Vol. 275, Issue 3, R861-R869, September 1998
Thermal acclimation of phase behavior in plasma membrane
lipids of rainbow trout hepatocytes
Jeffrey R.
Hazel,
Susan J.
McKinley, and
Martin F.
Gerrits
Department of Biology, Arizona State University, Tempe, Arizona
85287
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ABSTRACT |
The fluorescent probes laurdan
(6-dodecanoyl-2-dimethylaminonapthalene) and
N-[7-nitrobenz-2-oxa-1,3-diazol-4-yl]
dipalmitoyl-L-
-phosphatidylethanolamine (NBD-PE) in addition to Fourier transform infrared spectroscopy (FTIR)
were employed to measure the phase behavior and physical properties of
hepatocyte plasma membranes isolated from the livers of thermally
acclimated (5 and 20°C) rainbow trout
(Oncorhynchus mykiss). The primary
objective was to determine the extent to which the phase behavior of
membrane lipids is conserved at different growth temperatures.
Arrhenius plots of laurdan-generalized polarization revealed a single
discontinuity believed to reflect either the onset of the gel-fluid
phase transition or the formation of gel phase microdomains, and this
discontinuity occurred at significantly higher temperatures in
membranes of 20°C (13.2 ± 0.7°C)- than 5°C (7.2 ± 0.1°C)-acclimated trout. Similarly, acclimation from 5 to 20°C
increased both the onset temperature (from 2.0 ± 0.3 to 7.2 ± 0.6°C) and the thermal range (from 10.9 ± 0.5 to 16.0 ± 1.0) of
the gel-fluid transition as assessed by FTIR. The gel-fluid transition
midpoint (approximately 
2°C) and completion temperatures (9°C) were unchanged by thermal acclimation. The anisotropy
of NBD-PE fluorescence displayed a distinct minimum in membranes of
both warm- and cold-acclimated trout (reflecting alterations in lipid
packing that in pure lipid membranes ultimately lead to the formation
of nonlamellar phases) in the range of 56-58°C; only membranes
of 5°C-acclimated trout displayed an additional minimum at
significantly lower temperatures (24.5 ± 1.7°C). Collectively, these data suggest that the regulation of both the temperature at which
gel phase lipids begin to form in response to cooling as well as the
propensity of membrane lipids to form nonlamellar phases at higher
temperatures may be key features of membrane organization subject to
adaptive regulation.
phase transition; gel-fluid transition; fluid-nonlamellar
transition; fluid-reversed hexagonal transition; homeoviscous
adaptation; laurdan; N-[7-nitrobenz-2-oxa-1,3-diazol-4-yl]
dipalmitoyl-L--phosphatidylethanolamine; Oncorhynchus
mykiss; Fourier transform infrared
spectroscopy
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INTRODUCTION |
A COMMON RESPONSE OF poikilothermic organisms to
altered temperature is a restructuring of membrane lipid composition.
This restructuring occurs in diverse taxa, including bacteria (43), plants (51), and animals (17), and encompasses virtually all lipid
constituents of the membrane. Temperature-induced modifications in
membrane lipid composition include
1) the type and quantity of
unsaturated fatty acids (14); 2) the
mix of molecular species comprising a given phospholipid class (18,
56); 3) the size, hydrophobicity,
and charge of phospholipid head groups (38); 4) the balance between
bilayer-stabilizing and -destabilizing lipids (27, 33, 40);
5) the proportion of plasmalogen
relative to diacyl phospholipids (29); and
6) the cholesterol-to-polar lipid
ratio (42). Such fine tuning of membrane lipid composition is perhaps
the most pervasive cellular response to temperature change and is
presumed to reflect a homeostatic mechanism of fundamental adaptive
significance.
One paradigm widely invoked to explain the temperature-induced
remodeling of membrane lipid composition is preservation of the
bulk-phase physical properties, or "fluidity" [more
correctly (on the basis of the probes most commonly used to assess
fluidity), membrane order], of membrane lipids(6), and is termed
homeoviscous adaptation (HVA) (45). The seminal discovery by Cossins
and colleagues (4, 7) that membrane lipid order is conserved in
synaptosomal membranes of various vertebrates when assessed at the
respective cell or body temperatures provides the strongest support for
HVA. However, the observations 1)
that the extent and occurrence of HVA are quite variable (8),
2) that HVA can occur
without compensation of membrane function and vice versa (39, 44),
3) that some aspects of membrane
remodeling (e.g., low-temperature accumulation of polyunsaturated fatty
acids and bilayer-destabilizing lipids) are not consistent with HVA
(discussed in Ref. 15), and 4) that
membrane function is frequently poorly correlated with acyl chain order
(48) all argue that factors other than, or in addition to, membrane
order are important for the conservation of membrane function in a
variable thermal environment. An alternative view of membrane
adaptation emphasizes the dynamic phase behavior of membrane lipids
(15). According to this view, lipid composition is regulated so that
membranes remain within a lamellar fluid phase "window" that
extends from the thermotropic transition to the gel phase at low
temperature to the formation of nonlamellar lipid phases at high
temperatures (32). Moreover, the proximity of the growth temperature to
the liquid crystalline/reversed hexagonal
(HII) phase transition
temperature (Th) may be
particularly important in the regulation of dynamic membrane properties
essential for cellular processes dependent on membrane fusion, such as
cell division in prokaryotes and intracellular membrane traffic in eukaryotes (10, 34). In support of this view, both
Escherichia coli (40, 41) and
Acholeplasma laidlawii (27) regulate
the lipid composition of their membranes so that the transition to nonbilayer phases occurs ~10°C above the growth temperature (40). Collectively, these results suggest that the dynamics of membrane lipid
phase behavior are conserved in response to thermal challenge.
