3R Info Bulletins

Non-invasive electrical monitoring of the population spiking activity in the central nervous system

Establishment of a novel system for the production of large numbers of mouse basophils in vitro

New tools for the generation of peptide- and antibody-based ligands in vitro: Reduction of antibody production in experimental animals

Genetic manipulation of the human airway epithelium – a paradigmatic system to study host responses to human respiratory viruses

A new in-vitro approach to the study of brain tumours: an alternative to in-vivo experiments in animals

Generic in-vitro assays for immunological correlates of protection against foot-and-mouth disease to replace animal challenge infections

Still relevant twenty-five years on / 25 years of funding the 3Rs - past accomplishments and future prospects

Bacterial Meningitis: Investigating Injury and Regenerative Therapy in vitro

A novel ex vivo mouse aorta perfusion model

Metabolism as part of alternative testing strategies in fish

Toxoplasma gondii virulence is predictable in cultured human cells

Serum-free defined media, a largely unsolved problem in cell culture

From pigs to cells: Virulence of classical swine fever virus is predictable in cell cultures

Fish Acute Toxicity Test: The number of animals can be reduced

The blood-brain barrier in a dish: a new multicellular in vitro model

A novel in-vitro cell model of the human airway epithelium

Refined ex-vivo rodent heart model reduces in vivo experimentation

Detection of Pain in Laboratory Animals via Gene Expression?

An in-vitro system for detecting the health effects of inhaled particles and gases

Bioconcentration of chemicals in fish can be assessed in vitro

Host pathogen interactions can be studied in amoebae instead of animals

From blood to brain and vice versa: Transport Processes in Choroid Plexus can be studied in vitro

Exploring natural anticoagulation by endothelial cells: A novel in vitro model

Predicting drug hypersensitivity by in vitro tests

Non-Invasive Methods: Investigation of Airways Diseases by MRI in Rats

Improvement of Pain Therapy in Laboratory Mice

Environmental enrichment does not disrupt standardization

Computer-based quantification of (adverse) effects triggered by drugs and chemicals

Bone metabolism and bone-biomaterial interactions can be studied ex vivo

The tick blood meal: From a living animal or from a silicone membrane?

Immune cells in the liver : The generation and use of a mouse Kupffer cell line

Formation of new blood vessels in the heart can be studied in cell cultures

Generation of parasite cysts in cultured cells instead of living animals.

Simulation of stroke related damage in cultured human nerve cells.

Environmental enrichment does not affect the variability of animal experimentation data in the Light/Dark test.

Identification of new human skin irritation markers for tests with human skin reconstructs

Animal-free screening of biological materials for their contamination by rodent viruses

Phenotype Characterisation and Welfare Assessment of Transgenic Mice

Prevention of adverse effects in pigs after vaccination

Fever in the test tube - towards a human(e) pyrogen test

Housing and husbandry conditions affect stereotypic behaviour in laboratory gerbils

Aggregating brain cell cultures: Investigation of stroke related brain damage

Transgenic protozoa as an alternative to transgenic animals

Identification of neurotoxic chemicals in cell cultures

Leishmaniasis: Development of an in vitro assay for drug screening

Immunization of laboratory animals

Ten years Foundation Research 3R

Permanent fish cell cultures as novel tools in environmental toxicology

Regulation of digestion in cell culture

The three 'R's of Russell & Burch, 1959

Call for 3R-Research Proposals

Human recombinant antibodies

Predicting human drug metabolism

Gerhard Zbinden and 3R

mAbs without mice?

Foundation Research 3R

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3R-INFO-BULLETIN 25

Formation of new blood vessels in the heart can be studied in cell cultures

Formation of new blood vessels, a therapeutic concept

Coronary heart disease is very common in human. It often causes hypoxia and myocardial ischemia as one of the severe consequences. This affects the function of the heart and results in a significant morbidity and mortality for the patient. Stimulation of angiogenesis (development of new blood vessels) by pharmacological or molecular methods (therapeutic angiogenesis)[*] would generate the formation of new coronary collaterals in the myocardium, i.e., small branches of arteries and veins that develop to bypass narrowed or blocked segments. Improving coronary collateral circulation would limit myocardial ischemia and is therefore a promising new concept (1).

Three-Dimensional cell cultures

Models of angiogenesis in vitro are based on the capacity of activated endothelial cells (cells forming the walls of blood vessels) to invade three-dimensional substrates. These substrates (Matrix) may consist of collagen gels, plasma clot, purified fibrin, Matrigel, or a mixture of these proteins with others. It is possible to embed and culture pieces of blood vessels (vascular explants such as aortic rings) and to observe cells sprouting and forming capillary-like structures (CLS) (3). These models allow the preservation of the vessel architecture during the in vitro assay, and thus are close to an "ex vivo" model (4). One particular model of angiogenesis (the Nicosia-model), used for in vitro angiogenesis of aortic explants, was further developed for heart explants. Briefly, pieces (ca. 1 mm3) of left ventricular myocardium of rat or mouse hearts are embedded in a fibrin-gel, overlayed with growth medium and angiogenic stimulants (agonists) and/or inhibitors (antagonist). These cultures are then incubated for 10 days. Active molecules are added again every third day, and oxygen saturation can be lowered down to 1% O₂ (Fig. 1). A single mouse heart allows to assess more than 20 different samples, each tested in octuplicates.

Fig. 1: Schematic represenation of three-dimensional angiogenesis assay in vitro; heart and aorta explants embedded in gel give rise to capillary sprouts (CLS).

