Site-specific folate conjugation to a cytotoxic protein.

Conjugation to folic acid is known to enhance the uptake of molecules by human cells that over-produce folate receptors. Variants of bovine pancreatic ribonuclease (RNase A) that have attenuated affinity for the endogenous ribonuclease inhibitor protein (RI) are toxic to mammalian cells. Here, the random acylation of amino groups in wild-type RNase A with folic acid is shown to decrease its catalytic activity dramatically, presumably because of the alteration to a key active-site residue, Lys41. To effect site-specific coupling, N(δ)-bromoacetyl-N(α)-pteroyl-l-ornithine, which is a folate analogue with an electrophilic bromoacetamido group, was synthesized and used to S-alkylate Cys88 of the G88C variant of RNase A. The pendant folate moiety does not decrease enzymatic activity, enables RI-evasion, and endows toxicity for cancer cells that over-produce the folate receptor. These data reveal a propitious means for targeting proteins and other molecules to cancer cells.

20-kDa placental hGH-V has diminished diabetogenic and lactogenic activities compared with 22-kDa hGH-N while retaining antilipogenic activity.

Placental human growth hormone-variant (hGH-V) and pituitary human growth hormone-N (hGH-N) are of identical size (22 kDa) but differ in 13 residues scattered throughout the protein. Several isoforms of GH are produced by the hGH-N and hGH-V genes including a 20-kDa hGH-V resulting from a 45-bp deletion caused by the use of an alternative acceptor site within exon 3. To date, the biological properties of the 20-kDa GH-V have not been characterized in vivo. Using young male Wistar rats fed either chow or a high-fat (HF) diet for 4 wk postweaning, we investigated the effect of 7 days treatment with either 22-kDa hGH-N, 20-kDa hGH-V (5 ug x g(-1) x day(-1) sc), or vehicle on body composition and endocrine and metabolic profiles. Total body growth (absolute weight gain and linear growth trajectory) in the 20-kDa hGH-V-treated animals was intermediary between that of control and hGH-N-treated animals. Both 22-kDa hGH-N and 20-kDa hGH-V significantly reduced total body fat mass compared with control animals, and there were no differences between the GH isoforms in anti-lipogenic activity in animals fed the HF diet. Fasting plasma insulin and C peptide were significantly increased in animals on the HF diet and further increased by hGH-N but were unchanged in 20-kDa hGH-V-treated animals compared with saline-treated controls. Plasma volume as assessed by hematocrit was increased in hGH-N-treated animals but was unchanged in 20-kDa hGH-V-treated animals compared with controls. Furthermore, 20-kDa hGH-V had reduced lactogenic (prolactin receptor mediated) activity characteristic of hGH-N as tested in vitro compared with the 20-kDa hGH-N and 22-kDa hGH-N variants. In summary, placental 20-kDa hGH-V retains some of the growth-promoting and all antilipogenic activities of pituitary 22-kDa hGH-N but has diminished diabetogenic and lactogenic properties compared with the native 22-kDa hGH-N.

General method for site-specific protein immobilization by Staudinger ligation.

Protein microarrays are playing an increasingly important role in the discovery and characterization of protein-ligand interactions. The uniform orientation conferred by site-specific immobilization is a demonstrable advantage in using such microarrays. Here, we report on a general strategy for fabricating gold surfaces displaying a protein in a uniform orientation. An azido group was installed at the C-terminus of a model protein, bovine pancreatic ribonuclease, by using the method of expressed protein ligation and a synthetic bifunctional reagent. This azido protein was immobilized by Staudinger ligation to a phosphinothioester-displaying self-assembled monolayer on a gold surface. Immobilization proceeded rapidly and selectively via the azido group. The immobilized enzyme retained its catalytic activity and was able to bind to its natural ligand, the ribonuclease inhibitor protein. This strategy provides a general means to fabricate microarrays displaying proteins in a uniform orientation.

Inhibition of human pancreatic ribonuclease by the human ribonuclease inhibitor protein.

