Integrin alpha2beta1 mediates the anti-angiogenic and anti-tumor activities of angiocidin, a novel tumor-associated protein

We recently characterized an anti-tumor protein termed angiocidin. Here, we report that angiocidin may inhibit angiogenesis by binding collagen and its receptors. Angiocidin bound purified type I collagen and alpha2beta1 with high affinity. K562 cells expressing alpha2beta1 bound and adhered to angiocidin while K562 cells which only expressed alpha5beta1 integrin showed no binding and adhesion. Binding was specific since a neutralizing antibody against alpha2beta1 inhibited binding but antibodies against alpha5beta1 had no effect. Additionally, angiocidin co-localized with alpha2beta1 on K562 alpha2beta1 transfected cells, pancreatic cancer colo 357 cells, breast cancer MB-231 cells and human umbilical endothelial vein (HUVE) cells. In an alpha2beta1-dependent collagen gel angiogenesis assay, angiocidin showed potent inhibitory activity. We identified a 20-amino-acid amino terminal peptide of angiocidin that bound both alpha2beta1 and type I collagen. This peptide promoted alpha2beta1-dependent cell adhesion and inhibited tumor growth and angiogenesis. Taken together, these results are consistent with the conclusion that the anti-tumor activity of angiocidin arises from its ability to ligate collagen and alpha2beta1 on endothelial cells and tumor cells. Our results provide support for the concept that targeting matrix-cell interactions is a viable strategy for the development of anti-cancer therapeutics.     

Source of nitrogen as a factor limiting saponin production by hairy root and suspension cultures of <Emphasis Type="Italic">Calendula officinalis</Emphasis> L.

Triterpenic saponins represented in Calendula officinalis L. by oleanolic acid (OA) glycosides are pentacyclic triterpene compounds with a wide range of biological and medicinal properties. This report demonstrates nitrogen source impact on growth, saponin accumulation, and secretion in hairy root and suspension cultures of marigold. Hairy roots preferred nitrate as a mineral source of nitrogen, but its impact on growth, OA glycosides accumulation, and secretion were line-dependent. The best productivity of OA glycosides was found in CC16 line (74.86 mg flask^?1) in ½ MS medium modified by 2.5× KNO₃ and ammonium elimination with 2.5 g l^?1 peptone. Organic nitrogen source at 27.5-g l^?1 impairs the growth rate of hairy roots. Its effect on saponin accumulation and secretion to the surrounding medium depended on line and media composition. Nitrate:ammonium ratio of 4:2 for CC16 resulted in 5.7-fold increment of saponin secretion comparing to the standard medium. Embryo roots, apical bud, and hypocotyls explants were crucial for induction of suspension culture synthesizing saponins; however, effect of mineral form of nitrogen in cultivating medium had to be considered. The highest OA glycosides level (171.97 μg g^?1 of dry weight) was recorded in the root derived culture with nitrate as a sole mineral form of nitrogen. Peptone from lactalbumin decidedly inhibited the saponin formation; however, it was essential for culture initiation, proliferation, and organ differentiation.     

NKG2D initiates caspase-mediated CD3zeta degradation and lymphocyte receptor impairments associated with human cancer and autoimmune disease

Deficiencies of the T cell and NK cell CD3ζ signaling adapter protein in patients with cancer and autoimmune diseases are well documented, but mechanistic explanations are fragmentary. The stimulatory NKG2D receptor on T and NK cells mediates tumor immunity but can also promote local and systemic immune suppression in conditions of persistent NKG2D ligand induction that include cancer and certain autoimmune diseases. In this paper, we provide evidence that establishes a causative link between CD3ζ impairment and chronic NKG2D stimulation due to pathological ligand expression. We describe a mechanism whereby NKG2D signaling in human T and NK cells initiates Fas ligand/Fas-mediated caspase-3/-7 activation and resultant CD3ζ degradation. As a consequence, the functional capacities of the TCR, the low-affinity Fc receptor for IgG, and the NKp30 and NKp46 natural cytotoxicity receptors, which all signal through CD3ζ, are impaired. These findings are extended to ex vivo phenotypes of T and NK cells among tumor-infiltrating lymphocytes and in peripheral blood from patients with juvenile-onset lupus. Collectively, these results indicate that pathological NKG2D ligand expression leads to simultaneous impairment of multiple CD3ζ-dependent receptor functions, thus offering an explanation that may be applicable to CD3ζ deficiencies associated with diverse disease conditions.     

RGD conjugation to polyethyleneimine does not improve DNA delivery to bone marrow stromal cells

Bone marrow stromal cells (BMSC) modified with therapeutic genes are being actively pursued for gene therapy protocols. To develop safe and effective nonviral methods for BMSC modification, the cationic polymer polyethyleneimine (PEI) has been utilized to condense plasmid DNA for intracellular delivery. This study was conducted to explore the feasibility of increasing the PEI's effectiveness by coupling integrin-binding arginine-glycine-aspartic acid (RGD) peptides to the polymer. BMSC from rats were isolated and expanded in culture for gene transfer studies. In contrast to our expectations, RGD-conjugated PEI did not exhibit an enhanced binding to BMSC. This was the case where the peptides were conjugated to PEI by short, disulfide linkages or long poly(ethylene glycol) linkages. Using a reporter gene for the enhanced green fluorescent protein, the transfection efficiency of RGD-conjugated PEI was also lower than the delivery by the native PEI, which exhibited equivalent transfection efficiency to that of an adenovirus. We conclude that native PEI was sufficient for the transformation of BMSC and that coupling of the integrin-binding RGD-peptides did not improve the effectiveness of this polymer for BMSC transfection.     

Case report of a woman with monoclonal gammapathy and papillary thyroid carcinoma, diagnosed because of detection of CHEK2 (I157T) mutation in genetic examinations

The CHEK2 gene encodes the CHK2 protein, which is kinase involved in DNA repair processes. By activating a lot of cell substrates, it can regulate the cell cycle, demonstrates suppressive effects, and participates in the senescence and apoptosis processes. Mutations in the CHEK2 gene are associated with increased risk of numerous cancers. The case described herein is that of a woman with a missense mutation that results in the substitution of isoleucine for threonine at position 157. This variant of the mutation doubles the risk of papillary thyroid carcinoma two times and causes up to 9% of these cancer. It is also associated with a two-fold increased risk of cancers of the kidney (10%), colon (10%), and ovary (10% - G1), a 1.6-fold increased risk of prostate cancer (8% of all of them and 12% of familiar ones), and a 1.5-fold increased risk of breast cancer (7%). The screening procedures were initiated in a carrier who revealed papillary thyroid carcinoma. Genetic screening of the family diagnosed her daughter as the carrier of this mutation. Until now no active cancer disease has been recognized in the daughter. On the example of the presented case we discuss indications for screening in cases of positive family history. The group especially predisposed seem to be patients with at least two coexisting carcinomas. Having diagnosed the mutation, it is necessary to do genetic screening of family members. Continuous oncological observation of the carriers of CHEK 2 mutation is essential.