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White Feces Syndrome of Shrimp Arises from Transformation, Sloughing and Aggregation of Hepatopancreatic Microvilli into Vermiform Bodies Superficially Resembling Gregarines

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Accompanying acute hepatopancreatic necrosis disease (AHPND) in cultivated Asian shrimp has been an increasing prevalence of vermiform, gregarine-like bodies within the shrimp hepatopancreas (HP) and midgut. In high quantity they result in white fecal strings and a phenomenon called white feces syndrome (WFS). Light microscopy (LM) of squash mounts and stained smears from fresh HP tissue revealed that the vermiform bodies are almost transparent with widths and diameters proportional to the HP tubule lumens in which they occur. Despite vermiform appearance, they show no cellular structure. At high magnification (LM with 40-100x objectives), they appear to consist of a thin, outer membrane enclosing a complex of thicker, inter-folded membranes. Transmission electron microscopy (TEM) revealed that the outer non-laminar membrane of the vermiform bodies bore no resemblance to a plasma membrane or to the outer layer of any known gregarine, other protozoan or metazoan. Sub-cellular organelles such as mitochondria, nuclei, endoplasmic reticulum and ribosomes were absent. The internal membranes had a tubular sub-structure and occasionally enclosed whole B-cells, sloughed from the HP tubule epithelium. These internal membranes were shown to arise from transformed microvilli that peeled away from HP tubule epithelial cells and then aggregated in the tubule lumen. Stripped of microvilli, the originating cells underwent lysis. By contrast, B-cells remained intact or were sloughed independently and whole from the tubule epithelium. When sometimes engulfed by the aggregated, transformed microvilli (ATM) they could be misinterpreted as cyst-like structures by light microscopy, contributing to gregarine-like appearance. The cause of ATM is currently unknown, but formation by loss of microvilli and subsequent cell lysis indicate that their formation is a pathological process. If sufficiently severe, they may retard shrimp growth and may predispose shrimp to opportunistic pathogens. Thus, the cause of ATM and their relationship (if any) to AHPND should be determined.
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White Feces Syndrome of Shrimp Arises from
Transformation, Sloughing and Aggreg ation of
Hepatopancreatic Microvilli into Vermiform Bodies
Superficially Resembling Gregarines
Siriporn Sriurairatana
1
, Visanu Boonyawiwat
2
, Warachin Gangnonngiw
3
, Chaowanee Laosutthipong
1,4
,
Jindanan Hiranchan
1,4
, Timothy W. Flegel
1,3
*
1 Center of Excellence for Shrimp Molecular Biology and Biotechnology (Centex Shrimp), Faculty of Science, Mahidol University, Bangkok, Thailand, 2 Department of Farm
Resources and Production Medicine, Faculty of Veterinary Medicine, Kasetsart University, Thailand, 3 National Center for Genetic Engineering and Biotechnology, National
Science and Technology Development Agency, Pratum Thani, Thailand, 4 Department of Biotechnology, Faculty of Science, Mahidol University, Bangkok, Thailand
Abstract
Accompanying acute hepatopancreatic necrosis disease (AHPND) in cultivated Asian shrimp has been an increasing
prevalence of vermiform, gregarine-like bodies within the shrimp hepatopancreas (HP) and midgut. In high quantity they
result in white fecal strings and a phenomenon called white feces syndrome (WFS). Light microscopy (LM) of squash mounts
and stained smears from fresh HP tissue revealed that the vermiform bodies are almost transparent with widths and
diameters proportional to the HP tubule lumens in which they occur. Despite vermiform appearance, they show no cellular
structure. At high magnification (LM with 40-100x objectives), they appear to consist of a thin, outer membrane enclosing a
complex of thicker, inter-folded membranes. Transmission electron microscopy (TEM) revealed that the outer non-laminar
membrane of the vermiform bodies bore no resemblance to a plasma membrane or to the outer layer of any known
gregarine, other protozoan or metazoan. Sub-cellular organelles such as mitochondria, nuclei, endoplasmic reticulum and
ribosomes were absent. The internal membranes had a tubular sub-structure and occasionally enclosed whole B-cells,
sloughed from the HP tubule epithelium. These internal membranes were shown to arise from transformed microvilli that
peeled away from HP tubule epithelial cells and then aggregated in the tubule lumen. Stripped of microvilli, the originating
cells underwent lysis. By contrast, B-cells remained intact or were sloughed independently and whole from the tubule
epithelium. When sometimes engulfed by the aggregated, transformed microvilli (ATM) they could be misinterpreted as
cyst-like structures by light microscopy, contributing to gregarine-like appearance. The cause of ATM is currently unknown,
but formation by loss of microvilli and subsequent cell lysis indicate that their formation is a pathological process. If
sufficiently severe, they may retard shrimp growth and may predispose shrimp to opportunistic pathogens. Thus, the cause
of ATM and their relationship (if any) to AHPND should be determined.