The ribonuclease inhibitor protein (RI) binds to members of the bovine pancreatic ribonuclease (RNase A) superfamily with an affinity in the femtomolar range. Here, we report on structural and energetic aspects of the interaction between human RI (hRI) and human pancreatic ribonuclease (RNase 1). The structure of the crystalline hRI x RNase 1 complex was determined at a resolution of 1.95 A, revealing the formation of 19 intermolecular hydrogen bonds involving 13 residues of RNase 1. In contrast, only nine such hydrogen bonds are apparent in the structure of the complex between porcine RI and RNase A. hRI, which is anionic, also appears to use its horseshoe-shaped structure to engender long-range Coulombic interactions with RNase 1, which is cationic. In accordance with the structural data, the hRI.RNase 1 complex was found to be extremely stable (t(1/2)=81 days; K(d)=2.9 x 10(-16) M). Site-directed mutagenesis experiments enabled the identification of two cationic residues in RNase 1, Arg39 and Arg91, that are especially important for both the formation and stability of the complex, and are thus termed "electrostatic targeting residues". Disturbing the electrostatic attraction between hRI and RNase 1 yielded a variant of RNase 1 that maintained ribonucleolytic activity and conformational stability but had a 2.8 x 10(3)-fold lower association rate for complex formation and 5.9 x 10(9)-fold lower affinity for hRI. This variant of RNase 1, which exhibits the largest decrease in RI affinity of any engineered ribonuclease, is also toxic to human erythroleukemia cells. Together, these results provide new insight into an unusual and important protein-protein interaction, and could expedite the development of human ribonucleases as chemotherapeutic agents.

Characterization of the tryptophan residues of human placental ribonuclease inhibitor and its complex with bovine pancreatic ribonuclease A by steady-state and time-resolved emission spectroscopy.

Human placental ribonuclease inhibitor (hRI) containing six tryptophan (Trp) residues located at positions 19, 261, 263, 318, 375, and 438 and its complex with RNase A have been studied using steady-state and time-resolved fluorescence (298 K) as well as low-temperature phosphorescence (77 K). Two Trp residues in wild-type hRI and also in the protein-protein complex with RNase A are resolved optically. The accessible surface area values of Trp residues in the wild-type hRI and its complex and consideration of inter-Trp energy transfer in the wild-type hRI reveal that one of the Trp residues is Trp19, which is located in a hydrophobic buried region. The other Trp residue is tentatively assigned as Trp375 based on experimental results on wild-type hRI and its complex. This residue in the wild-type hRI is more or less solvent exposed. Both the Trp residues are perturbed slightly on complex formation. Trp19 moves slightly toward a more hydrophobic region, and the environment of Trp375 becomes less solvent exposed. The complex formation also results in a more heterogeneous environment for both the optically resolved Trp residues.

Cloning and expression of two new prolactin-related proteins, prolactin-related protein-VIII and -IX, in bovine placenta.

BACKGROUND: Prolactin-related proteins (PRPs) are specific proteins of the growth hormone/prolactin (GH/PRL) family in bovine placenta. This study reports the identification and sequencing of a full-length cDNA for two new members of bovine PRPs, bPRP-VIII and -IX, and their localization and quantitative expression in bovine placenta. METHODS: New bPRP-VIII and -IX were identified from bovine placentome. Localization and quantitative gene expression in the placenta were respectively investigated by in situ hybridization and real-time RT-PCR methods. Recombinant proteins of these genes were produced by a mammalian HEK293 cell expression system. RESULTS: Full-length bPRP-VIII and -IX cDNA were respectively cloned with 909 and 910 nucleotide open-reading-frames corresponding to proteins of 236 and 238 amino acids. The predicted bPRP-VIII amino acid sequence shared about 40 to 70% homology with other bPRPs, and bPRP-IX had about 50 to 80% homology of others. The two new bPRPs were detected only in the placenta by RT-PCR. mRNA was primarily expressed in the cotyledon and intercotyledonary tissues throughout gestation. An in situ hybridization analysis revealed the presence of bPRP-VIII and -IX mRNA in the trophoblastic binucleate and/or trinucleate cells. bPRP-VIII mRNA was observed in the extra-embryonic membrane on Day 27 of gestation, however, no bPRP-IX mRNA was observed in the extra-embryonic membrane in the same stage of pregnancy by quantitative real-time RT-PCR analysis. Both new bPRP genes were possible to translate a mature protein in a mammalian cell expression system with approximately 28 kDa in bPRP-VIII and 38 kDa in bPRP-IX. CONCLUSION: We identified the new members of bovine prolactin-related protein, bPRP-VIII and -IX. Localization and quantitative expression were confirmed in bovine placenta by in situ hybridization or real-time PCR. Their different temporal and spatial expressions suggest a different role for these genes in bovine placenta during gestation.

