Molecularly precise dendrimer-drug conjugates with tunable drug release for cancer therapy.

The structural preciseness of dendrimers makes them perfect drug delivery carriers, particularly in the form of dendrimer-drug conjugates. Current dendrimer-drug conjugates are synthesized by anchoring drug and functional moieties onto the dendrimer peripheral surface. However, functional groups exhibiting the same reactivity make it impossible to precisely control the number and the position of the functional groups and drug molecules anchored to the dendrimer surface. This structural heterogeneity causes variable pharmacokinetics, preventing such conjugates to be translational. Furthermore, the highly hydrophobic drug molecules anchored on the dendrimer periphery can interact with blood components and alter the pharmacokinetic behavior. To address these problems, we herein report molecularly precise dendrimer-drug conjugates with drug moieties buried inside the dendrimers. Surprisingly, the drug release rates of these conjugates were tailorable by the dendrimer generation, surface chemistry, and acidity.

Acid-active cell-penetrating peptides for in vivo tumor-targeted drug delivery.

Cell-penetrating peptides (CPPs) such as transactivator of transcription (TAT) peptide have long been explored for promoting in vitro cell penetration and nuclear targeting of various cargos, but their positive charges cause strong nonspecific interactions, making them inapplicable for many in vivo applications. In this work, we used TAT to demonstrate a molecular modification approach for inhibiting nonspecific interactions of CPPs in the bloodstream while reactivating their functions in the targeted tissues or cells. The TAT lysine residues' amines were amidized to succinyl amides ((a)TAT), completely inhibiting TAT's nonspecific interactions in the blood compartment; once in the acidic tumor interstitium or internalized into cell endo/lysosomes, the succinyl amides in the (a)TAT were quickly hydrolyzed, fully restoring TAT's functions. Thus, (a)TAT-functionalized poly(ethylene glycol)-block-poly(ε-caprolactone) micelles achieved long circulation in the blood compartment and efficiently accumulated and delivered doxorubicin to tumor tissues, giving rise to high antitumor activity and low cardiotoxicity. This amidization strategy effectively and easily enables in vivo applications of CPPs.

Prodrugs forming high drug loading multifunctional nanocapsules for intracellular cancer drug delivery.

Anticancer drugs embedded in or conjugated with inert nanocarriers, referred to as nanomedicines, show many therapeutic advantages over free drugs, but the inert carrier materials are the major component (generally more than 90%) in nanomedicines, causing low drug loading contents and thus excessive uses of parenteral excipients. Herein, we demonstrate a new concept directly using drug molecules to fabricate nanocarriers in order to minimize use of inert materials, substantially increase the drug loading content, and suppress premature burst release. Taking advantage of the strong hydrophobicity of the anticancer drug camptothecin (CPT), one or two CPT molecule(s) were conjugated to a very short oligomer chain of ethylene glycol (OEG), forming amphiphilic phospholipid-mimicking prodrugs, OEG-CPT or OEG-DiCPT. The prodrugs formed stable liposome-like nanocapsules with a CPT loading content as high as 40 or 58 wt % with no burst release in aqueous solution. OEG-DiCPT released CPT once inside cells, which showed high in vitro and in vivo antitumor activity. Meanwhile, the resulting nanocapsules can be loaded with a water-soluble drug-doxorubicin salt (DOX.HCl)-with a high loading efficiency. The DOX.HCl-loaded nanocapsules simultaneously delivered two anticancer drugs, leading to a synergetic cytotoxicity to cancer cells. The concept directly using drugs as part of a carrier is applicable to fabricating other highly efficient nanocarriers with a substantially reduced use of inert carrier materials and increased drug loading content without premature burst release.

Degradable poly(beta-amino ester) nanoparticles for cancer cytoplasmic drug delivery.

Fast cytoplasmic drug delivery can overcome cancer cells' drug resistance and thus have an enhanced therapeutic efficacy. Such a drug delivery regime requires drug carriers capable of entering cancer cells, localizing and rapidly releasing the drug into endosomes/lysosomes, and subsequently disrupting their membranes to release the drug into the cytosol. We herein report a low-toxic and degradable poly(beta-amino ester)-graft-polyethylene glycol (BAE-PEG) co-polymer forming pH-responsive nanoparticles capable of cytoplasmic drug delivery. BAE-PEG was synthesized by condensation polymerization of diacrylate and piperazine in the presence of a PEG-diacrylate macromonomer. BAE-PEG with 2% or 5% PEG side chains formed micelles (nanoparticles) with diameters of about 100 nm. The BAE-PEG nanoparticles were shown to rapidly enter cancer cells, localize in their endosomes/lysosomes, and subsequently disrupt them to release the drugs into the cytosol. Camptothecin loaded in the nanoparticles had a higher cytotoxicity to SKOV-3 ovarian cancer cells than free camptothecin.

