Inona avy no voarakitra ato amin'ity fampianarana ity?

Ity fampianarana ity dia mifantoka amin'ny zooplankton, ahitana ny habitat-ny, ny sakafo, ny habe, ny taxonomy ary ny fizarana malaky.

Iza moa no miteny ao amin'ity fampianarana ity?

Emma Tovar, mpiara-miasa mpikaroka ao amin'ny Scripps Institution of Oceanography.

Inona no andraikitry ny zooplankton ao amin'ny ekosistiana an-dranomasina?

Ny zooplankton dia tena zava-dehibe amin'ny rojo sakafo an-dranomasina satria izy ireo no fihinanan'ny zavamaniry lehibe kokoa.

Aiza no misy ny zooplankton?

Ny zooplankton dia miaina amin'ny faritra lalina rehetra ao anaty ranomasina, na dia misy karazany amin'ny rano mangina aza.

Ahoana ny fitondran'ny zooplankton ny sakafo?

Ny zooplankton dia mety ho herbivorous, carnivorous, omnivorous, na mixotrophic, miankina amin'ny karazany.

Inona avy ireo sokajy tsotra ao amin'ny zooplankton?

Ny zooplankton dia mizara ho holoplankton, izay mijanona ho plankton mandritra ny androm-piainana, sy ny meroplankton, izay manova endrika rehefa lehibe.

Inona ny anjara asan'ny zooplankton amin'ny biolojika mpanova?

Izy ireo dia mandray anjara amin'ny famahana ny CO2 sy ny tsingerin'ny calcium carbonate amin'ny alalan'ny fotosintesis sy ny famoronana fako organika.

Ahoana sy inona no ampiasain'ny mpikaroka hianarana momba ny zooplankton?

Ny mpikaroka dia mampiasa fitaovana toy ny mach ness sy ny zoo glider mba hanarahanao zooplankton sy ny firafiny.

Inona no atao hoe dia vertical migration amin'ny zooplankton?

Izy io dia fifindrana zooplankton mankany ambony sy ambany amin'ny antambahin'ny rano mifanaraka amin'ny tsingerina andavanandro.

Nahoana ny fanatoboka oha-panjonoana zooplankton izy io zava-dehibe?

Izy io dia ahafahan'ny mpikaroka mahafantatra ny toerana anjakan'ny karazana zooplankton sy ny antony amam-pahafantarana ny habaka mety misy azy ireo.

Marine Biology at Home 7: Zooplankton

00:59:33

https://www.youtube.com/watch?v=6dpP9UaUNco

Ringkasan

TLDRNy leziona "Marine Biology at Home" avy amin'i Emma Tovar, mpiasa mpikaroka ao amin'ny Scripps Institution of Oceanography, dia mifantoka amin'ny fandalinana ny zooplankton, zavamaniry manan-danja amin'ny rojo sakafo an-dranomasina. Ao amin'ity leziona ity, dia niresaka momba ny fanasokajiana sy ny taxonomy izy, anisan'izany ny fomba hiovan'ny zooplankton amin'ny alalan'ny fitomboana (holoplankton sy meroplankton), ny fizarana marindrano, ary ny sakafon'izy ireny izay mety ho karazana zavamaniry, zava-dehibe hafa na zavatra maty (detritus). Nisongadina ihany koa ny fanelanelanana momba ny fepetra misy ao anatiny sy ny asa atao mba handalinana kokoa ny dynamics an'ny zooplankton, toy ny fampiasana fitaovana teknolojia sy fomba hafa toy ny sarin'ireo vondrona ho fandalinana ny fifandraisana mpihinana sy mitohana. Raha fintinina, ity fampianarana ity dia manolotra fahatakarana lalina sy miavaka momba ny anjara asan'ny zooplankton eo amin'ny tontolo an-dranomasina, indrindra amin'ny fanajariana sy fandanjalanjana ny ekosistiana an-dranomasina.

Takeaways

🌊 Ny zooplankton dia tena zava-dehibe eo amin'ny rojo sakafo an-dranomasina.
🐠 Ny zooplankton dia afaka misitrika zava-maniry na zava-maniry hafa.
🔬 Nampiasa fitaovana teknolojia ny mpikaroka mba hanarahana sy hisamborana ny zooplankton.
📏 Ny zooplankton dia mizara ho karazana holoplankton sy meroplankton.
🌞 Ny zooplankton dia afaka miseho amin'ny toerana misy ny hazavana ao amin'ny ranomasina.
🧬 Ny fandalinana ny zooplankton dia ahitana teknolojia sy renirano vaovao.
📊 Ny firafitr'ireo zooplankton mivantana dia azo trohina amin'ny alalan'ny sary avo lenta.
🌅 Ny dia vertical migration no fifindran'ireo zooplankton manaraka ny tsingerina andro.
🌽 Ny zooplankton dia mety ho karazana vorona sarotra satria manararaotra sakafo marobe.
🌈 Ny tülnar dia azo sakanana amin'ny alalan'ny biby teny.

Garis waktu

00:00:00 - 00:05:00
Emma Tovar dia nanolotra ny tenany ho mpiasa fikarohana ao amin'ny Scripps Institution of Oceanography izay nitokana ho amin'ny fandinihana ny zooplankton. Ny asany dia ny mandrindra ny santionany avy amin'ny dia an-dranomasina ary ny fizarana dia momba ny fampidirana ny zooplankton sy ny fomba fanadihadiana azy ireo.
00:05:00 - 00:10:00
Ny zooplankton dia karazana biby planktonic izay afaka mipetraka amin'ny halaliny rehetra amin'ny ranomasina ary manana fiteny sinhala izay midika hoe biby mandeha. Ny sakafon'izy ireo dia miainga amin'ny phytoplankton hatramin'ny biby hafa ary misy koa ny mixotrophs izay afaka mampifandray ny photosynthesis sy ny fanjifana biolojika.
00:10:00 - 00:15:00
Zooplankton dia azo zaraina ho holoplankton izay mijanona ho plankton mandritra ny androm-piainany sy maroplankton izay plankton fotsiny amin'ireo dingana voalohany amin'ny fivoarana. Ny holoplankton lehibe, toy ny siponophores, dia sakafo fototra ho an'ny trondro sy balaenoptera.
00:15:00 - 00:20:00
Ny zooplankton koa dia azo zaraina araka ny habeny avy amin'ny nanoplankton mankany amin'ny microphytoplankton sy macro zooplankton. Ny macro zooplankton dia azo jerena amin'ny mason-tsivana toy ny pteropods sy ny jellyfish.
00:20:00 - 00:25:00
Zooplankton dia mipetraka amin'ny faritra marina samihafa arakaraka ny sakafony, ny oksizena ary ny hazavana misy. Maro amin'izy ireo no mipetraka ao amin'ny faritra euphotika satria misy hazavana ampy mba hitomboana ny photosynthesis.
00:25:00 - 00:30:00
Zooplankton dia anarany rehefa tafiditra amin'ny sokajy biolojika isan-karazany, ao anatin'izany ny crustaceans sy ny cnidarians. Ireo vondrona ireo dia manan-danja amin'ny fitomboan'ny fihinanana sy ny lafiny fandavana.
00:30:00 - 00:35:00
Zooplankton dia anisan'ny sokajin'ny crustaceans toa ny copepods sy ny krill, izay manana anjara toerana lehibe amin’ny indostria ara-tsakafo an-dranomasina.
00:35:00 - 00:40:00
Ny deal vertical migration dia manasongadina ny hetsika synchronisée amin'ny zooplankton araka ny maizina sy ny hazavana amin'ny fotoana iray, izay manampy azy ireo hisoroka ny fahavononana ary mitazona ny angovo.
00:40:00 - 00:45:00
Ny mpianatra maro ao Scripps dia mijery ny zooplankton sy ny fitondran-tenany amin'ny fomba avionika anaty rano sy mankany amin'ny famantarana ADN amin'ny fandinihana ny fahasamihafana sy ny fifanakalozana.
00:45:00 - 00:50:00
Ny famoronana sary amin'ny alalan'ny zo scan sy zo cam dia mampiseho an-tapitrisa ny antsipirihany amin'ny zooplankton sarobidy amin'ny fandinihana ny diversite sy ny alan'ny fisiana.
00:50:00 - 00:59:33
Emma Tovar dia mamintina ny kaonty ho famporisihana ny olona hanohy ny fianarana an-dranomasina sy hizarana ny fahalalana, manentana ny mpijery hanohy hijery ny lohahevitra manan-danja toy ny zooplankton sy ny andraikitr'izy ireo amin'ny ekosistemam-dràno.