However, lipid phase behavior has not been extensively studied in
membranes of temperature-acclimated eukaryotes. Consequently, the
present experiments were undertaken to examine the phase behavior and
physical properties of plasma membranes isolated from hepatocytes of
thermally acclimated (to 5 and 20°C) rainbow trout
(Oncorhynchus mykiss). Fluorescent
probes particularly sensitive to the formation of either gel (laurdan)
or nonlamellar
[N-[7-nitrobenz-2-oxa-1,3-diazol-4-yl] dipalmitoyl-L--phosphatidylethanolamine
(NBD-PE)] lipid phases were employed along with Fourier transform
infrared spectroscopy (FTIR) to determine
1) whether lipid phase transition
boundaries (gel-fluid and lamellar-hexagonal) vary with acclimation
temperature and 2) whether the
proximity of the acclimation temperature to these phase boundaries is
conserved as a consequence of temperature acclimation.
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MATERIALS AND METHODS |
Animals. Rainbow trout
(O. mykiss) ranging in body weight
from 150 to 300 g were obtained from the Alchesay Federal Trout Hatchery in Whiteriver, AZ. After transport to the laboratory, fish
were maintained in circular, fiberglass aquariums at temperatures of
either 5 or 20°C under recirculating conditions (with the total water volume of the aquariums being replaced by fresh water every 24 h). Fish were fed a commercial diet (Glencoe Mills, Minneapolis, MN) to
satiation once daily and were held on a 12:12-h light-dark photocycle.
Trout were maintained at their respective acclimation temperatures for
at least 6 wk before experimentation.
Preparation of plasma membranes.
Hepatic plasma membranes were isolated by a combination of differential
and density gradient centrifugation according to a modification of the
procedure of Armstrong and Newman (3) as previously described (42, 55). Briefly, 4 g of liver representing tissue pooled from two fish in the
case of cold-acclimated trout (198.5 ± 25.7 g total body wt) or three
fish in the case of warm-acclimated trout (141.5 ± 18.7 g total body
wt) were homogenized in four volumes of homogenizing buffer (HB:
0.25 M sucrose, 0.02 M Tris · HCl, pH 7.4 containing 1 mM of freshly prepared benzamidine and 1 mg/ml DNase) by
six up-and-down strokes of a Teflon/glass Potter-Elvehjem tissue
homogenizer (500 rpm). Homogenates were filtered through 250-µm nylon
mesh and diluted to a final volume of nine times the liver weight with HB lacking DNase and benzamidine. The resulting crude homogenate (in
20-ml aliquots) was layered over 15 ml of 41% (wt/vol) buffered sucrose (0.02 M Tris · HCl, pH 7.4) and centrifuged
at 22,600 g for 30 min in a Beckman
JA-20 rotor. Membrane material that accumulated at the boundary of the
41% sucrose solution was collected by Pasteur pipette, diluted
fourfold with fresh HB, and centrifuged at 7,000 g for 15 min in a Beckman JA-20 rotor.
The resulting pellet was resuspended in 1 ml of fresh HB, layered over
20 ml of 18% Percoll (prepared in HB), and centrifuged at 33,000 g for 25 min in a Beckman Ti50.2
rotor. The plasma membrane band, located in the upper region of the
tube, was collected by displacement with 66% (wt/vol) sucrose and
diluted ~10-fold with 0.15 M NaCl, 10 mM
Tris · HCl, pH 7.4 before centrifugation at 100,000 g for 2 h in a Beckman Ti50.2 rotor.
The final membrane fraction (present as a thin surface film on top
of a translucent Percoll pellet) was washed free of the Percoll pellet,
resuspended in storage buffer (20 mM Tris · HCl, pH
7.8), and stored frozen at 80°C until used. Measurement of
marker enzyme activities established that although this membrane
fraction contains both apical (canalicular) and basolateral domains
(but no significant contamination from endoplasmic reticulum,
mitochondria, peroxisomes, or lysosomes), it is two- to threefold more
enriched in canalicular (overall enrichment of canalicular membranes
based on specific activities of
Na+-K+-ATPase
and 5'-nucleotidase is 10- to 100-fold) than basolateral membranes, as reported in previous studies (42, 55).
