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Extended Life-Span and Stress Resistance in Drosophila

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Extended Life-Span and Stress Resistance in Drosophila Lin, Seroude, Benzer Objective Find genes in fruit flies that extend lifespan. Method This study performed a ... – PowerPoint PPT presentation

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Title: Extended Life-Span and Stress Resistance in Drosophila


1
Extended Life-Span and Stress Resistance in
Drosophila
  • Lin, Seroude, Benzer

2
Objective
  • Find genes in fruit flies that extend lifespan.

3
Method
  • This study performed a screen for gene mutations
    that extend lifespan in flies.
  • Insert P-elements that disrupt gene function
  • Recover long-lived mutants
  • Determine which gene the P-element affected.

4
  • Methuselah gene was isolated
  • Mutant methuselah (mth) flies outlived parent
    strain by 35.
  • Mth mutants also have increased resistance to
    stress
  • starvation
  • high temp
  • paraquat

5
Mth subjected to stress
  • Paraquat induces free radicals
  • mth was resistant to dietary paraquat.
  • Normal males with a concentration of 20mM are
  • sluggish after 12hrs.
  • 90 dead after 48hrs.
  • Mth mutant males at same concentration are
  • active after 12hrs.
  • 50 alive after 48hrs.
  • Longevity and paraquat resistance are associated.

6
Starvation
  • Mth had a 50 increase in survival time of the
    parent strain in the starvation test.
  • Females were more resistant than males.
  • Larger body weight may help.
  • In fact, mth mutants outweighed the parent strain
    by 20-30.

7
Temperature
  • 1.Mth survived longer at 36C than parent strain.
  • mth appear to have higher expression of heat
    shock proteins and chaperones
  • Note daf-2 and age-1 worms had a higher
    resistance to heat than control worms.

8
What is the Methuselah gene?
  • mth appears to be a G Protein Coupled Receptors
    (GPCR) involved in stress response and biological
    aging.
  • GPCRs are involved in an array of activities
  • neurotransmission
  • hormone physiology
  • drug response
  • transduction of stimuli (light and odorants)

9
Extended Lifespan Conferred by Cotransporter Gene
Mutation in Drosphila
  • Rogina, Reenan, Nilsen, Helfand

10
Methods
  • Induced mutations in flies
  • Identified long-lived mutations
  • Isolated gene responsible
  • Im Not Dead Yet (INDY)

11
Test in other fly strains
  • Indy mutations were crossed into several other
    stocks that were isolated 20-30 yrs ago.
  • Results showed an extension of lifespan of
    40-80. (only 15 in Luckinbill stock)
  • So Indy extends life directly.
  • Note Indy even extended lifespan of selected
    long lived lines by a small margin

12
Fertility
  • Need to confirm that lifespan extention not
    caused by a drop in fertility.
  • Compared to control flies, Indy flies were normal
    or superior in fertility

13
Activity
  • Need to confirm that lifespan extention not
    caused by a drop in physical activity.
  • No significant differences were found in
  • flight
  • courtship
  • feeding behavior
  • No differences found between Indy and Controls in
    early life.
  • Indy maintained behavioral and locomotor
    activities at high levels for much longer.

14
  • When Indy is mildly reduced it extends lifespan.
  • A further reduction leads to less dramatic
    extension. (additional 10-20 increase)
  • Created flies with a single copy of Indy and no
    normal copy
  • Indy activity was reduced.
  • Lifespan was shortened 10-20.

15
  • Indy appears to be involved in intermediary
    metabolism and may represent a new class of
    longevity gene.
  • The genetically induced reduction of dicarboxylic
    acid cotransporter in the Indy mutants may be
    creating a state similar to CR.

16
A Mutant Drosophila Insulin Receptor Homolog that
Extends Lifespan and Impairs Neuroendocrine
Function
  • Tatar, Kopelman, Epstein

17
  • The gene InR is an insulin-like receptor in fruit
    flies.
  • It is homologous to insulin receptors in mammals
    and to daf-2 in worms.
  • Studied InR gene variants (alleles) in flies

18
Various allele combinations produce different
results
  • Some had a reduced survival rate
  • Females in one type extended life span by 85
  • Males followed the female pattern in most cases
  • Not all the InR alleles extend longevity because
    the gene is highly variable.
  • Some alleles produced developmental defects that
    carry over into adults.

