Inhibition of the 26S proteasome induces expression of GLCLC, the catalytic subunit for gamma-glutamylcysteine synthetase.

The majority of short- and long-lived cellular proteins are degraded by the activities of the 26S proteasome, a large multi-catalytic protease. Its unique function places it as a central regulatory activity for many important physiological processes. Lactacystin is a very specific 26S proteasome inhibitor and represents an excellent tool for demonstrating that a pathway exhibits proteasome-dependent biochemical regulation. Exposure of HepG2 cells to lactacystin resulted in robust elevation of GLCLC mRNA levels, followed by an increase in GSH concentrations. GLCLC is the gene that encodes the catalytic subunit for gamma-glutamylcysteine synthetase, the rate-limiting enzyme for the synthesis of glutathione (GSH). Inhibition of non-proteasome, protease activities did not induce GLCLC. Gel mobility shift assays and expression of CAT activity from heterologous reporter vectors identified Nrf2 mediation of the GLCLC antioxidant response element, ARE4, as the mechanism by which lactacystin induced GLCLC. These studies have identified 26S proteasome activity as a central regulatory pathway for glutathione synthesis.

Multi-faceted regulation of gamma-glutamylcysteine synthetase.

Glutathione is an important antioxidant that is involved in numerous cellular activities. gamma-Glutamylcysteine synthetase (gammaGCS) is a key regulatory enzyme in the synthesis of glutathione. It is a heterodimeric zinc metalloprotein that belongs to a unique class of proteins that gain activity due to formation of a reversible disulfide bond. The two subunits of gammaGCS exhibit differential and coordinate transcription regulation. In addition, the subunits are regulated at the posttranscriptional and posttranslational levels. These various levels of regulation allow numerous stimuli to induce or inhibit activity.

The heterogeneous nuclear ribonucleoprotein C protein tetramer binds U1, U2, and U6 snRNAs through its high affinity RNA binding domain (the bZIP-like motif).

Based on UV cross-linking experiments, it has been reported that the C protein tetramer of 40 S heterogeneous nuclear ribonucleoprotein complexes specifically interacts with stem-loop I of U2 small nuclear RNA (snRNA) (Temsamani, J., and Pederson, T. (1996) J. Biol. Chem. 271, 24922-24926), that C protein disrupts U4:U6 snRNA complexes (Forne, T., Rossi, F., Labourier, E., Antoine, E., Cathala, G., Brunel, C., and Tazi, J. (1995) J. Biol. Chem. 270, 16476-16481), that U6 snRNA may modulate C protein phosphorylation (Mayrand, S. H., Fung, P. A., and Pederson, T. (1996) Mol. Cell. Biol. 16, 1241-1246), and that hyperphosphorylated C protein lacks pre-mRNA binding activity. These findings suggest that snRNA-C protein interactions may function to recruit snRNA to, or displace C protein from, splice junctions. In this study, both equilibrium and non-equilibrium RNA binding assays reveal that purified native C protein binds U1, U2, and U6 snRNA with significant affinity ( approximately 7.5-50 nM) although nonspecifically. Competition binding assays reveal that U2 snRNA (the highest affinity snRNA substrate) is ineffective in C protein displacement from branch-point/splice junctions or as a competitor of C protein's self-cooperative RNA binding mode. Additionally, C protein binds snRNA through its high affinity bZLM and mutations in the RNA recognition motif at suggested RNA binding sites primarily affect protein oligomerization.

Oligonucleotide binding specificities of the hnRNP C protein tetramer.

Through the use of various non-equilibrium RNA binding techniques, the C protein tetramer of mammalian40S hnRNP particles has been characterized previously as a poly(U) binding protein with specificity for the pyrimidine-rich sequences that often precede 3' intron-exon junctions. C protein has also been characterized as a sequence-independent RNA chaperonin that is distributed along nascent transcripts through cooperative binding and as a protein ruler that defines the length of RNA packaged in 40S monoparticles. In this study fluorescence spectroscopy was used to monitor C protein-oligonucleotide binding in a competition binding assay under equilibrium conditions. Twenty nucleotide substrates corresponding to polypyrimidine tracts from IVS1 of the adenovirus-2 major late transcript, the adenovirus-2 oncoprotein E1A 3' splice site, IVS2 of human alpha-tropomyosin, the consensus polypyrimidine tract for U2AF65, AUUUA repeats and r(U)20were used as competitors. A 20 nt beta-globin intronic sequence and a randomly generated oligo were used as competitor controls. These studies reveal that native C protein possesses no enhanced affinity for uridine-rich oligonucleotides, but they confirm the enhanced affinity of C protein for an oligonucleotide identified as a high affinity substrate through selection and amplification. Evidence that the affinity of C protein for the winner sequence is due primarily to its unique structure or to a unique context is seen in its retained substrate affinity when contiguous uridines are replaced with contiguous guanosines.

