Hemachand Tummala

Identification of a Novel Skin Penetration Enhancement Peptide by Phage Display Peptide Library Screening

Skin is an important site for local or systemic application of drugs. However, a majority of drugs have poor permeability through the skins topmost layer, stratum corneum (SC). The aim of this study was to identify safe and smaller peptides that could enhance the skin penetration of drug molecules. By screening phage display peptide library, we have identified a T2 peptide (LVGVFH), which enhanced the penetration of bacteriophages (~800 nm long bacterial viruses) across porcine and mouse skin. Pretreating the skin with synthetic T2 peptide at pH 4.5 resulted in significant penetration enhancement of hydrophilic drug 5-fluorouracil (5-FU) across skin. FTIR spectroscopy showed that the T2 peptide interacted with skin lipids to enhance the skin penetration. Pretreating the skin with T2 peptide enhanced the partitioning of small molecules with different lipophilicities (5-FU, fluorescein isothiocyanate, and rhodamine 123 hydrochloride) into skin. Fluorescence studies showed that T2 peptide enhanced the diffusion of these molecules into intercellular lipids of SC and thus enhanced the penetration into the skin. Histidine at the c-terminus of T2 peptide was identified to be critical for the skin penetration enhancement. T2 peptide interacted with skin lipids to cause skin penetration enhancement. The study identified a novel, safe, and noninvasive peptide to improve the skin penetration of drugs without chemical conjugation.

Cyclin A2 and CDK2 as Novel Targets of Aspirin and Salicylic Acid: A Potential Role in Cancer Prevention

Data emerging from the past 10 years have consolidated the rationale for investigating the use of aspirin as a chemopreventive agent; however, the mechanisms leading to its anticancer effects are still being elucidated. We hypothesized that aspirins chemopreventive actions may involve cell-cycle regulation through modulation of the levels or activity of cyclin A2/cyclin-dependent kinase-2 (CDK2). In this study, HT-29 and other diverse panel of cancer cells were used to demonstrate that both aspirin and its primary metabolite, salicylic acid, decreased cyclin A2 (CCNA2) and CDK2 protein and mRNA levels. The downregulatory effect of either drugs on cyclin A2 levels was prevented by pretreatment with lactacystin, an inhibitor of proteasomes, suggesting the involvement of 26S proteasomes. In-vitro kinase assays showed that lysates from cells treated with salicylic acid had lower levels of CDK2 activity. Importantly, three independent experiments revealed that salicylic acid directly binds to CDK2. First, inclusion of salicylic acid in naïve cell lysates, or in recombinant CDK2 preparations, increased the ability of the anti-CDK2 antibody to immunoprecipitate CDK2, suggesting that salicylic acid may directly bind and alter its conformation. Second, in 8-anilino-1-naphthalene-sulfonate (ANS)-CDK2 fluorescence assays, preincubation of CDK2 with salicylic acid dose-dependently quenched the fluorescence due to ANS. Third, computational analysis using molecular docking studies identified Asp145 and Lys33 as the potential sites of salicylic acid interactions with CDK2. These results demonstrate that aspirin and salicylic acid downregulate cyclin A2/CDK2 proteins in multiple cancer cell lines, suggesting a novel target and mechanism of action in chemoprevention. Implications: Biochemical and structural studies indicate that the antiproliferative actions of aspirin are mediated through cyclin A2/CDK2. Mol Cancer Res; 14(3); 241–52. ©2015 AACR.