19
Conclusions
  • Specific mutations in the Insulin Receptor InR in
    flies extend lifespan up to 85.
  • The similarities in phenotype suggest that
    insulin signaling may be central to a common
    mechanism in several species.
  • Certainly insulin signaling has an effect on
    neuroendocrine regulation of metabolism and the
    reproductive state and their associated affects
    on aging.

20
IGF-1 receptor regulates lifespan and resistance
to oxidative stress in mice
  • Holzenberger, M. et al.

21
Background
  • Insulin and insulin-like signaling molecules have
    been linked to longevity in nematode worms and in
    fruit flys (Drosophila melanogaster). These
    molecules include daf-2 and the insulin receptor
    InR. Mutations that inactivate the protein Chico,
    which acts downstream of InR, also extend
    lifespan.

22
  • Most long-lived daf-2 and InR mutants are also
    dwarfs with low fertility, but some long-lived
    InR mutants have normal size and fertility,
    indicating that longevity may be regulated
    independently of body size and fertility.
  • daf-2 and InR are structural homologs of a family
    of vertebrate receptors that includes the insulin
    receptor and the insulin-like growth-factor
    type-1 receptor (IGF-1R).

23
  • In vertebrates, the insulin receptor regulates
    glucose metabolism, while IGF-1R promotes growth.
    IGF-1R is activated by its ligand IGF-1, which is
    secreted in response to growth hormone.
  • While is has been demonstrated that the InR
    family of proteins regulate lifespan in
    invertebrates, it is not yet clear if InR,
    IGF-1R, or both regulate lifespan in vertebrates.

24
  • In mice, inactivation of the growth hormone
    receptor decreases circulating IGF-1, impairs
    growth development, and increases lifespan.
  • Calorie restriction, the only intervention
    demonstrated to reliably and consistently
    increase mammalian lifespan, always reduces
    circulating IGF-1.

25
  • Oxidative stress causes aging. Mouse and fly
    mutants that are resistant to oxidative stress
    are long-lived.
  • Based on this evidence, Horzenberger et al
    decided to test the hypothesis that mammalian
    lifespan is regulated by IGF-1R, and to test the
    effects of oxidative stress on mice with altered
    IGF-1R.

26
Methods
  • Recall that most organisms have two copies of
    each gene, one inherited from each parent.
  • Using genetic engineering methods, it is possible
    to delete or otherwise alter one or both copies
    of a gene, so that the animal has either one or
    no working copy of the gene.
  • A mouse altered in this way is called a
    "knock-out" mouse.

27
  • When both copies are knocked out, it is called a
    homozygous null mutant, or a double knock-out.
  • An IGF-1R double knock-out is annotated Igf1r-/-
  • When one copy of IGF-1R is knocked out, it is
    called a single knock-out, annotated Igf1r/-.
  • Horzenberger created Igf1r-/- and Igf1r/- mice.
    The double knock-out Igf1r-/- mice did not
    survive. The single knock-out Igf1r/- mice
    survived.

28
  • The mice were fed as much as they wished to eat
    of a standard diet and kept in standard housing
    until their natural death.
  • Adult mice were treated by injection of paraquat
    to induce oxidative stress. Paraquat is a
    herbicide that induces formation of reactive
    oxygen species (ROS).

29
Results
  • The single knock-out Igf1r/- mice lived an
    average of 26 longer than wild-type mice.
  • Female Igf1r/- mice lived an average of 33
    longer than wild-type,
  • Male Igf1r/- mice lived an average of 16
    longer.

30
  • Weight at birth and during the first three weeks
    were the same as in normal (wild-type) mice.
  • After the weaning period (around 20 days) male
    Igf1r/- mice grew slightly less than normal
    mice, being about 8 smaller at 7 weeks.
  • Female Igf1r/- mice were within 6 of the weight
    of normal mice.
  • The weight differences affected all tissues and
    persisted throughout life.