Lipid extraction and preparation of lipid vesicles for
FTIR and model membrane studies. Total plasma membrane
lipid extracts were prepared by the method of Bligh and Dyer (5).
Multilamellar lipid vesicles were prepared by the reversed-phase
evaporation method as described by Gruner et al. (12). Vesicles were
prepared in 20 mM Tris · HCl buffer (pH 7.4)
containing both NaCl and KCl, each at 72.5 mM.
Fluorescence spectrometry. The
generalized polarization of laurdan (6-dodecanoyl-2-dimethyl
aminonapthalene) fluorescence was employed because in model membrane
systems it is particularly sensitive to the presence of gel phase
lipids (35). Isolated membrane was diluted (in storage buffer) to a
concentration of 100 µg membrane protein/ml. The diluted membrane
suspension (4 ml) was incubated with laurdan (2 µl of a 2 mM stock solution in methanol) at room temperature (with gentle
stirring in an amber bottle) for 1 h before fluorescence measurements.
The generalized polarization (GP) was computed from the emission
intensities at 440 nm (IB) and
490 nm (IR), employing an
excitation wavelength of 350 nm according to the following equation as
described by Parasassi et al. (35)
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(1)
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The fluorescence anisotropy of NBD-PE was employed because of
its sensitivity in model membrane systems to the lamellar-to-hexagonal phase transition as described by Han and Gross (13).
Plasma membrane diluted (to a final volume of 4 ml in storage buffer) to a concentration of 100 µg protein/ml was incubated with NBD-PE (2 µl of a 1 mg/ml stock solution in ethanol) as previously described for laurdan. Fluorescence anisotropies
(r) were determined from the
fluorescence intensities measured in directions parallel
(IV) and perpendicular
(IH) to the electric vector of
the exciting light (employing excitation and emission wavelengths of
460 and 528 nm, respectively) as a function of temperature according to the following equation (25)
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(2)
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All
fluorescence measurements were made using a Perkin-Elmer LS-50B
luminescence spectrophotometer equipped with a thermally jacketed cell
holder connected to a constant-temperature circulating water bath. The
temperature of the cuvette contents was measured directly employing a
fine thermocouple thermometer.
FTIR. Infrared spectroscopy measures
the low-energy transitions between vibrational levels generated by
characteristic motions (e.g., stretching) of different chemical bonds
in the lipid molecule without introducing a potentially perturbing
probe (28). Vibrational frequencies attributed to the methylene
(CH2) asymmetric stretch are
particularly sensitive to the conformational order of the lipid acyl
chain, shifting to lower wave numbers in the gel compared with the
fluid lamellar phase. Vesicle samples were placed between two
CaF2 windows separated by a
50.8-µm (0.002 in.) Teflon spacer. Sample temperature was controlled
to within 1.0°C by a combination of circulating coolant and
microprocessor-controlled heating elements in a custom-designed (CIC
Photonics) cell. Data were collected under continuous nitrogen gas
purge with a Perkin Elmer Spectrum 2000 FTIR spectrophotometer.
Seventy-five spectra were averaged at each temperature and Fourier
transformed employing a strong apodization function to yield data every
1 cm
1. Peak frequencies were determined,
without baseline adjustment, from second-derivative spectra following
subtraction of a background scan (collected under
N2 purge) employing the Spectrum
2000 software.
Analytic and statistical procedures.
Protein was assayed colorimetrically employing the bicinchoninic acid
(BCA) method as described by Smith et al. (47). Discontinuities in the
Arrhenius plots of laurdan GP (TGPl) were
assigned by using the breakpoint regression routine (employing the
quasi-Newton method) of Statistica. Minima in the temperature
dependence of NBD-PE fluorescence anisotropy
(Th or
TNBD) were identified by fitting the data to a polynomial regression (employing SigmaPlot); the lowest
calculated (theoretical) value of fluorescence anisotropy versus
temperature was taken as the minimum value. From the FTIR data, the
midpoint temperature (point of inflection) of the gel-fluid transition
(Tm) was determined by
first-derivative analysis of the temperature dependence of the
methylene asymmetric stretching frequencies employing the TableCurve-2D
software package; the onset (TFTIRl: the
temperature above which lipids are in the fluid or liquid phase) and
completion temperatures (Ts: the
temperature below which lipids are in the gel phase) of the gel-fluid
transition were similarly determined from maxima and minima in
second-derivative spectra of the primary data. All statistical tests
were performed using the Statistica computer program.
