Bryophytes 2: Anthocerotophyta and Marchantiophyta

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is the second video talking about bryophytes so  overview of this video we're going to look at  

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lineages of bryophytes and we're only gonna look  at two: we're going to look at Anthocerotophyta,  

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the hornworts, and Marchantiophyta, the  liverworts. if you have maybe a not super recent  

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botany textbook even recent botany textbooks might  refer to the liverworts as the Hepatophyta (which  

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hepato means liver) so that name was recently  changed to the Marchantiophyta so our bryophytes  

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were the first group of plants to evolve on land  we think and this says that they are paraphyletic  

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that's currently unknown the research that I've  been using to kind of evolve our botany course  

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actually says that they are likely monophyletic  which goes against pretty much anything else  

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you'll read and so that just means that they would  have had a single bryophyte ancestor that then led  

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to their lineage where they you know you diversify  from there and we get these different groups of  

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bryophytes whereas if they're paraphyletic we  sort of get one group of bryophytes branching  

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off and we stay on this sort of path toward the  rest of plants then another group of bryophytes  

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branches off so it's just about can we group them  all and trace them all back to one shared common  

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ancestor that's only shared by that group or do  they sort of share ancestors with other groups  

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along the way and it's looking like from this one  thousand transcriptomes project that they might be  

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monophyletic so there's three major lineages all  of them are small and prostrate and so there's  

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exceptions to this but that they lay kind of  flat to the surface or aren't able to hold  

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themselves up right because they lack lignified  vascular tissue so when we learned about xylem  

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we learned that it's made of sieve tube or not  seep developments vessel elements and tricky 'its  

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and those are lignified cells with that secondary  cell wall right fights don't have that so because  

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of this they require wet conditions to survive  they don't have roots to penetrate down into  

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some kind soil surface there isn't a soil surface  for them to penetrate down into right we just have  

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this rocky terrestrial surface when they first  move so they're going to be reliant on you know  

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their fungal associates to help them scavenge  water and maybe reliant on their cyanobacterial  

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associates to help them fix nitrogen as they  have access to nutrients so they require wet  

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conditions there to survive I'm getting a little  sidetrack here except a few mosses especially  

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there's large groups of mosses now that can  survive and incredibly dry conditions that most  

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other organisms can't they have the ability to  completely dry out and then stay in that condition  

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and then rehydrate later and live which most  organisms can't do so mosses do have some kind  

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of exceptional abilities to be dry even though  as a general rule bryophytes need water they  

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do need water to reproduce because their sperm  have to travel through water to fertilize eggs

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all of the bryophytes also have gametophyte  dominance so when you look at a bryophyte you  

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see this green tissue it's the largest part of the  organism it is haploid so all other plants when we  

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see this larger part of their lifecycle that's the  green photosynthetic part that's a sporophyte but  

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for bryophytes it's the gametophyte so that this  is a kind of trait that unites them together and  

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so the gametophyte is the larger part of the  lifecycle it generally has a longer lifespan  

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and it's nutritionally independent so it's the  photosynthetic part and can feed itself so there's  

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always exceptions this is Dawsonia superba it is  a moss that can grow up to two feet tall it does  

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not have a lignified vascular tissue like we see  in plants but it has this sort of analogous set of  

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structures where it has hydroids and leptoids  where it's able to kind of transmit water and  

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sugars from its upper parts to its lower parts  but it's not lignified let's look at this first  

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group of bryophytes are hornworts and current  research that i'm using says that it's likely  

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that the hornworts are not genetically closest to  vascular plants but perhaps they evolved first so  

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I'm just gonna cross that off because who knows  right now it's all up for debate so what they look  

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like is this flat kind of flap of tissue that  has little root-like structures so this whole  

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thing is the gametophyte these little root-like  structures are called rhizoids so that just means  

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root like they don't function to absorb water  they don't have any vascular tissue within them  

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they just function for anchorage so they are  to kind of hook themselves to the terrestrial  

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surface and you do find fungal associates with  these rhizoids so they sort of had this possibly  

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mycorrhizal relationship pre-roots that allowed  them to maybe access any nutrients in that kind  

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of rocky surface and help break down that surface  so this is our ballast and in this palace for  

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hornworts often you'll see little pockets where  they have cyanobacteria living inside them so  

