Gene therapy by electroporation for the treatment of chronic renal failure in companion animals.

BACKGROUND: Growth hormone-releasing hormone (GHRH) plasmid-based therapy for the treatment of chronic renal failure and its complications was examined. Companion dogs (13.1+/-0.8 years, 29.4+/-5.01 kg) and cats (13.2+/-0.9 years, 8.5+/-0.37 kg) received a single 0.4 mg or 0.1 mg species-specific plasmid injection, respectively, intramuscularly followed by electroporation, and analyzed up to 75 days post-treatment; controls underwent electroporation without plasmid administration. RESULTS: Plasmid-treated animals showed an increase in body weight (dogs 22.5% and cats 3.2%) compared to control animals, and displayed improved quality of life parameters including significant increases in appetite, activity, mentation and exercise tolerance levels. Insulin-like growth factor I (IGF-I, the downstream effector of GHRH) levels were increased in the plasmid treated animals. Hematological parameters were also significantly improved. Protein metabolism changes were observed suggesting a shift from a catabolic to an anabolic state in the treated animals. Blood urea nitrogen and creatinine did not show any significant changes suggesting maintenance of kidney function whereas the control animal's renal function deteriorated. Treated animals survived longer than control animals with 70% of dogs and 80% of cats surviving until study day 75. Only 17% and 40% of the control dogs and cats, respectively, survived to day 75. CONCLUSION: Improved quality of life, survival and general well-being indicate that further investigation is warranted, and show the potential of a plasmid-based therapy by electroporation in preventing and managing complications of renal insufficiency.

Double-blinded, Placebo-controlled plasmid GHRH trial for cancer-associated anemia in dogs.

The use of growth hormone releasing hormone (GHRH) plasmid-based therapy to treat companion dogs with spontaneous malignancies and anemia receiving a cancer-specific treatment was examined in a double-blinded, placebo-controlled trial. The dogs (age 10.5 +/- 2.5 years, weight 24.9 +/- 12.9 kg) received a single 0.35 mg dose of plasmid or placebo intramuscularly (i.m.), followed by electroporation (EP), and were analyzed for up to 120 days. The response rate was defined as > or = 5% increase above the nadir in the red blood cell (RBC), hemoglobin (Hb), and hematocrit (Ht) levels. Plasmid-treated dogs had at least a 7% increase in all three parameters. The initial response rates for the plasmid-treated dogs were 40.6 and 35.5%, respectively on days 40 and 60, which increased to 54.2% on day 90. Although the response rate reduced to 47.1% by day 120, it was still 22.1% higher than in the control dogs. Post-hoc analysis of the GHRH-treated group showed that responder dogs survived 84% longer, 178 +/- 26 days post-treatment, while nonresponders and controls survived for 95 +/- 16 and 97 +/- 31 days post-treatment, respectively. The quality of life, defined by 10 different parameters, dramatically improved with treatment. Overall, the possibility of a GHRH plasmid-based therapy for anemia in cancer-afflicted subjects is important enough to deserve further investigation.

Growth hormone-releasing hormone plasmid treatment by electroporation decreases offspring mortality over three pregnancies.

LifeTideSW5 is a growth hormone-releasing hormone (GHRH)-expressing plasmid delivered by intramuscular (IM) electroporation (EP), and the first therapeutic plasmid delivered by this physical method to be approved for use in food animals. Gestating sows (n = 997) were treated once with a single 5-mg GHRH-plasmid by EP or served as controls. Data on offspring from three parities subsequent to treatment were collected. No adverse effects related to treatment were noted. First parity post-treatment offspring from treated sows displayed a 2.93 kg (P < 0.0001) increase in carcass weight (CW), 1.0 mm (P < 0.0001) less back-fat (P2), and a 27.0 g CW/day (P < 0.0001) increase in rate of gain (ROG) compared with controls. An increase of 21.6% was recorded in the number of offspring surviving. In the second and third parities post-treatment, offspring from treated females displayed higher number of born alive and total born number, and lower stillborn rates. Third parity offspring from treated sows displayed a 1.6 kg advantage in CW (P < 0.05), 1.0 mm less P2 (P < 0.05), and a 10.0 g CW/day benefit in ROG. Furthermore, offspring from treated females had a 19.04% lower post-wean loss rate. Overall, plasmid GHRH administration decreased morbidity and mortality in treated females and their offspring over three consecutive pregnancies.

Plasmid-based expression technology using growth hormone releasing hormone: a novel method for physiologically stimulating long-term growth hormone secretion.

