Angela Risso

Biological Characterization of Two Novel Cathelicidin-derived Peptides and Identification of Structural Requirements for Their Antimicrobial and Cell Lytic Activities

Cathelicidins are a family of myeloid antimicrobial peptide precursors that have been identified in several mammalian species (Zanetti, M., Gennaro, R., and Romeo, D. (1995) FEBS Lett. 374, 1-5). Two novel bovine congeners have been deduced from cDNA. Their C-terminal sequences of 27 and 28 residues correspond to putative antimicrobial peptides with a cationic N-terminal region predicted to assume an amphipathic α-helical conformation followed by a hydrophobic C-terminal tail. Peptides corresponding to these sequences have been chemically synthesized and shown to exert a potent antimicrobial activity against Gram-negative and Gram-positive bacteria, including methicillin-resistant Staphylococcus aureus, and fungi. Both peptides are also cytotoxic to human erythrocytes and neutrophils, although at higher than microbicidal concentrations. The target selectivity has been improved by synthesizing truncated analogues, comprising only the 18 N-terminal residues, which show a great reduction in cytotoxic, but not in antimicrobial activity. The involvement of the C-terminal hydrophobic tail in the cytotoxic activity has been further demonstrated by inducing a major loss of activity in an analogue after replacing highly hydrophobic residues with more hydrophilic ones.

SMAP-29: a potent antibacterial and antifungal peptide from sheep leukocytes

SMAP‐29 is a cathelicidin‐derived peptide deduced from sheep myeloid mRNA. The C‐terminally amidated form of this peptide was chemically synthesized and shown to exert a potent antimicrobial activity. Antibiotic‐resistant clinical isolates highly susceptible to this peptide include MRSA and VREF isolates, that are a major worldwide problem, and mucoid Pseudomonas aeruginosa associated with chronic respiratory inflammation in CF patients. In addition, SMAP‐29 is also active against fungi, including Cryptococcus neoformans isolated from immunocompromised patients. SMAP‐29 causes significant morphological alterations of the bacterial surfaces, as shown by scanning electron microscopy, and is also hemolytic against human, but not sheep erythrocytes. Its potent antimicrobial activity suggests that this peptide is an excellent candidate as a lead compound for the development of novel antiinfective agents.

Leukocyte antimicrobial peptides: multifunctional effector molecules of innate immunity

Antimicrobial peptides are effector molecules of innate immunity that provide a first line of defense against pathogens. In mammals, they are stored in granules of leukocytes and are present in those sites that are exposed to microbial invasion, such as mucosal surfaces and skin. In the last decade, biochemical investigations and recombinant DNA technology have allowed the identification and characterization of several antimicrobial peptides from various animal and vegetal species. Most of the mammalian peptides have been grouped in two broad families: defensins and cathelicidin‐derived peptides. Functional studies have shown that the toxicity mechanisms for many peptides consist of a rapid permeabilization of the target cell membrane. In addition to their microbicidal activity, some members of both families are multifunctional molecules, playing a modulating role in the inflammation and the antigen‐driven immune response.

BMAP-28, an Antibiotic Peptide of Innate Immunity, Induces Cell Death through Opening of the Mitochondrial Permeability Transition Pore

ABSTRACT BMAP-28, a bovine antimicrobial peptide of the cathelicidin family, induces membrane permeabilization and death in human tumor cell lines and in activated, but not resting, human lymphocytes. In addition, we found that BMAP-28 causes depolarization of the inner mitochondrial membrane in single cells and in isolated mitochondria. The effect of the peptide was synergistic with that of Ca2+ and inhibited by cyclosporine, suggesting that depolarization depends on opening of the mitochondrial permeability transition pore. The occurrence of a permeability transition was investigated on the basis of mitochondrial permeabilization to calcein and cytochrome c release. We show that BMAP-28 permeabilizes mitochondria to entrapped calcein in a cyclosporine-sensitive manner and that it releases cytochrome c in situ. Our results demonstrate that BMAP-28 is an inducer of the mitochondrial permeability transition pore and that its cytotoxic potential depends on its effects on mitochondrial permeability.

CD69 molecule in human neutrophils: its expression and role in signal-transducing mechanisms.