Citation: Sriurairatana S, Boonyawiwat V, Gangnonngiw W, Laosutthipong C, Hiranchan J, et al. (2014) White Feces Syndrome of Shrimp A rises from
Transformation, Sloughing and Aggregation of Hepatopancreatic Microvilli into Vermiform Bodies Superficially Resembling Gregarines. PLoS ONE 9(6): e99170.
doi:10.1371/journal.pone.0099170
Editor: Kenneth So
¨
derha
¨
ll, Uppsala University, Sweden
Received March 15, 2014; Accepted May 12, 2014; Published June 9, 2014
Copyright: ß 2014 Sriurairatana et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits
unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: The authors confirm that all data underlying the findings are fully available without restriction. All data are included within the manuscript.
Funding: Partial funding for this work was obtained from the Surathani Shrimp Farmers Club, the Frozen Food Association of Thailand, Charoen Pokphand
Company Ltd., the Thai Commission for Higher Education, the National Research Council of Thailand and Mahidol University. The funders had no role in study
design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing Interests: The manuscript consists entirely of descriptive discoveries of an un-patentable, natural phenomenon and it describes no experimental
work or unique innovations that would be needed to conceivably result in the development of a commercial product. Thus, there are no actual, intended or
conceivable patents, products in development or products marketed to declare as being associate d with the contents of this manuscript. The partial support from
the Charoen Pokphand Company Ltd., Surathani Shrimp Farmers Club and public sectors listed above was offered simply to assist in investigations on the cause
of shrimp mortality for the free benefit of the Thai and world shrimp industry and for the free, overall, benefit of the Thai and world economies. Thus, the funding
provided entailed no constraints on adherence to all PLOS ONE policies on sharing data and materials.
* E-mail: sctwf@mahidol.ac.th
Introduction
The results presented in this manuscript describing transforma-
tion, sloughing and aggregation of hepatopancreatic microvilli into
vermiform bodies superficially resembling gregarines was obtained
over a period of 6 years in a piecemeal fashion as a series of
initially independent, sideline observations made during the course
of dedicated research projects on a variety of known shrimp
pathogens ranging from viruses to bacteria, fungi and parasites. It
was not until very recently that the connections between the
independent observations were understood, allowing them to be
linked together into a coherent whole. A major activity that helped
us to gain understanding of the connections between our
piecemeal observations was the intensive research that has been
carried out since 2009 and particularly since 2011 on many
hundreds of shrimp specimens studied in attempts to determine
the cause of acute hepatopancreatic necrosis disease (AHPND), the
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most recent, serious shrimp pandemic to cause severe losses in
Asian shrimp cultivation.