Molecular recognition of human eosinophil-derived neurotoxin (RNase 2) by placental ribonuclease inhibitor.

Placental ribonuclease inhibitor (RI) binds diverse mammalian RNases with dissociation constants that are in the femtomolar range. Previous studies on the complexes of RI with RNase A and angiogenin revealed that RI utilises largely distinctive interactions to achieve high affinity for these two ligands. Here we report a 2.0 angstroms resolution crystal structure of RI in complex with a third ligand, eosinophil-derived neurotoxin (EDN), and a mutational analysis based on this structure. The RI-EDN interface is more extensive than those of the other two complexes and contains a considerably larger set of interactions. Few of the contacts present in the RI-angiogenin complex are replicated; the correspondence to the RI-RNase A complex is somewhat greater, but still modest. The energetic contributions of various interface regions differ strikingly from those in the earlier complexes. These findings provide insight into the structural basis for the unusual combination of high avidity and relaxed stringency that RI displays.

The structure of an engineered domain-swapped ribonuclease dimer and its implications for the evolution of proteins toward oligomerization.

BACKGROUND: Domain swapping has been proposed as a mechanism that explains the evolution from monomeric to oligomeric proteins. Bovine and human pancreatic ribonucleases are monomers with no biological properties other than their RNA cleavage ability. In contrast, the closely related bovine seminal ribonuclease is a natural domain-swapped dimer that has special biological properties, such as cytotoxicity to tumour cells. Several recombinant ribonuclease variants are domain-swapped dimers, but a structure of this kind has not yet been reported for the human enzyme. RESULTS: The crystal structure at 2 A resolution of an engineered ribonuclease variant called PM8 reveals a new kind of domain-swapped dimer, based on the change of N-terminal domains between the two subunits. The swapping is fastened at both hinge peptides by the newly introduced Gln101, involved in two intermolecular hydrogen bonds and in a stacking interaction between residues of different chains. Two antiparallel salt bridges and water-mediated hydrogen bonds complete a new interface between subunits, while the hinge loop becomes organized in a 3(10) helix structure. CONCLUSIONS: Proteins capable of domain swapping may quickly evolve toward an oligomeric form. As shown in the present structure, a single residue substitution reinforces the quaternary structure by forming an open interface. An evolutionary advantage derived from the new oligomeric state will fix the mutation and favour others, leading to a more extended complementary dimerization surface, until domain swapping is no longer necessary for dimer formation. The newly engineered swapped dimer reported here follows this hypothetical pathway for the rapid evolution of proteins.

Analysis of the interactions of human ribonuclease inhibitor with angiogenin and ribonuclease A by mutagenesis: importance of inhibitor residues inside versus outside the C-terminal "hot spot".

