Cross-suppression of EGFR ligands amphiregulin and epiregulin and de-repression of FGFR3 signalling contribute to cetuximab resistance in wild-type KRAS tumour cells.

BACKGROUND: In addition to the mutational status of KRAS, the epidermal growth factor receptor (EGFR) ligands amphiregulin (AREG) and epiregulin (EREG) might function as bona fide biomarkers of cetuximab (Ctx) sensitivity for most EGFR-driven carcinomas. METHODS: Lentivirus-delivered small hairpin RNAs were employed to specifically reduce AREG or EREG gene expression in wild-type KRAS A431 squamous cell carcinoma cells. Colony-forming assays were used to monitor the impact of AREG and EREG knockdown on Ctx efficacy. Amphiregulin and EREG protein expression levels were assessed by quantitative ELISA in parental A431 cells and in pooled populations of A431 cells adapted to grow in the presence of Ctx. A phosphoproteomic platform was used to measure the relative level of phosphorylation of 42 distinct receptor tyrosine kinases before and after the acquisition of resistance to Ctx. RESULTS: Stable gene silencing of either ligand was found to notably reduce the expression of the other ligand. Parental A431 cells with normal expression levels of AREG/EREG exhibited significantly increased growth inhibition in response to Ctx, compared with derivatives that are engineered to produce minimal AREG/EREG. The parental A431 cells acutely treated with Ctx exhibited reduced basal expression levels of AREG/EREG. Pooled populations of Ctx-resistant A431 cells expressed significantly lower levels of AREG/EREG and were insensitive to the downregulatory effects of Ctx. Phosphoproteomic screen identified a remarkable hyperactivation of FGFR3 in Ctx-resistant A431 cells, which gained sensitivity to the cytotoxic and apoptotic effects of the FGFR3 TK inhibitor PD173074. The A431 parental cells acutely treated with Ctx rapidly activated FGFR3 and their concomitant exposure to Ctx and PD173074 resulted in synergistic apoptosis. CONCLUSION: Cross-suppression of AREG/EREG expression may explain the tight co-expression of AREG and EREG, as well as their tendency to be more highly expressed than other EGFR ligands to determine Ctx efficacy. The positive selection for Ctx-resistant tumour cells exhibiting AREG/EREG cross-suppression may have an important role in the emergence of Ctx resistance. As de-repression of FGFR3 activity rapidly replaces the loss of EGFR-ligand signalling in terms of cell proliferation and survival, combinations of Ctx and FGFR3-targeted drugs may be a valuable strategy to enhance the efficacy of single Ctx while preventing or delaying acquired resistance to Ctx.

Cloning, expression and purification of human epidermal growth factor using different expression systems.

Epidermal growth factor (EGF) is a protein that belongs to the family of growth factors that bind the ErbB receptors, which play a prominent role in the development of carcinomas. We had demonstrated that potato carboxypeptidase inhibitor (PCI) acts as an EGF antagonist. Because of the low affinity of PCI for the epidermal growth factor receptor, it was decided to design EGF mutants with PCI abilities. In order to achieve this we have first cloned, expressed and purified the native protein, EGF. Different expression systems with different locations of the recombinant protein were designed and a purification protocol was designed with those which allowed expression of EGF. Finally, the sample needed folding. Differences in the amount of EGF obtained and its activity were observed depending on the expression system used.

Classification of protein disulphide-bridge topologies.

The preferential occurrence of certain disulphide-bridge topologies in proteins has prompted us to design a method and a program, KNOT-MATCH, for their classification. The program has been applied to a database of proteins with less than 65% homology and more than two disulphide bridges. We have investigated whether there are topological preferences that can be used to group proteins and if these can be applied to gain insight into the structural or functional relationships among them. The classification has been performed by Density Search and Hierarchical Clustering Techniques, yielding thirteen main protein classes from the superimposition and clustering process. It is noteworthy that besides the disulphide bridges, regular secondary structures and loops frequently become correctly aligned. Although the lack of significant sequence similarity among some clustered proteins precludes the easy establishment of evolutionary relationships, the program permits us to find out important structural or functional residues upon the superimposition of two protein structures apparently unrelated. The derived classification can be very useful for finding relationships among proteins which would escape detection by current sequence or topology-based analytical algorithms.