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Video Tanya Jawab

Inona avy no voarakitra ato amin'ity fampianarana ity?
Ity fampianarana ity dia mifantoka amin'ny zooplankton, ahitana ny habitat-ny, ny sakafo, ny habe, ny taxonomy ary ny fizarana malaky.
Iza moa no miteny ao amin'ity fampianarana ity?
Emma Tovar, mpiara-miasa mpikaroka ao amin'ny Scripps Institution of Oceanography.
Inona no andraikitry ny zooplankton ao amin'ny ekosistiana an-dranomasina?
Ny zooplankton dia tena zava-dehibe amin'ny rojo sakafo an-dranomasina satria izy ireo no fihinanan'ny zavamaniry lehibe kokoa.
Aiza no misy ny zooplankton?
Ny zooplankton dia miaina amin'ny faritra lalina rehetra ao anaty ranomasina, na dia misy karazany amin'ny rano mangina aza.
Ahoana ny fitondran'ny zooplankton ny sakafo?
Ny zooplankton dia mety ho herbivorous, carnivorous, omnivorous, na mixotrophic, miankina amin'ny karazany.
Inona avy ireo sokajy tsotra ao amin'ny zooplankton?
Ny zooplankton dia mizara ho holoplankton, izay mijanona ho plankton mandritra ny androm-piainana, sy ny meroplankton, izay manova endrika rehefa lehibe.
Inona ny anjara asan'ny zooplankton amin'ny biolojika mpanova?
Izy ireo dia mandray anjara amin'ny famahana ny CO2 sy ny tsingerin'ny calcium carbonate amin'ny alalan'ny fotosintesis sy ny famoronana fako organika.
Ahoana sy inona no ampiasain'ny mpikaroka hianarana momba ny zooplankton?
Ny mpikaroka dia mampiasa fitaovana toy ny mach ness sy ny zoo glider mba hanarahanao zooplankton sy ny firafiny.
Inona no atao hoe dia vertical migration amin'ny zooplankton?
Izy io dia fifindrana zooplankton mankany ambony sy ambany amin'ny antambahin'ny rano mifanaraka amin'ny tsingerina andavanandro.
Nahoana ny fanatoboka oha-panjonoana zooplankton izy io zava-dehibe?
Izy io dia ahafahan'ny mpikaroka mahafantatra ny toerana anjakan'ny karazana zooplankton sy ny antony amam-pahafantarana ny habaka mety misy azy ireo.

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Teks

Gulir Otomatis:

00:00:00
hi and welcome to another lecture with
00:00:02
marine biology at home
00:00:04
before we get started don't forget to
00:00:06
check out our facebook page
00:00:08
for extra tidbits that you wouldn't find
00:00:10
in our lectures
00:00:11
and remember that we have a youtube
00:00:13
channel so please like and subscribe to
00:00:16
at biology at home to find all of our
00:00:19
content in one place
00:00:20
and remember when you subscribe you'll
00:00:22
stay up to date on when new lectures
00:00:24
drop
00:00:26
so who is talking right now hi everyone
00:00:30
my name is emma tovar
00:00:32
and i work as a staff research associate
00:00:35
at scripps institution of oceanography
00:00:38
out here in
00:00:39
sunny san diego california and the lab
00:00:42
that i work in focuses on
00:00:44
zooplankton research and my job mostly
00:00:47
surrounds
00:00:48
cataloging samples that we've collected
00:00:51
from various research cruises
00:00:53
and i've been here for about
00:00:56
just a little over four years now and i
00:00:59
have to say i have definitely
00:01:01
learned a lot from the various grad
00:01:04
students who have come and gone
00:01:06
throughout scripps and in our lab
00:01:08
and it's just been a good experience
00:01:10
overall
00:01:11
now if you have any questions about this
00:01:13
lecture or would like to learn more
00:01:15
about scripts
00:01:16
in general please don't hesitate to send
00:01:19
me an email
00:01:20
and i have it down here below and i look
00:01:22
forward to hearing from you
00:01:26
as i said before our lab focuses on
00:01:29
zooplankton
00:01:30
so naturally today's lecture is going to
00:01:33
be focusing
00:01:34
on these awesome marine organisms um
00:01:37
this
00:01:38
lecture will be a brief introduction
00:01:41
into zooplankton
00:01:42
and the many ways that people have been
00:01:44
studying
00:01:45
these tiny little organisms i'll be
00:01:48
going through habitat
00:01:49
diet size classification basic taxonomy
00:01:54
and migration patterns to help give
00:01:57
everyone a better picture of why
00:02:00
zooplankton are an important part of
00:02:02
the marine food web and to round out our
00:02:05
lecture today i actually also want to
00:02:08
spotlight some of the cool research that
00:02:11
has been done
00:02:12
to help everyone better understand
00:02:14
zooplankton
00:02:15
and their role within the oceans
00:02:20
all right so by this point i think i
00:02:22
have said so plankton enough times right
00:02:24
so i'm going to say it a couple more
00:02:26
unfortunately so bear with me
00:02:29
um today we're going to focus
00:02:31
specifically on
00:02:32
marine zooplankton there are freshwater
00:02:35
zooplankton
00:02:36
and there are very lots of similarities
00:02:38
between the two but for today
00:02:40
we're going to just focus on the marine
00:02:43
guys
00:02:44
and so zooplankton are planktonic
00:02:46
animals that can live
00:02:48
at all depths of the ocean the word
00:02:51
zooplankton actually is derived from
00:02:53
the greek word zune meaning animal
00:02:56
and planktoes meaning to wander or drift
00:03:00
so when you combine the two what you get
00:03:02
are
00:03:03
wandering or drifting animals which
00:03:05
pretty much sums up
00:03:06
zooplankton this is one of those random
00:03:09
tidbits that you might want to remember
00:03:11
because you never know when it might be
00:03:13
handy for one of your
00:03:14
zoom trivia nights
00:03:18
many might assume that zooplankton
00:03:21
might consist of a diet of just eating
00:03:24
others or types of zooplankton
00:03:26
and while this is definitely one
00:03:29
way to gather nutrients zooplankton have
00:03:33
evolved many different strategies in
00:03:35
order to eat and to survive
00:03:38
and so and one of those is to actually
00:03:41
be
00:03:41
herbivores or obiferous and feed
00:03:44
primarily excuse me on
00:03:46
phytoplankton um another one what you're
00:03:48
familiar with
00:03:49
is carnivores or to be carnivorous
00:03:53
and carnivorous so plankton feed
00:03:56
on other types of zooplankton so other
00:03:58
animals
00:04:00
and then we have zooplankton that are
00:04:03
detritivores or they eat primarily
00:04:05
detritus
00:04:06
which is the dead organic matter
00:04:08
[Music]
00:04:10
that we can it usually will fall
00:04:11
throughout the water column
00:04:14
and then we have zooplankton that will
00:04:17
also
00:04:18
be omnivorous and so they feed
00:04:21
on a mixed diet of plants
00:04:24
and animals and detritus so probably one
00:04:28
of the least picky eaters out there so
00:04:30
kudos to them i suppose
00:04:32
and then lastly we have our mix of
00:04:34
troughs and so
00:04:36
these are very interesting organisms
00:04:39
that they can eat other zooplankton
00:04:43
and also photosynthesize
00:04:46
and so examples of mixotrops might
00:04:48
include ciliates or rhizaria
00:04:51
and they're mixotrophic owing to their
00:04:55
ability to retain
00:04:57
functional algal organelles or
00:05:00
maintenance of their alkyl endosymbionts
00:05:03
and so
00:05:05
there's just when you think about how
00:05:08
zooplankton are able to eat and survive
00:05:09
there's just a lot of different ways
00:05:11
that they're able to do that
00:05:15
all right so all of zooplankton can fall
00:05:19
into one of two categories either
00:05:22
they are holoplankton or they are marrow
00:05:25
plankton
00:05:26
and so holoplankton go on here
00:05:30
there we go holoplankton are types of
00:05:33
plankton that will stay in the
00:05:34
planktonic state their whole lives and
00:05:36
they will drift and drift and drift
00:05:38
throughout that
00:05:39
epi-mesopelagic pelagic zones and
00:05:43
i will expand a little bit more on that
00:05:45
later
00:05:46
and so haloplankton as you can see here
00:05:49
in this image there's many different
00:05:51
types there's lots of different types of
00:05:53
holoplankton
00:05:54
and they can range in size from a few
00:05:57
micrometers
00:05:59
to very very large we're talking maybe
00:06:04
cnidarians like jellies or siphonophores
00:06:07
and so holoplankton are very important
00:06:10
because they serve
00:06:11
as a vital food source for large
00:06:14
organisms like
00:06:15
fish or baleen whales when you think of
00:06:18
whales might think of like
00:06:20
um a humpback whale or something and
00:06:24
an example i want to show you some i
00:06:27
just want to highlight some of the
00:06:28
different types
00:06:29
of plankton that i have seen in the
00:06:31
samples that i work with so
00:06:33
it can vary between let me get my pen
00:06:37
it can vary between copepods
00:06:40
or between i've seen doliolids in our
00:06:43
samples definitely senior faucets
00:06:47
i've definitely seen salps some years
00:06:49
we've had lots and lots of subs in our
00:06:52
samples
00:06:53
um we've seen siphonophores pretty often
00:06:55
the same goes for appendicularians
00:06:58
and again you can see just from this
00:07:00
image that there are many different
00:07:01
types
00:07:02
of zooplankton that are holoplankton and
00:07:05
they will stay
00:07:07
very small their whole lives
00:07:10
and so let me go ahead and erase
00:07:14
my doodles here okay
00:07:17
so go ahead and move on to the next one
00:07:20
so the
00:07:21
second category that we were talking
00:07:22
about are marrow plankton
00:07:25
and so maroplankton are types of
00:07:28
plankton
00:07:28
that will only stay plankton
00:07:32
in for a part of their lives
00:07:35
and so typically that would mean the
00:07:36
early stages of development for
00:07:39
these different organisms and so they
00:07:41
start off in the planktonic state
00:07:43
as nopalei but then as they mature
00:07:46
and become larger they will settle in
00:07:48
different parts of the ocean
00:07:50
and a lot of these you probably have
00:07:52
seen before
00:07:54
whether it's at the beach or whether it
00:07:56
was at an aquarium
00:07:59
all of these organisms you see here they
00:08:01
all had to start off pretty small
00:08:03
and so a common example you might see
00:08:07
pen would be the
00:08:10
common sea star although right here it
00:08:12
says starfish that's not what we're
00:08:14
supposed to say
00:08:15
another one we might see a lot at the
00:08:17
beach
00:08:18
would be crabs here we have the green
00:08:21
crab
00:08:22
if you have been to an aquarium recently
00:08:25
you may have had the chance to see an
00:08:27
octopus
00:08:28
and so all of these organisms had to
00:08:31
start off
00:08:32
as napli in the planktonic state and
00:08:35
then over time
00:08:36
they grew and matured into the organisms
00:08:40
you see below
00:08:41
and so these different categories
00:08:43
holoplankton
00:08:44
and marrow plankton and it helps us to
00:08:46
be able to better understand
00:08:48
the size different size classifications
00:08:50
for the different types of zooplankton
00:08:53
and why some stay in the planktonic
00:08:56
state and why
00:08:57
others mature and grow and become larger
00:09:03
all right so zooplankton can also be
00:09:05
categorized
00:09:06
based by size and so what we have at
00:09:10
this table
00:09:11
are four different size classes before
00:09:13
we jump into this table i want to also
00:09:15
talk about
00:09:16
