Eukaryote evolution + Mitochondria

Question 1

What innovations are currently boosting discoveries of new major groups and evolutionary relationships of eukaryotes?

Answer 1

DNA sequencing innovations such as metagenomics and single-cell genomics

Question 2

What are metagenomics?

Answer 2

when all the DNA in an environment is sequenced and genomes are pieced together

Question 3

What are single-cell genomics?

Answer 3

when single cells are isolated and genomes are sequenced from them

Question 4

T or F: most eukaryotes are multicellular

Answer 4

false, most are single-celled

Question 5

What are the major groups of eukaryotes? How many are there?

Answer 5

it’s constantly being revised

but there’s a bunch?
Ex. Archaeplastida (plants, algae) Amorphea (animals, fungi)

most are single celled protists

unknown which groups are ancestral

Question 6

What is the major message regarding the new tree of eukaryotes?

Answer 6

it’s incredibly dynamic and is always changing

Question 7

Which eukaryote branch/super group is the ancestral root?

Answer 7

we have no idea

Question 8

What new supergroup has recently been discovered? (“the lions of the microbial world”)

Answer 8

Nibbleromonas quarantinus and Nebulomonas marisrubri

two microbial predators

Question 9

How does Nibbleromonas quarantinus predate other protists?

Answer 9

by eating chunks from them

Question 10

How does Nebulomonas marisrubri predate other protists?

Answer 10

consuming the entire organism

Question 11

Where do the newly discovered Nibbleromonas quarantinus and Nebulomonas marisrubri sit in the phylogeny of eukaryotes?

Answer 11

they’re in the super group Provora

but they are a separate and diverged lineage

even the two species are extremely distinct from one another (ex. as different as humans and yeast)

Question 12

What was the first eukaryote?

Answer 12

unknown

Question 13

Did prokaryotes or eukaryotes emerge first?

Answer 13

prokaryotes

Question 14

What are some major eukaryotic genome features/innovations? (ie., differences between eukaryotes and prokaryotes)

Answer 14

nuclear membrane
organelles
cytoskeleton
introns and spliceosomes
mitosis and meiosis
larger gene number
larger cell size and cell number
etc.

Question 15

What is the most accepted evolutionary model to explain the emergence of eukaryotes?

Answer 15

symbiogenic models

Question 16

Describe the symbiogenic model and how it relates to the origin of eukaryotes

Answer 16

basically symbiosis between two prokaryotic cells to make the first eukaryotic cell

states that an “archaeal host cell” and an “alphaproteobacterial endosymbiont” merged

Question 17

How are eukaryotes related to prokaryotes?

Answer 17

prokaryotes and Archaea are closely related and then there’s a very long branch (distance) between them and eukaryotes

Question 18

T or F: eukaryotes evolved from Archaea

Answer 18

true

Question 19

Why is it now accepted that eukaryotes emerged from archaeal lineages? what does this suggest?

Answer 19

newly discovered archaea (sisters of eukaryotes) genomes have features previously believed to be eukaryote-specific -

this suggests that maybe eukaryotic ancestor is more complex - challenging previous beliefs

Question 20

Where were the archaea that are sisters of eukaryotes discovered? What kind of data was used to study these?

Answer 20

Loki’s castle, the hydrothermal vents between Norway and Greenland

metagenomic data used

Question 21

What is an example of a protein that is characteristic of eukaryotes and was found in the newly discovered Loki archaea? what does this suggest?

Answer 21

actin: a major structural protein previously though to only be in eukaryotic cells

this provides evidence that eukaryotes and archaea are related

Question 22

Up until 2020, how was Archaea studied in the labs? what changed?

Answer 22

just based on sequences

the first ‘Asgard’ archaea from deep sea vents was cultured over 13 years = it was GROWN in a lab, not just sequenced

Question 23

What is the evidence for the symbiogenic hypothesis of eukaryotic cell origin?