Three-dimensional structure of human RNase 1 delta N7 at 1.9 A resolution.

Human pancreatic ribonuclease 1 (RNase 1) is considered to be the human counterpart of bovine pancreatic RNase A. Truncation of seven amino-acid residues from the amino-terminal sequence resulted in RNase 1 Delta N7, which has a reduced ribonucleolytic activity and a lower affinity for the human placental RNase inhibitor (PRI). This RNase 1 variant has been cloned, heterologously overexpressed, purified and crystallized. Its crystal structure has been determined and refined using data to 1.9 A resolution. The molecule displays the alpha + beta folding topology typical of members of the RNase A superfamily. The main distinct features found in RNase 1 Delta N7 are basically located in three loops affecting the fitting of the enzyme to the active site of subtilisin and the shape of the B2 subsite. These changes, taken with the lack of the catalytically active residue Lys7, may explain the reduced affinity of RNase 1 Delta N7 for PRI and the low ribonucleolytic activity of the protein when compared with the native enzyme.

Human pancreatic ribonuclease 1: expression and distribution in pancreatic adenocarcinoma.

BACKGROUND: Human pancreatic ribonuclease (RNase 1) is a pancreatic enzyme that is present at high levels in the serum of most patients with pancreatic adenocarcinoma. For this reason, the authors studied its patterns of expression at the single-cell level in pancreatic adenocarcinoma tissues by immunohistochemical analysis and in situ hybridization (ISH). METHODS: Immunohistochemical analysis with polyclonal antibodies against RNase 1 and by ISH with digoxigenin-labeled RNase 1 probe were used to detect RNase 1 in the neoplastic cells of ductal type pancreatic adenocarcinomas. RESULTS: Fifteen of 18 carcinoma samples were positive for RNase 1, demonstrating that the expression of ribonuclease that the authors observed previously in human pancreatic adenocarcinoma cell lines was not an artifact of cell culture. The authors also found RNase 1 in some of the metaplastic ducts and atrophic islets in 4 of 6 chronic pancreatitis samples, and they observed RNase 1 immunostaining in hyperplastic ducts adjacent to one of the well-differentiated adenocarcinomas. CONCLUSIONS: The expression levels of RNase 1 by tumor cells from pancreatic adenocarcinomas are consistent with the high RNase 1 levels found in the serum of most patients with pancreatic adenocarcinoma. This expression of RNase 1, which is an acinar protein, demonstrates that the patterns of gene expression in pancreatic adenocarcinoma are distinct from those of normal pancreatic duct cells. Conversely, RNase 1 expression levels in altered ductal cells from some chronic pancreatitis tissues and hyperplastic ducts from carcinoma tissues suggest that abnormal expression levels may be an early event in pancreatic tumorigenesis.

Three-dimensional crystal structure of human eosinophil cationic protein (RNase 3) at 1.75 A resolution.

Eosinophil cationic protein (ECP; RNase 3) is a human ribonuclease found only in eosinophil leukocytes that belongs to the RNase A superfamily. This enzyme is bactericidal, helminthotoxic and cytotoxic to mammalian cells and tissues. The protein has been cloned, heterologously overexpressed, purified and crystallized. Its crystal structure has been determined and refined using data up to 1. 75 A resolution. The molecule displays the alpha+beta folding topology typical for members of the ribonuclease A superfamily. The catalytic active site residues are conserved with respect to other ribonucleases of the superfamily but some differences appear at substrate recognition subsites, which may account, in part, for the low catalytic activity. Most strikingly, 19 surface-located arginine residues confer a strong basic character to the protein. The high concentration of positive charges and the particular orientation of the side-chains of these residues may also be related to the low activity of ECP as a ribonuclease and provides an explanation for its unique cytotoxic role through cell membrane disruption.

