Capillary leak syndrome (CLS) is an increasingly acknowledged multifaceted and potentially lethal disease. Initial nonspecific symptoms are followed by the intriguing CLS hallmark: the double paradox associating diffuse severe edema and hypovolemia, along with hemoconcentration and hypoalbuminemia. Spontaneous resolutive phase is often associated with poor outcome due to iatrogenic fluid overload during leak phase. CLS is mainly triggered by drugs (anti-tumoral therapies), malignancy, infections (mostly viruses) and inflammatory diseases. Its idiopathic form is named after its eponymous finder: Clarkson\'s disease. CLS pathophysiology involves a severe, transient and multifactorial endothelial disruption which mechanisms are still unclear. Empirical and based-on-experience treatment implies symptomatic care during the acute phase (with the eventual addition of drugs amplifying cAMP levels in the severest cases), and the prophylactic use of monthly polyvalent immunoglobulins to prevent relapses. As CLS literature is scattered, we aimed to collect and summarize the current knowledge on CLS to facilitate its diagnosis, understanding and management.

Antibody-toxin fused agents or immunotoxins, are a newly engineered class of cytotoxic agents consisting of a bacterial or plant toxin moiety hooked up either to a monoclonal antibody or a specific growth factor. Nevertheless, acquiring a full potency in clinic is mostly restricted due to the Capillary leak syndrome (CLS), a serious immune provoked, life-threatening side effect, subsequent to the endothelial damage, resulting in fluid escape from the bloodstream into tissues including lungs, muscle and brain, developing organ failure and eventually death. Proposed underlying mechanisms include direct damage to endothelial cells, acute inflammation, Lymphokine-activated killer (LAK) cells engagement, alteration in cell-cell/cell-matrix connectivities and cytoskeletal dysfunction. Very poor biodistribution and heterogeneous extravasation pattern in tumor site result in accumulation of ITs close to the extravasation site, gradual toxin release and initiation of nearby endothelial cells lysis, secretion of pro-inflammatory cytokines, development of acute inflammation and engagement of Lymphokine-activated killer (LAK) cells. Intrinsic immunogenicity of applied toxin moiety is another important determinant of CLS incidence. Toxins with more intrinsic immunogenicity possess more probability for CLS development. Recently, development of new generations of antibodies and mutated toxins with conserved cytotoxicity has partly tapered risk of CLS development. Here, we describe probable mechanisms involved in CLS and introduce some of the recently applied strategies for lessening incidence of CLS as much as possible.

Recombinant immunotoxins (RITs) are proteins that contain a toxin fused to an antibody or small molecules and are constructed by the genetic engineering technique. RITs can bind to and be internalized by cells and kill cancerous or non-cancerous cells by inhibiting protein synthesis. A wide variety of RITs have been tested against different cancers in cell culture, xenograft models, and human patients during the past several decades. RITs have shown activity in therapy of several kinds of cancers, but different levels of side effects, mainly related to vascular leak syndrome, were also observed in the treated patients. High immunogenicity of RITs limited their long-term or repeat applications in clinical cases. Recent advances in the design of immunotoxins, such as humanization of antibody fragment, PEGylation, and modification of human B- and T-cell epitopes, are overcoming the above mentioned problems, which predict the use of these immunotoxins as a potential therapeutic method to treat cancer patients.

Aging is associated with upregulation of tumor necrosis factor (TNF) and increased vascular inflammation. TNF is a major proinflammatory cytokine that contributes to both vascular inflammation and vascular leak syndrome (VLS). The purpose of this study was to investigate whether the aging affects TNF-induced VLS. Vascular leak, histology, and cytokine assays were performed in young and aged groups of wild-type and TNF overexpressing transgenic (Tg) mice. An aged group of TNF Tg mice showed substantially amplified VLS compared with young Tg mice. Age-related amplification of TNF-induced VLS appears to be related to local vascular fibrosis and the systemic upregulation of TNF and MCP-1 levels in older TNF Tg mice. Our finding suggests that chronic high-grade TNF exposure could mediate the severe vascular pathogenicity of VLS.

Although TNF-α possesses promising anticancer activity, clinical application is limited partly due to cardiovascular toxicities. TNF-α effects on vessels are likely related to vascular toxicity, but much remains poorly understood. Similarly, IL-2 is an attractive treatment option for cancers but its clinical use is limited by the side effect of vascular leak syndrome (VLS). We report here that TNF-α alone can trigger VLS. Administration of recombinant TNF-α induced VLS in normal mice and TNF-α transgenic mice exhibited VLS. Perivascular infiltrates in the lungs and specific cytokines in serum were observed in VLS-induced mice. This study shed a new light on the critical role of the TNF-α in IL-2-induced or non IL-2-induced VLS and provides important points to TNF-α therapy.

Immunotoxins are a novel class of antibody-conjugated therapeutics currently in clinical development for a variety of malignancies. They consist of an antibody-based targeting domain fused to a bacterial toxin payload for cell killing. Immunotoxins kill cells by inhibiting protein synthesis, a unique mechanism of action that is toxic to both dividing and nondividing cells. Recent advances in the design and administration of immunotoxins are overcoming historical challenges in the field, leading to renewed interest in these therapeutics.

Ribosome-inactivating proteins (RIPs) are EC3.2.32.22 N-glycosidases that recognize a universally conserved stem-loop structure in 23S/25S/28S rRNA, depurinating a single adenine (A4324 in rat) and irreversibly blocking protein translation, leading finally to cell death of intoxicated mammalian cells. Ricin, the plant RIP prototype that comprises a catalytic A subunit linked to a galactose-binding lectin B subunit to allow cell surface binding and toxin entry in most mammalian cells, shows a potency in the picomolar range. The most promising way to exploit plant RIPs as weapons against cancer cells is either by designing molecules in which the toxic domains are linked to selective tumor targeting domains or directly delivered as suicide genes for cancer gene therapy. Here, we will provide a comprehensive picture of plant RIPs and discuss successful designs and features of chimeric molecules having therapeutic potential.