- Email: [email protected]
From epithelial remodelling to carcinogenesis
Journal Pre-proof From epithelial remodelling to carcinogenesis
Leszek Satora, Jennifer Mytych, Anna Bilska-Kos, Katarzyna Kozioł PII:
S0079-6107(19)30080-X
DOI:
https://doi.org/10.1016/j.pbiomolbio.2019.08.001
Reference:
JPBM 1469
To appear in:
Progress in Biophysics and Molecular Biology
Received Date:
16 April 2019
Accepted Date:
01 August 2019
Please cite this article as: Leszek Satora, Jennifer Mytych, Anna Bilska-Kos, Katarzyna Kozioł, From epithelial remodelling to carcinogenesis, Progress in Biophysics and Molecular Biology (2019), https://doi.org/10.1016/j.pbiomolbio.2019.08.001
This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. © 2019 Published by Elsevier.
Journal Pre-proof 1
From epithelial remodelling to carcinogenesis
2 3
*Leszek
Satoraa, Jennifer Mytychb, Anna Bilska-Kosc and Katarzyna Koziołb
4 5
*aPomeranian
6
bDepartment
7
36-100 Kolbuszowa, Poland.
8
cDepartment
9
Institute - National Research Institute, Radzików, 05-870 Błonie, Poland
Center of Clinical Toxicology Kartuska 4/6, 80-104 Gdansk, Poland.
of Animal Physiology and Reproduction, University of Rzeszów, Werynia 502,
of Plant Biochemistry and Physiology, Plant Breeding and Acclimatization
10 11
*Corresponding
12
Dr Leszek Satora
13
Pomeranian Center of Clinical Toxicology Kartuska 4/6, 80-104 Gdansk, Poland.
14
Tel: +48 682 19 39
15
E-mail: [email protected]
16 17 18 19 20 21
author
Journal Pre-proof 22
Abstract
23
The novel cancer theory named ‘The tissue organization field theory’ (TOFT) suggests that
24
carcinogenesis is a process analogous to embryonic development, whereby organs are formed
25
through interactions among different cell types. The suggested ‘morphological remodelling’
26
of the epithelium under hypoxia in gut breathing fish (GBF) has many common features with
27
carcinogenesis. It appears that research into the relationship among epidermal growth factor
28
receptor (EGFR), hypoxia inducible factor (HIF) as well as hypoxia and normoxia states in
29
GBF fishes can be crucial in learning about the steering mechanisms of squamous epithelium
30
proliferation, leading to a better understanding of carcinogenesis.
31 32
Key Words: Gut breathing fish; EGFR, HIF 1; hypoxia; epithelial remodelling;
33
carcinogenesis; TOFT theory
34 35
The proliferation of the squamous cells in the digestive tract of gut breathing fish (GBF)
36
under hypoxia conditions seems to be an extremely beneficial event. This process allows fish
37
to create a thin air-blood barrier and use the digestive tract as an additional respiratory organ
38
during hypoxic conditions (Satora et al., 2019). Ancistrus chagresi (spinosus) included in the
39
GBF fish group can adjust about 25% of the surface of the stomach to air-breathing (Graham,
40
1997), while in bronze Corydoras about 48% of the digestive tract can be transformed into an
41
additional respiratory organ under water hypoxia conditions (Leknes, 2015). Therefore it may
42
be indicated that the above mentioned adaptations are a type of the‘morphological
43
remodelling’ of epithelial cells.
44
Studies using specific antibodies against the intracellular domain of human epidermal growth
45
factor receptor (EGFR) demonstrated the presence of active, proliferating squamous cells in
Journal Pre-proof 46
the GBF fish digestive tract, in both corydoras (Satora et al., 2017; Mytych et al., 2018) and
47
otocinclus (Satora et al., 2019). High EGFR expression observed in the respiratory part of the
48
intestine in bronze Corydoras and in the stomach of O. affinis suggest higher proliferation
49
activity and angiogenesis of epithelium in that part of the intestine, which creates the
50
conditions for aerial respiration. Furthermore, quantitative analysis of EGFR protein
51
abundance also revealed its higher synthesis in the respiratory stomach of O. affinis (Satora et
52
al., 2019). However, the experimental setup allowing inhibition and /or stimulation of
53
proliferation markers seems to be an important next stage of research on gut breathing fish.
54
Antibodies anti-EGFR (cytoplasmic domain) are used to test active, proliferating epithelial
55
cells in the diagnosis, prognosis and monitoring of the squamous carcinomas (Gröbe et al.,
56
2014). Increased levels of EGFR are linked with malignant transformations of squamous cells
57
(e.g. squamous cell carcinoma in the lungs, esophagus, neck, head). EGFR mediating
58
signalling has been shown to induce mitogenic responses in a variety of cell types. The
59
diagnosis of poor prognosis is based on the studies of EGFR expression in human breast
60
cancer (Gröbe et al., 2014). Most studies on EGFR and its ligands in fish were performed
61
using recombinant mammalian proteins (Wang and Ge, 2004; Tse and Ge, 2009; Mytych et
62
al., 2018). Furthermore, in teleost fish the lineage-specific co-evolution of the EGF
63
receptor/ligand signalling system was demonstrated (Laisney et al., 2010) and the
64
amplification of EGFR gene was also observed (Gomez et al., 2004; Laisney et al., 2010),
65
similarly to carcinogenesis (Chang et al., 2019). It may be speculated that this process is
66
induced by hypoxia.
67
Hypoxia inducible factor-1 (HIF-1) is one of the major components of cellular response to
68
oxygen deprivation. Activated HIF-1 plays a crucial role in adaptive responses of the tumour
69
cells to fluctuations in oxygen concentration through transcriptional activation of over 100
70
downstream genes. HIF-1 regulates important biological processes required for tumour
Journal Pre-proof 71
survival and progression, including transcription of genes involved in the cell proliferation
72
(Masoud and Li, 2015).
