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Seasonal temperature declines do not decrease periphytic surfactant biodegradation or increase algal species sensitivity
Chemosphere, Vol. 35, No. 5, pp. 1143-l 160, 1997 0 1997 Elsevier Science Ltd All rights reserved. Printed in Great Britain 00456535/97 $17.00+0.00
Pergamon
PII: SOO45-6535(97)00169-O
SEASONAL
TEMPERATURE
DECLINES
BIODEGRADATION
DO NOT DECREASE
OR INCREASE
David M. Lee*l, James B. Guckertl,
PERIPHYTIC
SURFACTANT
ALGAL SPECIES SENSITIVITY
Scott E. Belangerl
1The Procter & Gamble Company, Environmental
and Tom C.J. Feijtelz
Science Department,
Ivorydale Technical Center,
Cincinnati, Ohio 45127-1087 (USA) 2The Procter & Gamble Company, European Technical Center, Strombeek-Bever
(Belgium)
(Received in USA 27 January 1997; accepted 26 February 1997)
ABSTRACT The effects sensitivity
of seasonally are reviewed
temperatures
decreasing
on surfactant
studies conducted
ranged from 28 to 0°C over all studies and temperature
over the course of each individual with in-flowing dosed
river water temperature
from four stream mesocosm study.
Mesocosm
periphyton
biodegradation
over a 5-year period.
declines were approximately
were naturally colonized
for 8 to 11 weeks
with
ethoxysulfate
sampling period.
Mineralization
ug/L. @pb) quantities
(AES), C25Eg-alkyl of Cl2-AS
of the surfactants
ethoxylate
sulfate
heterotrophic
of AES increased
the highest
receiving
respiration.
decline. period.
between
surfactant
Mineralization Periphytic
concentration
of AE by periphyton
dose of AES and remained
during periods
dosed with final effluent increased
of seasonal
a positive temperature
slightly over the testing
algal taxonomy and biovolume were evaluated during the AES study. Overall, these tests
showed no increases in species sensitivity that there is no correlation mineralization
and mineralization
over the testing period.
between naturally decreasing
Taken collectively,
seasonal temperatures
these results indicate
and lower rates of surfactant
or increased species sensitivity by naturally acclimated periphyton.
0 1997 Elsevier Science Ltd Key words:
The
Mineralization
constant in streams receiving lower doses. All studies involving surfactant exposure demonstrated correlation
(Cl2-AS),
constant in the control streams.
results from the AE study occurred with an increase in periphyton in streams
Streams were
in the dosed streams generally increased
remained approximately
over the dosing period
9 to 14°C
(AE) or 0 to 13% final effluent during the
and AE by periphyton
over the dosing period while mineralization
Cl2-alkyl
Seasonal
on tile substrata
river water for a period of 3 to 8 weeks prior to the initiation of sampling.
C45E2.17S-alkyl
and algal
periphyton,
alkyl sulfate, alkyl ethoxysulfate,
sewage effluent, cold water, ecotoxicology 1143
alkyl ethoxylate, mesocosm,
artificial streams,
1144
1. INTRODUCTION Integration
of biodegradation
rates for chemicals discharged
sensitivity
to the chemical of concern are key components
materials that may be transported ability of environmental
to environmental
microorganisms
compound to laboratory-cultured
and evaluation
of species
of modem chemical risk assessments.
As such,
compartments
to biodegrade
and/or indigenous
into the environment are routinely
the compound
organisms.
studied with regard to the
and the relative
toxicity
of the
The objective of these tests is to accurately
predict the potential fate and effects of a compound on the aquatic environment. Conclusions
drawn from such environmental
uncertainty
testing data are often made with a degree of uncertainty.
is a result of the fact that the number of physical/chemical
variables
usually quite large and in constant flux [l].
Among these variables, differences
routinely
important
considered
Furthermore, be called
to play a particularly
the ability to extrapolate
into question
due to significant
seasonal
in temperature
role in xenobiotic-environment
laboratory, mesocosm
or field conclusions
differences
This
in the environment
is
have been
interactions
[2-71.
from region to region may
in mean and seasonal
environmental
temperatures. It has long been suspected activity, including
that seasonal
biodegradation.
decreases
in temperature
This temperature-activity
result in reduced
correlation
Q 10 principle, has been supported in a number of studies [4, 5, 8-lo]. been conducted
in the laboratory
and incubated
at temperatures
manipulations
in temperature
mineralization
and thymidine
information
regarding
the characteristics
where environmental different
samples are removed from particular
than those observed
in situ.
in stream seston [lo].
the effect of temperature
and susceptibilities
environments
Peters et al. have reported in significant
changes
that
in glucose
Thus, while these tests provide valuable
on a particular community,
of communities
based heavily on the
However, many of these studies have
as little as *5”C from in situ resulted incorporation
hypothesis,
levels of microbial
they may not accurately
that have naturally
acclimated
reflect
to changes
in
temperature. However,
a number of evaluations
automatically
decline with low or decreasing
that levels of glutamate Furthermore,
have shown that microbial activities,
uptake in Antarctic
has been shown to be especially this understanding
clear at the community
by demonstrating
Antarctic water temperature. water with temperatures biodegradation
resulting
that high levels of microbial
environments,
zones.
of unique adaptation
are not affected
the biodegradation
no correlation
by changes assemblages
While investigating between
to in
of crude oil in sea
of natural bacterial
in faster degradation.
in soils, Knaebel et al. [15] observed
and suggested
In man-made
production
down to 0°C but also showed the capability
ethoxylate
and degradation,
[l 11. This phenomenon
Siron et nl. [14] not only demonstrated
to the oil at these temperatures,
in temperate
isolated from these waters were
level [12]. Bolter and Dawson [13] contributed
that levels of secondary
acclimate
degradation.
to those observed
this work also observed that a number of bacterial organisms
uniquely adapted for growth and survival under cold conditions
do not
Mortia et al. [l l] have demonstrated
seasonal temperatures. waters are comparable
including biodegradation,
microbial
to
alkyl activity
activity may not be required for surfactant
Painter and King [ 161 showed that there was no difference
in floe
1145 formation
or growth when activated sludge is grown at 10 or 20°C.
that lowering
the temperature
(LAS) and alkyl ethoxylate porous pot activated
resulted
in only slightly decreased
(AE) biodegradation
[16].
Evaluating
sludge plants, Birch [17] observed from
9 to 15°C.
ranging
demonstrated
no decrease in linear nonionic surfactant biodegradation
sludge tests with temperatures determined
declining
bacterial
by temperature
community
time.
themselves
Tests conducted
in sediments
Diurnal temperature downstream characteristics temperature
by Kravetz
in continuous
with
et al. [18] who
flow-through
by other environmental
itself, many environmental
activated
factors and are not
variables change seasonally
[19, 201.
with the temperature-related at in situ temperatures
environmental
have suggested
to temperature-dependent
can also be very significant
with river continuum
theory.
parameters
conditions
abundance,
fluctuations
Collectively,
that exist at any
that seasonal temperature
and change predictably
measured or predicted during risk assessments and by other environmental
as a result
Thus, it is likely that the traits of a
role in changes in bacterial production,
as compared
variations
in accordance
in LAS or AE degradation
These data suggest that the levels of activity of
are influenced
with, natural shifts in temperature
may play a subordinate
consumption
sulfonate
of LAS and AE in
alone.
are tightly associated
particular
the biodegradation
were confirmed
from 25 to 8°C.
assemblages
In addition to the effects of temperature of, or in concurrence
results
this study also showed
levels of linear alkylbenzene
no difference
temperatures
natural and man-made
These
Furthermore,
shifts
biomass and oxygen
in organic
carbon
[20].
from river headwaters
these observations
to
suggest that the
are likely to be influenced by seasonal shifts in
that are themselves
altered by natural fluctuations
of
temperature. The following
reports four stream mesocosm
biodegradation
of surfactants
water was evaluated algal species determine
(2 anionic,
studies conducted over a live-year period.
1 nonionic)
by naturally acclimated
during periods of seasonal temperature
sensitivity
to surfactants
if seasonal decreases
was thoroughly
in temperature
declines.
examined.
In each study, the
periphyton
and source river
During the AES study, the level of The objective
of this analysis
result in decreases in surfactant biodegradation
was to
and increases
in algal toxicity.
2. MATERIALS 2.1 Biodegradation
AND METHODS studies - general
Surfactant biodegradation was measured water.
as the mineralization
Periphyton
was obtained
model stream ecosystem channels
studies were carried out from 1991 through of a l4C-labeled
1996. In all studies, biodegradation
tracer surfactant
by mesocosm
from the Procter and Gamble’s Experimental
facility located near Cincinnati,
Ohio, USA.
Briefly, the ESF consists
drawing source water from the Lower East Fork of the Little Miami River.
each channel was lined with terra cotta tile substrata (approximately the lower reaches were lined with trays containing long receiving
periphyton
Stream Facility
and river (ESF), a of eight
The upper reach of
8900 mm2 upper surface area), while
2 cm (average) diameter cobble. Each stream is 12-m
168 L/min and consist of 5 sections [21]: a headbox, a 5.5 m tile-lined reach, a 0.5 m flare, a
1146 5.5 m cobble reach and a 1 m tail pool.
The tile reach is an array of approximately
while the cobble reach is an array of 15 rows x 3 columns. of 3-8 weeks prior to sampling. quantities
of surfactant
characteristics).
All streams were subject to a colonization
At the end of the colonization
or effluent
Biodegradation
(“h) for a period
tests were performed
45 rows x 3 columns period
period, streams were dosed with ug/L
of .8-l 1 weeks
(see below
using tile periphyton
for individual
sampled
study
from the streams at
various times during the dosing period. 2.2 ESF operations
A detailed description
of the Experimental
Stream Facility (ESF), and its source of water, the Lower East
Fork of the Little Miami River, can be found in Belanger et al. [21]. With respect to the studies described here, the ESF channels received identical, untreated water from the Lower East Fork. After passing through a grate to remove large river debris, water from the Lower East Fork is not filtered or altered in any way prior to introduction
into the ESF.
seasonal changes, are maintained ESF is approximately
monitored
light intensity, photoperiod, influenced
between-stream
and air temperature
Natural and seasonal
changes
characteristics
monitors
for temperature,
A complete
description
considerations
were controlled and monitored to minimize system.
such as
between stream and temperature
ESF stream channels
and pH to verify source water
- 1991
to the study procedure
can be found in [22] with surrounding
dodecyl
sulfate) from August
19 to October
tiles were sampled at intervals corresponding
Periphyton
experimental
with approximately
design
= 0.867 cm2/mL).
Triplicate
random
to 0, 7, 14, 28,42 and 56 days after the initiation of Triplicate
and diluted with 0.2 urn filtered
aliquots of tile periphyton
were incubated
2.73 nCi of [ l-14C3 dodecyl sulfate (14C-C 12-AS, specific activity = 10 mCi/g) for 1 to
All incubations
were carried out at ambient
was determined
incubation vessel.
15, 1991 [23].
was scraped and brushed from the tiles, homogenized
control water (final concentration
mineralization
parameters
in [23], [24], [25], [26] and [27]. Briefly, streams were dosed with 0 to 1586 ug/L of Cl2-
alkyl sulfate (Cl2-AS,
6 hours.
[21]. Other environmental
oxygen, conductivity,
Water flow
within strict set points
in Lower East Fork stream water chemistry dissolved
including
time within the
for each stream [21].
2.3 C12-alkyl sulfate mineralization
dose.
variability
all ESF stream channels equally due to the ESF water distribution
have individual
periphyton
Water residence
for each stream channel, and rates were maintained
control to minimize
variability.
and river water characteristics,
the experiment.
