Brigitte H. Fasciotto

Curcumin Encapsulation in Submicrometer Spray-Dried Chitosan/Tween 20 Particles

Optimal curcumin delivery for medicinal applications requires a drug delivery system that both solubilizes curcumin and prevents degradation. To achieve this, curcumin has been encapsulated in submicrometer chitosan/Tween 20 particles via a benchtop spray-drying process. Spray-drying parameters have been optimized using a Taguchi statistical approach to minimize particle size and to favor spheroid particles with smooth surfaces, as evaluated with scanning electron microscopy (SEM) imaging. Nearly spherical particles with 285 ± 30 nm diameter and 1.21 axial ratio were achieved. Inclusion of curcumin in the spray-drying solution results in complete encapsulation of curcumin within the chitosan/Tween 20 particles. Release studies confirm that curcumin can be released completely from the particles over a 2 h period.

Processing of chromogranin A in the parathyroid: generation of parastatin-related peptides

Chromogranin A (CgA) is a glycoprotein present in secretory granules of endocrine cells. In the parathyroid, it is costored and cosecreted with parathormone (PTH) in response to hypocalcemia. CgA is the precursor of several bioactive peptides including pancreastatin and betagranin. Parastatin (PARA, pCgA(347-419)) is a novel peptide that we generated in vitro by enzymatic digestion of pCgA. In vitro, it inhibits low Ca(2+)-stimulated parathyroid secretion. Full activity resides in its first 19 residues. In order to determine if PARA or PARA-derived peptides are natural products of the parathyroid, we generated an antiserum directed against pCgA(347-359) corresponding to the bioactive N-terminal sequence of pPARA (pPARA(1-13) antiserum), and developed a specific radioimmunoassay that we used in conjunction with various chromatographic separations. We identified small peptides carrying the pPARA(1-13) immunoactivity in extracts and secretion medium of porcine parathyroid glands. Continuous and pulse-chase radiolabeling studies, along with immunoprecipitation using PARA(1-13) antiserum demonstrate that a newly-synthesized PARA-related peptide fraction with a Mr of 11 kDa is secreted by the parathyroid cells and accumulates in the secretion medium. Edman degradation of the 11 kDa PARA-related peptide band by Edman degradation yielded three major N-terminal sequences: S-K-M-D-R-L-A-K-E-L-(residues 313-322), D-R-L-A-K-E-L-T-A-E-(residues 316-325), and A-K-E-L-T-A-E-K-R-L-(residues 319-329), in a molar ratio of approximately 1:2:1. The peptide bonds required to be cleaved to yield these peptides, Trp-Ser, Met-Asp and Leu-Ala, suggest that a chymotrypsin-like endopeptidase participated in their formation. The molecular size and the results of amino acid compositional analysis, indicate that the C-termini of these peptides extended variably to residues 384-401 of pCgA. These results demonstrate that processing of CgA by the parathyroid gland generates bioactive PARA-related peptides that could affect the glands secretory activity.

Autocrine inhibition of parathyroid cell secretion requires proteolytic processing of chromogranin A

Chromogranin A (CgA, Secretory Protein-I) is a protein of about 450 amino acids representing a major soluble component of the secretory granules of parathyroid and other endocrine and neuroendocrine cells. In the parathyroid, CgA is costored and cosecreted with parathormone (PTH). We earlier found that CgA and the derived peptide, pancreastatin, inhibited secretion of PTH and CgA by parathyroid cells in culture and that CgA antiserum stimulated secretion above the maximum achieved at low (0.5 mM) Ca2+. In the present study, porcine parathyroid cells were incubated at different cell concentrations at low Ca2+. The amount of secreted CgA increased over the 6-h incubation period at 1 x 10(6) to 4 x 10(6) cells/ml, but plateaued after 3 h at 6 x 10(6) cells/ml. Secretion did not plateau when antisera were added at 3 h. Conditioned medium contained a factor or factors that blocked secretion by fresh parathyroid cells at 0.5 mM Ca2+. Pulse-chase studies revealed that 40% of the secreted CgA was processed after 6 h of chase. alpha-2-macroglobulin, an inhibitor of proteolytic processing, increased the amount of CgA in the medium by 30% at 1 h of chase and decreased the amount processed to 20% by 6 h. Other protease inhibitors similarly enhanced the amount of CgA in the medium. These data indicate that proteolytic processing of intact CgA is requisite for its autocrine inhibitory activity.