a smaller and even smaller size class
00:09:18
called nanoplank zooplankton
00:09:21
and they're unicellular animals that
00:09:24
feed on phytoplankton
00:09:26
and are then eaten by other types of
00:09:28
zooplankton
00:09:29
and their size range can vary from 2 to
00:09:32
20 micrometers
00:09:34
and we see an example of that here and
00:09:36
with these images
00:09:37
in order to be taken they probably had
00:09:39
to use a microscope because
00:09:41
my nano zooplankton are so small
00:09:44
and so now jumping back to the table we
00:09:47
start with
00:09:48
microsoft plankton and their size ranges
00:09:51
from
00:09:51
20 to 200 micrometers and different
00:09:54
types of organisms that can be
00:09:55
represented here would be
00:09:57
different stages of copepod and
00:10:00
if we take a look at the bottom of this
00:10:04
picture the bottom row g and h
00:10:07
are good examples of two different types
00:10:10
of copepod
00:10:11
in the nopolyi stage and then if we take
00:10:15
a look at i
00:10:16
here in the bottom right corner this
00:10:17
looks like some type of
00:10:20
bivalve not blue eye in its early stages
00:10:22
of development
00:10:23
and so these are pretty good examples to
00:10:25
look towards
00:10:26
when um thinking about the size and what
00:10:30
what zooplankton might look like
00:10:34
and then let's go ahead and delete our
00:10:36
doodles
00:10:38
and moving on okay so mesozoplankton
00:10:42
they range from 0.2 to 20 millimeters so
00:10:45
we're going up
00:10:46
in size a little bit and different types
00:10:48
of organisms within this category it
00:10:49
could be amphipods appendicularians
00:10:52
ketegnats
00:10:53
and copepods or doleolids and sulps
00:10:56
and with
00:11:00
these with organisms in this size class
00:11:02
you can see that
00:11:03
the the body type can change
00:11:07
dramatically
00:11:08
and so again we have different types of
00:11:10
copepod here
00:11:11
we have what looks like some sort of
00:11:14
marine worm
00:11:17
we have a ketignath here a euphemism
00:11:20
here
00:11:20
so many different shapes sizes
00:11:23
all included in the
00:11:27
in the mesoplankton category
00:11:31
and then go ahead erase erase
00:11:34
okay and moving on
00:11:38
so the next one we have are
00:11:40
macroplankton
00:11:41
and macrozooplankton their stage
00:11:44
or their size can range from 20 to 200
00:11:47
millimeters so they're getting much
00:11:49
bigger
00:11:50
and organisms in this category could
00:11:53
include euphausids
00:11:54
heteropods jellyfish larval fish
00:11:57
mycids pteropods and solitary selps
00:12:01
and so what we have an image here on the
00:12:04
right
00:12:05
is an example of a pteropod called
00:12:09
limousina helicena and you can tell
00:12:12
here that part of its shell actually has
00:12:15
been
00:12:16
damaged and this probably occurred when
00:12:18
it was being collected through the net
00:12:20
or something and so
00:12:21
because these shells are very delicate
00:12:24
and they're not used to
00:12:26
being handled roughly or being tossed
00:12:28
around by current
00:12:29
a strong current because they live at a
00:12:31
lower depth in the water column
00:12:33
and but you can see that the shell
00:12:35
should have extended a little bit
00:12:36
further down here
00:12:38
but this is a nice example of what a
00:12:40
macro zooplankton
00:12:41
might look like and so then lastly
00:12:44
we'll go to our mega zooplankton
00:12:48
they are pretty much organisms that are
00:12:51
greater than
00:12:52
200 millimeters and that can include
00:12:54
jellyfish and colonial salps
00:12:57
and in this image here we have a good
00:13:00
example which is called the portuguese
00:13:01
manowar
00:13:03
which is probably a very popular image
00:13:07
or
00:13:07
organisms that we have probably seen in
00:13:09
textbooks or on tv and such
00:13:12
and then another example that we have
00:13:15
are
00:13:16
the wind um i'm sorry by
00:13:20
the wind sailor or vilella velola
00:13:23
and these i have seen wash up ashore
00:13:26
in san diego and um
00:13:30
and they've washed up by the tens of
00:13:33
thousands and when they dry up they just
00:13:35
look like little
00:13:35
pieces of blue plastic wrap
00:13:39
and they just kind of fly away with the
00:13:41
breeze when they dry
00:13:42
up and so but they wash ashore because
00:13:46
they
00:13:47
use this part of their
00:13:52
body like a sail and are propelled along
00:13:55
the top of the ocean
00:13:57
or the surface ocean from the wind or by
00:14:00
the wind and so
00:14:01
when they wash up ashore they can't help
00:14:04
it and
00:14:04
they just eventually dry up but these
00:14:07
are also good examples of types of
00:14:09
megazooplankton
00:14:14
right so there are many species of
00:14:17
zooplankton
00:14:18
that live in the euphodic or
00:14:22
on this diagram we have the photic zone
00:14:25
of the ocean
00:14:26
and so what that means is that they live
00:14:28
at depths at which
00:14:30
sunlight can penetrate and feeding on
00:14:33
phytoplankton and phytoplankton are
00:14:35
restricted to a specific part of the
00:14:38
ocean
00:14:39
because they photosynthesize and in
00:14:41
order to photosynthesize they need
00:14:43
sunlight
00:14:44
and so in the photic zone
00:14:47
we see that that zone
00:14:51
is not very deep we're looking at
00:14:54
just right here excuse me
00:14:58
and in the marine ecosystem um the
00:15:02
photic zone can range in
00:15:05
um in depth between maybe roughly 30
00:15:08
meters
00:15:09
when you're looking more coastal or
00:15:11
inland
00:15:12
or when you are further out in the ocean
00:15:15
the photic zone can extend
00:15:17
between 100 and 200 meters out
00:15:20
in depth and so
00:15:22
[Music]
00:15:24
many different types of zooplankton will
00:15:27
live and thrive within the photic zone
00:15:30
however zooplankton do live and exist
00:15:34
in different parts of the water column
00:15:37
and not specifically just
00:15:38
photic zone and what we'll actually
00:15:40
learn a little bit later
00:15:43
one of our grad students in the lab that
00:15:45
i work in are studying
00:15:47
zooplankton that live and thrive
00:15:50
in the use my pen again
00:15:53
and the mesopelagic zone
00:15:57
and so there are zero painting that live
00:15:58
down there and so
00:16:01
when you look at the vertical
00:16:02
distribution of the zooplankton and
00:16:05
where they live
00:16:06
many variables go into play on
00:16:10
to why they exist at different depths in
00:16:12
the water column
00:16:13
and food availability is a key factor
00:16:17
along with oxygen saturation
00:16:21
there's another one the amount of light
00:16:24
sunlight available is another one
00:16:26
and so in turbulence and nutrients
00:16:30
the amount of nutrients available or
00:16:32
others and so there's many different
00:16:34
reasons why zooplankton will exist at
00:16:37
various depths
00:16:38
within the water column and and this is
00:16:41
a and could be a
00:16:42
really great lecture to expand on later
00:16:45
if someone wanted to
00:16:49
okay so let's talk about taxonomy and
00:16:52
the different phylums and subphylums of
00:16:54
zooplankton
00:16:55
and the next couple of slides i'll talk
00:16:57
about these different groups and show
00:17:00
a few examples of what they would look
00:17:02
like and
00:17:03
examples of the size that they can reach
00:17:05
and so the different
00:17:07
groups that we'll be talking about today
00:17:08
include
00:17:10
crustaceans nadarians
00:17:13
tinoforce aka comb jellies
00:17:16
urochordates salps and larvaceae
00:17:19
worms could be arrowworms or polycheats
00:17:22
pteropods which are planktonic snails
00:17:25
and protists
00:17:29
all right so first up our crustaceans
00:17:32
and crustaceans they have an external
00:17:36
chitin skeleton
00:17:37
and uh the word chitin might be familiar
00:17:39
for some of you who are
00:17:41
bug enthusiasts because insects
00:17:44
use chitin to create the exoskeleton
00:17:46
that they need in order to protect
00:17:49
the insides um and then crustaceans also
00:17:52
have segmentation that runs along their
00:17:54
body
00:17:55
the image here on the right you can see
00:17:57
uh really nicely the segmentation along
00:17:59
the
00:18:00
the tail and the segmentation allows for
00:18:03
the copepods and krill
00:18:05
[Music]
00:18:07
amphipods people to bend and move around
00:18:09
in the water
00:18:11
they also consist of paired jointed
00:18:13
appendages so the legs and then 10a
00:18:16
and along with the antennae are
00:18:18
mandibles and maxillae that
00:18:20
are part of the head appendages so the
00:18:23
maxillae they serve
00:18:24
to transport food to the mandible
00:18:28
but also assist in the filtration
00:18:32
water filtration and sometimes also play
00:18:35
a role in cleaning and grooming
00:18:38
and so crustaceans have a simple naplear
00:18:42
in some cases compound
00:18:43
eyes and these eyes help with deter
00:18:47
sensing where the direction of where the
00:18:50
sunlight is coming from
00:18:51
and crustaceans include copepods
00:18:54
krill and amphipods which are crabs and
00:18:57
lobsters
00:19:00
next so one group
00:19:03
of crustaceans we'll look at are
00:19:05
copepods and
00:19:07
they are the largest group of
00:19:08
