A ribosome-bound quality control complex triggers degradation of nascent peptides and signals translation stress.

The conserved transcriptional regulator heat shock factor 1 (Hsf1) is a key sensor of proteotoxic and other stress in the eukaryotic cytosol. We surveyed Hsf1 activity in a genome-wide loss-of-function library in Saccaromyces cerevisiae as well as ~78,000 double mutants and found Hsf1 activity to be modulated by highly diverse stresses. These included disruption of a ribosome-bound complex we named the Ribosome Quality Control Complex (RQC) comprising the Ltn1 E3 ubiquitin ligase, two highly conserved but poorly characterized proteins (Tae2 and Rqc1), and Cdc48 and its cofactors. Electron microscopy and biochemical analyses revealed that the RQC forms a stable complex with 60S ribosomal subunits containing stalled polypeptides and triggers their degradation. A negative feedback loop regulates the RQC, and Hsf1 senses an RQC-mediated translation-stress signal distinctly from other stresses. Our work reveals the range of stresses Hsf1 monitors and elucidates a conserved cotranslational protein quality control mechanism.

Experience of parents of preschool children in Hawaii during the COVID-19 pandemic.

OBJECTIVE: The COVID-19 pandemic has resulted in major disruption to economic, health, education, and social systems. Families with preschool children experienced extraordinary strain during this time. This paper describes a qualitative study examining the experience of parents of preschool children in Hawaii during the COVID-19 pandemic. SAMPLE: Thirteen (N = 13) parents of preschool children living on the island of Oahu, Hawaii, participated in small group discussions occurring in February and March 2021, approximately 1 year after the start of the pandemic in the state. Discussion transcripts were coded and sorted into themes. RESULTS: Four themes emerged: stressors due to the COVID-19 pandemic, family coping and resources, meaning of the COVID-19 crisis to the family, and family adaptation patterns. Themes mapped to the Family Adjustment and Adaptation Response model. CONCLUSION: Families relied on various resources to cope with stressors experienced due to the COVID-19 pandemic, and adopted new patterns related to seeking healthcare and household emergency preparedness. Findings may inform policies and interventions to support families during the ongoing COVID-19 pandemic and future public health emergencies.

Interplay between Carbonic Anhydrases and Metallothioneins: Structural Control of Metalation.

Carbonic anhydrases (CAs) and metallothioneins (MTs) are both families of zinc metalloproteins central to life, however, they coordinate and interact with their Zn2+ ion cofactors in completely different ways. CAs and MTs are highly sensitive to the cellular environment and play key roles in maintaining cellular homeostasis. In addition, CAs and MTs have multiple isoforms with differentiated regulation. This review discusses current literature regarding these two families of metalloproteins in carcinogenesis, with a dialogue on the association of these two ubiquitous proteins in vitro in the context of metalation. Metalation of CA by Zn-MT and Cd-MT is described. Evidence for protein-protein interactions is introduced from changes in metalation profiles of MT from electrospray ionization mass spectrometry and the metalation rate from stopped-flow kinetics. The implications on cellular control of pH and metal donation is also discussed in the context of diseased states.

Nuclear 82-kDa choline acetyltransferase decreases amyloidogenic APP metabolism in neurons from APP/PS1 transgenic mice.

Alzheimer disease (AD) is associated with increased amyloidogenic processing of amyloid precursor protein (APP) to ß-amyloid peptides (Aß), cholinergic neuron loss with decreased choline acetyltransferase (ChAT) activity, and cognitive dysfunction. Both 69-kDa ChAT and 82-kDa ChAT are expressed in cholinergic neurons in human brain and spinal cord with 82-kDa ChAT localized predominantly to neuronal nuclei, suggesting potential alternative functional roles for the enzyme. By gene microarray analysis, we found that 82-kDa ChAT-expressing IMR32 neural cells have altered expression of genes involved in diverse cellular functions. Importantly, genes for several proteins that regulate APP processing along amyloidogenic and non-amyloidogenic pathways are differentially expressed in 82-kDa ChAT-containing cells. The predicted net effect based on observed changes in expression patterns of these genes would be decreased amyloidogenic APP processing with decreased Aß production. This functional outcome was verified experimentally as a significant decrease in BACE1 protein levels and activity and a concomitant reduction in the release of endogenous Aß1-42 from neurons cultured from brains of AD-model APP/PS1 transgenic mice. The expression of 82-kDa ChAT in neurons increased levels of GGA3, which is involved in trafficking BACE1 to lysosomes for degradation. shRNA-induced decreases in GGA3 protein levels attenuated the 82-kDa ChAT-mediated decreases in BACE1 protein and activity and Aß1-42 release. Evidence that 82-kDa ChAT can enhance GGA3 gene expression is shown by enhanced GGA3 gene promoter activity in SN56 neural cells expressing this ChAT protein. These studies indicate a novel relationship between cholinergic neurons and APP processing, with 82-kDa ChAT acting as a negative regulator of Aß production. This decreased formation of Aß could result in protection for cholinergic neurons, as well as protection of other cells in the vicinity that are sensitive to increased levels of Aß. Decreasing levels of 82-kDa ChAT due to increasing age or neurodegeneration could alter the balance towards increasing Aß production, with this potentiating the decline in function of cholinergic neurons.

