21Drug TargeT InsIghTs 2015:9

Basal Plasma Levels of Copeptin are Elevated in Inactive 
Inflammatory Bowel Disease after Bowel Resection

Bodil Ohlsson and Olle Melander
Department of Clinical Sciences, Section of Internal Medicine, Skåne University Hospital, Malmö, and Lund University, Lund, Sweden.

A BSTR ACT: Evidence of interactions between the enteric nervous system, neuropeptides, and the immune system is growing. The aim of this study was 
to examine basal plasma levels of a variety of peptide precursors in patients with inflammatory bowel disease (IBD). In two middle-aged cohorts, Malmö 
Preventive Medicine (n = 5,415) and Malmö Diet and Cost Study (n = 6,103), individuals with the diagnosis of IBD were identified. Medical records 
were scrutinized. Three controls were matched for each patient. Copeptin, midregional fragments of adrenomedullin, pro-atrial natriuretic peptide, and 
proenkephalin A, as well as N-terminal protachykinin A and proneurotensin were analyzed in the plasma. Sixty-two IBD patients were identified. The 
only difference between patients and controls was higher copeptin levels in the patients compared with controls (P = 0.006), with higher copeptin levels in 
resected than unresected patients (P = 0.020). There was no difference in any precursor levels between Crohn’s disease and ulcerative colitis, between differ-
ent distributions of disease lesions, or between different treatments.

K E Y WOR DS: copeptin, inflammatory bowel disease, irritable bowel syndrome-like symptoms, neuropeptides, precursors

CITATION: Ohlsson and Melander. Basal Plasma Levels of Copeptin are elevated  
in Inactive Inflammatory Bowel Disease after Bowel Resection. Drug Target Insights 
2015:9 21–27 doi:10.4137/DTI.s26589.

RECEIVED: March 24, 2015. RESUBMITTED: June 1, 2015. ACCEPTED FOR 
PUBLICATION: June 3, 2015.

ACADEMIC EDITOR: anuj Chauhan, editor in Chief

TYPE: Original research

FUNDING: This work was supported by the Bengt Ihre Foundation, Dir. Albert Påhlsson 
Foundation, Foundation of Skåne University Hospital, and the Development Foundation 
of Region Skåne. The authors confirm that the funder had no influence over the study 
design, content of the article, or selection of this journal.

COMPETING INTERESTS: Authors disclose no potential conflicts of interest.

COPYRIGHT: © the authors, publisher and licensee Libertas Academica Limited. 
This is an open-access article distributed under the terms of the Creative Commons 
CC-BY-nC 3.0 License.

CORRESPONDENCE: bodil.ohlsson@med.lu.se

Paper subject to independent expert blind peer review by minimum of two reviewers. 
All editorial decisions made by independent academic editor. Upon submission 
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compliance with ethical requirements relating to human and animal study participants, 
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member of the Committee on Publication Ethics (COPE).

Published by Libertas Academica. Learn more about this journal.

Introduction
Interactions between the enteric nervous system (ENS) and 
the immune system have been the subject of much new evi-
dence in recent years. Inflammatory cells in the intestine 
express receptors for neuropeptides, and the enteric neurons 
are responsive to cytokines secreted from inflammatory cells.1,2 
Nevertheless, the focus in inflammatory bowel disease (IBD) 
has been the immune system, and few studies have exam-
ined the role of neuropeptides in the development and main-
tenance of the disease, especially in inactive disease. Even 
when the disease is under control and no signs of inflamma-
tion are present, patients with IBD often suffer from abdomi-
nal pain and functional abdominal complaints, so-called 
irritable bowel syndrome (IBS)-like symptoms.3 The reason 
for these complaints is unknown, but hypersensitivity, low-
grade inflammation, or impaired epithelial barrier has been 
suggested.3 Imbalance in neurotransmitters/neuropeptides 
has only been sparsely examined in relation to hypersensitiv-
ity and IBS-like symptoms. Structural changes occur in the 
ENS during IBD,4 and the precursor mRNAs encoding sub-
stance P and related receptors have been found to be upregu-
lated in Crohn’s disease.5,6 Recently, lower plasma levels of 
enkephalins were described in active IBD patients compared 
with controls.7

