Synthesis, biological activity and conformational analysis of cyclic GRF analogs

A novel cyclic GRF analog, cyclo(Asp8-Lys12)-[Asp8,Ala15]-GRF(1-29)-NH2, i.e. cyclo8,12[Asp8,Ala15]-GRF(1-29)-NH2, was synthesized by the solid phase procedure and found to retain significant biological activity. Solid phase cyclization of Asp8 to Lys12 proceeded rapidly (approximately 2 h) using the BOP reagent. Substitution of Ala2 with D-Ala2 and/or NH2-terminal replacement (desNH2-Tyr1 or N-MeTyr1) in the cyclo8,12[Asp8,Ala15]-GRF(1-29)-NH2 system resulted in highly potent analogs that were also active in vivo. Conformational analysis (circular dichroism and molecular dynamics calculations based on NOE-derived distance constraints) demonstrated that cyclo8,12[Asp8,Ala15]-GRF(1-29)-NH2 contains a long alpha-helical segment even in aqueous solution. A series of cyclo8,12 stereoisomers containing D-Asp8 and/or D-Lys12 were prepared and also found to be highly potent and to retain significant alpha-helical conformation. The high biological activity of cyclo8,12[N-MeTyr1,D-Ala2,Asp8,Ala15]-GRF(1-29)- NH2 may be explained on the basis of retention of a preferred bioactive conformation.     

In vitro stability of growth hormone releasing factor (GRF) analogs in porcine plasma.

The stability of growth-hormone releasing factor (growth regulating factor; GRF) analogs in porcine plasma was examined. GRF analogs were incubated in porcine plasma at 37 degrees C, extracted and subsequently analyzed using high performance liquid chromatography (HPLC). GRF(1-29)-NH2 was rapidly broken down in the plasma with a degradation rate of t1/2 = 13 min. The primary degradation product was identified as GRF(3-29)-NH2. Substitution of Gly15 by Ala15 slightly prolonged the plasma half-life (t1/2 = 17 min) and the major degradative fragment was found to be [Ala15]GRF(3-29)-NH2. The cleavage between the 2 and 3 position of the peptide was not inhibited by trasylol at a concentration of 1,000 KIU/ml but was dramatically reduced by the combined use of diprotin A and trasylol. Absence of the free amino group at the N-terminus and/or substitution of a D-amino acid residue at the penultimate position completely prevented cleavage between the 2 and 3 position in the structural linear GRF analogs. Side-chain to side-chain cyclization between Asp8 and Lys12 amino acid residues significantly improved the stability of GRF in plasma with t1/2 greater than 2 hr. An additional stability was provided by substitution of D-Ala2 for Ala2 in the structural cyclic analog. Cyclization between Lys21 and Asp25 also improved the stability of the GRF peptide in the plasma. Stability was further enhanced by the presence of D-Ala2 or by forming a dicyclic analog through an additional linkage between Asp8 and Lys12.     

A comparison of the biological activities of authentic rat GRF(1-43)OH with the analogue rat GRF(1-29)NH2

The purpose of this study was to characterize the biological activity of the synthetic rat growth hormone releasing factor analogue rGRF(1-29)NH2 and to compare its action on growth hormone (GH) release to that of authentic rGRF(1-43)OH. We first compared the concentration-response characteristics of the two peptides in static incubation, and then examined the reversibility and repeatability of the GH response in a perifusion system. Authentic rGRF(1-43)OH was significantly more potent in static incubation (EC50 = 3 x 10(-11) M) than the analogue (5 x 10(-11) M), whereas the reverse held true in perifusion. The shapes of the GH responses were similar for both peptides in the perifusion system. However, while the GH response to authentic rGRF was repeatable, the prior administration of rGRF(1-29)NH2 significantly reduced (greater than 50%) the GH response to the subsequent administration of either rGRF(1-29)NH2 or rGRF(1-43)OH. Thus authentic rGRF and the synthetic fragment may have different actions at the level of the GRF receptor or at a postreceptor (second messenger) step.     

Catabolism of rat growth hormone-releasing factor(1-29) amide in rat serum and liver.

