Identification of intermolecular bonds between human factor B and Cobra Venom Factor important for C3 convertase stability.

Cobra venom factor (CVF) is the complement-activating protein in cobra venom. CVF is a structural and functional analog of complement component C3. CVF, like C3b, forms a convertase with factor B. This bimolecular complex CVF, Bb is an enzyme that cleaves C3 and C5. However, CVF, Bb exhibits significantly different functional properties from C3b,Bb. Whereas both, CVF, Bb and C3b, Bb exhibit spontaneous decay-dissociation into the respective subunits, thereby eliminating the enzymatic activity, the CVF, Bb convertase is physico-chemically far more stable, decaying with a half-life that is more than two orders of magnitude slower than that of C3b,Bb. In addition, CVF, Bb is completely resistant to inactivation by Factors H and I. These two properties of CVF, Bb allow continuous activation of C3 and C5, and complement depletion in serum. In order to understand the structural basis for the physico-chemical stability of CVF,Bb, we have created recombinant hybrid proteins of CVF and human C3, based on structural differences between CVF and human C3b in the C-terminal C345C domain. Here we describe three human C3/CVF hybrid proteins which differ in only one, two, or five amino acid residues from earlier described hybrid proteins. In all three cases, the hybrid proteins containing CVF residues form more stable convertases, and exhibit stronger complement-depletion activity than hybrid proteins with human C3 residues. Three bonds between CVF residues and Factor Bb residues could be identified by crystallographic modeling that contribute to the greater stability of the convertases.

Addressing Cancer Health Disparities in the Pacific Peoples of Hawai'i, Guam, and the US Associated Pacific Islands Through Pacific-Focused Research Capacity Building.

Sociocultural, geographic, and biologic factors contribute to cancer health disparities (CHDs) in indigenous Pacific peoples (IPPs) in Guam, Hawai'i, and the US Associated Pacific Islands (USAPI). IPPs experience a greater burden of CHDs that are associated with late-stage diagnosis and poor survival outcomes compared with majority populations in the United States. A 16-year partnership between the University of Guam (UOG) and University of Hawai'i Cancer Center (UHCC) aims to advance health equity in Guam, Hawai'i, and the USAPI through cancer research, training, and outreach. Investigators at collaborating institutions study issues of regional and cultural relevance in IPPs, including breast, cervical, liver, and oral cancers and use of tobacco and betel nuts (Areca nuts). Junior faculty with IPP ancestry or those who are focused on CHDs in IPPs receive mentorship and career development opportunities, academic fellowships are provided for graduate students, and Pacific Island communities are engaged through a participatory development process. The partnership has generated more than 90 peer-reviewed publications, more than 100 abstracts, and 11 grant awards. Thirty graduate scholars from under-represented minorities have been trained, including two who are now UOG faculty and are conducting independent research, contributing to the partnership, and mentoring scientists of tomorrow. Participatory community engagement has contributed to the passage of significant cancer prevention and control legislation in Hawai'i, Guam, and Saipan. Research capacity at UOG has increased significantly, and research at UHCC has expanded to address issues unique to IPPs. Graduate students from under-represented minorities are pursuing careers in cancer research. A regional research infrastructure has been established to support team science, and research findings are informing public health policy and planning.

The Role of Complement in Myocardial Infarction Reperfusion Injury: An Underappreciated Therapeutic Target.

This article reviews the pathogenetic role of the complement system in myocardial infarction reperfusion injury. The complement activation pathways involved in myocardial tissue injury are identified, as are the complement-derived effector molecules. The results of past anti-complement therapies are reviewed; as the more recent therapeutic concept of complement depletion with humanized CVF described.

A Unique Partnership Between the University of Hawai'i Cancer Center and the University of Guam: Fifteen Years of Addressing Cancer Health Disparities in Pacific Islanders in Hawai'i and Guam.

This manuscript describes the efforts in research, education, and outreach of a unique partnership between the University of Hawai'i Cancer Center and the University of Guam in addressing cancer health disparities faced by Pacific Islanders in Hawai'i, Guam, and other parts of Micronesia. Significant accomplishments of this 15-year collaboration in research, training Micronesian students, and impact on the local communities are highlighted.