31
  • The Igf1r/- mice produced half the normal amount
    of IGF-1R.
  • Serum levels of IGF-1 were elevated in adult
    Igf1r/- mice, possibly as a response to the low
    levels of the receptor.

32
The following factors were all normal in the
Igf1r/- mice
  • Food intake
  • Resting metabolic rate
  • Circadian activity
  • Body temperature (often lower in other long-lived
    mutants)
  • Non-fasting insulin levels
  • Sexual maturation and litter size

33
Resistance to free radicals
  • Adult normal and Igf1r/- mice were treated with
    paraquat to induce ROS.
  • Igf1r/- mice lived longer after paraquat
    treatment than did normal mice. The relative
    difference was greater in female than in male
    Igf1r/- mice.
  • Treated mouse embryonic fibroblast cells with
    peroxide (H2O2) to induce ROS, and found that
    Igf1r/- cells survived better than cells from
    normal mice.

34
Conclusions
  • These experiments show that a decrease in IGF-1
    receptor levels can increase lifespan in a
    mammalian species.
  • These results indicate that the link between
    insulin-like signaling and longevity observed
    among invertebrates appears to operate in higher
    vertebrates.

35
  • The magnitude of the change in lifespan is
    gender-dependent, consistent with
    gender-dependent effects seen in Drosophila and
    long-lived mouse mutants.
  • It is possible that the life-extending effects of
    calorie restriction are due to reduced levels of
    circulating IGF-1, mimicking the IGF-1R reduction
    in this experiment.

36
SOD2 Functions Downstream of Sch9 to Extend
Longevity in Yeast
  • Fabrizio, Liou, Moy

37
Molecular dissection of aging gene pathways
  • Want to identify all genes that affect aging
  • these are potential drug targets
  • find genes are "drugable"
  • Want to understand connections between genes
    (pathways), so that we can understand
  • the mode of action of the gene,
  • potential side effects of drugs that target the
    gene,
  • how the desired drug effect may be circumvented
    or blocked

38
  • This paper describes the molecular dissection of
    an aging pathway, and illustrates the methods
    used to understand molecular pathways.
  • Illustrates how seemingly negative and
    contradictory results may arise

39
Introduction
  • Yeast cells with ample nutrients typically
  • divide rapidly
  • quickly become overcrowded
  • then spend the rest of their lives in a
    stationary phase.

40
Lifespan depends on the food source
  • Yeast fed SDC (synthetic dextrose complete
    medium)
  • reach max viability in 48 hrs
  • reach max population density by 72 hrs
  • survive for about 6 days.
  • respiratory rate remains high for most of
    lifespan.

41
  • Yeast fed YPD (rich glucose medium)
  • grow rapidly (by fermentation)
  • with overcrowding
  • continue to grow in size for some time
  • decrease metabolic rate
  • decrease macromolecular synthesis by gt100 times.
  • survive for months slowly utilizing reserve
    nutrients.

42
Measure lifespan in two ways in yeast
  • chronological lifespan days of life
  • budding lifespan number of buds generated by a
    mother cell

43
Chronological lifespan in yeast is
  • shortened by
  • null mutations in either or both superoxide
    dismutases
  • extended by
  • 1. overexpression of human oncoprotein Bcl-2,
    (protects against oxidative stress)
  • 2. mutations that reduce activity of
  • adenylate cyclase (Cyr1)
  • serine threonine kinase (Sch9).

44
Cyr1 and Sch9 are genes that function in pathways
that
  • mediate glucose dependent signalling
  • stimulate growth and glycolysis
  • decrease stress resistance.

45
  • Longevity in Cyr1 and Sch9 mutants requires
    stress-resistance transcription factors
  • Msn2
  • Msn4
  • Rim 15 protease kinase.
  • Suggests that investing in protection and repair
    slows aging

46
The super-oxide sensitive enzyme aconitase
  • The age-dependent inactivation of the super-oxide
    sensitive enzyme aconitase, which is high in
    wild-type cells, is decreased in mutations that
    extend longevity.
  • Stress resistance proteins appear to have no role
    in replicative longevity (because deletion of
    stress resistant transcription factors Msn2/Msn4
    has no effect)

47
  • G-proteins Ras1 and Ras2 function upstream of
    Cyr1.
  • They have overlapping roles in
  • growth
  • stress resistance.