Hyperactive neuroendocrine secretion causes size, feeding, and metabolic defects of C. elegans Bardet-Biedl syndrome mutants.

Bardet-Biedl syndrome, BBS, is a rare autosomal recessive disorder with clinical presentations including polydactyly, retinopathy, hyperphagia, obesity, short stature, cognitive impairment, and developmental delays. Disruptions of BBS proteins in a variety of organisms impair cilia formation and function and the multi-organ defects of BBS have been attributed to deficiencies in various cilia-associated signaling pathways. In C. elegans, bbs genes are expressed exclusively in the sixty ciliated sensory neurons of these animals and bbs mutants exhibit sensory defects as well as body size, feeding, and metabolic abnormalities. Here we show that in contrast to many other cilia-defective mutants, C. elegans bbs mutants exhibit increased release of dense-core vesicles and organism-wide phenotypes associated with enhanced activities of insulin, neuropeptide, and biogenic amine signaling pathways. We show that the altered body size, feeding, and metabolic abnormalities of bbs mutants can be corrected to wild-type levels by abrogating the enhanced secretion of dense-core vesicles without concomitant correction of ciliary defects. These findings expand the role of BBS proteins to the regulation of dense-core-vesicle exocytosis and suggest that some features of Bardet-Biedl Syndrome may be caused by excessive neuroendocrine secretion.

Overexpression of pyruvate dehydrogenase kinase 1 and lactate dehydrogenase A in nerve cells confers resistance to amyloid ß and other toxins by decreasing mitochondrial respiration and reactive oxygen species production.

We previously demonstrated that nerve cell lines selected for resistance to amyloid ß (Aß) peptide exhibit elevated aerobic glycolysis in part due to increased expression of pyruvate dehydrogenase kinase 1 (PDK1) and lactate dehydrogenase A (LDHA). Here, we show that overexpression of either PDK1 or LDHA in a rat CNS cell line (B12) confers resistance to Aß and other neurotoxins. Treatment of Aß-sensitive cells with various toxins resulted in mitochondrial hyperpolarization, immediately followed by rapid depolarization and cell death, events accompanied by increased production of cellular reactive oxygen species (ROS). In contrast, cells expressing either PDK1 or LDHA maintained a lower mitochondrial membrane potential and decreased ROS production with or without exposure to toxins. Additionally, PDK1- and LDHA-overexpressing cells exhibited decreased oxygen consumption but maintained levels of ATP under both normal culture conditions and following Aß treatment. Interestingly, immunoblot analysis of wild type mouse primary cortical neurons treated with Aß or cortical tissue extracts from 12-month-old APPswe/PS1dE9 transgenic mice showed decreased expression of LDHA and PDK1 when compared with controls. Additionally, post-mortem brain extracts from patients with Alzheimer disease exhibited a decrease in PDK1 expression compared with nondemented patients. Collectively, these findings indicate that key Warburg effect enzymes play a central role in mediating neuronal resistance to Αß or other neurotoxins by decreasing mitochondrial activity and subsequent ROS production. Maintenance of PDK1 or LDHA expression in certain regions of the brain may explain why some individuals tolerate high levels of Aß deposition without developing Alzheimer disease.

Ho'oilina Pono A'e: Integrating Native Hawaiian Healing to Create a Just Legacy for the Next Generation.

Native healing practitioners have been incorporated into health centers serving large populations of Kanaka 'Oiwi (Native Hawaiians). However, no studies have examined their impact. A community based participatory research study at Waimanalo Health Center from 2017 to 2019 examined the added value of integrating native healing practices into primary care, including whether there is acceptability of the integration, cultural connectedness due to integration, and empowerment for patients, providers, and staff. Semi-structured interviews were conducted by the research team with 24 patients, providers and staff, and community residents. Through content analysis, 5 themes emerged. The integration of native healing practices provides an alternative to western medicine, recalls ancestral knowledge, focuses on the whole person, generates increased disclosure leading to behavior change, and is central to a decolonizing process. The findings support the integration of native healing practices providing added value in primary care.