Molecular complexation of curcumin with pH sensitive cationic copolymer enhances the aqueous solubility, stability and bioavailability of curcumin

Curcumin is a natural dietary compound with demonstrated potential in preventing/treating several chronic diseases in animal models. However, this success is yet to be translated to humans mainly because of its poor oral bioavailability caused by extremely low water solubility. This manuscript demonstrates that water insoluble curcumin (~1μg/ml) forms highly aqueous soluble complexes (>2mg/ml) with a safe pH sensitive polymer, poly(butyl-methacrylate-co-(2-dimethylaminoethyl) methacrylate-co-methyl-methacrylate) when precipitated together in water. The complexation process was optimized to enhance curcumin loading by varying several formulation factors. Acetone as a solvent and polyvinyl alcohol as a stabilizer with 1:2 ratio of drug to polymer yielded complexes with relatively high loading (~280μg/ml) and enhanced solubility (>2mg/ml). The complexes were amorphous in solid and were soluble only in buffers with pHs less than 5.0. Hydrogen bond formation and hydrophobic interactions between curcumin and the polymer were recorded by infrared spectroscopy and nuclear magnetic resonance spectroscopy, respectively. Molecular complexes of curcumin were more stable at various pHs compared to unformulated curcumin. In mice, these complexes increased peak plasma concentration of curcumin by 6 times and oral bioavailability by ~20 times. This is a simple, economic and safer strategy of enhancing the oral bioavailability of curcumin.

Development of soluble inulin microparticles as a potent and safe vaccine adjuvant and delivery system.

The goal of the present study is to develop a potent and safe vaccine adjuvant that can also stabilize vaccine formulations during lyophilization and storage. Inulin is a safe plant polysaccharide, and in its water soluble isoform, it is known to stabilize protein formulations during storage. However, soluble inulins have never been shown to stimulate the immune system. In this study, for the first time, we showed that water soluble inulins could be developed into vaccine adjuvants by formulating as antigen encapsulated microparticles. A method was developed to prepare soluble inulin microparticles (sIMs) with high encapsulation efficiency (∼75%) and loading (∼75 μg/mg) of the antigen. When immunized in mice, sIMs have generated robust Th2-type antibody titers (IgG1: 500,000) compared to unadjuvanted antigens (IgG1: 17,500) or alum adjuvanted antigens (IgG1: 80,000). In vitro assays showed that a higher proportion of antigen presenting cells (APCs) have taken up the antigen when presented in sIMs versus in solution (99 % vs 22 %). In addition, the amount of antigen taken up per cell has also been enhanced by more than 25 times when antigen was presented in sIMs. Efficient uptake of the antigen by APCs through sIMS was attributed to the observed enhancement in the immune response by antigen loaded sIMs. The sIMs neither caused any granuloma/tissue damage at the injection site in mice nor were they toxic to the APCs in cell culture. In conclusion, the current study has developed a safe, soluble inulin based vaccine adjuvant and delivery system.

Aspirin and salicylic acid decrease c-Myc expression in cancer cells: a potential role in chemoprevention.

Epidemiological studies have demonstrated a significant correlation between regular aspirin use and reduced colon cancer incidence and mortality; however, the pathways by which it exerts its anti-cancer effects are still not fully explored. We hypothesized that aspirin’s anti-cancer effect may occur through downregulation of c-Myc gene expression. Here, we demonstrate that aspirin and its primary metabolite, salicylic acid, decrease the c-Myc protein levels in human HCT-116 colon and in few other cancer cell lines. In total cell lysates, both drugs decreased the levels of c-Myc in a concentration-dependent fashion. Greater inhibition was observed in the nucleus than the cytoplasm, and immunofluorescence studies confirmed these observations. Pretreatment of cells with lactacystin, a proteasome inhibitor, partially prevented the downregulatory effect of both aspirin and salicylic acid, suggesting that 26S proteasomal pathway is involved. Both drugs failed to decrease exogenously expressed DDK-tagged c-Myc protein levels; however, under the same conditions, the endogenous c-Myc protein levels were downregulated. Northern blot analysis showed that both drugs caused a decrease in c-Myc mRNA levels in a concentration-dependent fashion. High-performance liquid chromatography (HPLC) analysis showed that aspirin taken up by cells was rapidly metabolized to salicylic acid, suggesting that aspirin’s inhibitory effect on c-Myc may occur through formation of salicylic acid. Our result suggests that salicylic acid regulates c-Myc level at both transcriptional and post-transcription levels. Inhibition of c-Myc may represent an important pathway by which aspirin exerts its anti-cancer effect and decrease the occurrence of cancer in epithelial tissues.

