TABLE 1

Summary of effects on GLP-1 pharmacology (affinity and ability to activate cAMP pathway) in published site-directed mutagenesis studies of GLP-1R

WT (wild-type) refers to mutations that resulted in either <fivefold or no statistically significant change from wild-type GLP-1R. ND (not determinable) refers to a property that was measured, but for which a value was not determinable. Blank cells mean that the assays used to estimate that particular pharmacological property were not carried out in the cited work. Residues with symbol ^† refer to data from rat GLP-1R (if different, the equivalent human residue number is displayed in the table to aid comparison). GLP-1 affinity or potency fold-change values with suffix ^M are from membrane preparations, whereas suffix ^C is from whole-cell assays. Cell surface expression values below 75% of WT are shown (>75% are shown as WT): a suffix ^E represents estimation from ELISAs; suffix ^mic was evaluated from immunofluorescent microscopy; suffix ^cyt was evaluated by flow cytometry with an anti-Flag antibody; suffix ^Ag refers to affinity or cell surface expression levels determined from agonist radioligand-binding assays, whereas suffix ^Ant was from antagonist radioligand-binding assays. ΔLog τ_c values relative to WT are shown where >0.5 and were calculated from data where the expression-corrected efficacy term τ_c had been calculated using the operational model of agonism, as defined in Wootten et al. (2013c). Residues with transmembrane helices are numbered according to Wootten et al. (2013c).

Residue	Mutated to	-Fold Reduction Affinity	-Fold Reduction Potency^‡	Cell Surface Expression (% Wild-Type)	Comments and/or Other Observed Effects	Reference
P7^ECD	L	WT^C,Ant	WT	WT^E		Koole et al., 2011
R20^ECD	K	WT^C,Ant	WT	WT^E		Koole et al., 2011
L32^ECD	A	WT^M,Ag	WT	WT^Ag		Underwood et al., 2010
L32^ECD	A		WT			Patterson et al., 2013
W33^ECD	S	WT^C,Ant			Species change (human to rat)— the expected lack of effect on GLP-1 pharmacology was implied in text, but no data are shown	Tibaduiza et al., 2001
T35^ECD	A	WT		7%^Ag		Underwood et al., 2010
Val-36^ECD	A	WT^M,Ag	WT	WT^Ag		Underwood et al., 2010
W39^ECD^†		ND^C,Ag			Membrane expression confirmed via WB	Wilmen et al., 1997
R44^ECD	H	WT^C,Ant	WT	WT^E		Koole et al., 2011
N63^ECD	L	WT^C,Ag	WT	WT^Ag		Chen et al., 2010a
E68^ECD	A	WT^M,Ag	WT	WT^Ag		Underwood et al., 2010
E68^ECD	K		8			Day et al., 2011
Y69^ECD	A	ND^M,Ag	ND		ND^Ag	Underwood et al., 2010
W72^ECD^†		ND^C,Ag			Membrane expression confirmed via WB	Wilmen et al., 1997
N82^ECD	L	WT^C,Ag	WT	WT^Ag		Chen et al., 2010a