Amyloid-beta oligomers increase the localization of prion protein at the cell surface.

In Alzheimer's disease, the amyloid-ß peptide (Aß) interacts with distinct proteins at the cell surface to interfere with synaptic communication. Recent data have implicated the prion protein (PrP(C)) as a putative receptor for Aß. We show here that Aß oligomers signal in cells in a PrP(C)-dependent manner, as might be expected if Aß oligomers use PrP(C) as a receptor. Immunofluorescence, flow cytometry and cell surface protein biotinylation experiments indicated that treatment with Aß oligomers, but not monomers, increased the localization of PrP(C) at the cell surface in cell lines. These results were reproduced in hippocampal neuronal cultures by labeling cell surface PrP(C). In order to understand possible mechanisms involved with this effect of Aß oligomers, we used live cell confocal and total internal reflection microscopy in cell lines. Aß oligomers inhibited the constitutive endocytosis of PrP(C), but we also found that after Aß oligomer-treatment PrP(C) formed more clusters at the cell surface, suggesting the possibility of multiple effects of Aß oligomers. Our experiments show for the first time that Aß oligomers signal in a PrP(C)-dependent way and that they can affect PrP(C) trafficking, increasing its localization at the cell surface.

A novel KIF5B-ALK variant in nonsmall cell lung cancer.

BACKGROUND: The anaplastic lymphoma kinase (ALK) gene is involved frequently in chromosomal translocations, resulting in fusion genes with different partners found in various lymphoproliferative conditions. It was recently reported in nonsmall cell lung cancer (NSCLC) that the fusion protein encoded by echinoderm microtubule-associated protein-like 4-ALK (EML4-ALK) fusion gene conferred oncogenic properties. The objective of the current study was to identify other possible ALK fusion genes in NSCLC. METHODS: Immunohistochemical analysis was used to screen for aberrant ALK expression in primary NSCLC. The authors used 5' rapid amplification of complementary DNA ends to screen for potential, novel 5' fusion partners of ALK other than EML4-ALK. Reverse transcriptase-polymerase chain reaction and fluorescence in situ hybridization analyses were used to confirm the identity of 5' fusion partners. The genomic breakpoint was verified using genomic sequencing. Overexpression of the novel ALK fusion gene and variants 3a and 3b of EML4-ALK was performed to assess downstream signaling and functional effects. RESULTS: The authors identified a novel gene resulting from the fusion of kinesin family member 5B (KIF5B) exon 15 to ALK exon 20 in a primary lung adenocarcinoma. Western blot analysis of clinical tumor tissues revealed the expression of a protein whose size correlated with that of the predicted KIF5B-ALK. Overexpression of KIF5B-ALK in mammalian cells led to the activation of signal transducer and activator of transcription 3 and protein kinase B and to enhanced cell proliferation, migration, and invasion. CONCLUSIONS: The discovery of the novel KIF5B-ALK variant further consolidated the role of aberrant ALK signaling in lung carcinogenesis.

Rapid Implementation of a Statewide Observational Surveillance System to Monitor Wearing of Face Masks in Public Spaces.

This report describes the rapid implementation of a statewide observational surveillance program to monitor the public's wearing of face masks in public spaces during community spread of Coronavirus disease 2019 (COVID-19). It describes how the Hawai'i State Department of Health partnered with University of Hawai'i faculty to develop and implement the surveillance program. The surveillance program involved organizing volunteers to conduct weekly direct observations in designated locations. A smartphone application (app) was created to record real-time observational surveillance data. From September 5, 2020, to March 13, 2021, a total of 84 577 observations were conducted across the state. Eighty-three percent of those observed were correctly wearing a face mask, 7% were wearing a face mask incorrectly, and 10% were not wearing a mask. Following the 2-week pilot phase of the project, volunteers were surveyed regarding facilitators and barriers for conducting observations and motivations for volunteering. Feedback was used to refine project procedures. With few states having implemented such a surveillance program, the information reported in this article may inform communities interested in tracking mask-wearing behaviors in the context of the COVID-19 pandemic.

Experiences and perceptions of school staff regarding the COVID-19 pandemic and racial equity: The role of colorblindness.