Identification of functionally important amino acid sequences in cobra venom factor using human C3/Cobra venom factor hybrid proteins.

Cobra venom factor (CVF) is the complement-activating protein in cobra venom. CVF is a structural and functional analog of complement component C3. CVF, like C3b, forms a convertase with factor B. This bimolecular complex CVF,Bb is an enzyme that cleaves C3 and C5. However, CVF,Bb exhibits significantly different functional properties from C3b,Bb. The CVF,Bb convertase is physico-chemically very stable, and completely resistant to an activation by Factors H and I. These two properties, in contrast to C3b,Bb, allow continuous activation of C3 and C5, and complement depletion in serum. In order to understand the structural basis for the functional differences between CVF and C3, we have created several hybrid proteins of CVF and human C3. Here we report that replacing the C-terminal 168 amino acid residues of human C3 with the corresponding residues from CVF results in a hybrid protein (HC3-1496) which is essentially a human C3 derivative exhibiting the functional properties of CVF. This result demonstrates that the important structures for the CVF-specific functions reside within the C-terminal 168 amino acid residues of CVF. We further demonstrate that reverting the 46 C-terminal CVF residues of HC3-1496 to human C3 sequence results in a hybrid protein (HC3-1496/1617) that exhibits a physico-chemically unstable convertase with only residual complement depleting activity. This result demonstrates that most, but not all, structural requirements for CVF activity reside within the 46 C-terminal amino acid residues. We also investigated the potential role of position 1633, which is an acidic residue in human C3 (glutamic acid) but a basic amino acid residue (histidine) in CVF. However, the charge at position 1633 appears to be of no functional relevance. Exchanging the neutral amino acids present in CVF at positions 1499 and 1501 with the two charged amino acids at these positions in human C3 (aspartic acid and lysine) resulted in a hybrid protein that exhibited significantly slower convertase formation although both binding to Factor B and C3 cleavage was not affected, demonstrating that the charged amino acid residues at these two positions interfere with the formation of the convertase. In conclusion, our work demonstrates that hybrid proteins of human C3 and CVF present valuable tools to identify functionally important amino acid residues in CVF.

Absence of a neutralizing antibody response to humanized cobra venom factor in mice.

Cobra venom factor (CVF) is the complement-activating protein in cobra venom. Humanized CVF (hCVF) is a human C3 derivative where the C-terminal 168 amino acid residues were replaced with the homologous sequence from CVF. hCVF has been shown in multiple models of disease with complement pathology to be a promising therapeutic agent, with no observed adverse effects. Here we describe the antibody response to hCVF in two different strains of mice. hCVF was able to repeatedly decomplement the mice after four injections in weekly intervals, demonstrating the absence of a neutralizing antibody response. In contrast, natural CVF caused decomplementation in all mice only after the first administration. After two additional administrations of natural CVF, decomplementation was inconsistent and varied tremendously from mouse to mouse. After the fourth administration, natural CVF was essentially unable to deplete complement, consistent with the known generation of a neutralizing antibody response. We also analyzed the IgG antibody response to hCVF. There was great variation, with approximately one quarter of the mice exhibiting non-detectable levels of anti-hCVF IgG, and another quarter very low levels. The levels of anti-hCVF IgG did not correlate with the levels of remaining C3. The anti-hCVF antibodies cross-reacted with natural CVF, recombinant CVF, and human C3. Whereas overall the level of anti-hCVF IgG cross-reacting with human C3 was lower compared to rCVF or nCVF, mice with higher levels of anti-hCVF IgG exhibited higher binding to CVF and human C3, excluding the possibility that higher antibody levels reflect preferential immunogenicity of CVF-specific or human C3-specific epitopes.

Complement C3 is a novel modulator of the anti-factor VIII immune response.

