Vectorisation de molécules thérapeutiques aux tissus cérébraux / Drug delivery to the central nervous system

Nieto Montesinos, Rita Milagros

19 February 2014

La présence de la glycoprotéine P (P-gp) dans la barrière hémato-encéphalique (BHE) conduit à l’échec de nombreuses thérapies ciblant le système nerveux central (SNC). Cependant la P-gp protège aussi le cerveau contre des composés nocifs, essentiellement lipophiles, endogènes et exogènes susceptibles de passer la BHE par diffusion simple. Par conséquent, toute inhibition de la P-gp qui vise à améliorer la distribution des agents pharmacologiques dans le cerveau doit prendre en compte la neurotoxicité potentielle de cette inhibition. Les premiers travaux ont montré que l’elacridar et le tariquidar, deux modulateurs de la P-gp de troisième génération, augmentaient la distribution dans le cerveau de plusieurs de ses substrats. Malheureusement, d’autres études plus récentes, suggèrent l’utilisation de doses élevées de l’elacridar et du tariquidar pour moduler efficacement l’activité de la P-gp dans la BHE. Néanmoins, ces doses élevées en co-administration avec des substrats de la P-gp peuvent être associées à des interactions pharmacocinétiques et à des profils toxiques, limitant ainsi l'utilisation de ces inhibiteurs.Dans ce contexte, l’objectif principal de cette thèse est d’obtenir une modulation transitoire mais efficace de la P-gp dans la BHE par administration intraveineuse de doses faibles mais thérapeutiques de l’elacridar et du tariquidar sous leur forme libre ou co-encapsulé dans les liposomes. Le lopéramide, substrat de la P-gp, a été également administré sous sa forme libre comme une preuve in vivo d’une inhibition efficace de la P-gp dans la BHE.L'administration simultanée de ces deux modulateurs de la P-gp n’a pas modifié leurs concentrations plasmatiques ou celles du lopéramide, mais a entraîné une importante distribution du lopéramide dans le cerveau en raison de leur activité inhibitrice non- compétitive. De plus, la co-encapsulation de l’elacridar et du tariquidar dans des immunoliposomes stabilisées stériquement a amélioré la demi-vie et la distribution dans le cerveau des ceux deux composés. Par conséquent, la distribution dans le cerveau du lopéramide a été considérablement augmentée, sans aucune modification de sa pharmacocinétique ou distribution tissulaire. Par ailleurs, la diminution partielle de l'activité inhibitrice du tariquidar par des liposomes vides suggère l’utilisation de ce nanovecteur comme une approche de bio-détoxification pour le traitement des surdoses de tariquidar. En résumé, cette thèse propose différentes approches pour exploiter pleinement l’elacridar et le tariquidar. Les résultats décrits dans ce manuscrit devraient ouvrir des pistes intéressantes pour atteindre une inhibition efficace de la P-gp dans la BHE et pour réussir des thérapies ciblant le système nerveux central / Although the P-glycoprotein (P-gp) represents an obstacle in several central nervous system (CNS) pharmacotherapies, the P-gp also protects the brain from intoxication by endogenous and exogenous harmful lipophilic compounds that otherwise could penetrate the blood-brain barrier (BBB) by simple diffusion. Therefore, any modulation of the efflux transporter has to consider the potential neurotoxicity of such modulation. Early studies showed that elacridar and tariquidar, two third-generation P-gp modulators, increase the distribution of several P-gp substrates in the brain. Unfortunately, recent studies suggest the use of high doses of elacridar and tariquidar to efficiently modulate the P-gp at the BBB. Nevertheless, when co-administered with P-gp substrates, these high doses may be associated with pharmacokinetic interactions and toxic profiles, thus limiting the use of these compounds.Hence, this thesis aimed to attain a transient but efficient modulation of the P-gp at the BBB using elacridar and tariquidar but avoiding the use of large doses of these compounds. For this purpose we took advantage of the possible in vivo intravenous co-administration of low but therapeutic doses of elacridar and tariquidar, under their free form or co-encapsulated in liposomes. The brain distribution of free loperamide was determined as an in vivo probe of full inhibition of the P-gp activity at the BBB.The concurrent administration of both free P-gp modulators does not modify their plasma concentrations or those of the P-gp substrate but significantly increased the brain uptake of loperamide as a result of their non-competitive modulatory activity. Moreover, the co-encapsulation of elacridar and tariquidar in targeted sterically stabilized immunoliposomes improved the half-lives and brain distribution of both compounds. Consequently, the brain uptake of free loperamide was significantly enhanced without any modification of its pharmacokinetics or tissue distribution. Moreover, the partial impairment of the modulatory activity of tariquidar by empty liposomes, supports the use of this nanocarrier as a bio-detoxifying approach for the treatment of tariquidar overdoses.In summary, this thesis proposes different approaches for full exploitation of elacridar and tariquidar. The findings described in this manuscript should open interesting avenues to achieve an efficient overcoming of the P-gp at the BBB and succeed CNS pharmacotherapies.