4 min, resulting in minimal alterations of in situ river water temperature.
rate was automatically by computer
Thus, natural recruitment
in the facility throughout
by quantitating
Radioactivity
In addition to biodegradation C 12-AS on the mesocosm
was quantitated using liquid scintillation
determinations
community.
bacterial and algal periphyton
river water temperatures.
Radiolabeled
Cl2-AS
14C02 trapped by a KOH saturated wick placed inside the
[22], studies were conducted
counting. to evaluate the overall effect of
These studies evaluated the impact of Cl 2-AS on invertebrates
responses to C 12-AS [28], direct and indirect C 12-AS ecotoxicological
[27] and toxicity as assessed by community
analysis [24].
[26], effects
1147 2.4 ClqE3S-alkyl
ethoxysulfate
mineralization
- 1992
The mineralization
of the anionic surfactant,
14C-Cl4E3S-alkyl
similar procedures
from the CI2-AS
Streams were dosed with AES (average formula - C45E2.17S)
study.
ethoxysulfate
from August 24, 1992 through October 19, 1992. Experimental and [27].
In-stream
concentrations
and diluted as before.
60 pg/L of 14C-Cl4E3S procedure
described
Mineralization
(specific
above
activity
or by adding
aliquots
ESF periphyton
have been extensively
the 56-day exposure
to AES.
structure and function. was employed
studied with respect to algal taxonomy
Taxonomy
analyses were performed
(see [25] for complete
centric, naviculoid,
cymbelloid,
500 cells were enumerated Diatom population
using the
containing
acid.
density multiplied
etc.).
bibliography).
by the average volumetric
density alone [29].
Community
reported here, dominant
algal taxa were classified
(reviewed
unpublished
data from the Little Miami River).
species level), the taxon was excluded
“unclassitied”.
cell
as biovolume
which is the cell
during taxonomic
identifications.
of a population
to the community
present.
than cell
For the purposes
by known seasonal dominance
by [30, 311; supplemented
derived from
by [32-341 and Belanger
If seasonal or thermal preference
of the
and Lowe,
was not known (at the
from the analysis unless the genus as a whole had clear seasonal
Taxa were classified
any preference,
and
Supply, Ipswich, Great Britain).
are expressed
is the sum of all populations
of the literature
methods
counts from the Palmer-Maloney
size of the taxon determined
descriptions
tendencies.
abundances
the potential importance
biovolume
literature
of diatoms were noted (with diatoms being noted as
were calculated based on proportional
describes
and, where
Soft algae were counted using a Palmer-
Diatoms were acid cleaned using standard laboratory
Population
during
community
at the species level for diatoms
after mounting in Naphrax (Northern Biological
abundances
more accurately
and have used near identical
were sampled bi-weekly
browns, and reds). A broad use of current taxonomic
taxonomic
with corrected diatom identifications.
and remained
to vials
Five tiles were selected at random for purposes of investigating
Maloney cell (0.1 mL) volume in which the proportion
demonstrate
was determined
suspension
in [21] and [25]. Stream periphyton
possible, for soft algae (greens, cyanophytes,
preference
Mineralization
of incubated
scraped
algal taxonomy - 1992
methods from 1989-1996 as described
evaluation
tiles were sampled,
incubated with approximately
was then calculated by subtraction.
2.5 Cl4E;1S-alkyl ethoxysulfate
Biovohnne
Randomized
were then individually
= 14.0 mCi/g).
using
details of the dosing can be found in [24]
ranged from 0 to 774 ug/L.
Aliquots of diluted periphyton
(AES), was determined
as spring, summer, fall, or winter species.
it was classified as without seasonal preference. Dominance
was inferred if a population
If a taxon did not
Finally, some taxa lacked data
was >5% of the total biovolume
in
any stream on any week during the study.
2.6 C14E3-alkyl ethoxylate mineralization ESF streams November
were dosed
- I994
with 0 to 760 pg/L of C25E6-alkyl
ethoxylate
1, 1994. Tiles were sampled during the 56-day dosing period.
sealed in foil-lined, 400 mL of respective
heat sealable bags (Kapak Products, Minneapolis,
from September
6 through
Tiles with intact periphyton
Minnesota
were
USA) with approximately
stream water and tracer amounts (0.72-7.20 nCi/mL, specific activity = 14.0 mCi/g) of
1148 14C-Cl4E3
AE.
Foil-lined
and prevent gas-exchange.
bags were used as they exclude light (preventing Incubations
that received source water identical to that sent to the streams. of water were removed from the bags to vials containing the radiolabeled
Periphyton
AE was determined
by difference
by placing intact periphyton
At the end of the incubation
of the radioactivity
Winkler titrations
changes in heterotrophic
on tiles plus approximately
before and after incubation
period, aliquots Mineralization
of
remaining in the base and acid vials.
evaluated
respiration.
Periphyton
400 mL of stream water into heat-
sealable bags. The bags were then incubated overnight at in situ temperatures water bath.
in water tables at the ESF
25% H2SO4 or 0.5 M NaOH.
from this study were also used to determine
was evaluated
algal 14C02 incorporation)
were carried out at ambient temperatures
using a continuous-flow
river
the amount of oxygen used by the
heterotrophs.
2.7 Cl.+E3-alkyl ethoxylate study - 1995-96 ESF streams were colonized filtration)
for 8 weeks with combinations
from the Clermont
Co. Lower East Fork Wastewater
effluent were 0, 5 and 13% effluent. C25E6-AE
(nominal
biodegradation respective
After the colonization
concentrations)
from November
Treatment
Plant.
Final concentrations
of
period, streams were dosed with 0 or 37 ug/L
14, 1995 through
January
9, 1996.
For the
study, random tiles were sampled during the dosing period and incubated with 1500 mL of
stream water and approximately
were taken and tested for biodegradation at approximate aeration.
of river water and final effluent (prior to sand
river water temperature
Mineralization
0.72 nCi/mL of 14C-Cl4E3
AE.
21 days after the cessation of dosing.
was determined
in heat-sealable by quantifying
bags attached
An additional
set of samples
Incubations
were carried out
to a recirculating
chamber
with
the amount of 14C02 retained in two KOH bubble
traps. 2.8 Statistical Analysis
Statistical
analysis
for all measured
analysis of variance (ANOVA) responses
of stream periphyton.
discriminate asterisked
which individual (*) in the figures.
endpoints
were based on untransformed
data.
One-way
parametric
with surfactant exposure level as the treatment variable was used to assess A Least Significant treatments Significance
differed.
Differences
multiple
comparison
test was used to
Algal groups which were significantly
was inferred for all statistical tests at CL= 0.05.
different
are
All data was
analyzed using [35] or [36].
3. RESULTS
AND DISCUSSION
3.1 Seasonal changes in river water temperatures Figure 1 depicts the combined watershed
water temperature
generally begin steadily decreasing
mid-December.
data over the four studies discussed.
about the beginning
The average decrease in temperature
of September
Temperatures
in this
and continue to drop until
over the 1991- 1994 study periods was 12.2”C with an
1149 average final temperature temperature
of 125°C.
The 1995-96 AE study was conducted
had a colder initial value (-1 O’C) and dropped approximately
in the winter and river water
9°C before reaching near freezing
by the middle of the study. These temperature were observed
shifts from the fall to winter seasons in the Lower East Fork of the Little Miami River
to follow similar patterns of decline from 1991-94.
Temperature
1995-96 study indicates that the trend continues to result in water temperatures of the year.
Despite the similarity
marked by increases changing
in trend, each year demonstrates
and decreases
temperature
(decreasing
independent
that are unique to that particular in particular)
data resulting
year.
from the
near freezing prior to the end changes
in temperature
Thus, any effects of rapidly
should be clearly evident in the results of the endpoints
measured. 3.2 ClTalkyl
sulfate mineralization
The mineralization
data from the 1991 C12-AS study can be found in Figure 2.
included for all mineralization
data points to indicate standard deviations.
stream data points are quite small. Rates of CL2-AS mineralization significantly
Error bars have been
Standard deviations
of control
from control stream periphyton
were not
different at the end of the dosing period as compared to those observed at the beginning
study.
The rates of CL2-AS mineralization
study.
Spearman
rank correlation
of the
increased in all of the dosed streams during the course of the
coefficients
increase in overall turnover rates (mineralization
(based on untransformed and assimilated
dose (pcO.05, data not shown) [22]. There were no overall decreases of the streams over the dosing period and corresponding
data) also demonstrated
radiolabel)
was positively
in the levels of mineralization
river water seasonal temperature
that the
correlated
decline.
with in any
Details
are available in [22]. Previous studies have shown CL2-AS to have typically faster rates of mineralization As such, C 12-AS mineralization of mineralization
than AES or AE [37].
had the greatest potential for decrease with temperature.
In fact, a leveling
rates was observed in streams dosed with > 224 pg C12-AS/L between Days 256 through
270 during a period of particularly increases in mineralization AS mineralization
rapid temperature
decline (Fig 2). Nevertheless,
rates from Days 270 to 284, despite further temperature
all streams demonstrated decline.
data agrees with the results of Anderson et al. [38] and Zakova et al. [39], who independently C 12-AS degradation months.
Rates of CL2-
increased 0 to 4 times over the dosing period, despite a 14°C drop in temperature.
Interestingly,
by periphyton
This
reported that
in polluted sites generally remains the same during summer and winter
the ability of periphyton to rapidly degrade C 12-AS over seasonal ranges of
11.50
26 26 24 s 22 0, E z ;;i ;
20 16 16
g f
14 12
5
P
10
0 160 210 240 270 300 330 360
25
230
55
240
DayofYear
Figure 1. Seusonal temperature declines
is maintained
strains in periphyton degradation
observations,
that have the ability to produce
degradation
occurring
with the data presented
in periods of cold and decreasing
seasonal variations in the environment
3.3 Alkyl ethoxysulfate The mineralization
290
of CIJ-ulkyl
sulfate
in the number of bacterial
enzymes
of alkylsulfatases
responsible
oxygen) rather than temperature here, strongly temperatures
suggest
for Cl2-AS
was dependent
on water
specifically
[40].
that the rapid Cl2-AS
is the result of natural acclimation
to
mineralization
of radiolabeled
initiation of dose throughout
AES by mesocosm
the dosing period.
periphyton
the approximate
is depicted in Figure 3. Periphyton levels of mineralization
This level of mineralization
from the 774 ug AES/L from Day 236 through Day 263.
increased in a linear fashion through Day 291 to represent approximately incubation period.
260
and is not dependent on temperature.
the control and 13 ug AES/L streams maintained periphyton
alkylsulfatases,
that the production
oxygen demand and dissolved
combined
270
during the 1 Y91 mesocosm study.
during the winter months when there are decreases
[40]. Anderson et al. determined
quality factors (biological These
260 ofYear
Figure 2. Mineralization
during the 1991-96 mesocosm experiments temperature
250 Day
observed
from at the
was also observed in tests with The level of mineralization 75% mineralization
then
over a 2 day
1151 28
28
T
26
26
24 22
0 0
13CgAE.sIL ITlIlQAESlL
s 0,
20
f
18
t;i &
16 14
ig
,020 0251P
4
k
12
12
10 230
240
250
260 Day
270
Figure 3. Mineralization ethoxysulfate
280
290
300
240
250
260
ofYear
270 Day
of ClqE#-alkyl
Figure 4. Mineralization
during the 1992 mesocosm
280
290
300
310
ofYear
of C14E3-alkyl
ethoxysulfate during the 1994 mesocosm study
study. Temperatures
declined consistently
during the 1992 AES study from a high of 25°C to a low of about 13°C
by the eighth week of dosing (Fig 3).
