Characterization of recombinant photoconverting green fluorescent Akanes.

Akanes are fluorescent proteins that have several fluorescence maxima. In this report, Akane1 and Akane3 from Scleronephthya gracillima were selected, successfully overexpressed in Escherichia coli and purified by affinity chromatography. Fluorescence spectra of the recombinant Akanes matured in darkness, or ambient light were found to have several fluorescence peaks. SDS-PAGE analysis revealed that Akanes matured in ambient light have two fragments. MS/MS analysis of Akanes digested with trypsin showed that the cleavage site is the same as observed for the photoconvertible fluorescent protein Kaede. The differences between the calculated masses from the amino acid sequence of Akane1 and the measured masses of Akane1 fragments obtained under ambient light coincided with those of Kaede. In contrast, a mass difference between the measured N-terminal Akane3 fragment and the calculated mass indicated that Akane3 is modified in the N-terminal region. These results indicate that numerous peaks in the fluorescent spectra of Akanes partly arise from isoproteins of Akanes and photoconversion. Photoconversion of Akane1 caused a fluorescence change from green to red, which was also observed for Akane3; however, the fluorescent intensity decreased dramatically when compared with that of Akane3.

Multiplexed site-specific genome engineering in Mycolicibacterium neoaurum by Att/Int system.

Genomic integration of genes and pathway-sized DNA cassettes is often an indispensable way to construct robust and productive microbial cell factories. For some uncommon microbial hosts, such as Mycolicibacterium and Mycobacterium species, however, it is a challenge. Here, we present a multiplexed integrase-assisted site-specific recombination (miSSR) method to precisely and iteratively integrate genes/pathways with controllable copies in the chromosomes of Mycolicibacteria for the purpose of developing cell factories. First, a single-step multi-copy integration method was established in M. neoaurum by a combination application of mycobacteriophage L5 integrase and two-step allelic exchange strategy, the efficiencies of which were ∼100% for no more than three-copy integration events and decreased sharply to ∼20% for five-copy integration events. Second, the R4, Bxb1 and ΦC31 bacteriophage Att/Int systems were selected to extend the available integration toolbox for multiplexed gene integration events. Third, a reconstructed mycolicibacterial Xer recombinases (Xer-cise) system was employed to recycle the selection marker of gene recombination to facilitate the iterative gene manipulation. As a proof of concept, the biosynthetic pathway of ergothioneine (EGT) in Mycolicibacterium neoaurum ATCC 25795 was achieved by remodeling its metabolic pathway with a miSSR system. With six copies of the biosynthetic gene clusters (BGCs) of EGT and pentose phosphate isomerase (PRT), the titer of EGT in the resulting strain in a 30 mL shake flask within 5 days was enhanced to 66 mg/L, which was 3.77 times of that in the wild strain. The improvements indicated that the miSSR system was an effective, flexible, and convenient tool to engineer the genomes of Mycolicibacteria as well as other strains in the Mycobacteriaceae due to their proximate evolutionary relationships.

mRNA Delivery by a pH-Responsive DNA Nano-Hydrogel.

The delivery of mRNA to manipulate protein expression has attracted widespread attention, since that mRNA overcomes the problem of infection and mutation risks in transgenes and can work as drugs for the treatment of diseases. Although there are currently some vehicles that deliver mRNA into cells, they have not yet reached a good balance in terms of expression efficiency and biocompatibility. Here, a DNA nano-hydrogel system for mRNA delivery is developed. The nano-hydrogel is all composed of DNA except the target mRNA, so it has superior biocompatibility compared with those chemical vehicles. In parallel, the nano-hydrogel can be compacted into a nanosphere under the crosslinking by well-designed "X"-shaped DNA scaffolds and DNA linkers, facilitating the delivery into cells through endocytosis. In addition, smart intracellular release of the mRNA is achieved by incorporating a pH-responsive i-motif structure into the nano-hydrogel. Thus, taking the efficient delivery and release together, mRNA can be translated into the corresponding protein with a high efficiency, which is comparable to that of the commercial liposome but with a much better biocompatibility. Due to the excellent biocompatibility and efficiency, this nano-hydrogel system is expected to become a competitive alternative for delivering functional mRNA in vivo.

Evidence for expression of promoterless GFP cassette: Is GFP an ideal reporter gene in biotechnology science?