Adrenomedullin, enkephalin A, neurotensin, and sub-
stance P, as well as their receptors, have been demonstrated 
in the gastrointestinal tract2,8–11 and found to be involved in 

inflammation and nociception.10–14 Adrenomedullin has been 
shown to ameliorate the induction of colitis in animal models 
and to induce wound healing.10 Enkephalins exert both anti-
inflammatory and anti-nociceptive effects in induced colitis in 
animal models.13 Endogenous neurotensin facilitates visceral 
pain responses and is necessary for the development of irritant-
induced hyperalgesia.12 Substance P is involved in the regulation 
of mast cell activation,14 and the upregulation of substance P  
observed in the gastrointestinal tract in IBD patients seems to 
be associated with ongoing local inflammation, which can be 
clinically quiet.11 Copeptin, the precursor of arginine vasopres-
sin (AVP), is secreted from the posterior pituitary gland, and 
all three vasopressin receptors have been found in the gastro-
intestinal tract.15 The main roles of vasopressin are water reab-
sorption through V2 receptors,16 regulation of vascular tone 
by V1a receptor activation,17 and physiological adaptations to 
stress through adrenocorticotropic hormone (ACTH) release 
by the posterior pituitary involving V1b receptors.18 A few 
studies have examined the pharmacological, but not the physi-
ological, effect of vasopressin on water and sodium absorption 
and secretion in human intestines.19,20 In rodents, vasopressin 
has been reported to exert proinflammatory effects through 
mast cell activation and enhanced epithelial permeability in the 
colon.21 Atrial natriuretic peptide (ANP) is secreted from the 
heart and contributes to substantial fluid loss via the gastroin-
testinal tract.22 Peptides have a short half-time in plasma, so it 
is advantageous to measure the highly stable precursors instead 

Journal name: Drug Target Insights

Journal type: Original Research

Year: 2015

Volume: 9

Running head verso: Ohlsson and Melander

Running head recto: Basal plasma levels of copeptin in IBD

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Ohlsson and Melander

22 Drug TargeT InsIghTs 2015:9

of peptides, which are synthesized in stoichiometric amounts 
relative to the mature peptides.23,24

The aim of the present pilot study was to analyze the basal 
plasma levels of a variety of peptide precursors involved in the 
physiology of the gastrointestinal tract, ie, copeptin, midregional 
fragment of pro-adrenomedullin (MR-proADM), midregional 
fragment of pro-atrial natriuretic peptide (MR-proANP), 
midregional fragment of proenkephalin A (MR-PENK A), 
N-terminal protachykinin A (NT-PTA), and proneurotensin, 
in two well-defined populations of patients with IBD, as these 
precursors have been discussed in the development and activity 
of gastrointestinal diseases.

Material and Methods
The research protocol was in accordance with the Declaration 
of Helsinki, and the study was approved by the Ethics Com-
mittee of Lund University (2013/609).

Study population. The Malmö Preventive Medicine 
(MPM) study is a population-based, prospective, epidemio-
logic cohort of 22,444 men (born between 1921 and 1949) and 
10,902 women (born between 1926 and 1949) from Malmö, 
Sweden, who underwent baseline examinations between 1974 
and 1992.25 From this cohort, 18,240 were re-examined from 
2002 to 2006, and new blood samples were collected. Out of 
these, 5,415 were randomly chosen for precursor analyses.