73
The PCR studies and immunolocalization using antibodies specific to HIF-1α followed by
74
visualization under transmission electron microscope (TEM) revealed high expression of HIF-
75
1α and the presence of numerous HIF-1α epitopes in the respiratory part of the bronze
76
Corydoras’ intestine (Satora et al., 2018). In all GBF fish species examined a potential ability
77
for proliferation of squamous cells in various parts of the intestine was observed. It seems that
78
it is carried out according to the same mechanism, being driven by the states of water hypoxia
79
inducing a ‘cascade of events’ which leads to the proliferation of squamous epithelial cells
80
(Satora et al., 2017; Mytych et al., 2018; Satora et al., 2018; Satora et al., 2019).
81
The appearance of tetrapods and land colonization, one of the most important occurrence in
82
vertebrate evolution, were both connected with the high capacity of the air-breathing
83
(Graham, 1997). Although there is no direct physiological evidence described in the
84
paleontological records and we can only study currently existing species, a number of
85
generalizations can be made. For example, adapting the digestive tract to function as an
86
additional respiratory organ under hypoxia states seems to be associated with numerous
87
difficulties in the development of this ability in GBF fishes (Nelson, 2014). The extremely
88
delicate respiratory epithelium; the minimum thickness of the air-blood barrier in GBF fish is
89
about 0.2 m; is highly susceptible to mechanical damage and the action of gastric secretions
90
(Satora, 1998; Nelson, 2014). On the other hand, the ability to proliferate squamous cells and
91
the ‘morphological remodelling’ of the epithelium of the digestive tract in low oxygen
92
conditions seems to be an excellent property. Phylogenetically, the lungs were derived as a
93
unique adaptation to conditions of low oxygen content in the aquatic medium wherein the fish
94
ancestors lived. Despite differences, all of these organisms possessed a characteristic feature:
Journal Pre-proof 95
the presence of a simple squamous epithelium covering the numerous capillary vessels. This
96
adaptation facilitates gas diffusion (Satora, 1998; Icardo, 2018).
97
Lungs as well as respiratory and non-respiratory bladders of chondrostean appear to originate
98
from a respiratory, posterior pharynx (Icardo, 2018). It can also be assumed that their
99
formation could be related to the proliferation of the squamous cells and the gradual
100
enlargement of the diverticulum in the anterior part of the digestive tract. If the proposed
101
‘morphological remodelling’ process, which involves the proliferation of squamous cells
102
under hypoxia, played an important role in the development of lung and gas bladders, it could
103
have been further consolidated. It is suggested, that in GBF fishes the proliferation process of
104
squamous cells is strictly controlled and is probably inhibited under normoxia. It also seems
105
that putative O2 chemoreceptors, the neuroepithelial cells (NECs) which manifest peculiar
106
neurotransmitter profiles, they can play an important role in this process. However, future
107
experiments are needed to evaluate how NECs and neural pathways are centrally integrated in
108
GBF fishes (Zaccone et al., 2006; Jonz, 2018; Satora et al., 2019). In mammals during lung
109
development, undifferentiated cuboidal cells form lining in distal air spaces and transform
110
into respiratory epithelium (pneumocytes). EGF receptors are of critical importance in this
111
process (Miettinen et al., 1997).
112
About 90 years ago Otto Warburg described how cancer cells avidly consume glucose and
113
produce lactic acid under aerobic conditions (Warburg effect). Hypoxia, frequently observed
114
in solid tumors, results in an increased HIF1 transcription factor activity. Furthermore, HIF-
115
1is one of the most important effector molecules downstream to EGFR pathways (Koppenol
116
et al., 2011). On the other hand, hypoxia and normoxia are opposed conditions adjusting gill
117
remodelling as well as the production or reduction of cellular mass between the lamellae of
118
the gills in several species of teleosts fish (Nilsson, 2007). In this process NECs – putative O2
119
chemoreceptors - are involved (Tzaneva et al., 2001).
Journal Pre-proof 120
In accordance with the novel theory, cancer is a relational problem. The main attention was
121
focused on the level of biological organization - cancer as a problem of tissue organization
122
similar to histogenesis and organogenesis (Sonnenschein and Soto, 2016). According to
123
Sonnenschein and Soto (2016), carcinogenesis is a process analogous to embryonic
124
development, whereby organs are formed through interactions of different cell types. The
125
basic premise of the tissue organization field theory (TOFT) is that proliferation with
126
variation and motility is the default state of all cells (Sonnenschein and Soto, 2016).
127
On the other hand, epithelial-mesenchymal transition (EMT) and mesenchymal-epithelial
128
transition (MET) processes, take part not only in the physiological conditions but also in the
129
carcinogenesis (Taylor et al., 2010; Chaffer et al., 2007; Hugo et al., 2007). Further, it has
130
been demonstrated, that EMT may be induced by hypoxia states and through activation of the
131
EGFR signalling pathway (Misra et al., 2012). In addition, HIFs and EGFR are overexpressed
132
in many types of cancer (Wang 2017; Talks et al., 2000; Zhong et al.,1999) and exhibit, i.a.
133
mitogenic effects (Hirsch et al.,2003; Schultz et al., 2006; Gordan et al., 2007). There is a
134
possibility that enterocytes in the GBF fishes undergo a process of EMT under hypoxia. In
135
this scenario, during EMT process, the cells lose intercellular connection and acquire ability
136
to move, then they transform into mesenchymal cells with increased proliferation ability, and
137
next, they may differentiate into various cell types (including squamous) during MET process
138
(Kalluri and Weinberg, 2009; Pei et al., 2019). The resulting squamous cells are the optimal
139
barrier for gas exchange in the gastrointestinal tract. EMT and/or MET are accompanied by
140
serial events of extracellular matrix deposition, changes in the expression of genes associated
141
with both epithelium or mesenchymal layers, and eventually changes in the morphology
142
(Moustakas and Heldin, 2007). It is crucial to maintain the balance between proliferative and
143
antiproliferative factors and the correct regulation of cellular plasticity through EMT and
144
MET under local cellular environment (Gérard and Goldbeter, 2014; Roca et al., 2013). It is
Journal Pre-proof 145
suggested that both EGFR and HIF-1α may be essential signals enabling the ‘default state’ of
146
gastrointestinal epithelial cells in GBF fishes, in the response to the change in the oxygen
147
concentrations. Finally, there is the morphological rebuilding of the epithelium, which seems
148
to be consistent with the TOFT theory.