Predicting residual feed intake status using rumen microbial profiles in ewe lambs1.

Including feed efficiency as a trait for selection has gained interest in the sheep industry because it can result in reduced feed inputs or improve stocking rates, both of which translate into increased profitability for the producer. It is of interest whether the feed efficiency status of a testing population of sheep could be predicted using rumen microbial profiles associated with divergent feed efficiency status in a training population of sheep. Two populations of ewes were fed the same diet, and each group was evaluated for feed efficiency. A total of 20 animals in the testing population were selected for prediction assessment using feed efficiency, including the 6 top-ranked, the 6 bottom-ranked, and 8 middle-ranked ewes stratified over the distribution. Rumen fluid samples were collected and DNA was extracted for sequencing. Using a rumen microbial profile associated with diverging feed efficiency created from the training population, multiple discriminant analyses were performed using the DISCRIM procedure of SAS to determine the probability of correctly identifying lambs in the testing population as low, medium, or high feed efficiency using their microbial profiles. A profile of 6 rumen microbial species were used to correctly (P < 0.001) predict all testing population ewes into their actual feed efficiency status. A regression analysis using the same microbial profile was used to predict feed efficiency values, which were strongly correlated (r = 0.71; P < 0.001) with actual feed efficiency values. These results indicate that specific rumen microbial species may play a role in feed efficiency, and that a microbial profile could be used to rank sheep for feed efficiency.

Progesterone facilitates cisplatin toxicity in epithelial ovarian cancer cells and xenografts.

OBJECTIVES: The underlying premise of these investigations was that the lipophilic hormone progesterone, which partitions into and (at relatively high concentrations) impedes the fluid mechanics of the plasmalemma, would perturb integral associations between membrane lipids and exporter pumps that otherwise confer drug resistance. That progesterone can affect susceptibility of ovarian adenocarcinoma cells and xenografts to cisplatin was tested. METHODS: The cisplatin-resistant human cell lines SKOV-3 and OVCAR-3 were treated for 24 hours with cisplatin (0.1 microg/ml)+/-progesterone (0.01, 0.1 microg/ml). Cytotoxicity and platinum were measured by MTT assay and inductively coupled plasma mass spectrometry, respectively. Athymic mice were inoculated intraperitoneal (ip) with SKOV-3 cells. Cisplatin (2 mg/kg/week)+/-progesterone (25 mg sustained-release pellet) regimens were initiated ip at one week (when micrometastases were present) and continued to six weeks post-xenograft. Tumor burdens, histopathology, and platinum concentrations were assessed upon necropsy at 24 hours after the final injection of cisplatin. RESULTS: There were no significant in vitro/vivo anticancer effects of cisplatin alone. High-dose progesterone enhanced platinum accretion and induced drug toxicity in both cell lines. Tumorigenesis was suppressed by cisplatin+progesterone. The treatment synergy was related to elevated tumor platinum and morphological evidence of apoptosis. CONCLUSION: It appears that the addition of progesterone to ovarian cancer therapeutic modalities represents a step in improving responses.

pH-responsive nanoparticles for cancer drug delivery.

Solid tumors have an acidic extracellular environment and an altered pH gradient across their cell compartments. Nanoparticles responsive to the pH gradients are promising for cancer drug delivery. Such pH-responsive nanoparticles consist of a corona and a core, one or both of which respond to the external pH to change their soluble/insoluble or charge states. Nanoparticles whose coronas become positively charged or become soluble to make their targeting groups available for binding at the tumor extracellular pH have been developed for promoting cellular targeting and internalization. Nanoparticles whose cores become soluble or change their structures to release the carried drugs at the tumor extracellular pH or lysosomal pH have been developed for fast drug release into the extracellular fluid or cytosol. Such pH-responsive nanoparticles have therapeutic advantages over the conventional pH-insensitive counterparts.