2-Deoxyglucose Induces Cell Cycle Arrest and Apoptosisin Colorectal Cancer Cells Independent of Its Glycolysis Inhibition

2-Deoxyglucose (2DG) is an anticancer drug with excellent safety profile. Because of its higher dose requirements, its potential is yet to translate into a monotherapy. However, recently, 2DG has been tested as an adjunct in established chemotherapeutic regimens. 2DG enhanced the potency of several chemotherapeutic agents but not all. The rationale selection of known chemotherapeutic agents to use with 2DG is hampered becaue of the lack of complete understanding of mechanism behind 2DG anticancer effects. Although, 2DG is a well-known glycolytic inhibitor, which inhibits the key glycolytic enzyme hexokinase, its anticancer effects cannot be fully explained by this simplistic mechanism alone. In this article, we have shown for the first time that 2DG induced a transient expression of p21 and a continuous expression of p53 in colorectal cancer cells (SW620). The treatment also caused cell cycle arrest at G0/G1 phase and induced apoptosis through the mitochondrial pathway. The effects of 2DG on p21 and p53 protein levels were totally independent of its inhibitory effect on either hexokinase or ATP levels. Results from this study provides key insights into novel molecular mechanisms of 2DG and directs rational selection of other anticancer drugs to combine with 2DG in colorectal cancer treatment.

Pathogen-mimicking vaccine delivery system designed with a bioactive polymer (inulin acetate) for robust humoral and cellular immune responses

Abstract New and improved vaccines are needed against challenging diseases such as malaria, tuberculosis, Ebola, influenza, AIDS, and cancer. The majority of existing vaccine adjuvants lack the ability to significantly stimulate the cellular immune response, which is required to prevent the aforementioned diseases. This study designed a novel particulate based pathogen‐mimicking vaccine delivery system (PMVDS) to target antigen‐presenting‐cells (APCs) such as dendritic cells. The uniqueness of PMVDS is that the polymer used to prepare the delivery system, Inulin Acetate (InAc), activates the innate immune system. InAc was synthesized from the plant polysaccharide, inulin. PMVDS provided improved and persistent antigen delivery to APCs as an efficient vaccine delivery system, and simultaneously, activated Toll‐Like Receptor‐4 (TLR‐4) on APCs to release chemokines/cytokines as an immune‐adjuvant. Through this dual mechanism, PMVDS robustly stimulated both the humoral (>32 times of IgG1 levels vs alum) and the cell‐mediated immune responses against the encapsulated antigen (ovalbumin) in mice. More importantly, PMVDS stimulated both cytotoxic T cells and natural killer cells of cell‐mediated immunity to provide tumor (B16‐ova‐Melanoma) protection in around 40% of vaccinated mice and significantly delayed tumor progression in rest of the mice. PMVDS is a unique bio‐active vaccine delivery technology with broader applications for vaccines against cancer and several intracellular pathogens, where both humoral and cellular immune responses are desired. Graphical abstract The PMVDS is a pathogen‐mimicking, immune‐active (TLR‐4 agonist) vaccine delivery system that provides strong antibody and cell‐mediated immune responses against encapsulated antigens for efficient cancer immunotherapy. Figure. No Caption available.

