Mitochondrial DNA (mtDNA) often exists in a state of heteroplasmy, in which mutant mtDNA co-exists in cells with wild-type mtDNA. High frequencies of pathogenic mtDNA result in maternally inherited diseases; maternally and somatically acquired mutations also accumulate over time and contribute to diseases of ageing. Reducing heteroplasmy is therefore a therapeutic goal and in vivo models in post-mitotic tissues are needed to facilitate these studies. Here we describe a transgene-based model of a heteroplasmic lethal mtDNA deletion (mtDNA^Δ) in adult Drosophila muscle. Stimulation of autophagy, activation of the PINK1/parkin pathway or decreased levels of mitofusin result in a selective decrease in mtDNA^Δ. Decreased levels of mitofusin and increased levels of ATPIF1, an inhibitor of ATP synthase reversal-dependent mitochondrial repolarization, result in a further decrease in mtDNA^Δ levels. These results show that an adult post-mitotic tissue can be cleansed of a deleterious genome, suggesting that therapeutic removal of mutant mtDNA can be achieved

Guo, Ming

Hay, Bruce A.

Kandul, Nikolay P.

Zhang, Ting

PubMed

Caltech Authors - Main

	 
 
Supplementary Figure 1. tpRCA detects mtDNA∆ in indirect flight muscle (IFM) of 
mitoAflIII flies. a1-2, Red and green dots are observed only in the IFMs, in which mitoAflIII 
and mitoT4 DNA ligase are expressed, but not in the neighboring jump muscle,  
b1-2. The IFMs and jump muscle have very different structures, and can be easily 
differentiated at the level of light microscopy. Scale bar is 10 µm (b).  
Supp Figure 2A
b1a1
Indirect
flight
muscle
Jump
muscle
a2 b2
Jump
muscle
Indirect
flight
muscle
	  
 
 
 
 
 
 
Supplementary Figure 2. mitoAflIII flies display no defect in flight performance. A 
flight assay1-5 was used to compare flight performance between mitoAflIII (grey bars) and 
wildtype (white bars) ten-day-old male flies. Five groups of 30–50 flies of each type were 
introduced into the top of a 500-mL graduated cylinder whose internal walls were coated 
with paraffin oil. Wildtype flies quickly initiate horizontal flight, striking the wall close to the 
entry level, whereas poor fliers land at lower levels or at the bottom of the cylinder. 
Statistical significance was calculated with respect to percentage of total flies of each type 
that landed at each height using Student’s t-test with unequal variance. Bars depict mean + 
one standard deviation. P>0.05(ns).    
0%
10%
20%
30%
40%
50%
Landing Height
Pe
rc
en
ta
ge
 o
f f
lie
s i
n 
ea
ch
 re
pli
ca
te
50 12111098764321
mtDNA∆ –
mtDNA∆ +
ns
ns ns
ns
ns
ns
ns ns
ns
	 
 
 
 
Supplementary Figure 3. Atg1 and Atg8A RNAi (KD) using pIFM-Gal4. Relative 
percentages of Atg1 and Atg8a mRNAs in the pIFM-Gal4 >>pUASt-RNAi flies (grey) are 
normalized to those in the pIFM-Gal4 flies (white). Bars indicate mean ± one standard 
deviations. Statistical significance was calculated using Student’s t-test with unequal 
variance. P<0.01** and P<0.0001***. 
  
0%
25%
50%
75%
100%
Atg1 KD Atg8a KD
m
RN
A 
re
lat
ive
 a
du
nd
an
ce
** ***
	 
 
 
 
 
 
 
Supplementary Figure 4. Drosophila Atg8a and Atg8b transcript analysis in Atg8a 
mutant flies. Drosophila has two paralogs of yeast Atg8. a, Reverse transcription (RT) PCR 
analysis shows that Atg8a is expressed throughout male flies (heads, thoraces, and 
abdomens), whereas Atg8b transcripts are found only in male abdomens, reflecting 
expression in the testis (FlyBase.org)6. b, A P element insertion in the coding region of 
Atg8a (P{SUPor-P}Atg8aKG07569, referred here as Atg8a mutant) causes a massive reduction 
in the level of Atg8a mRNA in the entire fly body. The mRNA abundance of Atg8b is not 
affected in Atg8a mutant males. 
  