While levels of mineralization
control and low dose streams, the dramatic
increase in the mineralization
stream after Day 263 (Fig 3) is likely due to a biological acclimation with an enhanced
ability to mineralize
AES.
remained
relatively
rate observed
temperatures
did not impact the
process or the resulting rates of AES mineralization.
water [42] and river water [37].
of AES is rapid in tests using periphyton
This study confirms
these results and demonstrates
maintains the ability to rapidly degrade AES during periods of decreasing
three surfactants with the greatest ramifications
Due to its apparent greater structural complexity,
potential
of decreasing
or increased.
correlations
[41], estuarine
that the periphyton temperatures.
Of the
tested, AES contains the largest number of different functional groups (alkyl chain, ethoxy
groups, sulfate group).
constant
in the high dose
While it is not known if constant or increasing
Previous studies have shown that the biodegradation community
in the
to AES which provide the community
would have affected the duration of the lag period, it appears that decreasing temperature acclimation
constant
to be negatively temperature.
These results
impacted
in terms
AES may represent the compound
of biodegradation
by thermodynamic
During the course of this study, biodegradation support the hypothesis
that laboratory-temperature
(or Q LO) may not represent actual processes and rates of metabolism
either remained biodegradation
in the environment.
3.4 Alkyl ethoxylate mineralization Figure 4 shows the results of the biodegradation mineralization
experiments
during the 1994 AE study.
levels ranged from 1O-l 5% at Day 245 to 1520%
within the control
streams
increased mineralization
increased
gradually
over the dosing period with the exception
at Day 286. Levels of mineralization
Control stream
at Day 300. The levels of mineralization of a spike of
remained similar between the control streams
1152
30 26 26
240
250
260
270
260
290
300
z
310
5 &
Day of Year
0
0
300
340
320
P
35
15
Day of Year
Figure 6. Mineralization
Figure 5. Periphyton heterotrophic
360
of ClqEj-alkyl
ethoxylate during the 1995-96 mesocosm study
respiration during the 1994 Cl4E3alkyl ethoxylate mesocosm study. throughout
the study.
all concentrations dosed
stream
subsequent
performed
decrease
higher than expected during
the
Day
approximately
Among the dosed streams, rates of mineralization
increased over the dosing period in
except the 36 pg AE/L dosed stream, which showed a slight decrease. similarly
to the control
in mineralization
286 sampling
in demonstrating
a substantial
rates between Days 272 and 300 (Fig 4).
levels of mineralization
those observed
streams
observed
has not yet been at the beginning
The 36 ug AE/L increase
and
While the reason for the
in the control streams and the 13 pg AE/L stream determined,
levels
of the dosing period,
of mineralization
returned
when the temperature
to
was 10°C
warmer. 3.5 Periphytic heterotrophic Periphyton
heterotrophic
respiration
respiration,
a more general measure of heterotrophic
endpoint evaluated during the 1994 AE study (Fig 5). All streams demonstrated respiration
during the dosing period.
Heterotrophic
respiration
stream, which demonstrated
at Day 300. Periphyton
increase
in periphytic
temperature acclimated
decreases
slightly increased
mesocosm
levels of respiration
respiration
periphyton.
from Days 272-300.
These levels of
decline of approximately
14’C.
in all streams but the 36 ug AE/L stream and the overall in all streams across the dosing period, the data indicate that
from 25 to 11“C do not result in lower
and Cl2E9 alkyl ethoxylates studies evaluated
in mineralization
bacterial
from all streams
compared to the control streams with the exception of the 760 ug AE/L
respiration were observed during a seasonal river water temperature Given the overall increase
an increase in the level of
generally increased in all streams from Day
245 through Day 286, followed by a slight decrease in respiration showed similar levels of respiration
activity, was an additional
Furthermore,
levels
of AE biodegradation
these results support the efficient
by naturally
degradation
of CL6E9
observed by Vashon and Schwab [42] as well as Larson and Games [3]. These
biodegradation
in estuarine water [42] and river water [3]. Importantly,
the latter study
1153 demonstrated
rapid biodegradation
not been acclimated
of AE over a range of temperatures
to the incubation temperatures
3.6 AK-y1 ethoxylate mineralization The 1995-96 AE mineralization over an 11-week throughout
period
at temperatures less than 1OT
study investigated
(Fig 6).
concentrations.
AE biodegradation
Temperatures
the end of the experiment.
AE and 0 to 13% effluent,
(3-34°C) by river water which had
[3].
were generally
Among periphyton
there was little variation
Levels of mineralization
increased
at very cold temperatures
WC
samples tested from streams containing
in the amount of AE mineralization
substantially
effect on AE mineralization
maintaining
temperatures.
study) indicating biodegradative
This data indicates that this phenomenon
acclimation
of the periphyton
data from the experiments
is not a requirement
for
conducted from 1991 through 1994, it is evident
of surfactant increases when the commuuity
previously
is not
on seasonal surfactant biodegradation
surfactant (Figs 2, 3 and 4). Bacterial acclimation
is exposed to higher concentrations
and the resulting faster rates of biodegradation
[37]. This study demonstrates
periods of declining seasonal temperatures
that acclimation to Cl2-AS,
of
have been
AES and AE during
is dynamic and results in an enhanced ability of the periphytic
communities
to mineralize these surfactants.
communities
in the environment
rates of degradation
data).
capacity during low and decreasing seasonal temperatures.
Evaluating the mineralization
documented
over the testing period (Fig 6).
These data also support previous control stream data (1994 AE
that substrate
3.7 Effect of surfactant concentration
that the mineralization
slightly at the
that additions of up to 13% effluent do not have a detectable
(D.M. Lee, unpublished
affected by low and decreasing mineralization
observations
0 ug/L
across effluent
by Day 332 and decreased
January 8 and January 30, 1996 samplings for a net increase in mineralization These results confirm previous
(9 to O’C)
from the fourth week of testing
These mesocosm
studies also suggest that bacterial
will respond to higher concentrations
of these surfactants resulting in faster
during periods of decreasing seasonal temperatures.
3.8 Summary of seasonal temperature effects on surfactant biodegradation
Taken collectively, periphyton declining
these data indicate
that has been naturally levels of biodegradation
lowered (not acclimated
observed
conservative
rates calculated
in laboratory
reality.
of nitrilotriacetate
solely on a thermodynamic
experiments
degradation Furthermore,
and in which microorganisms using non-acclimated
under in situ conditions basis.
This hypothesis
(NTA, a common laundry builder) concentrations
does not decrease
in
these data show that
in which temperature
This had been hypothesized
from experiments
and that acclimated microorganisms
would be predicted
of surfactant
to lower temperatures.
to lower temperatures)
systems may not reflect environmental that biodegradation
that the extent
acclimated
is artificially
are trapped in closed batch
by Larson [43], who cautioned microorganisms
were likely
may degrade substrates faster than was supported by an extended study
in Canadian water over a
1154
DominantAlgalTaxa
-
le+4
-I
220 230 240 250 260 270 280 290 300 >I"
220 230 240 250 260 270 260 290 300 310
Day of Year
Day of Year
Figure 7. Total algal community hiovolume (A) and percent contribution
of dominant taxa to community
biovolume (B) during the 1992 AES experiment. 4-year
period
[44].
demonstrated temperatures
periods
of constant
consumer
use and discharge,
the Canadian
study
in the levels of NTA from summer to winter months in surface waters when
dropped to 0°C [43, 441. These results. combined with the observations
that any decrease minimally
During
no increases
in biodegradation
caused by thermodynamic
offset by increases in biodegradation
ramifications
ability within the community
of this study, indicate
of decreased
temperature
are
as it changes and responds to
seasonal trends. 3.9 Algal species sensitivity Algal community
biovolume
increased approximately
IO-fold during the AES experiment
in all treatments
(Figure 7A). However, the highest exposure (774 c(g AESIL), and to a lesser and non-significant second highest exposure (25 1 ug AESIL) increased jn biovolume the study. This pattern is consistent
with other microbial periphyton endpoints
heterotrophic
adaptation to AES at high concentrations
microbial community
155 algal taxa were considered community
The exception
dominant at some point in the study. Figure 7B depicts the percentage
of the
of “dominant” taxa. The 24 dominant taxa were usually 95% or greater of was the high exposure (774 ug/L) stream which had a significantly present.
stream (see also [24]). By the conclusion
not described
were classified (Figure 8A).
This indicates the presence
A substantial
percentage
lower
of several new taxa unique to this
of the study there were no exposure-dependent
as spring seasonal dominants
or graphed any further.
seasonal preference
[24] and perhaps is related to 24 of
of the 24 dominants
Few taxa (
of
(Fig. 3). Approximately
which was comprised
the community. percentage
extent the
at a greater rate during the mid-portion
based on the periphyton
responses
noted.
literature and are
(20-40%) of taxa were found to have little
Many of these taxa would be considered
ubiquitous.
cosmopolitan
taxa
1155
100
100
ii 90 2
E 90
2 g
g
60
.;
70
$
70
z
60
z s
60
a ii z c z
40
5 t%
40
30
E
20
'E
20
i? ; P
10
Q $) n.
10
60
SummerAlgal Taxa
60
p0
0 220 230 240 260 260 270 260 290 300 310 Day
30
0 220 230 240 260 260 270 260 290 300 310
ofYear
Day
ofYear
100 fi
90
5
60
I
;
70
P =
60
FallAlgalTaxa
p0 s Ib
40
E 8 ; P
20
30
10 0 220 230 240 260 260 270 260 290 300 310
220 230 240 260 260 270 260 290 300 310 Day
Figure
8.
Day
ofYear
ofYear
Percent contribution of taxa without seasonal thermal preference
(A), summer seasonal
preference (B), fall seasonal preference (C) and winter seasonal preference (0). which are good colonizers
[29, 311.
enhanced at the highest concentration seen in Fig. 7A. pattern.
The proportional
The percentage
Fall seasonal taxa showed the inverse relationship
portion of the study.
Importantly,
for any seasonal group. more or less sensitive sensitive.
for the overall increase in community
was
biovolume
summer and winter taxa (Fig. 8B, SD) showed no exposure-response
(Fig. 8C) with the high exposure concentration
uniquely
of these taxa as part of the total community
and are responsible
to that of the taxa without seasonal preference
being reduced compared to other treatments
there is no clear dose-response
during the mid-
pattern that persists to the end of the study
This suggests that no one group, adapted to either warmer or colder temperatures than any other group.
Cold-adapted
Algal species are largely cosmopolitan
is
algal species by this analysis appear to not be and generally circumpolar
in distribution
[45]
1156
and many of the same or highly related taxa would be expected throughout
to exist in similar habitats
elsewhere
the world.
4. CONCLUSIONS In conclusion, maintained decreases
the mineralization
and often increased in temperature
species composition tested artificial therefore,
which occur seasonally.
temperature
in enclosed
changes
batch
winter seasons and in geographies these results
support
for macroflora
along with natural changes
which isolated These
in
studies which have
However, these laboratory
recruitment.
such
These conclusions
the naturally results
studies
occurring
presented
here,
AES and AE in temperate zones during the fall and
with extended periods of low mean river water temperatures. of biodegradation
Similar investigations
was at least
Furthermore,
differ from laboratory
correlated.
natural
safety of Cl2-AS,
the extrapolation
seasons and geographies.
preventing
in temperature.
fluctuations
and used testing procedures
systems,
support the environmental
are positively
periphyton
to the surfactant AES.
These conclusions
and biodegradation
acclimated
seasonal decreases
which undergo natural temperature
that temperature
community
during significant
by naturally
do not increase algal species sensitivity
are based on communities concluded
of three surfactants
and species
of temperature-related
and fauna which are more limited in their phenotypic
sensitivity
In addition,
for surfactants
species sensitivity
across
are likely needed
and genetic plasticity
than microbial
organisms.