Novel DNA-based technologies were recently introduced for various purposes, such as screening of targets identified from genomic projects, shuffled molecules for vaccination, or to direct the in vivo production of hormones and other peptides for therapeutic or preventative applications. We have used a plasmid-based technology to deliver growth hormone releasing hormone (GHRH) to various animal species for screening, toxicology and therapy. A single intramuscular injection of a low dose of plasmid followed by electroporation can ensure that the target species will produce physiological levels of GHRH for extended periods of time, which would replace costly, frequent injections of the recombinant hormone and improve the quality of life and compliance of patients. This therapeutic modality is of particular importance in circumstances requiring long-term administration of small molecules with naturally short half-life (e.g. treatment of anemia and cachexia associated with renal failure, cancer or other chronic disability). A similar technique was used to create, test and validate protease-resistant analogs of GHRH with significantly longer half-life. Analysis of the characteristics of each of the plasmid components and tissue-specific transcription factors and the choice of target tissue is imperative when designing plasmids for therapeutic applications. Using the species-specific sequences of GHRH or other molecule along with the appropriate choice of plasmid backbone and expression cassette components can result in long and steady expression of the transgene product.

Growth hormone releasing hormone plasmid supplementation, a potential treatment for cancer cachexia, does not increase tumor growth in nude mice.

Growth hormone releasing hormone (GHRH) is known to have multiple anabolic effects and immune-stimulatory effects. Previous studies suggest that treatment with anabolic hormones also has the potential to mitigate the deleterious effects of cancer cachexia in animals. We studied the effects of plasmid-mediated GHRH supplementation on tumor growth and the role of antitumor immune cells with two different human tumor cell lines, NCI-H358 human bronchioalveolar carcinoma and MDA-MB-468 human breast adenocarcinoma, subcutaneously implanted in nude mice. GHRH supplementation by delivery of human GHRH from a muscle-specific GHRH expression plasmid did not increase tumor progression in tumor-bearing nude mice. Male animals implanted with the NCI-H358 tumor cell line and treated with the GHRH-expressing plasmid exhibited a 40% decrease in the size of the tumors (P<.02), a 48% increase in white blood cells (P<.025) and a 300% increase in monocyte count (P<.0001), as well as an increase in the frequency of activated CD3+ and CD4+ cells in the tumors, compared to tumors of control animals. No adverse effects were observed in animals that received the GHRH-plasmid treatment. The present study shows that physiological stimulation of the GHRH-GH-IGF-I axis in mice with cancer does not promote tumor growth and may provide a viable treatment for cancer cachexia in humans.

Highly efficient constant-current electroporation increases in vivo plasmid expression.

Electroporation has been demonstrated as an effective technique for enhancing the delivery of plasmids coding for DNA vaccines and therapeutic proteins into skeletal muscle. Nevertheless, constant-voltage techniques do not take into account the resistance of the tissue and result in tissue damage, inflammation, and loss of plasmid expression. In the present study, we have used a software-driven constant-current electroporator to deliver plasmids to mice and small and large pigs. The voltage, amperage, and resistance of the tissue during pulses were recorded and analyzed. Optimal conditions of electroporation were identified in both species, and found to be highly dependent on the individual tissue resistance. Six- to 10-week-old pigs had higher muscle resistance compared to 1- to 2-year-old pigs, but both values were four to five times lower than the resistance of the mouse muscle. In mice, optimum amperage, pulse length, and lag time between plasmid injection and electroporation were identified to be 0.1 Amps, 20 msec and 0 sec. The electroporation pulse pattern among the electrodes also affected plasmid expression. These results indicate that age- and tissue-specific resistance, pulse pattern, and other variables associated with the electroporation need to be optimized for each separate species to achieve maximum plasmid expression.

Optimization of electroporation parameters for the intramuscular delivery of plasmids in pigs.

Increased transgene expression after plasmid transfer to the skeletal muscle is obtained with electroporation in many species, but optimum conditions are not well defined. Using a plasmid with a muscle-specific secreted embryonic alkaline phosphatase (SEAP) gene, we have optimized the electroporation conditions in a large mammal (pig). Parameters tested included electric field intensity, number of pulses, lag time between plasmid injection and electroporation, and plasmid delivery volume. Electric pulses, between 0.4 and 0.6 Amp constant current, applied 80 sec after the injection of 0.5 mg SEAP-expressing plasmid in a total volume of 2 mL produced the highest levels of expression. Further testing demonstrated that electroporation of a nondelineated injection site reduces the levels of SEAP expression. These results demonstrate that electroporation parameters such as amperage, lag time, and the number of pulses are able to regulate the levels of reporter gene expression in pigs.

Effects of administration of two growth hormone-releasing hormone plasmids to gilts on sow and litter performance for the subsequent three gestations.