149
The suggested ‘morphological remodelling’ of the epithelium under hypoxia – factor which
150
‘triggers’ cells from the state of equilibriumin gut breathing fish has a number of common
151
features with carcinogenesis. However, it should be emphasized that the mechanisms of
152
dependence of metabolic profiles and cellular phenotypes are still poorly recognized as well
153
as the regulation of the fate of the cells in the cell proliferation processes is only just
154
beginning to be understood. Thus, GBF fishes are not only an evolutionary curiosity that
155
comes as a surprise to many researches (Icardo, 2018), but they also seem to be a very
156
interesting model organism within which the proliferation of squamous cells can be examined
157
in a multithreaded way. Further investigations of the mechanisms controlling this
158
phenomenon in gut breathing fish will result in extending our knowledge about cancer
159
processes.
160 161
Conflict of interest
162
The authors declare no conflict of interest.
163
Author contributions
164
L.S. conceived and designed the research project and wrote the manuscript. J.M., A.B-K and
165
K.K. interpreted the results and helped writing the manuscript.
166 167 168
Journal Pre-proof 169
References:
170
Chaffer, C.L., Thompson, E.W., Williams, E.D., 2007. Mesenchymal to epithelial transition
171
in development and disease. Cells Tissues Organs (Print) 185, 7–19.
172
Chang, H., Yang, Y., Lee, J.S., Jheon, S.H., Kim, Y.J., Chung, J.H., 2019. Epidermal growth
173
factor receptor gene amplification predicts worse outcome in patients with surgically resected
174
nonadenocarcinoma lung cancer. Clin. Lung Cancer. 20, 7-12
175
Gérard, C., Goldbeter, A., 2014. The balance between cell cycle arrest and cell proliferation:
176
control by the extracellular matrix and by contact inhibition. Interface Focus. 4, 20130075.
177
Gomez, A., Volff, J. N., Hornung, U., Schartl, M., Wellbrock, C., 2004. Identification of a
178
second egfr gene in Xiphophorus uncovers an expansion of the epidermal growth factor
179
receptor family in fish. Mol. Biol. Evol. 21, 266-275.
180
Gordan, J.D., Bertout, J.A., Hu, C.J., Diehl, J.A., Simon, M.C., 2007. HIF-2alpha promotes
181
hypoxic cell proliferation by enhancing c-myc transcriptional activity. Cancer Cell. 11, 335-
182
47.
183
Graham, J. B., 1997. Air-breathing Fishes. Evolution, diversity and adaptation. Academic
184
Press. San Diego, London, Boston, New York, Sydney, Tokyo, Toronto.
185
Gröbe, A., Eichhorn, W., Fraederich, M., Kluwe, L., Vashist, Y., Wikner, J., Smeets, R.,
186
Simon, R., Sauter, G., Heiland, M., Blessmann, M., 2014. Immunohistochemical and FISH
187
analysis of EGFR and its prognostic value in patients with oral squamous cell carcinoma. J
188
Oral Pathol. Med. 43, 205-210.
189
Hirsch, F.R., Scagliotti, G.V., Langer, C.J, Varella-Garcia, M., Franklin, W. A., 2003.
190
Epidermal growth factor family of receptors in preneoplasia and lung cancer: perspectives for
191
targeted therapies. Lung Cancer. 41, S29-S42.
Journal Pre-proof 192
Hugo, H., Ackland, M.L., Blick, T., Lawrence, M.G., Clements, J.A., Williams, E.D.,
193
Thompson, E.W., 2007. Epithelial-mesenchymal and mesenchymal-epithelial transitions in
194
carcinoma progression. J. Cell Physiol. 213 (2), 374-83.
195
Icardo, J. M., 2018. Lungs and gas bladders: Morphological insights. Acta Histochem. 120,
196
605-612.
197
Jonz, M., G., 2018. Insights into the evolution of polymodal chemoreceptors. Acta
198
Histochem. 120, 623-629.
199
Kalluri, R., Weinberg, R.A., 2009. The basics of epithelial-mesenchymal transition. J. Clin.
200
Invest. 119, 1420–1428.
201
Koppenol, WH., Bounds, P.L., Dang, C.V., 2011. Otto Warburg's contributions to current
202
concepts of cancer metabolism. Nat. Rev. Cancer.11, 325-37
203
Laisney, J. A., Braasch, I., Walter, R. B., Meierjohann, S., Schartl, M., 2010. Lineage-specific
204
co-evolution of the Egf receptor/ligand signaling system. BMC Evol. Biol. 27, 10-27.
205
Leknes, I. L., 2015. Goblet cells and mucus types in the digestive intestine and respiratory
206
intestine in bronze Corydoras (Callichthyidae: Teleostei). Anat. Histol. Embriol. 44, 321-327.
207
Masoud, G. N, Li, W., 2015. HIF-1α pathway: role, regulation and intervention for cancer
208
therapy. Acta Pharm. Sin B. 5, 378-89.
209
Miettinen, P.J., Warburton, D., Bu, D., Zhao, J.S., Berger, J.E., Minoo, P., Koivisto, T., Allen,
210
L., Dobbs, L., Werb, Z., Derynck, R., 1997. Imparied lung branching morphogenesis in the
211
absence of functional EGF receptor. Dev. Biol. 186, 224-236.
212
Misra, A., Pandey, C., Sze, S, K., Thanabalu, T., 2012. Hypoxia Activated EGFR Signaling
213
Induces Epithelial to Mesenchymal Transition (EMT). PLoS ONE 7(11): e49766.
214
doi:10.1371/journal.pone.0049766.
Journal Pre-proof 215
Moustakas, A., Heldin, C.H., 2007. Signaling networks guiding epithelial-mesenchymal
216
transitions during embryogenesis and cancer progression. Cancer Sci. 98, 1512-20.