ACKNOWLEDGMENTS The authors thank John Bowling, Burton Hamm, Daniel Davidson, Ellen LaBlanc, Rick Bausch, Ken Rupe, Dave Walker, Cheryl Tansky, Timothy Gsell and Roy Ventullo for their technical assistance. are grateful for the efforts of Rex Lowe (algal taxonomy) (biodegradation
The authors
as well as Robert Larson and Thomas
Federle
discussions).
REFERENCES 1.
R.M. Atlas and R. Bartha, In: Microbial Publishing
2.
Ecology
(2 nd Edition),
p. 533, The Benjamin/Cummings
Company, Inc., Menlo Park, CA (1987)
A.C. Palmisano, of xenobiotics
B.S. Schwab, D.A. Maruscik and R.M. Ventullo, by stream microbial
communities,
Canadian
Seasonal changes in mineralization
.Journul
of
Microbiology,
37,
939-947
(1991).
3.
R.J. Larson Environmental
and L.M. Science
Games,
Biodegradation
and Technology,
of linear
alcohol
15, 1488- 1493 (198 1).
ethoxylates
in natural
waters,
1157 4.
J.W. Rudd and R.D. Hamilton, Biodegradation
of trisodium nitrilotriacetate
lagoon, Journal Fisheries Research Board of Canada, 29,1203-1208 5.
6.
in a model aerated sewage
(1972).
R.J. Larson, G.G. Clinckemaillie
and L. Van Belle, Effect of temperature
biodegradation
of nitrilotriacetate,
Water Research, 15,615-620
S.B. Lartiges
and P.P. Garrigues,
pesticides
in different
Degradation
kinetics
and dissolved
(1981).
of organophosphorus
waters under various environmental
oxygen on
conditions,
and organonitrogen
Environmental
Science and
Technology, 29, 1246- 1254 (1995). 7.
L.G.
Whyte,
C.W.
psychrotrophic 8.
Greer
and
microorganisms,
W.E.
In&s,
Assessment
of the
Canadian Journal of Microbiology,
A. Barillier and J. Gamier, Influence
of temperature
biodegradation
42,99-106
and substrate concentration
yield in Seine river water batch cultures, Applied and Environmental
potential
of
(1996). on bacterial growth
Microbiology,
59, 1678-1682
(1993). 9.
T.L. Bott, Bacterial growth rates and temperature Limnology and Oceanography,
10.
29,191-197
11.
(1975).
G.T. Peters, J.R. Webster and E.F. Benfield, streams: effects of nitrogen, phosphorus
optima in a stream with a fluctuating thermal regime,
Microbial
and temperature,
activity associated
Freshwater Biology, l&405-413 (1987).
R.Y. Mortia, R.P. Griffiths and S.S. Hayasaka. Heterotrophic waters, In: Adaptations
with seston in headwater
activity of microorganisms
Within Antarctic Ecosystems, pp. 99-l 13, Gulf Publishing
in Antarctic
Company,
Houston,
Texas, (1977). 12.
13.
W.F. Vincent. Microbes and humans in Antarctica,
In: Microbial Ecosystems of Antarctica, (Edited by
W.F. Vincent) pp. 222-232,
Cambridge University Press, New York, (1988).
M. Bolter and R. Dawson,
Heterotrophic
utilisation
of biochemical
compounds
in Antarctic
waters,
Netherlands Journal of Sea Research, 16,3 15-332 (1982). 14.
R. Siron,
E. Pelleteir
petroleum
hydrocarbons
28,406-416 15.
Environmental
factors
influencing
in cold seawater, Archives of Environmental
the biodegradation
Contamination
of
and Toxicology,
(1995).
D.B. Knaebel, T.W. Federle and J.R. Vestal, Mineralization 11 contrasting
16.
and C. Brochu,
soils, Environmental
of linear alkylbenzene
H.A. Painter and E.F. King, The effect of phosphate and temperature and on biodegradation
of surfactants,
sulfonate (LAS) in
Toxicology and Chemistry, 9, 981-988 (1990). on the growth of activated sludge
Water Research, 12,909-9 15 (1978).
1158
17.
R.R. Birch, Prediction
of the fate of detergent chemicals during sewage treatment, Journal of Chemical
Technology and Biotechnology, 18.
L. Kravetz, branching
P.B. Salanitro,
50,4 1 l-422 (199 1).
P.B. Dom and K.F. Gum, Influence
on environmental
response
factors
of nonionic
of hydrophobe
type and extent of
Journal
surfactants,
of American
Oil
Chemists Society, 68, 610-618 (1991). 19.
J.R. Moeller, G.W. Minshall, K.W. Cummings, and R.L. Vannote, characteristics,
20.
21.
Transport
Organic Geochemistry,
experiments:
seasonal
mimicking
in streams
of differing
physiographic
1, 139-150 (1979).
developments
Hydrobiologia,
235/236,267-28
SE. Belanger,
J.B. Barnum, D.M. Woltering,
mesocosms.
E.M. Berghuis
of microbial
variables
and A. Kok, Mesocosm in North
Sea sediments,
1 (1992).
structure
J.W. Bowling,
and function
R.M. Ventullo,
in response
S.D. Schermerhom
to consumer
chemicals
and
in stream
In: Aquatic Mesocosm Studies in Ecological Risk Assessment (Edited by R.L. Graney, J.H. pp. 535-568, CRC Press, Boca Raton, (1994).
D.M. Lee, J.B. Guckert, R.M. Ventullo, D.H. Davidson and S.E. Belanger, Stream periphytic biodegradation
acclimation
concentrations,
Ecotoxicology
to the anionic
surfactant
supports
Environmental
rapid
Safety, in press, (1997).
and Environmental
degradation
of Cl2-alkyl
sulfate
Toxicology 6; Chemistry, 15,262-269
J.B. Guckert, Toxicity
assessment
bacterial
C 12-alkyl sulfate at environmentally-relevant
J.B. Guckert, D.D. Walker and S.E. Belanger, Environmental study
24.
carbon
Bak, A.J. Kop, G. Nieuwland,
Rodgers and J.A. Kennedy),
23.
R.C. Petersen, C.E. Cushing, J.R. Sedell, R.A. Larson organic
F.C. van Duyl, R.P.M.
R.L. Lowe. Algal periphyton
22.
of dissolved
by community
chemistry for a surfactant ecotoxicology in a continuous-flow
stream
mesocosm,
(1996). analysis, Journal of Microbiological
Methods, 25,
101-112 (1996). 25.
R.L. Lowe, periphyton mesocosms,
26.
J.B. Guckert, community
structure
Hydrobiologia,
S.E. Belanger, alkyl ethoxylate Contamination
S.E. Belanger,
D.H. Davidson
and function
on tile and cobble substrates
An evaluation
in experimental
of
stream
328, 135-146 (1996).
K.L. Rupe and R.G. Bausch, Responses sulfate
and D.W. Johnson,
anionic
surfactants
during
and Toxicology, 55, 75 l-758 (1995).
of invertebrates chronic
exposure,
and fish to alkyl sulfate and Bulletin
of Environmental
1159 27.
SE. Belanger,
E.M. Meiers and R.G. Bausch, Direct and indirect ecotoxicological
sulfate and alkyl ethoxylate
on macroinvertebrates
in stream mesocosms,
effects
of alkyl
Aquatic Toxicology, 31, 65-
87 (1995). 28.
J.B. Guckert, periphyton
29.
SE.
Belanger,
in experimental
R.J. Stevenson,
D.H. Davidson
M.L. Bothwell
and R.L. Lowe,
Responses
of algal and bacterial
during exposure to C12-alkyl sulfate, in prep., (1997).
stream mesocosms
and R.L. Lowe, In: Algal Ecology - Freshwater
Benthic Ecosystems
(1st Edition), p. 753. Academic Press, San Diego, CA (1996)
30.
S.L. Vanlandingham,
In: Guide to the Identification,
Environmental
Tolerance of Blue-Green Algae (Cyanophyta), EPA-60013-82-073 Protection
Agency, Cincinnati,
3 1. R.L. Lowe, In: Environmental United States Environmental 32.
Little
Requirements
Rivers,
and Pollution Tolerance of Freshwater
Ohio.
Effects
composition
of exposure
time, season,
of algal periphyton
In: Ecological
Assessment
American Society for Testing and Materials, Philadelphia,
C.I. Weber and B.H. McFarland. Ecological Assessment
of Efluent
by J.M. Bates and C.I. Weber), Materials, Philadelphia, 34.
substrate
type and planktonic
on artificial substrates
of Effl uent Impacts
Indigenous Aquatic Organisms (Edited by J.M. Bates and C.I. Weber),
33.
Diatoms, p. 333.
Protection Agency, Cincinnati, Ohio (1974)
on the taxonomic
Miami
and Pollution
OH (1982).
C.I. Weber and B.H. McFarland. populations
Requirements
p. 341, United States Environmental
in the Ohio and
on Communities
of
ASTM STP 730, pp. 166-219,
PA, (198 1).
Effects of copper on the periphyton Impacts on Communities
of a small calcareous
stream. In:
of Indigenous Aquatic Organisms (Edited
ASTM STP 730, pp. 101-131,
American
Society for Testing and
PA, (1981).
M.A. Lewis, Impact of a municipal wastewater
effluent on water quality periphyton
and invertebrates
in the Little Miami River near Xenia, Ohio, Ohio JournaZ of Science, 86,2-S (1986). 35.
SAS, SAS User’s Guide: Statistics, Statistical Analysis Systems, Cary, NC (1990).
36.
SAS, The SAS System for Windows, Version 3.10, Release 6.08, Cary, NC (1992).
37.
R.D. Swisher,
In: Surfactant Biodegradation
(2 nd Edition), p. 496.
Marcel Dekker, Inc., New York
(1970) 38.
D.J. Anderson,
M.J. Day, N.J. Russell and G,F. White, Die-away kinetic analysis of the capacity of
epilithic and planktonic
bacteria from clean and polluted river water to degrade sodium dodecyl sulfate,
Applied and Environmental
Microbiology,
56,758-763
(1990).
1160 39.
D. Zakova, microbial
P. Ferianc, assemblages
sulphosuccinate, 40.
41.
from water of the Danube to biodegrade
dodecyl
sulfate-degrading
Microbiology,
and epilithic
bacteria
and geographical
in a polluted
South Wales river, Applied
C. Lee, N.J. Russell and G.F. White, Modeling the kinetics of biodegradation Water Research, 29,2491-2497
of und
of anionic surfactants by
of five classes of surfactant
at three sites,
(1995).
R.D. Vashon and B.S. Schwab, Mineralization sulfates at trace concentrations
distributions
54, 555-560 (1988).
biofilm bacteria from polluted riverine sites: a comparison
42.
of planktonic
sodium dodecyl sulphate and dioctyl
M.J. Day, N.J. Russell and G.F. White, Temporal
sodium
Environmental
and D. Toth, Capacity
Biologia, 51, 259-270 (1996).
D.J. Anderson, epilithic
B. Polek, J. Godocikova
of linear alcohol ethoxylates
in estuarine water, Environmental
and linear alcohol ethoxy
Science and Technology, 16, 433-436
(1982). 43.
R.J. Larson. Role of biodegradation and Fate of Chemicals Cairns),
44.
Environment
C.R. Woodiwiss,
R.D. Walker and F.A. Brownridge,
Jr., Probable
fate. In: Biotransformation
Washington
and J.
D.C., (1980).