The Malmö Diet and Cancer Study (MDCS) is a  
population-based, prospective, epidemiologic cohort of 28,449  
men (born between 1923 and 1945) and women (born between 
1923 and 1950) from Malmö, Sweden, who underwent base-
line examinations between 1991 and 1996. From this cohort, 
6,103 individuals were randomly selected to participate in 
the MDCS cardiovascular cohort (MDC-CC), which was 
designed to investigate the epidemiology of carotid artery 
disease between 1991 and 1994.26 The baseline examination 
procedure has been described in detail previously.27

Briefly, the MPM and MDC-CC baseline examinations 
included a dietary assessment; a self-administered question-
naire about marital status, education, employment, smoking 
habits, wine consumption, physical activity, medical conditions 
and medication; anthropometric measurements; and collection 
of blood samples.

At baseline, no questions concerning bowel diseases 
were asked. Thus, we used local registers to retrieve prevalent 
cases of IBD according to the International Classification of 
Diseases (ICD) version 8, 9, and 10. We initially identified 
35  patients with IBD in the MPM re-examination cohort 
with available precursors analyses, and 70 patients with IBD in  
the MDC-CC cohort. The diagnoses were validated by scru-
tinizing all the medical records, and all patients with a clini-
cal diagnosis made after careful clinical examination including 
endoscopy and histopathological examination were included in 
the study. From the medical records, the activity and extent of 
disease, concomitant diseases, drug treatment, and bowel resec-
tions were recognized. Disease involvement in more than one 

gastrointestinal segment was defined as extensive disease. Six 
patients in the MPM cohort and nine patients in the MDC-
CC were excluded due to wrong diagnosis, the coexistence of 
cardiovascular disease, diabetes mellitus, or malignancy, or the 
medical records not being found in the archive and hence vali-
dation according to prevalent or incident IBD, disease activity, 
and concomitant diseases could not be performed. Thus, after 
validation of the information from the register using the medi-
cal records, 22 prevalent and 7 incident cases of IBD remained 
in the MPM cohort and 40 prevalent and 21 incident cases in 
the MDC-CC, at the time point when plasma samples were 
collected.

Analyses. At the MPM reexamination and at the MDC-
CC baseline examination, blood was collected in the morning 
after 12 hours of fasting, and plasma was separated and imme-
diately frozen at −80°C. In the MDC-CC, plasma samples 
were available for analyses of MR-PENK, NT-PTA, and pro-
neurotensin in 4,632 participants, and for analyses of copeptin, 
MR-proADM, and MR-proANP in 4,742 participants. The 
excluded participants (due to lack of plasma samples) were 
slightly younger, but did not otherwise differ in terms of sex, 
smoking habits, diabetes, hypertension status, body mass index 
(BMI), or plasma lipids.27,28

Copeptin, the stable precursor peptide of AVP, was mea-
sured by a murine monoclonal antibody directed to amino 
acids 137–144 of proAVP using a commercially available assay 
in the chemiluminescence/coated tube format (LUMItest 
CT-proAVP, Brahms GmbH) as described previously.29

MR-proADM and MR-proANP were analyzed using 
sandwich immunoluminometric assays targeted against amino 
acids in the mid-regions of the respective peptide (Brahms Sevadil 
LIA® and Brahms Seristra®, respectively, Brahms GmbH).30,31 
Briefly, two polyclonal antibodies targeted to amino acids 45–92 
of proADM was used for the measurement of MR-proADM,30 
and polyclonal sheep antibodies specific for amino acids 73–90 
were used for the measurement of MR-proANP.31

MR-PENK A is the stable fragment of the peptide pre-
cursor of enkephalins, and NT-PTA is the stable fragment of 
the peptide precursor of substance P. MR-PENK A was mea-
sured by a sensitive chemiluminescence immunoassay against 
amino acids 119−159 of the MR-PENK A precursor fragment 
(Brahms GmbH).23 A similar sensitive chemiluminescence 
immunoassay was developed to detect amino acids 1−37 of 
NT-PTA (Brahms GmbH).32

Proneurotensin was measured by a recent developed che-
miluminometric sandwich immunoassay to detect a proneu-
rotensin precursor fragment (pro NT/NMN 1–117) (Brahms 
GmbH).33

Statistical analyses. Patients with valid, prevalent 
IBD in the MPM (n = 22) and MDC-CC (n = 40) cohorts 
were matched with three controls from their own cohort. 
Those subjects with prevalent cardiovascular disease, diabe-
tes mellitus, or malignancy prior to the blood sampling were 
excluded from both patients and controls, as these diseases 

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Basal plasma levels of copeptin in IBD 

23Drug TargeT InsIghTs 2015:9

may interact with plasma precursor levels.28 Matching was 
performed considering age at baseline, date of inclusion, sex, 
smoking habits, and BMI.