Development of neutralizing antibodies against therapeutic Factor VIII (FVIII) is the most serious complication of the treatment of hemophilia A. There is growing evidence to show the multifactorial origin of the anti-FVIII immune response, combining both genetic and environmental factors. While a role for the complement system on innate as well as adaptive immunity has been documented, the implication of complement activation on the onset of the anti-FVIII immune response is unknown. Here, using in vitro assays for FVIII endocytosis by human monocyte-derived dendritic cells and presentation to T cells, as well as in vivo complement depletion in FVIII-deficient mice, we show a novel role for complement C3 in enhancing the immune response against therapeutic FVIII. In vitro, complement C3 and its cleavage product C3b enhanced FVIII endocytosis by dendritic cells and presentation to a FVIII-specific CD4+ T-cell hybridoma. The C1 domain of FVIII had previously been shown to play an important role in FVIII endocytosis, and alanine substitutions of the K2092, F2093 and R2090 C1 residues drastically reduce FVIII uptake in vitro Interestingly, complement activation rescued the endocytosis of the FVIII C1 domain triple mutant. In a mouse model of severe hemophilia A, transient complement C3 depletion by humanized cobra venom factor, which does not generate anaphylatoxin C5a, significantly reduced the primary anti-FVIII immune response, but did not affect anti-FVIII recall immune responses. Taken together, our results suggest an important adjuvant role for the complement cascade in the initiation of the immune response to therapeutic FVIII.

From basic mechanisms to clinical applications in heart protection, new players in cardiovascular diseases and cardiac theranostics: meeting report from the third international symposium on "New frontiers in cardiovascular research".

In this meeting report, particularly addressing the topic of protection of the cardiovascular system from ischemia/reperfusion injury, highlights are presented that relate to conditioning strategies of the heart with respect to molecular mechanisms and outcome in patients' cohorts, the influence of co-morbidities and medications, as well as the contribution of innate immune reactions in cardioprotection. Moreover, developmental or systems biology approaches bear great potential in systematically uncovering unexpected components involved in ischemia-reperfusion injury or heart regeneration. Based on the characterization of particular platelet integrins, mitochondrial redox-linked proteins, or lipid-diol compounds in cardiovascular diseases, their targeting by newly developed theranostics and technologies opens new avenues for diagnosis and therapy of myocardial infarction to improve the patients' outcome.

Meeting report from the 2nd International Symposium on New Frontiers in Cardiovascular Research. Protecting the cardiovascular system from ischemia: between bench and bedside.

Recent advances in basic cardiovascular research as well as their translation into the clinical situation were the focus at the last "New Frontiers in Cardiovascular Research meeting". Major topics included the characterization of new targets and procedures in cardioprotection, deciphering new players and inflammatory mechanisms in ischemic heart disease as well as uncovering microRNAs and other biomarkers as versatile and possibly causal factors in cardiovascular pathogenesis. Although a number of pathological situations such as ischemia-reperfusion injury or atherosclerosis can be simulated and manipulated in diverse animal models, also to challenge new drugs for intervention, patient studies are the ultimate litmus test to obtain unequivocal information about the validity of biomedical concepts and their application in the clinics. Thus, the open and bidirectional exchange between bench and bedside is crucial to advance the field of ischemic heart disease with a particular emphasis of understanding long-lasting approaches in cardioprotection.

Complement depletion with humanised cobra venom factor: efficacy in preclinical models of vascular diseases.

The complement system is an intrinsic part of the immune system and has important functions in both innate and adaptive immunity. On the other hand, inadvertent or misdirected complement activation is also involved in the pathogenesis of many diseases, contributing solely or significantly to tissue injury and disease development. Multiple approaches to develop pharmacological agents to inhibit complement are currently being pursued. We have developed a conceptually different approach of not inhibiting but depleting complement, based on the complement-depleting activities of cobra venom factor (CVF), a non-toxic cobra venom component with structural and functional homology to complement component C3. We developed a humanised version of CVF by creating human complement component C3 derivatives with complement-depleting activities of CVF (humanised CVF) as a promising therapeutic agent for diseases with complement pathogenesis. Here we review the beneficial therapeutic effect of humanised CVF in several murine models of vascular diseases such as reperfusion injury.

Humanized cobra venom factor: structure, activity, and therapeutic efficacy in preclinical disease models.

