Generation of 12 Drosophila Transgenic Negative Control Lines Based on Site-specific ΦC31 Integrase and pUASTattB Vector

doi:10.12300/j.issn.1674-5817.2023.100

Abstract

Abstract:

Objective Construction of a negative control line for the Drosophila transgenic system based on ΦC31 integrase and vector plasmid pUASTattB to provide a more scientific negative control for transgenic Drosophila research experiments. Methods The vector plasmid pUASTattB was microinjected into four different genetic backgrounds Drosophila lines attP-25C6, attP-68A4, attP-75B1 and attP-86F8 embryos carrying ΦC31 integrase. All of the injected embryos were incubuated to get G0 adults, and each of them was crossed with balancer stock ywR13S separately in a single vial (1 adult of the G0 generation and 3 of the ywR13S in each vial). The probability of successful insertion was calculated by observing the colour of the compound eyes of the G1 generation of Drosophila to determine whether there was a mini-White insertion. The G1 generation Drosophila adults successfully inserted into mini-White were then selected to make single-vial crosses (one G1 generation male Drosophila crossed with three virgins of balancer Drosophila line) with each of the three balancer Drosophila strains DB, ywR13S and yw122, respectively, for balanced seed preservation. The genomic DNA of the conserved Drosophila lines was extracted and the vector plasmid pUASTattB was identified for transfer by PCR. Results 12 Drosophila strains were obtained, all of which were red-eyedDrosophila melanogaster carrying the mini-White marker, and were identified by PCR as having the pUASTattB sequence insertion. Conclusion The 12 transgenic Drosophila strains can meet the negative control requirements for the transgenic fly research experiments that constructed with pUASTattB as the vector basically, enriching the Drosophila resources in the National Drosophila Resource Center of China.

Key words: Drosophila melanogaster, Transgenic, Negative control, Microinjection, Balancers

CLC Number:

R-332

Longmei XU, Ruling SHEN, Chun FAN, Wei WU. Generation of 12 Drosophila Transgenic Negative Control Lines Based on Site-specific ΦC31 Integrase and pUASTattB Vector[J]. Laboratory Animal and Comparative Medicine, 2023, 43(5): 541-547.

Figures/Tables 8

References 12

1	PORT F, STREIN C, STRICKER M, et al. A large-scale resource for tissue-specific CRISPR mutagenesis in Drosophila [J]. eLife, 2020, 9: e53865. DOI: 10.7554/eLife.53865 .
2	徐荣刚, 王霞, 王芳, 等. 果蝇研究技术与资源的开发[J]. 中国实验动物学报, 2018, 26(4):489-492. DOI: 10.3969/j.issn.1005-4847.2018.04.013 .
	XU R G, WANG X, WANG F, et al. Research techniques and resource development of Drosophila melanogaster [J]. Acta Lab Anim Sci Sin, 2018, 26(4):489-492. DOI: 10.3969/j.issn.1005-4847.2018.04.013 .
3	RUBIN G M, SPRADLING A C. Genetic transformation of Drosophila with transposable element vectors[J]. Science, 1982, 218(4570):348-353. DOI: 10.1126/science.6289436
4	FISH M P, GROTH A C, CALOS M P, et al. Creating transgenic Drosophila by microinjecting the site-specific phiC31 integrase mRNA and a transgene-containing donor plasmid[J]. Nat Protoc, 2007, 2(10):2325-2331. DOI: 10.1038/nprot. 2007.328 .
5	VENKEN K J T, BELLEN H J. Genome-wide manipulations of Drosophila melanogaster with transposons, flp recombinase, and ΦC31 integrase[J]. Methods Mol Biol, 2012, 859:203-228. DOI: 10.1007/978-1-61779-603-6_12 .
6	J.Greenspan Ralph. Fly Pushing:The theory and practice of Drosophila genetics[M]. Second edition,Cold Spring Harbor Laboratory Press, Cold Spring Harbor, New York,2004:13-15
7	STERN D L. Transgenic tools for targeted chromosome rearrangements allow construction of balancer chromosomes in non-melanogaster Drosophila species[J]. G3 (Bethesda), 2022, 12(4): jkac030. DOI: 10.1093/g3journal/jkac030 .
8	TIONG S Y, NASH D. Genetic analysis of the adenosine3 (Gart) region of the second chromosome of Drosophila melanogaster [J]. Genetics, 1990, 124(4):889-897. DOI: 10.1093/genetics/124.4.889 .
9	邵素娟, 吴薇. 全球果蝇资源库分布现状分析[J]. 南方农业, 2018, 12(26):186-186, 193. DOI: 10.19415/j.cnki.1673-890x.2018.26.091
	SHAO S J, WU W. Analysis on the distribution of Drosophila resource bank in the world[J]. South China Agric, 2018, 12(26):186-186, 193. DOI: 10.19415/j.cnki.1673-890x.2018.26.091 .
10	潘吉川, 姜秋实, 刘强, 等. 果蝇信息和种系资源的获得[J]. 中国实验动物学报, 2020, 28(2):286-288. DOI: 10.3969/j.issn.1005-4847.2020.02.021 .
	PAN J C, JIANG Q S, LIU Q, et al. Requirement of Drosophila information and stock resources[J].Acta Lab Anim Sci Sin, 2020, 28(2):286-288. DOI: 10.3969/j.issn.1005-4847.2020.02.021 .
11	ZIRIN J, HU Y H, LIU L P, et al. Large-scale transgenic Drosophila resource collections for loss- and gain-of-function studies[J]. Genetics, 2020, 214(4):755-767. DOI: 10.1534/genetics.119.302964 .
12	LUO J, SHEN P P, CHEN J. A modular toolset of phiC31-based fluorescent protein tagging vectors for Drosophila [J]. Fly, 2019, 13(1-4):29-41. DOI: 10.1080/19336934.2019.1595999 .

