Extracellular H+ dynamics during oogenesis in Rhodnius prolixus ovarioles
1 Laboratory of Nervous System Disorders, Wadsworth Center, Albany, NY
12201-0509, USA
2 Department of Zoology, University of Manitoba, Winnipeg, MB, Canada R3T
2N2
* Author for correspondence (e-mail: ehuebnr{at}cc.umanitoba.ca)
Accepted 18 May 2004
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Summary |
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Key words: hydrogen, H+, ion-selective probe, oogenesis, insect, Rhodnius prolixus
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Introduction |
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Insect cells commonly harness electrogenic H+ transport to help
maintain membrane potential and to produce a transmembrane chemical gradient
that drives secondary transport mechanisms
(Dittmann, 1997;
Haley and O'Donnell, 1997
;
Harvey and Wieczorek, 1997
).
The dependence of cellular H+ regulation on the extracellular space
makes this ion ideally suited to investigation using a self-referencing,
extracellular, ion-selective probe (ISP), permitting selective H+
measurement with minimal perturbation of the tissue. Previous studies using
extracellular voltage-sensitive probes have established that dynamic
bioelectric currents are present around ovarioles of a number of insects
(Bohrmann et al., 1986
; Bowdan
and Kunkel, 1990
,
1994
; Diehl-Jones and Huebner,
1989
,
1992
;
Dittmann et al., 1981
;
Huebner and Sigurdson, 1986
;
Jaffe and Woodruff, 1979
;
Overall and Jaffe, 1985
;
Verachtert and DeLoof, 1986
;
Woodruff et al., 1986b
). Ion
substitution studies and exposure to pharmacological agents have demonstrated
that Na+, Cl, K+ and Ca2+
contribute to these currents in Rhodnius
(Diehl-Jones and Huebner,
1993
). Although voltage-sensitive probes have provided some
insight into the character of these ionic currents they are inherently
limited, since current alterations due to secondary or synergistic effects of
pharmacological perturbation are difficult to rule out. The ion-selective
probe offers a considerable advantage as a direct measuring tool without
pharmacological complications.
The telotrophic ovarioles of Rhodnius prolixus provide an ideal
model for this study, since they possess an exaggerated polarity between nurse
cells and oocytes, and there exists a wealth of morphological,
endocrinological and electrophysiological data. The coupling of oogenesis to
the ingestion of a blood meal also makes identification of causal
relationships more likely. Despite the importance of pH in many cell processes
relevant to oogenesis in Rhodnius, little is known about pH and
H+ flux during this process. O'Donnell and Sharda
(1994) determined the
pHi of vitellogenic follicles 400600 µm in length and
carefully investigated the pH-dependence of oocyte membrane potential, but did
not examine H+ flux and pH changes related to oocyte growth over a
complete oogenesis cycle. Determining the timing and magnitude of
extracellular H+ dynamics is an essential first step towards
understanding the potential role(s) of transmembrane fluxes during oogenesis.
By determining the spatial and temporal distribution of H+ fluxes
around the ovariole during a complete oogenesis cycle, we can gain insight
into regional and stage-specific pHi changes in the adult
Rhodnius ovariole, and can consider these in relation to the cell
differentiation and regulatory events of oogenesis.
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Materials and methods |
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Ion-selective probe (ISP) technique
Extracellular H+ flux was measured with the automated scanning
electrode technique (ASET) using a non-invasive ion-selective probe (ISP;
Applicable Electronics, Inc., Sandwich, MA, USA; Science Wares, Inc.,
Falmouth, MA, USA) based on Kuhtreiber and Jaffe
(1990) and Somieski and Nagel
(2001
). Glass electrodes were
fashioned from TW150-4 borosilicate capillary tubes (World Precision
Instruments, Inc., Sarasota, FL, USA) pulled to a 4 µm diameter tip on a
Sutter P-97 Flaming/Brown pipette puller (Novato, CA, USA). Batches of
3040 electrodes were preheated overnight at 200°C in a presilanized
100 ml glass chamber, silanized by adding 80 µl dichlorosilane
(Sigma-Aldrich, St Louis, MO, USA) to the chamber for 30 min, and
postsilanized overnight at 200°C after the chamber was briefly vented (A.