AHPND Outbreaks began in cultivated shrimp Penaeus (Penaeus)
monodon and Penaeus (Litopenaeus) vannamei China in 2009 and
thereafter spread progressively to Vietnam (2010), Malaysia (2011)
and Thailand (2012), although the cause of the disease was not
known at that time. Indeed, it was not until 2011 that a case
definition for AHPND was first described (referred to as acute
hepatopancreatic necrosis syndrome or AHPNS at the time) by
D.V. Lightner from the University of Arizona at a seminar
organized by the Vietnamese Department of Animal Health in
Hanoi in June 2011 (unpublished). It was subsequently described
in the Global Aquaculture Advocate magazine under the heading
of early mortality syndrome (EMS) in the Jan/Feb issue of 2012.
Later in the same year, a disease card was prepared by the
Network for Aquaculture Centres in Asia Pacific (NACA) and
made available at its website (www.enaca.org). Finally, the
causative agent (i.e., novel isolates of Vibrio parahaemolyticus) was
discovered in 2013 [1]. The unique diagnostic characteristic of the
disease is massive, medial sloughing of shrimp hepatopancreatic
(HP) tubule epithelial cells as a result of a currently unknown
toxin(s) that originates from the causative bacteria colonizing the
shrimp stomach.
Since confirmatory diagnosis of AHPND is still dependent on
histological diagnosis of massive sloughing of HP cells, many
hundreds of cephalothorax tissue sections of shrimp suspected of
AHPND infections have been examined with a primary focus on
the shrimp hepatopancreas. During the course of this work on
AHPND, a variety of other hepatopancreatic pathogens have also
been encountered and recorded but are not often reported.
Among such anomalies there has been an increasing prevalence of
vermiform bodies that superficially resemble gregarines within the
lumens of hepatopancreatic (HP) tubules, at the HP-stomach-
midgut junction and in the midgut of cultivated giant tiger shrimp
(P. monodon) and whiteleg shrimp (P. vannamei ). They sometimes
occur in sufficient quantities to cause white fecal strings in a
phenomenon called white feces syndrome (WFS) in pond reared
shrimp from approximately 2 months of culture onwards, and they
were originally described as gregarines that caused WFS [2]. It has
been estimated [3] that Thai production losses due to WFS in
2010 were 10–15% based on decreased survival and smaller
harvest sizes of shrimp from WFS ponds, and this estimate
excluded the normal annual Thai losses to white spot disease.
Here we describe detailed studies of the vermiform bodies using
light and electron microscopes and show that they are not
independent organisms but formations consisting of aggregated,
transformed microvilli (ATM) that have originated by sloughing
from epithelial cells of the shrimp hepatopancreatic tubules. They
then accumulate at the HP-midgut junction before being
discharged within feces via the midgut.
Figure 1. Gross signs of white feces syndrome WFS. (a) Floating,
white fecal strings. (b) White fecal strings on a feeding tray. (c) White
intestine of affected shrimp. (d) Golden brown intestine of an affected
shrimp. (e) Photomicrograph of fecal string contents.
doi:10.1371/journal.pone.0099170.g001
Figure 2. Squash mount of vermiform bodies (ATM) in shrimp
hepatopancreatic tissue. (a) Low magnification photomicrograph
showing 3 ATM with the central one inside an HP tubule. (b) Higher
magnification photomicrograph showing an ATM containing cyst-like
structures later found to be sloughed B-cells. (c) High magnification of
an ATM stained with Rose Bengal to more clearly reveal its internal
membranous structure.