Concentrations
of nitrilotriacetate
and certain
and streams: 1971-1975, Water Research, 13, 599-612 (1979).
consequences
Technology, 14,41-50 (1991).
environmental
(Edited by A.W. Maki, K.L. Dickson
pp. 67-86, American Society for Microbiology,
metals in Canadian wastewaters 4.5. J. Cairns
kinetics in predicting
in the Aquatic
of a cosmopolitan
distribution,
Speculations
in Science and
Pergamon
PII: SOO45-6535(97)00169-O
SEASONAL
TEMPERATURE
DECLINES
BIODEGRADATION
DO NOT DECREASE
OR INCREASE
David M. Lee*l, James B. Guckertl,
PERIPHYTIC
SURFACTANT
ALGAL SPECIES SENSITIVITY
Scott E. Belangerl
1The Procter & Gamble Company, Environmental
and Tom C.J. Feijtelz
Science Department,
Ivorydale Technical Center,
Cincinnati, Ohio 45127-1087 (USA) 2The Procter & Gamble Company, European Technical Center, Strombeek-Bever
(Belgium)
(Received in USA 27 January 1997; accepted 26 February 1997)
ABSTRACT The effects sensitivity
of seasonally are reviewed
temperatures
decreasing
on surfactant
studies conducted
ranged from 28 to 0°C over all studies and temperature
over the course of each individual with in-flowing dosed
river water temperature
from four stream mesocosm study.
Mesocosm
periphyton
biodegradation
over a 5-year period.
declines were approximately
were naturally colonized
for 8 to 11 weeks
with
ethoxysulfate
sampling period.
Mineralization
ug/L. @pb) quantities
(AES), C25Eg-alkyl of Cl2-AS
of the surfactants
ethoxylate
sulfate
heterotrophic
of AES increased
the highest
receiving
respiration.
decline. period.
between
surfactant
Mineralization Periphytic
concentration
of AE by periphyton
dose of AES and remained
during periods
dosed with final effluent increased
of seasonal
a positive temperature
slightly over the testing
algal taxonomy and biovolume were evaluated during the AES study. Overall, these tests
showed no increases in species sensitivity that there is no correlation mineralization
and mineralization
over the testing period.
between naturally decreasing
Taken collectively,
seasonal temperatures
these results indicate
and lower rates of surfactant
or increased species sensitivity by naturally acclimated periphyton.
0 1997 Elsevier Science Ltd Key words:
The
Mineralization
constant in streams receiving lower doses. All studies involving surfactant exposure demonstrated correlation
(Cl2-AS),
constant in the control streams.
results from the AE study occurred with an increase in periphyton in streams
Streams were
in the dosed streams generally increased
remained approximately
over the dosing period
9 to 14°C
(AE) or 0 to 13% final effluent during the
and AE by periphyton
over the dosing period while mineralization
Cl2-alkyl
Seasonal
on tile substrata
river water for a period of 3 to 8 weeks prior to the initiation of sampling.
C45E2.17S-alkyl
and algal
periphyton,
alkyl sulfate, alkyl ethoxysulfate,
sewage effluent, cold water, ecotoxicology 1143
alkyl ethoxylate, mesocosm,
artificial streams,
1144
1. INTRODUCTION Integration
of biodegradation
rates for chemicals discharged
sensitivity
to the chemical of concern are key components
materials that may be transported ability of environmental
to environmental
microorganisms
compound to laboratory-cultured
and evaluation
of species
of modem chemical risk assessments.
As such,
compartments
to biodegrade
and/or indigenous
into the environment are routinely
the compound
organisms.
studied with regard to the
and the relative
toxicity
of the
The objective of these tests is to accurately
predict the potential fate and effects of a compound on the aquatic environment. Conclusions
drawn from such environmental
uncertainty
testing data are often made with a degree of uncertainty.
is a result of the fact that the number of physical/chemical
variables
usually quite large and in constant flux [l].
Among these variables, differences
routinely
important
considered
Furthermore, be called
to play a particularly
the ability to extrapolate
into question
due to significant
seasonal
in temperature
role in xenobiotic-environment
laboratory, mesocosm
or field conclusions
differences
This
in the environment
is
have been
interactions
[2-71.
from region to region may
in mean and seasonal
environmental
temperatures. It has long been suspected activity, including
that seasonal
biodegradation.
decreases
in temperature
This temperature-activity
result in reduced
correlation
Q 10 principle, has been supported in a number of studies [4, 5, 8-lo]. been conducted
in the laboratory
and incubated
at temperatures
manipulations
in temperature
mineralization
and thymidine
information
regarding
the characteristics
where environmental different
samples are removed from particular
than those observed
in situ.
in stream seston [lo].
the effect of temperature
and susceptibilities
environments
Peters et al. have reported in significant
changes
that
in glucose
Thus, while these tests provide valuable
on a particular community,
of communities
based heavily on the
However, many of these studies have
as little as *5”C from in situ resulted incorporation
hypothesis,
levels of microbial
they may not accurately
that have naturally
acclimated
reflect
to changes
in
temperature. However,
a number of evaluations
automatically
decline with low or decreasing
that levels of glutamate Furthermore,
have shown that microbial activities,
uptake in Antarctic
has been shown to be especially this understanding
clear at the community
by demonstrating
Antarctic water temperature. water with temperatures biodegradation
resulting
that high levels of microbial
environments,
zones.
of unique adaptation
are not affected
the biodegradation
no correlation
by changes assemblages
While investigating between
to in
of crude oil in sea
of natural bacterial
in faster degradation.
in soils, Knaebel et al. [15] observed
and suggested
In man-made
production
down to 0°C but also showed the capability
ethoxylate
and degradation,
[l 11. This phenomenon
Siron et nl. [14] not only demonstrated
to the oil at these temperatures,
in temperate
isolated from these waters were
level [12]. Bolter and Dawson [13] contributed
that levels of secondary
acclimate
degradation.
to those observed
this work also observed that a number of bacterial organisms
uniquely adapted for growth and survival under cold conditions
do not
Mortia et al. [l l] have demonstrated
seasonal temperatures. waters are comparable
including biodegradation,
microbial
to
alkyl activity
activity may not be required for surfactant
Painter and King [ 161 showed that there was no difference
in floe
1145 formation
or growth when activated sludge is grown at 10 or 20°C.
that lowering
the temperature
(LAS) and alkyl ethoxylate porous pot activated
resulted
in only slightly decreased
(AE) biodegradation
[16].
Evaluating
sludge plants, Birch [17] observed from
9 to 15°C.
ranging
demonstrated
no decrease in linear nonionic surfactant biodegradation
sludge tests with temperatures determined
declining
bacterial
by temperature
community
time.
themselves
Tests conducted
in sediments
Diurnal temperature downstream characteristics temperature
by Kravetz
in continuous
with
et al. [18] who
flow-through
by other environmental
itself, many environmental
activated
factors and are not
variables change seasonally
[19, 201.
with the temperature-related at in situ temperatures
environmental
have suggested
to temperature-dependent
can also be very significant
with river continuum
theory.
parameters
conditions
abundance,
fluctuations
Collectively,
that exist at any
that seasonal temperature
and change predictably
measured or predicted during risk assessments and by other environmental
as a result
Thus, it is likely that the traits of a
role in changes in bacterial production,
as compared
variations
in accordance
in LAS or AE degradation
These data suggest that the levels of activity of
are influenced
with, natural shifts in temperature
may play a subordinate
consumption
sulfonate
of LAS and AE in
alone.
are tightly associated
particular
the biodegradation
were confirmed
from 25 to 8°C.
assemblages
In addition to the effects of temperature of, or in concurrence
results
this study also showed
levels of linear alkylbenzene
no difference
temperatures
natural and man-made
These
Furthermore,
shifts
biomass and oxygen
in organic
carbon
[20].
from river headwaters
these observations
to
suggest that the
are likely to be influenced by seasonal shifts in
that are themselves
altered by natural fluctuations
of
temperature. The following
reports four stream mesocosm
biodegradation
of surfactants
water was evaluated algal species determine
(2 anionic,
studies conducted over a live-year period.
1 nonionic)
by naturally acclimated
during periods of seasonal temperature
sensitivity
to surfactants
if seasonal decreases
was thoroughly
in temperature
declines.
examined.
In each study, the
periphyton
and source river
During the AES study, the level of The objective
of this analysis
result in decreases in surfactant biodegradation
was to
and increases
in algal toxicity.
2. MATERIALS 2.1 Biodegradation
AND METHODS studies - general
Surfactant biodegradation was measured water.
as the mineralization
Periphyton
was obtained
model stream ecosystem channels
studies were carried out from 1991 through of a l4C-labeled
1996. In all studies, biodegradation
tracer surfactant
by mesocosm
from the Procter and Gamble’s Experimental
facility located near Cincinnati,
Ohio, USA.
Briefly, the ESF consists
drawing source water from the Lower East Fork of the Little Miami River.
each channel was lined with terra cotta tile substrata (approximately the lower reaches were lined with trays containing long receiving
periphyton
Stream Facility
and river (ESF), a of eight
The upper reach of
8900 mm2 upper surface area), while
2 cm (average) diameter cobble. Each stream is 12-m
168 L/min and consist of 5 sections [21]: a headbox, a 5.5 m tile-lined reach, a 0.5 m flare, a
1146 5.5 m cobble reach and a 1 m tail pool.
The tile reach is an array of approximately
while the cobble reach is an array of 15 rows x 3 columns. of 3-8 weeks prior to sampling. quantities
of surfactant
characteristics).
All streams were subject to a colonization
At the end of the colonization
or effluent
Biodegradation
(“h) for a period
tests were performed
45 rows x 3 columns period
period, streams were dosed with ug/L
of .8-l 1 weeks
(see below
using tile periphyton
for individual
sampled
study
from the streams at
various times during the dosing period. 2.2 ESF operations
A detailed description
of the Experimental
Stream Facility (ESF), and its source of water, the Lower East
Fork of the Little Miami River, can be found in Belanger et al. [21]. With respect to the studies described here, the ESF channels received identical, untreated water from the Lower East Fork. After passing through a grate to remove large river debris, water from the Lower East Fork is not filtered or altered in any way prior to introduction
into the ESF.
seasonal changes, are maintained ESF is approximately
monitored
light intensity, photoperiod, influenced
between-stream
and air temperature
Natural and seasonal
changes
characteristics
monitors
for temperature,
A complete
description
considerations
were controlled and monitored to minimize system.
such as
between stream and temperature
ESF stream channels
and pH to verify source water
- 1991
to the study procedure
can be found in [22] with surrounding
dodecyl
sulfate) from August
19 to October
tiles were sampled at intervals corresponding
Periphyton
experimental
with approximately
design
= 0.867 cm2/mL).
Triplicate
random
to 0, 7, 14, 28,42 and 56 days after the initiation of Triplicate
and diluted with 0.2 urn filtered
aliquots of tile periphyton
were incubated
2.73 nCi of [ l-14C3 dodecyl sulfate (14C-C 12-AS, specific activity = 10 mCi/g) for 1 to
All incubations
were carried out at ambient
was determined
incubation vessel.
15, 1991 [23].
was scraped and brushed from the tiles, homogenized
control water (final concentration
mineralization
parameters
in [23], [24], [25], [26] and [27]. Briefly, streams were dosed with 0 to 1586 ug/L of Cl2-
alkyl sulfate (Cl2-AS,
6 hours.
[21]. Other environmental
oxygen, conductivity,
Water flow
within strict set points
in Lower East Fork stream water chemistry dissolved
including
time within the
for each stream [21].
2.3 C12-alkyl sulfate mineralization
dose.
variability
all ESF stream channels equally due to the ESF water distribution
have individual
periphyton
Water residence
for each stream channel, and rates were maintained
control to minimize
variability.
and river water characteristics,
the experiment.
4 min, resulting in minimal alterations of in situ river water temperature.
rate was automatically by computer
Thus, natural recruitment
in the facility throughout
by quantitating
Radioactivity
In addition to biodegradation C 12-AS on the mesocosm
was quantitated using liquid scintillation
determinations
community.
bacterial and algal periphyton
river water temperatures.
