dr1 was found to contain two domains required for repression of transcription. The tethering domain interacts with the TATA box binding protein and directs the repressor complex to the promoter. This tethering domain can be replaced by a domain conferring sequence-specific recognition to the repressor complex. In the absence of the tethering domain, Dr1 interacts with its corepressor DRAP1, but this interaction is not functional. The enhancement of Dr1-mediated repression of transcription by DRAP1 requires the tethering domain. The second domain of Dr1 is the repression domain, which is glutamine-alanine rich. A 65-amino-acid polypeptide containing the repression domain fused to the Ga14 DNA binding domain repressed transcription when directed to TATA-containing and TATA-less promoters. This repression domain was also found to functionally and directly interact with the TATA box binding protein.

Characterization of distinct tethering and intracellular targeting domains in AKAP75, a protein that links cAMP-dependent protein kinase II beta to the cytoskeleton

Cyclic AMP-dependent protein kinase II beta (PKAII beta) is the principal mediator of cAMP action in neurons. A Kinase Anchor Proteins (AKAPs) are enriched in forebrain neurons and have distinct high affinity binding domains for the regulatory subunit (RII beta) of PKAII beta and components of the dendritic cytoskeleton. The selective accumulation of AKAP.RII beta complexes near dendritic microtubules tethers PKAII beta in proximity with adenylate cyclase in the synaptic plasma membrane and cytoskeletal proteins that are substrates for the kinase, thereby creating intraneuronal target sites for signals carried by cAMP. We have characterized the targeting (anchoring) and tethering (RII beta binding) domains of a prototypic anchor protein AKAP75. Deletion of N-terminal residues 27-48 generated a truncated RII beta-binding protein that partitions equally between the cytosol and detergent-insoluble fractions of HEK293 cells. Further removal of a non-adjacent sequence (residues 77-91) produced a cytosolic protein with unimpaired RII beta binding activity. Thus, two noncontiguous domains mediate the intracellular localization of AKAP75. Boundaries for the RII beta tethering domain were mapped to residues 392-413 by scanning mutagenesis. Residues containing long aliphatic side chains are essential for the high affinity binding of RII beta by AKAP75. Contributions of hydrophobic amino acids to tethering activity also depend on the position of the residue in the sequence. Certain conservative mutations that should not alter significantly the overall hydrophobicity or helicity of the tethering region (e.g. replacement of Leu with Ala) diminish the RII beta binding activity of AKAP75.