Separation and analysis of G protein gamma subunits

Proteomic analysis of bovine brain G protein gamma subunit processing heterogeneity

We characterized the variable processing of the G protein gamma subunit isoforms associated with bovine brain G proteins, a primary mediator of cellular communication. Ggamma subunits were isolated from purified brain G proteins and characterized by Edman sequencing, by MALDI MS, by chemical and/or enzymatic fragmentation assayed by MALDI MS, and by MS/MS fragmentation and sequencing. Multiple forms of six different Ggamma isoforms were detected. Significant variation in processing was found at both the amino termini and particularly the carboxyl termini of the proteins. All Ggamma isoforms contain a carboxyl-terminal CAAX motif for prenylation, carboxyl-terminal proteolysis, and carboxymethylation. Characterization of these proteins indicates significant variability in the normal processing of all of these steps in the prenylation reaction, including a new variation of prenyl processing resulting from cysteinylation of the carboxyl terminus. These results have multiple implications for intracellular signaling mechanisms by G proteins, for the role of prenyl processing variation in cell signaling, and for the site of action and consequences of drugs that target the prenylation modification.

Genomic analysis of G protein gamma subunits in human and mouse - the relationship between conserved gene structure and G protein betagamma dimer formation

Analysis of the genomic sequences, cDNAs and expressed sequence tags (ESTs) in human and mouse for the 12 genes of the gamma subunits of the heterotrimeric G proteins has allowed us to identify the common versus unique elements of the organization and expression of the members of this important gene family. All of the G protein gamma subunit genes are organized around two coding exons, each containing about 100 nucleotides coding for 30-40 amino acids. These two exons each correspond to a functional domain of the protein, which interestingly appears to impose constraints on both the structure of the protein and the structure of the gene. There is large variation in the intron size between these two coding exons, the number and size of 5' and 3' UTRs, and the overall size of the genes. There is general but not absolute conservation in the size and structure of these genes between humans and mice. Alternative splicing and potential differential promoter usage were detected for several Ggamma subunits, indicating possible differential regulation in expression. Only for Ggamma10, however, did we find an alternative coding transcript. This alternative transcript appears to code for a hybrid protein containing a DnaJ domain in place of its Ggamma exon 1 domain, joined to the Ggamma10 second exon domain. The predicted mRNA is expressed in humans, and the protein coded by it is readily translated in vitro. This protein does not form a functional G protein betagamma dimer, but it could generate a chaperone-like protein related to its DNA-J domain. These studies suggest that alternative splicing is not a prominent mechanism for generating G protein subunit diversity from within the human or mouse genomes. Instead, each of the known 12 gamma subunit genes generate transcripts with one prevalent protein.

Gamma 2 subunit of G protein heterotrimer is an N-end rule ubiquitylation substrate

Heterotrimeric G proteins transduce signals from activated transmembrane G protein-coupled receptors to appropriate downstream effectors within cells. Signaling specificity is achieved in part by the specific alpha, beta, and gamma subunits that compose a given heterotrimer. Additional structural and functional diversity in these subunits is generated at the level of posttranslational modification, offering alternate regulatory mechanisms for G protein signaling. Presented here is the identification of a variant of the gamma(2) subunit of G protein heterotrimer purified from bovine brain and the demonstration that this RDTASIA gamma(2) variant, containing unique amino acid sequence at its N terminus, is a substrate for ubiquitylation and degradation via the N-end rule pathway. Although N-end-dependent degradation has been shown to have important functions in peptide import, chromosome segregation, angiogenesis, and cardiovascular development, the identification of cellular substrates in mammalian systems has remained elusive. The isolation of RDTASIA gamma(2) from a native tissue represents identification of a mammalian N-end rule substrate from a physiological source, and elucidates a mechanism for the targeting of G protein gamma subunits for ubiquitylation and degradation.

Identification of a region in G protein gamma subunits conserved across species but hypervariable among subunit isoforms

The heterotrimeric GTP binding proteins, G proteins, consist of three distinct subunits: alpha, beta, and gamma. There are 12 known mammalian gamma subunit genes whose products are the smallest and most variable of the G protein subunits. Sequencing of the bovine brain gamma(10) protein by electrospray mass spectrometry revealed that it differs from the human protein by an Ala to Val substitution near the N-terminus. Comparison of gamma isoform subunit sequences indicated that they vary substantially more at the N-terminus than at other parts of the protein. Thus, species variation of this region might reflect the lack of conservation of a functionally unimportant part of the protein. Analysis of 38 gamma subunit sequences from four different species shows that the N-terminus of a given gamma subunit isoform is as conserved between different species as any other part of the protein, including highly conserved regions. These data suggest that the N-terminus of gamma is a functionally important part of the protein exhibiting substantial isoform-specific variation.