doi:10.1371/journal.pone.0099170.g002
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Materials and Methods
As stated in the introduction, the work described in this
manuscript was not the result of a dedicated study on ATM but
constitutes the accumulation of piecemeal observations on many
hundreds of shrimp samples obtained from many sources
including 1) shrimp submitted to us by shrimp farmers for free
diagnosis of a variety of diseases including EMS/AHPND, 2)
shrimp purchased from farms or from broodstock producers for
research or for laboratory training purposes and 3) shrimp donated
by farmers or broodstock producers as a result of our requests at
local presentations about what we now call ATM. In all cases, the
specimens used came with no attached constraints in the
publication of results obtained from their examination. Many of
these shrimp specimens were of grossly normal appearance and
showed normal histopathology (except perhaps for ATM). The
vast majority of the histology slides examined since 2012 have
been from shrimp ponds suspected of EMS/AHPNS outbreaks
and none of these ponds (mostly at less than 35 days cultivation)
have exhibited shrimp with gross signs of WFS because of the early
stage of culture, but many show the presence of ATM. One
passive surveillance of ponds exhibiting WFS outbreaks was
carried out from 2009 to 2010 using 25 ponds at approximately 2
months of culture on 13 farms in the middle and eastern part of
Thailand. In that survey, farmers collected approximately 10
shrimp from each pond, and transported them to the laboratory
live for free examination for the presence of what we now call
ATM by squash mount preparation.
The live shrimp obtained for various purposes and used
piecemeal for analysis of ATM ranged from post-larvae to adult
stages and were examined continually from 2009–2013. To
prepare wet mounts, shrimp were first immersed in ice water for
stunning and then surface sterilized with 70% ethanol before
removal of small portions of HP tissue for direct observation in
artificial sea water (25 ppt)(Marinium) by light microscopy or for
preparing smears. For smears, a small drop of artificial seawater
(25 ppt) or 2.7% NaCl solution was placed on a microscope slide.
The HP tissue was placed in the solution before smearing. The
Figure 3. HP tissue smear stained with hematoxylin and eosin to reveal ATM. The photomicrographs clearly show the vermiform
morphology and the cyst-like contents inside or free.
doi:10.1371/journal.pone.0099170.g003
Figure 4. ATM aggregation steps in H&E stained HP tissue
sections in comparison to true gregarines. (a) Small, scattered
membrane-lie structures in the HP tubule lumen. (b) More extended
membranes beginning to aggregate in the tubule lumen. (c) Tighter
aggregation of membranes bound by a continuous outer membrane
and taking the shape of ATM. (d) Highly condensed ATM in a tubule
lumen. (e) Accumulation of many individual ATM at the center of the HP
near the midgut junction. (f) True gregarines clustered near the midgut
junction and showing prominent nuclei.
doi:10.1371/journal.pone.0099170.g004
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smears were dried at 40uC before staining with H&E in the same
manner as tissue sections (see below). For histological examination
of tissue sections by light microscopy, shrimp were similarly
stunned, injected with Davidson’s fixative and processed for tissue
sections of the cephalothorax stained with hematoxylin and eosin
(H&E) by standard methods [4]. For electron microscopy, HP
tissue of shrimp shown to carry ATM in whole mounts was cut in
small portions of approximately 1 mm
3
, fixed in artificial sea water
(Marinium) at 30 ppt containing 4% TEM grade glutaraldehyde
for 24 hours before transfer to phosphate buffer (40 mM
NaH
2
PO4?H
2
O, 100 mM Na
2
HPO4, 170 mM NaCl, pH 7.4).
The pieces were then post-fixed in 1% OsO4 in the same buffer at
4uC for 1 h prior to being processed routinely for conventional
embedding in Spurr’s resin. Semithin sections for viewing by LM
were stained with toluidine blue (toluidine blue O 4 g, pyronin
1 g, borax 5 g, distilled water 500 ml) and ultrathin sections for
TEM were stained with uranyl acetate and lead citrate before
viewing with a Hitachi H-500 transmission electron microscope.
Results
Field signs of white feces syndrome (WFS)
Gross signs of WFS in shrimp cultivation ponds (Fig. 1)
included white to somewhat yellow, floating fecal strings (Fig. 1a)
that sometimes collected in mats or could also be found on feeding
trays (Fig. 1b). Examination of shrimp from ponds exhibiting signs
of WFS revealed that the dissected midgut junction and midgut
were distended and filled with white to yellow-golden contents
(Fig. 1c,d). When the contents of the gut or fecal strings were
examined in squash mounts with the light microscope, they
consisted of masses of vermiform bodies that superficially
resembled gregarines (Fig. 1e).