W87^ECD		WT^C,Ag	WT	24–62%	Transient and stable cell lines analyzed	Wilmen et al., 1997
Y88^ECD	A	ND^M,Ag	ND		ND^Ag	Underwood et al., 2010
L89^ECD	A	ND^M,Ag	ND		ND^Ag	Underwood et al., 2010
Pro-90^ECD	A	WT^M,Ag	WT	WT^Ag		Underwood et al., 2010
W91^ECD^†		ND^C,Ag			Membrane expression confirmed via WB	Wilmen et al., 1997
W110^ECD^†		ND^C,Ag			Membrane expression confirmed via WB	Wilmen et al., 1997
N115^ECD	L	WT^C,Ag	WT	WT^Ag		Chen et al., 2010a
W120^ECD^†		ND^C,Ag			Membrane expression confirmed via WB	Wilmen et al., 1997
R121^ECD	A	WT^M,Ag	WT	WT^Ag		Underwood et al., 2010
L123^ECD	A	WT^M,Ag	WT	47%^Ag		Underwood et al., 2010
E127^ECD	A	WT^M,Ag	WT	WT^Ag		Underwood et al., 2010
E127^ECD	A		WT			Patterson et al., 2013
E127^ECD	E	WT^M,Ag	WT	WT^Ag		Underwood et al., 2010
E128^ECD	A	WT^M,Ag	WT	WT^Ag		Underwood et al., 2010
E128^ECD	A		WT			Patterson et al., 2013
E128^ECD	Q	WT^M,Ag	WT	WT^Ag		Underwood et al., 2010
E128^ECD	M		WT			Day et al., 2011
R131^1.26b	N	WT^C,Ant	WT	WT^E		Koole et al., 2011
L141^1.36b	A	WT^C,Ag	WT	67%^cyt		Yang et al., 2016
Y145^1.40b	A	WT^C,Ag	WT	47%^cyt		Yang et al., 2016
Y148^1.43b	A	ND^C,Ag	26	WT^cyt		Yang et al., 2016
Y148^1.43b	N	15^C,Ag	8	WT^cyt		Yang et al., 2016
Y148^1.43b	F	ND^C,Ag	14	WT^cyt		Yang et al., 2016
Y148^1.43b	F	10^C,Ant	14	WT^cyt		Yang et al., 2016
T149^1.44b	M	60^C,Ant	14–33	WT^E ^& ^Ant		Beinborn et al., 2005
T149^1.44b	M^*	250^C,Ant	160	<50%^E	E_max = ND	Koole et al., 2011
T149^1.44b	M^*	250^C,Ant	160	<50%^E	For additional residue substiutions, see Koole et al., 2015	Koole et al., 2011
T149^1.43b	M	ND^C,Ag	59	WT^cyt		Yang et al., 2016
T149^1.43b	A	ND^C,Ag	82	WT^cyt		Yang et al., 2016
T149^1.43b	S	WT^C,Ag	WT	WT^cyt		Yang et al., 2016
Y152^1.47b	A	30^M,Ant	ND	7%^Ant		Coopman et al., 2011
Y152^1.47b	H	WT^C,Ag	WT	WT^cyt		Yang et al., 2016
S155^1.50b	A	WT^C,Ant	10	55%^E, 48%^Ant	ΔLog τ_c = 0.75	Wootten et al., 2013c
G168^ICL1	S	WT^C,Ant	WT	<50%^E		Koole et al., 2011
F169^ICL1^†	A	WT^C,Ag		WT^Ag	WT cAMP 10⁻⁷ M GLP-1	Mathi et al., 1997
R170^ICL1^†	A	WT^C,Ag		WT^Ag	WT cAMP 10⁻⁷ M GLP-1	Mathi et al., 1997
H171^ICL1^†	A	WT^C,Ag		WT^Ag	WT cAMP 10⁻⁷ M GLP-1	Mathi et al., 1997
L172^ICL1^†	A	WT^C,Ag		35%^Ag	WT cAMP 10⁻⁷ M GLP-1	Mathi et al., 1997
H173^ICL1^†	A	WT^C,Ag		48%^Ag	WT cAMP 10⁻⁷ M GLP-1	Mathi et al., 1997
C174^ICL1^†	A	WT^C,Ag		45%^Ag	37% cAMP 10⁻⁷ M GLP-1	Mathi et al., 1997
C174^ICL1	A		6			Underwood et al., 2013
C174^ICL1	S		7			Underwood et al., 2013
T175^2.45b^†	A	WT^C,Ag		57%^Ag	WT cAMP 10⁻⁷ M GLP-1	Mathi et al., 1997
R176^2.46b^†	A	WT^C,Ag	13	WT^Ag	26% cAMP 10⁻⁷ M GLP-1	Mathi et al., 1997
N177^2.47b^†	A	WT^C,Ag		22%^Ag	43% cAMP 10⁻⁷ M GLP-1	Mathi et al., 1997