The complement system is an integral component of both innate and adaptive immunity. However, complement is also a pathogenetic factor in many diseases. The development of agents for therapeutic complement inhibition is the topic of intense investigations by many investigators. We have developed a distinctly different therapeutic approach: complement depletion rather than inhibition. This approach is based on cobra venom factor (CVF), a C3 analog known to be able to safely deplete complement. This manuscript will briefly review the structure and activity of CVF, along with its similarities and differences to C3. Exploiting the knowledge of the structure/function relationship of CVF and C3, we created derivatives of human C3 which display the CVF-like activity of depleting complement, referred to as humanized CVF (hCVF). This review describes the structure and activity of hCVF, including the important property of not cleaving C5. The efficacy of hCVF for therapeutic complement depletion in nine preclinical models diseases with complement pathology is reviewed, including reperfusion injury, age-related macular degeneration (AMD), paroxysmal nocturnal hemoglobinuria (PNH), and immunogenicity of Factor VIII in hemophilia A. Complement depletion is characterized by the absence of toxicity, even after intra-arterial injection into the pulmonary artery of primates. No immunogenicity has been observed.

Hybrid proteins of Cobra Venom Factor and cobra C3: tools to identify functionally important regions in Cobra Venom Factor.

Cobra Venom Factor (CVF) is the complement-activating protein in cobra venom. CVF is structurally and functionally highly homologous to complement component C3. CVF, like C3b, the activated form of C3, forms a bimolecular complex with Factor B in serum, called C3/C5 convertase, an enzyme which activates complement components C3 and C5. Despite the high degree of homology, the two C3/C5 convertases exhibit significant functional differences. The most important difference is that the convertase formed with CVF (CVF,Bb) is physico-chemically far more stable than the convertase formed with C3b (C3b,Bb). In addition, the CVF,Bb convertase and CVF are completely resistant to inactivation by the complement regulatory proteins Factor H and Factor I. Furthermore, the CVF,Bb enzyme shows efficient C5-cleaving activity in fluid phase. In contrast, the C3b,Bb enzyme is essentially devoid of fluid-phase C5-cleaving activity. By taking advantage of the high degree of sequence identity at both the amino acid (85%) and DNA levels (93%) between CVF and cobra C3, we created hybrid proteins of CVF and cobra C3 where sections, or only a few amino acids, of the CVF sequence were replaced with the homologous amino acid sequence of cobra C3. In a first set of experiments, we created five hybrid proteins, termed H1 through H5, where the cobra C3 substitutions collectively spanned the entire length of the CVF protein. We also created three additional hybrid proteins where only four or five amino acid residues in CVF were exchanged with the corresponding amino acid residues from cobra C3. Collectively, these hybrid proteins, representing loss-of-function mutants of CVF, allowed the identification of regions and individual amino acid residues important for the CVF-specific functions. The results include the observation that the CVF ß-chain is crucially important for forming a stable convertase, whereas the CVF α-chain appears to harbor no CVF-specific functions. Furthermore, the CVF γ-chain is additionally important for the fluid-phase C5-cleaving activity of CVF,Bb. Interestingly, the structural changes in the individual hybrid proteins differentially affected the molecular functions of the CVF,Bb enzyme such as convertase formation, C3 cleavage, and C5 cleavage.

Complement depletion with humanized cobra venom factor in a mouse model of age-related macular degeneration.

The effect of complement depletion with humanized cobra venom factor (CVF) on retinal lesion development/neovascularization was determined in a mouse model of wet age-related macular degeneration (AMD). Mice were treated with the humanized CVF protein HC3-1496 prior to, and once daily for 28 days after laser coagulation surgery of the retina. CVF transgenic mice exhibiting permanently low levels of serum complement activity and PBS-treated mice served as positive and negative controls, respectively. Fluorescein isothiocyanate (FITC)-dextran funduscopy after laser surgery indicated the presence of lesions in all mice that underwent laser surgery. In HC3-1496-treated mice as well as CVF transgenic mice smaller lesions were seen after 8 days. Measurement of lesion sizes by histopathological examination of eyes after 28 days revealed a significant reduction of lesion area and volume in both HC3-1496-treated animals and CVF transgenic animals compared to PBS-treated control animals. Systemic complement depletion with a complement depletor, such as the humanized CVF protein HC3-1496, represents a promising therapeutic concept for patients with wet AMD.

A partnership between the cancer research center of Hawaii and the University of Guam in Cancer Research, Education, Training, and Outreach.