Plasma analyses were not available in some of the sub-
jects in the MDC-CC, so analyses were measured in 28 or 
34 prevalent patients with IBD and in 106 or 115 controls, 
respectively. As plasma analyses were not available in several 
of the few incidental cases, these were omitted from statistical 
calculations.

All calculations were performed with the SPSS version 
22 (Statistical Package for the Social Sciences, IBM Corpo-
ration). Calculations were performed separately for the two 
cohorts compared with controls. Furthermore, the two cohorts 
were added in an attempt to reach a greater cohort. As age 
differed between MPM and MDC-CC, and several peptide 
analyses correlated with age, the values were age-standardized 
using a linear regression model into which age was added 
as a covariate and the variables were expressed as z-scores. 
Those precursors that did not differ between the MPM and 
MDC-CC cohorts were copeptin (P = 0.623), MR-proADM  
(P = 0.058), and MR-proANP (P = 0.500), which were thus 
calculated together. Values are given as median [interquartile 
range (IQR)] or mean ± standard deviation (SD). The Mann–
Whitney U-test was used to compare the differences in pre-
cursor levels between patients and controls and for subgroup 
analyses within the IBD group. Fisher’s exact test was used for 
dichotomous variables. The Spearman rank correlation test was 
used for correlations between precursor and disease duration. 
P  0.05 was considered statistically significant.

Results
Patient characteristics.
MPM. The basal characteristics are described in Table 1.  

The 22 included patients were in an inactive phase during their 

enrollment in the study. Disease duration was 25.4 ± 13.4 years. 
None of the patients was receiving acute therapy, but six 
(27%) were on continuous treatment with anti-inflammatory 
or immune-modulating therapy. Twelve patients (54%) had 
undergone intestinal resections due to IBD, and 10 of the 
patients (46%) had extensive disease. Apart from IBD, six 
patients also suffered from hypertension and four from neph-
rolithiasis. Sporadic cases of asthma bronchialis, bile stones, 
chronic obstructive pulmonary disease (COPD), dyspepsia, 
hyperlipidemia, hypothyroidism, migraine, primary Sjögren’s 
syndrome, reflux, and renal insufficiency were found.

MDC-CC. All 40 included patients with prevalent IBD 
were in an inactive state during enrollment in the study. 
Disease duration was 13.1 ± 10.0  years (Table 1). None was 
undergoing acute therapy, and only three patients (8%) were 
on continuous treatment with anti-inflammatory or immune-
modulating therapy. Thirteen patients (32%) had undergone 
intestinal resections due to IBD, whereas 18 patients (45%) 
had an extensive distribution of the disease. Sporadic concom-
itant diseases were present in the form of asthma bronchialis, 
COPD, duodenal ulceration, dyspepsia, hiatal hernia, hyper-
tension, hypothyroidism, inguinal hernia, ankylosing spondy-
litis, and venous thrombosis.

Precursor analyses. When precursor analyses were done 
together, the higher plasma level of copeptin was the only sig-
nificant difference in plasma measurements between patients 
and controls (Table 2). Patients who had undergone bowel 
resection had higher plasma levels of copeptin compared with 
unresected patients [10.25 (7.94–13.75) and 6.33 (4.92–9.52) 
pmol/L, respectively, P = 0.020]. When the patients with a 
history of bowel resection were excluded (n = 23) together with 
their matched controls, there was no difference in copeptin 
levels between patients and controls [6.33 (4.92–9.52) and 5.81 
(3.52–9.64) pmol/L, respectively, P = 0.501]. There was no dif-

Table 1. Patient characteristics of the two cohorts.