As schools physically closed across the country to protect against the spread of the COVID-19 pandemic, it became clear early on that the burden on students will not be equally shared. Structural racism patterns the lives of people of color that, in turn, increases their exposure to the effects of the pandemic further impacting the quality of education the students of color have access to. It is critical to examine the ways in which racial disparities in social emotional and educational outcomes have the potential to increase as a result of the pandemic. To that end, using a content analysis of an open-ended survey, this study examines (a) how teachers and school staff experienced the pandemic, (b) their perception of student experiences during the transition to remote learning, and (c) school staff's perceptions of how racial inequities may be increased as a result of the pandemic. Our findings highlight the deep, but unequal impact of the pandemic on school staff, students, and their families. Teachers are overwhelmed and overworked, struggling to manage multiple roles while working at home. They also have tremendous empathy for the weight of the losses that students have experienced, and concern for the well-being of students in difficult living or family situations. However, most school staff maintained a colorblind analysis of the way the pandemic is affecting their students and did not recognize the role of systemic racism or potential for racial disparities to be increased. Implications and limitations are discussed. (PsycInfo Database Record (c) 2021 APA, all rights reserved).

Metallothionein Cd4S11 cluster formation dominates in the protection of carbonic anhydrase.

Metallothioneins (MTs) are ubiquitous proteins vital for essential metal homeostasis and heavy metal detoxification. The twenty-cysteinyl mammalian metallothioneins protect the proteome by sequestering heavy metals into thermodynamically stable metal thiolate structures when metalated with seven Cd2+. At physiological pH, the first metal (M) thiolate (SCys) structures formed involve M(SCys)4 terminal thiolates. With higher metal loading, M4(SCys)11 and M3(SCys)9 clusters form. As a regulator of the metallome, it is necessary to understand metal sequestration properties of MT in solution with other metalloproteins. We report that the association between apo-MT and apo-carbonic anhydrase (CA) enhances the formation of the protective mode of MT, in which Cd4(SCys)11-clusters form at much lower concentration levels than for the free apo-MT at physiological pH. Using stopped-flow kinetics and electrospray ionization mass spectrometry, we quantified this protective effect, determining that it is significant at pH 7.4, but the effect diminishes at pH 5.0. We report for the first time, the absolute stepwise binding constants of Cd2+ binding to human MT1a both in the presence and absence of CA through calibration by the known binding constant of Cd2+ to bovine CA. We report that this protein association affects the Cd2+ metalation rates of MT. The data support the physiological role of MTs as protectors of the metalloproteome from the toxic effects of Cd2+.

Assessing the severity of perinatal hypoxia-ischemia in piglets using near-infrared spectroscopy to measure the cerebral metabolic rate of oxygen.

Reduced cerebral function after neonatal hypoxia-ischemia is an early indicator of hypoxic-ischemic encephalopathy. Near-infrared spectroscopy offers a clinically relevant means of detecting impaired cerebral metabolism from the measurement of the cerebral metabolic rate of oxygen (CMRO2). The purpose of this study was to determine the relationship between postinsult CMRO2 and duration of hypoxia-ischemia in piglets. Twelve piglets were subjected to randomly selected durations of hypoxia-ischemia (5-28 min) and five animals served as controls. Measurements of CMRO2 were taken before and for 24 h after hypoxia-ischemia. Histology was carried out in nine piglets (six insults, three controls) to estimate brain injury. In the first 4 h after the insult, average CMRO2 of the insult group was significantly depressed (33 +/- 3% reduction compared with controls) and by 8 h, a significant correlation developed, which persisted for the remainder of the study, between CMRO2 and the duration of ischemia. Histologic staining suggested little brain damage resulted from shorter insult durations and considerable damage from more prolonged insults. This study demonstrated that near-infrared spectroscopy could detect early changes in CMRO2 after hypoxia-ischemia for a range of insult severities and CMRO2 could be used to distinguish insult severity by 8 h after the insult.

Kinetics of competitive Cd2+ binding pathways: the realistic structure of intrinsically disordered, partially metallated metallothioneins.