Materials. Laurdan
(6-dodecanoyl-2-dimethylaminonapthalene) and NBD-PE were obtained from
Molecular Probes (Eugene, OR). BCA protein assay kits were purchased
from Pierce (Rockford, IL). Lipid standards were obtained from Avanti
Polar Lipids (Alabaster, AL). Percoll, DNase I (Type II from bovine
pancreas), and miscellaneous biochemicals were from Sigma (St. Louis,
MO). All other reagents were of analytic grade. Organic solvents were
redistilled before use.
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RESULTS |
Laurdan GP. Laurdan consists of a
fluorescent napthalene moiety covalently linked to a 12-carbon lauric
acid chain. In the membrane, the lauroyl chain intercalates into the
bilayer interior while the napthalene moiety anchors the probe at the
lipid-water interface. The emission spectrum of laurdan is exquisitely
sensitive to the phase state of lipid membranes. In pure lipid
membranes, the emission maximum of laurdan is red shifted by ~50 nm
in the liquid crystalline as opposed to the gel phase (35). Figure 1A
illustrates that laurdan displays similar behavior when incorporated into trout liver plasma membranes. Whereas the intensity of the emission spectra measured at low temperatures (e.g., 5°C) is
dominated by a peak at ~440 nm, the amplitude of this peak declines
and a secondary, red-shifted emission peak appears at ~490-500
nm as temperature is increased. This red shift in the emission spectra (Fig. 1A) reflects a change in
both the polarity of the probe environment and the rate of relaxation
of molecules (most likely water) that can reorient around the
fluorescent moiety during its excited-state lifetime (36). The GP of
laurdan fluorescence, as measured by the difference in
fluorescence intensity of the blue and red emission maxima compared
with the total fluorescence intensity (refer to
Eq.
1), thus provides a sensitive
indicator of the onset of the gel-fluid transition in lipid membranes
of simple and defined composition. This is illustrated in Fig.
1B, which shows that Arrhenius plots
of laurdan GP in multilamellar vesicles of dimyristoyl
phosphatidylcholine (DMPC) display an abrupt discontinuity at the
gel-fluid transition temperature (24°C) (36); GP values are
relatively high (>0.4) in the gel phase (i.e., at temperatures
>24°C) and low (<0.3) in the fluid phase.
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Fig. 1.
A: effect of assay temperature on
emission spectra of laurdan in hepatic plasma membranes from
20°C-acclimated trout. Note that emission spectra are red shifted
at elevated temperatures, indicating increased proportions of
fluid-phase lipids. B: effect of assay
temperature on generalized polarization (GP) of laurdan in
multilamellar vesicles of dimyristoyl phosphatidylcholine (DMPC),
presented as both an Arrhenius plot and a direct linear plot
(inset). Temperature of gel-fluid
transition is indicated by arrow.
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Arrhenius plots of laurdan GP for probe incorporated into plasma
membranes of both 5- and 20°C-acclimated trout exhibited a single
discontinuity (Fig. 2); this discontinuity
was a consistent feature of the data and was observed in all
experiments (n = 5). Most notably, the
discontinuity occurred at a significantly lower (P = 0.014) temperature in plasma
membranes of 5°C (7.2 ± 0.1°C)- than 20°C (13.2 ± 0.7°C)-acclimated fish (Table
1). Fitting the data to a model that
assumed a single breakpoint and two linear segments of dissimilar slope
explained more than 99.5% of the variance in the data. Similar
discontinuities were present at the same temperatures in both
direct-linear [laurdan GP vs. temperature (°C)] and
log-linear [log laurdan GP vs. temperature (°C)] plots (data not shown), indicating that the discontinuities are not an
artifact of the mode of data presentation. Slopes at temperatures below
the discontinuity were significantly lower than those at higher
temperatures (by a factor of ~1.6-fold).
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Fig. 2.
Arrhenius plot demonstrating effect of temperature on generalized
fluorescence polarization of laurdan in plasma membranes isolated from
hepatocytes of 5- and 20°C-acclimated rainbow trout. Typical data
from a single experiment are illustrated.
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Table 1.
Average transition temperatures for the gel-fluid and high-temperature
phase transitions in liver plasma membranes of 5- and
20°C-acclimated rainbow trout (Oncorhynchus mykiss)
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CH2 asymmetric
stretch: FTIR. The temperature dependence of the
methylene stretching vibrations derived from the acyl chains of
membrane phospholipids has been extensively employed to define the
thermal range of the gel-fluid phase transition (2, 28, 49). As
illustrated in Fig. 3 for DMPC
(inset), the wave number of this
vibration increases dramatically with warming as the sample passes
through the gel-fluid transition (at 24°C). In phospholipid vesicles from trout hepatocyte plasma membranes (Fig. 3), the gel-fluid
transition occurs over a broader temperature range (Table 1; ~11 to
16°C, for 5- and 20°C-acclimated fish, respectively), indicating a less cooperative melting process, most likely reflecting the complex and heterogeneous nature of the lipids involved. Although neither Tm (1.6 to
2.3°C) nor Ts
(approximately 9°C) of the gel-fluid transition differed
significantly between acclimation groups (Table 1),
Tl (defined from a cooling
perspective) was significantly lower in cold (approximately
2.0°C)- than warm-acclimated (7.2°C) fish. Accordingly,
the width of the gel-fluid transition was significantly broader in warm
(~16°C)- than cold-acclimated (~11°C) trout (Table 1). In
contrast, although membranes of cold-acclimated fish were consistently
less ordered than those of warm-acclimated fish (i.e., characterized by
higher wavenumbers) at temperatures above 0°C, differences in
membrane order between acclimation groups were not significant in the
physiologically relevant temperature range (0-25°C).