H180^2.50b^†	R	21^C,Ag		WT^mic		Heller et al., 1996
H180^2.50b	A	ND^C,Ant	12	18%^E, ND^Ant	ΔLog τ_c = 0.86	Wootten et al., 2013c
N182^2.52b^†	A	WT^C,Ag		24%^Ag	“36% of WT” cAMP	Xiao et al., 2000
S186^2.56b	A	WT^C,Ant	WT	WT^E,Ant		Wootten et al., 2013c
F187^2.57b	A	ND^C,Ag	ND	5%^cyt		Yang et al., 2016
R190^2.60b^†	A	>20^C,Ag		21%^Ag	“27% of WT” cAMP	Xiao et al., 2000
R190^2.60b	A	32^M,Ant	270	7%^Ant		Coopman et al., 2011
R190^2.60b	A	20^C,Ant	34	53%^E, 44^Ant	ΔLog τ_c = 0.53	Wootten et al., 2013c
R190^2.60b	A	ND^C,Ag	ND	WT^cyt		Yang et al., 2016
R190^2.60b	K	ND^C,Ag	17	WT^cyt		Yang et al., 2016
R190^2.60b	K	32^C,Ant	17	WT^cyt		Yang et al., 2016
L192^2.62b	S		WT			Underwood et al., 2011
L192^2.62b	S	WT^C,Ag	WT	WT^cyt		Yang et al., 2016
V194^2.64b	A	WT^C,Ag	WT	WT^cyt		Yang et al., 2016
F195^2.65b	L		WT	59%^Ag		Underwood et al., 2011
I196^2.66b^†	S	WT^C,Ag	ND			Moon et al., 2012
K197^2.67b	A	28^M,Ant	630	57%^Ant		Coopman et al., 2011
K197^2.67b^†	A	5^C,Ag		30%^Ag	“25% of WT” cAMP	Xiao et al., 2000
K197^2.67b	A	ND^C,Ag	ND	51%^cyt		Yang et al., 2016
K197^2.67b	I	ND^C,Ag	ND	51%^cyt		Yang et al., 2016
K197^2.67b	I	28^C,Ant	ND	51%^cyt		Yang et al., 2016
K197^2.67b	Q	ND^C,Ag	ND	WT^cyt		Yang et al., 2016
K197^2.67b	R	ND^C,Ag	23	WT^cyt		Yang et al., 2016
D198^2.68b^†	A	10^C,Ag		16%^Ag	“45% of WT” cAMP	Xiao et al., 2000
D198^2.68b^†	A	63^M,Ant	44	WT^Ant		López de Maturana and Donnelly, 2002
D198^2.68b	A	43^M,Ant	977	66%^Ant		Coopman et al., 2011
D198^2.68b	A	ND^C,Ag	ND	WT^cyt		Yang et al., 2016
D198^2.68b^†	N	WT^M,Ag				López de Maturana and Donnelly, 2002
D198^2.68b	N	ND^C,Ag	89	WT^cyt		Yang et al., 2016
D198^2.68b	E	ND^C,Ag	434	WT^cyt		Yang et al., 2016
D198^2.68b	E	58^C,Ant	434	WT^cyt		Yang et al., 2016
A200-L201^†	V/A	WT^M,Ag	WT			López de Maturana et al., 2004
L201^2.68b	A	ND^C,Ag	ND	WT^cyt		Yang et al., 2016
K202^ECL1^†	A	WT^C,Ag		45%^Ag	“71% of WT” cAMP	Xiao et al., 2000
K202/W203^†	A/A	WT^M,Ag	WT			López de Maturana et al., 2004
W203^ECL1	T	WT^C,Ag	WT	WT^cyt		Yang et al., 2016
M204/Y205^†	A/A	37^M,Ant	51	28%^Ant		López de Maturana et al., 2004
M204/Y205^†	V/A	23^M,Ag	32	WT^Ant		López de Maturana et al., 2004
M204/Y205^†	A/V	29^M,Ag	87	WT^Ant		López de Maturana et al., 2004
M204^ECL1^†	A	WT^M,Ag	WT	44%^Ant		López de Maturana et al., 2004
M204^ECL1	A	ND^C,Ag	334	WT^cyt		Yang et al., 2016
M204^ECL1	R	ND^C,Ag	93	WT^cyt		Yang et al., 2016
Y205^ECL1^†	A	WT^M,Ag	WT	WT^Ant		López de Maturana et al., 2004
Y205^ECL1	A	ND^C,Ag	62	WT^cyt		Yang et al., 2016
S206/T207^†	A/A	WT^M,Ag	WT			López de Maturana et al., 2004
A208/A209^†	V/V	WT^M,Ag	WT			López de Maturana et al., 2004