Green fluorescent protein (GFP) has played an important role in biochemistry and cell biology as a reporter gene. It has been used to assess the potency of promoters for recombinant protein production. This investigation reveals evidences suggesting that the gfp GFP gene (EGFP) could be expressed without the promoter. In a study, a pLenti-F/GFP vector was constructed with the purpose to allow GFP expression in transduced cells but not in packaging cells; however, after transfecting the HEK293T cell line, GFP gene was expressed, compared to pLOX/CWgfp-transfected cells showed expression lag, lower levels and reduced percentage of GFP expression in the cells. This unexpected result could be due to auto transduction in packaging cell, possible retrotransposon activity in the cell line, possible contamination of pLenti-F/GFP with the pLOX/CWgfp and possible presence of a promoter within backbone of the vector. All the possibilities were ruled out. To exclude the possibility that a sequence within the region might act as a promoter, the fragment to be transfected was minimized to a region containing "from the start of the GFP gene to 5'LTR R". The GFP gene was again expressed. Therefore, our findings suggest the EGFP does not need promoter for expression. This should appeal to the researchers designing GFP based assays to evaluate the potency of promoters, since possible aberrant expression may have a potential to influence on the results of a planned experiment.

Live-Cell Imaging of Fluorescently Tagged Phloem Proteins with Confocal Microscopy.

Confocal laser scanning microscopy can enable observation of phloem cells in living tissues. Here we describe live imaging of phloem cells in the leaves and roots of Arabidopsis thaliana using fluorescently tagged proteins, either expressed in the vasculature using phloem specific promoters or constitutively expressed reference marker lines. Now, the majority of phloem cell types can be identified, allowing a precise cellular and subcellular localization of phloem proteins.

Enhancing Stability of Destabilized Green Fluorescent Protein Using Chimeric mRNA Containing Human Beta-Globin 5' and 3' Untranslated Regions.

BACKGROUND: In spite of recent progress in mRNA technologies and their potential applications for treatment of human diseases, problems such as the transient nature of mRNA limit the stability of gene up-regulation and, thus, potentially reduce mRNA efficiency for gene therapy. Using human ß-globin 5' and 3' untranslated regions (UTRs), this study aimed to develop the different chimeric constructs of mRNAs to increase the stability of destabilized green fluorescent protein (EGFPd2) in HEK 293 cells. METHODS: Purified human ß-globin (HBG) 5'-3'UTRs, and the coding sequence of destabilized green fluorescent protein (EGFPd2) were amplified separately and ligated to each other using SOEing PCR method in a different format. As controls, the original construct of EGFPd2 under the control of T7 promoter was used. Following in vitro transcription, HEK 293 cells were then transfected with several constructs and incubated at 37°C in a CO2 incubator. They were monitored under a fluorescence microscope every four hours for the first 24 hr, then every 12 hr afterwards. The resulting fluorescence was measured as a surrogate for translation efficiency and duration. RESULTS: By monitoring the HEK cells over 48 hr, cells transfected with mRNA with various HBG UTRs showed significantly different fluorescence intensity and stability in comparison with the pEGFPd2 prototype (control transcript) overtime. Overall, the images show that replacement of the 3' UTR end of the prototype vector pGFPd2 with the 3' end of ß-globin mRNA increases the half-life of the chimeric mRNA for more than 32 hr. CONCLUSION: This result indicates that ß-globin 3' UTR would definitely increase the half-life of mRNA and may help to decrease the mRNA therapeutic dosage in the treatment of diseases associated with mRNA therapy.

Protein Biophotosensitizer-Based IGZO Photo-thin Film Transistors for Monitoring Harmful Ultraviolet Light.

The development of health monitoring devices to prevent skin cancers or various diseases arising from exposure to harmful light has attracted increasing scientific interest and has led to the exploration of hybrid inorganic-biological systems through the incorporation of biomolecules. Here, ultraviolet (UV) photodetectors based on transistors incorporating green fluorescent protein (GFP) molecules on multilayer-stacked indium-gallium-zinc-oxide (IGZO) thin films are studied, where the top layer of the IGZO films has different surface properties. Light-sensitive GFP can play a role as a biophotosensitizer due to light-induced electron transfer during photoexcitation. Intriguingly, the IGZO photo-thin film transistors (TFTs) with GFP molecules on a relatively more hydrophilic surface (less defective surface) have better device performance and exhibit a dramatic decrease in the photocurrent after turning the UV light off compared to the cases without GFP molecules on the more hydrophilic surface and on the less hydrophilic surface (more defective surface). A physical mechanism based on energy band diagrams is proposed, and the light-induced threshold voltage shift in the IGZO photo-TFTs is estimated and explained in terms of oxygen-related vacancy sites and trap/interface conditions in the IGZO film and light-induced electron transfer from the GFP molecules.

