Profiling phospho-signaling networks in breast cancer using reverse-phase protein arrays.

Measuring the states of cell signaling pathways in tumor samples promises to advance the understanding of oncogenesis and identify response biomarkers. Here, we describe the use of Reverse Phase Protein Arrays (RPPAs or RPLAs) to profile signaling proteins in 56 breast cancers and matched normal tissue. In RPPAs, hundreds to thousands of lysates are arrayed in dense regular grids and each grid is probed with a different antibody (100 in the current work, of which 71 yielded strong signals with breast tissue). Although RPPA technology is quite widely used, measuring changes in phosphorylation reflective of protein activation remains challenging. Using repeat deposition and well-validated antibodies, we show that diverse patterns of phosphorylation can be monitored in tumor samples and changes mapped onto signaling networks in a coherent fashion. The patterns are consistent with biomarker-based classification of breast cancers and known mechanisms of oncogenesis. We explore in detail one tumor-associated pattern that involves changes in the abundance of the Axl receptor tyrosine kinase (RTK) and phosphorylation of the cMet RTK. Both cMet and Axl have been implicated in breast cancer, or in resistance to anticancer drugs, but the two RTKs are not known to be linked functionally. Protein depletion and overexpression studies in a 'triple-negative' breast cell line reveal cross talk between Axl and cMet involving Axl-mediated modification of cMet, a requirement for cMet in efficient and timely signal transduction by the Axl ligand Gas6 and the potential for the two receptors to interact physically. These findings have potential therapeutic implications, as they imply that bi-specific receptor inhibitors (for example, ATP-competitive small-kinase inhibitors such as GSK1363089, BMS-777607 or MP470) may be more efficacious than the mono-specific therapeutic antibodies currently in development (for example, Onartuzumab).

Chemical genomics: what will it take and who gets to play?

Chemical genomics requires continued advances in combinatorial chemistry, protein biochemistry, miniaturization, automation, and global profiling technology. Although innovation in each of these areas can come from individual academic labs, it will require large, well-funded centers to integrate these components and freely distribute both data and reagents.

Printing proteins as microarrays for high-throughput function determination.

Systematic efforts are currently under way to construct defined sets of cloned genes for high-throughput expression and purification of recombinant proteins. To facilitate subsequent studies of protein function, we have developed miniaturized assays that accommodate extremely low sample volumes and enable the rapid, simultaneous processing of thousands of proteins. A high-precision robot designed to manufacture complementary DNA microarrays was used to spot proteins onto chemically derivatized glass slides at extremely high spatial densities. The proteins attached covalently to the slide surface yet retained their ability to interact specifically with other proteins, or with small molecules, in solution. Three applications for protein microarrays were demonstrated: screening for protein-protein interactions, identifying the substrates of protein kinases, and identifying the protein targets of small molecules.

A small, thermostable, and monofunctional chorismate mutase from the archaeon Methanococcus jannaschii.

The gene for chorismate mutase (CM) from the archaeon Methanococcus jannaschii, an extreme thermophile, was subcloned and expressed in Escherichia coli. This gene, which belongs to the aroQ class of CMs, encodes a monofunctional enzyme (AroQf) able to complement the CM deficiency of an E. coli mutant strain. The purified protein follows Michaelis-Menten kinetics (kcat = 5.7 s-1 and Km = 41 microM at 30 degreesC) and displays pH-independent activity in the range of pH 5-9. Its activation parameters [Delta H = 16.2 kcal/mol, Delta S = -1. 7 cal/(mol.K)] are similar to those of another well characterized AroQ class CM, the mesophilic AroQp domain from E. coli. Like AroQp, the thermophilic CM is an alpha-helical dimer, but approximately 5 kcal/mol more stable than its mesophilic counterpart as judged from equilibrium denaturation studies. The possible origins of the thermostability of M. jannaschii AroQf, the smallest natural CM characterized to date, are discussed in light of available sequence and tertiary structural information.

UGA read-through artifacts--when popular gene expression systems need a pATCH.

pET and similar vectors are widely used for efficient gene expression in Escherichia coli and subsequent protein purification, often by means of a C-terminal histidine (His) tag. We found that the TGA translation termination signal following the His-tag sequence in pET constructs gives rise to a significant fraction of read-through protein extended by 21 amino acids. Mass spectrometry indicated that tryptophan is inserted at the UGA (opal) stop codon in the examined non-opal suppressor strains; no evidence for translational frameshifting was detected. We have shown that the problem of obtaining heterogeneous protein preparations can easily be corrected. Plasmid pATCH1 provides a replacement sequence for the inefficient stop signal and can be used to repair both pET vectors and existing pET-based expression constructs. Our observation illustrates the largely ignored fact that a UGA codon is the worst choice for proper translation termination in efficient overexpression vectors.

Exploring sequence constraints on an interhelical turn using in vivo selection for catalytic activity.