A passive surveillance of WFS outbreaks in P. vannamei was
carried out from 2009 to 2010 in the eastern and middle part of
Thailand in 25 ponds from 13 farms to determine the relationship
between WFS and vermiform bodies resembling gregarines. The
results revealed that 96% (24/25) of the ponds exhibiting WFS
contained shrimp specimens that presented vermiform bodies
resembling gregarines. Severely affected ponds exhibited reduction
in shrimp survival by 20–30 percent when compared to normal
ponds. There was also a decrease in feed consumption and growth
Figure 5. Semi-thin sections of HP tissue stained with toluidine blue. (a) Cross section of an HP tubule near the distal end showing densely
stained particles in crypts formed by folds of the tubule epihelium and showing aggregated, transformed microvilli (ATM) in the tubule lumen. Note
that microvillar layers of all the cells are intact. (b) Cross sections of HP tubules showing sloughed, transformed microvilli. (c) Cross section of anHP
tubule showing a modified, sloughed B-cell in the tubule lumen with microvilli scattered over its surface. Also seen are tubule epithelial cells with
normal microvilli and transformed mivrovilli, and one cell denuded of microvilli, undergoing lysis. (d) High magnification of clustered ATM at the
center of the HP clearly showing an outer membrane enclosing multitudes of folded transformed microvilli. Some also contain enclosed, sloughed B-
cells. Note many free transformed microvilli fragments surrounding the ATM.
doi:10.1371/journal.pone.0099170.g005
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rates were reduced as revealed by average daily weight gain (ADG)
for the whole crop operation of less than 0.1 g/day compared to
0.2 g/day in normal ponds. Feed conversion ratios (FCR) ranged
from 1.7 to 2.5 when compared to 1.5 or less for normal ponds.
Light microscopy
Whole mounts of shrimp hepatopancreatic tissue at any life
stage from post-larvae (PL) to broodstock of P. monodon and P.
vannamei currently cultivated in Asia (either diseased or grossly
normal) often revealed the presence of non-motile, vermiform
bodies superficially resembling gregarines within the tubule
lumens, the HP-midgut junction and the midgut (Fig. 2). The
average size was 39 (range 17 to 58)
mm wide by 279 (50 to
517)
mm long (N = 21) and was smaller but roughly proportional to
the size of the tubules that contained them. They sometimes
contained spherical bodies that resembled cysts (Fig. 2b). Besides
these cyst-like inclusions, they had no apparent cellular or
subcellular features (e.g., nuclei) and contained only what
appeared to be interfolded membranes that could be visibly
enhanced by staining with Rose Bengal (Fig. 2c). Smears of HP
tissue from affected shrimp stained with hematoxylin and eosin
made these bodies more clearly visible but still revealed no cellular
or subcellular structures such as nuclei (Fig. 3). However,
examination of these two types of preparations clearly revealed
why they were first referred to as gregarine-like entities (GLE).
Examination of living shrimp specimens of both P. monodon and
P. vannamei from post larval to broodstock life stages often revealed
the presence of GLE in small to massive numbers that varied from
shrimp to shrimp specimen, even from the same pond or hatchery
tank. The affected shrimp showed no gross signs of disease
(including white fecal strings) resulting from their presence, even in
high numbers.