OBJECTIVE: To determine whether a novel optimized plasmid carrying the porcine growth hormone-releasing hormone (GHRH) wild-type cDNA administered at a lower dose was as effective at eliciting physiologic responses as a commercial GHRH plasmid approved for use in Australia. ANIMALS: 134 gilts. PROCEDURES: Estrus was synchronized and gilts were bred. Pregnant gilts were assigned to 2 treatment groups (40 gilts/group) or 1 untreated control group (24 gilts). Gilts in one of the treatment groups received the commercial GHRH plasmid, whereas gilts in the other treatment group received a novel optimized GHRH plasmid; both plasmids were administered IM in the right hind limb, which was followed by electroporation. Sow and litter performance were monitored for the 3 gestations after treatment. RESULTS: A significant increase in insulin-like growth factor-I concentrations, decrease in perinatal mortality rate, increase in the number of pigs born alive, and increase in the weight and number of pigs weaned were detected for both groups receiving the GHRH-expressing plasmids, compared with values for the control group. Additionally, there was a significant decrease in sow attrition in GHRH-treated females, compared with attrition in the control group, during the 3 gestations after treatment. CONCLUSIONS AND CLINICAL RELEVANCE: Both of the GHRH plasmids provided significant benefits for sow performance and baby pig survivability for pregnant and lactating sows and their offspring during the 3 gestations after treatment, compared with results for untreated control gilts. Use of a novel optimized plasmid reduced the effective plasmid dose in these large mammals.

Parameters for DNA vaccination using adaptive constant-current electroporation in mouse and pig models.

Enhancing the expression of DNA vaccines requires that specific conditions of delivery are optimized. We describe experiments using adaptive constant-current electroporation (EP) in mice and pigs examining parameters such as target muscle, delay between plasmid delivery and onset of EP pulses and DNA vaccine formulation; our studies show that concentrated formulations result in better expression and immunogenicity. Furthermore, various conditions of EP that limit the amount of muscle damage were measured. The results of these studies will help to advance the success of DNA vaccines in animals into success in human clinical trials.

Maternal GHRH plasmid administration changes pituitary cell lineage and improves progeny growth of pigs.

Previous studies from our laboratory have demonstrated that administration of a myogenic plasmid that encodes a protease-resistant growth hormone-releasing hormone (HV-GHRH) to pregnant rat dams augmented long-term growth in first-generation progeny. In the present study, gilts were injected intra-muscularly at day 85 of gestation with 0, 0.1, 0.5, 1, or 5 mg of the HV-GHRH-expressing plasmid and were then electroporated. Piglets were weighed and bled periodically from birth to 100 kg. Piglets from gilts treated with 1 and 5 mg of HV-GHRH plasmid were larger at birth and weaning compared with controls. These two groups reached 100 kg 9 days earlier than the other groups. GHRH levels were increased at birth in piglets from treated gilts. IGF-I levels were significantly increased in the 5-mg group beginning at 21 days of age compared with controls. Pituitaries from the 5-mg group contained a significantly increased number of somatotrophs and lactotrophs from birth to 100 kg. This study confirms that enhanced maternal GHRH production results in intergenerational growth augmentation and that the magnitude of the response is dose dependent. The similarity of the response across species suggests that the effect is likely exerted as a fundamental component of gestational and developmental physiology.

Effects of plasmid-mediated growth hormone-releasing hormone supplementation on LL-2 adenocarcinoma in mice.

This study was designed to measure the effects of plasmid growth hormone-releasing hormone (GHRH) supplementation on LL-2 (Lewis lung adenocarcinoma) tumor-bearing immunocompetent mice. Male and female mice (n = 20/group/experiment) received 2.5 x 10(6) LL-2 cells in the left flank. One day later, we injected the mice intramuscularly with 20 micro g of a myogenic plasmid, pSP-hGHRH or pSP-betagal, as a control. Mean serum IGF-I was significantly higher in treated animals versus controls (P < 0.05). Male and female mice constitutively expressing GHRH exhibited a decline in tumor growth rate relative to controls (20% for males, P < 0.03, and 11% for females, P < 0.13). Histopathological analysis revealed that treated animals were less likely to develop lung metastases than controls (11%) and had no alternate-organ metastases. The number of metastases/lung was reduced by 57% in female mice with GHRH treatment (P < 0.006). When tumor size exceeded 8% of body weight, GHRH-treated mice showed normal urea, creatinine, and kidney volume, while controls displayed signs of renal insufficiency. This study provides evidence that with plasmid-mediated GHRH supplementation in tumor-bearing mice, tumor growth rate is not increased but is actually attenuated.