Kathy Qian Luo scite author profile

Understanding the survival mechanism of metastatic cancer cells in circulation will provide new perspectives on metastasis prevention and also shed new light on metastasis-derived drug resistance. In this study, we made it feasible to detect apoptosis of circulating tumor cells (CTCs) in real-time by integrating a fluorescence resonance energy transfer (FRET)-based caspase sensor into one in vitro microfluidic circulatory system, and two in vivo models: zebrafish circulation and mouse lung metastatic model. Our study demonstrated that fluid shear stresses triggered apoptosis of breast cancer cells in circulation by elevating the mitochondrial production of the primary free radical, superoxide anion. Cancer cells with high levels of manganese superoxide dismutase (MnSOD) exhibited stronger resistance to shear force-induced apoptosis and formed more lung metastases in mice. These metastasized cells further displayed higher resistance to chemotherapeutic agent doxorubicin, which also generates superoxide in mitochondria. Specific siRNA-mediated MnSOD knockdown reversed all three phenotypes. Our findings therefore suggest that MnSOD plays an important integrative role in supporting cancer cell survival in circulation, metastasis, and doxorubicin resistance. MnSOD can serve as a new biomarker for identifying metastatic CTCs and a novel therapeutic target for inhibiting metastasis and destroying doxorubicin-resistant breast cancer cells.

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Cytophilic Fluorescent Bioprobes for Long‐Term Cell Tracking

Feng

et al. 2011

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Application of the Fluorescence Resonance Energy Transfer Method for Studying the Dynamics of Caspase-3 Activation during UV-Induced Apoptosis in Living HeLa Cells

Luo

et al. 2001

Biochemical and Biophysical Research Communications

162

158

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Quantitation, Visualization, and Monitoring of Conformational Transitions of Human Serum Albumin by a Tetraphenylethene Derivative with Aggregation-Induced Emission Characteristics

et al. 2010

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Human serum albumin (HSA) is a major protein component of blood plasma, and its assay is of obvious value to biological research. We, herein, present a readily accessible fluorescent bioprobe for HSA detection and quantitation. A nonemissive tetraphenylethene derivative named sodium 1,2-bis[4-(3-sulfonatopropoxyl)phenyl]-1,2-diphenylethene (BSPOTPE) is induced to emit by HSA, showing a novel phenomenon of aggregation-induced emission (AIE). The AIE bioprobe enjoys a broad working range (0-100 nM), a low detection limit (down to 1 nM), and a superior selectivity to albumins. The fluorescent bioassay is unperturbed by the miscellaneous bioelectrolytes in the artificial urine. The AIE luminogen can also be used as a rapid and sensitive protein stain in gel electrophoresis for HSA visualization. Utilizing the AIE feature of BSPOTPE and the Forster resonance energy transfer from HSA to BSPOTPE, the unfolding process of HSA induced by guanidine hydrochloride is monitored, which reveals a multistep transition with the involvement of molten globule intermediates. Computational modeling suggests that the AIE luminogens dock in the hydrophobic cleft between subdomains IIA and IIIA of HSA with the aid of hydrophobic effect, charge neutralization, and hydrogen bonding interactions, offering mechanistic insight into the microenvironment inside the hydrophobic cavity.

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High Shear Stresses under Exercise Condition Destroy Circulating Tumor Cells in a Microfluidic System

Regmi

Luo

2017

Sci Rep

156

147

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Circulating tumor cells (CTCs) are the primary targets of cancer treatment as they cause distal metastasis. However, how CTCs response to exercise-induced high shear stress is largely unknown. To study the effects of hemodynamic microenvironment on CTCs, we designed a microfluidic circulatory system that produces exercise relevant shear stresses. We explore the effects of shear stresses on breast cancer cells with different metastatic abilities, cancer cells of ovarian, lung and leukemic origin. Three major findings were obtained. 1) High shear stress of 60 dynes/cm2 achievable during intensive exercise killed more CTCs than low shear stress of 15 dynes/cm2 present in human arteries at the resting state. 2) High shear stress caused necrosis in over 90% of CTCs within the first 4 h of circulation. More importantly, the CTCs that survived the first 4 h-circulation, underwent apoptosis during 16–24 h of post-circulation incubation. 3) Prolonged high shear stress treatment effectively reduced the viability of highly metastatic and drug resistant breast cancer cells. As high shear stress had much less damaging effects on leukemic cells mimicking the white blood cells, we propose that intensive exercise may be a good strategy for generating high shear stress that can destroy CTCs and prevent cancer metastasis.