Construction and transcriptional activity of human CREG promoter reporter gene plasmid / 解放军医学杂志

Objective To construct the promoter enhanced green fluorescent protein (pEGFP1) reporter gene vector of different truncated fragments of human cellular repressor of E1A-stimulated genes (hCREG), and compare the transcriptional activity of each promoter to determine the hCREG core promoter region. Methods The promoter fragment with length of 2003 (–1925/+78) bp was obtained by querying the hCREG sequence from US National Center of Biotechnology Information (NCBI) database and combining with the characteristics of the promoter. Five promoter fragments were truncated by PCR and double enzyme digestion and cloned into pEGFP1 to construct pEGFP1_hCREG_2003, pEGFP1_hCREG_945, pEGF P1_hCREG_586, pEGFP1_ hCREG_478 and pEG FP1_hCREG_358 reporter gene vector plasmid. The 293T cells were transiently co-transfected with the internal reference plasmid pGL4.73 [hRluc/SV40] for 48 hours. The green fluorescence expression of pEGFP1_hCREG promoter reporter gene was observed under fluorescence microscope, and the mRNA expression of each promoter was detected by real-time quantitative PCR, and the core promoter region was determined. Bioinformatics was used to predict the transcription factors that might bind to the core promoter region. Results Five hCREG promoter reporter gene vectors were successfully constructed by double enzyme digestion and gene sequencing. The results showed that the transcription activity of pEGFP1_ hCREG_586 was the highest (P0.05), implying that –867/ –509 bp is a negative regulatory region, and there existed enhancer sequences in –400/–281 bp and –508/–401 bp, so the core promoter region of hCREG gene is located in the upstream sequence of –508/–281 bp. Bioinformatics predicted that the possibly bound transcription factors in key promoter region –508/–281 bp were Pax5/P53, C/EBPβ, GR-β, GATA-1, GR-α, c-Jun, PRB/ PRA, YY1, RXR-α, AP-2, FOXP3, GR, TFIID, STAT4 and c-Ets-1. Conclusion The recombinant plasmid of hCREG gene promoter has been successfully constructed, the core promoter of which is located in –508/–281 bp, where several transcription factors might be bound.

Localization of PQ-LRP protein in Microsporum canis / 中华皮肤科杂志

Objective To determine the location of PQ-LRP protein in Microsporum canis using the enhanced green fluorescent protein(EGFP)as a marker.Methods The total RNA was extracted from Microsporum canis,and reversely transcribed into cDNA.The PQ-LRP gene was amplified by PCR using the above cDNA as the template.The fusion gene of PQ-LRP gene and EGFP gene was linked to the plasmid pCAMBIA 1300.Microsporum canis was subjected to Agrobacterium tumefaciens-mediated transformation,in order to achieve the integrated expression of the fusion gene LRP-EGFP in Microsporum canis under the regulation by the fungal universal promoter Ptrpc and terminator Ttrpc.Laser-scanning confocal microscopy was conducted to determine the cellular localization of the fusion protein.Results The expression vector pCAMBIA-LRP-EGFP was successfully constructed,and the fusion gene LRP-EGFP was expressed integratedly in Microsporum canis.Laser-scanning confocal microscopy showed that fluorescence signals of LRP-EGFP were concentrated on the cell membrane of Microsporum canis,giving a granular or cluster-like appearance.Conclusion The infusion gene LRP-EGFP can be successfully expressed in Microsporum canis,and PQ-LRP protein is located on the cell membrane of Microsporum canis.

Green fluorescent proteins engineered for cartilage-targeted drug delivery: Insights for transport into highly charged avascular tissues.