Glycoprotéine P

Barrière hémato-encéphalique

Elacridar

Tariquidar

Co-administration

Liposomes

P-glycoprotein

Blood-brain barrier

Elacridar,

Tariquidar

Co-administration,

Liposomes

Molecular Markers of Sensitivity to the Anticancer Effects of Different Statins in Human Tumour Cell Lines

Goard, Carolyn Anna

20 June 2014

Statins, common cholesterol control drugs, are appreciated to have promising anticancer activity through inhibition of the mevalonate pathway. Several lines of evidence suggest that certain tumours are susceptible to statins, but the underlying molecular features arbitrating this sensitivity remain unknown. We hypothesize that (i) not all statins will behave equivalently in the context of anticancer therapy, and (ii) a molecularly-defined subset of tumours are intrinsically sensitive to statins. My objectives have therefore been to further our understanding of functional differences between statins influencing their anticancer effects, and to investigate molecular features associated with statin sensitivity in breast cancer. Specifically, this thesis addresses two aims: (i) to characterize differential interactions between four statins and the xenobiotic transporter P-glycoprotein (P-gp; also known as ABCB1), and (ii) to identify molecular features associated with fluvastatin and lovastatin sensitivity in breast tumour cell lines. We first characterized the interactions of statins with P-gp in vitro and in multidrug-resistant (MDR) tumour cells. While lovastatin could directly bind to P-gp and modulate MDR, no significant interactions were observed with fluvastatin. Fluvastatin may therefore be appropriate for use in unselected patients, to avoid adverse drug interactions with coadministered P-gp substrate chemotherapeutics. Fluvastatin has also shown promise in breast cancer treatment, where molecular features predictive of statin sensitivity would be particularly valuable. A panel of 19 immortalized breast cell lines was therefore characterized for sensitivity to fluvastatin and lovastatin. Relatively statin-sensitive cells underwent apoptosis upon statin treatment, and were more likely to have an estrogen receptor alpha (ERα)-negative, basal-like phenotype. By mining available baseline gene expression data, a candidate 10-gene signature predictive of fluvastatin sensitivity was also generated. Taken together, this research provides insight into molecular markers of statin sensitivity that may facilitate fast-tracking of these drugs to clinical trials in subsets of cancer patients most likely to respond.

statin

P-glycoprotein

breast cancer

drug resistance

HMG-CoA reductase

mevalonate

0760 Medical Biophysics

0307 Molecular Biology

Structural and functional study of efflux pumps involved in drug resistance

Martinez Jaramillo, Lorena Marcela

14 February 2014

Resistance to chemotherapy is partly due to efflux pumps expressed in the plasma membrane which prevents the accumulation of anticancer, antiviral, antifungal and antibacterial drugs in target cells. Three human ABC transporters are particularly involved in MDR phenotype: P-gp/ABCB1, MRP1/ABCC1 and BCRP/ABCG2. Among the different approaches used to overcome the resistance linked to these transporters, the development of non-substrate drugs MDR-ABC transporters has been described. Here, new class of HIV-1 protease inhibitors not recognized by P-gp/BCRP were identified, promising to be attractive candidates to HAART therapy. Since the determination of the X-ray structures in different conformations is a key point to understand how MDR-ABC transporters translocate drugs across the plasma membrane, the crystal structures of three inward-facing conformations of mouse P-gp were resolved. One structure has a camel nanobody bound to the C-terminal side of the first nucleotide-binding domain, revealing a unique epitope on P-gp and freezing a new open-inward conformation. Finally, the enzymatic characterization of two inhibitors co-crystallized with the mouse P-gp has allowed to localize two main binding sites by which drugs efflux occurs. These results bring new findings of the drug-efflux mechanism and offer the possibility to target more precisely those sites to develop modulators of this pump

