Functional differences between protamine preparations for the transfection of mRNA.

Protamine is a natural cationic peptide mixture used as a drug for the neutralization of heparin and in formulations of slow-release insulin. In addition, Protamine can be used for the stabilization and delivery of nucleic acids (antisense, small interfering RNA (siRNA), immunostimulatory nucleic acids, plasmid DNA, or messenger RNA) and is therefore included in several compositions that are in clinical development. Notably, when mixed with RNA, protamine spontaneously generates particles in the size range of 20-1000 nm depending on the formulation conditions (concentration of the reagents, ratio, and presence of salts). These particles are being used for vaccination and immuno-stimulation. Several grades of protamine are available, and we compared them in the context of complex formation with messenger RNA (mRNA). We found that the different available protamine preparations largely vary in their composition and capacity to transfect mRNA. Our data point to the source of protamine as an important parameter for the production of therapeutic protamine-based complexes.

Design, Synthesis, and In Vitro Evaluation of Low Molecular Weight Protamine (LMWP)-Based Amphiphilic Conjugates as Gene Delivery Carriers.

Development of efficient non-viral carriers is one of the major challenges of gene delivery. In the current study, we designed, synthesized, and evaluated the in vitro gene delivery efficiency of novel amphiphilic constructs composed of cholesterol and low molecular weight protamine (LMWP: VSRRRRRRGGRRRR) peptide. Vectors having both hydrophobic and hydrophilic moieties were evaluated in terms of particle size and charge, DNA condensation ability, cytotoxicity, and gene transfection efficiency. The prepared vectors spontaneity self-assembled into the liposome-like particles with a high local positive density. The nano-vehicle A (H5-LMWP-Cholestrol) and nano-vehicle B (LMWP-Cholesterol) could form micelles at concentrations above 50 µg/mL and 65 µg/mL, respectively. The gel retardation assay showed that nano-vehicles A and B could condense pDNA more efficiently than the corresponding unconjugated peptides. The mean of size and zeta potential of complexed nano-vehicle A at N/P ratios of 5, 15, and 30 were 151 nm and 23 mv, and those of nano-vehicle B were 224 nm and 19 mv, respectively. In terms of transfection efficiency, the designed nano-vehicles showed almost two-fold higher gene expression level compared to PEI 25 kDa at optimal N/P ratios, and also exhibited negligible cytotoxicity on a model cancer cell, Neuro 2a. The findings of the present study revealed that these cationic micelles can be promising candidates as non-viral gene delivery vehicles.

Effects of Chitosan Derivative N-[(2-Hydroxy-3-Trimethylammonium)Propyl]Chloride on Anticoagulant Activity of Guinea Pig Plasma.

Intravenous injection of protamine sulfate or quarternized chitosan derivative to guinea pigs after injection of 70 aIIa U/kg non-fractionated heparin shortened plasma clotting time (shown by partial activated thromboplastin time, thrombin time, and prothrombin time). Intravenous injection of protamine sulfate or quarternized chitosan derivative to guinea pigs after injection of 1 mg/kg (100 aXa U/kg) low-molecular-weight heparin (clexane) led to shortening of plasma clotting time in the ReaClot Heparin test and to prolongation of plasma amidolytic activity in the factor Xa chromogenic substrate test.

Preparation of ultrathin, robust protein microcapsules through template-mediated interfacial reaction between amine and catechol groups.

A novel approach to the synthesis of protein microcapsules is developed through template-mediated interfacial reaction. Protein-doped CaCO3 templates are first synthetized via coprecipitation and then coated with a catechol-containing alginate (AlgDA) layer. Afterward, the templates are exposed to ethylenediamine tetraacetic acid disodium (EDTA) solution to dissolve CaCO3. During CaCO3 dissolution, the generated CO2 gas pushes protein molecules moving to the AlgDA layer, and thereby Michael addition and Schiff base reactions proceed, forming the shell of protein microcapsules. Three kinds of proteins, namely, bovine serum albumin, catalase, and protamine sulfate, are utilized. The shell thickness of microcapsule varies from 25 to 82 nm as the doping amount of protein increased from 2 to 6 mg per 66 mg CaCO3. The protein microcapsules have a robust but flexible shell and can be reversibly deformed upon exposure to osmotic pressure. The bioactivity of protein microcapsules is demonstrated through enzymatic catalysis experiments. The protein microcapsules remain about 80% enzymatic activity of the equivalent free protein. Hopefully, our approach could be extended to many other applications such as drug/gene delivery, tissue scaffolds, and catalysis due to the universality of Michael reaction and Schiff base reactions.

Polycationic protamine for water-insoluble complex formation with DNA.