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again that's another association that would  have allowed them to access nutrients in this  

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kind of harsh landscape and that's why we call  them salad is because they're always this sort  

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of flat flap of undifferentiated tissue and on  that thallus you have these little kind of vase  

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like structures and that's where the egg would  have been produced inside this archegonium and  

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so the sporophyte grows out of the gametophyte  so here's our sporophyte this is all diploid and

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it is one big sporangium

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and unlike most plants that we'll see there's  only I think one other example of this that  

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we'll see during our body class this sporophyte  grows from a basal meristem so we're used to  

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seeing apical meristems right the shoot apical  meristem in the root apical meristem this tip  

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oriented growth where new cells would normally  be produced at the tip however in this sport of  

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fight new cells are produced at the base and it  pushes the rest of the sporophyte growth upward  

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so the oldest part of the sporophyte is up here  who also interesting that the stomata and cuticle  

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are formed on the sporophyte but not necessarily  on the gametophyte so we're going to start seeing  

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a lot of adaptations that are beneficial for  living on land happening in the sporophyte  

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and that's actually going to lead us to this  sporophyte dominance another feature that helps  

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you recognize hornworts if we're going to zoom in  on this here so if we're looking at a horn we're  

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under the microscope its cells are gonna each have  one large plastid with a pyrenoid those paranoids  

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are sort of ancestral features we see paranoids  in our green algae like in our spirogyra and so  

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that is maybe pointing toward a more ancestral  trait so here we see our alloyed liverworts are  

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not liverworts hornworts says the thallus it's  this flap of undifferentiated tissue it's growing  

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a press to the surface prostrate and then it has  the sporophytes growing up out of the gametophyte  

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so that's at match or trophy where the embryo is  nourished in returning retained and then it's fed  

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through a system of cells here by the gametophyte  and then here on the right we can see the mono  

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plastic condition where we have one large plastid  inside each cell so that's pretty unique and it's  

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a good way to tell apart a thyroid liverwort  from a thali one word here we see the hornwort  

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sporophytes that are maturing and releasing their  spores so they start to D hiss from the top down  

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because this is where the most mature spores would  be and they can dry out because they have stomata  

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all over them and the stomata allow the escape  of moisture to dry out the sporangium once it's  

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dry and those spores have matured it will D hiss  so it will split into these different segments  

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that kind of twist there's a little elaters in  there these little kind of fibrils that help  

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disperse the spores and it does that from the tip  downward from the most mature part to the least  

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mature our liverworts that I can look like either  hornworts or mosses it makes them a little tricky  

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they can reproduce asexually by structures  called gemmae and they have simple pores for  

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gas exchange so unlike the hornworts de ma or a  hornwort sporophyte the head stomata which would  

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be regulated by guard cells liverworts are just  going to have holes in the gametophyte that can't  

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open and close so they can't regulate their gas  exchange and here it says most ancestral lineage  

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maybe not we don't know there's two different kind  of body plans for a hornwort not for a liver work  

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sorry I've had to rerecord this like four times  because PowerPoint keeps quitting on me so now  

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it's all just word salad okay so here's our leafy  liverwort it has these kind of major ranks of  

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leaves the larger upper leaves are going to be  produced in this sort of flat sheet and then if  

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you flip it over you'll have these ranks of little  under leaves that are smaller and stick out of the  

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bottom and mosses don't have that so if you're  trying to tell the difference between a leafy  

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liverwort and a moss you can look for those under  leaves they're really small you can still see them  

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they'll produce rhizoids along this surface  at any point they want to sort of attach to  

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that surface and they can produce the sporophytes  either along the body or some species will produce  

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them just at the end of these structures so these  are all sporophytes but now they're divided into  

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two main parts we have the seta which is the  stock and we have the spur medium and that's  

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where meiosis happens and spores are produced  that sporangium will generally dehisce to open  

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so when it dries out and split into these kind of  four compartments and so that helps release the  

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spores and we will look at the thyroid liverworts  and we draw the life cycle so here you can see  

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the leafy liverwort and these ranks of leaves so  you have these larger upper leaves that would be  

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on the upper surface if we were this is flipped  over under the microscope we could look at it the  

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other way and would look just like a moss except  for a few key features but the underside because  