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Fig. 3.
Temperature dependence of the asymmetric methylene stretching vibration
frequency in multilamellar lipid vesicles prepared from hepatic plasma
membranes of 5- and 20°C-acclimated rainbow trout. Typical data
from a single experiment are illustrated.
Inset: temperature dependence of
methylene asymmetric stretching vibration for DMPC.
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Anisotropy of NBD-PE. NBD-PE possesses
a fluorescent reporter moiety covalently attached to the head group of
dipalmitoyl phosphatidylethanolamine. Because the motional freedom of
the polar head group is reduced in the hexagonal compared with the lamellar phase (13), a transition to the hexagonal phase is expected to
result in a substantial increase in the fluorescence anisotropy of
fluorophores in the polar head group region. Conversely, within the
lamellar phase, head group motion is positively correlated with
temperature, and fluorescence anisotropy thus decreases with rising
temperature until Th is attained.
Consequently, minima in the temperature dependence of the fluorescence
anisotropy of head group probes such as NBD-PE define
Th. As illustrated in Fig.
4, this technique accurately reflects the
differences in Th for both
1-palmitoyl-2-oleoyl phosphatidylethanolamine
(Th = 67°C; Ref. 13)
and binary mixtures of dioleoyl phosphatidylethanolamine-dioleoyl phosphatidylcholine (Th = 36°C
for a 5:1 molar ratio; Ref. 13) employed as reference standards.
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Fig. 4.
Effect of temperature on fluorescence anisotropy of NBD-PE incorporated
into multilamellar vesicles of 1-palmitoyl-2-oleoyl
phosphatidylethanolamine (POPE) and a binary mixture of dioleoyl
phosphatidylethanolamine (DOPE)-dioleoyl phosphatidylcholine (DOPC)
(80:20). Observed minima correspond well with reported hexagonal phase
transition temperatures of these vesicles (11).
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The temperature dependence of NBD-PE anisotropy was more complex in
trout liver plasma membranes (Fig. 5).
Anisotropies for both 5- and 20°C-acclimated trout displayed a
clear minimum between 56 and 58°C (Table 1). However, plasma
membranes of 5°C-acclimated trout differed significantly from those
of 20°C-acclimated trout in displaying an additional, clearly
defined minimum at ~25°C (Table 1), resulting in higher NBD-PE
anisotropies (i.e., lower head group mobilities) in cold- than
warm-acclimated trout at temperatures above 25°C (Fig. 5). The
similarity of NBD-PE anisotropy values between acclimation groups at
temperatures below 25°C indicates a lack of significant differences
in the membrane properties sensed by this probe at physiological
temperatures.
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Fig. 5.
Effect of assay temperature on fluorescence anisotropy of
N-[7-nitrobenz-2-oxa-1,3-diazol-4-yl]
dipalmitoyl-L--phosphatidylethanolamine
(NBD-PE) incorporated into hepatic plasma membranes of 5- and
20°C-acclimated trout. Typical data from a single experiment are
illustrated. Consistently identified minima are indicated by arrows.
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DISCUSSION |
Because changes in temperature may shift the thermodynamic balance of
forces within a membrane toward lipid phases that are biologically
nonfunctional, the objective of the present experiments was to
determine the extent to which the boundaries (i.e., transition temperatures) between the phases assumed by membrane lipids are adjusted as growth temperature changes. As illustrated in Fig. 6, the fluid lamellar phase (indicated
graphically in Fig. 6 by the total length of the rectangle) is
delimited at low temperatures by transition to the gel phase (at
Tm) and at higher temperatures by the transition to nonlamellar (e.g., hexagonal, cubic, or micellar, at the lamellar-nonlamellar transition temperature,
TNL) phases. Excursions in
temperature either below Tm or
above Th significantly perturb
membrane structure and function (20, 46, 53, 54). To avoid such
problems, membrane lipid composition is adjusted so that the growth
temperature of the organism (Fig. 6) lies within the boundaries of the
fluid lamellar phase (i.e., within the temperature interval between
Tm and
TNL). Although thermal
compensation of membrane lipid composition is well established, the
extent to which the lipid packing forces that determine the phase
behavior of isolated membrane lipids are conserved at different growth temperatures is not currently clear, especially in eukaryotic poikilotherms. Accordingly, the spectroscopic approaches employed in
the present experiments were selected because they are well suited for
detecting changes in the phase behavior of membrane lipids both within
the lamellar phase (laurdan GP and FTIR) and between lamellar and
nonlamellar lipid phases (NBD-PE). It is worth noting, however, that in
most instances the methods employed sense primarily average membrane
properties and are not expected to reflect the properties of specific
microdomains that may be important for some membrane functions.