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Degradation of Cyclin B Is Required for the Onset of Anaphase in Mammalian Cells

Chang

Luo

2003

Journal of Biological Chemistry

131

108

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Recently, it has been shown that cyclin B1 was degraded mainly before the onset of anaphase in mammalian cells. When a nondegradable form of cyclin B1 was introduced into cells, the metaphase-anaphase transition was blocked. This blockage was not due to a failure in activating anaphase-promoting complex, nor was it due to a failure of degradation of securin. To resolve the question of whether this blockage by overexpressing the nondegradable form of cyclin B1 is physiologically relevant or not, we developed a novel method to estimate the relative protein level of the overexpressed cyclin B1 mutant within an individual cell. We found that a low level of nondegradable cyclin B1 (less than 30% of the endogenous cyclin B1) was sufficient to block the metaphase-anaphase transition, implying that the blockage of anaphase onset by the nondegradable cyclin B1 was not due to an artifact of excessive M-phase-promoting factor activity. This result suggests that, in mammalian cells, the majority of cyclin B1 must be destroyed before the cell can enter anaphase.It is well known that cyclin B must be degraded to inactivate M-phase-promoting factor (MPF) 1 to exit mitosis (1-8). Yet is inactivation of MPF required for the metaphase to anaphase (M/A) transition? There have been many conflicting reports on this topic (1,(7)(8)(9)(10)(11)(12)(13)(14)(15)(16)(17)(18)(19). Up until recently, the majority view was that inactivation of MPF is not required for the onset of anaphase (20, 21). For example, it was demonstrated in an in vitro study using Xenopus egg extracts that the degradation of cyclin B (and thus the inactivation of MPF) was not required for the separation of sister chromatids (9). A similar conclusion was reached in the in vivo study of budding yeast, which reported that the destruction of MPF activity is not required for the M/A transition (10). Recently, Stemmann et al. (15) extended the in vitro study of Holloway et al. (9) and found that when a high concentration of nondestructable cyclin B was added to the Xenopus extract, sister chromatid separation could be blocked. They attributed this blockage to an inhibitory phosphorylation of separase that might be caused by high kinase activity of MPF. Their findings now raise a very important question: In an in vivo metazoan system, is cyclin B required to be degraded before the onset of anaphase?It is possible that the answer may depend on the cell model. In this study, we try to answer this question in mammalian cells using a living cell imaging technique. To measure the dynamic change of the cyclin B level within a single living cell, we fused the wild type and nondestructible form of cyclin B1 (which is the major form of mitotic cyclin in mammalian cells) with fluorescence proteins such as green fluorescent protein (GFP) and DsRed (22-24). The protein stability of cyclin was then correlated with several key cellular events, including sister chromatid separation and the degradation of securin. To ensure the general applicability of our results, we used both trans...

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The gene-silencing efficiency of siRNA is strongly dependent on the local structure of mRNA at the targeted region

Luo

Chang

2004

Biochemical and Biophysical Research Communications

163

104

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The gene-silencing effect of short interfering RNA (siRNA) is known to vary strongly with the targeted position of the mRNA. A number of hypotheses have been suggested to explain this phenomenon. We would like to test if this positional effect is mainly due to the secondary structure of the mRNA at the target site. We proposed that this structural factor can be characterized by a single parameter called "the hydrogen bond (H-b) index," which represents the average number of hydrogen bonds formed between nucleotides in the target region and the rest of the mRNA. This index can be determined using a computational approach. We tested the correlation between the H-b index and the gene-silencing effects on three genes (Bcl-2, hTF, and cyclin B1) using a variety of siRNAs. We found that the gene-silencing effect is inversely dependent on the H-b index, indicating that the local mRNA structure at the targeted site is the main cause of the positional effect. Based on this finding, we suggest that the H-b index can be a useful guideline for future siRNA design.

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Kathy Qian Luo

Glowing Graphene Quantum Dots and Carbon Dots: Properties, Syntheses, and Biological Applications

High expression of MnSOD promotes survival of circulating breast cancer cells and increases their resistance to doxorubicin

Cytophilic Fluorescent Bioprobes for Long‐Term Cell Tracking

Application of the Fluorescence Resonance Energy Transfer Method for Studying the Dynamics of Caspase-3 Activation during UV-Induced Apoptosis in Living HeLa Cells

Quantitation, Visualization, and Monitoring of Conformational Transitions of Human Serum Albumin by a Tetraphenylethene Derivative with Aggregation-Induced Emission Characteristics

High Shear Stresses under Exercise Condition Destroy Circulating Tumor Cells in a Microfluidic System

Degradation of Cyclin B Is Required for the Onset of Anaphase in Mammalian Cells

The gene-silencing efficiency of siRNA is strongly dependent on the local structure of mRNA at the targeted region

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