ABC transporters

P-glycoprotein

Screening

X-ray structures

Binding sites

Intestinal Permeability and Presystemic Extraction of Fexofenadine and R/S-verapamil

Tannergren, Christer

January 2004

The main objective of this thesis was to investigate the in vivo relevance of membrane transporters and cytochrome P450 (CYP) 3A4-mediated metabolism in the intestine and liver for the bioavailability of drugs in humans after oral administration. In the first part of the thesis, the main transport mechanisms involved in the intestinal absorption and bioavailability were investigated for fexofenadine, a minimally metabolized drug, which is a substrate for P-glycoprotein (P-gp) and members of organic anion transporting polypeptide (OATP) family. Jejunal perfusion studies revealed that co-perfusion with verapamil increased the bioavailability of fexofenadine by decreasing the first-pass liver extraction as the low intestinal permeability was unchanged by the transport inhibitors studied. The mechanism behind the interaction probably involves inhibition of OATP-mediated sinusoidal uptake and/or P-gp-mediated canalicular secretion of fexofenadine. Results from the Caco-2 model supported that the intestinal absorption of fexofenadine is mainly determined by the low passive permeability of the drug, even though fexofenadine clearly is a P-gp substrate. In the second part of the thesis, the effect of repeated oral administration of the P-gp and CYP3A4 inducer St. John’s wort on the in vivo intestinal permeability and presystemic metabolism of the dual P-gp and CYP3A4 substrate verapamil was investigated in a jejunal perfusion study. St. John’s wort decreased the bioavailability of the enantiomers of verapamil by inducing the CYP3A4-mediated presystemic metabolism, probably mainly in the gut. It was also concluded that induction of efflux transporters, such as P-gp, does not affect the intestinal transport or the gut wall extraction of high permeability substrates like verapamil. Data from Caco-2 cells with induced CYP3A4-activity supported these findings. The plasma levels of the enantiomers of norverapamil also decreased despite an increased formation, which was attributed to induction of CYP3A4 and/or other metabolic routes.

Biopharmacy

Bioavailability

Fexofenadine

Verapamil

P-glycoprotein

CYP3A4

OATP

Enantioselective

Permeability

Caco-2

Intestinal perfusion

Biofarmaci

Biopharmacy

Biofarmaci

Involvement of Membrane Transport Proteins in Intestinal Absorption and Hepatic Disposition of Drugs Using Fexofenadine as a Model Drug

Petri, Niclas

January 2005

The aims of this thesis were to study the in vivo relevance of membrane transporters for intestinal absorption and the hepatic disposition of drugs in humans and preclinical models. Fexofenadine is a substrate for ABCB1 (P-glycoprotein) and members of the organic anion transporting polypeptide (OATP/SLCO) family. It is marginally metabolised in humans. The influence of known inhibitors of ABCB1 and OATPs on the membrane transport and pharmacokinetics of fexofenadine was investigated in Caco-2 and porcine models and in humans. The permeability of fexofenadine remained low, even when significantly altered by the addition of an inhibitor. Using the Loc-I-Gut® technique in vivo in humans, it was possible to see that the jejunal effective permeability of fexofenadine was unchanged when given with verapamil. However, the systemic exposure and apparent absorption rate of fexofenadine increased. This suggests that the first-pass liver extraction of fexofenadine was reduced by verapamil, probably through the inhibition of sinusoidal OATP-mediated and/or canalicular ABCB1-mediated secretion. The unchanged permeability can be explained by simultaneous inhibition of jejunal apical OATP-uptake and ABCB1-efflux, which would leave fexofenadine to be transported by passive trancellular diffusion. A Loc-I-Gut® perfusion in the porcine model enabling blood sampling in the portal and hepatic veins and bile collection revealed increased jejunal permeability, but no subsequent verapamil-induced elevation in the systemic exposure of fexofenadine. This indicates a species-related difference in the localisation of and/or the substrate specificity of fexofenadine for the transporters involved. The absence of an effect on the first-pass liver extraction in the porcine model might be caused by the observed lower liver exposure of verapamil. Finally, a novel intubation technique enabling dosing of fexofenadine in the jejunum, ileum and the colon showed that fexofenadine was absorbed less along the length the intestine in agreement with the properties of a low permeability drug.