Ribonucleases expressed by human pancreatic adenocarcinoma cell lines.

Human ribonucleases have been considered as a possible tumor marker for pancreatic cancer, and elevated serum levels of ribonuclease activity in patients with pancreatic cancer have been reported by many authors. The reason for this elevation is unknown. In this study, we demonstrate that human pancreatic adenocarcinoma cell lines synthesize and secrete different ribonucleases. We isolated and characterized human pancreatic, or secretory, ribonuclease (RNase 1) from the conditioned media of the human pancreatic adenocarcinoma cell lines Capan-1, MDAPanc-3, IBF-CP3 and Panc-1, and the ampullary adenocarcinoma cell line MDAAmp-7, which represent a wide range of differentiation stages. Only one of these cell lines, Panc-1, produces significant amounts of nonsecretory ribonuclease. We then established a purification procedure for both secretory and nonsecretory ribonucleases, consisting of concentration of the supernatant by tangential filtration, anion-exchange and cation-exchange liquid chromatography and C4 RP-HPLC. Ribonuclease activity fractions were monitored using both the spectrophotometric and negative-staining zymogram techniques. The results of N-terminal sequence analysis, kinetic analysis and endoglycosidase digestion studies indicate that the main ribonuclease secreted by all the cell lines is the secretory-type ribonuclease and that it is composed of several differently N-glycosylated forms. Northern blot analyses confirm that some of the cell lines express secretory ribonuclease mRNA. The mRNA levels produced by Panc-1 and MDAPanc-28 are too low to be detected. Similar levels of expression of nonsecretory ribonuclease are found by Northern blot analysis in all the cell lines except Panc-1, which expresses higher levels. Here, we describe, for the first time, that several human pancreatic cancer cell lines with different degrees of differentiation express and secrete ribonucleases. This fact indicates that one origin of the elevated serum RNase levels in patients with pancreatic cancer are tumor cells. Analysis of the oligosaccharide moiety of the RNase 1 secreted by Capan-1 shows that it is highly glycosylated and its N-glycan chains are significantly different from that of the RNase 1 produced by normal pancreas. These results renew the possibility of using human serum RNase 1 determination as a tumor marker.

The three-dimensional structure of human RNase 4, unliganded and complexed with d(Up), reveals the basis for its uridine selectivity.

The RNase 4 family is unique among RNase enzymes, displaying the highest level of sequence similarity and encompassing the shortest polypeptide chain. It is the only one showing high specificity. The human representative is an intracellular and plasma enzyme, first isolated from colon adenocarcinoma cell line HT-29. The crystal structures of human recombinant RNase 4, unliganded and in complex with d(Up), have been determined, revealing in the unique active site an explanation for the uridine specificity. Arg101, at a position not involved in catalysis in the other RNase enzymes, penetrates the enzyme moiety shaping the recognition pocket, a flip that is mediated by the interaction with the (shorter chain) C-terminal carboxylate group, providing an anchoring point for the O4 atom of the substrate uridine. The bulky Phe42 side-chain forces Asp80 to be in the chi1=-72.49 degrees rotamer, accepting a hydrogen bond from Thr44, further converting the latter into a hydrogen bond acceptor. This favours an interaction with the -NH-donor group of uridine at position 3 over that with the =N-acceptor of cytidine. The two chemical groups that distinguish uracyl from cytosine are used by the enzyme to discriminate between these two bases.

Protein similarities beyond disulphide bridge topology.

Structural superimposition is an important procedure to analyse the relationships between proteins. A new approach and program, KNOT-MATCH, has been developed for automated structural superimposition of proteins by means of their disulphide bridge topology. As a result of the superimposition, regular secondary structures, loops and clusters of residues become correctly aligned. This fact allows us to find out important structural overlaps of residues, sometimes with functional significance, not only among proteins belonging to the same family but also between apparently non-related proteins. Different disulphide-rich protein families, such as EGF-like, defensin-like and plant protease inhibitors, have been self or cross analysed with this approach. Some amino acids that have been experimentally determined to be structural and/or functional key residues for these proteins are conserved in the three-dimensional space after superimposition by KNOT-MATCH. The program can be very useful for finding relationships among proteins that would be hidden to the current alignment methods based on sequence and on main-chain topology.