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Fig. 6.
Dynamic phase behavior model of thermal adaptation in biological
membranes. Thermal range over which a fluid lamellar phase is
maintained is indicated by the total length of the rectangle
[i.e., interval from midpoint temperature
(Tm) to nonlamellar temperature
(TNL)]. An acute change in
ambient temperature alters the relationship between acclimation (i.e.,
body) temperature (TA, i.e., the temperature at which the membrane is
functioning) and the transitions to the gel
Tm and nonlamellar
TNL phases: a drop in temperature
from the warm acclimation temperature
(TAW) to
T'A (indicated by
"transitional" diagram in the center of the figure) increases the
interval between TA and TNL
(indicated by increased length of shaded area within the larger
rectangle), while decreasing the interval between
Tm and TA; a rise in temperature
would have the opposite effects. Acclimation or adaptation to the
lowered temperature (bottom)
restores the proximity of TNL and
Tm to the cold-acclimation
temperature (TAC).
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Membrane behavior at low temperature: the GP of
laurdan fluorescence and the asymmetric methylene stretching
vibration. Hepatic plasma membranes of both warm- and
cold-acclimated trout display distinct and reproducible discontinuities
in Arrhenius plots of laurdan emission GP values (Fig. 2). The
mathematical treatment applied to these data, which assumes a biphasic
temperature dependency, accounts for the vast majority (>99%) of the
variance in each experiment. Furthermore, even if one were to assume
the relationship to be curvilinear, it is clear from the data in Fig. 2
that the region of maximal curvature would occur at different
temperatures in 5°C- and 20°C-acclimated trout. We therefore
consider a discontinuous regression model to be a valid approach for
identifying the temperature(s) at which the laurdan GP/temperature
relationship changes. Such an analysis reveals that acclimation from 20 to 5°C depresses the temperature of this transition by ~6°C
(Table 1). One possible interpretation of these data is that the
Arrhenius discontinuities reflect the initial formation of gel-phase
lipid domains, i.e. the onset of the gel-fluid phase transition
(Tl). Complete transition to the
gel phase is presumed to occur at temperatures below those assayed in
these experiments (i.e., temperatures <0°C). This interpretation is supported by the FTIR data in Fig. 3, which indicate that completion of the fluid-to-gel transition in lipid vesicles prepared from trout
hepatocyte plasma membranes occurs at approximately 9°C in
both groups (Table 1). Similar to the transition sensed by laurdan
(TGPl), the onset of the fluid/gel
transition detected by FTIR (TFTIRl) is
reduced ~5°C in cold (1.9°C)- compared with warm-acclimated
(7.2°C) trout. However, TFTIRl is
~5°C lower than TGPl (1.9 vs.
7.2°C for cold-acclimated trout; 7.2 vs. 13.2°C for
warm-acclimated trout). Estimates of TFTIRl, however, are likely to be
conservative and underestimate the true onset temperature of the
transition by 3-5°C because they were obtained from a
second-derivative function that estimates the temperature of maximal
(rather than initial) change in slope of the initial function (i.e.,
the wave number/temperature plot). Taking this into consideration, the
laurdan and FTIR estimates of Tl
are in excellent agreement.
Alternatively, the discontinuities in the temperature dependence of
laurdan GP and the onset of the gel-fluid transition as detected by
FTIR may reflect fundamentally different events. It is possible that
TGPl reflects a transition from the liquid-disordered to the liquid-ordered phase, which has been reported
in model phospholipid membranes containing >10-15 mol% cholesterol (23, 52). The levels of cholesterol present in trout liver
plasma membranes (10-20 mol% relative to phospholipid), although
not sufficiently high to eliminate the gel-fluid transition (50 mol%
or higher), are consistent with this possibility (37). In addition, the
relatively high values of laurdan emission GP (0.4-0.5) observed
at temperatures above the discontinuity in trout liver plasma membranes
compared with DMPC (Figs. 1 and 2) and the relatively low intensity of
the emission at 490 nm are both indicative of the presence of
cholesterol in trout liver plasma membranes (36). Even though the phase
behavior responsible for TGPl cannot be
unambiguously assigned based on the present work, this
discontinuity most likely reflects either a phase separation resulting
in the formation of cholesterol-rich microdomains or the initiation of
the gel-fluid transition.