HP tissue of affected shrimp fixed with Davidson’s fixative and
processed for normal histological examination of tissue sections
stained with hematoxylin and eosin (H&E) did not give as good
resolution of the GLE as did whole squash mounts or stained
smears. Instead, they often appeared to be partially degraded by
the preparation steps, so that their membrane contents were
difficult to resolve or could not be distinguished easily from the
normal chyme-like material that is often seen in the HP lumens of
shrimp that are actively feeding. In some better preserved
specimens, it was possible to prepare a series of photomicrographs
suggestive of progressive aggregation and condensation of
individual membranes into GLE that lacked recognizable cellular
structures and accumulated at the center of the HP near the
midgut junction to superficially resemble gregarines (Fig. 4). The
progression began as scattered membranes (Fig. 4a) followed by
stages of aggregation (Figs. 4b & 4c) followed by condensation
(Fig. 4d) and accumulation at the HP center (Fig. 4e). For
comparison, a photomicrograph of H&E stained tissue of
cultivated P. monodon (Fig. 4f) shows true gregarine trophozooites
(probably Nematopsis sp. [5])clustered in the region of the HP/
midgut junction. These are rarely found in cultivated shrimp in
Thailand and compared to GLE, they are larger, stain more
intensely and have prominent nuclei. In addition, they do not arise
by a process of membrane aggregation and condensation.
Using light microscopy to examine semi-thin sections of HP
tissue of affected shrimp fixed and embedded for transmission
electron microscopy (TEM) and stained with toluidine blue, clearly
revealed that the GLE consisted of a thin outer membrane that
enclosed a complex of thicker interfolded membranes (Fig. 5a–d).
These sometimes surrounded what was later found to be sloughed,
whole B-cells (Fig. 5d). The tubules that contained the GLE also
showed many epithelial cells with abnormally thin microvillar
layers or denuded of microvilli ( Fig. 5c). The latter showed signs
of lysis (Fig. 5c). Free membrane-like structures were present in
the tubule lumens in addition to the GRL (Fig. 5b,d).
Transmission electron microscopy (TEM)
TEM of affected shrimp tissues (Fig. 6) revealed that the GLE
were surrounded by a thin, single-layer membrane that bore no
resemblance to a bilaminar plasma membrane or to the complex
outer layers of known protozoans, metazoans or gregarines
(http://tolweb.org/Gregarina/124806; [6,7,8,9,10,11,12], includ-
ing a gregarine previously reported from Thailand [5]. It enclosed
a complex of thicker, interfolded membranes with a tubular
substructure, and these occasionally surrounded whole B-cells
sloughed from the HP tubule epithelium. The GLE otherwise
contained no recognizable cellular contents such as nuclei,
mitochondria, ribosomes, etc. The origin of the outer, single-layer
membrane could not be determined, but the enclosed, interfolded
membranes with a tubular substructure were found to originate
Figure 6. TEM of an ATM structure containing an enclosed, sloughed and modified B-cell. Note the single-layer enclosing membrane and
the internal complex of sloughed, modified microvilli.
doi:10.1371/journal.pone.0099170.g006
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from microvilli of HP tubule epithelial cells of the R and F types
(Fig. 7). The microvilli first became transformed into a partially
collapsed state (Fig. 7a,c,d) before they peeled off of the cells
(Fig. 7b,c,d) and sloughed into the tubule lumen where they
aggregated to form GLE (Fig. 7a). The cells denuded of microvilli
subsequently lysed (Fig. 7a ), releasing their contents into the
tubule lumen, often leaving a remnant containing the basal
nucleus collapsed against the tubule basal membrane. Based on all
the information from light microscopy to electron microscopy,
these bodies were named aggregated transformed microvilli
(ATM).
By TEM, the F and R cells with transformed microvilli did not
show the presence of recognizable pathogens such as viruses,
bacteria or parasites. However, in the E-cell region of the HP
where the tubule epithelium was somewhat folded to form cript-
like spaces with facing microvillar layers, minute, densely staining
bodies of irregular shape and size could be seen by light
microscopy (Fig. 4a) and by TEM (Fig. 8). These appeared to
aggregate and be capable of passing through the microvillar layers
(Fig. 8a & b) to enter the subtending cellular cytoplasm (Fig. 8c).
This association appeared to be accompanied by changes in the
morphology of the microvilli (Fig. 8c & d), and cells that showed
advanced microvillar transformation appeared to have large
numbers of such inclusions (Fig. 8d). It was not clear whether
they had increased in numbers by accumulation or by prolifer-
ation. They lacked subcellular structures that might indicate
relationship to known viral, prokaryotic or eukaryotic organisms,
and it could not be determined whether they were causal or
incidental to ATM formation.