48
  • Msn2 Msn4 are required for longevity in Cyr1
    mutants
  • regulate genes with a stress response element
    (STRE) in their promoters.
  • Among the genes they regulate are those encoding
  • heat shock proteins
  • catalase (CTT1)
  • DNA-damage-inducing gene (DDR2)
  • genes involved in storage of nutrients.

49
  • Msn2 Msn4 may also regulate SOD.
  • SOD promoters have a stress response (STRE)
    sequence.

50
  • Fabrizio and colleagues performed several
    experiments to elucidate the molecular mechanisms
    of aging and death in yeast.
  • In particular, they looked at the role of
    superoxide dismutases in relation to mutations in
    known aging-related genes in yeast.

51
Experiments
  • To discover the molecular mechanisms of aging in
    yeast.
  • To determine the role of superoxide dismutases in
    lifespan extension caused by mutations in Sch9
    and cAMP/PKA pathway.
  • To investigate the role of proteins that function
    upstream of PKA to regulate longevity.

52
Materials and Methods
  • Yeast strains lacking RAS2, SOD2 and MSN2/MSN4.
  • SDC medium with 2 glucose supplemented with
    amino acids

53
Measurements
  • Determine number of viable cells on day 3
    measured in colony forming units (CFU).
  • Note A viable cell will reproduce and form a
    colony in 48 hrs.
  • Compare CFU to protein concentration in diet in a
    time dependent way.
  • Note Should correlate with increased cell
    damage and lysis.
  • Viability also measured by live/dead fluorescent
    assay.
  • (for stationary phase cells)
  • Determine the percentage of live cells by
    fluorescent microscopy.
  • (count red/green cells after staining with FUN-1
    dye)

54
  • Determine survival rate in the presence of
    superoxide agents.
  • (add paraquat or antimycin A to yeast cultures
    after 24 hrs.)
  • Determine survival rate in the presence of
    superoxide inhibitors.
  • (FCCP NaCN added at time zero)
  • Oxygen consumption measured.
  • Superoxide dismutase assays performed.
  • Catalase activity assays performed.

55
Experiments and Results
56
The role of Sod2 in lifespan extension
  • Transcription factors
  • Msn2/Mns4
  • Gis1 (regulated by Rim 15)
  • activate a variety of stress resistance genes
    through either
  • STRE
  • PDS element.
  • SOD2 has promoters containing both STRE PDS
    element.

57
  • Hypothesis
  • Sod2 functions downstream from Msn2/Mns4 Gis1
    to promote longevity.
  • Material
  • Created mutants with deleted SOD2 in two strains
    of yeast
  • cyr1mTn - usually long-lived
  • sch9? - usually long-lived (3fold longer lifespan
    compared to wild type)

58
Results
  • Mutants with deleted sod2 and double mutants
    sch9/sod2 survived similar to wildtype.
  • (suggests Sod2 required for usual 3fold longer
    lifespan of sch9 mutants)
  • Deletion of SOD2 decreased lifespan of cyr1mTn
    mutants.
  • (double mutants sod1/sod2 not studied-both
    suffer early mortality)
  • Found that SOD2 is expressed at high levels in
    sch9 mutants

59
An unexpected result
  • Deletion of cyr1mTn caused low levels of SOD2
    mRNA
  • The low levels of SOD2 mRNA may be explained by
    the early decrease in oxygen consumption rates
    in these mutants, since the expression of the
    mitochondrial SOD2 should decrease with the
    decrease in metabolic rate. This may also explain
    why the deletion of SOD2 did not abolish the
    lifespan extension in cyr1mTn mutants.

60
Superoxide Dismutase and Survival
  • Hypothesis
  • Superoxide dismutase plays a role in life
    extension observed in mutants
  • cyr1mTn
  • sch9?.

61
Method
  • Measure the chronological lifespan of yeast
    overexpressing antioxidant enzymes.
  • Deliberately overexpress various combinations of
  • cytosolic Sod1
  • mitochondrial Sod2
  • cytosolic catalase T (CTT1).