Clinical and veterinary uses of growth hormone-releasing factor [GRF(1- 29)NH2] require the design of analogs that are resistant to proteolysis by serum and liver degrading enzymes. This study investigated rat GRF(1-29)NH2 processing in serum and liver homogenate by means of high pressure liquid chromatography (HPLC). Synthetic rGRF(1-29)NH2 (30 microM) was incubated (0-120 min, 37 degrees C) in serum (49 +/- 8 mg prot./ml). The rGRF(1-29)NH2 (10 microM) was also incubated (0-120 min, 37 degrees C) with liver homogenate (200 +/- 6 micrograms prot./ml). Time course studies of rGRF(1-29)NH2 disappearance showed apparent half-lives of 18 +/- 4 min and 13 +/- 3 min in serum and liver homogenate, respectively. This was accompanied by the appearance of degradation products that were all less hydrophobic than the native peptide. In the serum, two major metabolites were detected and isolated by preparative HPLC. Combined results of amino acid analysis, sequencing, and chromatography with synthetic homologs revealed the presence of rGRF(1-20)OH and (3-20)OH. A small amount of rGRF(12-29)NH2, coeluting with rGRF(3-20)OH, was also found by sequencing. In the liver, rGRF(1-18)OH, (3-18)OH, and (1-10)OH were identified. The peptide bond Ala2-Asp3 (DPP IV cleavage site) was hydrolyzed in both serum and liver. Other tissue-specific cleavage sites were Arg11-Arg12 and Arg20-Lys21 (trypsin-like cleavage site) in the serum, and Tyr10-Arg11 and Tyr18-Ala19 (chymotrypsin-like cleavage site) in the liver.(ABSTRACT TRUNCATED AT 250 WORDS)     

Comparison of the insulinotropic activity of glucagon-superfamily peptides in rat pancreas perfusion.

Previous studies have demonstrated that glucagon-superfamily peptides stimulate insulin release from the pancreatic islets in a glucose dependent manner. In this study we have carried out a structure-activity study of their insulinotropic activity using a rat pancreas perfusion with 5.5 mM glucose concentration. The following peptides were examined: glucagon-like peptide-1(7-36)amide (tGLP-1), glucagon, gastric inhibitory peptide (GIP), peptide having an amino-terminal histidine and carboxy-terminal isoleucine amide (PHI), vasoactive intestinal polypeptide (VIP), growth hormone releasing factor(1-29)amide (GRF), GRF(1-27)amide and synthetic hybrid-peptides of PHI-GRF, PHI(1-11)-GRF(12-27) and PHI(1-20)-GRF(21-27). Their potencies were evaluated as: tGLP-1 = GIP > glucagon > PHI = VIP > PHI(1-20)-GRF(21-27) > PHI(1-11)-GRF(12-27) > GRF(1-29) = GRF(1-27). It is clear that 0.1 nM tGLP-1 stimulated insulin release, whereas 1 microM GRF(1-29) did not. These results indicate that 1) in addition to N-terminal amino acid (histidine or tyrosine), position 4 (glycine), position 9 (aspartic acid) and position 11 (serine) in the amino acid sequence are important for their insulinotropic activity, 2) not only the N-terminal portion but also the C-terminal portion of these peptides contribute to their insulinotropic activity.     

Tryptic hydrolysis of hGH-RH(1-29)-NH2 analogues containing Lys or Orn in positions 12 and 21.

Two analogues of the 29 amino acid sequence of human growth hormone-releasing hormone, namely [Nle27]hGH-RH(1-29)-NH2 and [Orn(12,21),Nle27]hGH-RH(1-29)-NH2, have been synthesized and subjected to digestion by trypsin. The course of degradation was followed using RP-HPLC and ESI-MS. Several intermediates and final products of degradation were identified and conclusions regarding the rate of cleavages at different positions occupied by Lys and Arg residues were drawn. The analogue containing ornithine was found to be less susceptible to hydrolysis by trypsin: the 12-13 and 21-22 peptide bonds were completely resistant to the cleavage. The results show that by replacing Lys with Orn, a possibility exists to design new peptides, which could be more stable in biological fluids.     

