Project description:Nanobody is one special type of single-domain antibody fragment with multiple advantages over traditional antibody. Our previous work established linear-double-stranded DNA (ldsDNA, or PCR amplicon) as novel biological parts for building AND gate genetic circuits in mammalian cells. During this AND-gate circuit formation process, the co-transfected up- and down-stream ldsDNAs could be linked together to form intact gene expression cassette. Here, we employed this ldsDNA-based AND-gate (LBAG) strategy to construct nanobody library in mammalian cells. The sequence complexity of complementary determining regions (CDRs) was introduced into ldsDNA by PCR amplification. After being co-transfected into mammalian cells, the up- and down- stream ldsDNAs undergo AND gate linkage and form full nanobody coding regions, containing CDR1-3. High throughput sequencing identified 22,173 unique oligonucleotide sequences in total generated by this strategy. Thus, we developed a novel method to construct nanobody library, which is a start point for building high content nanobody library in mammalian cells.

Project description:Generation of highly diverse peptide library by linear-double-stranded DNA based AND gate genetic circuit in mammalian cells

Project description:Generation of highly diverse peptide library by linear-double-stranded DNA based AND gate genetic circuit in mammalian cells

Project description:When in the closed form, the axial substrate translocation channel of the proteasome core particle (CP) is topologically blocked by the convergent N-termini of subunits. To probe the role of channel gating in mammalian proteasomes, we have deleted the N-terminal tail of 3. The resulting 3N proteasomes are intact but hyperactive in the hydrolysis of fluorogenic peptide substrates and degradation of polyubiquitinated Sic1. Cells expressing the hyperactive proteasomes show markedly elevated degradation of established proteasome substrates and resistance to oxidative stress, and multiplexed quantitative proteomics reveal ~ 200 proteins with reduced levels in the mutant cells. Potentially toxic proteins such as tau exhibit reduced accumulation and aggregate formation. These data demonstrate that the CP gate is a key negative regulator of proteasome function in mammals, and that opening the CP gate may be an effective strategy to increase proteasome activity and reduce levels of toxic proteins in cells.

Project description:Construction of Nanobody Library in Mammalian Cells by Linear-double-stranded DNA Based AND Gate Genetic Circuit

Project description:Sequence data from Neolithic (7,700BP) hunter-gatherer samples from Devil's Gate, East Asia.

Project description:TCGA Analysis of DNA Methylation for GBM Using Illumina Golden Gate BeadArray platform

Project description:TCGA Analysis of DNA Methylation for GBM Using Illumina Golden Gate BeadArray platform

Project description:A nanobody is an antibody fragment consisting of a single monomeric variable antigen-binding domain. Mammalian cells are ideal platforms for identifying nanobodies targeting hard-to-display transmembrane proteins and nanobodies that function as modulators of cellular phenotypes. However, the introduction of a high-diversity nanobody library into mammalian cells is challenging. We have developed two novel methods for constructing a nanobody library in mammalian cells. Complementarity-determining region (CDR) random sequences were first incorporated into upstream and downstream dsDNAs by PCR. In the first method, named dsDNA-HR, upstream and downstream dsDNAs containing an identical overlapping sequence were co-transfected into cultured mammalian cells for intracellular homologous recombination that resulted in the formation of an intact nanobody library expression cassette. In the second method, named in vitro ligation, we generated full-length nanobody expression dsDNAs via ligation of restriction digested upstream and downstream dsDNAs. The obtained full-length dsDNAs were transfected into mammalian cells for nanobody library expression. Using both methods, we generated over a million unique nanobody sequences, as revealed by high-throughput sequencing. Single-cell sequencing was employed to resolve the diversity of the dsDNA-HR nanobody library. We also identified a small molecule, Nocodazole, which could enhance the efficacy of dsDNA-HR.

Project description:The hepatocyte growth factor (HGF)/c-Met signaling pathway is known to mediate vascularization. We have previously demonstrated that expression of a human HGF transgene in the small airways produced mice (HGF TG) that were more susceptible to the tobacco carcinogen, 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK). We also have observed that HGF TG mice display significantly enhanced vascularization in the lungs that increases over time compared to wild-type (WT) littermates. To analyze which genes might contribute to increased vascularization from HGF overexpression in the airways, RNA and protein were isolated from whole lungs of individual HGF TG and WT adult mice. We profiled the mRNA expression of several hundred genes representative of six biological pathways involved in transformation, angiogenesis, and tumorigenesis using two commercial microarrays. Significant changes in expression over a 1.5-fold boundary were also observed in lung tumors derived from NNK-treated HGF TG mice. Lung tumors were induced by exposing mice to four weekly i.p. injections of 3mg NNK (15μg/μl) over 2 weeks. Whole lungs from control untreated animals were dissected after sacrifice at 10, 20, or 40 wks of age, and NNK induced lung tumors were dissected from the animals at 20 or 40 weeks of age. Total RNA was extracted from whole lung or isolated tumors from HGF TG or WT mice using TRIzol reagent and the Array Grade Total RNA Isolation Kit. The cDNA was generated and labeled using the TrueLabeling-AMP Linear RNA Amplication Kit. RNA was analyzed from 28 mice in total. The angiogenesis array was used to analyze 10 samples taken from 40 week old mice (HGF TG untreated [n=4], WT untreated [n=4], HGF TG NNK treated [n=1], WT NNK treated [n=1]) and 6 samples from 20 week old mice (HGF TG untreated [n=2], WT untreated [n=2], HGF TG NNK treated [n=1], WT NNK treated [n=1]). The cancer gene array was used to analyze 8 samples taken from 40 week old mice (HGF TG untreated [n=2], WT untreated [n=2], HGF TG NNK treated [n=2], WT NNK treated [n=2]) and 4 samples from 20 week old mice (HGF TG untreated [n=2], WT untreated [n=2]).