217
Mytych, J., Kozioł, K., Satora, L., 2018. Confirmation of the immunoreactivity of monoclonal
218
anti-human C-terminal EGFR antibodies in bronze Corydoras Corydoras aeneus
219
(Callichthyidae Teleostei) by Western Blot method. Acta Histochem. 120, 151–153.
220
Nelson, J. A., 2014. Breaking wind to survive: fishes that breathe air with their gut. J. Fish
221
Biol. 84, 554-576.
222
Nilsson, G.E., 2007. Gill remodeling in fish-a new fashion or an ancient secret? J. Exp. Biol.
223
210, 2403-2409.
224
Pei, D., Shu, X., Gassama-Diagne, A., Thiery, J.P., 2019. Mesenchymal-epithelial transition
225
in development and reprogramming. Nat. Cell Biol. 21(1):44-53. doi: 10.1038/s41556-018
226
0195-z.
227
Roca, H., Hernandez, J., Weidner, S., McEachin, R.C., Fuller, D., Sud, S., et al., 2013.
228
Transcription factors OVOL1 and OVOL2 induce the mesenchymal to epithelial transition in
229
human cancer. PLoS One. 8, e76773.
230
Satora, L., 1998. Histological and ultrastructural study of the stomach of the air-breathing
231
Ancistrus multispinnis (Siluriformes, Teleostei). Can. J. Zool. 76, 83-86.
232
Satora, L., Kozioł, K., Zebrowski, J., 2017. Squamous epithelium formation in the respiratory
233
intestine of the bronze Corydoras Corydoras aeneus (Callichthyidae Teleostei). Acta
234
Histochem. 119, 563–568.
235
Satora, L., Mytych, J., Bilska-Kos, A., 2018. The presence and expression of the HIF-1 1α in
236
the respiratory intestine of the bronze Corydoras Corydoras aeneus (Callichthyidae
237
Teleostei). Fish Physiol. Biochem. 44, 1291-1297.
Journal Pre-proof 238
Satora, L., Kozioł, K., Waldman, W., Mytych, J., 2019. Differential expression of epidermal
239
growth factor receptor (EGFR) in stomach and diverticulum of Otocinclus affinis
240
(Steindachner, 1877) as a potential element of the epithelium remodeling mechanism. Acta
241
Histochem. 121, 151-155.
242
Schultz, K., Fanburg, B.L., Beasley, D., 2006. Hypoxia and hypoxia-inducible factor-1 α
243
promote growth factor-induced proliferation of human vascular smooth muscle cells. Am J
244
Physiol Heart Circ Physiol. 290, H2528–H2534.
245
Sonnenschein, C., Soto, A, M., 2016. Carcinogenesis explained within the context of a theory
246
of organisms. Prog. Biophys. Mol. Biol. 122, 70e76.
247
Talks, K.L., Turley, H., Gatter, K.C., Maxwell, P.H., Pugh, C.W., Ratcliffe, P.J., et al. 2000.
248
The expression and distribution of the hypoxia-inducible factors HIF-1alpha and HIF-2 alpha
249
in normal human tissues, cancers and tumor-associated macrophages. Am J Pathol. 157, 411-
250
21.
251
Taylor, M, A., Parvani, J, G., Schiemann, W, P., 2010. The pathophysiology of epithelial-
252
mesenchymal transition induced by transforming growth factor-beta in normal and malignant
253
mammary epithelial cells. J. Mammary Gland Biol. Neoplasia, 15, 169-190
254
Tse, A.C, Ge, W., 2009. Differential regulation of betacellulin and heparin-binding EGF-like
255
growth factor in cultured zebrafish ovarian follicle cells by EGF family ligands. Comp.
256
Biochem. Physiol. A Mol. Integr. Physiol. 153,13-17.
257
Tzaneva, V., Bailey, S., Perry, S. F., 2011. The interactive effects of hypoxemia, hyperoxia,
258
and temperature on the gill morphology of goldfish (Carassius auratus). Am. J. Physiol.
259
Regul. Integr. Comp. Physiol. 300, R1344-R1351.
Journal Pre-proof 260
Wang, Y., Ge, W., 2004. Cloning of epidermal growth factor (EGF) and EGF receptor from
261
the zebrafish ovary: evidence for EGF as a potential paracrine factor from the oocyte to
262
regulate activin/follistatin system in the follicle cells. Biol. Reprod. 71, 749-760.
263
Wang, Z., 2017. ErbB Receptors and Cancer. Methods Mol Biol. 1652, 3-35.
264
Zaccone, G., Mauceri, A., Fasulo, S., 2006. Neuropeptides and nitric oxide synthase in the
265
gill and the air-breathing organs of fishes. J. Exp. Zool. 305A, 428–439.
266
Zhong, H., De Marzo, A.M., Laughner, E., Lim, M., Hilton, D.A., Zagzag, D, et al., 1999.
267
Overexpression of hypoxia-inducible factor 1alpha in common human cancers and their
268
metastases. Cancer Res. 59, 5830-5.
Journal Pre-proof Dr Leszek Satora Kraków 15.04.2019 Pomeranian Center of Clinical Toxicology Kartuska 4/6, 80-104 Gdansk, Poland. The Editor Progress in Biophysics & Molecular Biology The manuscript entitled “From epithelial remodeling to carcinogenesis” has not any conflicts of interest.
Sincerely, On behalf of all authors, Leszek Satora
Journal Pre-proof
The renowned biochemist Otto Warburg described how cancer cells avidly consume glucose and produce lactic acid under aerobic conditions (Warburg effect).
Hypoxia, frequently observed in solid tumors, results in an increased HIF1 transcription factor activity. Furthermore, HIF-1is one of the most important effector molecules downstream to EGFR pathways.
The suggested “morphological remodelling” of the epithelium under hypoxia in gut breathing fish (GBF) has a number of common features with carcinogenesis.
The observed similarities in the proliferation of squamous cells in GBF seem to confirm the ‘tissue organization field theory’ proposed by Sonnenschein and Soto.
Gut breathing fish seem to be a very interesting model organism within which the proliferation of squamous cells can be examined in a multithreaded way.