Biopharmacy

Fexofenadine

OATP

P-glycoprotein

Organic Anion Transporters

ATP-Binding Cassette Transporters

membrane transport proteins

Bioavailability

Biopharmaceutics

Biofarmaci

Biopharmacy

Biofarmaci

A novel approach to circumvent P-glycoporotein mediated cellular efflux and permeability enhancement of HIV protease inhibitor saquinavir

Jain, Ritesh, Mitra, Ashim K.,

January 2007

Thesis (Ph. D.)--School of Pharmacy. University of Missouri--Kansas City, 2007. / "A dissertation in pharmaceutical science and pharmacology." Advisor: Ashim K. Mitra. Typescript. Vita. Title from "catalog record" of the print edition Description based on contents viewed July 16, 2008. Includes bibliographical references (leaves 231-248). Online version of the print edition.

Etude expérimentale de la variabilité des effets respiratoires de la buprénorphine : rôle de la P-glycoprotéine et de l’acquisition d’une tolérance aux opioïdes / Experimental study of variability of buprenorphine-related respiratory effects : role of P-glycoprotein and tolerance acquisition

Alhaddad, Hisham

14 May 2013

La buprénorphine (BUP) peut être responsable d’une dépression respiratoire à l’origine d’intoxications graves parfois mortels. Cependant, les mécanismes exacts de ces effets respiratoires délétères ne sont pas encore clairement établis. Les objectifs de cette thèse étaient d’analyser la variabilité des effets respiratoires de la BUP en y intégrant : 1) le rôle exact de la P-glycoprotéine (P-gp) 2) le rôle de l’acquisition d’une tolérance aux opioïdes, tout en précisant les différences potentielles entre tolérance aux effets analgésiques et respiratoires et les mécanismes moléculaires mis en jeu. Pour cela, nous avons étudié en pléthysmographie les effets respiratoires de la BUP et de son métabolite actif la norbuprénorphine (NBUP) chez la souris Fvb femelle. Nous avons mesuré leur transport par la P-gp à la barrière hémato-encéphalique (BHE) en perfusion cérébrale in situ, après inhibition pharmacologique ou suppression du gène codant pour la P-gp. Nous avons étudié la part de variabilité dans ces effets, attribuable au sexe et à la souche de souris. Nous avons ainsi démontré que la P-gp exprimée à la BHE joue un rôle-clé dans la protection contre les effets respiratoires délétères induits par la BUP, en empêchant l’entrée dans le compartiment encéphalique de son métabolite, la NBUP. Nous avons observé que les souris Fvb femelles sont plus sensibles à la toxicité respiratoire de la BUP que les souris Fvb mâles qui sont, eux-mêmes plus sensibles à ces effets que les souris Swiss mâles, sans que la P-gp ne soit à aucun moment impliquée dans cette variabilité. Enfin, nous avons montré qu’une tolérance aux effets analgésiques et respiratoires de la BUP se développe de façon significativement plus réduite chez les souris Fvb déficientes en P-gp, suggérant un rôle crucial pour ce transporteur dans l’acquisition et l’expression de la tolérance à la BUP. Par ailleurs, nous avons montré qu’après administration répétée de morphine, apparait une tolérance plus faible à ses effets respiratoires qu’à ses effets analgésiques. La