Potato carboxypeptidase inhibitor, a T-knot protein, is an epidermal growth factor antagonist that inhibits tumor cell growth.

Epidermal growth factor (EGF) and its receptor (EGFR) are involved in many aspects of the development of carcinomas, including tumor cell growth, vascularization, invasiveness, and metastasis. Because EGFR has been found to be overexpressed in many tumors of epithelial origin, it is a potential target for antitumor therapy. Here we report that potato carboxypeptidase inhibitor (PCI), a 39-amino acid protease inhibitor with three disulfide bridges, is an antagonist of human EGF. It competed with EGF for binding to EGFR and inhibited EGFR activation and cell proliferation induced by this growth factor. PCI suppressed the growth of several human pancreatic adenocarcinoma cell lines, both in vitro and in nude mice. PCI has a special disulfide scaffold called a T-knot that is also present in several growth factors including EGF and transforming growth factor alpha. PCI shows structural similarities with these factors, a fact that can explain the antagonistic effect of the former. This is the first reported example of an antagonistic analogue of human EGF.

Production of human pancreatic ribonuclease in Saccharomyces cerevisiae and Escherichia coli.

Human pancreatic ribonuclease (HP-RNase) has considerable promise as a therapeutic agent. Structure-function analyses of HP-RNase have been impeded by the difficulty of obtaining the enzyme from its host. Here, a gene encoding HP-RNase was designed, synthesized, and inserted into two expression vectors that then direct the production of HP-RNase in Saccharomyces cerevisiae (fused to either an unmodified or a modified a-factor pre-pro segment) or Escherichia coli (fused to the pelB signal sequence). HP-RNase produced in S. cerevisiae was secreted into the medium as an active enzyme, isolable at 0.1-0.2 mg/liter of culture. This isolate was heterogeneous due to extensive glycosylation and incomplete maturation of the pre-pro segment. HP-RNase produced in E. coli with the pET expression system was purified from the insoluble fraction of the cell lysate. Renaturation of the reduced and denatured protein produced active, homogeneous enzyme recoverable at 1 mg/liter of culture. The N terminus of the HP-RNase produced from the bacterial expression system was processed fully in vivo. The yeast system, combined with techniques that allow detection of picograms of ribonuclease activity, offers a sensitive probe for studies of post-translational modification and secretory targeting in eukaryotic cells. The bacterial system enables studies both to reveal new structure-function relationships in ribonucleases and to evaluate the use of HP-RNase as a cytotoxin that is tolerated by the human immune system.

Pancreatic adenocarcinoma cell line, MDAPanc-28, with features of both acinar and ductal cells.

CONCLUSION: We established a new human pancreatic adenocarcinoma cell line, MDAPanc-28. Studies on this new line indicate that it expressed both acinar and ductal gene products suggesting that the patterns of gene expression in the pancreatic adenocarcinoma from which this cell line arose have features similar to those of the protodifferentiated cells hypothesized by Rutter and his colleagues for the developing pancreas (1,2). BACKGROUND: The cell line arose from a tumor that, like most pancreatic adenocarcinomas, was ductal on the basis of its histological appearance. METHODS: Once the cell line was established in culture, they were subjected to cytogenetic analysis and tested for their ability to grow in nude mice. RNA from the cells was analyzed by Northern blot analysis and PCR of reverse transcribed cDNA for the expression of both acinar and duct cell gene products. DNA was analyzed for the presence of mutated K-ras at codon 12. RESULTS: The cell line expressed trypsin and ribonuclease RNA, which are considered to be acinar cell markers, and carbonic anhydrase II (CAII), which is considered to be a duct-cell markers. The histological appearance of xenografts in nude mice was similar to that of the tumor from which the cell line was established. The chromosome number varied between 46 and 60.