果蝇品系序号Number of fly strains	名称 Name	attP位点所在染色体位置Chromosome of attP site	背景果蝇品系（基因型） Different genetic background strains (genotype)	用途 Application
背景果蝇
1	attP-25C6	2L	y[1] M{vas-int.Dm}ZH-2A w[*]; P{CaryP}attP40	定点插入
2	attP-68A4	3L	y[1] M{vas-int.Dm}ZH-2A w[*]; P{CaryP}attP2	定点插入
3	attP-75B1	3L	vas-phi-Zh2A-VK5	定点插入
4	attP-86F8	3R	y[1] M{vas-int.Dm}ZH-2A w[*]; M{3xP3-RFP.attP}ZH-86Fb	定点插入
平衡子果蝇
1	DB		W¹¹¹⁸; Sp/CyO; TM2/TM6B	平衡保种
2	ywR13S		yw; Sp/CyO; MKRS/TM2	平衡保种
3	yw122		yw hsFlp¹²²; Sp/CyO(y⁺); TM2/TM6B	平衡保种

果蝇品系序号Number of fly strains	名称 Name	attP位点所在染色体位置Chromosome of attP site	背景果蝇品系（基因型） Different genetic background strains (genotype)	用途 Application
背景果蝇
1	attP-25C6	2L	y[1] M{vas-int.Dm}ZH-2A w[*]; P{CaryP}attP40	定点插入
2	attP-68A4	3L	y[1] M{vas-int.Dm}ZH-2A w[*]; P{CaryP}attP2	定点插入
3	attP-75B1	3L	vas-phi-Zh2A-VK5	定点插入
4	attP-86F8	3R	y[1] M{vas-int.Dm}ZH-2A w[*]; M{3xP3-RFP.attP}ZH-86Fb	定点插入
平衡子果蝇
1	DB		W¹¹¹⁸; Sp/CyO; TM2/TM6B	平衡保种
2	ywR13S		yw; Sp/CyO; MKRS/TM2	平衡保种
3	yw122		yw hsFlp¹²²; Sp/CyO(y⁺); TM2/TM6B	平衡保种

序号 No.	平衡子名称 Name of balancers	显性标志 Dominant marker	对应染色体 Chromosome	表型描述 Comments of phenotype
1	Wg^Sp-1（Sp*）	Sp*	2#	腹侧板第三根刚毛由1根变为2根或2根以上
2	CyO（In(2LR)O, Cy dp^lv1 cn² pr）	Cy	2#	翅膀卷曲
3	MKRS（M（3）76A¹ kar¹ ry² Sb¹）	Sb	3#	刚毛短硬
4	TM2（In（3LR）Ubx¹³⁰）	Ubx	3#	大平衡棒
5	TM6B（In(3LR)TM6, Hu e）	Hu	3#	肩部多毛

序号 No.	平衡子名称 Name of balancers	显性标志 Dominant marker	对应染色体 Chromosome	表型描述 Comments of phenotype
1	Wg^Sp-1（Sp*）	Sp*	2#	腹侧板第三根刚毛由1根变为2根或2根以上
2	CyO（In(2LR)O, Cy dp^lv1 cn² pr）	Cy	2#	翅膀卷曲
3	MKRS（M（3）76A¹ kar¹ ry² Sb¹）	Sb	3#	刚毛短硬
4	TM2（In（3LR）Ubx¹³⁰）	Ubx	3#	大平衡棒
5	TM6B（In(3LR)TM6, Hu e）	Hu	3#	肩部多毛