mise en évidence d’une superactivation de l’adénylate cyclase dans la région périaqueducale impliquée dans les effets antinociceptifs des opioïdes, et non dans le tronc cérébral qui contient les centres de régulation de la ventilation, pourrait au moins en partie, expliquer cette différence d’intensité de tolérance observée. Enfin, pour compléter nos travaux expérimentaux, nous avons réalisé deux mini-revues bibliographiques pour, d’une part faire la synthèse des mécanismes de la tolérance aux opioïdes et de leur rôle dans la dépression respiratoire et d’autre part, analyser les situations déjà rapportées d’effets cliniques nés d’interactions médicamenteuses médiées par la P-gp. / Buprenorphine (BUP) may be responsible for respiratory depression resulting in serious andsometimes fatal poisonings. However, the exact mechanisms leading to these deleterious respiratoryeffects still remain unclear. The objectives of this thesis were to study the variability of BUP-inducedrespiratory effects by focusing on: 1) the involvement of P-glycoprotein 2) the role of tolerance to opioids in addition to investigating possible differences among tolerance to opioid-related antinociceptive and respiratory effects as well as the involved molecular mechanisms. We studied the respiratory effects of BUP and its active metabolite, norbuprenorphine (NBUP) using plethysmography in female Fvb mice. We measured P-gp-related transport of BUP and NBUP at the blood-brain barrier (BBB) using in situ brain perfusion after pharmacological P-gp inhibition as well as in P-gp knock-out mice. We also studied the role of gender and mice strain in the variability of BUP-related respiratory effects. We showed that P-gp at the BBB plays a key-protective role against BUP-related respiratory effects by limiting NBUP distribution into the brain. We observed that female Fvb mice are more sensitive to BUP-induced deleterious respiratory effects than male Fvb mice thatare more sensitive than male Swiss mice. Furthermore, we assessed that gender- and strain-attributedvariability is not related to P-gp. Finally, we demonstrated that tolerance to BUP-induced antinociceptive and respiratory effects is significantly reduced in P-gp knockout mice in comparison to controls, suggesting a critical role for P-gp in tolerance to BUP. In parallel, we showed that repeated administration of morphine results in reduced tolerance to its respiratory effects in comparison to its antinociceptive effects. Adenylate cyclase super-activation that we evidenced in the periaqueductal grey matter, the area involved in opioid-related analgesia control, but not in the brainstem, the area that contains centres of ventilation regulation, may at least in part be responsible for these observed differences in tolerance. Finally, to complete our experimental researches, we performed two mini-reviews, aiming at summarizing the various mechanisms of tolerance and their involvement in respiratory depression in addition to highlighting the importance of drug-drug interactions leading to P-glycoprotein inhibition in the occurrence of deleterious clinical effects.