Radiolabeled
Cl2-AS
14C02 trapped by a KOH saturated wick placed inside the
[22], studies were conducted
counting. to evaluate the overall effect of
These studies evaluated the impact of Cl 2-AS on invertebrates
responses to C 12-AS [28], direct and indirect C 12-AS ecotoxicological
[27] and toxicity as assessed by community
analysis [24].
[26], effects
1147 2.4 ClqE3S-alkyl
ethoxysulfate
mineralization
- 1992
The mineralization
of the anionic surfactant,
14C-Cl4E3S-alkyl
similar procedures
from the CI2-AS
Streams were dosed with AES (average formula - C45E2.17S)
study.
ethoxysulfate
from August 24, 1992 through October 19, 1992. Experimental and [27].
In-stream
concentrations
and diluted as before.
60 pg/L of 14C-Cl4E3S procedure
described
Mineralization
(specific
above
activity
or by adding
aliquots
ESF periphyton
have been extensively
the 56-day exposure
to AES.
structure and function. was employed
studied with respect to algal taxonomy
Taxonomy
analyses were performed
(see [25] for complete
centric, naviculoid,
cymbelloid,
500 cells were enumerated Diatom population
using the
containing
acid.
density multiplied
etc.).
bibliography).
by the average volumetric
density alone [29].
Community
reported here, dominant
algal taxa were classified
(reviewed
unpublished
data from the Little Miami River).
species level), the taxon was excluded
“unclassitied”.
cell
as biovolume
which is the cell
during taxonomic
identifications.
of a population
to the community
present.
than cell
For the purposes
by known seasonal dominance
by [30, 311; supplemented
derived from
by [32-341 and Belanger
If seasonal or thermal preference
of the
and Lowe,
was not known (at the
from the analysis unless the genus as a whole had clear seasonal
Taxa were classified
any preference,
and
Supply, Ipswich, Great Britain).
are expressed
is the sum of all populations
of the literature
methods
counts from the Palmer-Maloney
size of the taxon determined
descriptions
tendencies.
abundances
the potential importance
biovolume
literature
of diatoms were noted (with diatoms being noted as
were calculated based on proportional
describes
and, where
Soft algae were counted using a Palmer-
Diatoms were acid cleaned using standard laboratory
Population
during
community
at the species level for diatoms
after mounting in Naphrax (Northern Biological
abundances
more accurately
and have used near identical
were sampled bi-weekly
browns, and reds). A broad use of current taxonomic
taxonomic
with corrected diatom identifications.
and remained
to vials
Five tiles were selected at random for purposes of investigating
Maloney cell (0.1 mL) volume in which the proportion
demonstrate
was determined
suspension
in [21] and [25]. Stream periphyton
possible, for soft algae (greens, cyanophytes,
preference
Mineralization
of incubated
scraped
algal taxonomy - 1992
methods from 1989-1996 as described
evaluation
tiles were sampled,
incubated with approximately
was then calculated by subtraction.
2.5 Cl4E;1S-alkyl ethoxysulfate
Biovohnne
Randomized
were then individually
= 14.0 mCi/g).
using
details of the dosing can be found in [24]
ranged from 0 to 774 ug/L.
Aliquots of diluted periphyton
(AES), was determined
as spring, summer, fall, or winter species.
it was classified as without seasonal preference. Dominance
was inferred if a population
If a taxon did not
Finally, some taxa lacked data
was >5% of the total biovolume
in
any stream on any week during the study.
2.6 C14E3-alkyl ethoxylate mineralization ESF streams November
were dosed
- I994
with 0 to 760 pg/L of C25E6-alkyl
ethoxylate
1, 1994. Tiles were sampled during the 56-day dosing period.
sealed in foil-lined, 400 mL of respective
heat sealable bags (Kapak Products, Minneapolis,
from September
6 through
Tiles with intact periphyton
Minnesota
were
USA) with approximately
stream water and tracer amounts (0.72-7.20 nCi/mL, specific activity = 14.0 mCi/g) of
1148 14C-Cl4E3
AE.
Foil-lined
and prevent gas-exchange.
bags were used as they exclude light (preventing Incubations
that received source water identical to that sent to the streams. of water were removed from the bags to vials containing the radiolabeled
Periphyton
AE was determined
by difference
by placing intact periphyton
At the end of the incubation
of the radioactivity
Winkler titrations
changes in heterotrophic
on tiles plus approximately
before and after incubation
period, aliquots Mineralization
of
remaining in the base and acid vials.
evaluated
respiration.
Periphyton
400 mL of stream water into heat-
sealable bags. The bags were then incubated overnight at in situ temperatures water bath.
in water tables at the ESF
25% H2SO4 or 0.5 M NaOH.
from this study were also used to determine
was evaluated
algal 14C02 incorporation)
were carried out at ambient temperatures
using a continuous-flow
river
the amount of oxygen used by the
heterotrophs.
2.7 Cl.+E3-alkyl ethoxylate study - 1995-96 ESF streams were colonized filtration)
for 8 weeks with combinations
from the Clermont
Co. Lower East Fork Wastewater
effluent were 0, 5 and 13% effluent. C25E6-AE
(nominal
biodegradation respective
After the colonization
concentrations)
from November
Treatment
Plant.
Final concentrations
of
period, streams were dosed with 0 or 37 ug/L
14, 1995 through
January
9, 1996.
For the
study, random tiles were sampled during the dosing period and incubated with 1500 mL of
stream water and approximately
were taken and tested for biodegradation at approximate aeration.
of river water and final effluent (prior to sand
river water temperature
Mineralization
0.72 nCi/mL of 14C-Cl4E3
AE.
21 days after the cessation of dosing.
was determined
in heat-sealable by quantifying
bags attached
An additional
set of samples
Incubations
were carried out
to a recirculating
chamber
with
the amount of 14C02 retained in two KOH bubble
traps. 2.8 Statistical Analysis
Statistical
analysis
for all measured
analysis of variance (ANOVA) responses
of stream periphyton.
discriminate asterisked
which individual (*) in the figures.
endpoints
were based on untransformed
data.
One-way
parametric
with surfactant exposure level as the treatment variable was used to assess A Least Significant treatments Significance
differed.
Differences
multiple
comparison
test was used to
Algal groups which were significantly
was inferred for all statistical tests at CL= 0.05.
different
are
All data was
analyzed using [35] or [36].
3. RESULTS
AND DISCUSSION
3.1 Seasonal changes in river water temperatures Figure 1 depicts the combined watershed
water temperature
generally begin steadily decreasing
mid-December.
data over the four studies discussed.
about the beginning
The average decrease in temperature
of September
Temperatures
in this
and continue to drop until
over the 1991- 1994 study periods was 12.2”C with an
1149 average final temperature temperature
of 125°C.
The 1995-96 AE study was conducted
had a colder initial value (-1 O’C) and dropped approximately
in the winter and river water
9°C before reaching near freezing
by the middle of the study. These temperature were observed
shifts from the fall to winter seasons in the Lower East Fork of the Little Miami River
to follow similar patterns of decline from 1991-94.
Temperature
1995-96 study indicates that the trend continues to result in water temperatures of the year.
Despite the similarity
marked by increases changing
in trend, each year demonstrates
and decreases
temperature
(decreasing
independent
that are unique to that particular in particular)
data resulting
year.
from the
near freezing prior to the end changes
in temperature
Thus, any effects of rapidly
should be clearly evident in the results of the endpoints
measured. 3.2 ClTalkyl
sulfate mineralization
The mineralization
data from the 1991 C12-AS study can be found in Figure 2.
included for all mineralization
data points to indicate standard deviations.
stream data points are quite small. Rates of CL2-AS mineralization significantly
Error bars have been
Standard deviations
of control
from control stream periphyton
were not
different at the end of the dosing period as compared to those observed at the beginning
study.
The rates of CL2-AS mineralization
study.
Spearman
rank correlation
of the
increased in all of the dosed streams during the course of the
coefficients
increase in overall turnover rates (mineralization
(based on untransformed and assimilated
dose (pcO.05, data not shown) [22]. There were no overall decreases of the streams over the dosing period and corresponding
data) also demonstrated
radiolabel)
was positively
in the levels of mineralization
river water seasonal temperature
that the
correlated
decline.
with in any
Details
are available in [22]. Previous studies have shown CL2-AS to have typically faster rates of mineralization As such, C 12-AS mineralization of mineralization
than AES or AE [37].
had the greatest potential for decrease with temperature.
In fact, a leveling
rates was observed in streams dosed with > 224 pg C12-AS/L between Days 256 through
270 during a period of particularly increases in mineralization AS mineralization
rapid temperature
decline (Fig 2). Nevertheless,
rates from Days 270 to 284, despite further temperature
all streams demonstrated decline.
data agrees with the results of Anderson et al. [38] and Zakova et al. [39], who independently C 12-AS degradation months.
Rates of CL2-
increased 0 to 4 times over the dosing period, despite a 14°C drop in temperature.
Interestingly,
by periphyton
This
reported that
in polluted sites generally remains the same during summer and winter
the ability of periphyton to rapidly degrade C 12-AS over seasonal ranges of
11.50
26 26 24 s 22 0, E z ;;i ;
20 16 16
g f
14 12
5
P
10
0 160 210 240 270 300 330 360
25
230
55
240
DayofYear
Figure 1. Seusonal temperature declines
is maintained
strains in periphyton degradation
observations,
that have the ability to produce
degradation
occurring
with the data presented
in periods of cold and decreasing
seasonal variations in the environment
3.3 Alkyl ethoxysulfate The mineralization
290
of CIJ-ulkyl
sulfate
in the number of bacterial
enzymes
of alkylsulfatases
responsible
oxygen) rather than temperature here, strongly temperatures
suggest
for Cl2-AS
was dependent
on water
specifically
[40].
that the rapid Cl2-AS
is the result of natural acclimation
to
mineralization
of radiolabeled
initiation of dose throughout
AES by mesocosm
the dosing period.
periphyton
the approximate
is depicted in Figure 3. Periphyton levels of mineralization
This level of mineralization
from the 774 ug AES/L from Day 236 through Day 263.
increased in a linear fashion through Day 291 to represent approximately incubation period.
260
and is not dependent on temperature.
the control and 13 ug AES/L streams maintained periphyton
alkylsulfatases,
that the production
oxygen demand and dissolved
combined
270
during the 1 Y91 mesocosm study.
during the winter months when there are decreases
[40]. Anderson et al. determined
quality factors (biological These
260 ofYear
Figure 2. Mineralization
during the 1991-96 mesocosm experiments temperature
250 Day
observed
from at the
was also observed in tests with The level of mineralization 75% mineralization
then
over a 2 day
1151 28
28
T
26
26
24 22
0 0
13CgAE.sIL ITlIlQAESlL
s 0,
20
f
18
t;i &
16 14
ig
,020 0251P
4
k
12
12
10 230
240
250
260 Day
270
Figure 3. Mineralization ethoxysulfate
280
290
300
240
250
260
ofYear
270 Day
of ClqE#-alkyl
Figure 4. Mineralization
during the 1992 mesocosm
280
290
300
310
ofYear
of C14E3-alkyl
ethoxysulfate during the 1994 mesocosm study
study. Temperatures
declined consistently
during the 1992 AES study from a high of 25°C to a low of about 13°C
by the eighth week of dosing (Fig 3).