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these little tiny leaves so make sure to look  for those this is a picture of what that looks  

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like in a hopefully less confusing way here is our  thyroid liverwort and this is one that you might  

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see invading a nursery or greenhouse or anywhere  where it's kind of like shaded cool conditions  

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where there may be growing shade tolerant  plants this is a good invader and it invaded  

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the terrestrial surface so it's not surprising  so over here on the upper right we can see an  

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archegoniophor so the archegonia would be produced  under these little branches right there and then  

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the egg would be produced within the archegonium  get fertilized and develop into a sporophyte which  

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we're seeing these really early sporophytes  developing here they look like coconuts under  

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a palm tree and then the antheridiophore instead  of being that tree like structure it looks more  

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like a flat plate and that's because water  is going to bounce onto the antheridia and  

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splash the sperm out of those same three idea and  hopefully onto in archegoniophore so here we see  

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those archegoniophores growing on a thallus and  that thallus has all these little dots those are  

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simple pours and also if we look over here on the  bottom right we might see these structures these  

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are those gemmae cups and they don't have very  many gemmae in them anymore they've probably all  

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bounced out and been splashed out by water it's  just a little disk of haploid tissue that's been  

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going to be a clone of the gametophyte that can  land somewhere and grow into a new thallus so  

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we're going to draw the Marchantia lifecycle  and label all the parts so meiosis is over  

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here random line is over there realistically I  should leave myself more room on top but I did  

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not so here we go so let's start with some spores  so we have spores are produced by meiosis they're  

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going to be genetically different from each other  some of these might grow into a male gametophyte

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that's going to produce antheridiophores

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while others might grow into a female commute  fight that's going to produce archegoniophores

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and then both could produce gemmae

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and those gemmae would then just grow into  another gametophyte of the same type right so  

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gemmae from a male gametophyte would grow into  another male gametophyte gemmae from a female  

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gametophyte would grow into another female  gametophyte so we have the archegoniophore  

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so that just means the structure that bears the  archegonia and here we have an antheridiophore  

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so the structure that bears the antheridia these  are the gemmae cups oops gemmae cup with gemmae,  

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gemmae singular are gemma is called Gemma  so here's our gametophyte we're going to  

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zoom in on the archegoniophore and the  antheridiophore so if we look underneath  

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a branch of that archegoniophore there's going  to be archegonia kind of nestled into the kind  

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of area where those branches come out inside that  archegonium there'll be an egg to label this we  

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have the egg which was produced by mitosis  and this structure here is the archegonium

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and this is the neck or the venter  of the archegonium if we zoom in on  

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the antheridiophore would see on the top of  that structure up not I'm drawing this wrong  

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they're embedded in that surface let's start  this again so we have this sort of disk like  

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structure that's at the top of the codon  re-enter idea form that's the antheridial  

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head and kind of embedded in that are all of the  antheridia so this is where sperm will be produced

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so those little sperm are gonna get splashed  off of the antheridial head and then travel  

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to an egg when we get the egg and the sperm  meeting we get fertilization what you might  

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see in some of your textbooks or resources  called syngamy that's when you're thinking  

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of karyogamy and fertilization both  happening okay so fertilization this  

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happens on the female gametophyte in that  archegonium so this is the archegoniophore

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that's the archegonium and then now  we have the zygote which forms on  

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that female gametophyte that zygote  is going to grow by mitosis and it  

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does that growth on the female gametophyte  so here's our archegoniophore and it has

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sporangia with seta that grow underneath it so  each of these purple structures is a sporophyte

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and each one has seta it's that short little  stock there and a sporangia and meiosis happens  

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within that sporangium to make spores here's  a picture of some leafy liverworts for fights  

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they are very cute I love finding these they  are pretty ephemeral they don't stick around  

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for long so here's some that get produced at the  end of that gametophyte all right so here's our  

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seta (the stalk) and the sporangium at the  top where the spores are produced so that's  

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the site of meiosis for all plants this site of  meiosis is going to be inside that sporangium  

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so here we see they have opened by drying out  and push themselves open that's dehiscence so  

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be hist to release their spores and this looks  a lot like a moss right you might think it was  

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a moss but you'd have to take a close look  at those leaves or look for these sporangia