P-glycoprotéine

Buprénorphine

Variabilité

Dépression respiratoire

Pléthysmographie

Souris

P-glycoprotein

Buprenorphine

Variability

Respiratory depression

Plethysmography

Mice

615.9

Vectorisation de molécules thérapeutiques aux tissus cérébraux / Drug delivery to the central nervous system

Nieto Montesinos, Rita Milagros

19 February 2014

La présence de la glycoprotéine P (P-gp) dans la barrière hémato-encéphalique (BHE) conduit à l’échec de nombreuses thérapies ciblant le système nerveux central (SNC). Cependant la P-gp protège aussi le cerveau contre des composés nocifs, essentiellement lipophiles, endogènes et exogènes susceptibles de passer la BHE par diffusion simple. Par conséquent, toute inhibition de la P-gp qui vise à améliorer la distribution des agents pharmacologiques dans le cerveau doit prendre en compte la neurotoxicité potentielle de cette inhibition. Les premiers travaux ont montré que l’elacridar et le tariquidar, deux modulateurs de la P-gp de troisième génération, augmentaient la distribution dans le cerveau de plusieurs de ses substrats. Malheureusement, d’autres études plus récentes, suggèrent l’utilisation de doses élevées de l’elacridar et du tariquidar pour moduler efficacement l’activité de la P-gp dans la BHE. Néanmoins, ces doses élevées en co-administration avec des substrats de la P-gp peuvent être associées à des interactions pharmacocinétiques et à des profils toxiques, limitant ainsi l'utilisation de ces inhibiteurs.Dans ce contexte, l’objectif principal de cette thèse est d’obtenir une modulation transitoire mais efficace de la P-gp dans la BHE par administration intraveineuse de doses faibles mais thérapeutiques de l’elacridar et du tariquidar sous leur forme libre ou co-encapsulé dans les liposomes. Le lopéramide, substrat de la P-gp, a été également administré sous sa forme libre comme une preuve in vivo d’une inhibition efficace de la P-gp dans la BHE.L'administration simultanée de ces deux modulateurs de la P-gp n’a pas modifié leurs concentrations plasmatiques ou celles du lopéramide, mais a entraîné une importante distribution du lopéramide dans le cerveau en raison de leur activité inhibitrice non- compétitive. De plus, la co-encapsulation de l’elacridar et du tariquidar dans des immunoliposomes stabilisées stériquement a amélioré la demi-vie et la distribution dans le cerveau des ceux deux composés. Par conséquent, la distribution dans le cerveau du lopéramide a été considérablement augmentée, sans aucune modification de sa pharmacocinétique ou distribution tissulaire. Par ailleurs, la diminution partielle de l'activité inhibitrice du tariquidar par des liposomes vides suggère l’utilisation de ce nanovecteur comme une approche de bio-détoxification pour le traitement des surdoses de tariquidar. En résumé, cette thèse propose différentes approches pour exploiter pleinement l’elacridar et le tariquidar. Les résultats décrits dans ce manuscrit devraient ouvrir des pistes intéressantes pour atteindre une inhibition efficace de la P-gp dans la BHE et pour réussir des thérapies ciblant le système nerveux central / Although the P-glycoprotein (P-gp) represents an obstacle in several central nervous system (CNS) pharmacotherapies, the P-gp also protects the brain from intoxication by endogenous and exogenous harmful lipophilic compounds that otherwise could penetrate the blood-brain barrier (BBB) by simple diffusion. Therefore, any modulation of the efflux transporter has to consider the potential neurotoxicity of such modulation. Early studies showed that elacridar and tariquidar, two third-generation P-gp modulators, increase the distribution of several P-gp substrates in the brain. Unfortunately, recent studies suggest the use of high doses of elacridar and tariquidar to efficiently modulate the P-gp at the BBB. Nevertheless, when co-administered with P-gp substrates, these high doses may be associated with pharmacokinetic interactions and toxic profiles, thus limiting the use of these compounds.Hence, this thesis aimed to attain a transient but efficient modulation of the P-gp at the BBB using elacridar and tariquidar but avoiding the use of large doses of these compounds. For this purpose we took advantage of the possible in vivo intravenous co-administration of low but therapeutic doses of elacridar and tariquidar, under their free form or co-encapsulated in liposomes. The brain distribution of free loperamide was determined as an in vivo probe of full inhibition of the P-gp activity at the BBB.The concurrent administration of both free P-gp modulators does not modify their plasma concentrations or those of the P-gp substrate but significantly increased the brain uptake of loperamide as a result of their non-competitive modulatory activity. Moreover, the co-encapsulation of elacridar and tariquidar in targeted sterically stabilized immunoliposomes improved the half-lives and brain distribution of both compounds. Consequently, the brain uptake of free loperamide was significantly enhanced without any modification of its pharmacokinetics or tissue distribution. Moreover, the partial impairment of the modulatory activity of tariquidar by empty liposomes, supports the use of this nanocarrier as a bio-detoxifying approach for the treatment of tariquidar overdoses.In summary, this thesis proposes different approaches for full exploitation of elacridar and tariquidar. The findings described in this manuscript should open interesting avenues to achieve an efficient overcoming of the P-gp at the BBB and succeed CNS pharmacotherapies.

Glycoprotéine P

Barrière hémato-encéphalique

Elacridar

Tariquidar

Co-administration

Liposomes

P-glycoprotein

Blood-brain barrier

Elacridar,

Tariquidar

Co-administration,

Liposomes

Combating Multidrug Resistant Reservoirs in HIV and Bacterial Pathogens

Moises Morales Padiilla (8766684)