b
SSIII: +  –  +  –  
Atg8a           Atg8b
500 bp
100 bp
300 bp
sample    +   NTC
+  –  +  –  
sample    +   NTCAtg8a mutant:
Atg8a Atg8b
heads & thoraces:
abdomens:
SSIII: +  –  +  – NTC
+  +  –  – NTC
–  –  +  + NTC 
+  –  +  – NTC
+  +  –  – NTC 
–  –  +  + NTC 
500 bp
100 bp
300 bp
a
	 
 
 
 
 
Supplementary Figure 5. Rapamycin feeding results in decreased mtDNA∆ 
abundance in mitoAflIII flies. Relative abundances of total mtDNA (green) and mtDNA∆ 
(red and blue) in flies fed on food supplemented with 200µM rapamycin  were estimated 
using qPCR and normalized to those present in control mitoAflIII flies (grey). Colored bars 
indicate mean ± one standard deviations. Statistical significance is estimated as compared 
with the corresponding estimate in control flies using Student’s t-test with unequal variance. 
P>0.05(ns), P<0.05*, and P<0.01**. 
 
  
0%
50%
100%
Re
lat
ive
 p
er
ce
nt
ag
e 
mtDNA  ∆
totalmtDNA
mtDNA  ∆
nucDNA  
mtDNA  total
nucDNA  
** *
ns
	Supplementary Table 1. Insertions and their frequencies at the post-cleavage AflIII 
ligation site in mtDNA∆ 
5′-GTATTTACTTA         2580bp     CATGTTTTTGTTAAA-3′ 
3′-CATAAATGAATGTAC     2580bp         AAAAACAATTT-5′ 
sequence at the ligated post-cleavage site Insertion size 
(bp) 
frequency 
5′-GTATTTACTTAcatgCATGTTTTTGTTAAA-3′ 4 6/20 
5′-GTATTTACTTAcat CATGTTTTTGTTAAA-3′ 3 6/20 
5′-GTATTTACTTAcatg ATGTTTTTGTTAAA-3′ 3 5/20 
5′-GTATTTACTTAc   CATGTTTTTGTTAAA-3′ 1 2/20 
5′-GTATTTACTTA    CATGTTTTTGTTAAA-3′ 0 1/20 
Two primers flanking both AflIII sites amplify a fragment that spans mtDNA∆ deletion from mitoAflIII flies. 
Because direct sequencing of PCR products resulted in an ambiguity at the ligated post-cleavage AflIII 
site, the fragment was cloned, and 20 clones were sequenced. The sequence at the top depicts double 
stranded sequences generated after cleavage at both AflIII sites, with the AflIII site indicated in blue. 
Sequences isolated through PCR and cloning, along with their frequency are indicated. Bases inserted at 
the ligation sites are shown in red. 
  
	 8 
Supplementary Table 2. Viability of progeny from cross between pUASt-mitoT4lig 
lines and Gal4 drivers 
Gal4 driver P{pUASt-
mitoT4lig}attP1 
P{pUASt-mitoT4lig,pUASt-
mitoAflIII}attP1 
da-Gal4 viable lethal 
elav-Gal4 viable lethal 
mef2-Gal4 viable lethal 
ey-Gal4 viable lethal 
r4-Gal4 viable lethal 
Expression of mitoT4lig driven by five Gal4 drivers did not cause observable defects in Drosophila. In 
contrast, co-expression with mitoAflIII resulted in lethality early in development. 
 