Further investigations of the mechanisms controlling this phenomenon in GBF will result in a better understanding of cancer processes.
Leszek Satora, Jennifer Mytych, Anna Bilska-Kos, Katarzyna Kozioł PII:
S0079-6107(19)30080-X
DOI:
https://doi.org/10.1016/j.pbiomolbio.2019.08.001
Reference:
JPBM 1469
To appear in:
Progress in Biophysics and Molecular Biology
Received Date:
16 April 2019
Accepted Date:
01 August 2019
Please cite this article as: Leszek Satora, Jennifer Mytych, Anna Bilska-Kos, Katarzyna Kozioł, From epithelial remodelling to carcinogenesis, Progress in Biophysics and Molecular Biology (2019), https://doi.org/10.1016/j.pbiomolbio.2019.08.001
This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. © 2019 Published by Elsevier.
Journal Pre-proof 1
From epithelial remodelling to carcinogenesis
2 3
*Leszek
Satoraa, Jennifer Mytychb, Anna Bilska-Kosc and Katarzyna Koziołb
4 5
*aPomeranian
6
bDepartment
7
36-100 Kolbuszowa, Poland.
8
cDepartment
9
Institute - National Research Institute, Radzików, 05-870 Błonie, Poland
Center of Clinical Toxicology Kartuska 4/6, 80-104 Gdansk, Poland.
of Animal Physiology and Reproduction, University of Rzeszów, Werynia 502,
of Plant Biochemistry and Physiology, Plant Breeding and Acclimatization
10 11
*Corresponding
12
Dr Leszek Satora
13
Pomeranian Center of Clinical Toxicology Kartuska 4/6, 80-104 Gdansk, Poland.
14
Tel: +48 682 19 39
15
E-mail: [email protected]
16 17 18 19 20 21
author
Journal Pre-proof 22
Abstract
23
The novel cancer theory named ‘The tissue organization field theory’ (TOFT) suggests that
24
carcinogenesis is a process analogous to embryonic development, whereby organs are formed
25
through interactions among different cell types. The suggested ‘morphological remodelling’
26
of the epithelium under hypoxia in gut breathing fish (GBF) has many common features with
27
carcinogenesis. It appears that research into the relationship among epidermal growth factor
28
receptor (EGFR), hypoxia inducible factor (HIF) as well as hypoxia and normoxia states in
29
GBF fishes can be crucial in learning about the steering mechanisms of squamous epithelium
30
proliferation, leading to a better understanding of carcinogenesis.
31 32
Key Words: Gut breathing fish; EGFR, HIF 1; hypoxia; epithelial remodelling;
33
carcinogenesis; TOFT theory
34 35
The proliferation of the squamous cells in the digestive tract of gut breathing fish (GBF)
36
under hypoxia conditions seems to be an extremely beneficial event. This process allows fish
37
to create a thin air-blood barrier and use the digestive tract as an additional respiratory organ
38
during hypoxic conditions (Satora et al., 2019). Ancistrus chagresi (spinosus) included in the
39
GBF fish group can adjust about 25% of the surface of the stomach to air-breathing (Graham,
40
1997), while in bronze Corydoras about 48% of the digestive tract can be transformed into an
41
additional respiratory organ under water hypoxia conditions (Leknes, 2015). Therefore it may
42
be indicated that the above mentioned adaptations are a type of the‘morphological
43
remodelling’ of epithelial cells.
44
Studies using specific antibodies against the intracellular domain of human epidermal growth
45
factor receptor (EGFR) demonstrated the presence of active, proliferating squamous cells in
Journal Pre-proof 46
the GBF fish digestive tract, in both corydoras (Satora et al., 2017; Mytych et al., 2018) and
47
otocinclus (Satora et al., 2019). High EGFR expression observed in the respiratory part of the
48
intestine in bronze Corydoras and in the stomach of O. affinis suggest higher proliferation
49
activity and angiogenesis of epithelium in that part of the intestine, which creates the
50
conditions for aerial respiration. Furthermore, quantitative analysis of EGFR protein
51
abundance also revealed its higher synthesis in the respiratory stomach of O. affinis (Satora et
52
al., 2019). However, the experimental setup allowing inhibition and /or stimulation of
53
proliferation markers seems to be an important next stage of research on gut breathing fish.
54
Antibodies anti-EGFR (cytoplasmic domain) are used to test active, proliferating epithelial
55
cells in the diagnosis, prognosis and monitoring of the squamous carcinomas (Gröbe et al.,
56
2014). Increased levels of EGFR are linked with malignant transformations of squamous cells
57
(e.g. squamous cell carcinoma in the lungs, esophagus, neck, head). EGFR mediating
58
signalling has been shown to induce mitogenic responses in a variety of cell types. The
59
diagnosis of poor prognosis is based on the studies of EGFR expression in human breast
60
cancer (Gröbe et al., 2014). Most studies on EGFR and its ligands in fish were performed
61
using recombinant mammalian proteins (Wang and Ge, 2004; Tse and Ge, 2009; Mytych et
62
al., 2018). Furthermore, in teleost fish the lineage-specific co-evolution of the EGF
63
receptor/ligand signalling system was demonstrated (Laisney et al., 2010) and the
64
amplification of EGFR gene was also observed (Gomez et al., 2004; Laisney et al., 2010),
65
similarly to carcinogenesis (Chang et al., 2019). It may be speculated that this process is
66
induced by hypoxia.
67
Hypoxia inducible factor-1 (HIF-1) is one of the major components of cellular response to
68
oxygen deprivation. Activated HIF-1 plays a crucial role in adaptive responses of the tumour
69
cells to fluctuations in oxygen concentration through transcriptional activation of over 100
70
downstream genes. HIF-1 regulates important biological processes required for tumour
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survival and progression, including transcription of genes involved in the cell proliferation
72
(Masoud and Li, 2015).