Answer 23

There is likely a hybrid origin of genes from Archaea and Prokaryotes but this is hard to resolve because the two groups have very different ancestries

Question 24

T or F: endosymbiosis is an incredibly important process in the evolution of eukaryotes

Answer 24

true

Question 25

What gave rise to all eukaryotes via endosymbiosis?

Answer 25

mitochondria (alphaproteobacterial origin)

Question 26

What gave rise to all photosynthetic organisms?

Answer 26

Chloroplast (cyanobacterial origin)

Question 27

What was the result of endosymbiosis?

Answer 27

the acquisition of a ton of new genes and functions (acquired an entire new organism and its entire genome)

new metabolic potential

new niches become accessible (ex. photosynthesis, respiration)

Question 28

What was the most important step in the evolution of eukaryotes?

Answer 28

acquiring the mitochondrion

Question 29

T or F: some extant eukaryotes were descended from an ancestor without a mitochondrion

Answer 29

false! all extant eukaryotes, and all eukaryotes that have ever lived (as far as we know) have descended from an ancestor with a mitochondrion

Question 30

What evidence suggests mitochondria originated from a bacterial symbiont (alphaproteobacterial origin)?

Answer 30

the mitochondrion has:

its own genetic material that is associated with bacteria

a separate genome (separate from the nuclear genome that exists in all cells) descended from bacteria
- it’s usually circular
- it’s non-recombining

features resemble ancient engulfment of a bacteria

has phylogenetic bacterial origin

Question 31

T or F: the mitochondrion has a separate genome from the nuclear genome

Answer 31

true

Question 32

Describe the features of the mitochondrial genome

Answer 32

it’s usually circular
it’s non-recombining
it’s separate from the nuclear genome

Question 33

What is the phylogenetic origin of the mitochondria?

Answer 33

bacterial

Question 34

T or F: in all eukaryotes the mitochondrion contains its own genome

Answer 34

false, in some eukaryotes, not all this is true

Question 35

Where are the genes of the mitochondrion encoded?

Answer 35

either:

encoded in the mitochondrial genome and function in the mitochondrial genome

mitochondrial origin, but encoded in the nuclear genome and return to the mitochondrion to function

encoded in the nuclear genome and function in the mitochondrion

Question 36

What does having genes from 3 different places suggest about the evolution of mitochondria?

Answer 36

it shows the symbiogenic origin - that mitochondria evolved from an alphaproteobacterial symbiont

Question 37

How big are mitochondrial genomes?

Answer 37

very small (from 2-100 coding genes depending on the organism)

Question 38

Why have mitochondria lost so many genes?

Answer 38

evolving from the free-living alphaproteobacteria, they are now contained within cells = they don’t require as many coding genes so they can afford to lose some

Question 39

How many protein coding genes does the human mitochondrial genome have?

Answer 39

13

Question 40

Where do all of the lost genes from the mitochondrial genome go?

Answer 40

they’re transferred to the nuclear genome

Question 41

T or F: the mitochondrial genome is larger than the mitochondrial proteome?

Answer 41

false,

the proteome is larger than the genome because the proteome includes the genes that began in the nuclear genome and transferred to the mitochondrial genome

Question 42

describe the state of the transfer of genes from the mitochondrial genome to the nuclear genome and vice versa

Answer 42

it’s dynamic and continual

functional and pseudogenes are continually transferred

Question 43

T or F: some eukaryotes have lost their mitochondrial genome

Answer 43

true

Question 44

What do the eukaryotes that have lost their mitochondrial genome have instead?

Answer 44

an organelle containing some genes of mitochondrial origin that have been transferred to the nuclear genome

Question 45

What type of organisms are eukaryotes without a mitochondrial genome?

Answer 45

they’re anaerobic and usually parasites/pathogens of medical significance

Question 46

What is an example of a eukaryote that has lost its mitochondrial genome? describe it

Answer 46

Giardia lamblia - a single-celled, anaerobic protist that causes beaver fever

it has a nuclear genome with genes of mitochondrial origin that are concentrated in small organelles called mitosomes

Question 47

How do mitosomes differ from mitochondria?