Applications of BOP reagent in solid phase synthesis. Advantages of BOP reagent for difficult couplings exemplified by a synthesis of [Ala 15]-GRF(1-29)-NH2

The BOP reagent [benzotriazol-l-yl-oxy-tris-(dimethylamino)phosphonium hexa-fluorophosphate] introduced by Castro et al. [Tetrahedron Lett. (1975) 14, 1219-1222] is ideally suited for solid phase peptide synthesis. The rate of coupling using BOP compared favorably to DCC and other methods of activation including the symmetrical anhydride and DCC/HOBt procedures. BOP couplings using the solid phase procedure proceeded more rapidly and to a greater degree of completion for peptide bond formations that were previously determined to be very slow using the conventional DCC method. Stepwise solid phase peptide synthesis using BOP was successfully utilized for the preparation of the (22-29) and (13-29) fragments of [Ala15]-GRF(1-29)-NH2. Single couplings with 3 equiv. BOP and Boc-amino acids and 5.3 equiv. of diisopropylethylamine in DMF were used for each cycle. The yields of the fragments were superior and the purities comparable using the BOP procedure (single couplings) to those observed using multiple couplings via the DCC coupling method. A total synthesis of [Ala15]-GRF(1-29)-NH2 was also carried out using the BOP procedure (single couplings and 3 equiv. BOP and Boc-amino acids and 5.3 equiv. diisopropylethylamine in DMF for each cycle). Multiple couplings were only required for Boc-Asn-OH due to the proposed formation of Boc-aminosuccinimide during activation. The resultant GRF(1-29) analog was comparable to a control prepared with multiple DCC couplings under optimized conditions. In a parallel study, unprotected Boc-(hydroxy)-amino acids were successfully coupled with the BOP reagent. However, the number of coupling cycles after the introduction of unprotected hydroxy-amino acid must be minimal (less than 10). The use of the BOP reagent with unprotected Tyr in solid phase peptide synthesis was also clearly established.     

Amidation of growth hormone releasing factor (1-29) by serine carboxypeptidase catalysed transpeptidation

The applicability of serine carboxypeptidase catalysed transpeptidation reactions, using amino acid amides as nucleophiles, for C-terminal amidation of peptides has been investigated. With the aim of converting an unamidated precursor into GRF(1-29)-NH2, an interesting biologically active derivative of growth hormone releasing factor, a number of model reactions were initially investigated. In such a transpeptidation reaction, where the C-terminal amino acid is replaced by the amino acid amide, used as nucleophile, the C-terminal amino acid residue of the substrate can be chosen freely since it functions as leaving group and does not constitute part of the product. Since the C-terminal sequence of GRF(1-29)-NH2 is -Met-Ser-Arg-NH2 the model reactions Bz-Met-Ser-X-OH (X = Ala, Leu, Arg) + H-Arg-NH2----Bz-Met-Ser-Arg-NH2 + H-X-OH were first studied. With carboxypeptidase Y and X = Ala or Leu the amidated product could be obtained of 98% and 41%, respectively. With carboxypeptidase W-II and X = Arg a yield of no more than 72% could be obtained. The choice of Ala as leaving group in combination with carboxypeptidase Y therefore appeared optimal. With the longer peptide Bz-Leu-Gln-Asp-Ile-Met-Ser-Ala-OH the amidated product could be obtained in a yield of 78%, using carboxypeptidase Y, the only other product being Bz-Leu-Gln-Asp-Ile-Met-Ser-OH, formed due to the competing hydrolysis reaction. The full length peptide GRF(1-28)-Ala-OH was synthesized by the continuous flow polyamide solid-phase method.(ABSTRACT TRUNCATED AT 250 WORDS)     

Synthesis and biological activity of novel C-terminal-extended and biotinylated growth hormone-releasing factor (GRF) analogs.