crustaceans in the zooplankton world
00:19:11
and their range of size is around less
00:19:14
than a millimeter to around a few
00:19:16
millimeters long and so
00:19:18
planktonic forms belong to the order of
00:19:21
callanoida which i
00:19:22
see very often in the samples that i
00:19:24
scan they have a long pair
00:19:26
of antennae which you can see on the
00:19:28
image here and they're very beautiful
00:19:30
they swim mainly with the aid of five
00:19:32
pairs of thoracic appendages
00:19:35
and they lack compound eyes and so they
00:19:38
actually have medial noplear eyes and so
00:19:40
what this means if you look here
00:19:43
this is a good example and the medial
00:19:47
nocular eyes
00:19:49
are a simple type of eye that consists
00:19:53
of three photoreceptor units and
00:19:56
these units help the copepod be able to
00:19:59
tell the direction of where the light is
00:20:00
coming from so again
00:20:01
sunlight and they feed on phytoplankton
00:20:06
or smaller zooplankton depending on the
00:20:08
species but
00:20:09
from what we knew about their diet
00:20:10
earlier they could be omnivorous
00:20:12
herbivorous or carnivorous
00:20:18
and then next group are krill
00:20:21
and so krill are shrimp like we probably
00:20:23
have seen these
00:20:24
a lot and if you've seen any nature
00:20:26
documentaries or like planet earth and
00:20:28
stuff you've probably seen those
00:20:30
giant swarms of krill in the ocean and
00:20:34
the
00:20:34
majestic baleen whale jumping through
00:20:37
swimming through the ocean to gobble up
00:20:39
all of the krill right so
00:20:41
krill are very important food source for
00:20:44
many animals in the ocean
00:20:46
and they are abundant in antarctic and
00:20:48
an upwelling region so this is
00:20:50
also a main reason why many large
00:20:53
marine animals will migrate to the
00:20:56
antarctic
00:20:58
or or to colder regions because they're
00:21:00
looking for this krill to eat
00:21:02
and so again they're the main food of
00:21:04
baleen wheels and the antarctic
00:21:06
krill feed on phytoplankton and other
00:21:09
types of zooplankton
00:21:10
and they feed by means of a group of
00:21:13
appendages
00:21:14
that form a basket and so these
00:21:17
appendages
00:21:18
will help them move and filter water
00:21:22
towards their mandibles so that
00:21:24
they can quickly feed in a small
00:21:28
small space around them versus having to
00:21:31
venture out far swim further to find
00:21:33
their prey they just
00:21:34
kind of swoop in and draw the water in
00:21:37
and filter
00:21:38
and draw the water into their mandibles
00:21:41
to feed
00:21:45
okay so what i wanted to show you
00:21:47
quickly was a video
00:21:48
of a particular type of copepod it's
00:21:51
called metridia
00:21:52
longa and in this video what's happening
00:21:55
is that and it's a slow-mo which is good
00:21:58
because you really get to see
00:21:59
it in action it detects the
00:22:02
phytoplankton
00:22:03
and you should see it coming up just
00:22:05
right here so what happens after it
00:22:07
detects the phytoplankton is that it
00:22:09
triggers what's called
00:22:10
a an attack response and so
00:22:13
the copepod what it's going to do is it
00:22:16
creates a
00:22:17
section to draw in you can see it's
00:22:19
using
00:22:20
all of its appendages to draw in water
00:22:22
and phytoplankton
00:22:24
um in its mouth to feed and so a single
00:22:27
copepod can consume up to three
00:22:30
373 000 phytoplanktons per day
00:22:34
and they generally have to clear the
00:22:36
equivalent to about
00:22:37
a million times their own body volume of
00:22:40
water every day
00:22:41
to cover just their nutritional needs
00:22:45
and when you think about how much time
00:22:46
that takes and
00:22:48
what that process would look like it is
00:22:51
pretty
00:22:52
pretty crazy um just imagining how
00:22:55
humans would have to sustain themselves
00:22:56
we had to do that would be a lot of food
00:22:59
and so copepod spent a lot of their time
00:23:02
feeding and trying to find food and so
00:23:05
they
00:23:06
um because they are drifters and they
00:23:10
are not able to
00:23:12
move around say like a fish one or to
00:23:14
find its food it has to really utilize
00:23:17
um immediately what's surrounding them
00:23:20
and so
00:23:21
any advantage to be able to detect
00:23:25
phytoplankton or other types of
00:23:26
zooplankton
00:23:27
and quickly grab and eat them it would
00:23:30
be advantageous to their survival
00:23:35
all right nigerian so cnidarians
00:23:39
are there are more than 9000 living
00:23:42
species
00:23:43
in this group and they inhabit all
00:23:47
marine
00:23:47
in some freshwater environments and
00:23:51
these organisms are most abundant though
00:23:53
and diverse you'll see a lot of
00:23:55
diversity in tropical waters
00:23:58
and uh cnidarians are
00:24:01
radially symmetrical so similar parts
00:24:04
are arranged
00:24:05
symmetrically around a central disk
00:24:09
and they lack cephalization or like a
00:24:13
concentration of
00:24:14
sensory organs in the head
00:24:17
we would say maybe like the bell of like
00:24:19
a jellyfish for example
00:24:21
and with cnidarians their bodies have
00:24:24
two cell layers rather than three
00:24:27
and all cnidarians have what's called
00:24:30
pneumaticists
00:24:31
which are long thin coiled stingers
00:24:34
almost like barbs
00:24:35
and they can these barbs inject
00:24:39
uh their prey or some susp
00:24:43
you know helpless swimmer surfer with uh
00:24:46
with venom
00:24:47
and so these tiny darts are propelled
00:24:50
out of a
00:24:51
special cell and they're used to attack
00:24:54
or defend itself from animals other than
00:24:56
itself or
00:24:57
to catch its next dinner and so
00:25:00
nidarians can be broken down into
00:25:02
four major groups um anthrozoa which
00:25:06
includes
00:25:06
true corals anemones and sea pens
00:25:10
you have cubizoa the amazing box
00:25:12
jellyfish r1
00:25:14
or box jellies excuse me and
00:25:18
next you have hydrozoa they're the most
00:25:20
diverse group
00:25:21
within siphonophores hydroids
00:25:24
fire corals and many different types of
00:25:27
medusae
00:25:28
and then you have the cyphozoas or the
00:25:30
true
00:25:31
jellyfish and many nadarians
00:25:35
are mostly carnivorous and again they
00:25:38
use somaticists
00:25:39
or stinging cells to catch and grab
00:25:41
their prey
00:25:42
and these are probably some of the most
00:25:47
familiar for a lot of people when they
00:25:49
think of
00:25:50
the ocean or visiting the aquarium
00:25:52
they'll think oh i want to see the
00:25:53
jellyfish i want to see the jellyfish
00:25:55
and so
00:25:56
a lot of us have experience at least
00:25:59
visiting and seeing these in aquariums
00:26:00
and maybe some of us have experienced
00:26:02
being stung by a couple of these guys
00:26:07
so tina fours um
00:26:10
they are boop micro carnivores they like
00:26:14
to feed on smaller zooplankton and
00:26:16
platonic eggs
00:26:18
and invertebrate larvae they have eight
00:26:20
rows of
00:26:22
meridianal plates and some have two long
00:26:25
tentacles
00:26:26
and so these comb rows are few cilia
00:26:29
they're arranged along the sides
00:26:31
again of the tin of four and they're
00:26:32
clearly visible like we can see in the
00:26:34
image
00:26:35
on the right and the cilia they beat
00:26:38
together
00:26:39
and in unison and propel it helps propel
00:26:42
the tenoform in the water and
00:26:45
some species of tina four will actually
00:26:48
move with a flapping motion um
00:26:51
or like undulations of the body and
00:26:55
um yes many times many tina fours can
00:26:58
have
00:26:58
two long tentacles um on their body but
00:27:02
some also just lack tentacles completely
00:27:05
and unlike nedarians which have
00:27:10
stinging cells or neuromaticists
00:27:13
the tinophores do not instead they
00:27:16
possess sticky cells called coloblasts
00:27:20
to catch
00:27:20
and to hold on to their prey
00:27:23
and one of the most interesting
00:27:28
things about tinofors is that they have
00:27:31
they're able to um produce the slice
00:27:35
light scattering effect by beating the
00:27:38
eight rows of cilia
00:27:39
on their body and this when used when
00:27:42
they when you see the cilia moving it
00:27:44
appears like it almost like um a rainbow
00:27:47
a transition of color and it's really
00:27:49
beautiful and i
00:27:50
um i'll show you in the next slide a
00:27:52
video of this
00:27:54
and um and most people
00:27:57
assume that with ptenophores that um
00:28:00
bioluminescence is also the same rainbow
00:28:03
effect
00:28:04
that you might see but actually the
00:28:06
colors that you will
00:28:07
typically see with bioluminescence um
00:28:10
would be
00:28:11
green and blue and so
00:28:14
not all latinophores can
00:28:17
produce bioluminescence but
00:28:21
when you do see bioluminescence
00:28:23
occurring antenna force
00:28:24
it can only occur in
00:28:28
pitch black or in darkness and so
00:28:32
let's see here in the next video i just
00:28:34
want to show
00:28:36
a good example of what the tinoforms
00:28:39
look like
00:28:39
when they are beating the cilia and you
00:28:42
can see this rainbow
00:28:44
color effect happening here um