Reproducibility of the in vitro system

First we tested basic culture conditions to ensure reproducibility of the assay. In contrast to aortic explants forming CLS in serum-free conditions, CLS formation of heart explants requires fetal calf serum (FCS, 5%) to ensure survival, whereas too high FCS concentrations mask the activity of angiogenically active molecules. In heart explants from mice younger than 8 weeks, CLS formed spontaneously-an unwanted response for testing the stimuli of angiogenic active factors. In 12-week-old adult mice however, virtually no CLS was formed under normoxia (standard culture condition, 19% O₂). Sex of the animals did not account for differences observed in CLS formation. Thus, for our future experiments, we chose adult mice, older than 12 weeks, to abolish the effect of active angiogenesis during adolescence of animals. Under hypoxia (3% O₂) however, CLS formation substantially increased, an established feature of angiogenesis, observed in vivo and in vitro.

Differential response toward angiogenic factors

Different classic angiogenic molecules induced diverse CLS: Platelet Derived Growth Factor (PDGF-BB) induced outgrowth of a mixture of organized branched endothelial sprouts, unorganized single endothelial cells and pericytes/smooth muscle cells. In contrast, basic Fibroblast Growth Factor (beta FGF) induced mainly unbranched, elongated CLS. Vascular Endothelial Growth Factor (VEGF₁₆₅) induced elongated CLS, and branching appeared complex (Fig. 2).

Fig. 2: Differential morphology of CLS can be observed after administration of different angiogenic molecules to mouse heart explants: basic Fibroblast Growth Factor - beta FGF (10 ng/ml), Platelet-Derived Growth Factor B-dimer -PDGF-BB (10 ng/ml), Vascular Endothelial Growth Factor - VEGF (5 ng/ml).

In vivo like response

Independent of the morphology induced by different agonists, outgrowing sprouts were composed of endothelial cells by more than 90% when outgrowing cells were subcultured and assessed by endothelial cell marker CD31, Dil-Ac-LDL. Double in-gel-staining with FITC-coupled lectin G. simplicifolia (green fluorescent) and Cy3-coupled antibody against -smooth muscle actin (red fluorescence) revealed endothelial sprouts with single attached smooth muscle cell-like cells (pericytes) (Fig. 3). Pericyte attachment forming endothelial tubes have been observed in vivo and contributes to vessel remodeling, maturation and stabilization.

Fig. 3: In-gel characterization of CLS by FITC-coupled lectin G. simplicifolia (green fluorescent) and Cy3-coupled anti alpha-smooth muscle actin-staining (red staining).

Organ specific response

Mechanisms involved in angiogenesis of the heart were further investigated in explants derived form transgenic mice lacking genes involved in angiogenesis. As an example, the role of nitric oxide (NO) in angiogenesis: NO promotes not only blood vessel relaxation and regulates vascular tone, but is critical for angiogenesis initiation and modulation (5). We investigated the role of inducible nitric oxide synthase (iNOS) under conditions of moderate hypoxia (3% O₂). In heart explants from iNOS (-/-) mice no CLS could be formed, regardless of angiogenic stimuli used (Fig. 4), whereas in aortae explants CLS was reproducibly formed from, however, at a reduced level when compared to wild type aorta (Fig. 4). Thus, iNOS requirement for angiogenesis is organ specific, optional for the aorta, but mandatory for the heart.

Fig. 4: Role of iNOS in angiogenesis: In vitro angiogenesis of aorta and heart in iNOS (-/-) mice under hypoxia (3% O₂). A standardized scale ranging from 0 to 8 indicated the degree of sprouting (CLS index). In aortae of iNOS (-/-) mice, in vitro angiogenesis in response to beta FGF, VEGF and PDGF-BB is present but strongly reduced when compared to wild type (+/+) animals. In hearts of iNOS (-/-) mice, angiogenesis was completely abrogated conditions when compared to wild-type animals.

A versatile in vitro model

The present in vitro angiogenesis model (6) of the heart allows:

• assessing angiogenesis in mouse and rat hearts. Both, induction and repression of angiogenesis can be investigated.
• rapid screening of pharmacological compounds by using only a small number of animals.
• different type of angiogenical active stimuli to be investigated due to the flexibility of experimental conditions.
• the use of tissue from knockout mice to investigate the role of specific genes in heart angiogenesis.

Together, a wide range of questions connected with therapeutic angiogenesis can be answered without the use of in vivo experiments.

Published updated version of this Bulletin 25/2007 (PDF)

References:

1. Freedman SB, Isner JM. Therapeutic angiogenesis for coronary artery disease. Ann Intern Med. 2002;136:54-71.
2. Schumacher B, Pecher P, von Specht BU, Stegmann T. Induction of neoangiogenesis in ischemic myocardium by human growth factors: first clinical results of a new treatment of coronary heart disease. Circulation. 1998;97:645-50.
3. Nicosia RF, Ottinetti A. Growth of microvessels in serum-free matrix culture of rat aorta. A quantitative assay of angiogenesis in vitro. Lab Invest. 1990;63:115-22.
4. Vailhe B, Vittet D, Feige JJ. In vitro models of vasculogenesis and angiogenesis. Lab Invest. 2001;81:439-52.
5. Sieber CC, Sumanovski LT, Stumm M, van der Kooij M, Battegay E. In vivo angiogenesis in normal and portal hypertensive rats: role of basic fibroblast growth factor and nitric oxide. J Hepatol. 2001;34:644-50.
6. Kiefer F, Munk V, Dieterle T, Humar R, Battegay EJ. A versatile model of angiogenesis in the rodent heart. In revision.

Letzte Änderung: 30.01.2008