Crystal structure of ribonuclease A.d(ApTpApApG) complex. Direct evidence for extended substrate recognition.

The crystal structure of the complex between ribonuclease A and d(ApTpApApG) has been solved by x-ray crystallography using the molecular replacement method. The model includes, besides the enzyme, the d(ApTpApA) 5'-segment (A1T2A3A4) and 68 solvent molecules. The R-factor for the strongest 87% of the measured data that partially extends to 2.3-A resolution is 0.207. The A1 position is well defined; the 5'-O of the deoxyribose establishes a hydrogen bond with a solvent molecule that is, in turn, bonded to the epsilon-amino group of Lys66. The base (B0 site) is well ordered; it interacts with a symmetry-related enzyme molecule. In the crystal, the phosphate group at the p0 site has no direct charge compensation. However, Lys66 is not too far, and, in solution, it could bind to it. The T2 (R1B1p1) site is occupied as in other complex structures, and it is defined by very good electron density. The A3 site shows that the adenine moiety interacts with Asn71 and Gln69 and that the phosphate at p2 forms a salt bridge with Lys7. The most consistent model for the base of A4 (B3), both in terms of electron density and stereochemistry, shows that it forms a hydrogen bond with Gln69 and a g-g- array with the base at B2. The stacking of B2 and B3 may be a general feature of the binding of polyribonucleotides to ribonuclease A. The side chains of Gln69, Asn71, and Glu111 may thus constitute a malleable binding site capable of establishing various hydrogen bonds depending on the nature of the stacked bases. There is no evidence for the 3' G5 site in the electron density map.

Heterogeneity in the glycosylation pattern of human pancreatic ribonuclease.

Different molecular forms of ribonuclease were isolated from fresh human pancreas obtained from healthy transplant donors. The purification procedure consists of the preparation of an acetone powder, followed by (NH4)2SO4 precipitation and two chromatography steps (cationic exchange and reversed-phase). Protein bands in gel electrophoresis with RNAase activity were monitored using a negative-staining zymogram technique. Several glycosylated enzyme forms with apparent molecular masses ranging from 14 to 40 kDa were separated. Peptides containing the three Asn-Xaa-Thr/Ser acceptor sites for glycosylation were isolated and analysed. The site with Asn-34 was almost completely glycosylated, while the sites with Asn-76 and Asn-88 had carbohydrate in about half and a minor part of the molecules, respectively. The carbohydrate compositions of the glycopeptides are different from those of the same gene product isolated from human urine. C-Terminal threonine was present in part of the molecules, indicating partial degradation by carboxypeptidase.

A versatile negative-staining ribonuclease zymogram.

A versatile negative-staining ribonuclease zymogram is described. The method has several advantages as it combines, by means of different staining procedures, high resolving power, sensitivity, and specificity with a rapid, reproducible, and simultaneous analysis of purity of ribonuclease samples on the same polyacrylamide gel. Activity bands can be visualized at any time during the incubation process without staining of the gel. This allows the choice of different staining procedures after incubation. Using poly(C) as substrate less than 1 pg of bovine pancreatic ribonuclease A was detected in less than 2 h after the electrophoretic run. An additional advantage with respect to other methods is that no refrigeration is needed during electrophoresis.

Expression of acinar and ductal products in Capan-1 cells growing in synthetic serum and serum-free media.