Ribonuclease inhibitor (RI) binds diverse mammalian RNases with extraordinary avidity. Here, we have investigated the structural basis for this tight binding and broad specificity by mutational analysis of the complexes of RI with angiogenin (Ang) and RNase A (K(D)=0.5 fM and 43 fM, respectively). Both crystal structures are known; the interfaces are large, and the ligands dock similarly, although few of the specific interactions formed are analogous. Our previous mutagenesis studies focused primarily on one contact region, containing RI 434-438 and the enzymatic active site. Many single-residue replacements produced extensive losses of binding energy (2.3-5.9 kcal/mol), suggesting that this region constitutes a "hot spot" in both cases. We have now explored the roles of most of the remaining RI residues that interact with Ang and/or RNase A. One major cluster in each complex lies in a Trp-rich area of RI, containing Trp261, Trp263, Trp318, and Trp375. Although the energy losses from individual replacements in this portion of the Ang complex were small-to-moderate (0-1.5 kcal/mol), the changes from multiple substitutions were much greater than additive, and the binding energy provided by this region is estimated to be approximately 6 kcal/mol (30 % of total). Effects of replacing combinations of hot spot components had also been found to be superadditive, and this negative cooperativity is now shown to extend to the neighboring contact residue RI Ser460. The overall contribution of the hot spot, taking superadditivity into account, is then approximately 14-15 kcal/mol. The hot spot and Trp-rich regions, although spatially well separated, are themselves functionally linked. No other parts of the RI-Ang interface appear to be energetically important. Binding of RNase A is more sensitive to substitutions throughout the interface, with free energy losses>/=1 kcal/mol produced by nearly all replacements examined, so that the sum of losses greatly exceeds the binding energy of the complex. This discrepancy can be explained, in part, by positive cooperativity, as evident from the subadditive effects observed when combinations of residues in either the hot spot or Trp-rich region are replaced. These findings suggest that the binding energy may be more widely distributed in the RNase A complex than in the Ang complex.

Superadditive and subadditive effects of "hot spot" mutations within the interfaces of placental ribonuclease inhibitor with angiogenin and ribonuclease A.

Previous single-site mutagenesis studies on the complexes of ribonuclease inhibitor (RI) with angiogenin (Ang) and RNase A suggested that in both cases a substantial fraction of the binding energy is concentrated within one small part of the crystallographically observed interface, involving RI residues 434-438. Such energetic "hot spots" are common in protein-protein complexes, but their physical meaning is generally unclear. Here we have investigated this question by examining the detailed interactions within the RI.ligand hot spots and the extent to which they function independently. The effects of Phe versus Ala substitutions show that the key residue Tyr434 interacts with both ligands primarily through its phenyl ring; for Tyr437, the OH group forms the important contacts with RNase A, whereas the phenyl group interacts with Ang. Kinetic characterization of complexes containing multiple substitutions reveals striking, but distinctive, cooperativity in the interactions of RI with the two ligands. The losses in binding energy for the RNase complex associated with replacements of Tyr434 and Asp435, and Tyr434 and Tyr437, are markedly less than additive (i.e., by 2.4 and 1.3 kcal/mol, respectively). In contrast, the energetic effects of the 434 and 435, and 434 and 437, substitution pairs on binding of Ang are fully additive and 2.5 kcal/mol beyond additive, respectively. Superadditivities (0.9-2.4 kcal/mol) are also observed for several multisite replacements involving these inhibitor residues and two Ang residues, Arg5 and Lys40, from this part of the interface. Consequently, the decreases in binding energy for some triple-variant complexes are as large as 8.5-10.1 kcal/mol (compared to a total DeltaG of -21.0 kcal/mol for the wild-type complex). Potential explanations for these functional couplings, many of which occur over distances of >13 A and are not mediated by direct or triangulated contacts, are proposed. These findings show that the basis for the generation of hot spots can be complex, and that these sites can assume significantly more (as with Ang) or less (as with RNase) importance than indicated from the effects of single-site mutations.

Molecular recognition of human angiogenin by placental ribonuclease inhibitor--an X-ray crystallographic study at 2.0 A resolution.