The DNA/protamine complex was prepared by a reaction between DNA and protamine sulfate solutions with stirring, and its cell viability, antibacterial effect and histopathological responses were examined. A water-insoluble white powder, DNA/protamine complex, with a porous structure was obtained. The molar binding ratio of the complex prepared from a solution containing equal amounts of DNA and protamine sulfate by weight was 0.038 and the efficiency of complex formation was 61%. In a cell culture test using MC-3T3-E1 mouse osteoblast cells, the complex showed less cytotoxicity than protamine sulfate alone and cell viabilities were more than 98%. A porous disk could be prepared easily and showed an antibacterial effect against Staphyrococcus aureus, Porphyromonas gingivalis and Prevotella intermedia in an antibacterial sensitivity test and a mild tissue response in vivo test. These results suggested that the DNA/protamine complex could be a useful biodegradable biomaterial with antibacterial effects.

An efficient and low immunostimulatory nanoparticle formulation for systemic siRNA delivery to the tumor.

We have developed a nanoparticle formulation [liposomes-protamine-hyaluronic acid nanoparticle (LPH-NP)] for systemically delivering siRNA into the tumor. The LPH-NP was prepared in a self-assembling process. Briefly, protamine and a mixture of siRNA and hyaluronic acid were mixed to prepare a negatively charged complex. Then, cationic liposomes were added to coat the complex with lipids via charge-charge interaction to prepare the LPH-NP. The LPH-NP was further modified by DSPE-PEG or DSPE-PEG-anisamide by the post-insertion method. Anisamide is a targeting ligand for the sigma receptor over-expressed in the B16F10 melanoma cells. The particle size, zeta potential and siRNA encapsulation efficiency of the formulation were approximately 115 nm, +25 mV and 90%, respectively. Luciferase siRNA was used to evaluate the gene silencing activity in the B16F10 cells, which were stably transduced with a luciferase gene. The targeted LPH-NP (PEGylated with ligand) silenced 80% of luciferase activity in the metastatic B16F10 tumor in the lung after a single i.v. injection (0.15 mg siRNA/kg). The targeted LPH-NP also showed very little immunotoxicity in a wide dose range (0.15-1.2 mg siRNA/kg), while the previously published formulation, LPD-NP (liposome-protamine-DNA nanoparticle), had a much narrow therapeutic window (0.15-0.45 mg/kg).

Oligonucleotide-protamine-albumin nanoparticles: preparation, physical properties, and intracellular distribution.

Oligodesoxynucleotides (ODNs) or the corresponding phosphorothioates (PTOs) spontaneously form spherical nanoparticles ("proticles") with protamine in aqueous solutions. The proticles can cross cellular membranes and release the ODNs within the cells. Thus, they represent a potential drug delivery system. The major disadvantages of this system are a lack of stability in salt solutions and its inability to also release PTOs. The present study shows, using PTOs and protamine free base, that these shortcomings can be eliminated by the addition of human serum albumin (HSA) as a third component to the starting mixture. The "ternary" proticles thus obtained contain maximally a few percent of the HSA that was originally present. Nevertheless, they differ from the previously studied "binary" proticles: (1) They are stable in salt solutions for at least several hours. (2) They show a high cellular uptake into murine fibroblasts, and they readily release the PTOs after uptake. The ternary proticles therefore represent a considerable improvement over binary proticles for use as drug delivery systems.

PEG-modified protamine with improved pharmacological/pharmaceutical properties as a potential protamine substitute: synthesis and in vitro evaluation.

Cardiopulmonary bypass (CPB) procedures are frequently associated with massive inflammatory responses, resulting in a high rate of morbidity and mortality in routine cardiac operations. One recognized attribute of these deleterious responses is the synergic effect of heparin and protamine, which elicit the activation of the complement system in vivo. To circumvent such toxic effects following protamine reversal of heparin anticoagulation in the CPB procedures, we proposed that poly(ethylene glycol) (PEG)-modified protamine could retain the heparin-neutralization ability and yet diminish the induced complement activation by the formed heparin-protamine complexes (HPC), thereby providing highly improved pharmacological properties. PEGylation of protamine was carried out by utilizing N-hydroxysuccinimidyl (NHS) conjugation chemistry. Size exclusion chromatography (SEC), reverse-phase high performance liquid chromatography (RP-HPLC), and matrix-assisted laser desorption mass spectrometry (MALDI-MS) were used to assess the conjugation stiochiometry, the purity of the conjugates, and the site of PEG modification, respectively. The heparin-neutralizing activity was determined by using heparin affinity chromatography and various biological assays including the plasma-activated partial thromboplastin time (aPTT), anti-Xa, and anti-IIa methods. The potency in inducing complement activation was examined in vitro using the CH50 hemolytic assay. The PEG-modified protamine was successfully synthesized with a PEG/protamine stiochiometry of 1:1. Only one conjugation site for PEG that was located at the N-terminal end of protamine was obtained. In the biological evaluations, the PEG-modified protamine displayed a full retention of the heparin-neutralizing ability of protamine and a significantly reduced activity in complement activation following its complexation with heparin. Results from studies of the particle size and zeta potential indicated that the PEG-modified protamine formed substantially smaller aggregates with heparin, rendering them less effective in triggering the size-dependent complement responses. As with protamine, PEG-modified protamine exhibited an enhanced aqueous solubility, therefore attaining significantly improved pharmaceutical properties. These preliminary results suggested that the PEG-modified protamine conjugate might serve as a potential protamine substitute with improved therapeutic and pharmaceutical properties in heparin reversal.