PREVALENT IBD MPM
n = 22

PREVALENT IBD MDC-CC
n = 40

P-VALUE

Age (years) 69.7 ± 7.2 56.0 ± 6.5 0.0001

Sex (male/female) 12/10 19/21 0.791

Smoking (n, %) 0.182

Missing values (n) 2

Smokers 11 (50) 12 (30)

Nonsmokers 11 (50) 26 (65)

BMI (kg/m2) 23.8 ± 3.8 24.8 ± 3.5 0.237

Duration of IBD (years) 25.4 ± 13.4 13.1 ± 10.0 0.0001

Missing values (n) 2

Crohn’s disease/ulcerative colitis 8/14 19/21 0.435

Notes: n (%) = number and percentage of cases. Values are given as mean ± standard deviation (SD). Mann–Whitney U-test or Fisher’s exact test. P  0.05 was 
considered statistically significant.
Abbreviations: BMI, body mass index; IBD, inflammatory bowel syndrome; MDC-CC, Malmö Diet and Cancer Study cardiovascular cohort; MPM, Malmö 
Preventive Medicine.

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Ohlsson and Melander

24 Drug TargeT InsIghTs 2015:9

ference in copeptin levels whether or not the patients suffered 
from Crohn’s disease or ulcerative colitis [7.19 (4.15–11.34)  
and 8.13 (5.03–11.68) pmol/L, respectively, P = 0.461], 
whether they were treated with anti-inflammatory drugs or 
not [4.69 (3.06–11.77) and 8.09 (5.60–11.43) pmol/L, respec-
tively, P = 0.254], or whether they had a limited or extensive 
disease [8.03 (5.53–12.60) and 8.13 (5.24–11.05) pmol/L, 
respectively, P = 0.493].

Since age and disease duration were strongly correlated  
(rs = 0.374, P = 0.003), the correlation between disease dura-
tion and plasma levels of MR-proADM (rs = 0.380, P = 0.005),  
NT-PTA (rs = 0.483, P = 0.001), and MR-PENK A (rs = 0.302,  
P = 0.037) was reflected by concomitant correlation with age 
(rs = 0.668, P  0.0001; rs = 0.483, P  0.0001; and rs = 0.315, 
P = 0.026, respectively).

The expression of Crohn’s disease or ulcerative colitis, 
treatment with anti-inflammatory drugs or not, limited or 
extensive disease, or a past bowel resection did not affect the 
plasma levels of any of the other precursors (data not shown).

When calculated separately, there was a difference between 
MPM and controls regarding plasma levels of copeptin and 
MR-proADM but not regarding those of the other precursors 
(Table 3). The level of copeptin was higher in patients who had 
undergone a bowel resection (n = 12) compared with the non-
resected (n = 6, missing value = 4), although it did not reach 
statistical significance in the small cohort [11.46 (8.33–19.08) 
and 7.42 (5.68–14.44), respectively, P = 0.291]. Neither was 
there any difference in plasma copeptin levels depending on 
Crohn’s disease or ulcerative colitis [7.92 (5.68–11.01) and 

10.41 (5.92–16.68), respectively, P = 0.365], were treated with 
anti-inflammatory drugs or not [9.71 (3.90–12.81) and 8.66 
[6.09–18.16] pmol/L, respectively, P = 0.693) or a limited or 
extensive disease [11.75 (7.08–17.86) and 9.01 (5.90–13.82), 
respectively, P = 0.604]. Regarding MR-proADM, there was 
no difference in plasma levels depending on bowel resection 
or not [0.83 (0.65–1.22) and 0.84 (0.73–1.05), respectively,  
P = 0.892], Crohn’s disease or ulcerative colitis [0.75 (0.69–0.87)  
and 0.86 (0.66–1.11), respectively, P = 0525], were treated 
with anti-inflammatory drugs or not [0.84 (0.67–1.11) and 
0.79 (0.68–1.01) pmol/L, respectively, P = 0.858], or a limited 
or extensive disease [0.89 (0.75–1.37) and 0.77 (0.64–1.04),  
respectively, P = 0.182].