A series of novel hGRF(1-29)-NH2 analogs were synthesized and biotinylated. The immunological and biological activities of these analogs were then characterized. To distance the biotin moiety from the putative bioactive core, a C-terminal spacer arm consisting of -Gly-Gly-Cys-NH2 (-GGC) was added to hGRF(1-29)-NH2 (hGRF29) and analogs, with subsequent biotinylation performed at the cysteine residue. Neither addition of the C-terminal spacer arm nor biotinylation affected affinity of these analogs for GRF antibody. Relative to hGRF(1-44)-NH2 (hGRF44: potency = 1.0), the biotinylated analogs were equipotent in vitro to their nonbiotinylated, parent compounds: [desNH2Tyr1,D-Ala2,Ala15]hGRF29-GGC-(tpBiocyt in)-NH2 (4.7) = [Ala15]hGRF29-GGC-(tpBiocytin)-NH2 (3.9) greater than hGRF29-GGC-(tpBiocytin)-NH2 (0.8). Based upon cumulative GH release data in vivo (0-60 min postinjection), [desNH2Tyr1,D-Ala2,Ala15]hGRF29-GGC-(tpBiocyt in)-NH2, [Ala15]hGRF29-GGC-(tpBiocytin)-NH2, and hGRF29-GGC-(tpBiocytin)-NH2 displayed 8.6, 5.5, and 0.8 times, respectively, the potency of hGRF44. These in vivo potency values were not significantly different from the corresponding parent compounds (i.e., with or without the C-terminal spacer arm). In summary, biotinylated hGRF analogs have been developed that retain full immunoreactivity and potent bioactivity (in vitro and in vivo), thus permitting their use in GRF receptor isolation, ELISA, and histochemical procedures.     

Kinetics of dipeptidyl peptidase IV proteolysis of growth hormone-releasing factor and analogs.

The kinetics and selectivity of proteolysis of synthetic human growth hormone-releasing factor and analogs by purified human placental dipeptidyl peptidase IV (DPP IV) were studied by HPLC. The initial rates of Ala2-Asp3 cleavage (pH 7.8, 37 degrees C, So = 0.15 mM) were all approx. 5 mumol min-1 mg-1 for the parent hormone, GRF(1-44)-NH2, and the fragments, GRF(1-29)-NH2 and GRF(1-20)-NH2. Lower activities observed for GRF(1-11)-OH, GRF(1-3)-OH, and cyclic lactam analogs indicate S1'-Sn' binding. Assays of [Trp6]-GRF(1-29)-NH2 versus [D-Trp6]-GFR(1-29)-NH2 indicate an S4' binding cavity. Peptides with D-configuration at P2, P1 or P1' and desNH2Tyr1 and N-MeTyr1 analogs of GRF were not cleaved. Catalytic parameters for the P1-substituted analogs [X2,Ala15]-GRF(1-29)-NH2 were found to vary with X as follows, Km: Abu less than Ala less than Pro less than Val less than Ser less than Gly much less than Leu; kcat: Pro greater than Ala greater than Abu greater than Ser greater than Gly much greater than Leu greater than Val; kcat/Km: Abu greater than Pro greater than Ala much greater than Ser greater than Gly = Val much greater than Leu. Km is at a minimum and kcat/Km at a maximum, for a hydrophobic P1 side-chain of about 0.25 nm in length, i.e., the ethyl side-chain of alpha-aminobutyric acid (Abu) is very close to optimal. These results further define the S1 selectivity of DPP IV and may be useful in the design of DPP IV resistant GRF analogs that can be produced by recombinant DNA methods and the design of DPP IV inhibitors.     

Secondary structure of the human growth hormone releasing factor (GRF 1-29) by two-dimensional 1H-nmr spectroscopy

The secondary structure of the human growth hormone releasing factor (GRF 1-29) in a solution mixture of 60% aqueous phosphate buffer:40% 2,2,2-trifluoroethanol-d₃ has been investigated by two-dimensional ¹H-nmr spectroscopy. Sequential resonance assignments and elements of secondary structure were obtained from phase-sensitive correlation spectroscopy, relayed coherence spectroscopy, and nuclear Overhauser spectroscopy experiments. The observation of a large number of α-amide and amide-amide interresidual nuclear Overhauser effect connectivities as well as the existence of 11 slowly exchanging amide protons indicates that the peptide adopts a well-defined secondary structure most likely constituted of a single long helix. This conclusion is consistent with the CD measurements.     