BACKGROUND: Capan-1 is a human pancreatic adenocarcinoma cell line of presumed ductal origin. This is based on the histologic appearance of the tumor from which it arose. Yet considerable controversy exists regarding the actual cell of origin for these exocrine carcinomas. Two acinar antigens, ribonuclease and trypsin, were analyzed in cells growing in synthetic serum. METHODS: Capan-1 cells were adapted to grow in basal medium supplemented with synthetic serum, because fetal bovine serum (FBS) normally used to culture cells contains bovine ribonuclease, which can interfere with measurements of the ribonuclease secretion. These cells were also adapted to grow in different serum-free media, allowing us to determine its minimal growth requirements. The presence of ribonuclease in Capan-1 and PANC-1 conditioned media was monitored by activity. Other acinar and ductal markers were monitored using Northern blot analysis. RESULTS: Capan-1, PANC-1, IBF-CP3, and MDAAmp-7 cell lines were successfully adapted to grow in synthetic serum by means of the adaptation protocol reported here. The adaptation of Capan-1 to serum-free media showed that the cells are capable of growing in a medium containing insulin, transferrin, selenium, a nonprotein carrier, and lipoic and linoleic acids. Northern blot analysis showed the expression of carbonic anhydrase II, cytokeratin 18, ribonuclease, and trypsin in Capan-1 cells growing in FBS and synthetic serum. No changes in morphology, karyotype, or gene expression were observed in these cells as a result of the adaptation process. CONCLUSION: The cell line Capan-1 is expressing some ductal as well as acinar products despite its supposed ductal origin. The expression of trypsin at the mRNA level and ribonuclease at mRNA and protein levels is shown in Capan-1 cells. The protein expression will be further investigated as the cell line has been adapted to grow in synthetic serum and serum-free media with no apparent changes with respect to their growth in FBS.

Structure and function of ribonuclease A binding subsites.

Ribonuclease A binds nucleic acids through multiple electrostatic interactions between the phosphates of the polynucleotide and the positive groups (side chains of lysines and arginines) of the protein subsites. The bases only play a significant role in the binding at the active site. The active centre p1R1B1 sites determine the specificity of the catalytic cleavage. The phosphate-binding subsites p2 (Lys-7 and Arg-10), p1 (Lys-41, His-12 and His-119) and p0 (Lys-66) are essential for an effective catalysis and are conserved in all mammalian pancreatic ribonucleases. Additional phosphate-binding subsites confer further catalytic efficiency, probably by avoiding non-productive binding. The minimum chain size for optimum catalysis is probably longer than six or seven nucleotides. The full occupancy of binding sites by the long chain polynucleotides would explain the preference of the enzyme for these substrates. The multiplicity of binding subsites is responsible for the helix-destabilizing activity of ribonuclease A. Its capacity for destroying the secondary structure of single-stranded nucleic acids may be of importance for the complete hydrolysis of RNA in the digestive tract. A large variety of proteins, with very different structures and functions, interact with nucleic acids. An analysis of their binding properties shows that there is no general model for protein-nucleic acid interaction. However, the vast amount of work on the ribonuclease A binding subsites should serve as a model for the study of the binding properties of many other proteins that recognize nucleic acids.

Interference of the carbohydrate moiety in coomassie brilliant blue R-250 protein staining.

The binding of Coomassie Brilliant Blue R-250 to several species of bovine pancreatic ribonuclease is affected by the presence of a carbohydrate moiety in the enzyme molecule. Enzymic deglycosylation of several chromatographic fractions of ribonuclease, which have different degrees of glycosylation, results in increased staining by Coomassie Brilliant Blue R-250. Ovalbumin and other glycoproteins tested show similar behavior. The results indicate that carbohydrate moieties may represent a common hindrance to the binding of Coomassie Brilliant Blue dyes to glycoproteins.

Chemical and computer graphics studies on the topography of the ribonuclease A active site cleft. A model of the enzyme-pentanucleotide substrate complex.

The affinity labelling of bovine pancreatic ribonuclease A with 6-chloropurine 5' ribonucleotide allowed us to postulate the existence of a new phosphate-binding subsite, P2, adjacent to the main purine-binding subsite. The study of this reaction in greater detail together with the study of a complex of the enzyme with the pentanucleotide pApUpApApG by means of model building and computer graphics indicate that at least five phosphate groups of the RNA molecule can interact with five positive regions of the enzyme. In each one a lysine residue is present: Lys-104, -66, -41, -7 and -37 appear sequentially in the 5'----3' direction. The distance between each lysine is 0.7-0.8 nm, the same distance as that found between the phosphate groups on the RNA molecule. The study also enabled many amino acid residues of the enzyme to be described as forming part of, or being near, the different binding subsites.