The 20-cysteine mammalian metallothioneins are considered to be central to the homeostatic control of the essential metals Zn(ii) and Cu(i) and, as part of their metal-loaded status, play a role in reversing oxidative stress. Native apo-MT does not adopt a well-known structural motif, being described as a random-coil or intrinsically-disordered. Conclusions reached from a combination of ESI-mass spectral charge states, As(iii) metallation of apo-MT at low pH, from molecular dynamic calculations and from metallation of the α-domain fragment, suggest that in fact the native apo-MT adopts a structure that is highly efficient towards metallation at physiological pH. The results in this paper show that the initial (M < 5) Cd(ii) metallation at physiological pH takes place to form structures based on isolated Cd(SCYS)4 units, beads. At pH 5, cysteine bridged Cd4(SCYS)11 clusters form. ESI-mass spectral profile of cysteine modification of apo-MT at physiological pH shows that it is folded, whereas in the presence of 3 M guandinium hydrochloride the apo-MT is unfolded. Stopped flow kinetic studies of the Cd(ii) metallation shows that the reaction is much slower for the unfolded vs. the folded apo-MT for formation of either beads or clusters. Metallation is also much slower for the formation of clusters than the formation of beads. These results are first to quantify the presence of structure in native apo-MT in terms of the critical metallation properties. The implications of this study suggest that oxidation of apo-MT due to ageing or other agent will negatively impact the metallation process for essential metals.

Metallothionein: An Aggressive Scavenger-The Metabolism of Rhodium(II) Tetraacetate (Rh2(CH3CO2)4).

Anthropogenic sources of xenobiotic metals with no physiological benefit are increasingly prevalent in the environment. The platinum group metals (Pd, Pt, Rh, Ru, Os, and Ir) are found in marine and plant species near urban sources, and are known to bioaccumulate, introducing these metals into the human food chain. Many of these metals are also being used in innovative cancer therapy, which leads to a direct source of exposure for humans. This paper aims to further our understanding of nontraditional metal metabolism via metallothionein, a protein involved in physiologically important metal homeostasis. The aggressive reaction of metallothionein and dirhodium(II) tetraacetate, a common synthetic catalyst known for its cytotoxicity, was studied in detail in vitro. Optical spectroscopic and equilibrium and time-dependent mass spectral data were used to define binding constants for this robust reaction, and molecular dynamics calculations were conducted to explain the observed results.

Capturing platinum in cisplatin: kinetic reactions with recombinant human apo-metallothionein 1a.

cis-Diamminedichloroplatinum(ii) (cisplatin), a powerful chemotherapeutic, can incur chemoresistance in cancers, reducing therapeutic success. Metallothioneins (MTs) are suspected of metallodrug interference via ligand removal and metal sequestration. The mechanistic details and reactions rates kobs for the systematic deconstruction of cisplatin by apo-human MT are reported and analysed from mass spectral data.

Lead(II) Binding in Metallothioneins.

Heavy metal exposure has long been associated with metallothionein (MT) regulation and its functions. MT is a ubiquitous, cysteine-rich protein that is involved in homeostatic metal response for the essential metals zinc and copper, as well as detoxification of heavy metals; the most commonly proposed being cadmium. MT binds in vivo to a number of metals in addition to zinc, cadmium and copper, such as bismuth. In vitro, metallation with a wide range of metals (especially mercury, arsenic, and lead) has been reported using a variety of analytical methods. To fully understand MT and its role with lead metabolism, we will describe how MT interacts with a wide variety of metals that bind in vitro. In general, affinity to the metal-binding cysteine residues of MT follows that of metal binding to thiols: Zn(II) < Pb(II) < Cd (II) < Cu(I) < Ag(I) < Hg(II) < Bi(III). To introduce the metal binding properties that we feel directly relate to the metallation of metallothionein by Pb(II), we will explore MT's interactions with metals long known as toxic, particularly, Cd(II), Hg(II), and As(III), along with xenobiotic metals, and how these metal-binding studies complement those of lead binding. Lead's effects on an organism's physiological functions are not fully understood, but it is known that chronic exposure inflicts amongst other factors pernicious anemia and developmental issues in the brain, especially in children who are more vulnerable to its toxic effects. Understanding the interaction of lead with metallothioneins throughout the biosphere, from bacteria, to algae, to fish, to humans, is important in determining pathways for lead to enter and damage physiologically significant protein function, and thereby its toxicity.

Glutathione binding to dirhodium tetraacetate: a spectroscopic, mass spectral and computational study of an anti-tumour compound.