Coating of mannan on LPD particles containing HPV E7 peptide significantly enhances immunity against HPV-positive tumor.

PURPOSE: Previously, our laboratory has reported that liposome-protamine-DNA (LPD) nanoparticle is an effective delivery system for tumor-associated antigens. Mannan, which potentially targets antigen-presenting cells, was coated on LPD to further enhance its antitumor activity. METHODS: Cholesterol-conjugated mannan was coated on LPD. The abilities of mannan-coated LPD to target antigen-presenting cells, to activate dendritic cells, and to induce antitumor immunity were investigated and compared to those of LPD alone. RESULTS: Both in vitro and in vivo uptake of LPD showed that mannan-coated LPD particles were preferably taken up by dendritic cells and macrophages. In addition, the expression of co-stimulatory molecules CD80/CD86 on DC2.4 cells after co-incubation with mannan-coated LPD was significantly higher than that after co-incubation with LPD. A model major histocompatibility complex class I-restricted peptide antigen from HPV 16 E7 protein was incorporated into LPD to immunize mice against the growth of TC-1 tumor cells expressing E7 protein. Coating with mannan significantly enhanced both preventive and therapeutic activities of LPD/E7. Finally, the release of IFN-gamma from isolated splenocytes was significantly enhanced when mice were immunized with mannan-coated LPD/E7 than with LPD/E7 alone. CONCLUSION: Targeting of the LPD/E7 to local draining lymph nodes by mannan is partially responsible for the enhanced anti-tumor activity.

Effective and less toxic reversal of low-molecular weight heparin anticoagulation by a designer variant of protamine.

PURPOSE: This investigation assessed protamine reversal of heparin anticoagulation by formation of a protamine-heparin alpha-helix by use of a new designer-variant protamine [+18BE] that was made from an existing protamine variant [+18B] whose non-alpha-helix-forming amino acid proline (P) was replaced by an alpha-helix-forming glutamic acid (E). The rate of administration of the new [+18BE] variant protamine on efficacy and toxicity in comparison to that of [+21] standard protamine and [+18B] was also studied. METHODS: Acetyl-EAA(K2A2K2A)4K2-Amide [+18BE] was administered intravenously in a 1:1 dose to low-molecular-weight heparin (LMWH)-anticoagulated (intravenous 150 IU antifactor Xa/kg) dogs over 10 seconds or 3 minutes (n = 7, each group). Reversal efficacy was documented by measuring activated clotting time, thrombin clotting time, antifactor Xa, and antifactor IIa. Toxicity was defined by measuring systemic blood pressure, heart rate, cardiac output, pulmonary artery pressure, and oxygen consumption. Measurements were made at baseline, after administration of LMWH, before its reversal, and for 30 minutes thereafter. Results were compared with those after LMWH reversal with [+21] standard protamine and the [+18B] variant. A total toxicity score (TTS) was calculated for each compound from maximal declines in blood pressure, heart rate, cardiac output, and oxygen consumption. RESULTS: LMWH anticoagulation reversal was significantly (p < 0.01) less toxic over 10 seconds and 3 minutes with the [+18BE] designer variant (TTS -2.3, -2.2) compared with the [+21] standard protamine (TTS -6.4, -7.2). Percent LMWH reversal at 3 minutes revealed [+18BE] to have antifactor Xa activity as high as 91%, compared with 68% for protamine [+21], when given over 3 minutes (p < 0.05). CONCLUSIONS: This investigation documents that a new designer variant of protamine [+18BE] has superior efficacy compared with [+21] standard protamine for reversal of LMWH anticoagulation and that this occurs with a highly favorable toxicity profile.

Reversal of low-molecular-weight heparin anticoagulation by synthetic protamine analogues.