Q210Q211^†	A/A	WT^M,Ag	WT			López de Maturana et al., 2004
Q211^ECL1	D	WT^C,Ag	WT	WT^cyt		Yang et al., 2016
Q211^ECL1	R	WT^C,Ag	WT	WT^cyt		Yang et al., 2016
H212^ECL1^†	A	WT^C,Ag		WT^Ag	“WT cAMP”	Xiao et al., 2000
H212^ECL1	A	WT^C,Ag	WT	WT^cyt		Yang et al., 2016
H212/Q213^†	A/A	WT^M,Ag	WT			López de Maturana et al., 2004
D215^ECL1^†	A	WT^C,Ag		51%^Ag	“57% of WT” cAMP	Xiao et al., 2000
W214^ECL1	V	WT^C,Ag	WT	WT^cyt		Yang et al., 2016
W214/D215^†	A/A	WT^M,Ag	WT			López de Maturana et al., 2004
G216/L217^†	A/A	WT^M,Ag	WT			López de Maturana et al., 2004
L217^ECL1	A	WT^C,Ag	WT	WT^cyt		Yang et al., 2016
L218/S219^†	A/A	WT^M,Ag	WT			López de Maturana et al., 2004
Y220/Q221^†	A/A	WT^M,Ag	WT			López de Maturana et al., 2004
Y220^ECL1	D	ND^C,Ag	105	WT^cyt		Yang et al., 2016
D222^3.25b^†	A	WT^C,Ag		WT^Ag	“82% of WT” cAMP	Xiao et al., 2000
D222/S223^†	A/A	WT^M,Ag	WT			López de Maturana et al., 2004
L224/G225^†	A/A	WT^M,Ag	WT			López de Maturana et al., 2004
C226^3.29b^*^†	A	25^M,Ant	38	65%^Ant		Mann et al., 2010a
C226^3.29b	A		>90			Underwood et al., 2013
R227^3.30b^†	A	>20^C,Ag		31%^Ag	“90% WT” cAMP	Xiao et al., 2000
R227/L228^†	A/A	WT^M,Ag	WT			López de Maturana et al., 2004
V229/F230^†	A/A	WT^M,Ag	WT			López de Maturana et al., 2004
L232/M233^†	V/T	10^C,Ag	100			Moon et al., 2012
M233^3.36b	A	ND^C,Ag	70	WT^cyt		Yang et al., 2016
M233^3.36b	A	16^C,Ant	70	WT^cyt		Yang et al., 2016
M233^3.36b	T	ND^C,Ag	62	WT^cyt		Yang et al., 2016
M233^3.36b	F	WT^C,Ag	WT	WT^cyt		Yang et al., 2016
Q234^3.37b	A	13^M,Ant	45	27%^Ant		Coopman et al., 2011
Q234^3.37b	A	ND^C,Ag	151	35%^cyt		Yang et al., 2016
Q234^3.37b	N	WT^C,Ag	WT	WT^cyt		Yang et al., 2016
Q234^3.37b	E	ND^C,Ag	29	69%^cyt		Yang et al., 2016
Q234^3.37b	E	17^C,Ant	29	69%^cyt		Yang et al., 2016
Y235^3.38b	A	24^M,Ant	23	12%^Ant		Coopman et al., 2011
C236^3.39b	A		WT			Underwood et al., 2013
N240^3.43b^†	A	>20^C,Ag		14%^Ag	“8% WT” cAMP	Xiao et al., 2000
N240^3.43b	A	WT^C,Ant	7	WT^E,Ant	ΔLog τ_c = 0.67	Wootten et al., 2013c
N240^3.43b	Q	WT^C,Ant	WT	WT^E,Ant		Wootten et al., 2016
N240/Q394	A/A	WT^C,Ant	WT	71%^E,Ant	ΔLog τ_c = 0.70	Wootten et al., 2016
N240/Q394	Q/N	5^C,Ant	WT	71%^E,Ant		Wootten et al., 2016
Y241^3.44b	A		WT	42%^Ag		Underwood et al., 2011
Y241^3.44b	A	WT^C,Ag	WT	WT^cyt		Yang et al., 2016
E247^3.50b	A	WT^C,Ag		64%^Ag	“39% WT” cAMP	Xiao et al., 2000
E247^3.50b	A	ND^C,Ant	14	18%^E, ND^Ant	ΔLog τ_c = 0.99	Wootten et al., 2013c
F260^ICL2	L	WT^C,Ant	WT	<50%^E		Koole et al., 2011
E262^ICL2^†	A	WT^C,Ag		WT^Ag	WT cAMP 10⁻⁷ M GLP-1	Mathi et al., 1997
Q263^ICL2^†	A	WT^C,Ag		WT^Ag	WT cAMP 10⁻⁷ M GLP-1	Mathi et al., 1997