In the MDC-CC cohort, no differences were seen 
between controls and patients in any plasma precursor analy-
ses (Table 4). Neither were any differences in plasma levels 
of any of the precursors between the expression of Crohn’s 
disease or ulcerative colitis, treatment with anti-inflammatory 
drugs or not, limited or extensive disease, or a past bowel 
resection (data not shown).

Discussion
The main conclusion of this study is that basal plasma copeptin 
levels are elevated after complete bowel resection, but other 
peptide precursors are unaffected in middle-aged subjects in 
inactive IBD compared with matched controls. However, the 
elevated copeptin levels did not reach statistical significance 
when precursor levels were calculated separately in the MDC-
CC cohort, or when the MPM cohort was separated into 

Table 2. Plasma peptide levels from all patients with inflammatory bowel disease and controls.

IBD (n = 62) CONTROLS (n = 186) P-VALUE

Copeptin (pmol/L) 8.0 (4.8–11.5) (56) 5.8 (3.4–8.5) (181) 0.006

MR-proADM (nmol/L) 0.6 (0.4–0.8) (56) 0.5 (0.4–0.7) (182) 0.127

MR-proANP (pmol/L) 78.0 (59.2–111.8) (56) 72.7 (54.1–101.3) (182) 0.367

Notes: n = number of analyses. Values are given as median [interquartile range (IQR)]. Mann–Whitney U-test. P  0.05 was considered statistically significant.
Abbreviations: IBD, inflammatory bowel disease; MR-proADM, midregional fragment of pro-adrenomedullin; MR-proANP, midregional fragment of pro-atrial 
natriuretic peptide.

Table 3. Plasma peptide levels from patients in Malmö Preventive Medicine (MPM) compared with controls.

MPM (n = 22) CONTROLS (n = 66) P-VALUE

Copeptin (pmol/L) 8.66 (5.90–12.81) 6.23 (3.79–9.19) 0.007

MR-proADM (nmol/L) 0.80 (0.68–1.04) 0.70 (0.57–0.84) 0.010

MR-proANP (pmol/L) 104.27 (77.10–149.13) 98.73 (68.14–145.69) 0.649

MR-PENK (pmol/L) 59.48 (54.41–74.41) 60.89 (50.39–74.63) 0.785

NT-PTA (pmol/L) 78.98 (64.11–98.66) 80.64 (67.12–97.40) 0.852

Proneurotensin (pmol/L) 79.15 (63.15–130.45) 84.45 (62.18–119.65) 0.972

Notes: n = number of analyses. Values are given as median [interquartile range (IQR)]. Mann–Whitney U-test. P  0.05 was considered statistically significant.
Abbreviations: IBD, inflammatory bowel disease; MR-proADM, midregional fragment of pro-adrenomedullin; MR-proANP, midregional fragment of pro-atrial 
natriuretic peptide; MR-PENK, midregional fragment of proenkephalin A; NT-PTA, N-terminal polytachykinin A.

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25Drug TargeT InsIghTs 2015:9

resected and unresected groups. The elevated plasma level 
of MR-proADM observed in the MPM cohort was diluted 
when the two cohorts were calculated together.

The etiology of IBD is unknown, but a complex interplay 
of genetic, microbial, immunologic, and environmental fac-
tors are discussed. The inflammation in IBD is mainly situated 
in the mucosa, but transmural inflammation has been docu-
mented in both Crohn’s disease and ulcerative colitis.4 The 
majority of the neuropeptides are found both in the central 
nervous system (CNS) and in the ENS, and we do not know 
whether the plasma peptides are of gastrointestinal or cephalic 
origin. Gastrointestinal peptides may be secreted from both 
enterochromaffin mucosal cells and enteric neurons.9,11,34 Fur-
thermore, IBD affects the brain–gut axis with possible subse-
quent effects on peptide release from the brain.35 The modest 
effect on plasma levels of precursors in the present study sug-
gests that, despite the chronic nature of IBD, the disease does 
not have a major impact on peptide secretion. Nevertheless, as 
a wide range of neuropeptides and inflammatory factors are 
involved in physiological and pathophysiological processes, 
the balance between peptides, rather than the actual concen-
tration of one specific peptide, may be important.