Shipley and J. Kunkel, personal communication). H+ probes were
backfilled with 40 mmol l1 KH2PO4 and
100 mmol l1 KCl, pH 7.0, then frontfilled with a 4050
µm column of hydrogen liquid ion exchanger (#85293, Fluka Chemie, Inc.,
Switzerland). The H+ probe was placed in an electrode holder
(#MEH2SW15, World Precision Instruments, Sarasota, FL. USA) with an Ag/AgCl
wire. A DRIREF2 (World Precision Instruments) was used as a reference
electrode. The ASET preamplifiers and 3D stepper motor system were mounted on
a Zeiss IM35 microscope (Zeiss Canada, Toronto) using a modified stage.
xy axes transmitted images of the ovariole were acquired using a Zeiss plan 2.5x objective and a Cohu 6500 (San Diego, CA, USA) video camera. Side view (z-axis) images were captured using a Panasonic WV-CD50 video camera fitted with a long focal length Optem Zoom-70 lens (Thales Optern, Fairport, NY, USA). A Computer Eyes 1024 framegrabber (Digital Vision Inc.) received inputs from both cameras. A Fostec (Schott-Fostec, Southbridge, MA, USA) fiber-optic lamp fitted with an infrared filter illuminated the sample. A Melles Griot (Ottawa, Canada) air table was used to minimize vibrations, and a Faraday cage (built by the authors) was used to minimize external electronic interference. The ISP signal was independently monitored using a Tektronics 2205 oscilloscope (Beaverton, OR, USA) to evaluate probe noise. All ISP and peripheral equipment was connected to a dedicated AC wall outlet with a neutral line connected directly to ground through an isolation transformer to eliminate noise from other equipment in the building; this arrangement was of utmost importance to achieve the low noise necessary to detect ion fluxes at the biological level.
Electrode calibrations were performed at the beginning and end of each ovariole scan, by measuring voltage offset in 0.1 mol l1 phosphate buffers with pH 8.0, 7.0 and 6.0, providing a measure of the probe's accuracy and response speed. H+-selective probes were only used if the slope of a line derived by plotting the logarithm of [H+] vs. the electrode's voltage output equaled the expected Nernst value of 56.2 mV (±5%) per tenfold change in concentration, and the probe took less than 10 s to settle on a voltage value during the calibration procedure at the beginning and end of each ovariole scan.
Each scan included background noise measurements taken at a point over 500 µm away from the tissue before and after scanning points along the ovariole. Twenty-five positions were measured along all stage 29 ovarioles (Fig. 1); additional positions measured in some ovarioles were included to obtain more information as the stalk separating T and T-1 follicles formed, as follicle cells began to differentiate during stages 23, and also to measure specific areas associated with the development of regionally specialized chorion production during stages 89. In some cases, certain positions did not exist or were inaccessible without severe disruption of the tissue and recording chamber; measurements were not made at these points. An image was captured at every point measured, to record the probe's position, to allow proper placement of a vector representing the H+ flux at that point during data analysis (described below), and to permit assessment of the ovariole's condition throughout the scan.
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A 3-D sampling routine was used to measure H+ concentration at an `origin' position within 2 µm of the ovariole surface, and 10 µm away from this origin in each of the x- and y-axes in the horizontal plane, and in the vertical z-axes, for a total of four measurements (Fig. 2). At each of these four points, the probe was paused for 1 s before taking a 1 s reading. Five complete 3-D measurements were taken at each position along the ovariole, and averaged during analysis. All positions were measured halfway up the ovariole in the vertical z-axis.
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Exported data were compiled using Microsoft ExcelTM, where
H+ flux was calculated based on the method of Kuhtreiber and Jaffe
(1990). The equations used to
calculate flux were modified to include the diffusion coefficient for hydrogen
(9.31x105 cm2 s1),
and the bath hydrogen concentration. 2-D and 3-D resultant vectors were
generated from the x- and y-axes values and the x-,
y- and z-axes values, respectively. The vertical
z-axis data were excluded, because they confounded the data without
contributing any essential further information.
Next, an image was generated using Adobe IllustratorTM 9.0 that displayed H+ flux at each position measured along the ovariole, using the first image taken during the trial as a backdrop. The image corresponding to the vector being placed (showing the position of the probe in relation to the ovariole) was positioned over the original image and rendered partially transparent to allow the two ovariole images to be juxtaposed. If the second picture required rotating to line up correctly, as sometimes happened when the ovariole moved slightly during a trial, it was adjusted to the nearest 0.5°, and the corresponding vector was similarly rotated before being placed. A line of arbitrary, consistent length was scaled according to the vector magnitude, so that H+ flux at different positions and from different ovarioles could be directly compared. Each vector was positioned so that the origin was next to the ovariole at the location where the probe measurement was taken. Once positioned, each vector was scored as a positive efflux if it extended away from the ovariole, or as a negative influx if it extended over the ovariole image.