Synthesis, characterization, and pharmacokinetic studies of PEGylated glucagon-like peptide-1

Glucagon-like peptide-1-(7-36) (GLP-1) is a hormone derived from the proglucagon molecule, which is considered a highly desirable antidiabetic agent mainly due to its unique glucose-dependent stimulation of insulin secretion profiles. However, the development of a GLP-1-based pharmaceutical agent has a severe limitation due to its very short half-life in plasma, being primarily degraded by dipeptidyl peptidase IV (DPP-IV) enzyme. To overcome this limitation, in this article we propose a novel and potent DPP-IV-resistant form of a poly(ethylene glycol)-conjugated GLP-1 preparation and its pharmacokinetic evaluation in rats. Two series of mono-PEGylated GLP-1, (i) N-terminally modified PEG(2k)-N(ter)-GLP-1 and (ii) isomers of Lys(26), Lys(34) modified PEG(2k)-Lys-GLP-1, were prepared by using mPEG-aldehyde and mPEG-succinimidyl propionate, respectively. To determine the optimized condition for PEGylation, the reactions were monitored at different pH buffer and time intervals by RP-HPLC and MALDI-TOF-MS. The in vitro insulinotropic effect of PEG(2k)-Lys-GLP-1 showed comparable biological activity with native GLP-1 (P = 0.11) in stimulating insulin secretion in isolated rat pancreatic islet and was significantly more potent than the PEG(2k)-N(ter)-GLP-1 (P < 0.05) that showed a marked reduced potency. Furthermore, PEG(2k)-Lys-GLP-1 was clearly resistant to purified DPP-IV in buffer with 50-fold increased half-life compared to unmodified GLP-1. When PEG(2k)-Lys-GLP-1 was administered intravenously and subcutaneously into rats, PEGylation improved the half-life, which resulted in substantial improvement of the mean plasma residence time as a 16-fold increase for iv and a 3.2-fold increase for sc. These preliminary results suggest a site specifically mono-PEGylated GLP-1 greatly improved the pharmacological profiles; thus, we anticipated that it could serve as potential candidate as an antidiabetic agent for the treatment of non-insulin-dependent diabetes patients.     

High-resolution X-ray structure of the unexpectedly stable dimer of the [Lys(-2)-Arg(-1)-des(17-21)]endothelin-1 peptide

Previous structural studies on the [Lys((-2))-Arg((-1))]endothelin-1 peptide (KR-ET-1), 540-fold less potent than ET-1, strongly suggested the presence of an intramolecular Arg(-1)-Asp(8) (R(-1)-D(8)) salt bridge that was also observed in the shorter [Lys((-2))-Arg((-1))-des(17-21)]endothelin-1 derivative (KR-CSH-ET). In addition, for these two analogues, we have shown that the Lys-Arg dipeptide, which belongs to the prosequence, significantly improves the formation of the native disulfide bonds (>or=96% instead of approximately 70% for ET-1). In contrast to what was inferred from NMR data, molecular dynamics simulations suggested that such an intramolecular salt bridge would be unstable. The KR-CSH-ET peptide has now been crystallized at pH 5.0 and its high-resolution structure determined ab initio at 1.13 A using direct methods. Unexpectedly, KR-CSH-ET was shown to be a head-to-tail symmetric dimer, and the overall interface involves two intermolecular R(-1)-D(8) salt bridges, a two-stranded antiparallel beta-sheet, and hydrophobic contacts. Molecular dynamics simulations carried out on this dimer clearly showed that the two intermolecular salt bridges were in this case very stable. Sedimentation equilibrium experiments unambiguously confirmed that KR-ET-1 and KR-CSH-ET also exist as dimers in solution at pH 5.0. On the basis of the new dimeric structure, previous NMR data were reinterpreted. Structure calculations were performed using 484 intramolecular and 38 intermolecular NMR-derived constraints. The solution and the X-ray structures of the dimer are very similar (mean rmsd of 0.85 A). Since the KR dipeptide at the N-terminus of KR-CSH-ET is present in the prosequence, it can be hypothesized that similar intermolecular salt bridges could be involved in the in vivo formation of the native disulfide bonds of ET-1. Therefore, it appears to be likely that the prosequence does assist the ET-1 folding in a chaperone-like manner before successive cleavages that yield the bioactive ET-1 hormone.     