R264^ICL2^†	A	WT^C,Ag		WT^Ag	WT cAMP 10⁻⁷ M GLP-1	Mathi et al., 1997
I265^ICL2^†	A	WT^C,Ag		WT^Ag	WT cAMP 10⁻⁷ M GLP-1	Mathi et al., 1997
F266^4.42b^†	A	WT^C,Ag		WT^Ag	WT cAMP 10⁻⁷ M GLP-1	Mathi et al., 1997
K267^4.43b^†	A	WT^C,Ag		WT^Ag	WT cAMP 10⁻⁷ M GLP-1	Mathi et al., 1997
L268^4.44b^†	A	WT^C,Ag		WT^Ag	WT cAMP 10⁻⁷ M GLP-1	Mathi et al., 1997
L278^4.54b	M		WT			Underwood et al., 2011
W284^4.60b	A	32^M,Ant	1349	34%^Ant		Coopman et al., 2011
G285^4.61b	A	WT^C,Ant	WT	WT^E		Koole et al., 2012a
I286^4.62b	A	WT^C,Ant	WT	WT^E		Koole et al., 2012a
V287^4.63b	A	WT^C,Ant	WT	WT^E		Koole et al., 2012a
I286/V287	A/A		WT		85% SB^M,Ag	Dods and Donnelly, 2015
K288^4.64b	A	126^C,Ant	ND	WT^E		Koole et al., 2012a
K288^4.64b	A	23^M,Ant	5732	WT^Ant	ΔLog τ_c = 1.39	Dods and Donnelly, 2015
K288^4.64b^†	A	79^M,Ant	251			Al-Sabah and Donnelly, 2003b
K288^4.64b^†	L	63^M,Ant	79			Al-Sabah and Donnelly, 2003b
K288^4.64b	L	ND^C,Ag	ND	70%^cyt		Yang et al., 2016
K288^4.64b^†	R	WT^M,Ag	WT			Al-Sabah and Donnelly, 2003b
K288/Y289	A, A		2188		28% SB^M,Ag	Dods and Donnelly, 2015
Y289^4.65b	A	WT^C,Ant	WT	WT^E		Koole et al., 2012a
Y289^4.65b	A	WT^M,Ant	WT	20%^Ant		Dods and Donnelly, 2015
L290^4.66b	A	WT^C,Ant	WT	WT^E		Koole et al., 2012a
Y291^4.67b	A	WT^C,Ant	WT	WT^E		Koole et al., 2012a
L290/Y291^†	A/A	WT^M,Ag	WT			Mann et al., 2010a
L290-Y291	A/A		WT		99% SB^M,Ag	Dods and Donnelly, 2015
E292^ECL2	A	100^C,Ant	126	WT^E	ΔLog τ_c = 0.57	Koole et al., 2012a
E292^ECL2	A	ND^C,Ag	33	39%^cyt		Yang et al., 2016
D293^ECL2	A	25^C,Ant	16	62%^E		Koole et al., 2012a
E292/D293^†	A/A	8^M,Ag	79			Mann et al., 2010a
E292/D293	A/A		25		75% SB^M,Ag	Dods and Donnelly, 2015
E294^ECL2	A	WT^C,Ant	WT	WT^E	ΔLog τ_c = 0.65	Koole et al., 2012a
G295^ECL2	A	WT^C,Ant	WT	WT^E		Koole et al., 2012a
E294-G295^†	A/A	WT^M,Ag	WT			Mann et al., 2010a
E294-G295	A/A		WT		97% SB ^M,Ag	Dods and Donnelly, 2015
C296^ECL2^*^†	A	18^M,Ant	WT	23%^Ant		Mann et al., 2010a
C296^ECL2	A	13^C,Ant	126	60^E		Koole et al., 2012a
C296^ECL2	S	ND^C,Ag	96	WT^cyt		Yang et al., 2016
W297^ECL2	A	63^C,Ant	316	WT^E	ΔLog τ_c = 1.00	Koole et al., 2012a
W297^ECL2	A	ND^C,Ag	ND	WT^cyt		Yang et al., 2016
W297^ECL2	H	ND^C,Ag	50	40%^cyt		Yang et al., 2016
T298^ECL2	A	WT^C,Ant	WT	WT^E		Koole et al., 2012a
W297/T298^†	A/A	100^M,Ant	50			Mann et al., 2010a;
W297/T298^†	A/A	100^M,Ant	50			Donnelly, 2012
W297/T298	A/A		22		57% SB^M,Ag	Dods and Donnelly, 2015
R299^ECL2	A	32^C,Ant	85	WT^E		Koole et al., 2012a
R299^ECL2	A	WT^M,Ant	WT	40%^Ant	ΔLog τ_c = 0.60	Dods and Donnelly, 2015
R299^ECL2	S	ND^C,Ag	43	WT^cyt		Yang et al., 2016
N300^ECL2	A	126^C,Ant	501	WT^E	ΔLog τ_c = 0.80	Koole et al., 2012a