Once signs had been assigned, the data from each ovariole were grouped according to ovariole stage, and stage-specific means and standard errors (S.E.M.) were calculated for each position measured along the ovariole. Using StatView software (SAS Institute Inc., Cary, NC, USA), single-factor analyses of variance (ANOVAs) were calculated for each stage, using ovariole position as the categorical variable, to assess the significance of signal vs. background noise. Significant difference was assigned as P<0.05. Fishers' PLSD (Protected Least Significant Differences) post-tests were performed to derive pairwise comparisons between all positions for each stage.
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Results |
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Significant extracellular H+ fluxes were localized to specific ovariole structures. H+ flux at some positions was especially prominent during all stages (Table 2), including all three positions along the interfollicular stalk separating the T and T-1 follicles, and both positions along the pedicel. In addition, H+ flux at other positions became significant during later stages, notably the junction between T and T-1 follicles during stages 79, and the position where the anterior and posterior regions of the T follicle meet.
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During the entire course of experimentation using ovarioles from insects dissected 312 d.p.f., only one stage-1 ovariole was encountered. This ovariole was unhealthy, and was consequently removed from subsequent analysis. Interestingly, only one of ten stage-3 ovarioles had formed a connective stalk long enough to measure three positions. During stage 4, H+ efflux at the connective stalk separating T and T-1 follicles reached its maximum rate. By stage 5, all ovarioles sampled but one had well developed interfollicular stalks. Beginning with stage-7 ovarioles, a small but significant increase in H+ efflux over the T-1 T-2 junction could be detected that was higher than other positions nearby. All other positions were not significantly different from background noise or from the positional average during previous stages. Along the T follicle in stage-8 ovarioles, H+ flux at the anterior T 1/3 and 2/3 positions actually reversed to become a significant influx. Stage-9 ovarioles developed two strong H+ effluxes not present in earlier stages. First, H+ efflux was observed at the T-1:T-2 junction, anterior to the newly activated T-1 follicle. Weaker efflux in this region was observed during stages 7 and 8, and by stage 9 many T-1 follicles had entered vitellogenesis and formed well-developed interfollicular stalks. The stage-9 average was heavily weighted by trials with T-1 follicles in midvitellogenesis. H+ efflux at the connective stalk separating T and T-1 follicles during stage 9 also increased. The second new H+ flux was seen over the specialized rim and pseudomicropyle structures of the forming chorion. A strong, discretely localized efflux in this region was observed in two ovarioles. While the graphs presented here show only a single point, this efflux was characterized further, and is considered further below along with other special regions of interest.
The spatial and temporal patterns of H+ fluxes presented in Table 2 are more easily visualized in a contour plot as (Fig. 3). Changes in H+ flux along the anterior of the T follicle are evident, while pedicel H+ fluxes were stable over time. Except for influxes along the anterior T 1/3 and 2/3 positions of stage-8 ovarioles (mentioned above), none of the influxes observed in later stages were significantly different from background noise.
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Detailed analysis of H+ flux at specific regions along the ovariole
The spatiotemporal patterns of extracellular H+ flux, derived
from the average flux at each position along ovarioles grouped according to
stage, constitute the major focus of this work. In addition to the average
extracellular fluxes observed, a few special cases not evident in the above
data were encountered that merit discussion, and these are considered
below.
During two scans of stage-9 ovarioles, an increased number of positions were measured near the prominent H+ efflux near the forming chorion rim, in order to resolve the source of H+ flux more accurately. H+ efflux was confined to a narrow region along the horizontal (anteroposterior) xy plane (Fig. 4), and continued circumferentially around the ovariole in the z-axis (N=2). In addition, H+ efflux in this region could be detected along stage-9 T follicles held in different orientations, suggesting it formed a ring encircling the entire rim. Fine mapping of the region to identify individual cells responsible for generating H+ efflux was not possible due to the limited optics of the side-mounted camera, and difficulties in visualizing specific groups of cells using the xy-plane camera due to the curvature of the ovariole. Nevertheless, the resolution was such that we could resolve a distinct and narrow zone (probably 34 cells wide at most) that composed part of the rim close to the juncture between the cap and the neck region of the main body (Fig. 4, asterisk). Remarkably, H+ efflux in this area continued even after ovulation (N=2), when the associated chorionated oocyte had been released into the oviduct (Fig. 5, asterisk). No H+ flux was detected around the corresponding region of a recently ovulated egg (N=1; not shown).