The role of interhelical turns in determining protein structure has been investigated previously in relatively simple four-helix-bundle proteins using combinatorial mutagenesis coupled with screening for functional variants. To assess the tolerance to sequence substitution of a short, interhelical turn in a larger, more complicated protein, we have exploited a more sensitive in vivo selection for catalytic activity. Randomization of three solvent-exposed turn residues in Escherichia coli chorismate mutase (Ala65, His66, and His67), followed by selection, indicated that >63% of tripeptides, including some with significantly altered backbone conformations, can functionally replace the native sequence. The increased sensitivity of the catalytic assay allowed optimal sequences to be distinguished from less appropriate ones, revealing a statistically significant preference for hydrophilic residues in solvent-exposed positions. It also enabled investigation of the extent to which either secondary structure or tertiary interactions influence substitution patterns. Randomization of an alpha-helical residue (Lys64), together with the adjacent solvent-exposed tripeptide, Ala65-His66-His67, showed that the secondary structure at position 64 does not limit the range of side chains allowed at this site. In contrast, randomization of a buried turn residue (Leu68), together with the same tripeptide, revealed an extremely strict requirement for hydrophobic aliphatic amino acids at this position. The strong constraint imposed by the tertiary interaction, in contrast to the weak influence of secondary structure, has important implications for protein design.

Redesigning enzyme topology by directed evolution.

Genetic selection was exploited in combination with structure-based design to transform an intimately entwined, dimeric chorismate mutase into a monomeric, four-helix-bundle protein with near native activity. Successful reengineering depended on choosing a thermostable starting protein, introducing point mutations that preferentially destabilize the wild-type dimer, and using directed evolution to optimize an inserted interhelical turn. Contrary to expectations based on studies of other four-helix-bundle proteins, only a small fraction of possible turn sequences (fewer than 0.05 percent) yielded well-behaved, monomeric, and highly active enzymes. Selection for catalytic function thus provides an efficient yet stringent method for rapidly assessing correctly folded polypeptides and may prove generally useful for protein design.

Probing enzyme quaternary structure by combinatorial mutagenesis and selection.

Genetic selection provides an effective way to obtain active catalysts from a diverse population of protein variants. We have used this tool to investigate the role of loop sequences in determining the quaternary structure of a domain-swapped enzyme. By inserting random loops of four to seven residues into a dimeric chorismate mutase and selecting for functional variants by genetic complementation, we have obtained and characterized both monomeric and hexameric enzymes that retain considerable catalytic activity. The low percentage of active proteins recovered from these selection experiments indicates that relatively few loop sequences permit a change in quaternary structure without affecting active site structure. The results of our experiments suggest further that protein stability can be an important driving force in the evolution of oligomeric proteins.

Hydrolytic antibodies: variations on a theme.

Comparison of four independently-derived hydrolytic antibodies reveals striking similarities in their active sites. A common structural motif appears to be induced when the immune system is challenged with antigens containing aryl phosphonate and phosphonamidate groups, and key variations on this 'theme' must account for the observed differences in catalytic efficacy and mechanism. The limited structural repertoire accessed through standard immunization procedures suggests that new approaches may be needed to produce antibody catalysis with enzyme-like efficiencies.

Cloning and analysis of a constitutive heat shock (cognate) protein 70 gene inducible by L-glutamine.

An intronless gene encoding a protein of 652 amino acid residues with an M(r) of 71,266, showing between 79% and 59% identity in nucleotide sequence with heat shock protein 70 (HSP 70) genes of Bremia lactucae (a parasitic Oomycete of lettuce) and a wide range of organisms that include humans, was isolated from the nonparasitic Oomycete Achlya klebsiana. While the gene appears to be constitutively expressed, L-glutamine augmented its expression particularly under conditions of nutritional stress. L-Glutamine enhanced the transcription of a 2.4-kilobase poly(A)+ RNA simultaneously in the same way as it elevated the cellular level of the HSP 70-like protein. A polyclonal antibody (affinity-purified) raised in rabbit against the purified monomeric (M(r) 120,000) form of an NAD-specific glutamate dehydrogenase (Yang, B., and LéJohn, H.B. (1994) J. Biol. Chem. 269, 4506-4512) immunoprecipitated the HSP 70-like protein, and it was used to study the kinetics of induction of this stress-related protein and the effect of proteinase inhibitors on its metabolism. By using as probes four partial length cDNA clones, nine overlapping DNA fragments of the organism's genome carrying the HSP 70-like protein gene were isolated from a genomic library. The nucleotide sequence of the gene, including its boundaries, was determined by using these genomic clones. The 5'-untranslated boundary of the gene displayed the classical nucleotide arrangement of heat shock elements as well as CCAAT and TATA box motifs. Within the coding region are the typical conserved amino acid heat shock protein signatures 1 and 2 at the predicted locations. By primer extension and S1 nuclease protection mapping system, we estimated that the gene is probably transcribed into a message of 2.2 kilobases.