Secretory cargo composition affects polarized secretion in MDCK epithelial cells

Polarized epithelial cells secrete proteins at either the apical or basolateral cell surface. A number of non-epithelial secretory proteins also exhibit polarized secretion when they are expressed in polarized epithelial cells but it is difficult to predict where foreign proteins will be secreted in epithelial cells. The question is of interest since secretory epithelia are considered as target tissues for gene therapy protocols that aim to express therapeutic secretory proteins. In the parathyroid gland, parathyroid hormone is processed by furin and co-stored with chromogranin A in secretory granules. To test the secretion of these proteins in epithelial cells, they were expressed in MDCK cells. Chromogranin A and a secreted form of furin were secreted apically while parathyroid hormone was secreted 60% basolaterally. However, in the presence of chromogranin A, the secretion of parathyroid hormone was 65% apical, suggesting that chromogranin can act as a “sorting escort” (sorting chaperone) for parathyroid hormone. Conversely, apically secreted furin did not affect the sorting of parathyroid hormone. The apical secretion of chromogranin A was dependent on cholesterol, suggesting that this protein uses an established cellular sorting mechanism for apical secretion. However, this sorting does not involve the N-terminal membrane-binding domain of chromogranin A. These results suggest that foreign secretory proteins can be used as “sorting escorts” to direct secretory proteins to the apical secretory pathway without altering the primary structure of the secreted protein. Such a system may be of use in the targeted expression of secretory proteins from epithelial cells.

N-terminal proteolytic processing of porcine chromogranin A in parathyroid tissue

Chromogranin A (CgA) is a glycoprotein stored in secretory granules of many endocrine and neuroendocrine cells. CgA undergoes tissue specific processing to release regulatory peptides. In the parathyroid, although processing is limited and variable, several CgA-derived peptides have been characterized including parastatin and betagranin. An early stage of CgA processing is the generation of a 64-kDa fragment (CgA64). In this study, we have purified CgA64 from porcine parathyroid glands by chromatographic separations. Edman degradation of this CgA64 yielded the N-terminal sequence NDQAELKEGTEEASSKEAAEKRGDXAVEKND corresponding to pCgA(94-125). Amino acid composition suggests that CgA64 corresponds to CgA(94-430) (i.e. the entire CgA molecule, less the N-terminal residues 1-93). To determine the origin of CgA64, we fractionated parathyroid membrane vesicles by sucrose gradient centrifugation. Intact CgA is predominantly located in dense sucrose fractions (secretory granules), whereas CgA64 is located near the top of the gradient (soluble protein fraction). In vitro incubation of these fractions revealed that the conversion of CgA did not occur in intact granules. These results indicate that CgA64 is not present in intact granules suggesting that it is not a naturally occurring secretory product in parathyroid cells.

Transcriptional Profile of Immediate Response to Ionizing Radiation Exposure

Astronauts participating in long duration space missions are likely to be exposed to ionizing radiation associated with highly energetic and charged heavy particles. Previously proposed gene biomarkers for radiation exposure include phosphorylated H2A Histone Family, Member X (γH2AX), Tumor Protein 53 (TP53), and Cyclin-Dependent Kinase Inhibitor 1A (CDKN1A). However, transcripts of these genes may not be the most suitable biomarkers for radiation exposure due to a lack of sensitivity or specificity. As part of a larger effort to develop lab-on-a-chip methods for detecting radiation exposure events using blood samples, we designed a dose–course microarray study in order to determine coding and non-coding RNA transcripts undergoing differential expression immediately following radiation exposure. The main goal was to elicit a small set of sensitive and specific radiation exposure biomarkers at low, medium, and high levels of ionizing radiation exposure. Four separate levels of radiation were considered: 0 Gray (Gy) control; 0.3 Gy; 1.5 Gy; and 3.0 Gy with four replicates at each radiation level. This report includes raw gene expression data files from the resulting microarray experiments from all three radiation levels ranging from a lower, typical exposure than an astronaut might see (0.3 Gy) to high, potentially lethal, levels of radiation (3.0 Gy). The data described here is available in NCBIs Gene Expression Omnibus (GEO), accession GSE64375.

Elucidation of dose-dependent transcriptional events immediately following ionizing radiation exposure

Long duration space missions expose astronauts to ionizing radiation events associated with highly energetic and charged heavy particles. Such exposure can result in chromosomal aberrations increasing the likelihood of the development of cancer. Early detection and mitigation of these events is critical in providing positive outcomes. In order to aid in the development of portable devices used to measure radiation exposure, we constructed a genome-wide screen to detect transcriptional changes in peripheral blood lymphocytes shortly after (approximately 1 hour) radiation exposure at low (0.3 Gy), medium (1.5 Gy) and high (3.0 Gy) doses compared to control (0.0 Gy) using Affymetrix® Human Gene 1.0 ST v1 microarrays. Our results indicate a number of sensitive and specific transcriptional profiles induced by radiation exposure that can potentially be implemented as biomarkers for radiation exposure as well as dose effect. For overall immediate radiation exposure, KDELC1, MRPS30, RARS, and HEXIM1 were determined to be effective biomarkers while PRDM9, CHST4, and SLC26A10 were determined to be biomarkers specific to 0.3 Gy exposure; RPH, CCDC96, WDYHV1, and IFNA16 were identified for 1.5 Gy exposure; and CWC15, CHCHD7, and DNAAF2 were determined to be sensitive and specific to 3.0 Gy exposure. The resulting raw and analyzed data are publicly available through NCBIs Gene Expression Ominibus via accession GSE64375.