While levels of mineralization
control and low dose streams, the dramatic
increase in the mineralization
stream after Day 263 (Fig 3) is likely due to a biological acclimation with an enhanced
ability to mineralize
AES.
remained
relatively
rate observed
temperatures
did not impact the
process or the resulting rates of AES mineralization.
water [42] and river water [37].
of AES is rapid in tests using periphyton
This study confirms
these results and demonstrates
maintains the ability to rapidly degrade AES during periods of decreasing
three surfactants with the greatest ramifications
Due to its apparent greater structural complexity,
potential
of decreasing
or increased.
correlations
[41], estuarine
that the periphyton temperatures.
Of the
tested, AES contains the largest number of different functional groups (alkyl chain, ethoxy
groups, sulfate group).
constant
in the high dose
While it is not known if constant or increasing
Previous studies have shown that the biodegradation community
in the
to AES which provide the community
would have affected the duration of the lag period, it appears that decreasing temperature acclimation
constant
to be negatively temperature.
These results
impacted
in terms
AES may represent the compound
of biodegradation
by thermodynamic
During the course of this study, biodegradation support the hypothesis
that laboratory-temperature
(or Q LO) may not represent actual processes and rates of metabolism
either remained biodegradation
in the environment.
3.4 Alkyl ethoxylate mineralization Figure 4 shows the results of the biodegradation mineralization
experiments
during the 1994 AE study.
levels ranged from 1O-l 5% at Day 245 to 1520%
within the control
streams
increased mineralization
increased
gradually
over the dosing period with the exception
at Day 286. Levels of mineralization
Control stream
at Day 300. The levels of mineralization of a spike of
remained similar between the control streams
1152
30 26 26
240
250
260
270
260
290
300
z
310
5 &
Day of Year
0
0
300
340
320
P
35
15
Day of Year
Figure 6. Mineralization
Figure 5. Periphyton heterotrophic
360
of ClqEj-alkyl
ethoxylate during the 1995-96 mesocosm study
respiration during the 1994 Cl4E3alkyl ethoxylate mesocosm study. throughout
the study.
all concentrations dosed
stream
subsequent
performed
decrease
higher than expected during
the
Day
approximately
Among the dosed streams, rates of mineralization
increased over the dosing period in
except the 36 pg AE/L dosed stream, which showed a slight decrease. similarly
to the control
in mineralization
286 sampling
in demonstrating
a substantial
rates between Days 272 and 300 (Fig 4).
levels of mineralization
those observed
streams
observed
has not yet been at the beginning
The 36 ug AE/L increase
and
While the reason for the
in the control streams and the 13 pg AE/L stream determined,
levels
of the dosing period,
of mineralization
returned
when the temperature
to
was 10°C
warmer. 3.5 Periphytic heterotrophic Periphyton
heterotrophic
respiration
respiration,
a more general measure of heterotrophic
endpoint evaluated during the 1994 AE study (Fig 5). All streams demonstrated respiration
during the dosing period.
Heterotrophic
respiration
stream, which demonstrated
at Day 300. Periphyton
increase
in periphytic
temperature acclimated
decreases
slightly increased
mesocosm
levels of respiration
respiration
periphyton.
from Days 272-300.
These levels of
decline of approximately
14’C.
in all streams but the 36 ug AE/L stream and the overall in all streams across the dosing period, the data indicate that
from 25 to 11“C do not result in lower
and Cl2E9 alkyl ethoxylates studies evaluated
in mineralization
bacterial
from all streams
compared to the control streams with the exception of the 760 ug AE/L
respiration were observed during a seasonal river water temperature Given the overall increase
an increase in the level of
generally increased in all streams from Day
245 through Day 286, followed by a slight decrease in respiration showed similar levels of respiration
activity, was an additional
Furthermore,
levels
of AE biodegradation
these results support the efficient
by naturally
degradation
of CL6E9
observed by Vashon and Schwab [42] as well as Larson and Games [3]. These
biodegradation
in estuarine water [42] and river water [3]. Importantly,
the latter study
1153 demonstrated
rapid biodegradation
not been acclimated
of AE over a range of temperatures
to the incubation temperatures
3.6 AK-y1 ethoxylate mineralization The 1995-96 AE mineralization over an 11-week throughout
period
at temperatures less than 1OT
study investigated
(Fig 6).
concentrations.
AE biodegradation
Temperatures
the end of the experiment.
AE and 0 to 13% effluent,
(3-34°C) by river water which had
[3].
were generally
Among periphyton
there was little variation
Levels of mineralization
increased
at very cold temperatures
WC
samples tested from streams containing
in the amount of AE mineralization
substantially
effect on AE mineralization
maintaining
temperatures.
study) indicating biodegradative
This data indicates that this phenomenon
acclimation
of the periphyton
data from the experiments
is not a requirement
for
conducted from 1991 through 1994, it is evident
of surfactant increases when the commuuity
previously
is not
on seasonal surfactant biodegradation
surfactant (Figs 2, 3 and 4). Bacterial acclimation
is exposed to higher concentrations
and the resulting faster rates of biodegradation
[37]. This study demonstrates
periods of declining seasonal temperatures
that acclimation to Cl2-AS,
of
have been
AES and AE during
is dynamic and results in an enhanced ability of the periphytic
communities
to mineralize these surfactants.
communities
in the environment
rates of degradation
data).
capacity during low and decreasing seasonal temperatures.
Evaluating the mineralization
documented
over the testing period (Fig 6).
These data also support previous control stream data (1994 AE
that substrate
3.7 Effect of surfactant concentration
that the mineralization
slightly at the
that additions of up to 13% effluent do not have a detectable
(D.M. Lee, unpublished
affected by low and decreasing mineralization
observations
0 ug/L
across effluent
by Day 332 and decreased
January 8 and January 30, 1996 samplings for a net increase in mineralization These results confirm previous
(9 to O’C)
from the fourth week of testing
These mesocosm
studies also suggest that bacterial
will respond to higher concentrations
of these surfactants resulting in faster
during periods of decreasing seasonal temperatures.
3.8 Summary of seasonal temperature effects on surfactant biodegradation
Taken collectively, periphyton declining
these data indicate
that has been naturally levels of biodegradation
lowered (not acclimated
observed
conservative
rates calculated
in laboratory
reality.
of nitrilotriacetate
solely on a thermodynamic
experiments
degradation Furthermore,
and in which microorganisms using non-acclimated
under in situ conditions basis.
This hypothesis
(NTA, a common laundry builder) concentrations
does not decrease
in
these data show that
in which temperature
This had been hypothesized
from experiments
and that acclimated microorganisms
would be predicted
of surfactant
to lower temperatures.
to lower temperatures)
systems may not reflect environmental that biodegradation
that the extent
acclimated
is artificially
are trapped in closed batch
by Larson [43], who cautioned microorganisms
were likely
may degrade substrates faster than was supported by an extended study
in Canadian water over a
1154
DominantAlgalTaxa
-
le+4
-I
220 230 240 250 260 270 280 290 300 >I"
220 230 240 250 260 270 260 290 300 310
Day of Year
Day of Year
Figure 7. Total algal community hiovolume (A) and percent contribution
of dominant taxa to community
biovolume (B) during the 1992 AES experiment. 4-year
period
[44].
demonstrated temperatures
periods
of constant
consumer
use and discharge,
the Canadian
study
in the levels of NTA from summer to winter months in surface waters when
dropped to 0°C [43, 441. These results. combined with the observations
that any decrease minimally
During
no increases
in biodegradation
caused by thermodynamic
offset by increases in biodegradation
ramifications
ability within the community
of this study, indicate
of decreased
temperature
are
as it changes and responds to
seasonal trends. 3.9 Algal species sensitivity Algal community
biovolume
increased approximately
IO-fold during the AES experiment
in all treatments
(Figure 7A). However, the highest exposure (774 c(g AESIL), and to a lesser and non-significant second highest exposure (25 1 ug AESIL) increased jn biovolume the study. This pattern is consistent
with other microbial periphyton endpoints
heterotrophic
adaptation to AES at high concentrations
microbial community
155 algal taxa were considered community
The exception
dominant at some point in the study. Figure 7B depicts the percentage
of the
of “dominant” taxa. The 24 dominant taxa were usually 95% or greater of was the high exposure (774 ug/L) stream which had a significantly present.
stream (see also [24]). By the conclusion
not described
were classified (Figure 8A).
This indicates the presence
A substantial
percentage
lower
of several new taxa unique to this
of the study there were no exposure-dependent
as spring seasonal dominants
or graphed any further.
seasonal preference
[24] and perhaps is related to 24 of
of the 24 dominants
Few taxa (
of
(Fig. 3). Approximately
which was comprised
the community. percentage
extent the
at a greater rate during the mid-portion
based on the periphyton
responses
noted.
literature and are
(20-40%) of taxa were found to have little
Many of these taxa would be considered
ubiquitous.
cosmopolitan
taxa
1155
100
100
ii 90 2
E 90
2 g
g
60
.;
70
$
70
z
60
z s
60
a ii z c z
40
5 t%
40
30
E
20
'E
20
i? ; P
10
Q $) n.
10
60
SummerAlgal Taxa
60
p0
0 220 230 240 260 260 270 260 290 300 310 Day
30
0 220 230 240 260 260 270 260 290 300 310
ofYear
Day
ofYear
100 fi
90
5
60
I
;
70
P =
60
FallAlgalTaxa
p0 s Ib
40
E 8 ; P
20
30
10 0 220 230 240 260 260 270 260 290 300 310
220 230 240 260 260 270 260 290 300 310 Day
Figure
8.
Day
ofYear
ofYear
Percent contribution of taxa without seasonal thermal preference
(A), summer seasonal
preference (B), fall seasonal preference (C) and winter seasonal preference (0). which are good colonizers
[29, 311.
enhanced at the highest concentration seen in Fig. 7A. pattern.
The proportional
The percentage
Fall seasonal taxa showed the inverse relationship
portion of the study.
Importantly,
for any seasonal group. more or less sensitive sensitive.
for the overall increase in community
was
biovolume
summer and winter taxa (Fig. 8B, SD) showed no exposure-response
(Fig. 8C) with the high exposure concentration
uniquely
of these taxa as part of the total community
and are responsible
to that of the taxa without seasonal preference
being reduced compared to other treatments
there is no clear dose-response
during the mid-
pattern that persists to the end of the study
This suggests that no one group, adapted to either warmer or colder temperatures than any other group.
Cold-adapted
Algal species are largely cosmopolitan
is
algal species by this analysis appear to not be and generally circumpolar
in distribution
[45]
1156
and many of the same or highly related taxa would be expected throughout
to exist in similar habitats
elsewhere
the world.
4. CONCLUSIONS In conclusion, maintained decreases
the mineralization
and often increased in temperature
species composition tested artificial therefore,
which occur seasonally.
temperature
in enclosed
changes
batch
winter seasons and in geographies these results
support
for macroflora
along with natural changes
which isolated These
in
studies which have
However, these laboratory
recruitment.
such
These conclusions
the naturally results
studies
occurring
presented
here,
AES and AE in temperate zones during the fall and
with extended periods of low mean river water temperatures. of biodegradation
Similar investigations
was at least
Furthermore,
differ from laboratory
correlated.
natural
safety of Cl2-AS,
the extrapolation
seasons and geographies.
preventing
in temperature.
fluctuations
and used testing procedures
systems,
support the environmental
are positively
periphyton
to the surfactant AES.
These conclusions
and biodegradation
acclimated
seasonal decreases
which undergo natural temperature
that temperature
community
during significant
by naturally
do not increase algal species sensitivity
are based on communities concluded
of three surfactants
and species
of temperature-related
and fauna which are more limited in their phenotypic
sensitivity
In addition,
for surfactants
species sensitivity
across
are likely needed
and genetic plasticity
than microbial
organisms.