N300^ECL2	A	36^M,Ant	104	18%^Ant		Dods and Donnelly, 2015
N300^ECL2	A	ND^C,Ag	ND	16%^cyt		Yang et al., 2016
R299/N300^†	A/A	25^M,Ant	>3000			Mann et al., 2010a;
R299/N300^†	A/A	25^M,Ant	>3000			Donnelly, 2012
R299/N300	A/A		331		41% SB^M,Ag	Dods and Donnelly, 2015
S301^ECL2	A	WT^C,Ant	WT	63%^E		Koole et al., 2012a
N302^ECL2	A	25^C,Ant	16	WT^E	ΔLog τ_c = 0.53	Koole et al., 2012a
S301/N302^†	A/A	WT^M,Ag	WT			Mann et al., 2010a
S301/N302	A/A		WT		86% SB^M,Ag	Dods and Donnelly, 2015
N302/M303^†	V/K	WT^C,Ag	10			Moon et al., 2012
M303^ECL2	A	WT^C,Ant	WT	WT^E		Koole et al., 2012a
N304^ECL2	A	WT^C,Ant	WT	70%^E	ΔLog τ_c = 0.74	Koole et al., 2012a
N304^ECL2	A	WT^C,Ag	WT	WT^cyt		Yang et al., 2016
M303/N304^†	A/A	WT^M,Ag	WT			Mann et al., 2010a
M303/N304	A/A		WT		91% SB^M,Ag	Dods and Donnelly, 2015
Y305^5.35b	A	79^C,Ant	40	52%^E		Koole et al., 2012a
Y305^5.35b	A	WT^M,Ant	WT	22%^Ant		Dods and Donnelly, 2015
W306^5.36b	A	ND^C,Ant	ND	ND	No receptor expression	Koole et al., 2012a
W306^5.36	A	109^M,Ant	206	41%^Ant		Dods and Donnelly, 2015
W306^5.36	A	ND^C,Ag	ND	WT^cyt		Yang et al., 2016
^†Y305/W306^†	A/A	316^M,Ant	50			Mann et al., 2010a;
^†Y305/W306^†	A/A	316^M,Ant	50			Donnelly, 2012
Y305/W306	A/A		263		60% SB^M,Ag	Dods and Donnelly, 2015
L307^5.37b	A	13^C,Ant	25	47%^E		Koole et al., 2012a
L307^5.37b	A		WT		87% SB^M,Ag	Dods and Donnelly, 2015
I308^5.38b	A		WT		78% SB^M,Ag	Dods and Donnelly, 2015
L307/I308^†	A/A	251^M,Ant	6			Mann et al., 2010a;
L307/I308^†	A/A	251^M,Ant	6			Donnelly 2012
I309^5.39b	A	WT^M,Ant	WT	WT^Ant		Dods and Donnelly, 2015
R310^5.40b	A	10^M,Ant	1259	17%^Ant		Coopman et al., 2011
R310^5.40b	A	WT^M,Ant	1290	19%^Ant	ΔLog τ_c = 0.75	Dods and Donnelly, 2015
I309/R310^†	A/A	50^M,Ant	>3000			Mann et al., 2010a;
I309/R310^†	A/A	50^M,Ant	>3000			Donnelly, 2012
I309/R310	A/A		13,490		13% SB^M,Ag	Dods and Donnelly, 2015
L311/P312	A/A		WT		91% SB^M,Ag	Dods and Donnelly, 2015
A316^5.46b	T	WT^C,Ant	WT	<25%^E		Koole et al., 2011
N320^5.50b	A	18^C,Ant	10	WT^E,Ant	ΔLog τ_c = 0.50	Wootten et al., 2013c
F321^5.51b^†	A	WT^C,Ag		WT^Ag	WT cAMP 10⁻⁷ M GLP-1	Mathi et al., 1997
L322^5.52b^†	A	WT^C,Ag		WT^Ag	WT cAMP 10⁻⁷ M GLP-1	Mathi et al., 1997
I323^5.53b^†	A	WT^C,Ag		35%^Ant	WT cAMP 10⁻⁷ M GLP-1	Mathi et al., 1997
F324^5.54b^†	A	WT^C,Ag		WT^Ag	WT cAMP 10⁻⁷ M GLP-1	Mathi et al., 1997
I325/F326^†	A/A	WT^C,Ag		WT^Ag	WT cAMP 10⁻⁷ M GLP-1	Mathi et al., 1997
V327^5.57b^†	A	WT^C,Ag	15	WT^Ag	42% cAMP 10⁻⁷ M GLP-1	Mathi et al., 1997
I328^5.58b^†	A	WT^C,Ag	9	WT^Ant	39% cAMP 10⁻⁷ M GLP-1	Mathi et al., 1997
C329^5.59b^†	A	WT^C,Ag		WT^Ant	WT cAMP 10⁻⁷ M GLP-1	Mathi et al., 1997