Osteoarthritis (OA), the most common form of arthritis, is a multi-factorial disease that primarily affects cartilage as well as other joint tissues such as subchondral bone. The lack of effective drug delivery, due to the avascular nature of cartilage and the rapid clearance of intra-articularly delivered drugs via the synovium, remains a major challenge in the development of disease modifying drugs for OA. Cationic delivery carriers can significantly enhance the uptake, penetration and retention of drugs in cartilage by interacting with negatively charged matrix proteoglycans. In this study, we used "supercharged" green fluorescent proteins (GFPs), engineered to have a wide range of net positive charge and surface charge distributions, to characterize the effects of carrier charge on transport into cartilage in isolation of other factors such as carrier size and shape. We quantified the uptake, extent of cartilage penetration and cellular uptake of the GFP variants into living human knee cartilage and bovine cartilage explants. Based on these results, we identified optimal net charges of GFP carriers for potential drug targets located within cartilage extracellular matrix as well as the resident live chondrocytes. These cationic GFPs did not have adverse effects on cartilage in terms of measured cell viability and metabolism, cartilage cell biosynthesis and matrix degradation at doses needed for drug delivery. In addition to quantifying the kinetics of GFP uptake, we developed a predictive mathematical model for transport of the GFP variants that exhibited the highest uptake and penetration into cartilage. This model was further used to predict the transport behavior of GFPs during scale-up to in vivo applications such as intra-articular injection into human knees. The insights gained from this study set the stage for development of cartilage-targeted delivery systems to prevent cartilage degeneration, improve tissue regeneration and reduce inflammation that may cause degradation of other joint tissues affected by OA.

The role of fetal-maternal microchimerism as a natural-born healer in integrity improvement of maternal damaged kidney

ABSTRACT Purpose: To identify the fetal stem cell (FSC) response to maternal renal injury with emphasis on renal integrity improvement and Y chromosome detection in damaged maternal kidney. Materials and Methods: Eight non-green fluorescent protein (GFP) transgenic Sprague-Dawley rats were mated with GFP-positive transgenic male rats. Renal damage was induced on the right kidney at gestational day 11. The same procedure was performed in eight non-pregnant rats as control group. Three months after delivery, right ne- phrectomy was performed in order to evaluate the injured kidney. The fresh perfused kidneys were stained with anti-GFP antibody. Polymerase chain reaction (PCR) assay was also performed for the Y chromosome detection. Cell culture was performed to detect the GFP-positive cells. Technetium-99m-DMSA renal scan and single-photon emission computed tomography (SPECT) were performed after renal damage induction and 3 months later to evaluate the improvement of renal integrity. Results: The presence of FSCs was confirmed by immune histochemical staining as well as immunofluorescent imaging of the damaged part. Gradient PCR of female rat purified DNA demonstrated the presence of Y-chromosome in the damaged maternal kidney. Moreover, the culture of kidney cells showed GPF- positive cells by immuno- fluorescence microscopy. The acute renal scar was repaired and the integrity of dam- aged kidney reached to near normal levels in experimental group as shown in DMSA scan. However, no significant improvement was observed in control group. Conclusion: FSC seems to be the main mechanism in repairing of the maternal renal injury during pregnancy as indicated by Y chromosome and GFP-positive cells in the sub-cultured medium.

The role of fetal-maternal microchimerism as a natural-born healer in integrity improvement of maternal damaged kidney.

PURPOSE: To identify the fetal stem cell (FSC) response to maternal renal injury with emphasis on renal integrity improvement and Y chromosome detection in damaged maternal kidney. MATERIALS AND METHODS: Eight non-green fluorescent protein (GFP) transgenic Sprague- Dawley rats were mated with GFP-positive transgenic male rats. Renal damage was induced on the right kidney at gestational day 11. The same procedure was performed in eight non-pregnant rats as control group. Three months after delivery, right nephrectomy was performed in order to evaluate the injured kidney. The fresh perfused kidneys were stained with anti-GFP antibody. Polymerase chain reaction (PCR) assay was also performed for the Y chromosome detection. Cell culture was performed to detect the GFP-positive cells. Technetium-99m-DMSA renal scan and single-photon emission computed tomography (SPECT) were performed after renal damage induction and 3 months later to evaluate the improvement of renal integrity. RESULTS: The presence of FSCs was confirmed by immune histochemical staining as well as immunofluorescent imaging of the damaged part. Gradient PCR of female rat purified DNA demonstrated the presence of Y-chromosome in the damaged maternal kidney. Moreover, the culture of kidney cells showed GPF- positive cells by immunofluorescence microscopy. The acute renal scar was repaired and the integrity of damaged kidney reached to near normal levels in experimental group as shown in DMSA scan. However, no significant improvement was observed in control group. CONCLUSION: FSC seems to be the main mechanism in repairing of the maternal renal injury during pregnancy as indicated by Y chromosome and GFP-positive cells in the sub-cultured medium.