	Supplementary Table 3. Amounts of total mtDNA and mtDNA∆ in IFMs estimated with qPCR and tpRCA 
 
qPCR, mtDNAall/3R:tub qPCR, mtDNA∆/mtDNAtotal qPCR, mtDNA∆/3R:tub tpRCA, mtDNA∆/mtDNAtotal 
Genetic 
background 
Sample 
number Mean %  Std Dev  
Std Err 
Mean Mean % Std Dev 
Std Err 
Mean Mean % Std Dev 
Std Err 
Mean 
Sample 
number Mean % Std Dev 
Std Err 
Mean 
mitoAflIII 6 94.18 5.33 2.18 75.63 1.19 0.38 77.62 0.87 0.35 22 72.32 10.93 2.33 
Atg1 KD 4 90.41 3.13 1.57 82.05 2.18 1.09 83.20 1.75 0.87 23 93.48 17.76 3.70 
Atg8a KD 4 84.27 12.40 6.20 89.41 0.71 0.35 89.74 2.00 1.00 23 90.15 18.05 3.77 
Atg8a mutant 5 91.64 6.47 2.89 89.40 2.17 0.97 91.31 3.23 1.44 21 95.95 15.42 3.37 
Atg1(6B) OE 4 94.40 1.04 0.52 3.82 0.79 0.39 4.29 0.54 0.27 22 2.66 1.17 0.25 
Atg8a OE 4 90.41 3.40 1.70 66.92 3.08 1.54 66.91 3.48 1.74 26 70.12 15.04 2.95 
Parkin OE 4 76.48 4.73 2.37 5.08 0.32 0.16 4.26 0.32 0.16 22 2.47 1.14 0.24 
PINK1 OE 4 91.34 5.51 2.75 26.24 2.67 1.33 27.49 0.70 0.35 24 16.19 4.91 1.00 
Parkin OE in 
Atg8a mutant 
4 92.25 2.32 1.16 82.26 1.93 0.97 84.19 1.17 0.59 26 67.20 20.98 4.11 
Mfn KD 4 94.51 0.28 0.14 39.16 1.29 0.65 43.29 3.32 1.66 26 26.05 8.99 1.76 
Drp1 OE 4 94.57 0.76 0.38 88.13 1.89 0.94 90.32 1.82 0.91 28 90.85 17.86 3.37 
ATPIF1 OE 4 92.38 3.15 2.18 68.28 8.53 4.26 69.19 8.40 4.20 N/A N/A N/A N/A 
ATPIF1 OE 
in Mfn KD 
4 89.69 5.32 2.65 11.61 0.71 0.35 11.43 0.98 0.49 N/A N/A N/A N/A 
All genetic backgrounds contained P{pIFM-mitoAflIII, pIFM-mitoT4lig, pIFM-Gal4}attP1 transgene (mitoAflII), in an otherwise wildtype background (top row), or in combination with other mutations 
or transgenes supporting overexpression (OE) or knock down (KD) of a tested gene. To compare relative estimations calculated with qPCR and tpRCA on the same scale, we computed 
normalized percentages relative to mitoAflIII flies. A fold difference was calculated between relative amounts in mitoAflIII alone and in combination with a tested gene backgrounds using qPCR 
(see methods), then the fold difference was normalized to the corresponding percentage estimation in mitoAflIII flies (Fig. 2d). P-element insertion in a coding area of Atg8a (Atg8a mutant) caused 
a massive reduction in Agt8a expression and is thought to represent a strong hypomorph or null mutant (Supplementary Fig. 4)7. tpRCA was used to visualize and quantify mtDNA∆ and mtDNAtotal 
molecules in whole mounts of Drosophila IFMs. Amounts of mtDNA∆ were estimated directly from confocal images as percentage of total mtDNA (mtDNAtotal), multiplied by 3/2 (see methods for 
details). 
	Supplementary Table 4. Primers for quantification of mtDNA∆ amount with qPCR 
Name Estimate 5′- Sequence- 3′ Amplicon  
size (bp) 
mtAflIII∆ mtDNA∆ 5′-CATATTTGTCGAGACGTTAATTATGGTTG-3′ 
5′-GAATTCGGCAAAAATAATATTCGCCTG-3′ 
129 
mt:CytB mtDNAWT 5′-TAGTGTTAATCATATTTGTCGAGACGTT-3′ 
5′-ATATGAACCGTAATAAATTCCTCGTCC-3′ 
130 
mt:ND5 mtDNAtotal 5′-GAAGTAAAGCTACATCCCCAATTCG-3′ 
5′-GGTGAGATGGTTTAGGACTTGTTTC-3′ 
113 
3R:tub nuclear DNA 
(nucDNA) 
5′-TATAAGTAAAGGCAGCAGGGAGAC-3′ 
5′-ATCTGGGTACTCTTCCTCTCCATC-3′ 
121 
 
