ABSTRACT
Background: Cancer is the second leading cause of death globally and ∼39.5% of people will be diagnosed with cancer at some point during their lifetimes. Thus, there is an unmet need to identify novel strategies for early cancer detection and prevention. The emerging evidence suggests that the gut microbiome has a role in promoting cancer. This microbiome including bacteria plays a vital role in maintaining homeostasis in the body. An imbalance in bacterial composition may cause diseases including cancer. Here we developed a microfluidic chip that can accurately simulate the gut microbiome to test the effects of bacteria and therapies on cancer cells. Methods and Results: To test the causal effect of bacteria on cancer, we developed a new highthroughput microfluidic device for simulating the environment of the gut. Initially, we used the photolithography technique where we designed the chip in AutoCAD and fabricated using photoresist resins and Polydimethylsiloxane (PDMS). Next, we tested the effect of bacteria on the growth of colorectal cancer cells. For this, we cultured colorectal cancer cells (HCT-116) with lipopolysaccharide (LPS), which is found in the outer membrane of bacteria, as well as the Bacillus bacteria in our microfluidics. Our data show that both LPS and Bacillus significantly accelerate the growth of cancer cells 2.02 times (p value = 0.012) and 1.58 times (p value = 0.011), respectively, over a 4 day culture period. These results show that the increased presence of certain bacteria can promote cancer cell growth and that our chip can be used to test the specific correlation between bacteria and cancer cell growth. The previously described method was inefficient and time-consuming. To overcome this limitation, we designed a new chip that allows running 16 samples at once with improved efficiency and accuracy. The template of the device that had 16 microfluidic channels was printed by a 3D printer and used for PDMS replica molding. The PDMS device was attached to the modified multiwell plate to feed media to and collect waste from each channel in a high-throughput manner. In the initial design, the bacteria grew faster than cancer cells taking over the chips. Our new design has dual layered chambers to keep bacteria and cancer cells separated by a membrane, allowing only bacterial secretions to pass through the membrane to cancer cells, mimicking the human gut. The new design also allowed the chip to maintain continuous microfluidic flow and a hypoxic environment. Conclusion: Our research demonstrates that the new microfluidic device has broader implications including simulating other body organs such as the lung and liver, and testing the impact of viruses such as influenza and COVID-19 on human cells. This device can be used to test both the effect of bacteria and new treatment on clinical samples for the identification of personalized therapy, thus reducing the need for mouse model testing, which is a lengthy and expensive process.
ABSTRACT
Angiotensin converting enzyme II (ACE2) is the cellular receptor of SARS-CoV-2. At present, ACE2 receptor is considered to be the key component in the SARS-CoV-2 infection and transmitting in the host. Among the cancer patients with COVID-19, the gastrointestinal cancer is the second most prevalent. The MethyLight and QASM assays were used to evaluated the genomic DNA 5mC methylation, while the CviAII enzyme-based 6mA-RE-qPCR was applied to determine motif-specific DNA 6mA methylation. The 6mA and 5mC methylation analyses of the long interspersed nuclear elements 1 (LINE1) were used to evaluate the global level of genomic 6mA and 5mC methylations, respectively. To investigate the role of ACE2 DNA methylation in regulating ACE2 expression, we performed a genome-wide methylation analysis in colorectal cancer samples collected at the Sixth Affiliated Hospital of Sun Yat-sen University. The DNA 5mC methylation of ACE2 promoter in tumor tissues were significantly lower than that in normal tissues, while the DNA 6mA methylation of ACE2 promoter in tumor tissues was significantly higher than that in normal tissues. In addition, the mRNA and protein expression of ACE2 in tumor tissues were lower than that in normal tissues. To explore the epigenetic regulation on ACE2 expression, we treated colon cancer cell lines with 5-Azacytidine and found ACE2 expression was upregulated after lowering the DNA 5mC methylation. The correlation analysis in patient cohort samples showed that ACE2 mRNA expression was positively correlated with DNA 5mC and negatively associated with DNA 6mA methylation. Next, a novel CRISPR-based tool was developed for sequence-specific 6mA editing on ACE2 promoter region, and it was applied in HCT116 cell to further confirm the regulatory role of DNA 6mA methylation in ACE2 mRNA expression. This tool was proved to be reliable with our findings that the CRISPR/dCas9-METTL3 tool could dramatically upregulate DNA 6mA methylation in ACE2 promoter, while the global level of genomic 6mA methylation remained unchanged. Both the mRNA and protein expression of ACE2 were significantly increased following a sequence-specific DNA 6mA editing in ACE2 promoter. In conclusion, we revealed the aberrant DNA 5mC and 6mA methylations in colorectal cancer, which upregulate ACE2 expression in colorectal cancer cells that may confer the susceptibility to SARS-CoV-2 infection. We developed a novel CRISPR-based tool that could realize site-directed 6mA methylation editing. Notably, the epigenetic regulation of DNA 6mA methylation on ACE2 expression provides an insight into the intersection of the biology of cancer, SARS-CoV-2 infection and organ-specific complication in COVID-19. Aberrant ACE2 methylation may serve as a biomarker and treatment target in these patients.