Quantitative analysis of autophagy in green fluorescent protein-light chain 3 transgenic murine keratinocytes / 中华皮肤科杂志

Objective To explore a high-throughput method for quantitative analysis of autophagosomes.Methods Green fluorescent protein-light chain 3(GFP-LC3)transgenic murine keratinocytes were randomly divided into 4 groups:control group receiving no treatment,starvation group subjected to starved culture,20 J/cm2 ultraviolet A (UVA) group treated with 20 J/cm2 UVA radiation,and 40 J/cm2 UVA group treated with 40 J/cm2 UVA radiation.After 6-hour treatment,the cells were fixed,and images were acquired by confocal laser scanning microscopy.A macro was created by the ImageJ software to automatically quantify the GFP-LC3 puncta in the cells and the number of cells.Then,the level of autophagy was compared among different groups.Results By using the macro created by the ImageJ software,autophago-somes in the keratinocytes were successfully identified and quantified.Less than 0.6 second was needed for analyzing an image of 4.2 mega pixels in a test computer.The average number of autophagosomes in keratinocytes was significantly higher in the starvation group,20-J/cm2 UVA group and 40-J/cm2 UVA group than in the control group whether with the treatment with pepstatin A (F =20.05,P ＜0.05) or not (F =5.01,P ＜ 0.05).This method could successfully differentiate the autophagy levels among the starvation group,UVA irradiation groups and control group.Conclusion A new high-throughput method,which can rapidly and accurately quantify GFP-LC3 puncta in cells,is established successfully to quantificationally detect autophagy.

Different riboswitches on regulatory efficiency of downstream target genes: a comparative study / 军事医学

Objective To compare the regulation effects of different activated and inhibitory riboswitches , and to facilitate the precise regulation of gene circuits .Methods A green fluorescent protein amcyan expression vector regulated by different riboswitches (addA, M6, TPP and btuB) was constructed, and the expression level of amcyan under different ligand concentrations was analyzed by RT-qPCR and relative fluorescence intensity , and then compared with the expression level of a vector without any riboswitch .The dynamic control performance was analyzed .Results Under the control of addA and M6 activated riboswitches , the expression of green fluorescent protein increased with ligand concentrations , and addA riboswitch had more dynamic regulatory effect than M 6 riboswitch.However, under the control of TPP and btuB inhibitory riboswitches , the expression of green fluorescence decreased with the increase in ligand concentrations , and the dynamic regulation of btuB riboswitch was slightly greater than that of TPP riboswitch .Conclusion The regulation efficacy of different riboswitches which have the same mechanism varies .Activated riboswitch addA and inhibitory riboswitch btuB with dynamic regulation and control advantages are more suitable for precise metabolism regulation and target gene expression in Escherichia coli.

Acclimatization of symbiotic corals to mesophotic light environments through wavelength transformation by fluorescent protein pigments.

The depth distribution of reef-building corals exposes their photosynthetic symbionts of the genus Symbiodinium to extreme gradients in the intensity and spectral quality of the ambient light environment. Characterizing the mechanisms used by the coral holobiont to respond to the low intensity and reduced spectral composition of the light environment in deeper reefs (greater than 20 m) is fundamental to our understanding of the functioning and structure of reefs across depth gradients. Here, we demonstrate that host pigments, specifically photoconvertible red fluorescent proteins (pcRFPs), can promote coral adaptation/acclimatization to deeper-water light environments by transforming the prevalent blue light into orange-red light, which can penetrate deeper within zooxanthellae-containing tissues; this facilitates a more homogeneous distribution of photons across symbiont communities. The ecological importance of pcRFPs in deeper reefs is supported by the increasing proportion of red fluorescent corals with depth (measured down to 45 m) and increased survival of colour morphs with strong expression of pcRFPs in long-term light manipulation experiments. In addition to screening by host pigments from high light intensities in shallow water, the spectral transformation observed in deeper-water corals highlights the importance of GFP-like protein expression as an ecological mechanism to support the functioning of the coral-Symbiodinium association across steep environmental gradients.

Improved Tracking and Resolution of Bacteria in Holographic Microscopy Using Dye and Fluorescent Protein Labeling.

Digital holographic microscopy (DHM) is an emerging imaging technique that permits instantaneous capture of a relatively large sample volume. However, large volumes usually come at the expense of lower spatial resolution, and the technique has rarely been used with prokaryotic cells due to their small size and low contrast. In this paper we demonstrate the use of a Mach-Zehnder dual-beam instrument for imaging of labeled and unlabeled bacteria and microalgae. Spatial resolution of 0.3 µm is achieved, providing a sampling of several pixels across a typical prokaryotic cell. Both cellular motility and morphology are readily recorded. The use of dyes provides both amplitude and phase contrast improvement and is of use to identify cells in dense samples.

