Roberto Valvassori

The multifunctional role of fibroblasts during wound healing in Hirudo medicinalis (Annelida, Hirudinea)

Summry— Extracellular matrix components play a key role during the angiogenic process for a correct development of blood vessels: fibroblasts are the main cell type involved in the regulation of ECM protein production. In this study we characterize H. medicinalis fibroblasts and demonstrate that they take part to the regulation of angiogenesis that occurs during wound healing process. Massive proliferation and phenotypic modification are two distinctive markers of fibroblast activation. These cells, that are usually responsible for collagen production and function as an energy reservoir, are recruited during wound healing to form a collagen scaffold through a direct mechanic action and through secretion of specific proteoglycans. In addition we show that the activity of fibroblasts is modulated by EGF, a growth factor involved in wound healing in vertebrates. The formation of bundles of collagen fibrils by fibroblasts is fundamental for the development and migration of new blood vessels in lesioned areas during wound repair: administration of lovastatin in explanted leeches affects fibroblasts, damages collagen “scaffold” and indirectly causes the reduction of neo‐capillary formation.

Superelongation in helical muscles of leeches

SummaryThe fine structure of leech body wall muscles, has been analysed under great length variations. All the measurable parameters of the fibre (distance between thick filaments, sarcomere and A band width, percentage of actin crowns around myosin filaments, fibre radius) at different elongations were tested with equations describing the geometrical model of helical fibres.Anaesthetized and nonanaesthetized worms behave in different ways and can be utilized to verify the ‘changing partner hypothesis’. The fit between theoretical and experimental data suggests that a double change of partner actually takes place in extremely stretched fibres.

Hirudo medicinalis: A new model for testing activators and inhibitors of angiogenesis

An increasing body of evidence indicates that in the leech Hirudo medicinalis the angiogenic process is finely regulated and coordinated by the botryoidal tissue. In this paper we provide evidence on the involvement of botryoidal tissue cells in angiogenesis induced in H. medicinalis by a variety of stimuli including surgical wounds or the administration of modulators of neovascularization. Interestingly, we show that either human activators of vascular cell growth, or anti-angiogenic peptides like angiostatin and endostatin, or the drug mitomycin, can induce a prompt biological response in H. medicinalis. We show as well that angiogenesis in this invertebrate shares a surprising degree of similarity with neovascularization in vertebrates, both at the biochemical and cellular levels, because it involves similar growth factors/growth factor receptors, and relies on analogous cell–cell or cell–matrix interactions. For these reasons we suggest that H. medicinalis can be used as a reproducible model for testing activators or inhibitors of angiogenesis, and for investigating the biochemical, ultrastructural and cellular processes involved in new vessel formation.

Larval anatomy and structure of absorbing epithelia in the aphid parasitoid Aphidius ervi Haliday (Hymenoptera, Braconidae)

The present work describes Aphidius ervi Haliday (Hymenoptera, Braconidae) larval anatomy and development, focusing on time-related changes of body structure and cell ultrastructure, especially of the epithelial layers involved in nutrient absorption. Newly hatched 1st instar larvae of A. ervi are characterised by gut absence and a compact cluster of cells makes up their body. As the parasitoid larva develops, the central undifferentiated cell mass becomes hollowed out, leading to the formation of gut anlage. This suggests that absorption of nutrients at that stage may take place through the body surface, as more directly demonstrated by the occurrence on the epidermis of proteins associated with transepithelial transport, such as Na(+)/K(+)-ATPase and alkaline phosphatase (ALP). Second instar larvae show the presence of the gut with a well-differentiated brush border and a peritrophic membrane. Gut cells are filled by masses of glycogen granules and lipid droplets. The tracheal system starts to be visible. The haemocoel becomes evident in late 2nd instar, and contains large silk glands. Mature 3rd instar larvae are typically hymenopteriform. The midgut accounts for most of the body volume and is actively involved in nutrient absorption, as indicated by the well developed brush border and by the presence of Na(+)/K(+)-ATPase and ALP on the basolateral and luminal membrane respectively. At this stage, large lipid droplets have gradually replaced the cellular glycogen stores in the midgut cells. The tracheae are completely differentiated, but their internal lumen still contains fibrillar material, suggesting that they are not functional as long as host fluids bath the parasitoid larva. In late 3rd instar larvae, silk glands, structurally similar to Malpighian tubules, show a very intense vesicular traffic toward the internal lumen, which, eventually, results in being filled by secretion products, suggesting the possible recycling of metabolic waste products during mummy formation.

Hirudo medicinalis: avascular tissues for clear-cut angiogenesis studies?