62
Results
  • Activity in both Sod1 Sod2 increased 3fold in
    SOD1/SOD2 over-expressors.
  • Activity of catalase increased 3fold in catalase
    expressors.
  • Mean chronological lifespan for SOD1/SOD2 double
    over-expressors increased 33.
  • Double overexpression of SOD1 and CTT1 resulted
    in 10 lifespan extension.
  • Over-expression of SOD1 or SOD2 alone resulted in
    minor increase in mean survival.
  • Over-expression of cytosolic catalase alone
    slightly decreased survival.

63
In the SP1 background
  • CuZnDos, MnSod, and catalase T over-expressed.
  • Over-expression of SOD1 and SOD2 was modest with
    10 extension of mean survival.
  • Single over-expression of either SOD1 or SOD2
    caused no significant survival.
  • So the results depend on the strain of yeast used
    (depends on genetic background)

64
  • Treated wildtype yeast with
  • FCCP or NaCN
  • which reduce mitochondrial superoxide generation
    in mammals.
  • Treatment with these superoxide inhibitors
    increased survival of the wildtype yeast.

65
Survival of Ras Mutants
  • In yeast, Ras1 and Ras2 activate Cyr1, which
    promotes aging and death.
  • Measured the lifespan of Ras1 and Ras2 deletion
    mutants.
  • deletion of Ras1 slightly decreased survival
  • deletion of Ras2 doubled survival.

66
To confirm role of Ras2 in longevity
  • Tested strains carrying temperature sensitive
    mutations in the Ras pathway.
  • (lacking RAS1 and with temp sensitive mutation
    in RAS2)
  • Again, survival was doubled.

67
Conversely
  • mutants with constitutionally active Ras2 died
    early
  • mutant with constitutionally active PKA (bcy1)
    lived 2 instead of 6 days.
  • Suggests a pathway that includes
  • Ras2
  • Cyr1
  • PKA
  • regulates chronological lifespan.

68
Ras2, Msn2/Msn4, and SOD2
  • Test whether ras2 mutants are resistant to
    oxidative stress during aging.
  • Treated mutant strains with superoxide generating
    agent paraquat.
  • After 7 days of treatment
  • Ras2 mutants gt70 viable
  • Wildtype 5 viable

69
  • Test the role of stress-resistance genes in
    extended longevity of ras2 mutants.
  • Deleted transcription factors Msn2 and Msn4 in
    ras2 mutants.
  • The life extension of ras2 was abolished.
  • So Msn2 and Msn4 do mediate longevity extension.
  • Suggests Ras2 and Cyr1 function in the same
    pathway to
  • regulate stress resistance
  • promote senescence.

70
  • Test if superoxide dismutases function downstream
    of Ras2/PKA/Msn2/Msn4 pathway.
  • Deleted SOD2 in ras2 mutants.
  • Found
  • lifespan of ras2?sod2? mutants was shortened
  • but they outlived wildtype by 30.
  • Confirms that the induction of other systems is
    important in survival extension.

71
  • Test if increasing superoxide protection extends
    extra lifespan of ras2? mutants.
  • Over-expressed (ox) both SOD1 and SOD2 in ras2
    mutants.
  • Found
  • ras2?SOD1oxSOD2ox mutants marginally outlived
    ras2? mutants.
  • Indicates that ras2? mutants have optimized their
    protection against superoxide toxicity.

72
  • Again, the results of the experiment depend on
    the particular genetic background of the yeast
    strain, and on the particular intervention
    intended to affect aging.

73
Age-dependent Metabolic Rates
  • Test if survival extension is a result of early
    metabolic decrease.
  • Measured oxygen consumption in longlived
    mutants.
  • In wildtype respiration is
  • low when cells actively growing
  • remained high until day 5 or 6.
  • In sch9? mutants the age-dependent rates were the
    same as wildtype.
  • In ras2? and cyr1mTn mutants metabolic rates
    decreased 48 hours earlier.

74
  • However, in ras2? mutants in the SP1 background
    rates were the same as wildtype.
  • No significant effects were found for
    over-expression of
  • SOD1 SOD2
  • SOD1 CTT1.
  • Suggests that an early decrease in age-specific
    metabolic rate is
  • associated with certain mutations that extend
    survival
  • but not required for longevity extension.