Chemically Engineered Nanoparticle-Protein Interface for Real-Time Cellular Oxidative Stress Monitoring.

A co-engineered nanoparticle/protein peroxide detector is created. This system features a gold nanoparticle functionalized with a galactose headgroup (AuNP-Gal) that reacts covalently with a boronate-modified green fluorescent protein (PB-GFP). Boronate acid-saccharide complexation between PB-GFP and AuNP-Gal affords a highly stable assembly. This complex is disrupted by peroxide, allowing quantitative and selective monitoring of hydrogen peroxide production in real time.

Expression and identification of VEGF165 in bone marrow mesenchymal stem cells of rhesus / 天津医药

Objective To detect the transferred vascular endothelial growth factor (VEGF)165 gene expression in rhesus autologous bone marrow mesenchymal stem cells (MSCs), and to explore the functional viability of transgenic MSCs. Methods MSCs from rhesus bone were isolated by Ficoll, which were used to detect the phenotype. After the culturing, the expression vector pcDNA-eGFP-VEGF165 was transfected into bone marrow MSCs. Fluorescence microscope and flow cytometry were used to detect the enhanced green fluorescent protein (eGFP) expression. At the same time, the phenotype in transfected MSCs was also indentified. The VEGF165 expression level was detected by RT-PCR. Results The highly purified MSCs were collected successfully. The transfected MSCs and daughter cells showed expressions of eGFP and VEGF165, which also remained the characteristics of MSCs. Conclusion The VEGF165 gene that is transfected into MSCs can maintain characteristics of MSCs, and stably express foreign genes.

Influence of cigarette smoking extract on fluorescence expression of thrombomodulin on surface of COS-7 cells / 心血管康复医学杂志

Objective:To explore whether cigarette smoking extract (CSE) has influence on fluorescence protein ex-pression of thrombomodulin (TM) on surface of African green monkey kidney fibroblast cells (COS-7) or not . Methods:When TM-green fluorescent protein (GFP) plasmid was successfully constructed ,COS-7 cells were trans-fected by it ,then incubated by prepared 5% CSE (5% CSE group) ,PBS of certain volume was added to serum-free minimal essential medium (MEM ,simple medium) ,which was cultured at the same time and treated as control group .Flow cytometry counting method was used to detect change of TM-GFP expression amount on COS-7 surface at different time point .Results:Compare with control group ,there were no significant difference in the expression of TM-GFP on COS-7 surface at 1h and 6h in 5% CSE group [1h :(134.99 ± 18.41) vs .(146.61 ± 12.06) ,6h :(116.89 ± 27.28) vs .(123.89 ± 39.24) ,P>0.05 both] .Conclusion:The 5% cigarette smoking extract has no influ-ence on fluorescence expression of thrombomodulin on surface of African green monkey kidney fibroblast cells .

Kallikrein 1-transfected bone marrow mesenchymal stem cells：selection of the multiplicity of infection / 中国组织工程研究

BACKGROUND:Kalikrein 1 is an important component of the kalikrein-kinin system. Studies have shown that kalikrein can protect the cardiovascular system by promoting angiogenesis and inhibiting myocardial inflammation, but there is no report on its effect on inducing differentiation of stem cels. OBJECTIVE: To determine the transfection efficiency of kalikrein 1 adenoviral vector in rat bone mesenchymal stem cels. METHODS:Using adenovirus as a vector, the target gene kalikrein 1 was transfected into rat bone marrow mesenchymal stem cels. Fluorescence microscopy, MTT method and flow cytometry were used to investigate the effect of transfection and determine the optimal multiplicity of infection. RESULTS AND CONCLUSION:Adenovirus carrying kalikrein 1 was successfuly transfected into rat bone marrow mesenchymal stem cels. Results from flow cytometry showed that the transfection efficiency was associated with the multiplicity of infection. When the multiplicity of infection was 150, the transfection efficiency was 80.8%. MTT results showed that when the multiplicity of infection was 200, the cel growth was inhibited remarkably. These findings indicate that adenovirus-mediated kalikrein 1 can be successfuly transfected into rat bone marrow mesenchymal stem cels with the optimal multiplicity of infection=150.