00:28:47
yes you can see it running all along
00:28:49
down here on this one
00:28:51
i'm gonna see if i can ah yes there we
00:28:54
go and you get a much better up close
00:28:55
look on what that process looks like
00:28:58
and when you see these up close
00:29:03
they are moving so quickly and they look
00:29:06
very beautiful
00:29:08
in their environment and in most
00:29:11
aquariums when they're trying to display
00:29:13
tina forest they
00:29:15
will try to display them in a darker
00:29:18
tank or
00:29:18
tank that has less light so that you
00:29:20
really can see the different colors
00:29:22
that are on the tinoforce so this is a
00:29:26
nice video to showcase and highlight
00:29:38
that
00:31:19
all right so up next we have
00:31:20
urochordates which will include
00:31:22
salps and la rossier
00:31:27
click and so
00:31:30
salps they're typically barrel-like in
00:31:33
form and they are filter-filled feeders
00:31:36
excuse me and they move
00:31:38
by contracting or pumping water through
00:31:41
their body
00:31:42
so in order to propel them through the
00:31:44
water
00:31:45
and they can be seen typically at the
00:31:47
surface
00:31:48
as a single self or you can see them in
00:31:50
these
00:31:51
massive massive colonies and so their
00:31:55
most abundant concentrations can of
00:31:58
are typically found within the southern
00:32:00
ocean near antarctica
00:32:02
and we've seen a lot of these salps of
00:32:05
salps
00:32:06
in our samples within the last couple of
00:32:08
years and
00:32:10
this is noteworthy because typically we
00:32:12
don't see
00:32:13
salps this far north especially along
00:32:17
in san diego or near san diego and so
00:32:21
there's been a lot of interest recently
00:32:23
on
00:32:24
why this is and how this will affect
00:32:28
local zooplankton populations
00:32:32
in the future and so next
00:32:35
we have larvacier and so they are
00:32:38
from the group chordata and they live in
00:32:41
gelatinous balloons
00:32:43
or what we call houses and um
00:32:47
the larvae can also be called
00:32:49
appendicularians and
00:32:51
they will periodically leave or abandon
00:32:55
their house in order to feed
00:32:57
and so they are mostly transparent
00:33:02
and they are filter feeders and they do
00:33:05
eat
00:33:06
other types of plankton or zooplankton
00:33:09
and
00:33:10
so the house portion of where
00:33:14
of the appendicular like appendicular
00:33:17
excuse me or larcier
00:33:19
is characterized by two openings and
00:33:21
they're located on
00:33:23
opposite ends of the structure of the
00:33:26
house
00:33:26
and they enclose the trunk and the body
00:33:29
and so
00:33:30
with the lavarcian they can propel the
00:33:33
house
00:33:34
forward through the water by beating its
00:33:38
tail and by beating its tail it produces
00:33:42
a current that pretty much pulls the
00:33:45
water through
00:33:46
and then forward or through the opening
00:33:49
excuse me of the house
00:33:50
and then it pushes the water back out
00:33:53
through
00:33:54
the back end of the house and so what
00:33:57
this does it
00:33:57
allows for the microscopic food
00:34:01
particles
00:34:03
to pass through and become captured
00:34:06
and then it allows for the levarcian to
00:34:10
eat and then move on and basically what
00:34:14
happens is that
00:34:15
these organisms will consistently
00:34:19
create and abandon houses several times
00:34:22
each day
00:34:22
and this is important because these
00:34:25
empty houses
00:34:27
provide valuable carbon source for
00:34:29
oceans and to help
00:34:31
produce marine snow that other types of
00:34:34
zooplankton
00:34:35
at lower depths in the um
00:34:38
in the water column feed on for their
00:34:41
source
00:34:41
of food and nutrition so these lavarcies
00:34:46
are
00:34:46
pretty cool and not much footage
00:34:50
is recorded on their feeding behavior so
00:34:52
it's always really neat
00:34:53
when we do have that footage to observe
00:34:55
how they
00:34:57
react in their natural environment for
00:35:02
this next slide we're going to be
00:35:03
talking about worms which will include
00:35:05
ketignaths and
00:35:06
polykeats and so with ketignatz
00:35:10
um this image by the way is so cool um
00:35:13
they are also known as arrow worms
00:35:16
and they can be found in open waters of
00:35:20
pretty much every ocean
00:35:21
and they range from around 0.2 to 12
00:35:24
centimeters in length
00:35:26
and they have a slender transparent body
00:35:28
with one or two pairs of fins
00:35:32
and so their head is rounded as you can
00:35:34
see in this picture
00:35:35
and armed with on each side a group of
00:35:38
grasping spines
00:35:40
and they use these spines to hunt
00:35:43
primarily on
00:35:44
copepods and so they rely on
00:35:47
the tufts of these tiny hairs and you
00:35:49
can kind of see it in this picture here
00:35:51
on their head to recognize the
00:35:53
vibrations produced by
00:35:55
by their prey and so what the ketignaths
00:35:58
will do
00:36:00
is they'll use this the hairs and
00:36:03
and actually snatch up the prey and they
00:36:07
like i said primarily feed on copepods
00:36:09
but they will also eat amphipods and
00:36:12
ostracods and other or types of worms
00:36:15
like polyketes
00:36:16
and other types of planktonic tunicates
00:36:18
as well and sometimes too
00:36:20
fish larvae and what's really cool about
00:36:23
this image is that you can see their
00:36:24
teeth and they use
00:36:27
their teeth to also capture their prey
00:36:30
and what's really interesting about
00:36:35
keating gnats excuse me is that
00:36:39
even when i i have seen these um in my
00:36:42
samples you can
00:36:44
so easily see their the head
00:36:48
and the spines and the and the jaw
00:36:50
pretty much of these keating nets and
00:36:53
they truly look like carnivorous
00:36:56
zooplankton
00:36:57
and they're ready to eat other types of
00:36:58
zooplankton
00:37:01
and then the next types of worm again
00:37:03
are polychaetes
00:37:05
and these guys are segmented worms and
00:37:07
they're among the most common marine
00:37:09
organisms that we can find out there
00:37:12
and they can be found living in depths
00:37:14
of the ocean
00:37:15
or you can find them near the surface
00:37:17
and a lot of the time
00:37:18
if you went tide pooling or out on the
00:37:21
mud flats you
00:37:22
would see them burying their bodies into
00:37:25
the sand or mud
00:37:26
at the beach and they usually have a
00:37:28
well-developed head
00:37:30
and often have are complete with
00:37:32
well-developed eyes
00:37:33
antennae and sensory palps because a lot
00:37:36
of the times
00:37:38
these polykeds can be out of the water
00:37:40
as well so they need to have
00:37:42
more developed organs and sensor or
00:37:46
sensory organs to
00:37:47
be able to detect light and oxygen
00:37:50
when they're out of the water
00:37:55
alright so pteropods or planktonic
00:37:59
snails
00:38:00
they are specialized free-swimming
00:38:02
pelagic sea snails
00:38:04
and slugs and they are characterized by
00:38:08
a foot that has been modified to form
00:38:11
a pair of wing-like flaps
00:38:15
or parapodia that allow them to actually
00:38:18
swim
00:38:19
within the water column and they can
00:38:21
actually be quite graceful when we find
00:38:23
them out
00:38:25
in the ocean and most live in the top 10
00:38:28
meters of the ocean
00:38:30
and they're pretty small so they're less
00:38:32
than about a centimeter in length
00:38:34
and pteropods include two different
00:38:37
groups
00:38:38
uh thico samada or the sea butterflies
00:38:41
or
00:38:42
not sure if i'm pronouncing this right
00:38:44
uh gymnosomata the sea angels
00:38:47
and um dico samada
00:38:51
they are the sea butterflies they
00:38:53
produce a
00:38:54
net of sticky mucus to passively collect
00:38:58
and eat marine snow
00:39:00
and so this is a great method to
00:39:03
maximize the amount of energy that
00:39:05
you're using
00:39:06
by creating just like a big
00:39:10
net to do the work for you versus trying
00:39:12
to actively go out and hunt
00:39:14
whereas with gymnosomata they do the
00:39:17
opposite and they
00:39:18
are active predators and they will go
00:39:21
out
00:39:21
and snatch up prey um
00:39:25
using these appendages that
00:39:28
look like almost like a jaw
00:39:31
of some sort and they will pull the
00:39:35
pry into their mouth to feed and so two
00:39:37
different types
00:39:38
of pteropods but
00:39:42
two very different methods for finding
00:39:44
their food
00:39:47
all right so last of the taxonomic
00:39:50
groups that we're going to cover today
00:39:51
are protists and with protists they
00:39:57
are not easily categorized and so
00:40:01
they're single-celled
00:40:02
or multicellular eukaryotic organisms
00:40:05
and
00:40:06
again like i said they can't be
00:40:07
classified strictly as
00:40:09
either a plant or an animal or a fungi
00:40:12
so
00:40:13
they don't easily fall into a single
00:40:15
taxonomic group for that reason
00:40:17
and they can be found anywhere
00:40:19
containing liquid water so
00:40:21
oceans or or some freshwater bodies as
00:40:24
well
00:40:25
um and in the oceans they exist as uh
00:40:28
types of plankton and so what we're
00:40:30
going to cover with protists today