73
The PCR studies and immunolocalization using antibodies specific to HIF-1α followed by
74
visualization under transmission electron microscope (TEM) revealed high expression of HIF-
75
1α and the presence of numerous HIF-1α epitopes in the respiratory part of the bronze
76
Corydoras’ intestine (Satora et al., 2018). In all GBF fish species examined a potential ability
77
for proliferation of squamous cells in various parts of the intestine was observed. It seems that
78
it is carried out according to the same mechanism, being driven by the states of water hypoxia
79
inducing a ‘cascade of events’ which leads to the proliferation of squamous epithelial cells
80
(Satora et al., 2017; Mytych et al., 2018; Satora et al., 2018; Satora et al., 2019).
81
The appearance of tetrapods and land colonization, one of the most important occurrence in
82
vertebrate evolution, were both connected with the high capacity of the air-breathing
83
(Graham, 1997). Although there is no direct physiological evidence described in the
84
paleontological records and we can only study currently existing species, a number of
85
generalizations can be made. For example, adapting the digestive tract to function as an
86
additional respiratory organ under hypoxia states seems to be associated with numerous
87
difficulties in the development of this ability in GBF fishes (Nelson, 2014). The extremely
88
delicate respiratory epithelium; the minimum thickness of the air-blood barrier in GBF fish is
89
about 0.2 m; is highly susceptible to mechanical damage and the action of gastric secretions
90
(Satora, 1998; Nelson, 2014). On the other hand, the ability to proliferate squamous cells and
91
the ‘morphological remodelling’ of the epithelium of the digestive tract in low oxygen
92
conditions seems to be an excellent property. Phylogenetically, the lungs were derived as a
93
unique adaptation to conditions of low oxygen content in the aquatic medium wherein the fish
94
ancestors lived. Despite differences, all of these organisms possessed a characteristic feature:
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the presence of a simple squamous epithelium covering the numerous capillary vessels. This
96
adaptation facilitates gas diffusion (Satora, 1998; Icardo, 2018).
97
Lungs as well as respiratory and non-respiratory bladders of chondrostean appear to originate
98
from a respiratory, posterior pharynx (Icardo, 2018). It can also be assumed that their
99
formation could be related to the proliferation of the squamous cells and the gradual
100
enlargement of the diverticulum in the anterior part of the digestive tract. If the proposed
101
‘morphological remodelling’ process, which involves the proliferation of squamous cells
102
under hypoxia, played an important role in the development of lung and gas bladders, it could
103
have been further consolidated. It is suggested, that in GBF fishes the proliferation process of
104
squamous cells is strictly controlled and is probably inhibited under normoxia. It also seems
105
that putative O2 chemoreceptors, the neuroepithelial cells (NECs) which manifest peculiar
106
neurotransmitter profiles, they can play an important role in this process. However, future
107
experiments are needed to evaluate how NECs and neural pathways are centrally integrated in
108
GBF fishes (Zaccone et al., 2006; Jonz, 2018; Satora et al., 2019). In mammals during lung
109
development, undifferentiated cuboidal cells form lining in distal air spaces and transform
110
into respiratory epithelium (pneumocytes). EGF receptors are of critical importance in this
111
process (Miettinen et al., 1997).
112
About 90 years ago Otto Warburg described how cancer cells avidly consume glucose and
113
produce lactic acid under aerobic conditions (Warburg effect). Hypoxia, frequently observed
114
in solid tumors, results in an increased HIF1 transcription factor activity. Furthermore, HIF-
115
1is one of the most important effector molecules downstream to EGFR pathways (Koppenol
116
et al., 2011). On the other hand, hypoxia and normoxia are opposed conditions adjusting gill
117
remodelling as well as the production or reduction of cellular mass between the lamellae of
118
the gills in several species of teleosts fish (Nilsson, 2007). In this process NECs – putative O2
119
chemoreceptors - are involved (Tzaneva et al., 2001).
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In accordance with the novel theory, cancer is a relational problem. The main attention was
121
focused on the level of biological organization - cancer as a problem of tissue organization
122
similar to histogenesis and organogenesis (Sonnenschein and Soto, 2016). According to
123
Sonnenschein and Soto (2016), carcinogenesis is a process analogous to embryonic
124
development, whereby organs are formed through interactions of different cell types. The
125
basic premise of the tissue organization field theory (TOFT) is that proliferation with
126
variation and motility is the default state of all cells (Sonnenschein and Soto, 2016).
127
On the other hand, epithelial-mesenchymal transition (EMT) and mesenchymal-epithelial
128
transition (MET) processes, take part not only in the physiological conditions but also in the
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carcinogenesis (Taylor et al., 2010; Chaffer et al., 2007; Hugo et al., 2007). Further, it has
130
been demonstrated, that EMT may be induced by hypoxia states and through activation of the
131
EGFR signalling pathway (Misra et al., 2012). In addition, HIFs and EGFR are overexpressed
132
in many types of cancer (Wang 2017; Talks et al., 2000; Zhong et al.,1999) and exhibit, i.a.
133
mitogenic effects (Hirsch et al.,2003; Schultz et al., 2006; Gordan et al., 2007). There is a
134
possibility that enterocytes in the GBF fishes undergo a process of EMT under hypoxia. In
135
this scenario, during EMT process, the cells lose intercellular connection and acquire ability
136
to move, then they transform into mesenchymal cells with increased proliferation ability, and
137
next, they may differentiate into various cell types (including squamous) during MET process
138
(Kalluri and Weinberg, 2009; Pei et al., 2019). The resulting squamous cells are the optimal
139
barrier for gas exchange in the gastrointestinal tract. EMT and/or MET are accompanied by
140
serial events of extracellular matrix deposition, changes in the expression of genes associated
141
with both epithelium or mesenchymal layers, and eventually changes in the morphology
142
(Moustakas and Heldin, 2007). It is crucial to maintain the balance between proliferative and
143
antiproliferative factors and the correct regulation of cellular plasticity through EMT and
144
MET under local cellular environment (Gérard and Goldbeter, 2014; Roca et al., 2013). It is
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suggested that both EGFR and HIF-1α may be essential signals enabling the ‘default state’ of
146
gastrointestinal epithelial cells in GBF fishes, in the response to the change in the oxygen
147
concentrations. Finally, there is the morphological rebuilding of the epithelium, which seems
148
to be consistent with the TOFT theory.