Answer 47

mitosomes are tiny organelles that exist in organisms without a proper mitochondrion to permit anaerobic respiration

Question 48

Are there any eukaryotes that have completely lost their mitochondrion (no genome, no organelle)?

Answer 48

only one so far

Monocercomonoides sp. - a microbe isolated from chinchilla guts

Question 49

Are there examples of eukaryotes that never had a mitochondrion? why/why not?

Answer 49

Not yet. Why not?

maybe they haven’t been discovered yet

maybe they went extinct and haven’t been preserved well in the fossil record

maybe they never existed because the acquisition of a mitochondria is the defining feature of eukaryotes

Question 50

What are the 4 major features of evolution in eukaryotes?

Answer 50

typically diploid

sexual reproduction and recombination

cellular and genomic complexity

wide range of population sizes - changes what type of evolutionary forces are at work

Question 51

How do the features of eukaryotic evolution compare to that of bacteria and archaea?

Answer 51

typically, eukaryotes are diploid, whereas bacteria are haploid

eukaryotes reproduce sexually and have recombination, whereas bacteria reproduce asexually (but can still have recombination events)

eukaryotes have larger and more complex genomes and more complex cells (ex. mitochondrial genome and nuclear genome)

eukaryotic populations can range a lot in size, whereas generally, prokaryotic populations are all very large (natural selection is main force)

Question 52

How might having a smaller population size, for example, as seen in multicellular eukaryotes, influence their evolution?

Answer 52

evolution will be more strongly influenced by genetic drift when the populations are smaller than by natural selection

Question 53

How might population size explain the differences in evolutionary patterns seen between prokaryotes and eukaryotes?

Answer 53

eukaryotes can have much smaller population sizes than prokaryotes, so whether there’s genetic drift or natural selection occurring, evolution will look different

Question 54

Does horizontal gene transfer occur in eukaryotes?

Answer 54

yes, but much less common than in prokaryotes

Question 55

What is an example of a time when horizontal gene transfer in eukaryotes is beneficial?

Answer 55

it may be a good way to adapt to a new ecological niche by picking up genes that are already adapted to the ecology, the population will save evolutionary time adapting to the environment

Question 56

What are the potential outcomes of horizontal gene transfer?

Answer 56

a new piece of DNA has entered the germline…
it can:

be expressed
not be expressed
be passed on to offspring and spread
not be spread
become fixed
become lost

Question 57

What’s an example of horizontal gene transfer in eukaryotes? explain

Answer 57

red aphids - clearly contain carotenoids (red pigmentation)

animals have lost the genes to synthesize their own carotenoids, but carotenoids are essential so they must be acquired through diet

the aphid diet of phloem, however, does not contain carotenoids

studies have shown now that the red aphids have re-acquired the carotenoid biosynthesis genes via horizontal transfer from fungi

Question 58

How have red aphids used horizontal gene transfer?

Answer 58

all animals have lost the carotenoid biosynthesis genes because they’ve been able to get carotenoids from their diet

red aphids do not get carotenoids from diet, but have re-acquired these carotenoid synthesizing genes by integrating them into their genome FROM FUNGI (horizontal gene transfer), expressing them, and passing them on to offspring = these genes are being maintained by vertical gene transfer

Question 59

Why is fungi likely the source for the horizontal acquisition of the carotenoid biosynthesis gene in red aphids?

Answer 59

it’s parsimonious

when looking at the phylogenetic relationship of carotenoid synthases (enzymes) in aphids, the closest relatives were fungi

Question 60

Describe eukaryotic genomes

Answer 60

big
filled with junk (a lot of redundancy and clutter, ie., noncoding DNA)

Question 61

Why is the eukaryotic genome referred to as filled with junk?

Answer 61

it has accumulated a lot of non-coding genes and is very large and redundant

Question 62

How does the eukaryotic genome compare to that of a prokaryotic genome?