On the basis of the foregoing results, most, if not all, of the lipids
in plasma membranes of warm-acclimated trout are expected to be in a
fluid state because the acclimation temperature (20°C) is well
above both TGPl (13°C) and
TFTIRl (7.2°C). In contrast,
cold-acclimated fish, for which the acclimation temperature (5°C)
lies between TFTIRl (1.9°C) and
TGPl (7°C), operate much closer to
the low-temperature boundary of the fluid phase and may contain some
gel phase or phase-separated lipids at normal physiological
temperatures. This suggestion is consistent with reports of a small but
significant fraction of gel phase lipids in a variety of membranes at
physiological temperatures (21, 22, 26, 57). The failure of
cold-acclimated fish to depress the onset of the gel-fluid transition
to an extent (relative to acclimation temperature) comparable to that
in warm-acclimated fish most likely reflects the closer proximity of
cold-acclimated fish to the physiological limitations imposed by
freezing temperatures; there is no apparent advantage to be derived
from shifting the gel-fluid transition to sub-zero temperatures that
the fish cannot survive. Nevertheless, the significant reduction (of
~5-6°C) in both TGPl and
TFTIRl with cold acclimation is expected
to permit the maintenance of a predominantly fluid membrane to lower
temperatures (2-7°C) in cold- than warm-acclimated trout
(7-13°C; Table 1). Interestingly, neither
Tm nor
Ts are significantly influenced by
growth temperature. Thus the primary locus of the acclimatory response
in rainbow trout is the temperature at which gel phase or
cholesterol-rich domains begin to form with cooling. These results are
generally similar to those previously reported for the simpler
membranes of a variety of microorganisms (reviewed in Ref. 17) and are
consistent with the principle of homeophasic adaptation originally
proposed by McElhaney (31), with the exceptions that, in trout, the
width of the gel-fluid transition is broader and neither
Tm nor
Ts is subject to acclimatory adjustment.
The gel-fluid transition observed for trout hepatocyte plasma membranes
is considerably broader (11-16°C; Table 1) or less cooperative
than that reported for membranes of human platelets (49) and is more
consistent with that previously reported for trout spermatozoa (24),
most likely reflecting either 1) the heterogeneous nature of the lipid composition or
2) the presence of considerable
amounts of polyunsaturated fatty acids and/or cholesterol.
In contrast to phase behavior, estimates of membrane physical
properties for trout hepatocyte plasma membranes (to the extent that
they can be inferred from the absolute values of either laurdan emission GP or the wave number of the
CH2 asymmetric stretching vibration) depend on the assessment method. Values for laurdan emission
GP in the fluid phase did not vary significantly between acclimation
groups (Fig. 2), whereas FTIR measurements indicated a less ordered
membrane in cold- than warm-acclimated trout (corresponding to a
regulatory efficacy of ~95%), particularly at elevated temperatures (Fig. 3). Previous studies of trout hepatocyte plasma membranes indicated nearly perfect (efficacy ~91%) compensation of membrane order in the bilayer interior [as assessed by
1,6-diphenyl-1,3,5-hexatriene (DPH) fluorescence
polarization], but the same study found no significant compensation
employing a probe
1-(4-[trimethylamino]-phenyl)-6-phenyl-1,3,5-hexatriene anchored at
the bilayer-water interface (16). The present results with laurdan
confirm the lack of compensation of membrane physical properties in the
interfacial region of the bilayer, but the FTIR data in combination
with the laurdan results and previous work [both on these
membranes employing DPH (16) and on other membrane systems (11,
19)] support the concept of a gradient of compensation in
membrane order across the bilayer, with the greatest degree of
compensation being observed in the bilayer interior.
Membrane behavior at high temperature: fluorescence
anisotropy of NBD-PE. Plasma membranes of both warm-
and cold-acclimated trout display a well-defined minimum in NBD-PE
anisotropy at relatively high temperatures (56-58°C) similar
to that seen in model lipid membranes undergoing the
lamellar-to-HII phase transition
(Fig. 5). This high-temperature minimum most likely reflects changes in
packing constraints originating from within the hydrophobic region of
the bilayer that reflect the tendency of these lipids to adopt some
type of nonlamellar configuration. Unambiguous confirmation of this
hypothesis requires the demonstration of nonlamellar lipid phases by
more rigorous biophysical methods. The temperatures of these minima are
clearly well beyond the physiological temperature range of rainbow
trout. Nevertheless, in situ processes believed to be dependent on
transient formation of nonlamellar lipid intermediates, including
membrane fusion and intracellular membrane trafficking, are normally
controlled by a suite of regulatory proteins (30, 59). One function of
such proteins may be to lower the temperature at which localized
nonlamellar structures are formed to within the physiological
temperature range. We thus believe that the measured transition
temperatures accurately reflect the intrinsic properties of membrane
lipids and reliably report the relative propensities of these lipids to
form nonlamellar structures.