[1]	Feng WEI, Weiwei CHENG, Yafu YIN. Characteristics and Application of Transgenic Mouse Models in Alzheimer's Disease [J]. Laboratory Animal and Comparative Medicine, 2022, 42(5): 432-439.
[2]	Jiani LIU, Jiangang LIU, Yun WEI, Hao LI, Zenggang LUO, Yi WANG, Kun LI. Pathological and Synaptic Morphological Changes of the Olfactory Bulb in APP/PS1 Model Mice at Different Ages and the Intervention Effect of Memantine [J]. Laboratory Animal and Comparative Medicine, 2022, 42(3): 177-186.
[3]	WANG Qianqian, WANG Wei, LIU Rui, WEI Zhen, LIU Chong. Factors Affecting Production Efficiency of Bacterial Artificial Chromosome Transgenic Mice [J]. Laboratory Animal and Comparative Medicine, 2021, 41(6): 535-542.
[4]	DU Xiao-yan, CHEN Bai-an, WU Yi, GUO Meng. The Significance of Transgenic Animal Technology for Graduated Students in Medical University and Review of Teaching Experience [J]. Laboratory Animal and Comparative Medicine, 2018, 38(6): 459-462.
[5]	MA Deng-lei, ZHANG Lan. P301S Mutant Tau Transgenic Mouse and Their Applications [J]. Laboratory Animal and Comparative Medicine, 2017, 37(6): 491-496.
[6]	GU Xiao-wen, SUN Rei-lin, FEI Jian. Construction of Afp-cre-lacZ Transgenic Mouse Model [J]. Laboratory Animal and Comparative Medicine, 2017, 37(2): 89-93.
[7]	ZHOU Wei-min, ZHU Ke-yan, CHEN Fang-ming, CAI Yue-qing, FANG Ming-sun, Qi Yue-han, CHEN min-li. Pathological Change of Kidney in Pkd1 Knock-out Mice with Polycystic Kidney Induced by Tamoxifen [J]. Laboratory Animal and Comparative Medicine, 2017, 37(1): 11-14.
[8]	WANG Jin-jin, KUANG Fang-zhe, ZHUANG Hua, LU Cui-jie, KUANG Ying. Identification of Mouse Prss37 Transcription Initiation Site and Preliminary Analysis of Its Transcription Regulation [J]. Laboratory Animal and Comparative Medicine, 2016, 36(2): 93-100.
[9]	ZHANG Mei-ying, YANG Wei, WU Hong-lian, DONG Wan-wei, ZHOU Sheng-lai,YU Yang, WANG Wei, GUO Xiao-chong, ZHENG Zhi-hong. A Preliminary Study on Phenotype of 5-Lipoxygenase Transgenic Mice [J]. Laboratory Animal and Comparative Medicine, 2015, 35(4): 265-270.
[10]	CHEN Ke-yan, CHEN Zhen-wen, DONG Wan-wei, ZHENG Zhi-hong. Producing Transgenic Pig by Bacteria Magnetic Particles [J]. Laboratory Animal and Comparative Medicine, 2015, 35(4): 288-293.
[11]	LI Zhao-yang, JIANG Chuan, GUO Xiao-chong, YANG Wei, DONG Wan-wei, ZHENG Zhi-hong. Modeling of B16 Melanoma in Dicer1 Transgenic Mice [J]. Laboratory Animal and Comparative Medicine, 2015, 35(4): 294-297.
[12]	JIANG Wei-hua, LI Shan-gang, CHEN Xue-jin. Advances on Research of APOE Gene Function and Related Diseases Models [J]. Laboratory Animal and Comparative Medicine, 2015, 35(3): 249-257.
[13]	LIU Lei, WANG Bao-zhu, LAO Quan-heng, LIU Min, XUE Zheng-feng, JI Ming-chun. Preliminary Study on Development of bcr Promotor Driven EGFP Expressing Transgenic Mice [J]. Laboratory Animal and Comparative Medicine, 2015, 35(2): 149-154.
[14]	JIA Xiao-feng, XU Yan, LIU Miao, WANG Liang, SHI Hui-juan. Impact of Different Method in Sperm Membrane Treatment on Exogenous Plasmid Transgenic Efficiency by Sperm [J]. Laboratory Animal and Comparative Medicine, 2013, 33(4): 256-260.
[15]	GUO Xin-bing, GONG Xiu-li, CHEN Yan-wen, FANG Yu-dan, ZHANG Jing-zhi. Viral Particle Titer and Transgene Length Affect Integration Rate of Lentiviral Vector Mediated Transgenic Mice [J]. Laboratory Animal and Comparative Medicine, 2013, 33(3): 185-189.