The CD69 glycoprotein is an early activation antigen of T and B lymphocytes and it is constitutively expressed on thymocytes and platelets. Here we report its presence on neutrophils and on bone marrow-derived myeloid precursors. Indeed, promyelocytic cells are CD69+ on the cell membrane, while in resting neutrophils this molecule is located inside the cell. However, intracellular CD69 molecules are rapidly mobilized to the cell surface upon activation by PMA or fMLP. This translocation is independent on a new protein synthesis, as it is not inhibited by cycloheximide; furthermore, CD69 molecules are likely stored in a trans-Golgi structure since their expression is not affected by brefeldin A, a drug that blocks molecular trafficking from ER to Golgi vesicles. Immunoprecipitation of CD69 molecules either from activated neutrophils or from bone marrow cells showed that this protein has the same molecular size (28-34 kDa) as observed in platelets, T and B lymphocytes, and thymocytes. This similarity is reflected also in the functional role played by this molecule: in neutrophils as well as in lymphocytes and platelets, CD69 stimulation induced Ca2+ influx through cellular membrane; furthermore, the perturbation of the CD69 antigen on PMA-activated neutrophils enhances the lysozyme release, suggesting a role of this molecule in the regulation of granule exocytosis, probably through a Ca(2+)-dependent mechanism.

Structural and Functional Analysis of Horse Cathelicidin Peptides

ABSTRACT Cathelicidin-derived antimicrobial peptides are a component of the peptide-based host defense of neutrophils and epithelia, with a widespread distribution in mammals. We recently reported the cDNA sequences of three putative horse myeloid cathelicidins, named eCATH-1, -2, and -3. A Western analysis was performed to investigate their presence in neutrophils and processing to mature peptides. eCATH-2 and eCATH-3, but not eCATH-1, were found to be present in uncleaved forms in horse neutrophils. The corresponding mature peptides were detected in inflammatory sites, suggesting that processing of the propeptides takes place upon neutrophil activation. A functional characterization was then performed with synthetic eCATH peptides. Circular dichroism measurements indicated an amphipathic α-helical conformation of these peptides in an anisotropic environment, and in vitro assays revealed a potent activity and a broad spectrum of antimicrobial activity for eCATH-1 and a somewhat more restricted spectrum of activity for eCATH-2. Conversely, a strong dependence on salt concentration was observed when the activity of eCATH-3 was tested. This peptide efficiently killed bacteria and some fungal species, i.e.,Cryptococcus neoformans and Rhodotorula rubra, in low-ionic-strength media, but the activity was inhibited in the presence of physiological salt medium. This behavior could be modified by modulating the amphipathicity of the molecule. In fact, the synthetic analogue LLK-eCATH-3, with a slightly modified sequence that increases the hydrophobic moment of the peptide, displayed a potent activity in physiological salt medium against the strains resistant to eCATH-3 under these conditions.

Neocytolysis: none, one or many? A reappraisal and future perspectives

Neocytolysis is the hypothesis formulated to explain experimental evidence of selective lysis of young red blood cells (RBCs) (neocytes) associated with decreased plasma levels of erythropoietin (EPO). In humans, it appears to take place whenever a fast RBC mass reduction is required, i.e., in astronauts during the first days of spaceflight under weightlessness, where a fast reduction in plasma volume and increase in haematocrit occur. EPO plasma levels then decline and a decrease in RBC mass takes place, apparently because of the selective lysis of the youngest, recently generated RBCs (neocytes). The same process seems to occur in people descending to sea level after acclimatization at high altitude. After descent, the polycythaemia developed at high altitude must be abrogated, and a rapid reduction in the number of circulating RBCs is obtained by a decrease in EPO synthesis and the lysis of what seem to be young RBCs. In vivo, neocytolysis seems to be abolished by EPO administration. More recent research has ascribed to neocytolysis the RBC destruction that occurs under such disparate pathophysiologic conditions as nephropathy, severe obstructive pulmonary disease, blood doping, and even malaria anaemia. According to the theory, EPOs central role would be not only to stimulate the production of new RBCs in conditions of anaemia, as maintained by the orthodox view, but also that of a cytoprotective factor for circulating young RBCs. Why neocytes are specifically destroyed and how is this related to decreased EPO levels has not yet been elucidated. Changes in membrane molecules of young RBCs isolated from astronauts or mountain climbers upon return to normal conditions seem to indicate a higher susceptibility of neocytes to ingestion by macrophages. By limiting the context to space missions and high altitude expeditions, this review will address unresolved and critical issues that in our opinion have not been sufficiently highlighted in previous works.