Synthesis of degradable functional poly(ethylene glycol) analogs as versatile drug delivery carriers.

Poly(ethylene glycol) (PEG) is widely used as a water soluble carrier for polymer-drug conjugates. Herein, we report degradable linear PEG analogs (DPEGs) carrying multifunctional groups. The DPEGs were synthesized by a Michael addition based condensation polymerization of dithiols and PEG diacrylates (PEGDA) or dimethacrylates (PEGDMA). They were stable at pH 7.4 but quickly degraded at pH 6.0 and 5.0. Thus, DPEGs could be used as drug carriers without concern for their retention in the body. DPEGs could be made to carry such functional groups as terminal thiol or (meth)acrylate and pendant hydroxyl groups. The functional groups were used for conjugation of drugs and targeting groups. This new type of PEG analog will be useful for drug delivery and the PEGylation of biomolecules and colloidal particles.

Degradable cisplatin-releasing core-shell nanogels from zwitterionic poly(beta -aminoester)-graft-PEG for cancer chemotherapy.

Cisplatin conjugated onto macromolecules or loaded in micelles can be preferentially delivered to tumors to minimize its toxicity to healthy tissues and increase its drug efficacy. Herein, we report cisplatin-containing nanogels possibly useful for targeted delivery of cisplatin. Carboxylic acid-functionalized poly(beta -aminoester)graft-poly(ethylene glycol) copolymers were synthesized by cocondensation polymerization of piperazine with 2,2-bis(acryloxymethyl)propionic acid, PEG 2,2-bis(acryloxymethyl)propionate macromonomer (mPEG). The graft copolymers formed 100-200 nm nanogels with low size-distribution by the complexation of their carboxylic groups with cisplatin. The nanogels were negatively charged and had a PEG outer layer. Thus, they had "stealth properties" suitable for in vivo applications. The nanogels had significantly lower in vitro cytotoxicity to SKOV-3 ovarian cancer cells than free cisplatin, but similar anticancer activity toward SKOV-3 tumors xenografted to immunocompromised mice.

Complement-inhibiting effect of ovarian cancer antigen CA-125.

Malignant transformation of ovarian cells of surface epithelial origin is associated with expression of a membrane-spanning glycoprotein, cancer antigen (CA)-125. The bulk of the putative CA-125 molecule is comprised a very large, folded, multivalent, mucin-like exodomain. That the extracellular motif of CA-125 exerts immunosuppressive effects which promote tumor progression has been suggested. We report that CA-125 attenuates complement lysis of antibody-sensitized cells. The secreted form of CA-125 derived from culture medium of the human ovarian adenocarcinoma cell line OVCAR-3 caused a dose-response inhibition of sheep erythrocyte hemolysis. Moreover, OVCAR-3 cells became prone to complement attack (trypan blue uptake) mediated by a gonadotropin-releasing hormone receptor antibody when (membrane-bound) CA-125 was excised/removed by trypsin/washing; this effect was counteracted by replacement with (soluble) CA-125. It is conceivable that CA-125 entraps/sheds effectors of the complement cascade.

Highly stable core-surface-crosslinked nanoparticles as cisplatin carriers for cancer chemotherapy.

Cisplatin is a potent anticancer drug with low solubility in water. A new type of highly stable polymer micelles, namely core-surface-crosslinked nanoparticles (SCNPs) made from amphiphilic brush copolymers, were evaluated as the carrier of cisplatin. Cisplatin could be loaded in the SCNPs with poly(epsilon-caprolactone) (PCL) cores and hydrophilic poly(ethylene glycol) (PEG) or poly[2-(N,N-dimethylamino)ethyl methacrylate] (PDMA) shells with high loading efficiency (approximately 90%). In vitro cellular uptake experiments indicated that both SCNPs could be easily taken up by SKOV-3 ovarian cancer cells. Both cell proliferation assay and IC50 measurements indicated that cisplatin encapsulated in the SCNPs had much enhanced cytotoxicity to the cancer cells compared to free cisplatin. The positive charges on the PCL/PDMA SCNPs promoted the cellular internalization of the nanoparticles, resulting in higher cytotoxicity of cisplatin in these SCNPs. The IC50 of the cisplatin encapsulated in PCL/PDMA SCNPs was as low as 0.01 microg/mL, lower than that of cisplatin in PCL/PEG SCNPs and free cisplatin.