In Vitro and In Vivo Antimetastatic Effect of Glutathione Disulfide Liposomes

Cancer metastasis is the major cause of cancer mortality. Despite extensive research efforts, effective treatment for cancer metastasis is still lacking. Cancer metastasis involves 4 essential steps: cell detachment, migration, invasion, and adhesion. Detachment is the first and required step for metastasis. Glutathione disulfide (GSSG) is derived from the oxidation of glutathione (GSH), which is present in biological systems in millimolar concentration. Although GSSG is commercially available, the impact of GSSG on cell functions/dysfunctions has not been fully explored due to the fact that GSSG is not cell membrane permeable and a lack of method to specifically increase GSSG in cells. We have developed GSSG liposomes that effectively deliver GSSG to cells. Unexpectedly, cells treated with GSSG liposomes were resistant to detachment by trypsinization. This observation led to the investigation of the antimetastatic effect of GSSG liposomes. Our data demonstrate that GSSG liposomes at 1 mg/mL completely blocked cell detachment and migration, and significantly inhibited cancer cell invasion. Aqueous GSSG showed no such effect, confirming that the effects on cell detachment, migration, and invasion were caused by the intracellular delivery of GSSG. An in vivo experiment with a murine melanoma experimental metastasis model showed that GSSG liposomes prevented melanoma lung metastasis. The unique antimetastatic mechanism through the effects on detachment and migration, and effective in vitro and in vivo metastasis inhibition, warrants further investigation of the GSSG liposomes as a potential treatment for cancer metastasis.

Salicylic acid metabolites and derivatives inhibit CDK activity: Novel insights into aspirin's chemopreventive effects against colorectal cancer

Aspirins potential as a drug continues to be evaluated for the prevention of colorectal cancer (CRC). Although multiple targets for aspirin and its metabolite, salicylic acid, have been identified, no unifying mechanism has been proposed to clearly explain its chemopreventive effects. Our goal here was to investigate the ability of salicylic acid metabolites, known to be generated through cytochrome P450 (CYP450) enzymes, and its derivatives as cyclin dependent kinase (CDK) inhibitors to gain new insights into aspirins chemopreventive actions. Using in vitro kinase assays, for the first time, we demonstrate that salicylic acid metabolites, 2,3-dihydroxy-benzoic acid (2,3-DHBA) and 2,5-dihydroxybenzoic acid (2,5-DHBA), as well as derivatives 2,4-dihydroxybenzoic acid (2,4-DHBA), 2,6-dihydroxybenzoic acid (2,6-DHBA), inhibited CDK1 enzyme activity. 2,3-DHBA and 2,6-DHBA did not inhibit CDK2 and 4; however, both inhibited CDK-6 activity. Interestingly, another derivative, 2,4,6-trihydroxybenzoic acid (2,4,6-THBA) was highly effective in inhibiting CDK1, 2, 4 and 6 activity. Molecular docking studies showed that these compounds potentially interact with CDK1. Immunoblotting experiments showed that aspirin acetylated CDK1, and pre-incubation with salicylic acid and its derivatives prevented aspirin-mediated CDK1 acetylation, which supported the data obtained from molecular docking studies. We suggest that intracellularly generated salicylic acid metabolites through CYP450 enzymes within the colonic epithelial cells, or the salicylic acid metabolites generated by gut microflora may significantly contribute to the preferential chemopreventive effect of aspirin against CRC through inhibition of CDKs. This novel hypothesis and mechanism of action in aspirins chemopreventive effects opens a new area for future research. In addition, structural modification to salicylic acid derivatives may prove useful in the development of novel CDK inhibitors in cancer prevention and treatment.

Peptides as Skin Penetration Enhancers for Low Molecular Weight Drugs and Macromolecules

The skin is the largest organ in the human body and constitutes a potential site for local and systemic drug delivery. However, the impermeable nature of the outermost layer of the skin called stratum corneum (SC) ensures a stringent barrier for transport of hydrophilic molecules and macromolecules into and across the skin. Hence, only small (<500 Da) and lipophilic (Log P = 1–3) molecules can be passively delivered through the skin. In particular, it is challenging to deliver hydrophilic drugs and macromolecules, such as proteins and nucleic acids, into and across the skin. To address these limitations, several physical and chemical skin penetration enhancement techniques have been proposed. Recently, peptides have emerged as successful skin penetration enhancers for both small molecular weight drugs and macromolecules. These peptides are called skin penetration enhancement peptides (SPEPs). Currently, majority of the SPEPs have been discovered from already-established cell-penetrating peptides, pore-forming antimicrobial peptides, or by screening random peptide displayed phage libraries. In this chapter, we have discussed the discovery of various classes of SPEPs and their mechanism of skin permeation enhancement.