I330^5.60b	A	WT^C,Ag		WT^Ag	WT cAMP 10⁻⁷ M GLP-1	Mathi et al., 1997
V331^5.61b^†	A	WT^C,Ag	14	WT^Ag	45% cAMP 10⁻⁷ M GLP-1	Mathi et al., 1997
I332^5.62b^†	A	WT^C,Ag		WT^Ag	WT cAMP 10⁻⁷ M GLP-1	Mathi et al., 1997
A333^5.63b^†	L	WT^C,Ag		WT^Ag	WT cAMP 10⁻⁷ M GLP-1	Mathi et al., 1997
S333^5.63b	C	WT^C,Ant	WT	<50%^E	For additional residue substiutions, see Koole et al., 2015	Koole et al., 2011
K334^5.64b^†	A	WT^C,Ag		WT^Ag	28% cAMP 10⁻⁷ M GLP-1	Takhar et al., 1996; Mathi et al., 1997
K334^5.64b^†	A	WT^C,Ag		WT^Ag	28% cAMP 10⁻⁷ M GLP-1
L335^5.65b^†	A	WT^C,Ag		WT^Ag	WT cAMP 10⁻⁷ M GLP-1	Takhar et al., 1996; Mathi et al., 1997
L335^5.65b^†	A	WT^C,Ag		WT^Ag	WT cAMP 10⁻⁷ M GLP-1
K336^5.66b^†	L	WT^C,Ag		WT^Ag	WT cAMP 10⁻⁷ M GLP-1	Takhar et al., 1996; Mathi et al., 1997
K336^5.66b^†	L	WT^C,Ag		WT^Ag	WT cAMP 10⁻⁷ M GLP-1
K334/K351	Deletions	WT^C,Ag		^Ag See paper for details		Takhar et al., 1996
C347^6.36b	A		WT			Underwood et al., 2013
R348^6.37b^†	G	12^C,Ag	ND	WT^mic		Heller et al., 1996
R348^6.37b^†	A	WT^C,Ag		WT^Ag	WT cAMP 10⁻⁷ M GLP-1	Takhar et al., 1996
L349^6.38b^†	A	WT^C,Ag		76%^Ag	WT cAMP 10⁻⁷ M GLP-1	Takhar et al., 1996
A-350^6.39b^†	E	ND^C,Ag		<10%^Ag	5% cAMP 10⁻⁷ M GLP-1	Takhar et al., 1996
A-350^6.39b^†	K	WT^C,Ag		21%^Ag	2% cAMP 10⁻⁷ M GLP-1	Takhar et al., 1996
K351^6.40b^†	A	WT^C,Ag		WT^Ag	WT cAMP 10⁻⁷ M GLP-1	Takhar et al., 1996
T353^6.42b	A	ND^C,Ant	22	30%^E, ND^Ant	ΔLog τ_c = 0.84	Wootten et al., 2013c
H363^6.52b	A	98^M,Ant	ND	24%^Ant		Coopman et al., 2011
H363^6.52b	A	23^C,Ant	4	59%^E, 53%^Ant	ΔLog τ_c = 1.71	Wootten et al., 2013c
E364^6.53b	A	58^M,Ant	15	42%^Ant		Coopman et al., 2011
E364^6.53b	A	25^C,Ant		51%^E,Ant	ΔLog τ_c = 0.66	Wootten et al., 2016
E364^6.53b	A	ND^C,Ag	ND	6%^cyt		Yang et al., 2016
E364^6.53b	Q	WT^C,Ag	WT	42%^cyt		Yang et al., 2016
E364^6.53b	Q	0.2^C,Ant	WT	42%^cyt		Yang et al., 2016
E364/E387	N/Q	ND^C,Ag	ND	WT^cyt		Yang et al., 2016
E364^6.53b	Y	WT^C,Ag	WT	WT^cyt		Yang et al., 2016
E364^6.53b	D	WT^C,Ag	WT	53%^cyt		Yang et al., 2016
F367^6.56b	A	ND^C,Ag	72	WT^cyt		Yang et al., 2016
F367^6.56b	A	32^C,Ant	72	WT^cyt		Yang et al., 2016
F367^6.56b	I	ND^C,Ag	20	WT^cyt		Yang et al., 2016
F367^6.56b	H	7^C,Ag	131	WT^cyt		Yang et al., 2016
M371^ECL3	A	WT ^M,Ant	WT	54%^Ant		Dods and Donnelly, 2015
D372^ECL3	A	WT ^M,Ant	59	13%^Ant		Dods and Donnelly, 2015
E373^ECL3	A	WT^M,Ant	WT	28%^Ant		Dods and Donnelly, 2015
H374^ECL3	A	WT^M,Ant	WT	22%^Ant		Dods and Donnelly, 2015
H374^ECL3	A	WT^C,Ag	WT	WT^cyt		Yang et al., 2016
A-375^ECL3	A	10^M,Ant	WT	WT^Ant		Dods and Donnelly, 2015
R376^ECL3	G	WT^M,Ant	WT	WT^Ant		Dods and Donnelly, 2015
R376^ECL3	Q	WT^C,Ag	WT	WT^cyt		Yang et al., 2016