Control of AMPK-related kinases by USP9X and atypical Lys(29)/Lys(33)-linked polyubiquitin chains

AMPK (AMP-activated protein kinase)-related kinases regulate cell polarity as well as proliferation and are activated by the LKB1-tumour suppressor kinase. In the present study we demonstrate that the AMPK-related kinases, NUAK1 (AMPK-related kinase 5) and MARK4 (microtubule-affinity-regulating kinase 4), are polyubiquitinated in vivo and interact with the deubiquitinating enzyme USP9X (ubiquitin specific protease-9). Knockdown of USP9X increased polyubiquitination of NUAK1 and MARK4, whereas overexpression of USP9X inhibited ubiquitination. USP9X, catalysed the removal of polyubiquitin chains from wild-type NUAK1, but not from a non-USP9X-binding mutant. Topological analysis revealed that ubiquitin monomers attached to NUAK1 and MARK4 are linked by Lys(29) and/or Lys(33) rather than the more common Lys(48)/Lys(63). We find that AMPK and other AMPK-related kinases are also polyubiquitinated in cells. We identified non-USP9X-binding mutants of NUAK1 and MARK4 and find that these are hyper-ubiquitinated and not phosphorylated at their T-loop residue targeted by LKB1 when expressed in cells, suggesting that polyubiquitination may inhibit these enzymes. The results of the present study demonstrate that NUAK1 and MARK4 are substrates of USP9X and provide the first evidence that AMPK family kinases are regulated by unusual Lys(29)/Lys(33)-linked polyubiquitin chains.     

聚乙二醇定点修饰蛋白质药物的技术和临床研究进展

聚乙二醇(PEG)定点修饰蛋白药物是针对蛋白特定基团特定位点的修饰,相比于非定点随机修饰的特点是PEG修饰位点的单一与确定,避免了修饰异构体的干扰,能较好的保留药物体内外活性;修饰产物组成均一、性质稳定,便于质量控制,降低由修饰异构体引起的潜在的安全性风险,并很大程度上提高得率,降低成本。已有PEG定点修饰蛋白药物上市,还有部分处于临床试验阶段。本文综述了PEG定点修饰蛋白药物的技术研究与临床进展,包括PEG定点修饰剂、定点修饰方法、PEG定点修饰的上市和临床药物及面临的问题,并展望了PEG修饰技术未来的发展前景。     

Semisynthesis of human growth hormone-releasing factor by trypsin catalyzed coupling of leucine amide to a C-terminal acid precursor.

Human growth hormone-releasing factor, GRF(1-44)-NH2, was synthesized by trypsin catalyzed coupling of Leu-NH2 to Arg43 of the precursor, GRF(1-43)-OH, prepared by solid phase peptide synthesis. The semisynthetic GRF(1-44)-NH2 was fully characterized and showed full potency in the rat pituitary in vitro bioassay. Conversion to GRF(1-44)-NH2 was limited to 60-70% in both 75% v:v N,N'-dimethylacetamide and 95% v:v 1,4-butanediol due to competing transpeptidations at Arg41 and Arg38 generating [Leu42]-GRF(1-42)-NH2 and [Leu39]-GRF(1-39)-NH2 side-products, respectively. The rates of formation and yields of GRF(1-44)-NH2 versus pH, Leu-NH2 concentration, and solvent composition were also studied.     

In vitro release of growth hormone-releasing factor (GRF) from the hypothalamus: somatostatin inhibits GRF release.