We examined the shrimp midgut only in squash mounts and in
the portion of the midgut that occasionally appeared in saggital
tissue sections of the whole cephalothorax region in H&E stained
slides. We did not examine the midgut further with semithin
sections or by TEM. However, in the H&E sections we found no
evidence that ATM were formed in the midgut. Instead, they
simply accumulated there as they were released from the HP.
Figure 7. TEM of steps in microvillar transformation and sloughing. (a) Low magnification of HP tubule epithelial cells showing normal and
transformed microvilli and two denuded cells undergoing lysis. Also shown is an early stage in the aggregation of transformed and sloughed
microvilli surrounded by an enclosing membrane. (b) Low magnification of HP tubule epithelial cells with transformed microvilli peeling from the cell
surface, prior to cell lysis. (c) Higher magnification of the field from (b) clearly showing the difference between normal and transformed microvilli. (d)
High magnification of HP tubule epithelial cells showing the tubular nature of transformed and peeled microvillar layers.
doi:10.1371/journal.pone.0099170.g007
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Discussion
Before we had detailed results from electron microscopy
revealing the nature of ATM origin, we were dependent on light
microscopy results showing vermiform bodies that resembled
gregarines. A search of the literature about gregarines at that time
revealed that none of those previously reported from shrimp
[13,14,15], including one previously reported from Thailand [5]
bore any resemblance to ATM. Specifically, they lacked motility
(i.e., in squash mounts) and showed no organelles such as usually
prominent nuclei. Subsequent results from electron microscopy
confirmed the absence of nuclei and other ultrastructural features
normally found in gregarines (e.g., complex pellicles, mitochon-
dria, ribosomes, etc.). However, we did find a previous report by
Johnson [16] that described the occasional presence of cellophane-
like aggregations of membranous material in the hepatopancreatic
tubule lumens of crabs and proposed that they arose from the
microvilli of the tubule epithelial cells. She did not give details of
their formation and expressed the inability to explain their
function or significance. She also expressed the inability to
conclude whether they were the result of a normal process or of
some kind of rare pathology. Our ATM from shrimp morpho-
logically resembled the structures described by Johnson in crabs by
light microscopy (her Figs. 129, 147 and 164) and especially by
TEM (her Fig. 152). We could find no other published description
of these entities in crustaceans.
When the occurrence of ATM is severe, it can lead to the
formation of white fecal strings in shrimp, and if many shrimp in
the same pond exhibit this phenomenon, it can lead to floating
fecal strings that sometimes accumulate in floating mats (i.e., white
feces syndrome or WFS). This usually occurs from 2 months of
cultivation onwards, and it may be accompanied by high shrimp
mortality. However, ATM sometimes occur together with shrimp
hepatopancreatic diseases such as the AHPND, other types of
vibriosis, and parasitemia with the microsporidian Enterocytozoon
hepatopenaei. As a result, the cause of WFS in Vietnam was
Figure 8. TEM of unusual electron-dense particles in HP tubule crypts. (a) Low magnification of electron-dense particles of highly variable
shape in the HP tubule lumen between layers of normal microvilli from facing epithelial cells. (b) High magnification of one of the electron-dense
particles between the microvilli on the outside surface of an epithelial cell, possibly prior to cell entry. (c) High magnification of electron dense
particles inside an epithelial cell with adjacent microvilli on the cell surface undergoing morphological changes. (d) Low magnification of an epithelial
cell containing large numbers of electron dense particles and with microvilli in an advanced stage of transformation.
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attributed also to E. hepatopenaei [17], but this was later shown to be
very unlikely based on closer study of natural and laboratory
infections of E. hepatopenaei in Thailand [18]. Thus, it is certain that
these severe cases of WFS result from massive ATM formation.
However, the cause of ATM formation remains a mystery.