The levels of copeptin and vasopressin in plasma are cor-
related with each other in both healthy volunteers and sick 
patients.24 Vasopressin has been shown to increase epithelial 
permeability,21 but its effect on water reabsorption in the gas-
trointestinal tract has only been studied in pharmacological 
doses of vasopressin, and the results are not conclusive.19,20 As 
patients with IBD and a history of bowel resection had higher 
plasma levels of copeptin, the question remains whether the 
altered precursor levels measured in plasma are a primary 
etiological factor or a secondary effect of the disease.7,36 The 
difference could hypothetically be explained by a compensa-
tory mechanism due to a shorter bowel, with ensuing reduced 
amount of vasopressin receptors and/or reduced water reab-
sorption capacity of the bowel.15,24

Elevated plasma levels of vasopressin have been found 
in diseases characterized by chronic inflammation.37 In mice, 
injections of vasopressin into the periaqueductal gray raised the 
plasma levels of all enkephalins,38 and stimulation of peripheral 

vasopressin receptors had proinflammatory effects in experi-
mental colitis, whereas inhibition of the receptors abolished 
the vasopressin effect.21 The effect of vasopressin on encephalin 
secretion has not been studied in humans. Proenkephalin is the 
precursor of Met-enkephalin and Leu-enkephalin, and in con-
trast to the findings in our study with unaffected MR-PENK A, 
plasma levels of Met-enkephalin have previously been shown 
to be lowered in IBD patients.7,36 The study by Owczarek et al7 
was performed in younger patients with active disease, which 
could exhaust the peptides in the blood circulation and explain 
the different results. The actual encephalin concentration in 
the gastrointestinal tissue is not measured, but agonists to the 
peripheral opioid receptors lead to anti-inflammatory and 
anti-nociceptive effects.13 These studies suggest a role of the 
enkephalins and their receptors in disease activity. The higher 
levels of copeptin in IBD patients with a bowel resection may 
thus be of interest, as vasopressin may modulate gastrointesti-
nal inflammation, either directly38 or indirectly through modu-
lation of proenkephalins and their stimulation of the opioid 
receptors.13,21 The role of copeptin to keep the IBD patient in 
remission deserves to be further examined.

IBS-like symptoms are present in 35%–40% of IBD 
patients during remission. This well-described phenomenon 
has for several years been believed to depend on low-grade 
inflammation.3 Very few human studies have examined the 
effect of neuropeptides on visceral pain, but a connection 
between spinal afferents, enteric mast cells, and the ENS has 
been confirmed, suggesting how elevation of intestinal hyper-
sensitivity might occur involving neural peptides, eg, neuroten-
sin and substance P.12,14 Substance P has also been shown to 
exert proinflammatory effects, especially on neurogenic inflam-
mation.11,14 Noninflamed small bowel samples from patients 
with Crohn’s disease have shown increased expression of sub-
stance P mRNA in one study,5 with more binding sites in the 
inflamed areas, although unchanged mRNA levels were found 
in another study.6 Plasma levels of substance P have previ-
ously been found to be increased in IBS patients but not in 
IBD patients with IBS-like symptoms.39 Presence of IBS-like 
symptoms was not measured in this retrospective study, but the 
unaltered plasma levels of precursors in the current study do 

Table 4. Plasma peptide levels from patients in Malmö Diet and Cancer Study cardiovacsular cohort (MDC-CC) compared with controls.