Survival and senescence of human young red cells in vitro.

Background: A number of experimental investigations in vivo suggest that in humans a decrease of circulating erythrocyte number ensues whenever erythropoietin (EPO) plasma level decreases. Since the process seems to selectively eliminate young red cells (neocytes), it has been named neocytolysis. The experimental models in vivo have revealed and documented multiple forms of neocytolysis but have not fully elucidated the specificity of the target red cells and the relation with EPO level changes. In an attempt to better characterize the neocytolytic process, we have undertaken an in vitro investigation on age-ranked human red cells. Methods: By centrifugation on Percoll density gradient we separated the red cells population into three subsets, neocytes, middle-aged and old. Then we comparatively investigated the kinetics of survival of the subsets cultured under different conditions: with medium alone, with 10% autologous plasma, with EPO, alone or in combination with autologous monocytes. Results: Neocytes showed a viability and a survival rate lower than the other red cells when cultured in medium or with 10% plasma. EPO at physiological doses increased their survival rate, but not that of the other subsets. This effect was enhanced by co-culture with monocytes. Conclusion: Likely neocytes are more sensitive than the other RBCs subsets to presence or absence of survival signals, such as EPO or plasma or monocytes derived factors. These observations could provide an insight into the link between the decrease in EPO plasma level and the reduction of circulating red cells mass and account for the specificity of neocytes clearance.

Expression of fetal hemoglobin in adult humans exposed to high altitude hypoxia

In humans, acute erythroid expansion can lead to maturation of red blood cell (RBC) precursors containing fetal hemoglobin (F red cells). This can occur in patients after recovery from bone marrow transplantation, or in individuals affected by sickle cell or thalassemic syndromes. An accelerated erythroid lineage expansion is also a hallmark of the adaptive response to high altitude hypoxia. To explore the possible effect of this environment on F red cell production, we analyzed RBCs from five subjects during and after 17 days spent at high altitude and investigated the expression of fetal hemoglobin by different methodological approaches. By flow cytometry, we found a moderate increase of circulating F red cells during and after the hypoxia exposure, with respect to control cells analyzed before a stay at high altitude. The increased expression of γ-globin (as the specific subunit contained in F hemoglobin together with α-globin) was further confirmed by immunoblotting of young RBC hemolysates and quantitative RT-PCR of transcripts purified from a reticulocyte-enriched RBC fraction. Thus, in healthy adults the exposure to high altitude hypoxia induces maturation of F red cells at a level higher than under normal condition. The effect appears reduced after return to normoxia.

Immunochemical evidence for the presence of a lipoxygenase 1 in isolated plasma membranes from soybean cotyledons

Abstract An antibody was raised against a synthetic oligopeptide, corresponding to the 19–31 interval of the polypeptide chain of soluble lipoxygenase 1 (LOX 1) from soybean seeds. Cross-reactivity of this antibody towards proteins of a soybean cotyledon plasma membrane (PM) fraction was detected. The anti-LOX 1 antibody cross-reacted with a protein of approximately 94 kDa, when the membrane proteins were separated by sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE). The same protein, separated in non-denaturing conditions, exhibited LOX activity with an optimum at pH 9.0. The cross-reactivity of the 94 kDa protein was maintained also in Na2CO3 or NaCl-washed membranes, confirming that the enzyme appears to be tightly bound. Finally, the protein, showing LOX activity, was separated by immunoprecipitation using the anti-LOX 1 antibody bound to protein A-Sepharose CL-4B. Again, reactivity with the protein of 94 kDa was detected. These findings show that isolated soybean PMs exhibit a LOX activity, which depends on the presence of the LOX 1 isoform. It is suggested that soluble LOX 1 may be in a dynamic equilibrium with a part of the enzyme, which appears to be linked to PMs.