Hopefully, understanding their nature and mode of formation will
lead to more directed studies to determine their cause.
Overall, our work has shown that the formation of ATM results
from transformation of microvilli followed by sloughing from the
subtending cell and by subsequent lysis of that cell. These features
indicate that ATM formation is a pathological process. The fact
that ATM were not previously described in shrimp, despite their
easy recognition in whole mounts and smears of HP tissue from
living shrimp, argues that their previous occurrence was probably
overlooked due to low prevalence, as previously reported by
Johnson for crabs [16]. However, they have recently increased in
prevalence in Asia to the extent that they are now too prevalent to
be overlooked.
It may be significant that the increase in prevalence of ATM has
been coincidental with the increase in prevalence of AHPND
outbreaks. Although this might suggest a possible causal associa-
tion, there has also been a coincidental increase in prevalence of
the hepatopancreatic microsporidian Enterocytozoon hepatopenaei [18]
with AHPND, and we now know that this is certainly not a causal
relationship, since AHPND is caused by unrelated bacteria [1]. So
at least for E. hepatopenaei and AHPND bacteria, it seems likely that
some of their increased prevalence has resulted from contamina-
tion of broostock and/or post-larvae (PL). This contention is
supported by anecdotal evidence from widely separated Thai
shrimp farmers who received portions of single batches of PL
derived from SPF shrimp stocks but then experienced AHPND
outbreaks more-or-less simultaneously. It is also supported by our
discovery of endemic E. hepatopenaei in locally held broodstock and
PL of SPF P. vannamei stocks that originated from the Americas
where this microsporidian has never previously been reported
[18].
Altogether the previous information suggests that the biosecurity
measures in at least some shrimp hatcheries have not been
sufficiently rigorous to exclude contamination by imported and/or
local pathogens. Therefore, we must consider two possibilities with
respect to ATM. Either they are caused by a new agent that has
contaminated SPF stocks in a similar manner to AHPND and E.
hepatopenaei, or that they constitute an alternate manifestation of an
existing pathogen. For example, it has been reported that AHPND
bacteria produce a potent toxin that can cause sloughing of
hepatopancreatic tubule epithelial cells [1], and it may be asked
whether the same toxin at low doses may cause the formation of
ATM in the absence of cell sloughing. To test this latter possibility,
the laboratory infection model recently described [1] may be used
with diluted toxin preparations from the causative bacteria. With
respect to the existence of a new pathogen, comparative
metagenomic analysis of shrimp with and without ATM may be
the most useful. Alternatively, the possible involvement of the
minute, electron dense bodies described here to be associated with
microvillar transformation may be further investigated. For
example, it may be possible to separate them physically from
tissue homogenates by differential centrifugation and/or filtration
for further analysis and for laboratory challenge tests.
In conclusion, we have revealed by TEM that vermiform
structures superficially resembling gregarines and commonly
found now in the HP of Asian cultivated shrimp are not
independent organisms but result from the transformation,
sloughing and aggregation of microvilli from the HP tubule
epithelial cells themselves. The denuded epithelial cells subse-
quently undergo lysis, indicating that the process has the potential
for negative impact on shrimp growth and survival, and in very
severe cases can lead to the phenomenon called white feces
syndrome (WFS). Further investigation is needed to understand
the cause of ATM and evaluate their impact on shrimp
production.
Acknowledgments
We would like to thank the editors and the reviewers who provided
valuable comments that were important for improving the text and figures
of our manuscript.
Author Contributions
Conceived and designed the experiments: SS VB TWF. Performed the
experiments: SS VB TWF WG CL JH. Analyzed the data: SS VB TWF.
Contributed reagents/materials/analysis tools: SS VB WG. Contributed to
the writing of the manuscript: SS VB TWF.
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White Feces Syndrome of Shrimp and ATM
PLOS ONE | www.plosone.org 8 June 2014 | Volume 9 | Issue 6 | e99170
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