Glutathione (γ-l-glutamyl-l-cysteinyl-glycine) is a ubiquitous tripeptide found in all plants and animals. Glutathione has key roles as a metallochaperone and as a cellular thiol involved in metabolism. Little is known about how glutathione interacts with organometallic compounds in vivo. Here, we report the reactions of glutathione in vitro with dirhodium(ii) tetraacetate (tetrakis(µ-acetato)dirhodium(ii), Rh2(OAc)4), a compound with anti-tumour properties. Electrospray ionization mass spectrometry, UV-Visible absorption and circular dichroism spectroscopic methods were used to determine the stoichiometries and optical properties of the final conjugate. Computational analyses were used to predict the binding modes of glutathione to the Rh2(OAc)4, and report on the orbital assignments for the resulting products. We explored the competition by GSH for methionine-bound axial sites on Rh2(OAc)4 to investigate the use of weak thioether to protect its cellular-based anti-cancer activity. Our study highlights the important role that axial ligation would play in deactivating or significantly decreasing the efficacy of this bimetallic anti-tumor drug. The computational data explain the stability of the mono-adduct and the appearance of new absorption bands in the UV region including retention of the Rh-Rh single bond. Additionally, these data show that glutathione can effectively disable the potency of these metallo-drugs through orbital overlap of the entire Rh-Rh core as a result of the strong binding. Electronic absorption spectroscopy, mass spectrometry and computational analysis are a powerful combination in understanding possible chemical reactions in vivo and this information can be used to synthetically tune dirhodium complexes for use in the fight against cancer.

Stepwise copper(i) binding to metallothionein: a mixed cooperative and non-cooperative mechanism for all 20 copper ions.

Copper is a ubiquitous trace metal of vital importance in that it serves as a cofactor in many metalloenzymes. Excess copper becomes harmful if not sequestered appropriately in the cell. As a metal ion chaperone, metallothionein (MT) has been proposed as a key player in zinc and copper homeostasis within the cell. The underlying mechanisms by which MT sequesters and transfers copper ions, and subsequently achieves its proposed biological function remain unknown. Using a combination of electrospray ionization mass spectrometry (ESI-MS), circular dichroism (CD), and emission spectroscopy, we report that the Cu(i) to human apo-MT1a binding mechanism is highly pH-dependent. The 20 relative Kf-values for the binding of 1 to 20 Cu(i) to the 20 cysteines of MT were obtained from computational simulation of the experimental mass spectral results. These data identified the pH-dependent formation of three sequential but completely different Cu-SCYS clusters, as a function of Cu(i) loading. These data provide the first overall sequence for Cu(i) binding in terms of domain specificity and transient binding site structures. Under cooperative binding at pH 7.4, a series of four clusters form: Cu4SCYS-6, followed by Cu6SCYS-9 (ß), then a second Cu4SCYS-6 (α), and finally Cu7SCYS-x (α) (x = up to 11). Upon further addition of Cu(i), a mixture of species is formed in a non-cooperative mechanism, saturating the 20 cysteines of MT1a. Using benzoquinone, a cysteine modifier, we were able to confirm that Cu6SCYS-9 formed solely in the N-terminal ß-domain, as well as confirming the existence of the presumed Cu4SCYS-6 cluster in the α-domain. Based on the results of ESI-MS and computational simulation we were able to identify Cu:MT speciation that resulted in specific emission and CD spectral properties.

The angiosuppressive effects of 20(R)- ginsenoside Rg3.

Aberrant angiogenesis is an essential step for the progression of solid tumors. Thus anti-angiogenic therapy is one of the most promising approaches to control tumor growth. In this study, we examined the ability of 20(R)-ginsenoside Rg3 (Rg3), one of the active compounds present in ginseng root, to interfere with the various steps of angiogenesis. Rg3 was found to inhibit the proliferation of human umbilical vein endothelial cells (HUVEC) with an IC50 of 10 nM in Trypan blue exclusion assay. Rg3 (1-10(3) nM) also dose dependently suppressed the capillary tube formation of HUVEC on the Matrigel in the presence or absence of 20 ng/ml vascular endothelial growth factor (VEGF). The VEGF-induced chemoinvasion of HUVEC and ex vivo microvascular sprouting in rat aortic ring assay were both significantly attenuated by Rg3. In addition, Rg3 (150 and 600 nM) remarkably abolished the basic fibroblast growth factor (bFGF)-induced angiogenesis in an in vivo Matrigel plug assay. The Matrix metalloproteinases (MMPs), such as MMP-2 and MMP-9, which play an important role in the degradation of basement membrane in angiogenesis and tumor metastasis present in the culture supernatant of Rg3-treated aortic ring culture were found to decrease in their gelatinolytic activities. Taken together, these data underpin the anti-tumor property of Rg3 through its angiosuppressive activity.