00:40:32
is talk about three phylums in
00:40:34
particular
00:40:36
um within protista that are animal-like
00:40:40
and then that they're heterotrophic and
00:40:42
get their food
00:40:43
by consuming other types of organisms
00:40:48
and so the first one is forams or
00:40:50
foraminifera
00:40:52
and so they secrete a skeleton of
00:40:54
calcium carbonate
00:40:56
and their designs can be quite beautiful
00:40:59
and symmetrical
00:41:00
and they're common in
00:41:03
attack a common type of plankton excuse
00:41:06
me
00:41:06
and a relative of the amoeba and they
00:41:08
can range
00:41:10
from 30 micrometers to a few millimeters
00:41:13
in size so you could you can see some of
00:41:15
them with the naked eye
00:41:17
and they have pseudopodia
00:41:21
that stream from their body wall and
00:41:23
that helps them to trap food particles
00:41:26
and so they're usually bacteriopores
00:41:29
or sometimes they could be
00:41:31
photosymbiotic and so
00:41:34
this is just another way that they're
00:41:36
able to
00:41:38
sustain themselves and then they are
00:41:40
able to
00:41:41
form deep into the sediment
00:41:44
typically along the sea floor
00:41:49
and then next we have radiolaria and
00:41:52
these two
00:41:53
also secrete a skeleton but this one
00:41:55
made out of silica
00:41:56
and sometimes the designs can be quite
00:41:59
ornate as you can see in this image here
00:42:02
and they occur either singularly
00:42:05
or in colonies depending on the type of
00:42:07
species
00:42:08
and these are also a common type of
00:42:10
plankton that can range in size from 50
00:42:13
micrometers to a few millimeters
00:42:17
and some of the radiolarians that i've
00:42:19
seen in samples i could definitely see
00:42:21
just with the naked eye and they have a
00:42:24
membrane of pseudocytin that separates
00:42:26
the interior cell
00:42:28
from the exterior cytoplasm and they
00:42:31
also form sediment deep within
00:42:35
or form sediment deep and deep sea from
00:42:38
skeletons
00:42:42
and then lastly we have ciliates and so
00:42:44
ciliates are common types of plankton
00:42:46
that feed on bacteria
00:42:48
and other types of smaller phytoplankton
00:42:52
and so this sometimes makes them
00:42:53
mixotropic and
00:42:55
they can they have more of an alarm like
00:42:58
a long
00:42:59
get body structure and they range in
00:43:02
size from about 50 micrometers
00:43:04
to over a millimeter in length
00:43:07
and they can be covered in rows of cilia
00:43:11
like you can see in this image here and
00:43:14
so protists again
00:43:15
are very unique in that they're not
00:43:18
easily
00:43:19
confined to a particular category and so
00:43:22
we're learning
00:43:23
constantly learning new things about
00:43:24
protists and so our information
00:43:28
can quickly change from year to year
00:43:30
depending on what
00:43:32
new discoveries are found about about
00:43:34
protists
00:43:38
so i want to briefly talk about deal
00:43:40
vertical
00:43:41
migration and its importance in why
00:43:44
zooplankton do this and how it affects
00:43:49
community or coastal communities and
00:43:51
also
00:43:52
communities at lower depths in the water
00:43:54
column and so
00:43:56
deal vertical migration to define it is
00:43:58
synchronized movement of zooplankton
00:44:00
that move
00:44:01
up and down the water column over a
00:44:03
daily cycle
00:44:04
and a lot of people think that this may
00:44:07
be the largest
00:44:08
natural daily movement of biomass on our
00:44:11
planet
00:44:12
and to show what this looks like
00:44:15
here i have an image of
00:44:19
a ecosounder images that were collected
00:44:24
using a zooplankton acoustic profiler
00:44:27
and this is a type of active sonar
00:44:29
system that
00:44:30
both transmits and receives acoustic or
00:44:33
sound signals
00:44:34
underwater and by doing this we can
00:44:37
actually kind of visualize
00:44:40
aggregations of of whatever actually
00:44:43
really is
00:44:46
is sitting in the water at depth and so
00:44:49
what we
00:44:50
see here if we look at the surface
00:44:55
everything is nice and labeled so we
00:44:56
have surface and then
00:44:58
down below over and between 70 and 90
00:45:01
meters
00:45:02
we have an aggregation of zooplankton at
00:45:05
what looks like
00:45:06
probably around
00:45:09
12 a.m or so and as we get towards
00:45:14
near dawn we see that the aggregations
00:45:16
of zooplankton start
00:45:18
to move up in the water column so the
00:45:20
trigger
00:45:21
as to why this is occurring
00:45:25
can be a change in light intensity which
00:45:28
is probably the most likely trigger for
00:45:30
deal vertical migration and and then
00:45:33
also changes in depth are associated
00:45:36
with
00:45:37
could be associated with cloud cover or
00:45:39
eclipses phases of the moon
00:45:42
all these fluctuations in light
00:45:44
basically intensity so
00:45:46
like light plays a significant role in
00:45:50
how zooplankton travel up and down the
00:45:52
water column
00:45:53
and as you can see over a period of
00:45:55
about 12 hours
00:45:56
the zooplankton are near surface
00:46:00
most likely feeding on phytoplankton and
00:46:02
then
00:46:03
as the sunlight dissipates over the
00:46:06
evening
00:46:07
or the afternoon the aggregation of
00:46:09
zooplankton
00:46:10
go back down to depth and reside there
00:46:13
throughout the night
00:46:14
and then starting the cycle over the
00:46:16
next day
00:46:19
so there's different types of deal
00:46:21
vertical migrations
00:46:23
there's nocturnal one period of maximum
00:46:25
biomass and surface waters at night
00:46:28
there are twilight were two periods of
00:46:31
maximum biomass in surface waters
00:46:34
at dawn and at dusk and then there's
00:46:37
reverse
00:46:38
dvm which is one period of maximum
00:46:40
biomass and surface waters
00:46:43
during the daylight
00:46:46
and so with deal vertical migration
00:46:51
the range of what this occurs at could
00:46:53
be between a few centimeters or more
00:46:55
than 25 meters and what we could see in
00:46:57
the previous image is that it definitely
00:46:59
was
00:47:00
in a much larger range and some of the
00:47:04
reasons why zooplankton might
00:47:08
crack or perform deal vertical migration
00:47:10
is to
00:47:11
perhaps reduce predation by fish and
00:47:13
other predators that require
00:47:14
sight or i'm sorry require light so
00:47:17
there's sight feeders so
00:47:18
the zooplankton will stay at depth
00:47:20
during during the day to avoid predation
00:47:23
other reasons could include maximizing
00:47:25
growth efficiency
00:47:27
reducing inter-specific and
00:47:29
intra-specific competition and grazing
00:47:32
and dvm plays a large role in the active
00:47:35
transport
00:47:36
of dissolved organic matter to depth so
00:47:39
we're talking about the biological pump
00:47:42
and what that is is that it's the
00:47:43
conversion of co2
00:47:45
and inorganic nutrients by phytoplankton
00:47:48
during photosynthesis
00:47:49
as well as a cycling of calcium
00:47:51
carbonate so when zooplankton
00:47:54
are going up and down the water column
00:47:56
they are
00:47:57
eating the phytoplankton so thus
00:48:00
ingesting the co2 that has been
00:48:04
um that has been converted by the
00:48:06
phytoplankton
00:48:08
as well as creating fecal
00:48:11
pellets that drop in the water column
00:48:13
and all this
00:48:15
falls down into different depths of the
00:48:18
water column
00:48:19
which provide nutrients that other
00:48:21
marine organisms need in order to
00:48:22
survive
00:48:23
and so dvm is pretty important process
00:48:26
and
00:48:28
hopefully maybe someone in the future
00:48:30
would be interested in
00:48:31
diving deeper no pun intended into
00:48:34
expanding on why this is
00:48:36
an important role in our
00:48:40
ecosystem and why zooplankton are
00:48:43
encouraged or have adapted to perform
00:48:46
this
00:48:47
okay so now that we have covered some
00:48:49
ground
00:48:50
on what zooplankton are and getting a
00:48:53
basic introduction
00:48:56
now we can start asking some questions
00:48:59
about
00:48:59
how can we study zooplankton and for as
00:49:02
long as
00:49:04
people have been curious about the
00:49:06
natural world
00:49:07
scientists have been trying to answer
00:49:09
this question
00:49:11
and different themes that we can start
00:49:13
to think about
00:49:15
in terms of how to study zooplankton
00:49:17
might include
00:49:18
diversity abundance distribution
00:49:22
or behaviors and the next couple of
00:49:25
slides
00:49:26
we're going to go ahead and dive into
00:49:28
different examples
00:49:30
of what current grad students
00:49:34
and past grad students have worked on to
00:49:38
better answer how can we study
00:49:42
zooplankton first up we have
00:49:45
ben whitmore and he studied zooplankton
00:49:48
predator prey
00:49:49
interactions and typically um
00:49:52
sample collection is done by using
00:49:56
a large net whether it's a bongo net and
00:49:59
in this case for
00:50:00
a lot of samples that ben had looked at
00:50:02
it was collected by
00:50:03
using the mach ness and the mach ness
00:50:07
is a multiple opening closing net an
00:50:09
environmental sensing system that's
00:50:11
acronym for muchness