Human placental RNase inhibitor (hRI), a leucine-rich repeat protein, binds the blood vessel-inducing protein human angiogenin (Ang) with extraordinary affinity (Ki <1 fM). Here we report a 2.0 A resolution crystal structure for the hRI-Ang complex that, together with extensive mutagenesis data from earlier studies, reveals the molecular features of this tight interaction. The hRI-Ang binding interface is large and encompasses 26 residues from hRI and 24 from Ang, recruited from multiple domains of both proteins. However, a substantial fraction of the energetically important contacts involve only a single region of each: the C-terminal segment 434-460 of hRI and the ribonucleolytic active centre of Ang, most notably the catalytic residue Lys40. Although the overall docking of Ang resembles that observed for RNase A in the crystal structure of its complex with the porcine RNase inhibitor, the vast majority of the interactions in the two complexes are distinctive, indicating that the broad specificity of the inhibitor for pancreatic RNase superfamily proteins is based largely on its capacity to recognize features unique to each of them. The implications of these findings for the development of small, hRI-based inhibitors of Ang for therapeutic use are discussed.

Site-specific mutagenesis reveals differences in the structural bases for tight binding of RNase inhibitor to angiogenin and RNase A.

RNase inhibitor (RI) binds with extraordinary affinity (Ki approximately 10(-13)-10(-16) M) to diverse proteins in the pancreatic RNase superfamily. In the present study, the structural basis for the recognition of two RI ligands, human angiogenin (Ang) and bovine RNase A, has been investigated by site-specific mutagenesis of human RI and Ang. The RI residues examined were those that appear to form strong contacts with RNase A in the crystal structure of the porcine RI x RNase A complex [Kobe, B. & Deisenhofer, J. (1995) Nature (London) 374, 183-186] that would not be replicated in the Ang complex. Ala substitutions of five of these residues (Glu-287, Lys-320, Glu-401, Cys-408, and Arg-457) were found to have little or no effect on binding of RNase A. In contrast, replacements of Tyr-434, Asp-435, and Tyr-437 and deletion of the C-terminal residue Ser-460 substantially weakened affinity for RNase A: the losses of binding energy associated with the mutations were 5.9, 3.6, 2.6, and 3.5 kcal/mol, respectively. Thus these four residues, which are neighbors in the tertiary structure, appear to constitute a "hot spot" for the RNase A interaction. However, only one of them, Asp-435, was equally important for binding of Ang; the Ki increases produced by mutations of the others were 20- to 93-fold smaller for Ang than for RNase A. Consequently, Tyr-434 plays a significant but lesser role in the Ang complex, whereas Tyr-437 and Ser-460 make only minor contributions. Ala mutations of four Ang residues (His-8, Gln-12, Asn-68, and Glu-108) that correspond to RI contacts on RNase A produced no major changes in affinity for RI. These findings indicate that RI uses largely different interactions to achieve its extremely tight binding of RNase A and Ang.

Somatogenic and lactogenic activity of the recombinant 22 kDa isoform of human placental growth hormone.

During pregnancy, the human placenta secretes a variant of pituitary growth hormone (hGH-V) differing in sequence from the pituitary growth hormone (hGH-N) by 13 amino acids substitutions. HGH-V replaces hGH-N in the maternal bloodstream during the second half of pregnancy. HGH-V is produced in two, possibly three, isoforms: a 22 kDa form, a glycosylated 25 kDa form, and a probable 26 kDa form resulting from alternative splicing of the mRNA. Here we have studied the somatogenic and lactogenic activity of recombinant 22 kDa hGH-V isoform produced in Escherichia coli and compared it with the 22 kDa form of hGH-N. The two variants exert a similar somatogenic effect on rabbit and rat cells, but differ as regards their lactogenic activity in the rat.

Specificity of vascular endothelial cell growth factor receptor ligand binding domains.

Vascular endothelial cell growth factor binds with high affinity to FLT and KDR, two homologous tyrosine kinase receptors expressed on vascular endothelial cells. Placental growth factor, a vascular endothelial cell growth factor homologue, also binds with high affinity to the extracellular domains of FLT but not to the extracellular region of KDR. Vascular endothelial cell growth factor binds competitively with placental growth factor to the extracellular ligand binding domains of FLT, indicating that both ligands probably complex to overlapping or identical regions of this receptor.

Comparative aspects of placental lactogens: structure and function.