149
The suggested ‘morphological remodelling’ of the epithelium under hypoxia – factor which
150
‘triggers’ cells from the state of equilibriumin gut breathing fish has a number of common
151
features with carcinogenesis. However, it should be emphasized that the mechanisms of
152
dependence of metabolic profiles and cellular phenotypes are still poorly recognized as well
153
as the regulation of the fate of the cells in the cell proliferation processes is only just
154
beginning to be understood. Thus, GBF fishes are not only an evolutionary curiosity that
155
comes as a surprise to many researches (Icardo, 2018), but they also seem to be a very
156
interesting model organism within which the proliferation of squamous cells can be examined
157
in a multithreaded way. Further investigations of the mechanisms controlling this
158
phenomenon in gut breathing fish will result in extending our knowledge about cancer
159
processes.
160 161
Conflict of interest
162
The authors declare no conflict of interest.
163
Author contributions
164
L.S. conceived and designed the research project and wrote the manuscript. J.M., A.B-K and
165
K.K. interpreted the results and helped writing the manuscript.
166 167 168
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References:
170
Chaffer, C.L., Thompson, E.W., Williams, E.D., 2007. Mesenchymal to epithelial transition
171
in development and disease. Cells Tissues Organs (Print) 185, 7–19.
172
Chang, H., Yang, Y., Lee, J.S., Jheon, S.H., Kim, Y.J., Chung, J.H., 2019. Epidermal growth
173
factor receptor gene amplification predicts worse outcome in patients with surgically resected
174
nonadenocarcinoma lung cancer. Clin. Lung Cancer. 20, 7-12
175
Gérard, C., Goldbeter, A., 2014. The balance between cell cycle arrest and cell proliferation:
176
control by the extracellular matrix and by contact inhibition. Interface Focus. 4, 20130075.
177
Gomez, A., Volff, J. N., Hornung, U., Schartl, M., Wellbrock, C., 2004. Identification of a
178
second egfr gene in Xiphophorus uncovers an expansion of the epidermal growth factor
179
receptor family in fish. Mol. Biol. Evol. 21, 266-275.
180
Gordan, J.D., Bertout, J.A., Hu, C.J., Diehl, J.A., Simon, M.C., 2007. HIF-2alpha promotes
181
hypoxic cell proliferation by enhancing c-myc transcriptional activity. Cancer Cell. 11, 335-
182
47.
183
Graham, J. B., 1997. Air-breathing Fishes. Evolution, diversity and adaptation. Academic
184
Press. San Diego, London, Boston, New York, Sydney, Tokyo, Toronto.
185
Gröbe, A., Eichhorn, W., Fraederich, M., Kluwe, L., Vashist, Y., Wikner, J., Smeets, R.,
186
Simon, R., Sauter, G., Heiland, M., Blessmann, M., 2014. Immunohistochemical and FISH
187
analysis of EGFR and its prognostic value in patients with oral squamous cell carcinoma. J
188
Oral Pathol. Med. 43, 205-210.
189
Hirsch, F.R., Scagliotti, G.V., Langer, C.J, Varella-Garcia, M., Franklin, W. A., 2003.
190
Epidermal growth factor family of receptors in preneoplasia and lung cancer: perspectives for
191
targeted therapies. Lung Cancer. 41, S29-S42.
Journal Pre-proof 192
Hugo, H., Ackland, M.L., Blick, T., Lawrence, M.G., Clements, J.A., Williams, E.D.,
193
Thompson, E.W., 2007. Epithelial-mesenchymal and mesenchymal-epithelial transitions in
194
carcinoma progression. J. Cell Physiol. 213 (2), 374-83.
195
Icardo, J. M., 2018. Lungs and gas bladders: Morphological insights. Acta Histochem. 120,
196
605-612.
197
Jonz, M., G., 2018. Insights into the evolution of polymodal chemoreceptors. Acta
198
Histochem. 120, 623-629.
199
Kalluri, R., Weinberg, R.A., 2009. The basics of epithelial-mesenchymal transition. J. Clin.
200
Invest. 119, 1420–1428.
201
Koppenol, WH., Bounds, P.L., Dang, C.V., 2011. Otto Warburg's contributions to current
202
concepts of cancer metabolism. Nat. Rev. Cancer.11, 325-37
203
Laisney, J. A., Braasch, I., Walter, R. B., Meierjohann, S., Schartl, M., 2010. Lineage-specific
204
co-evolution of the Egf receptor/ligand signaling system. BMC Evol. Biol. 27, 10-27.
205
Leknes, I. L., 2015. Goblet cells and mucus types in the digestive intestine and respiratory
206
intestine in bronze Corydoras (Callichthyidae: Teleostei). Anat. Histol. Embriol. 44, 321-327.
207
Masoud, G. N, Li, W., 2015. HIF-1α pathway: role, regulation and intervention for cancer
208
therapy. Acta Pharm. Sin B. 5, 378-89.
209
Miettinen, P.J., Warburton, D., Bu, D., Zhao, J.S., Berger, J.E., Minoo, P., Koivisto, T., Allen,
210
L., Dobbs, L., Werb, Z., Derynck, R., 1997. Imparied lung branching morphogenesis in the
211
absence of functional EGF receptor. Dev. Biol. 186, 224-236.
212
Misra, A., Pandey, C., Sze, S, K., Thanabalu, T., 2012. Hypoxia Activated EGFR Signaling
213
Induces Epithelial to Mesenchymal Transition (EMT). PLoS ONE 7(11): e49766.
214
doi:10.1371/journal.pone.0049766.
Journal Pre-proof 215
Moustakas, A., Heldin, C.H., 2007. Signaling networks guiding epithelial-mesenchymal
216
transitions during embryogenesis and cancer progression. Cancer Sci. 98, 1512-20.
217
Mytych, J., Kozioł, K., Satora, L., 2018. Confirmation of the immunoreactivity of monoclonal
218
anti-human C-terminal EGFR antibodies in bronze Corydoras Corydoras aeneus
219
(Callichthyidae Teleostei) by Western Blot method. Acta Histochem. 120, 151–153.