00:50:13
and it collects zooplankton
00:50:16
at different depths in the water column
00:50:18
and then these samples are brought back
00:50:19
to surface and are preserved
00:50:21
and so while this is a good way to
00:50:25
look at the different types of
00:50:27
zooplankton
00:50:28
that are at different depths it's not
00:50:31
the best way to
00:50:33
observe how far apart organisms are
00:50:36
and it makes it almost impossible to
00:50:39
study zooplankton predator prey
00:50:40
interactions so instead what ben had
00:50:43
done
00:50:44
instead of using a net he helped come up
00:50:47
with the idea of using
00:50:48
a high resolution camera called the
00:50:50
zocam
00:50:51
and that is attached to an unmanned
00:50:54
submersible that glides
00:50:56
through the water very slowly about four
00:50:58
inches per second so this
00:51:00
is called the zoo glider
00:51:03
and here we have two different images of
00:51:04
the zoo glider in action and as you can
00:51:07
see
00:51:07
the zocam is attached at the bottom
00:51:11
here or at the end of the zo the zo
00:51:14
glider
00:51:15
and the submersible
00:51:18
um can stay
00:51:22
goes on deployments between 14 and 30
00:51:24
days
00:51:25
and the types of metadata that are
00:51:26
collected from the zoe glider
00:51:29
would include depth and time so that
00:51:31
allows
00:51:32
ben to get a better picture or tell more
00:51:35
accurate
00:51:36
accurately how far apart the zooplankton
00:51:38
are
00:51:40
and so with that metadata when he um
00:51:44
is able to pull these images from the
00:51:47
zocam
00:51:48
he he can see where the
00:51:51
predator and potential prey are and in a
00:51:54
much better sense than if we were just
00:51:56
to collect it with
00:51:58
with a net and so in this image here we
00:52:01
see that
00:52:02
marked in blue are what looks like a
00:52:05
ketignath perhaps
00:52:07
and surrounding it in the red circles
00:52:09
are its potential prey items which
00:52:11
are most likely different types of
00:52:13
copepod
00:52:15
and this is giving us a much better
00:52:18
picture
00:52:19
and representation of the amount of prey
00:52:22
available um in in relation to
00:52:26
the different types of predators that
00:52:28
are within the water column
00:52:31
another benefit of using the zocam
00:52:34
is that it generates these amazing
00:52:36
images that have a lot of detail
00:52:38
and the difference between these images
00:52:41
and the images i'm going to show you
00:52:42
with this
00:52:42
with the zoho scan that i use is that
00:52:46
the zoe glider is able to capture the
00:52:48
zooplankton
00:52:50
in their natural posture which is really
00:52:53
important so it gives us a better
00:52:55
idea of what the different zooplankton
00:52:58
look like naturally
00:52:59
versus when they're preserved in
00:53:01
formalin
00:53:04
so next up we have
00:53:07
stephanie matthews and she studies
00:53:10
zooplankton in the mesopelagic part of
00:53:13
the ocean
00:53:14
and so here we have stephanie here
00:53:17
looking at something
00:53:18
at the microscope very classic
00:53:21
and so um mesoplagic zooplankton which
00:53:25
live in the deep ocean between 200
00:53:27
and 1000 meters are fairly small and are
00:53:30
affected by ocean currents and so
00:53:32
they're usually eaten by pelagic fish
00:53:34
such as tuna
00:53:35
or mahi mahi and again stephanie also
00:53:39
uses
00:53:39
the mach ness to collect samples
00:53:43
and also with the mach nas data such as
00:53:46
temperature
00:53:46
salinity oxygen and fluorescence is also
00:53:49
gathered
00:53:50
so what stephanie does is that she uses
00:53:52
dna sequencing to identify organisms
00:53:55
present at each location
00:53:57
and this is important because it can
00:53:59
help her
00:54:00
identify the different organisms that
00:54:03
were
00:54:03
sampled and stephanie does prefer this
00:54:06
method over microscopy which i
00:54:09
i totally understand and dna analysis
00:54:12
allows her to work with other scientists
00:54:15
that are doing sample collections in
00:54:17
different parts of the ocean
00:54:19
and compare and see what the diversity
00:54:22
looks like
00:54:24
and so here we have her looking at
00:54:28
they're getting the mach ness set up for
00:54:29
deployment
00:54:31
and her ultimate goal
00:54:35
is to map the distribution of
00:54:37
zooplankton
00:54:38
um map the distribution of zooplankton
00:54:41
species in the
00:54:43
mesopelagic ocean so that she can
00:54:45
understand
00:54:46
the what aspects of the environment are
00:54:48
important
00:54:49
for the zooplankton survival and so if
00:54:52
she can create a database
00:54:54
that includes many different species
00:54:56
with metal bar coding then she can
00:54:59
help other researchers as well identify
00:55:01
the different
00:55:02
the about abundance and diversity of
00:55:04
zooplankton in the ocean
00:55:08
okay so now we're at the part where i
00:55:12
talk about what i do
00:55:14
and so i use the zo scan to scan and
00:55:17
catalog
00:55:20
organisms that were collected at sea
00:55:23
using different types of nets
00:55:25
and so in order to actually get those
00:55:27
samples i have to go visit lindsay
00:55:29
down and she's the pelagic invertebrate
00:55:32
collections manager at scripps
00:55:34
and i gather my samples from her
00:55:37
and take him back to the lab and
00:55:38
basically i what i do with each sample
00:55:40
is i split the sample based off of size
00:55:43
and then from there i take an aliquot
00:55:47
of the different size fractions and put
00:55:50
the aliquot on the skin
00:55:52
and disperse it so that none of the
00:55:54
organisms are touching each other
00:55:56
and that's important because if the
00:55:58
organisms are touching each other and
00:56:00
you go to scan it it'll make it very
00:56:02
hard for me to
00:56:03
separate and manually sort the images
00:56:05
later
00:56:06
and so as you can see here at the bottom
00:56:08
these images
00:56:10
are very detail rich
00:56:13
and if you were to zoom in on a raw
00:56:16
image you could really see a lot
00:56:19
of characteristics in the different
00:56:22
zooplankton
00:56:23
and making sure that they're not
00:56:25
touching it helps
00:56:27
me better see the different
00:56:29
characteristics and identifying them
00:56:31
and the images that are produced using
00:56:33
the zo scan
00:56:35
are quite beautiful actually and again
00:56:38
full of detail
00:56:39
and they kind of give us a better
00:56:42
image or a better idea of what some of
00:56:46
these smaller zooplankton look like
00:56:48
and sometimes what we might do is we
00:56:50
compare those skin images with
00:56:52
images captured from the zoo scan or
00:56:54
zocam as well
00:56:57
and so what i want to show you quickly
00:56:58
is a video uh
00:57:00
like a very simple time lapse of what i
00:57:02
do in the lab
00:57:03
so here's my glamorous face just kidding
00:57:06
so what we see here
00:57:07
is just me walking around right using
00:57:09
the zo
00:57:11
scan and so i have to use a step stool
00:57:15
to get up there
00:57:16
because i am on the shorter side and
00:57:19
though this is not may not be glamorous
00:57:22
work
00:57:23
it is definitely necessary work and so
00:57:26
by
00:57:27
scanning images from these different
00:57:30
samples collected out see we're able to
00:57:31
get a snapshot
00:57:32
of the abundance of and diversity of
00:57:36
different types of
00:57:37
of zooplankton that are collected
00:57:40
from different parts along the santa
00:57:42
barbara basin
00:57:43
and other parts of the ocean so it's
00:57:47
it's good work overall
00:57:50
hey we are near the finish line i'm sure
00:57:54
you guys are ready to exit out of your
00:57:56
web browser
00:57:58
and so before we wrap it up today though
00:58:02
i just want to encourage everyone to
00:58:04
please help spread the word about marine
00:58:07
biology at
00:58:08
home and if you know someone that would
00:58:11
like to contribute
00:58:12
or you know someone that maybe would
00:58:14
like to expand
00:58:16
more on a specific topic that they have
00:58:18
seen
00:58:20
in our videos here please go ahead
00:58:23
and send them over to our facebook group
00:58:26
marine bio at home to get more info
00:58:29
and to figure out how to contribute like
00:58:32
that and so
00:58:33
thank you everyone for your support for
00:58:36
continuing to stay interested for asking
00:58:39
questions and being present
00:58:41
sometimes it can't be easy because given
00:58:44
the current situation
00:58:45
a lot of us are stuck at home so let's
00:58:48
try our best to try
00:58:50
to stay engaged with one another to
00:58:52
check in with one another
00:58:53
and to continue awesome research in the
00:58:57
sciences
00:58:57
and to report back and and tell other
00:59:00
people about what we've learned
00:59:04
and again thank you to everyone for
00:59:07
watching this video today
00:59:09
i hope that it was informative
00:59:12
enough to generate some interest for
00:59:14
yourself
00:59:15
and learn more about zooplankton and the
00:59:18
oceans
00:59:19
in general thank you to everyone that
00:59:22
contributed information for this lecture
00:59:26
and i hope that everyone has a great and
00:59:29
fantastic day
00:59:31
see you later