Answer 62

eukaryotic genomes are large and contain a lot of redunancy and non-coding genes, whereas prokaryotic genomes tend to be streamlined, small, consisting of mostly coding genes and little non-coding

Question 63

T or F: there’s a huge diversity in genome sizes within eukaryotes

Answer 63

true

Question 64

how is eukaryotic genome size related to organismal complexity? how does this compare to prokaryotic genomes and organismal complexity?

Answer 64

it’s not related in eukaryotes

in prokaryotes, the bigger genome = more genes, complexity of organism

Question 65

What is the C-value paradox or enigma?

Answer 65

C-value = content of nuclear DNA (ie., genome size)

the paradox = eukaryotic genome size is unrelated to the complexity of the organism

Question 66

Explain and give an example that supports the C-value paradox

Answer 66

related organisms, even from the same species, may have differences in genomic sizes

ex. D. melanogaster flies from one location have genomes that range from 169.7-192.8 Mbases of DNA == huge variation in sizes within a population of the same species

Question 67

Which eukaryotes have the biggest genomes?

Answer 67

Amoeba (single-celled) has the largest

Question 68

Why are larger genomes often under-studied/why is there a bias in our understanding of eukaryotic genomes?

Answer 68

because the bigger the genome, the longer they take to sequence

Question 69

T or F: most DNA in eukaryotic genomes is noncoding vs most DNA in prokaryotic genomes is coding

Answer 69

true

Question 70

What kind of questions can we ask about the non-coding DNA in large eukaryotic genomes?

Answer 70

is it, or any of it, functional?
is it, or any of it, junk?

Question 71

How can we apply the Spandrels/Panglossian metaphor to the presence of non-coding DNA in large eukaryotic genomes?

Answer 71

eukaryotic genomes have large amounts of non-coding DNA - is it there for a reason? Is it because of natural selection?

we’ve seen in prokaryotes that natural selection favours a smaller genome size, so no, these genes are not there for a reason - likely just no pressure to get rid of them/have a streamlined genome?

Question 72

What percentage of the human genome is coding genes? What percentage is transposable elements?

Answer 72

protein-coding genes = ~1.5%
transposable elements = ~44%

Question 73

What are transposable elements?

Answer 73

“jumping genes”

DNA sequences that break the Mendelian rules of inheritance and can move around the genome to be inherited more often

Question 74

What does the onion test tell us about using Spandrel/Panglossian ideology to explain the size of a eukaryotic genome?

Answer 74

onions have a genome that’s 5x larger than the human genome…

basically, does every gene in a genome actually have to be assigned a function/reason to be there? No = not everything is there for a reason

Question 75

What is an NUMT?

Answer 75

A nuclear-mitochondrial transfer of DNA

basically, mitochondrial DNA (pseudogenes and non-coding genes) being transferred into the nuclear genome

Question 76

How common are human NUMTs? How big are they?

Answer 76

rare and the common ones are small

Question 77

How do NUMTs relate to the size of the human genome and it’s large proportion of non-coding genes?

Answer 77

the mitochondria are continuously transferring pseudogenes and non-coding genes out to the nuclear genome to streamline the mitochondrial genome

this increases the size of the nuclear genome and its proportion of non-coding DNA

Question 78

What was the result of the study on human NUMT and size?

Answer 78

high frequency of very rare NUMTs ranging in size but none were fixed

common NUMTs were small and some became fixed

Question 79

What are 3 key features of mitochondrial evolution (genes encoded in the mitochondrial genome)?

Answer 79

mitochondrial genes have:

uniparental inheritance (usually from mother)

different mutation rates (ex. high in animals)

no recombination (a feature from bacterial origin) = mitochondrial genome is circular like bacteria and is inherited as one piece

Question 80

What are the consequences in mitochondrial evolution of no recombination?

Answer 80

neighbours matter!

genetic hitchhiking

essentially reproducing asexually - can cause accumulation of deleterious mutations, especially in small population sizes

Question 81

T or F: animal mitochondrial DNA has high mutation rates

Answer 81

true

Question 82

Why does animal mitochondrial DNA (MtDNA) have very high mutation rates?