MDC-CC (n = 40) CONTROLS (n = 120) P-VALUE

Copeptin (pmol/L) 6.70 (3.86–10.55) (34) 5.65 (3.23–8.42) (115) 0.182

MR-proADM (nmol/L) 0.45 (0.38–0.54) (34) 0.45 (0.38–0.51) (116) 0.489

MR-proANP (pmol/L) 66.60 (52.40–82.62) (34) 65.85 (47.38–85.65) (116) 0.499

MR-PENK (pmol/L) 42.65 (37.45–47.52) (28) 46.15 (39.60–53.62) (106) 0.086

NT-PTA (pmol/L) 51.86 (44.18–60.38) (28) 51.01 (41.00–61.67) (102) 0.854

Proneurotensin (pmol/L) 96.28 (62.09–142.69) (28) 93.39 (67.37–138.27) (106) 0.860

Notes: n = number of analyses. Values are given as median [interquartile range (IQR)]. Mann–Whitney U-test. P  0.05 was considered statistically significant.
Abbreviations: IBD, inflammatory bowel disease; MR-proADM, midregional fragment of pro-adrenomedullin; MR-proANP, midregional fragment of pro-atrial 
natriuretic peptide; MR-PENK, midregional fragment of proenkephalin A; NT-PTA, N-terminal polytachykinin A.

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Ohlsson and Melander

26 Drug TargeT InsIghTs 2015:9

not suggest involvement of peptides for development of gas-
trointestinal symptoms.

The limitation of the present study is the small study 
population. However, previous studies in the field have been of 
smaller or similar sizes.7,36 The advantage of measuring precur-
sors instead of peptides depends on the high stability of these 
precursors, which are synthesized in stoichiometric amounts 
relative to the mature peptides.23,24 The strength is that we 
have analyzed several precursors in well-characterized cohorts. 
Higher plasma levels of precursors may be related to a reduced 
degradation/excretion in an elder cohort, rather than an altered 
expression/secretion.40 This means that multiple factors influ-
ence the precursor levels in plasma. We have matched for age, 
gender, smoking habits, and BMI, and excluded patients with 
cardiovascular diseases, diabetes mellitus, and malignancy, but 
factors such as dietary habits, alcohol intake, stress, physical 
activity, sleeping habits, and drug therapy may also influence 
the secretion and degradation of precursors. The difference 
between the two cohorts regarding plasma values of PENK, 
PNT, and PTA may be reflected by the different factors men-
tioned above. Although not statistically significant, there were 
more cases of Crohn’s disease in the MDC-CC cohort than 
in the MPM cohort, and also a different smoking prevalence 
between the two cohorts. As data on the MPM cohort were 
collected several years before those of the MDC-CC cohort, 
treatment regimens in the daily clinic also differed, which may 
have influenced the precursor secretion. Thus, the two cohorts 
were not matched or identical in composition.

In conclusion, higher basal plasma levels of copeptin 
were found in inactive IBD patients, whereas the basal plasma 
levels of MR-proADM, MR-proANP, MR-PENK A, NT-
PTA, and proneurotensin were not altered in inactive IBD 
compared with controls in middle-aged subjects. Elevated 
copeptin levels were found in IBD patients who had under-
gone bowel resection. The role of copeptin to keep the IBD 
patient in remission deserves to be further examined.

List of Abbreviations
AVP, arginine vasopressin; BMI, body mass index; IBD, inflam-
matory bowel disease; MDC-CC, Malmö Diet and Cancer Study 
cardiovascular cohort; MPM, Malmö Preventive Medicine; 
MR-proADM, midregional fragment of pro-adrenomedullin; 
MR-proANP, midregional fragment of pro-atrial natriuretic 
peptide; MR-PENK, midregional fragment of proenkephalin 
A; NT-PTA, n-terminal polytachykinin A.

Author Contributions
Made substantial contributions to the conception and design 
of the study, participated in the interpretation of the statis-
tical analysis, and financed the study: BO, OM. Validated 
the medical records and wrote the manuscript: BO. Both 
authors were involved in revising the manuscript critically 
for important intellectual content, and approved the final 
manuscript.

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