Cancer Health Disparities. The term cancer health disparities describes the unequal burden of cancer incidence, morbidity, and mortality in different population groups. By and large, the higher burden of cancer is observed in racial or ethnic minorities, immigrant communities, inner city populations, and insular, rural, or otherwise geographically isolated populations. In rare instances, however, the majority Caucasian population suffers a higher burden of cancer, e.g., melanoma. There are multiple and overlapping causes for cancer health disparities, including genetic make up, cultural norms and beliefs, behavior, environmental factors, as well as social aspects such as socio-economic status, poverty, and education. Reducing cancer health disparities is an important and integral component of the nation's effort to improve the health of all Americans. The science of cancer health disparities aims to better understand the causes of health disparities and to develop better means of prevention, diagnosis, and therapy, although some of the social aspects of cancer health disparities may be beyond the reach of the biomedical community.

Cobra venom factor: Structure, function, and humanization for therapeutic complement depletion.

Cobra venom factor (CVF) is the complement-activating protein in cobra venom. This manuscript reviews the structure and function of CVF, how it interacts with the complement system, the structural and functional homology to complement component C3, and the use of CVF as an experimental tool to decomplement laboratory animals to study the functions of complement in host defense and immune response as well as in the pathogenesis of diseases. This manuscript also reviews the recent progress in using the homology between CVF and C3 to study C3 structure and function, and to develop human C3 derivatives with the complement-depleting function of CVF. These human C3 derivatives represent humanized CVF, and are a conceptually different concept for pharmacological intervention of the complement system, therapeutic complement depletion. The use of humanized CVF for therapeutic complement depletion in several pre-clinical models of human diseases is also reviewed.

Depletion of the C3 component of complement enhances the ability of rituximab-coated target cells to activate human NK cells and improves the efficacy of monoclonal antibody therapy in an in vivo model.

Growing evidence indicates antibody-dependent cellular cytotoxicity (ADCC) contributes to the clinical response to monoclonal antibody (mAb) therapy of lymphoma. Recent in vitro analysis suggests C3b can inhibit mAb-induced natural killer (NK)-cell activation and ADCC. Further studies were conducted to assess the effect of C3 depletion on mAb-induced NK activation and therapy of lymphoma. Normal human serum inhibited the ability of rituximab-coated lymphoma cells to activate NK cells as previously reported. Serum did not inhibit NK-cell activation when it was preincubated with cobra venom factor (CVF) to deplete C3. Similar results were found when transudative pleural fluid or nonmalignant ascites was used as surrogates for extravascular fluid, suggesting the inhibitory effect of complement may be present in the extravascular compartment, in which many malignant lymphocytes reside. In vivo, C3 was depleted before mAb treatment in a syngeneic murine model of lymphoma. Survival of lymphoma-bearing mice after treatment with CVF plus mAb and with a human C3 derivative with CVF-like functions (HC3-1496) plus mAb was both superior to that of mAb alone. These studies show that complement depletion enhances NK-cell activation induced by rituximab-coated target cells and improves the efficacy of mAb therapy in a murine lymphoma model.

Humanized cobra venom factor decreases myocardial ischemia-reperfusion injury.

Cobra venom factor (CVF) is a complement activating protein in cobra venom, which functionally resembles C3b, and has been used for decades for decomplementation of serum to investigate the role of complement in many model systems of disease. The use of CVF for clinical practice is considered impractical because of immunogenicity issues. Humanization of CVF was recently demonstrated to yield a potent CVF-like molecule. In the present study, we demonstrate that mice treated with recombinant humanized CVF (HC3-1496) are protected from myocardial ischemia-reperfusion (MI/R) injuries with resultant preservation of cardiac function. Also, C3 deposition in the myocardium following MI/R was not observed following treatment with HC3-1496. HC3-1496 led to complement activation and depletion of C3, but preserved C5 titers. These data suggest, unlike CVF, HC3-1496 does not form a C5 convertase in the mouse, similar to recent studies in human sera/plasma. These results suggest that humanized CVF (HC3-1496) protects the ischemic myocardium from reperfusion injuries induced by complement activation and represents a novel anti-complement therapy for potential clinical use.