Answer 82

• mitochondria is the site of respiration = high levels of free oxygen radicals (mutagenic)
• replication of non-dividing cells (errors increased)
• some pathways for DNA repair are absent

Question 83

Why is animal MtDNA used as a marker for molecular evolution, ecology, and species identification?

Answer 83

because animal MtDNA has very high mutation rates

Question 84

T or F: Muller’s ratchet can apply to animal mtDNA - why/why not?

Answer 84

true because MtDNA does not undergo recombination

Question 85

What are the consequences of Muller’s ratchet/no recombination in MtDNA?

Answer 85

an accumulation of slightly deleterious mutations over time because there’s no way to recombine them out of the genome

overall decline in fitness

Question 86

What are two examples of human mitochondrial diseases?

Answer 86

Leber’s hereditary optic neuropathy (LHON) = blindness in male adolescents

Leigh syndrome = subacute necrotizing encephalomyelopathy

caused by mutations of mitochondrial genes

Question 87

How has LHON (a mitochondrial disease) been linked to founder effects? discuss the example of French Canadians / Les Filles du Roy

Answer 87

the relatively high frequency of LHON amongst French Canadians has been traced back to a single woman who was sent as part of a founding population to Nouvelle-France (Quebec City) in the 1600s

she was a carrier of the mitochondrial mutation and passed it on to her descendants

the genes from the founding population are still influencing the current population = founder effect

Question 88

what did the study of LHON in French Canadians show regarding the fitness of males vs. females in terms of survival past the 1st year? what does this mean for the heritability of the mutation?

Answer 88

females showed no differences in survival

males with the mitochondrial mutation haplotype for LHON had significantly lower fitness and reduced survival past 1 year than males that did not have the haplotype and than females

= the mutation is mitochondrial and only inherited from a carrier mother by offspring and expressed only in males

Question 89

What is the “Mother’s Curse”?

Answer 89

mitochondrial mutations that are passed through females but don’t have deleterious outcomes will not be removed in females and will be then passed on to sons in which it may be deleterious

Question 90

What does the Mother’s Curse, Les Filles du Roy, and LHON haplotype tell us about the patterns of evolution for mitochondria vs. nuclear genomes?

Answer 90

the patterns of evolution are different for the two genomes and heritability and gene expression are different

Question 91

Is there conflict between mitochondrial and nuclear genomes? if so, when does it occur?

Answer 91

sometimes, when they are not totally aligned

Question 92

What is an example of conflict between the mitochondrial and nuclear genomes?

Answer 92

cytoplasmic male sterility (CMS)

Question 93

How are mitochondrial genes passed to offspring in gymnosperms?

Answer 93

uniparentally through males

Question 94

What is CMS? what type of plants is it most common in?

Answer 94

a mitochondrial trait that sterilizes male flowers

it’s common in plants that produce male and female flowers (especially in agricultural crops)

used as a way to prevent self-fertilization

Question 95

How do plants with CMS display conflict their between mitochondrial and nuclear genomes?

Answer 95

CMS is a mitochondrial trait that sterilizes male flowers

in flowers that produce both male and female plants, and that have sterilized male flowers because of CMS, the nuclear genome will act to restore fertility of male flower = co-evolution

Question 96

When/why does conflict arise between the nuclear and mitochondrial genomes?

Answer 96

as a consequence of transmission because mitochondrial genes are inherited only through one sex, so the nuclear genome may not be aligned

Question 97

What is an example of a selfish mitochondria?

Answer 97

mitochondrial genomes or haplotypes that sterilize male reproductive parts

Question 98

What is a selfish mitochondria?

Answer 98

mitochondrial genomes or haplotypes that are transmitted more or unequally between sexes

like “jumping genes”

Question 99

Are selfish mitochondria more common in plants or animals?

Answer 99

plants - ex. Cytoplasmic male sterility

Question 100

Why would cytoplasmic male sterility be used as a tool by crop breeders?

Answer 100

to prevent self-fertilization, control crosses, and artificially select desired traits