Here we utilize a novel, well-characterized, endogenous mitochondrial mutation in the ATP6 gene of Drosophila melanogaster with a nearly complete loss of ATP synthase activity. These Drosophila mutants have a missense mutation in ATP6 (G to A transition resulting in a glycine to glutamate change at position 116 in the protein), the mitochondrial gene encoding subunit 6 of the F₁F_o-ATP synthase(complex V of the respiratory chain. ATP6 allows for the hydrogen ion translocation required for the rotation of the F_o motor and the production of ATP from ADP. Drosophila ATP6¹ mutants model human mitochondrial encephalomyopathy and demonstrate phenotypes associated with degenerative disease, including: reduced longevity, mitochondrial pathology, progressive neural dysfunction, tissue degeneration and locomotor impairment.

ATP6¹ Drosophila mutants exhibit a stereotyped phenotypic progression that is analogous to the symptomatic progression reported for many human mitochondrial disease patients. ATP6¹ mutant flies demonstrate stress sensitivity, shortened lifespan, muscle degeneration and abnormal mitochondrial morphology. ATP6¹ animals come out of the pupal case looking and acting completely normal and are morphologically and behaviorally indistinguishable from wildtype animals. ATP6¹ animals exhibit a stereotypical progression of disease following onset (~day 8) when the animals begin to have reduced locomotor activity. By day 13, ATP6¹ animals are sensitive to mechanical stress resulting in paralysis, suggesting neuromuscular impairment. At ~day 20, ATP6¹ animals can be observed having sporadic and unprovoked seizure-like activity. Late in pathogenesis ATP6¹ phenotypes continue to worsen until their premature death.

We discovered that ATP6¹ animals have a similar developmental survival rate as wildtype animals whether they are raised at 22°C or 29°C (Figure 1C). Interestingly, ATP6¹ animals show a modest but significant shortening in the time of development during the larval and pupal stages at 22°C and during the larval stage at 29°C (Figure 1D). Additionally, ATP6¹ females lay significantly more eggs than wildtype animals during their first week of life (Figure 1E). These data demonstrate that the altered physiology of ATP6¹ animals results in an accelerated development and increase in female fecundity. Such effects could cause increase utilization of energy early in life to ensure survival despite the dramatically altered physiology.

To examine the seizure behavior we asked whether sensory hyperstimulation, such as a strobe light, could elicit seizure behavior in ATP61 flies. Video analysis of locomotor function prior to, during, and following 1450 fpm (flashes per minute) strobelighting (20 seconds) was used to examine the ability to induce seizure behavior by sensory hyperstimulation alone. Although strobe lighting did not affect the locomotion of wildtype flies, ATP61 animals exhibited convulsive behavior with a high penetrance both during and after the strobe light. Surprisingly, the convulsive behavior was followed by full paralysis that continued well after resumption of normal lighting (Figure 1F). This phenotype was also progressive, as young animals did not exhibit convulsions or paralysis (Figure 1F).

Which is a phenotype associated with mutations in ATP synthase?

Figure 1.jpg

longer than normal lifespan

sterility

increased locomotor activity, especially as aging progresses

faster than normal larval and pupal development

Question

Here we utilize a novel, well-characterized, endogenous mitochondrial mutation in the ATP6 gene of Drosophila melanogaster with a nearly complete loss of ATP synthase activity. These Drosophila mutants have a missense mutation in ATP6 (G to A transition resulting in a glycine to glutamate change at position 116 in the protein), the mitochondrial gene encoding subunit 6 of the F₁F_o-ATP synthase(complex V of the respiratory chain. ATP6 allows for the hydrogen ion translocation required for the rotation of the F_o motor and the production of ATP from ADP. Drosophila ATP6¹ mutants model human mitochondrial encephalomyopathy and demonstrate phenotypes associated with degenerative disease, including: reduced longevity, mitochondrial pathology, progressive neural dysfunction, tissue degeneration and locomotor impairment.

ATP6¹ Drosophila mutants exhibit a stereotyped phenotypic progression that is analogous to the symptomatic progression reported for many human mitochondrial disease patients. ATP6¹ mutant flies demonstrate stress sensitivity, shortened lifespan, muscle degeneration and abnormal mitochondrial morphology. ATP6¹ animals come out of the pupal case looking and acting completely normal and are morphologically and behaviorally indistinguishable from wildtype animals. ATP6¹ animals exhibit a stereotypical progression of disease following onset (~day 8) when the animals begin to have reduced locomotor activity. By day 13, ATP6¹ animals are sensitive to mechanical stress resulting in paralysis, suggesting neuromuscular impairment. At ~day 20, ATP6¹ animals can be observed having sporadic and unprovoked seizure-like activity. Late in pathogenesis ATP6¹ phenotypes continue to worsen until their premature death.

We discovered that ATP6¹ animals have a similar developmental survival rate as wildtype animals whether they are raised at 22°C or 29°C (Figure 1C). Interestingly, ATP6¹ animals show a modest but significant shortening in the time of development during the larval and pupal stages at 22°C and during the larval stage at 29°C (Figure 1D). Additionally, ATP6¹ females lay significantly more eggs than wildtype animals during their first week of life (Figure 1E). These data demonstrate that the altered physiology of ATP6¹ animals results in an accelerated development and increase in female fecundity. Such effects could cause increase utilization of energy early in life to ensure survival despite the dramatically altered physiology.

To examine the seizure behavior we asked whether sensory hyperstimulation, such as a strobe light, could elicit seizure behavior in ATP61 flies. Video analysis of locomotor function prior to, during, and following 1450 fpm (flashes per minute) strobelighting (20 seconds) was used to examine the ability to induce seizure behavior by sensory hyperstimulation alone. Although strobe lighting did not affect the locomotion of wildtype flies, ATP61 animals exhibited convulsive behavior with a high penetrance both during and after the strobe light. Surprisingly, the convulsive behavior was followed by full paralysis that continued well after resumption of normal lighting (Figure 1F). This phenotype was also progressive, as young animals did not exhibit convulsions or paralysis (Figure 1F).

Which is a phenotype associated with mutations in ATP synthase?

Figure 1.jpg

		longer than normal lifespan
		sterility
		increased locomotor activity, especially as aging progresses
		faster than normal larval and pupal development

Accepted Answer

The mutation is the random change in the genome of an organism.

Which is a phenotype associated with mutations in ATP synthase? Figure 1.jpg longer than normal lifespan sterility increased locomotor activity, especially as aging progresses faster than normal larval and pupal development