Fabrication of dendrimer-releasing lipidic nanoassembly for cancer drug delivery.

An inherent dilemma in the use of nanomedicines for cancer drug delivery is their limited penetration into tumors due to their large size. We have demonstrated that dendrimer/lipid nanoassemblies can solve this problem by means of tumor-triggered disassembly and the release of small (several nanometers) dendrimers to facilitate tumor penetration. Herein, we report a general strategy for the fabrication of nanoassemblies from hydrophobic and hydrophilic dendrimers with phospholipids. Hydrophobic dendrimers could assemble with lipids via hydrophobic interactions, whereas hydrophilic dendrimers could only assemble with lipids in the presence of anionic surfactants via both electrostatic and hydrophobic interactions. The nanoassemblies of hydrophobic dendrimers/lipids were found to be capable of stripping off their lipid layers via fusion with the cell membrane and then intracellular or extracellular release of dendrimers, whereas the nanoassemblies of hydrophilic dendrimers/lipids were internalized via endocytosis and then released their dendrimers inside the cells. Therefore, these dendrimer/lipid nanoassemblies could be used for the delivery of different cancer drugs.

Effects of progesterone on ovarian tumorigenesis in xenografted mice.

Circumstantial evidence indicates that progestins reduce the risk of epithelial ovarian cancer. We report that the tumorigenic capacity of human ovarian carcinoma (SKOV-3) cells inoculated into the peritoneal cavity of athymic mice is suppressed by pretreatment with subcutaneous progesterone-releasing pellets. Numbers of tumor implants on the intestines/mesentery and invasiveness into underlying host tissues were reduced at 6 weeks following exposure to progesterone. Progesterone prevented tumors from forming on the liver. Life spans of progesterone-treated animals were prolonged. There was no beneficial effect of administration of progesterone if initiated after ovarian tumors had become established on organ surfaces. Our findings implicate a role for progesterone in ovarian cancer prophylaxis.

DNA damages in ovarian surface epithelial cells of ovulatory hens.

A cause-effect relationship between ovulation and common (surface) epithelial ovarian cancer has been suspected for many years. The ovarian surface epithelium apparently becomes exposed to genotoxins that are generated during the ovulatory process. Intensive egg-laying hens readily develop ovarian carcinomatosis. Indeed, elevated levels of potentially mutagenic 8-oxo-guanine adducts were detected in avian ovarian epithelial cells isolated from the apical surfaces and perimeters of pre-and postovulatory follicles, respectively. Internucleosomal DNA fragmentation indicative of apoptosis was evident in ovarian surface epithelial cells associated with the formative site of ovulation (stigma line) and regressive ruptured follicles. It is conceivable that a genetically altered progenitor cell with unrepaired DNA but not committed to death (i.e., a unifocal "escape") could give rise to a transformed phenotype. Hence, the high rate of ovarian cancer in egg-laying hens could be the consequence of genomic damages to the ovarian surface epithelium associated with incessant ovulations, thereby increasing the likelihood of mutation and clonal expansion.

Steroid hormonal regulation of proliferative, p53 tumor suppressor, and apoptotic responses of sheep ovarian surface epithelial cells.

Ovarian surface epithelial cells have been implicated in the genesis of common ovarian cancers. The integrity of DNA of ovarian surface epithelial cells contiguous with the ovulatory stigma becomes compromised during the rupture process; most cells degenerate by apoptosis, however some, bearing sublethal lesions, persist along the margins of ovulated follicles. Clonal expansion of a genetically-damaged surface epithelial cell (i.e. with unrepaired DNA, but not committed to death) can presumably give rise to ovarian carcinoma. It was hypothesized that estradiol and progesterone regulate ovarian surface epithelial cell-cycle dynamics associated with folliculo-luteal transitions and ovulatory wound repair/remodeling. Progesterone up-regulated the tumor suppressor p53 and inhibited baseline and estradiol-stimulated proliferation of cultured sheep ovarian surface epithelial cells. Anti/mitotic responses to steroid hormones were transcriptionally- and receptor-dependent. Rates of apoptosis (DNA fragmentation) were unaffected by progesterone. High concentrations of estradiol, via a nongenomic (perhaps antioxidant) mechanism, suppressed basal and H(2)O(2)-induced apoptosis. We suggest that, progesterone serves to inhibit proliferation of ovarian surface epithelial cells throughout the luteal phase--providing the time (growth arrest) required to correct any metabolic disturbances to DNA that are perpetrated as an inevitable by-product of the ovulatory process. With luteolysis and dominance of an estrogenic preovulatory follicle the ovarian surface epithelium is then regenerated. Thus, it is conceivable that perturbations to the steroid hormonal milieu of ovarian cycles could be a predisposing factor for cancerous transformation of an ovarian surface epithelial cell.