Basic studies on angiogenesis in normal and pathologic conditions, as well as research on drugs or genes/proteins that stimulate or regulate the angiogenic process, can rely on an increasing number of experimental models. Among non-mammalian models, Zebrafish is adopted by an increasing number of research groups. Moreover, angiogenesis and vasculogenesis in invertebrates like the leech Hirudo medicinalis share a high degree of similarity with the same processes occurring in humans, both under the structural/functional and biochemical points of view. Interestingly, Hirudo angiogenic growth factor receptors respond to corresponding human/mammalian recombinant growth factors and cytokines; in addition, Hirudo endogenous angiogenic growth factors and receptors react with antibodies against their human/mammalian counterparts. Furthermore, as it will be shown in this review, Hirudo has the unique advantage of having a virtually avascular muscular body wall, whereas the reliability of such a peculiar feature as a model for physiologically vascularised mammalian tissues has to be thoroughly investigated. Hirudo has proven so far to allow unambiguous, clear-cut studies on the angiogenic potential of gene-products or drugs, as well as on the anti-angiogenic compounds. This article will review the biology of angiogenesis in Hirudo and the data so far collected on angiogenesis stimulation/modulation in this model; an example describing a study on the biological activity of a naked DNA vector for angiogenesis gene therapy will also be provided.

Vascular endothelial growth factor is involved in neoangiogenesis in Hirudo medicinalis (Annelida, Hirudinea)

Vascular endothelial growth factor (VEGF) is fundamental in vertebrates for correct development of blood vessels. However, there are only few data about the presence of VEGF in invertebrates. In this study the role of VEGF in neovessel formation is investigated in Hirudo medicinalis. The leech is able to respond to administration of human VEGF by formation of new vessels. The response of H. medicinalis to this growth factor is explained by the presence of two specific VEGF-like receptors (Flt-1/VEGFR-1 and Flk-1/VEGFR-2) as demonstrated by immunohistochemistry and biochemical analysis. The VEGF-like produced by this annelid following surgical stimulation determines not only blood vessel formation, proliferation of vascular endothelial cells but also an increase of cytoplasmic calcium levels. The administration of specific VEGF receptor antibodies can inhibit angiogenesis in leeches previously stimulated with VEGF.

Three-dimensional reconstruction of the contractile system of the Nematomorpha muscle fiber.

The body-wall muscle fiber of Nematomorpha (flattened circomyarian with central cytoplasmic axis) is characterized by very long (about 120 μ m) bipolar, paramyosinic filaments with a periodic asymmetrical organization. They are arranged in longitudinal contractile fields and form paired systems of very elongated semihelices regularly staggered along the fiber axis, concave toward the periphery and alternatively enantiomorphic. A three-dimensional reconstruction of the contractile system was performed considering the morphology of the contractile fields, the position in these latter of the central reversal zones and tapered extremities of thick filaments, and the peculiar distribution in the direction of the filament polarity. The validity of the possible models was checked comparing the actual images visible under the electron microscope with those obtainable by means of a computer. The possible functional meaning of this contractile structure is briefly discussed.

Leech responses to tissue transplantation

The aim of the present work is to describe histologically, histochemically and immunocytochemically, the sequence of events that lead to first and second set rejection of allo- or xenograft in leeches. Graft responses of leeches are comparable and are described following specific steps: inflammatory phase, rejection phase and granulation tissue formation (including re-epithelialisation, angiogenesis and fibroplasia).The responses to first and second graft in first set graft rejection as well as to the first transplant in second set graft experiments are identical and in the time span of a week all grafts are destroyed and disappear. In the second set graft rejection experiments the responses against the second transplant are markedly accelerated. The second graft shows massive structural alterations and it is rapidly rejected, within 3-4 days.Our results permit to highlight that in leeches there is a specific responsiveness of immune system similar to those described in highly divergent phyla.

Hematopoietic cell formation in leech wound healing.

The angiogenic process in vertebrates and hirudineans has been compared. The leech Hirudo medicinalis, subjected to an angiogenic stimulus (surgical explant or cytokine treatment) responds, as a vertebrate, with the formation of an extensive network of new vessels accompanied by the production of circulating cells. The reviewed data confirm the surprising similarity between hirudinean and vertebrate processes in wound healing, and suggest that basic common events such as antigenic expressions of endothelial and hemopoietic cells, cytokine secretion and regulation as well as extracellular matrix interactions, are conserved and extended across diverse species, tissues and developmental phases.

Collagen reorganization in leech wound healing

Background Information. Leeches respond to surgical lesions with the same sequence of events as that described for wound healing in vertebrates, where collagen is important for the development of tensions in healing wounds, functioning as an extracellular scaffold for accurate regeneration of the structures disrupted by surgical or traumatic actions.