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Date	Name	Size	Description	Versions
13:43, 29 September 2018	SAHS 1 Fig1.png (file)	187 KB	In our circuit of the build process, we have been doing nucleic acid gel electrophoresis to verify. After the loop is complete, sequencing verification.	2
13:52, 29 September 2018	SAHS 1 Fig3.png (file)	307 KB	SAHS is an exogenous protein with a signal peptide in front of it that allows the protein to be secreted outside the membrane. But our site organism is E. coli, because there is a cell wall, so the protein can not be secreted out of the membrane. There...	2
13:53, 29 September 2018	SAHS 1 Fig2.png (file)	90 KB	In our circuit of the build process, we have been doing nucleic acid gel electrophoresis to verify. After the loop is complete, sequencing verification.	2
14:55, 29 September 2018	KaiC 2 .gif (file)	234 KB	[1]Akiyama S. Structural and dynamic aspects of protein clocks: how can they be so slow and stable?[J]. Cellular & Molecular Life Sciences Cmls, 2012, 69(13):2147-2160.	1
14:57, 29 September 2018	KaiC 3 .gif (file)	96 KB	[1]Akiyama S. Structural and dynamic aspects of protein clocks: how can they be so slow and stable?[J]. Cellular & Molecular Life Sciences Cmls, 2012, 69(13):2147-2160.	1
15:18, 29 September 2018	All Kai.gif (file)	57 KB	[1]Shultzaberger R K, Boyd J S, Katsuki T, et al. Single mutations in sasA enable a simpler ΔcikA gene network architecture with equivalent circadian properties.[J]. Proceedings of the National Academy of Sciences of the United States of America, 2014...	1
15:19, 29 September 2018	KaiC 4 .gif (file)	951 KB	[1]Swan J A, Golden S, Liwang A, et al. Structure, function, and mechanism of the core circadian clock in cyanobacteria.[J]. Journal of Biological Chemistry, 2018, 293(14):5026-5034.	1
15:22, 29 September 2018	Kai ABC 2.gif (file)	761 KB	[1]Swan J A, Golden S, Liwang A, et al. Structure, function, and mechanism of the core circadian clock in cyanobacteria.[J]. Journal of Biological Chemistry, 2018, 293(14):5026-5034.	1
15:23, 29 September 2018	Kai 2 .gif (file)	273 KB	[1]Swan J A, Golden S, Liwang A, et al. Structure, function, and mechanism of the core circadian clock in cyanobacteria.[J]. Journal of Biological Chemistry, 2018, 293(14):5026-5034.	1
15:27, 29 September 2018	PKaiBC 2 .gif (file)	102 KB	[1]Espinosa J, Boyd J S, Cantos R, et al. Cross-talk and regulatory interactions between the essential response regulator RpaB and cyanobacterial circadian clock output[J]. Proceedings of the National Academy of Sciences of the United States of America...	1
15:33, 29 September 2018	KaiA.png (file)	68 KB	https://www.uniprot.org/uniprot/Q79PF6	1
15:35, 29 September 2018	KaiB.png (file)	110 KB	https://www.uniprot.org/uniprot/Q79PF5	1
15:37, 29 September 2018	KaiC z.png (file)	216 KB	https://www.uniprot.org/uniprot/Q79PF4	1
15:38, 29 September 2018	KaiC x.png (file)	242 KB	https://www.uniprot.org/uniprot/Q79PF4	1
15:39, 29 September 2018	CikA.png (file)	74 KB	https://www.uniprot.org/uniprot/Q9KHI5	1
15:42, 29 September 2018	SasA.png (file)	44 KB	https://www.uniprot.org/uniprot/Q06904	1
05:44, 30 September 2018	KaiC 1 .gif (file)	142 KB	[1]Akiyama S. Structural and dynamic aspects of protein clocks: how can they be so slow and stable?[J]. Cellular & Molecular Life Sciences Cmls, 2012, 69(13):2147-2160	4
05:40, 4 October 2018	KaiA Gel.png (file)	56 KB		1
05:45, 4 October 2018	KaiB Gel.png (file)	52 KB		1
05:48, 4 October 2018	KaiC Gel.png (file)	33 KB		1
05:54, 4 October 2018	SasA Gel.png (file)	87 KB		1
05:56, 4 October 2018	CikA Gel.png (file)	92 KB		1
06:03, 4 October 2018	RpaA Gel.png (file)	88 KB		1
06:16, 4 October 2018	SAHS protein Gel.png (file)	132 KB		2
06:23, 4 October 2018	CAHS Gel.png (file)	50 KB		1
06:24, 4 October 2018	CAHS protein Gel.png (file)	118 KB		1
06:31, 4 October 2018	PKaiBC Gel.png (file)	75 KB		1
10:44, 5 October 2018	SAHS Gel 1.png (file)	356 KB		1
10:46, 5 October 2018	SAHS Gel 2.png (file)	242 KB		1
10:49, 5 October 2018	SAHS pro Gel 1.png (file)	400 KB		1
10:54, 5 October 2018	CAHS Com pro Gel1.png (file)	258 KB		1
08:04, 6 October 2018	K2623011.png (file)	194 KB		1
08:06, 6 October 2018	K2623013.png (file)	248 KB		1
10:05, 7 October 2018	K2623016.png (file)	417 KB		1
17:48, 16 October 2018	Kai 1 .gif (file)	109 KB		2
18:04, 16 October 2018	PKaiBC 1 .gif (file)	79 KB		2
18:29, 16 October 2018	PKaiBC RpaA .gif (file)	207 KB		2
04:38, 17 October 2018	GroupA.png (file)	23 KB		1
04:38, 17 October 2018	GroupB.png (file)	23 KB		1
06:15, 17 October 2018	Math.png (file)	47 KB		1
06:24, 17 October 2018	Mathb.png (file)	49 KB		1
06:48, 17 October 2018	A fitting.txt (file)	2 KB		1
06:49, 17 October 2018	B fitting.txt (file)	2 KB		1
12:43, 17 October 2018	Figure 9- the circuit of BBa K2623014.png (file)	48 KB		1
12:53, 17 October 2018	Figure 10- the E.coli DH5а with BBa-K2623014 and IPTG turns red.(D+ is E.coli DH5а with BBa K2623014 and IPTG, D- is E.coli DH5а with BBa K2623014 without IPTG, D0 is E.coli DH5а without BBa K2623014).png (file)	448 KB		1
12:57, 17 October 2018	Figure 5- gradient dilution.png (file)	123 KB		1
13:01, 17 October 2018	Figure 5- the CFU of BL21.png (file)	22 KB		1
13:09, 17 October 2018	Figure 7- the colony recovery rate.png (file)	16 KB		1
13:17, 17 October 2018	Figure 15- the plate of colony for counting.png (file)	1.06 MB		1
13:33, 17 October 2018	BBa K2623016.jpg (file)	1.75 MB		1

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