The manner of release of growth hormone-releasing factor (GRF) from the rat hypothalamus was studied in a perifusion system using a highly sensitive radioimmunoassay for rat GRF. The recovery of GRF in this system was 50-60%. The release of GRF from the rat hypothalamic blocks was almost stable for 20-240 min after the start of the perifusion and was stimulated by depolarization induced by high K+ concentration. The release of GRF was inhibited by somatostatin at concentrations of 10(-11) to 10(-8) M with maximum inhibition to 52.5% of the basal release at a concentration of 10(-9) M. These results suggest that this system is useful in studying the regulatory mechanism of GRF release and that, in addition to its action on the pituitary, somatostatin appears to act at the level of the hypothalamus in inhibiting GRF release in the regulation of GH secretion.     

微球包裹pcDNA3-GRF（1-32）在小鼠肌肉组织的表达及对生长的影响

以乳酸-乙醇酸共聚物为载体,采用复乳液中蒸发法制备载生长激素释放因子（Growth hormone releasing factor,GRF）真核表达质粒pcDNA3-GRF（1-32）微球,其中包封率达69%,平均粒径为2.20μm,载药量80μg/mg,收率70%;体内转染小鼠肌肉组织, 提取注射部位肌肉组织DNA 和总RNA,经PCR和RT-PCR,发现注射pcDNA3-GRF（1-32）微球组的GRF表达水平最高（UVIBAND Version 99分析）,释放的GRF表达质粒在小鼠肌肉内存在并表达的时间至少30d。体重统计结果表明,30d后微球包裹质粒组累积增重与其它组相比差异极显著（P<0.01）,比裸质粒组、质粒和空白微球混合物组、生理盐水组分别高12.87%,19.72%,58.58%;结论认为,载pcDNA3-GRF（1-32）微球具有缓释作用,并可实现GRF基因体内局部基因转染、表达,发挥其相应的生物学效应,有希望成为提高质粒在动物肌肉组织表达效率的新方法。     

Administration of human pancreatic growth hormone-releasing factor (GRF) analogs enhances responsiveness of cultured rat pituitary cells to GRF

The aim of this study was to investigate whether anterior pituitary responsiveness to human pancreatic growth hormone-releasing factor containing 29 amino acids (GRF-29) can be modulated by GRF-29 itself. Male rats were injected (sc) daily for 3 days with 50 ug of GRF-29, or were treated twice daily for 14 days with 5 ug of [D-Ala-2]-GRF-29 (a potent GRF agonist). Control animals were injected with saline. After the last injection, pituitaries were removed, dispersed, cultured for 96 h and then challenged with either GRF-29 or [D-Trp-6]-LHRH (a LHRH agonist). Cultured cells from analog-treated rats were more responsive to GRF-29 stimulation than were cells obtained from controls. In contrast, neither treatment altered the response to [D-Trp-6]-LHRH. These studies indicate that periodic administration of GRF analogs can increase hypophyseal GRF responsiveness. Such control may be an important component in the physiological regulation of GH secretion and has important implications for potential therapeutic uses of GRF analogs.     

The roles of Tyr(91) and Lys(162) in general acid-base catalysis in the pigeon NADP+-dependent malic enzyme

The role of general acid-base catalysis in the enzymatic mechanism of NADP+-dependent malic enzyme was examined by detailed steady-state kinetic studies through site-directed mutagenesis of the Tyr(91) and Lys(162) residues in the putative catalytic site of the enzyme. Y91F and K162A mutants showed approx. 200- and 27000-fold decreases in k(cat) values respectively, which could be partially recovered with ammonium chloride. Neither mutant had an effect on the partial dehydrogenase activity of the enzyme. However, both Y91F and K162A mutants caused decreases in the k(cat) values of the partial decarboxylase activity of the enzyme by approx. 14- and 3250-fold respectively. The pH-log(k(cat)) profile of K162A was found to be different from the bell-shaped profile pattern of wild-type enzyme as it lacked a basic pK(a) value. Oxaloacetate, in the presence of NADPH, can be converted by malic enzyme into L-malate by reduction and into enolpyruvate by decarboxylation activities. Compared with wild-type, the K162A mutant preferred oxaloacetate reduction to decarboxylation. These results are consistent with the function of Lys(162) as a general acid that protonates the C-3 of enolpyruvate to form pyruvate. The Tyr(91) residue could form a hydrogen bond with Lys(162) to act as a catalytic dyad that contributes a proton to complete the enol-keto tautomerization.