Ovarian responses to undernutrition in pregnant ewes, USA.

In most mammals oogonia proliferate by mitosis and begin meiotic development during fetal life. Previous studies indicated that there is a delay in the progression to the first stage of meiotic arrest in germ cells of female fetuses of undernourished ewes. We report that underfeeding (50% NRC requirement beginning on Day 28 of pregnancy) provokes an increase in oxidative base lesions within DNA of mid-gestational (Day 78) fetal oogonia; this condition was associated with up-regulation of the tumor suppressor/cell-cycle arrest modulator p53, antiapoptotic factor Bcl-2, and base-excision repair polymerase beta. Fetal ovarian weights and germ cell concentrations were not altered by nutrient deprivation. Ovaries of ewes on control diets (100% NRC) contained more tertiary follicles than their restricted counterparts; however, peripheral venous estradiol-17beta was not different between groups. There was no effect of treatment on p53 accumulation in maternal oocytes. Luteal structure-function was not perturbed by undernutrition. No fetal losses were attributed to the dietary restriction. It is proposed that DNA of interphase fetal oogonia is vulnerable to oxidative insults perpetrated by a nutritional stress to the dam, and that multiple/integrated adaptive molecular response mechanisms of cell-cycle inhibition (providing the time required for base repairs) and survival hence sustain the genomic integrity and population stability of the germline.

Inhibitory effects of progesterone on plasma membrane fluidity and tumorigenic potential of ovarian epithelial cancer cells.

The lethality of common (surface) epithelial ovarian cancer is contingent on its metastatic capacity. Dissemination of the neoplasia throughout the abdominal cavity has been associated with secretion of proteolytic enzymes from vesicles shed by ovarian cancer cells. We report that the lipophilic steroid hormone progesterone decreases the fluid dynamics of plasma membranes of human SKOV-3 adenocarcinoma cells. The decrease in membrane fluidity was related to an inhibition in vitro of exocytotic vesicle release, cellular invasiveness into Matrigel, and colony formation in three-dimensional collagen matrix. Tumorigenesis was suppressed by progesterone in immunocompromised nude mice inoculated intraperitoneally with SKOV-3 cells. Progestins could therefore be of benefit in the prevention and(or) treatment of early-stage ovarian carcinomatosis.

Integration of nanoassembly functions for an effective delivery cascade for cancer drugs.

A "cluster-bomb"-like lipid-dendrimer nanoassembly synergizes the functions of its components and thereby efficiently accomplishes the drug delivery cascade for high efficacy in treating cancer. The nanoassembly successfully circulates in the blood and accumulates in the tumor. Once in the tumor, it releases small dendrimers that act like "bomblets", enabling tumor penetration, cell internalization, and drug release.

Linear-dendritic drug conjugates forming long-circulating nanorods for cancer-drug delivery.

Elongated micelles have many desirable characteristics for cancer-drug delivery, but they are difficult to obtain since amphiphilic polymers form such nanostructures only within narrow composition ranges depending on their own structures. Herein, we demonstrated a facile fabrication of different nanostructures via drug content-controlled self-assembly of amphiphilic linear-dendritic drug conjugates - using the number of the conjugated hydrophobic drug molecule camptothecin (CPT) to tailor the hydrophobicity of amphiphilic PEG-block-dendritic polylysine-CPT (PEG-xCPT) conjugates and thereby control their self-assembled nanostructures - nanospheres or nanorods of different diameters and lengths. The shape and size of the nanostructures were found to strongly affect their in vitro and in vivo properties, particularly the blood clearance kinetics, biodistribution and tumor targeting. The nanorods with medium lengths (<500 nm) had a much longer blood circulation and faster cellular uptake than the nanospheres or long nanorods. Thus, polymeric nanorods with proper lengths may be ideal nanocarriers capable of uniting the opposite requirements in cancer-drug delivery.