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H+ efflux begins at the junction between T-1 and T-2 follicles by stage 7, in the region of the newly forming connective (Fig. 6). Increased sampling in this region during four trials revealed that H+ efflux also extended posteriorly, presumably associated with the columnar follicle cells at the anterior pole of the oocyte (Fig. 6, asterisk).
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Discussion |
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General features of extracellular H+ flux during oogenesis in Rhodnius prolixus
One of the most striking features of H+ flux around adult
Rhodnius ovarioles is that the large, sustained transmembrane fluxes
at the interfollicular stalk separating T and T-1 follicle and at the pedicel
were effluxes. While average influxes were observed in other regions, notably
the anterior tropharium and the anterior surface of the T follicle during
stages 89, they were smaller and by no means balanced overall efflux.
Substantial influxes were also observed during individual trials in regions
that did not show average influxes, including over the lateral T follicle. As
a result, H+ flux across the cell membranes of the ovariole did not
appear to add up to zero, suggesting that H+ fluxes do not
establish a current loop, but rather that an intracellular source produces
H+ for efflux.
The lateral surfaces of vitellogenic T follicles did produce substantial
H+ fluxes; however, both influxes and effluxes were observed, and
in calculating the mean values at each stage the balance of influx and efflux
in these regions negated differences significant from noise. There are two
possible explanations for these results: first, that the differences reflected
the future embryonic axis, as shown for bioelectric currents around insect
follicles (Bowdan and Kunkel,
1990) and that we were incapable of discriminating them, since T
follicle orientation was not accounted for during these trials. A second
possibility stems from the morphology of the lateral follicular epithelium,
which forms large intercellular spaces during vitellogenesis to facilitate
yolk uptake. The ion-selective probe may have been positioned over either the
basal surface of a follicle cell or over the intercellular space. Differences
in H+ flux between these two regions, as might occur if small local
current loops were established, might explain the measurements we
obtained.
Regional H+ fluxes observed during oogenesis
Prominent extracellular H+ fluxes measured using the
ion-selective probe were mapped to discrete regions of the ovariole,
suggesting they are important to regional cell physiology. At many locations,
the pattern of H+ flux also changed over an oogenesis cycle,
suggesting these temporal changes are linked to dynamic events during
oogenesis. Thus it is important to consider the location and temporal dynamics
of these fluxes relative to the germ and somatic cell events contributing to
the development of a viable mature oocyte.
H+ efflux at the junctions separating follicles
The interfollicular stalks are ideally situated to regulate interfollicular
communication, coordinating entry into vitellogenesis or generating
anteroposterior polarity in both adjoining follicles. Therefore, the prominent
H+ efflux observed at the interfollicular stalk separating T and
T-1 follicles is significant. In particular, the stage-related variation in
the strength of this H+ efflux suggests a relationship to the
development of the terminal follicle.
Oogenesis in insect ovarioles involves a progression of stages: an oocyte in the penultimate (T-1) position becomes the terminal oocyte once the current chorionated T follicle passes into the oviduct. The H+ efflux at the anterior end of the T follicle could be traced back to follicles in the T-1 position as early as stage 7, where efflux begins before the connective stalk begins to form (see Fig. 6 and Results).
Identification of the cells that generate H+ efflux will be
essential to determine which cells might be affected by changes in
pHi, and will permit a better understanding of the potential
downstream effects of H+ efflux. Several cell groups exist at the
junction separating T and T-1 follicles that could be wholly or partly
responsible for generating the observed H+ efflux
(Fig. 7). For example, the
somatic cells of the connective stalk are functionally isolated from the
adjacent follicles. This could be seen when fluorescent dyes were injected
into the oocytes of either follicle. The dyes moved into follicle cells
surrounding the injected oocyte, but did not pass into cells of the stalk, or
into adjacent follicles (see Fig.
7 for orientation). This suggested that stalk cells are not
coupled to adjacent follicles via gap junctions
(Huebner, 1981b;
Telfer et al., 1982
; E.
Huebner, unpublished results). Thus transmembrane H+ flux may
influence intracellular H+ levels in the cells forming the stalk,
the follicle cells surrounding the oocyte, the oocyte itself, or some
combination thereof. While the cells responsible for H+ flux in
this region cannot be positively identified by this study alone, we hope to
address this question in future studies.