Remarkably, membranes of cold-acclimated trout display an additional
minimum at significantly lower temperatures (~25°C). It is
unlikely that this low-temperature minimum reflects the formation of a
nonlamellar lipid phase. Nevertheless, this minimum, present only
in membranes of cold-acclimated fish, must reflect a
temperature-induced change in membrane lipid packing that constrains, to some degree, molecular motions in the head group region (9); this
constraint is most likely due to the thermal expansion of the
hydrophobic volume with rising temperature. Increased proportions of
bilayer-destabilizing lipids (such as phosphatidylethanolamine) are a
common adaptation of membrane lipid composition to growth at low
temperature in poikilotherms (14, 50). Because bilayer-destabilizing lipids have a greater propensity than bilayer-stabilizing lipids to
form the HII phase, the presence
of elevated proportions of the former in plasma membranes of
cold-acclimated trout may cause significant changes in lipid packing
forces to arise at lower temperatures (~25°C) in membranes of
cold- than warm-acclimated trout (57°C). The relatively large
acclimatory shift (of ~32°C) in the temperature at which this
change in lipid packing is first evident points to the potential
significance of regulating the propensity of lipids to form nonlamellar
phases, possibly because these phases have been implicated in dynamic
attributes of membrane function such as vesicle fusion and trafficking.
This hypothesis is supported by recent findings in E. coli (41) and A. laidlawii (1), demonstrating that organisms grown at
different temperatures modulate membrane lipid composition so that the
transition to the HII phase occurs
~10°C above the growth temperature.
Perspectives
In summary, characteristics of both the gel-fluid and
lamellar-nonlamellar phase boundaries of trout hepatocyte plasma
membranes vary with growth temperature. As illustrated in Fig.
7, warm-acclimated trout function well
within the interval between the gel-fluid and the presumed
lamellar-nonlamellar phase boundaries, the acclimation temperature
(20°C) being 7 (TGPl) to 13°C
(TFTIRl) above the former and 36°C
below the latter. In contrast, cold-acclimated trout function much
closer to the gel-fluid transition boundary [the acclimation
temperature, 5°C, being ~2°C either above
(TFTIRl) or below
(TGPl) this boundary, depending on the
technique used to measure it]. Consequently, even though
Tl is reduced by 5-6°C
with cold acclimation, the absolute relationship between the growth
temperature and Tl is not strongly
conserved. Nevertheless, acclimatory adjustments in
Tl may constitute a significant
adaptive response that limits the formation of gel-phase lipids at low acclimation temperatures. Of particular interest, the first indications of alterations in lipid packing as temperature is increased above the
gel-fluid transition occur at a lower temperature in cold- than
warm-acclimated trout (25 vs. 58°C), presumably reflecting an
increased propensity to form nonlamellar phases resulting from elevated
proportions of bilayer-destabilizing lipids in membranes of
cold-acclimated trout. Collectively, these data suggest that the
propensity of membrane lipids to form a nonlamellar phase may be
subject to stronger acclimatory pressures than is the gel-fluid transition temperature and represents a key attribute of membrane organization subject to adaptive regulation.
View larger version (25K):
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|
Fig. 7.
Summary of effects of acclimation temperature on phase behavior of
membrane lipids in hepatic plasma membranes of rainbow trout acclimated
to 5 and 20°C. Tl, temperature
of the onset of the gel-fluid transition;
Ts, completion temperature of the
gel-fluid transition; TNBD',
temperature of the minimum in NBD-PE fluorescence anisotropy unique to
cold-acclimated trout. Unshaded polygons define the minimal expanse of
the fluid lamellar phase; hatched regions indicate presence of
gel-phase lipids; crosshatched regions indicate the presence of
nonlamellar phase lipids; shaded regions indicate minimal range of the
gel-fluid transition: diagonal boundary runs between the onset of the
gel fluid transition as detected by laurdan GP
(TGPl) and FTIR
(TFTIRl), respectively; stippled region
in cold-acclimated fish represents interval between first indications
of altered lipid packing forces
(TNBD') and
TNL. Dashed arrow indicates
uncertainty in the molecular events giving rise to
TNBD'. Vertical arrows
indicate direction of change in phase boundaries when acclimation
temperature is altered. * Statistically significant change in
phase boundaries.
|
|
| |
ACKNOWLEDGEMENTS |
The authors thank the personnel of the Alchesay National Fish
Hatchery and Larry Nienaber for fish maintenance and acknowledge support from National Science Foundation Grant IBN-9507226.
| |
FOOTNOTES |
Address for reprint requests: J. R. Hazel, Dept. of Biology, LSC 226, Arizona State Univ., Tempe, AZ 85287-1501.
Received 11 December 1997; accepted in final form 21 May 1998.
| |
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