21 June 2022

<p>Multidrug resistance is a major issue in treatment and eradication of diseases. There are many mechanisms by which pathogens develop multi drug resistance. Here we focus on the ability of pathogens to evade drug treatment by establishing multi drug resistant reservoirs. In the case of HIV, the virus is able to evade drug treatment and forms both latent and active replicating reservoirs throughout the body. In the case of many bacterial pathogens, multidrug resistance reservoirs are established within mammalian cells, such as macrophages. Many classes of antibiotics are unable to penetrate mammalian cells, making intracellular bacteria difficult to clear</p><p>Previously our research group has developed a Trojan horse strategy to deliver antivirals to HIV cellular reservoirs. Ester based prodrug dimers of abacavir, a reverse transcriptase inhibitor, acted to both inhibit efflux transporters at the BBB and revert to the monomeric therapy in the reducing environments of the cell. Herein we present a new group of sterically hindered carbonate based disulfide linkers that shows improved payload delivery of abacavir and maintain the stability of prodrug molecules towards hydrolysis. We employed these linker molecules to synthesize prodrug dimers of the HIV latency reversal agent prostratin with the hope of targeting latent HIV reservoirs. Payload release studies as well as latency reversal experiments with a latently infected T-helper cell model confirmed that the prostratin carbonate homodimers (<b>ProS₂Me₂</b> and <b>ProS₂Me₄</b>) were able to revert to monomeric prostratin and reverse HIV latency. We next sought to synthesize a prostrain-protease inhibitor heterodimer. While our initial study of a prostratin-lopinavir heterodimer employing this linker strategy (<b>ProLpvS₂Me₂</b>) did not show significant HIV latency reversal activity, we hope to expand our heterodimer studies to achieve dual therapeutic molecules that can both reverse HIV latency and deliver antivirals to HIV reservoirs.</p><p>In order to combat intracellular bacteria our group has focused on development of a novel class of cell penetrating peptides with intrinsic broad spectrum antimicrobial activity that are based on a repeating amino acid triad which forms a cationic amphiphilic polyproline helix (CAPH) scaffold. The first member of this class, <b>P14LRR</b>, exhibited clearance of intracellular bacteria and concentration dependent co-localization within mammalian cells. In efforts to optimize antimicrobial activity we have expanded the CAPHs library by adjusting the chain length between the proline backbone and the guanadinium groups of the cationic amino acids. The first peptide from this expanded library, <b>P14GAP</b> showed much greater cell penetration and antimicrobial activity against a wide range of pathogenic bacteria. However, <b>P14GAP</b> also showed greater toxicity towards mammalian cells, increased hemolysis, and greater membrane binding with mammalian cells as compared to <b>P14LRR</b>. Here we describe the design and synthesis of <b>P14GAP-C1</b>, which contains a methylene between the proline backbone and the guanadinium group. This new analogue decreased the hemolysis activity as compared to <b>P14GAP</b>, although similar membrane binding with mammalian cells was observed. This improvement in hemolysis activity and a slight improvement in cell viability may allow us to use higher concentrations of peptide to treat multidrug resistant bacterial infections.</p><p> </p>

HIV

multidrug resistance

P-glycoprotein

prodrugs

Latent HIV

antibacterial

Peptide

Cationic Amphiphilic Peptides

Organic Chemistry

Inhibiting Efflux With Novel Non-Ionic Surfactants: Rational Design Based on Vitamin E TPGS

Wempe, Michael F., Wright, Charles, Little, James L., Lightner, Janet W., Large, Shannon E., Caflisch, George B., Buchanan, Charles M., Rice, Peter J., Wacher, Vincent J., Ruble, Karen M., Edgar, Kevin J.

31 March 2009

Tocopheryl Polyethylene Glycol Succinate 1000 (TPGS 1000) can inhibit P-glycoprotein (P-gp); TPGS 1000 was not originally designed to inhibit an efflux pump. Recent work from our laboratories demonstrated that TPGS activity has a rational PEG chain length dependency. In other recent work, inhibition mechanism was investigated and appears to be specific to the ATPase providing P-gp energy. Based on these observations, we commenced rational surface-active design. The current work summarizes new materials tested in a validated Caco-2 cell monolayer model; rhodamine 123 (10 μM) was used as the P-gp substrate. These results demonstrate that one may logically construct non-ionic surfactants with enhanced propensity to inhibit in vitro efflux. One new surfactant based inhibitor, Tocopheryl Polypropylene Glycol Succinate 1000 (TPPG 1000), approached cyclosporine (CsA) in its in vitro efflux inhibitory potency. Subsequently, TPPG 1000 was tested for its ability to enhance the bioavailability of raloxifene - an established P-gp substrate - in fasted male rats. Animals dosed with raloxifene and TPPG 1000 experienced an increase in raloxifene oral bioavailability versus a control group which received no inhibitor. These preliminary results demonstrate that one may prepare TPGS analogs that possess enhanced inhibitory potency in vitro and in vivo.

caco-2 cell monolayers

efflux ratio

P-glycoprotein

vitamin E TPGS

Internal Medicine