75
Discussion
  • Expression of mitochondrial SOD2 is required for
    extended longevity in yeast.
  • Expression can be caused by mutations that
    decrease the activity of
  • Ras/Cyr1/PKA pathway
  • and Sch9 pathway.
  • Superoxide toxicity definitely plays a role in
    yeast aging and death.
  • Yet, SOD2 over-expression is not sufficient for
    maximum survival.

76
  • Studies show that genes regulated by
  • stress resistance transcription factors
  • kinases (Msn2, Msn4, Rim15)
  • also mediate chronological lifespan.

77
  • Extended longevity achieved in single mutants by
    inducing SOD2 expression.
  • The double expression of SOD1 SOD2 extends
    survival by 30.
  • No other mutation achieved this.

78
  • In longlived mutants the superoxide
    inactivation/reactivation of aconitase is lower
    than wildtype.
  • Suggests superoxide promotes aging by
  • decreasing activity of an essential enzyme
  • leads to generation of highly reactive free
    radicals.

79
  • Paraquat and antyimycin A
  • promote damage to mitochondria
  • reduced lifespan.
  • They lead to the production of superoxides that
    are
  • highly toxic to sod2 mutants
  • decrease survival of wildtype.

80
  • Mutations that cause respiratory deficiency also
    cause early death.
  • This is consistent with aging and death due to
    mitochondrial
  • superoxide levels
  • loss of function.

81
Other systems are involved.
  • Sod2 is required for survival extension.
  • It is not the only factor involved.

82
  • For example
  • the over-expression of
  • SOD1
  • SOD2
  • has a smaller effect on lifespan than
  • ras2
  • sch9.

83
  • Another example
  • ras2 and cyr1mTn mutants lacking SOD2
  • survive for shorter time than single mutants
  • but survive longer than wildtype.

84
Yeast vs higher organisms
  • There is a similarity in
  • genes
  • pathways
  • between yeast and higher eukaryotes

85
In yeast
  • Downregulating glucose signaling by
  • ras2
  • cyr1
  • sch9
  • leads to
  • increased longevity
  • resistance to oxidative stress
  • resistance to heat shock.

86
  • In cyr1 mutants chronological lifespan mediated
    by stress resistance transcription factors
  • Msn2
  • Msn4.
  • These factors induce the expression of genes
    encoding for
  • heat shock proteins
  • catalase
  • DNA-damage inducing gene DDR2
  • SOD2.

87
In worms
  • signal transduction genes
  • age-1
  • daf-2
  • work through stress resistance factor DAF-16 to
  • extend survival 65-100
  • increase thermotolerance
  • increase antioxidant defense.

88
  • In yeast, chronological lifespan linked to
    mitochondrial
  • superoxide generation
  • Sod2.
  • In worms the daf-2 pathway regulates
  • heat shock proteins
  • mitochondrial SOD.

89
  • In yeast the Ras/Cyr1/PKA pathway downregulates
  • glycogen storage
  • genes inducing diauxic shift.(hypometabolic)
  • In worms the daf-2 pathways regulate
  • storage of reserve nutrients (fat glycogen)
  • switch to dauer state. (hypometabolic)

90
  • So yeast and worms regulate
  • stress resistance
  • longevity
  • by modulating the activity of similar proteins
    and pathways.
  • Analogous pathways in fruit flies and mice
    regulate
  • stress resistance
  • aging.

91
Conclusions
  • Evidence exists for prosenescence pathways
  • activated by glucose (and other nutrients)
  • downregulated by starvation.

92
  • The pathways include
  • Ras2/Cyr1/PKA
  • Sch9.
  • They downregulate stress resistance transcription
    factors
  • Msn2
  • Msn4
  • Gis1.
  • This results in the downregulation of many stress
    resistance genes including SOD2.

93
  • In old yeast the combination of
  • high respiration rate
  • low protection from superoxides
  • leads to
  • inactivation of aconitase
  • mitochondrial damage
  • leads to death.

94
  • Negative or contradictory results may arise when
    experiments are performed on animals with
    different genetic backgrounds.
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