Protamine reversal of unfractionated and low-molecular-weight heparin (LMWH) causes hypotension, bradycardia, pulmonary artery hypertension, and declines in oxygen consumption. Furthermore, protamine incompletely reverses the anti-Xa activity of LMWH. The present study assesses the efficacy and toxicity of three protamine variants having +16 and +18 charges in reversal of LMWH (Logiparin, LHN-1): [+16] P(AK2A2K2)4, [+18] PK(K2A2K2A)3K2AK3, and [+18B] acetyl-PA(K2A2K2A)4K2-amide. The [+18B] compound was made by acetylating and amidating the [+18] to decrease in vivo degradation and to increase the alpha-helix forming propensity. Variants were examined in a canine model (n = 7, each variant) and compared to controls (n = 7, each variant) and compared to controls (n = 7) reversed with standard protamine with a +21 charge. Animals were anesthetized, anticoagulated with LMWH (150 IU factor Xa activity/kg), and reversed with protamine variants (1.5 mg/kg with 100 IU/mg). Blood pressure (BP), heart rate (HR), cardiac output (CO), pulmonary artery pressures, oxygen saturations, and oxygen consumption (VO2) were continuously monitored. Comparisons were undertaken at baseline, after heparin, before variant administration, and for 30 min thereafter. A total toxicity score (TTS) was calculated for each variant, accounting for maximal declines in BP, HR, CO, and VO2 during the first 5 min after reversal. Protamine [+21] was most toxic, TTS -7.6, with the variants being less toxic (P < 0.01, ANOVA): TTS = [+16] -2.8, [+18] -1.3, and [+18B] -4.1.(ABSTRACT TRUNCATED AT 250 WORDS)

Efficacy and toxicity of differently charged polycationic protamine-like peptides for heparin anticoagulation reversal.

PURPOSE: The role of total cationic charge of synthetic protamine-like peptides in heparin anticoagulation reversal and accompanying adverse hemodynamic effects was studied. METHODS: Five protamine variants having specific total charges of [+8], [+16], [+18], [+20], and [+21] were synthesized by fluorenylmethoxycarbonyl procedures. Each of these lysine-containing peptides plus arginine-containing control salmine native protamine (n-protamine, [+21] charge) was studied in five dogs who received heparin 150 IU/kg intravenously followed by 1.5 mg/kg (intravenously during a 10-second period) of the synthesized peptide or control n-protamine. RESULTS: Anticoagulation reversal as assessed by a number of coagulation tests was more effective with peptides of greater cationic charge. In this regard, activated clotting time reversal 3 minutes after peptide administration was 7%, [+8]; 54%, [+16]; 81%, [+18]; 92%, [+20]; 81%, [+21]; and greater than 100% [n-protamine]. Reversal of heparin anticoagulation at 3 and 30 minutes, respectively, correlated significantly (*p < or = 0.05, p < or = 0.01 [see corresponding symbols within abstract]) with total cationic charge as assessed by activated clotting time (r = 0.97, 0.99 ), prothrombin time (r = 0.98, 0.87*), activated partial thromboplastin time (r = 0.99, 0.78), thrombin clotting time (r = 0.84,* 0.85*), heparin anti-Xa activity (r = 0.87,* 0.85*), and heparin anti-IIa activity (r = 0.79 at 3 minutes, p = 0.06). Maximum declines in systemic mean arterial pressure (MAP) were greater with more positively charged peptides: -1 mm Hg, [+8]; -3 mm Hg, [+16]; -31 mm Hg; [+18]; -31 mm Hg, [+20]; -35 mm Hg, [+21]; and -34 mm Hg [n-protamine]. Maximum decreases in MAP, cardiac output, and systemic oxygen consumption were highly correlated (p < or = 0.05) with total cationic charge: MAP, r = 0.87; cardiac output, r = 0.87; and systemic oxygen consumption, r = 0.86. A total toxicity score, reflecting adverse hemodynamic effects, was greater with increasing charge: -1.9 +/- 1.1, [+8]; -2.7 +/- 0.8, [+16]; -6.6 +/- 3.3, [+18]; -6.1 +/- 3.5, [+20]; -6.9 +/- 3.8, [+21]; and -7.0 +/- 5.2 [n-protamine]. The correlation of mean peptide total toxicity score to total cationic charge was significant (r = 0.89, p < 0.05). CONCLUSIONS: These data suggest for the first time that effective alternatives to salmine protamine for reversal of heparin anticoagulation can be synthesized. Furthermore, total cationic charge appears to be an important determinant for both anticoagulation reversal and toxicity of protamine-like peptides.

Protamines. III. Synthesis of the tetradecapeptide corresponding to the C-terminal sequence 52--65 of galline.

The synthesis of peptides containing blocks of arginyl residues is proposed through amidination of the corresponding ornithyl analogs. In order to test this strategy the ornithyl analog of the C-terminal sequence 52--65 of galline was synthesized by the conventional method. The amidination reaction, performed on fragments of different length and ornithyl-residue content, quantitatively converts ornithines into arginines. The strategy proposed may represent a powerful tool for the synthesis of protamines and other basic proteins.