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H+ influx along the anterior surface of the T follicle
A significant feature of stage-8 ovarioles was the onset of H+
influx across the cap region of the T follicle. While H+ influx was
observed in some T follicles during earlier stages, it appears in the majority
of follicles during stage 8 and early stage 9, when H+ efflux at
the connective stalk was reduced. Vitellogenesis is also occurring at a rapid
pace during this period. Fusion of smaller yolk vesicles into larger, more
membrane-efficient spheres requires acidification of the vesicle interior to
release vitellogenin from its receptor
(DiMario and Mahowald, 1986;
Dittmann, 1997
;
Dittmann and Munz, 1999
), so
that excess membrane can be recycled to the oocyte surface. This process
appears to involve H+-pump activity, probably a V-ATPase
(DiMario and Mahowald, 1986
;
O'Donnell and Sharda, 1994
),
or a Na+/H+ antiporter
(Dittmann, 1997
;
Dittmann and Munz, 1999
) to
move H+ from the ooplasm into the yolk spheres. It is possible that
yolk vesicle acidification occurs during the later stages of oogenesis and is
strong enough that it exhausts the H+ pool available for efflux, so
that cytoplasmic pH remains stable throughout vitellogenesis.
Strong H+ efflux from follicle cells forming specialized chorion structures
While the source of other H+ fluxes remains speculative, the
H+ efflux that develops during stage 9 near the cap rim, where the
micropyle and pseudomicropyle cells form, is clearly generated by the follicle
cells. H+ efflux begins during chorionation
(Fig. 4), when most follicle
cells are no longer coupled to the oocyte and are separated from it by the
chorion. After the mature egg passed into the oviduct, H+ efflux
was still present along the follicle cells
(Fig. 5) but not the egg (not
shown), indicating the follicle cells generate this flux. H+ efflux
in this region occurs within a narrow zone and attenuates a short distance
away in either direction along the anteroposterior axis
(Fig. 4). While it was not
possible to identify the exact group(s) of follicle cells responsible for
generating this efflux, fine mapping of the region narrowed the field to a
band of cells anterior to the neck, over the cells forming the rim.
It is unlikely that H+ efflux here affects oocyte pH. Only one
group of follicle cells remains in contact with the oocyte during
choriogenesis, although it is unknown whether the cells remain electrically
coupled. These cells are responsible for forming the micropyle, a channel in
the shell allowing sperm to reach the oocyte. Typically, no more than 16
micropyle cells are present, with single cells or doublets spaced relatively
evenly around the rim's circumference (Beament,
1946,
1947
). These cells are
neighbored by pseudomicropyle cells, which are similar in morphology, except
the channels they form do not reach the oolemma. Approximately 200 of these
cells circle the rim, which is about 250 µm in radius (Beament,
1946
,
1947
). This means that the
micropyle cells are spaced roughly 1112 cells, or 100 µm, apart.
H+ flux was measured for several tens of µm above and below the
plane of measurement (not shown), without attenuating as it did along the
anteroposterior axis. Since H+ efflux in this region occurred
around the entire rim and was not solely a product of the micropyle cells, it
would appear that H+ efflux in this region could not affect the
oocyte. The link between these localized fluxes and their role in regional
follicle cell differentiation merits further study
(Huebner and Bjornsson,
2002
).
Potential roles of transmembrane H+ fluxes during oogenesis
The temporal and spatial pattern of transmembrane H+ flux
observed in this study underscores the potential importance of pH change in a
number of cell differentiation and developmental events during oogenesis. A
number of events during oogenesis in Rhodnius are potentially
regulated by changes in pHi; during the period when H+
efflux was observed at the interfollicular stalk connecting T and T-1
follicles, gap-junctional coupling is established between follicle cells and
the oocyte (Huebner and Injeyan,
1981), cytoskeletal changes occur in both oocyte and follicle
cells (Watson and Huebner,
1986
; McPherson and Huebner,
1993
), and the oocyte engages in endocytic uptake of yolk
precursors (Huebner and Anderson,
1972a
,b
).
In this paper we establish the location and dynamic changes of extracellular
H+ fluxes generated by the adult Rhodnius ovariole during
an oogenesis cycle, and consider a number of relevant pH-regulated events, the
importance of which we hope to address in future studies. This research sets
the stage for exploring a number of important questions regarding the role of
H+ dynamics in regulating oogenesis.
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Acknowledgments |
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References |
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