ACKNOWLEDGMENTS The authors thank John Bowling, Burton Hamm, Daniel Davidson, Ellen LaBlanc, Rick Bausch, Ken Rupe, Dave Walker, Cheryl Tansky, Timothy Gsell and Roy Ventullo for their technical assistance. are grateful for the efforts of Rex Lowe (algal taxonomy) (biodegradation
The authors
as well as Robert Larson and Thomas
Federle
discussions).
REFERENCES 1.
R.M. Atlas and R. Bartha, In: Microbial Publishing
2.
Ecology
(2 nd Edition),
p. 533, The Benjamin/Cummings
Company, Inc., Menlo Park, CA (1987)
A.C. Palmisano, of xenobiotics
B.S. Schwab, D.A. Maruscik and R.M. Ventullo, by stream microbial
communities,
Canadian
Seasonal changes in mineralization
.Journul
of
Microbiology,
37,
939-947
(1991).
3.
R.J. Larson Environmental
and L.M. Science
Games,
Biodegradation
and Technology,
of linear
alcohol
15, 1488- 1493 (198 1).
ethoxylates
in natural
waters,
1157 4.
J.W. Rudd and R.D. Hamilton, Biodegradation
of trisodium nitrilotriacetate
lagoon, Journal Fisheries Research Board of Canada, 29,1203-1208 5.
6.
in a model aerated sewage
(1972).
R.J. Larson, G.G. Clinckemaillie
and L. Van Belle, Effect of temperature
biodegradation
of nitrilotriacetate,
Water Research, 15,615-620
S.B. Lartiges
and P.P. Garrigues,
pesticides
in different
Degradation
kinetics
and dissolved
(1981).
of organophosphorus
waters under various environmental
oxygen on
conditions,
and organonitrogen
Environmental
Science and
Technology, 29, 1246- 1254 (1995). 7.
L.G.
Whyte,
C.W.
psychrotrophic 8.
Greer
and
microorganisms,
W.E.
In&s,
Assessment
of the
Canadian Journal of Microbiology,
A. Barillier and J. Gamier, Influence
of temperature
biodegradation
42,99-106
and substrate concentration
yield in Seine river water batch cultures, Applied and Environmental
potential
of
(1996). on bacterial growth
Microbiology,
59, 1678-1682
(1993). 9.
T.L. Bott, Bacterial growth rates and temperature Limnology and Oceanography,
10.
29,191-197
11.
(1975).
G.T. Peters, J.R. Webster and E.F. Benfield, streams: effects of nitrogen, phosphorus
optima in a stream with a fluctuating thermal regime,
Microbial
and temperature,
activity associated
Freshwater Biology, l&405-413 (1987).
R.Y. Mortia, R.P. Griffiths and S.S. Hayasaka. Heterotrophic waters, In: Adaptations
with seston in headwater
activity of microorganisms
Within Antarctic Ecosystems, pp. 99-l 13, Gulf Publishing
in Antarctic
Company,
Houston,
Texas, (1977). 12.
13.
W.F. Vincent. Microbes and humans in Antarctica,
In: Microbial Ecosystems of Antarctica, (Edited by
W.F. Vincent) pp. 222-232,
Cambridge University Press, New York, (1988).
M. Bolter and R. Dawson,
Heterotrophic
utilisation
of biochemical
compounds
in Antarctic
waters,
Netherlands Journal of Sea Research, 16,3 15-332 (1982). 14.
R. Siron,
E. Pelleteir
petroleum
hydrocarbons
28,406-416 15.
Environmental
factors
influencing
in cold seawater, Archives of Environmental
the biodegradation
Contamination
of
and Toxicology,
(1995).
D.B. Knaebel, T.W. Federle and J.R. Vestal, Mineralization 11 contrasting
16.
and C. Brochu,
soils, Environmental
of linear alkylbenzene
H.A. Painter and E.F. King, The effect of phosphate and temperature and on biodegradation
of surfactants,
sulfonate (LAS) in
Toxicology and Chemistry, 9, 981-988 (1990). on the growth of activated sludge
Water Research, 12,909-9 15 (1978).
1158
17.
R.R. Birch, Prediction
of the fate of detergent chemicals during sewage treatment, Journal of Chemical
Technology and Biotechnology, 18.
L. Kravetz, branching
P.B. Salanitro,
50,4 1 l-422 (199 1).
P.B. Dom and K.F. Gum, Influence
on environmental
response
factors
of nonionic
of hydrophobe
type and extent of
Journal
surfactants,
of American
Oil
Chemists Society, 68, 610-618 (1991). 19.
J.R. Moeller, G.W. Minshall, K.W. Cummings, and R.L. Vannote, characteristics,
20.
21.
Transport
Organic Geochemistry,
experiments:
seasonal
mimicking
in streams
of differing
physiographic
1, 139-150 (1979).
developments
Hydrobiologia,
235/236,267-28
SE. Belanger,
J.B. Barnum, D.M. Woltering,
mesocosms.
E.M. Berghuis
of microbial
variables
and A. Kok, Mesocosm in North
Sea sediments,
1 (1992).
structure
J.W. Bowling,
and function
R.M. Ventullo,
in response
S.D. Schermerhom
to consumer
chemicals
and
in stream
In: Aquatic Mesocosm Studies in Ecological Risk Assessment (Edited by R.L. Graney, J.H. pp. 535-568, CRC Press, Boca Raton, (1994).
D.M. Lee, J.B. Guckert, R.M. Ventullo, D.H. Davidson and S.E. Belanger, Stream periphytic biodegradation
acclimation
concentrations,
Ecotoxicology
to the anionic
surfactant
supports
Environmental
rapid
Safety, in press, (1997).
and Environmental
degradation
of Cl2-alkyl
sulfate
Toxicology 6; Chemistry, 15,262-269
J.B. Guckert, Toxicity
assessment
bacterial
C 12-alkyl sulfate at environmentally-relevant
J.B. Guckert, D.D. Walker and S.E. Belanger, Environmental study
24.
carbon
Bak, A.J. Kop, G. Nieuwland,
Rodgers and J.A. Kennedy),
23.
R.C. Petersen, C.E. Cushing, J.R. Sedell, R.A. Larson organic
F.C. van Duyl, R.P.M.
R.L. Lowe. Algal periphyton
22.
of dissolved
by community
chemistry for a surfactant ecotoxicology in a continuous-flow
stream
mesocosm,
(1996). analysis, Journal of Microbiological
Methods, 25,
101-112 (1996). 25.
R.L. Lowe, periphyton mesocosms,
26.
J.B. Guckert, community
structure
Hydrobiologia,
S.E. Belanger, alkyl ethoxylate Contamination
S.E. Belanger,
D.H. Davidson
and function
on tile and cobble substrates
An evaluation
in experimental
of
stream
328, 135-146 (1996).
K.L. Rupe and R.G. Bausch, Responses sulfate
and D.W. Johnson,
anionic
surfactants
during
and Toxicology, 55, 75 l-758 (1995).
of invertebrates chronic
exposure,
and fish to alkyl sulfate and Bulletin
of Environmental
1159 27.
SE. Belanger,
E.M. Meiers and R.G. Bausch, Direct and indirect ecotoxicological
sulfate and alkyl ethoxylate
on macroinvertebrates
in stream mesocosms,
effects
of alkyl
Aquatic Toxicology, 31, 65-
87 (1995). 28.
J.B. Guckert, periphyton
29.
SE.
Belanger,
in experimental
R.J. Stevenson,
D.H. Davidson
M.L. Bothwell
and R.L. Lowe,
Responses
of algal and bacterial
during exposure to C12-alkyl sulfate, in prep., (1997).
stream mesocosms
and R.L. Lowe, In: Algal Ecology - Freshwater
Benthic Ecosystems
(1st Edition), p. 753. Academic Press, San Diego, CA (1996)
30.
S.L. Vanlandingham,
In: Guide to the Identification,
Environmental
Tolerance of Blue-Green Algae (Cyanophyta), EPA-60013-82-073 Protection
Agency, Cincinnati,
3 1. R.L. Lowe, In: Environmental United States Environmental 32.
Little
Requirements
Rivers,
and Pollution Tolerance of Freshwater
Ohio.
Effects
composition
of exposure
time, season,
of algal periphyton
In: Ecological
Assessment
American Society for Testing and Materials, Philadelphia,
C.I. Weber and B.H. McFarland. Ecological Assessment
of Efluent
by J.M. Bates and C.I. Weber), Materials, Philadelphia, 34.
substrate
type and planktonic
on artificial substrates
of Effl uent Impacts
Indigenous Aquatic Organisms (Edited by J.M. Bates and C.I. Weber),
33.
Diatoms, p. 333.
Protection Agency, Cincinnati, Ohio (1974)
on the taxonomic
Miami
and Pollution
OH (1982).
C.I. Weber and B.H. McFarland. populations
Requirements
p. 341, United States Environmental
in the Ohio and
on Communities
of
ASTM STP 730, pp. 166-219,
PA, (198 1).
Effects of copper on the periphyton Impacts on Communities
of a small calcareous
stream. In:
of Indigenous Aquatic Organisms (Edited
ASTM STP 730, pp. 101-131,
American
Society for Testing and
PA, (1981).
M.A. Lewis, Impact of a municipal wastewater
effluent on water quality periphyton
and invertebrates
in the Little Miami River near Xenia, Ohio, Ohio JournaZ of Science, 86,2-S (1986). 35.
SAS, SAS User’s Guide: Statistics, Statistical Analysis Systems, Cary, NC (1990).
36.
SAS, The SAS System for Windows, Version 3.10, Release 6.08, Cary, NC (1992).
37.
R.D. Swisher,
In: Surfactant Biodegradation
(2 nd Edition), p. 496.
Marcel Dekker, Inc., New York
(1970) 38.
D.J. Anderson,
M.J. Day, N.J. Russell and G,F. White, Die-away kinetic analysis of the capacity of
epilithic and planktonic
bacteria from clean and polluted river water to degrade sodium dodecyl sulfate,
Applied and Environmental
Microbiology,
56,758-763
(1990).
1160 39.
D. Zakova, microbial
P. Ferianc, assemblages
sulphosuccinate, 40.
41.
from water of the Danube to biodegrade
dodecyl
sulfate-degrading
Microbiology,
and epilithic
bacteria
and geographical
in a polluted
South Wales river, Applied
C. Lee, N.J. Russell and G.F. White, Modeling the kinetics of biodegradation Water Research, 29,2491-2497
of und
of anionic surfactants by
of five classes of surfactant
at three sites,
(1995).
R.D. Vashon and B.S. Schwab, Mineralization sulfates at trace concentrations
distributions
54, 555-560 (1988).
biofilm bacteria from polluted riverine sites: a comparison
42.
of planktonic
sodium dodecyl sulphate and dioctyl
M.J. Day, N.J. Russell and G.F. White, Temporal
sodium
Environmental
and D. Toth, Capacity
Biologia, 51, 259-270 (1996).
D.J. Anderson, epilithic
B. Polek, J. Godocikova
of linear alcohol ethoxylates
in estuarine water, Environmental
and linear alcohol ethoxy
Science and Technology, 16, 433-436
(1982). 43.
R.J. Larson. Role of biodegradation and Fate of Chemicals Cairns),
44.
Environment
C.R. Woodiwiss,
R.D. Walker and F.A. Brownridge,
Jr., Probable
fate. In: Biotransformation
Washington
and J.
D.C., (1980).
Concentrations
of nitrilotriacetate
and certain
and streams: 1971-1975, Water Research, 13, 599-612 (1979).
consequences
Technology, 14,41-50 (1991).
environmental
(Edited by A.W. Maki, K.L. Dickson
pp. 67-86, American Society for Microbiology,
metals in Canadian wastewaters 4.5. J. Cairns
kinetics in predicting
in the Aquatic
of a cosmopolitan
distribution,
Speculations
in Science and