G377^ECL3	A	WT^M,Ant	WT	19%^Ant		Dods and Donnelly, 2015
T378^7.32b	A	WT^M,Ant	WT	12%^Ant		Dods and Donnelly, 2015
L379^7.33b	R	12^C,Ag	141	WT^Ag		Moon et al., 2015
L379^7.33b	E	11^C,Ag	165	WT^Ag		Moon et al., 2015
L379^7.33b	A	WT^M,Ant	WT	31%^Ant		Dods and Donnelly, 2015
R380^7.34b	D	21^C,Ag	1853	WT^Ag		Moon et al., 2015
R380^7.34b	G	4^C,Ag	40	WT^Ag		Moon et al., 2015
R380^7.34b	A	128^M,Ant	263	68%^Ant		Dods and Donnelly, 2015
R380^7.34b	Q	ND^C,Ag	ND	WT^cyt		Yang et al., 2016
F381^7.35b	R	WT ^C,Ag	WT	WT^Ag		Moon et al., 2015
F381^7.35b	E	>200^C,Ag	234	WT^Ag		Moon et al., 2015
F381^7.35b	A	WT^M,Ant	WT	16%^Ant		Dods and Donnelly, 2015
F381^7.35b	S	WT^C,Ag	WT	WT^cyt		Yang et al., 2016
I382^7.36b	A	WT^M,Ant	WT	23%^Ant		Dods and Donnelly, 2015
K383^7.37b	A	WT^M,Ant	56	WT^Ant	ΔLog τ_c = 1.18	Dods and Donnelly, 2015
L384^7.38b	A	WT^M,Ant	WT	WT^Ant		Dods and Donnelly, 2015
L384^7.38b	A	ND^C,Ag	41	WT^cyt		Yang et al., 2016
L384^7.38b	A	48^C,Ant	41	WT^cyt		Yang et al., 2016
L384^7.38b	V	ND^C,Ag	16	WT^cyt		Yang et al., 2016
F385^7.40b	A	WT^M,Ant	WT	WT^Ant		Dods and Donnelly, 2015
T386^7.41b	A	WT^M,Ant	WT	18%^Ant		Dods and Donnelly, 2015
E387^7.42b	A	WT^M,Ant	WT	43%^Ant	ΔLog τ_c = 0.52	Dods and Donnelly, 2015
E387^7.42b	A	WT^M,Ant	WT	WT^Ant		Coopman et al., 2011
E387^7.42b	D	13^C,Ag	10	WT^cyt		Yang et al., 2016
E387^7.42b	D	12^C,Ant	10	WT^cyt		Yang et al., 2016
E387^7.42b	N	WT^C,Ag	WT	WT^cyt		Yang et al., 2016
L388^7.43b	A	ND^C,Ag	208	WT^cyt		Yang et al., 2016
L388^7.43b	I	5^C,Ag	81	WT^cyt		Yang et al., 2016
L388^7.43b	F	WT^C,Ag	WT	WT^cyt		Yang et al., 2016
T391^7.44b	A	WT^M,Ant	WT	64%^M,Ant		Coopman et al., 2011
T391^7.44b	A		WT	WT^Ag		Underwood et al., 2011
S392^7.47b	A	WT^C,Ant	WT	WT^E, ^Ant		Wootten et al., 2013c
Q394^7.49b	A	WT^C,Ant	WT	WT^E, ^Ant		Wootten et al., 2013c
Q394^7.49b	N	WT^C,Ant		WT^E,Ant		Wootten et al., 2016
M397^7.52b	L	WT^C,Ag	WT			Dong et al., 2012
Y402^7.57b	A	ND^C,Ant	10	21%^E, ND^Ant	ΔLog τ_c = 1.59	Wootten et al., 2013c
C403^7.58b	A		5.4			Underwood et al., 2013
N406^7.61b	A	WT^C,Ant	WT	WT^E,Ant		Wootten et al., 2013c
R421^CTT	Q	WT^C,Ant	WT	<50%^E		Koole et al., 2011
C438 ^CTT	A		WT			Underwood et al., 2013
C458 ^CTT	A		WT			Underwood et al., 2013
C462 ^CTT	A		WT			Underwood et al., 2013

CTT, C-terminal tail; SB, specific binding of radiolabeled ligand; WB, Western blotting.
↵^† Note that potency changes can be due to changes in affinity, efficacy, and/or cell surface expression, and hence should be interpreted with caution, especially when either the affinity and/or expression levels are not known.
↵* Also included in double mutations.