  
	Supplementary Table 5. Primers for reverse transcription (RT) qPCR 
Annotation 
number 
Gene 
symbol 
5′- Sequence- 3′ Amplicon  
size (bp) 
CG10967 Atg1 5′-CAGGAGGACGAGAACACGGTGTC-3′ 
5′-GGAAGGTTCTTTGGCACCAGCAC-3′ 
155 
CG32672 Atg8a 5′-TATCCAGACCGTGTGCCCGTC-3′ 
5′-GTGGATGCGCTTGCGAATGAGG-3′ 
136 
CG2135 βGlu 5′-TGGAGGGCATGCACTCACTTC-3′ 
5′-GGTCCGAAAATCGGCGAAGTTCC-3′ 
147 
mitoAflIII AflIII 5′-AGCTGTAGATCTAAAAGGCGGCCG-3′ 
5′-ATAGCAGCTGGCGTGGAATTGGC-3′ 
141 
 
  
	Supplementary Table 6. Padlock probes and corresponding detection probes 
Probe Estimate 5′- Sequence- 3′ 
ppMtDNAtotal mtDNAtotal 5'-P-CTTCAATATATTCATAAGCTAGTCTTGTTACGT
TTAAACCTCAACGTACTTGATTGGCTCCTTCTTAGTCA
GTCTGCAATAGTAAATGGAG-3′ 
dpMtDNAtotal–
Alexa®488 
tpRCA product  
of ppMtDNAtotal 
5'-Alexa488-CCTCAACGTACTTGATTGGCTCC-3' 
ppMtDNA∆ mtDNA∆ 5'-P-GTAATAATCAACCATAATTATCTTTCTTCGTCC
TCATTGCTGCTGCTGTACTACTAGTTCTTGTACTTACT
CACCGTTAGCATGTAAAGTTC-3′ 
dpMtDNA∆–
TAMRA 
RCA product of 
ppMtDNA∆ 
5′-TAMRA-CCTCATTGCTGCTGCTGTACTAC-3' 
The probes were purchased from Integrated DNA Technologies®. P, 5' phosphate. Target-
complementary sequences of padlock probes are underscored and tag sequence segments of padlock 
probes used for fluorescence detection are color coded.  
	Supplementary Methods 
 
qPCR quantifiction of relative amounts of mtDNA∆. To quantify the amounts of 
mtDNA∆ relative to both mtDNAtotal and nuclear DNA (nucDNA) we applied the ΔΔCt 
algorithm as follows: 
Normalizer #1 (mtDNAtotal, mt:NADH5)  Normalizer #2 (nucDNA, 3R:Tube) 
ΔCtmtDNA∆ sample = CtmtDNA∆ – CtmtDNAtotal  ΔCtmtDNA∆ sample = CtmtDNA∆ – CtnucDNA 
ΔCtmtDNA∆ reference = CtmtDNA∆ – CtmtDNAtotal  ΔCtmtDNA∆ reference = CtmtDNA∆ – CtnucDNA 
ΔΔCt = ΔCtmtDNA∆ sample – ΔCtmtDNA∆ reference  ΔΔCt = ΔCtmtDNA∆ sample – ΔCtmtDNA∆ reference 
Fold difference = 2 –∆∆Ct    Fold difference = 2 –∆∆Ct 
 
RT-qPCR quantifiction of transcript abundance. We calculated a fold difference in 
transcript number of a gene of interest (GOI) following Pfaffl8 to account for differences 
in amplification efficiencies of used primers using the following equation: 
∆CtGOI = CtGOI test – CtGOI reference 
∆CtβGlu = CtβGlu test – CtβGlu reference 
E = efficiency from a standard curve, E= 10-1/slope 
Fold difference = EGOI∆Ct(GOI) / EMlc2∆Ct(βGlu) 
  
	 
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Selective removal of deletion-bearing mitochondrial DNA in heteroplasmic Drosophila

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Selective removal of deletion-bearing mitochondrial DNA in heteroplasmic Drosophila

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