220
Nelson, J. A., 2014. Breaking wind to survive: fishes that breathe air with their gut. J. Fish
221
Biol. 84, 554-576.
222
Nilsson, G.E., 2007. Gill remodeling in fish-a new fashion or an ancient secret? J. Exp. Biol.
223
210, 2403-2409.
224
Pei, D., Shu, X., Gassama-Diagne, A., Thiery, J.P., 2019. Mesenchymal-epithelial transition
225
in development and reprogramming. Nat. Cell Biol. 21(1):44-53. doi: 10.1038/s41556-018
226
0195-z.
227
Roca, H., Hernandez, J., Weidner, S., McEachin, R.C., Fuller, D., Sud, S., et al., 2013.
228
Transcription factors OVOL1 and OVOL2 induce the mesenchymal to epithelial transition in
229
human cancer. PLoS One. 8, e76773.
230
Satora, L., 1998. Histological and ultrastructural study of the stomach of the air-breathing
231
Ancistrus multispinnis (Siluriformes, Teleostei). Can. J. Zool. 76, 83-86.
232
Satora, L., Kozioł, K., Zebrowski, J., 2017. Squamous epithelium formation in the respiratory
233
intestine of the bronze Corydoras Corydoras aeneus (Callichthyidae Teleostei). Acta
234
Histochem. 119, 563–568.
235
Satora, L., Mytych, J., Bilska-Kos, A., 2018. The presence and expression of the HIF-1 1α in
236
the respiratory intestine of the bronze Corydoras Corydoras aeneus (Callichthyidae
237
Teleostei). Fish Physiol. Biochem. 44, 1291-1297.
Journal Pre-proof 238
Satora, L., Kozioł, K., Waldman, W., Mytych, J., 2019. Differential expression of epidermal
239
growth factor receptor (EGFR) in stomach and diverticulum of Otocinclus affinis
240
(Steindachner, 1877) as a potential element of the epithelium remodeling mechanism. Acta
241
Histochem. 121, 151-155.
242
Schultz, K., Fanburg, B.L., Beasley, D., 2006. Hypoxia and hypoxia-inducible factor-1 α
243
promote growth factor-induced proliferation of human vascular smooth muscle cells. Am J
244
Physiol Heart Circ Physiol. 290, H2528–H2534.
245
Sonnenschein, C., Soto, A, M., 2016. Carcinogenesis explained within the context of a theory
246
of organisms. Prog. Biophys. Mol. Biol. 122, 70e76.
247
Talks, K.L., Turley, H., Gatter, K.C., Maxwell, P.H., Pugh, C.W., Ratcliffe, P.J., et al. 2000.
248
The expression and distribution of the hypoxia-inducible factors HIF-1alpha and HIF-2 alpha
249
in normal human tissues, cancers and tumor-associated macrophages. Am J Pathol. 157, 411-
250
21.
251
Taylor, M, A., Parvani, J, G., Schiemann, W, P., 2010. The pathophysiology of epithelial-
252
mesenchymal transition induced by transforming growth factor-beta in normal and malignant
253
mammary epithelial cells. J. Mammary Gland Biol. Neoplasia, 15, 169-190
254
Tse, A.C, Ge, W., 2009. Differential regulation of betacellulin and heparin-binding EGF-like
255
growth factor in cultured zebrafish ovarian follicle cells by EGF family ligands. Comp.
256
Biochem. Physiol. A Mol. Integr. Physiol. 153,13-17.
257
Tzaneva, V., Bailey, S., Perry, S. F., 2011. The interactive effects of hypoxemia, hyperoxia,
258
and temperature on the gill morphology of goldfish (Carassius auratus). Am. J. Physiol.
259
Regul. Integr. Comp. Physiol. 300, R1344-R1351.
Journal Pre-proof 260
Wang, Y., Ge, W., 2004. Cloning of epidermal growth factor (EGF) and EGF receptor from
261
the zebrafish ovary: evidence for EGF as a potential paracrine factor from the oocyte to
262
regulate activin/follistatin system in the follicle cells. Biol. Reprod. 71, 749-760.
263
Wang, Z., 2017. ErbB Receptors and Cancer. Methods Mol Biol. 1652, 3-35.
264
Zaccone, G., Mauceri, A., Fasulo, S., 2006. Neuropeptides and nitric oxide synthase in the
265
gill and the air-breathing organs of fishes. J. Exp. Zool. 305A, 428–439.
266
Zhong, H., De Marzo, A.M., Laughner, E., Lim, M., Hilton, D.A., Zagzag, D, et al., 1999.
267
Overexpression of hypoxia-inducible factor 1alpha in common human cancers and their
268
metastases. Cancer Res. 59, 5830-5.
Journal Pre-proof Dr Leszek Satora Kraków 15.04.2019 Pomeranian Center of Clinical Toxicology Kartuska 4/6, 80-104 Gdansk, Poland. The Editor Progress in Biophysics & Molecular Biology The manuscript entitled “From epithelial remodeling to carcinogenesis” has not any conflicts of interest.
Sincerely, On behalf of all authors, Leszek Satora
Journal Pre-proof
The renowned biochemist Otto Warburg described how cancer cells avidly consume glucose and produce lactic acid under aerobic conditions (Warburg effect).
Hypoxia, frequently observed in solid tumors, results in an increased HIF1 transcription factor activity. Furthermore, HIF-1is one of the most important effector molecules downstream to EGFR pathways.
The suggested “morphological remodelling” of the epithelium under hypoxia in gut breathing fish (GBF) has a number of common features with carcinogenesis.
The observed similarities in the proliferation of squamous cells in GBF seem to confirm the ‘tissue organization field theory’ proposed by Sonnenschein and Soto.
Gut breathing fish seem to be a very interesting model organism within which the proliferation of squamous cells can be examined in a multithreaded way.
Further investigations of the mechanisms controlling this phenomenon in GBF will result in a better understanding of cancer processes.