Expression of glutathione and gamma-glutamylcysteine synthetase mRNA is Jun dependent.

The gene GLCLC encodes the catalytic subunit of gamma-glutamylcysteine synthetase (glutamate-cysteine ligase E.C. 6.3.2.2), the rate limiting enzyme for glutathione synthesis. When HepG2 cells were exposed to the serine/threonine phosphatase inhibitor okadaic acid (OA), increased expression of GLCLC was observed, as was the development of resistance to xenobiotic induced GSH depletion. Okadaic acid is known to activate both NF-kappaB and AP-1 activity. Inhibition of NF-kappaB activity by overexpression of an IkappaB alpha transdominant inhibitor or exposure to the protease inhibitor TLCK did not inhibit the OA mediated increase in GLCLC transcripts. Fibroblasts derived from a mouse containing a c-Jun null mutation exhibited diminished AP-1 binding activity, reduced levels of GLCLC message, and a correspondingly low GSH concentration compared to wild type cells. When the null cells, which express Jun B and Jun D, were exposed to OA, AP-1 binding activity increased, as did expression of GLCLC message. These results indicate that AP-1 transcription factors participate in the regulation of glutathione metabolism.

A major determinant of hnRNP C protein binding to RNA is a novel bZIP-like RNA binding domain.

The C protein tetramer of hnRNP complexes binds approximately 150-230 nt of RNA with high cooperativity (McAfee J et al., 1996, Biochemistry 35:1212-1222). Three contiguously bound tetramers fold 700-nt lengths of RNA into a 19S triangular intermediate that nucleates 40S hnRNP assembly in vitro (Huang M et al., 1994, Mol Cell Biol 14:518-533). Although it has been assumed that the consensus RNA recognition motif (RRM) of C protein (residues 8-87) is the primary determinant of RNA binding, we report here that a recombinant construct containing residues 1-115 has very low affinity for RNA at physiological ionic strength (100 mM NaCl). Moreover, we demonstrate that an N-terminal deletion construct lacking the consensus RRM but containing residues 140-290 binds RNA with an affinity sufficient to account for the total free energy change observed for the binding of intact protein. Like native C protein, the 140-290 construct is a tetramer in solution and binds RNA stoichiometrically in a salt-resistant manner in 100-300 mM NaCl. Residues 140-179 of the N-terminal truncated variant contain 11 basic and 2 acidic residues, whereas residues 180-207 specify a leucine zipper motif that directs dimer assembly. Elements within the 50-residue carboxy terminus of C protein are required for tetramer assembly. A basic region followed by a leucine zipper is identical to the domain organization of the basic-leucine zipper (bZIP) class of DNA binding proteins. Sequence homologies with other proteins containing RRMs and the bZIP motif suggest that residues 140-207 represent a conserved bZIP-like RNA binding motif (designated bZLM). The steric orientation of four high-affinity RNA binding sites about rigid leucine zipper domains may explain in part C protein's asymmetry, its large occluded site size, and its RNA folding activity.

Proteins C1 and C2 of heterogeneous nuclear ribonucleoprotein complexes bind RNA in a highly cooperative fashion: support for their contiguous deposition on pre-mRNA during transcription.

Proteins C1 and C2 together comprise about one-third the protein mass of mammalian core 40S heterogeneous nuclear ribonucleoprotein particles (40S hnRNP) and exist as heterotetramers of (C1)3C2. On the basis of nonequilibrium binding studies, it has been suggested that the C proteins specifically bind oligo(U)- and poly(U)-rich sequences, and preferentially associate with uridine-rich regions near the 3' termini of many introns. We describe here a more quantitative characterization of the equilibrium binding properties of native and recombinant C protein to homoribopolymers using fluorescence spectroscopy. Like C protein from HeLa cells, the recombinant proteins spontaneously oligomerize to form tetramers with the same hydrodynamic properties as native protein. Near-stoichiometric binding titrations of the fluorescent homoribopolymer polyethenoadenosine (poly[r(epsilon A)]) with recombinant (C1)4 and (C2)4 homotetramers along with competition binding assays with poly(A) and poly(C) indicate that the binding site size (n) is between 150 and 230 nucleotides. This site size range is in close agreement with that previously determined for native C protein through hydrodynamic and ultrastructural studies (approximately 230 nucleotides). (C1)4 and (C2)4 bind poly(G) with intrinsic affinities (Ki) of 10(9) M-1, which are a hundredfold higher than their affinities for poly(U). In opposition to reports that C protein does not bind poly(A) and poly(C), we find that the C proteins bind these substrates with moderate Ki, but with high cooperativity (omega). The overall affinity (K omega) for the binding of both proteins to poly(A) and poly(C) is 10-fold higher (> 10(8) but < 10(9) M-1) than their affinities for poly(U). The highly cooperative binding of C protein to these substrates provides a mechanistic basis for the distribution of C protein along the length of nucleic acid substrates.