Removal of the pituitary from pregnant rats provided early evidence that the placenta was the source of prolactin-like bioactivity. After mid-pregnancy the placenta was able to support progesterone production by the corpus luteum (luteotrophic activity) and continued development of the mammary gland (mammotrophic activity). Three groups of mammals, the rodents, the ruminant artiodactyls and the primates are now known to produce from fetal placenta a remarkable variety of proteins which are related in structure to pituitary prolactin and growth hormone. Prolactin and growth hormone are themselves structurally related and are thought to have arisen from a common ancestral gene by gene duplication and evolutionary divergence. The receptors with which they interact also form a family of homologous proteins. Surprisingly the placental lactogens appear to have arisen more than once in evolution since in primates they are structurally closely related to growth hormone, while in rodents and ruminants they have closer similarity to prolactin. There is suggestive evidence that there may be specific receptors for placental lactogens in some fetal and maternal tissues. In humans a five-gene cluster on chromosome 17 contains two growth hormone (GH) and three placental lactogen (PL) genes. Two human PL genes encode identical proteins that are expressed in the placenta. One of the human GH genes is also placentally expressed. In mice, chromosome 13 carries the genes for mouse prolactin, for placental lactogen-I and -II (PL-I and PL-II) and for two other prolactin-related proteins, the proliferins. Rats also express PL-I and PL-II, together with at least three other placental prolactin-like proteins different from proliferins.(ABSTRACT TRUNCATED AT 250 WORDS)

Purification and biochemical characterization of recombinant human placental growth hormone produced in Escherichia coli.

The hGH-V (or hGH-2) gene codes for human placental growth hormone (hPGH). Secretion of hPGH is continuous, in contrast with the pulsed secretion of pituitary growth hormone (hGH) which it progressively replaces in the maternal bloodstream. hGH-V cDNA has previously been cloned and isolated. Analysis of its nucleotide sequence has revealed a 191-residue protein, hPGH, differing from hGH at 13 positions. The calculated pI is more basic than that of the pituitary hormone. Here we have inserted hGH-V cDNA into the pIN-III-ompA3 plasmid in order to produce hPGH in its native form in Escherichia coli D1210. Expression of hGH-V cDNA in E. coli is significantly lower than that of hGH cDNA with the same expression system. The hPGH produced in E. coli was purified in quantities sufficient to allow its biochemical and immunochemical characterization. The molecular mass of the protein was determined by electrospray m.s. The determined mass, 22,320 Da, agrees well with the molecular mass calculated from the translated cDNA sequence, assuming the presence of two disulphide bridges. Having established the technique for producing hPGH with a primary structure identical to the natural, non-glycosylated, 22 kDa isoform, we can now plan the full physicochemical and pharmaceutical characterization of this new hormonal entity.

Characterization and sequencing of rabbit, pig and mouse angiogenins: discernment of functionally important residues and regions.

Rabbit, pig and mouse angiogenins have been purified from blood serum and characterized, and the rabbit and pig proteins have been sequenced fully. A partial sequence of the mouse protein is consistent with the sequence deduced from the genomic DNA (Bond, M.D. and Vallee, B.L. (1990) Biochem. Biophys. Res. Commun. 171, 988-995). All three angiogenins are homologous to the pancreatic RNases and contain the essential catalytic residues His-13, Lys-40 and His-114, and the 6 half-cystines of the human protein. Like human angiogenin they display extremely low ribonucleolytic activities toward wheat-germ RNA, yeast RNA, poly(C) and poly(U). The rabbit and pig proteins induce neovascularization in vivo and also inhibit protein synthesis in vitro. The interaction of rabbit, pig and bovine angiogenins with placental ribonuclease inhibitor, a potent inhibitor of angiogenin, was examined by fluorescence spectroscopy. Rate and equilibrium binding constants indicate that rabbit angiogenin binds to the inhibitor much like human angiogenin, whereas the pig and bovine proteins show significant differences. A comparison of the five angiogenin sequences now available points to specific residues that are highly conserved among them but differ from the corresponding residues in the RNases. These residues are clustered in particular regions of the three-dimensional structure, two of which contribute to the angiogenic, second-messenger and/or protein synthesis inhibition activities of human angiogenin.