Salinity tolerance of Artemia and - Friends of Great Salt Lake · Brine shrimp (Artemia franciscana ) • 5-10mm length • Filter algae • Several generations per year • Winter
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Salinity tolerance of Artemia and
Ephydra: uncertainty and discrepancies
Phil Brown
Utah Division of Wildlife Resources
Great Salt Lake Ecosystem Program
Brine shrimp
(Artemia franciscana)
• 5-10mm length
• Filter algae
• Several generations per yearper year
• Winter die-off
• Produce resting eggs (cysts)
Doyle Stephens, USGS
Brine flies (genus Ephydra)
• Inhabit lake bottom
• Bioherms/ stromatolites
• Larvae feed on • Larvae feed on detritus and algae
• Adults emerge onto lake surface and shore
FOGSL 2003
Small organisms, large role
• Energy transfer up the chain (bird food)
• Nutrient cycling• Nutrient cycling
Brine shrimp (Artemia
franciscana)
Brine fly (Ephydra
cinerea)
Kerry S. Matz—Bugguide.net
Small organisms, large biomass
At peak 2008 densities:At peak 2008 densities:
• 5.8 shrimp/liter
• 94,000 tons in lake
• 13,400 bull African
elephants
• 1.3 million people
• Est. 370 million per
linear shoreline mile
• Up to 5700 larvae per
m2 of suitable lake
bed
Salinity as habitat
• Biodiversity declines as salinity increases
• A few well-adapted species remain
Predators Physiology
Effects of salinity• Increased energy cost for osmoregulation
• Lowered O2 levels may be a stress
• Reduced hatching success (brine shrimp)
• Leaves less resources for growth, reproduction
Ecologic thresholds
• Even tolerant species have their limits
• Response can be abrupt
Threshold response
African jewelfish Crop yield
J.N. Langston and P.J. Schofield
U.S. Geological Survey M.H. McCallum et al. Australian
Society of Agronomy
GSL Elevation
• Dec 2009:
4194.4 ft
• Historic
average:
4200 ft.Salin ity 2000-2010
G SL elevation 1940-2010
4190
4195
4200
4205
4210
4215
Fe
et
a.s
.l.
19631952 201019991987
• Historic low:
4191.4 ft in
1963
• Snowpack in
GSL basin is
58-67% of
normal
Salin ity 2000-2010
4
6
8
10
12
14
16
18
20
Jun
-00
No
v-0
1
Mar
-03
Au
g-0
4
De
c-05
Ap
r-0
7
Sep
-08
Jan
-10
Sa
lin
ity
(%
)
When is salinity too high?
• We need to know effects on:
– Survival, short and longer term
– Life span
– Growth– Growth
– Reproduction
– Food resources
• Existing studies are not sufficient for GSL
Consult the literature
• Little information on GSL shrimp at high salinities
Study 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28
A. franciscana 1
(GSL) 1
1
1
2
Salinity %
2
A. franciscana 3
(San Francisco) 3
3
4
5
A. franciscana 6
(New Zealand) 6
A. monica 7
8
8
8
9
A. parthenogenetica 3
3
3
Artemia franciscana
Cady et al. 1999—UDWR report
• Tested short term survival and hatching
• Poor survival above 15% salinity
• Can hatch in 8-9% maximum salinity• Can hatch in 8-9% maximum salinity
• Low sample sizes and salinities
• Leaves out long term effects
• Suggests GSL currently borderline
Artemia franciscana
VanHaecke et al. 1984
• GSL strain
• 9 day survival from 0.5-12% salinity
• Temperature tolerance
• High survival and temperature tolerance
• Salinity range too low to be applicable now
Artemia franciscana
Wear and Haslett 1987
• New Zealand strain
• Temperature interaction
• Threshold
between 20
and 26%?
• Same 120 25
• Same
species, very
different
habitat
• Contrasts w/
Cady et al.
1999
0
20
40
60
80
100
120
8% 14% 20% 26%
S alin ity
% S
urv
iva
l,
To
tal o
ffs
pri
ng
(0
.1X
)
5
9
13
17
21
25
Ma
tura
tio
n t
ime
(d
ay
s)
% Surv iv al T otal offspring M aturation time
Triantaphyllidis et al. 1995
• San Francisco Bay strain
Artemia franciscana
80
100 1600
• Reproduction
threshold
between 10
and 14%?
• 26 d survival
0
20
40
60
80
3.5% 6% 10% 14% 18%
0
400
800
1200
B rood size # broods T otal offspring
• 26 d survival
dropped at
18%
• Contrasts w/
other studies
Mono Lake Artemia
• Tolerates up to 16-18%
• No thresholds detected
• Habitat and species very different from GSL• Habitat and species very different from GSL
GSL Field Data
Field Data
2000-2009
• Salinity 9% -
18%
Salinity not
related to:6
8
10
12
14
16
18
20
Sa
lin
ity
(%
)
related to:
• # of adults
(r2 = 0.1)
• Brood size
(r2 = 0.1)
• Cyst densities
(r2 = 0.2)
6
2000 2001 2003 2004 2005 2007 2008 2010
0
1
2
3
4
5
6
7
8
2000 2001 2003 2004 2005 2007 2008 2010
Ad
ult
s (
#/l
ite
r)
What we know
• Survival, reproductive output, and body size decrease in high salinities
• Response may or may not be abrupt
– Could occur at 10-26% salinity– Could occur at 10-26% salinity
– 15% may be the optimum
• North Arm is too saline
• Salinity in early 1960s 23-28%
• Temperature makes this worse
Ephydra cinerea
• Research on this species is lacking
• Collins 1980: ecology & habitat, but no salinity
• Herbst et al. 1988: salinity tolerance of • Herbst et al. 1988: salinity tolerance of Mono Lake species (E. hians)
• More difficult to sample and keep in laboratory
What we know
• Mono Lake species tolerates up to 20%
– Signs of osmotic dehydration
• Great Salt Lake population may tolerate up to 26%up to 26%
• Eggs can tolerate up to 30%
• North Arm is too saline
What we need to know
• Detailed response of GSL population to high salinities (>16%)
– Long term survival
– Reproductive output
– Growth & development
• Threshold or linear response?
– Identify salinities at which populations are
considered impaired
What we need to know• Interacting effect of
temperature
• Effects on phytoplankton communities
• Once we know what salinity is too high, how likely are is too high, how likely are we to get there?
Context & Conclusions
• Not charismatic, but important
• Primary pathway for lake nutrients to reach waterfowl
• We do not know the upper salinity • We do not know the upper salinity tolerances
NH4+
PO43-
Context & Conclusions
• Extinction is not a concern
• Functional impairment is
• What will periodic declines do to dependent waterfowl and industry?
• Determine minimum acceptable lake level
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