WO1998039473A1

WO1998039473A1 - In vitro analysis for detection of tumours of the intestine

Info

Publication number: WO1998039473A1
Application number: PCT/EP1998/001223
Authority: WO
Inventors: Herbert Lochs; Alexander Swidsinski
Original assignee: Schering Aktiengesellschaft
Priority date: 1997-03-06
Filing date: 1998-03-04
Publication date: 1998-09-11
Also published as: AU721826B2; DE19711111A1; EP0977888A1; DE19711111C2; CA2293704A1; AU6727598A

Abstract

The invention relates to in vitro analysis of intraepithelial intestinal bacteria, constituents thereof and reaction products of the host thereon, for detection of tumours of the intestine and the precursors thereof.

Description

In vitro detection for the detection of intestinal tumors

The invention relates to the use of in vitro detection of intraepithelial intestinal bacteria, constituents thereof and reaction products of the host thereon, for the detection of intestinal tumors and their precursors.

Malignant tumors are a serious threat to human health because of their poor prognosis. The treatment options for the majority of malignant tumors are currently limited and depend on the stage of the disease. Early detection of the disease and its preliminary stages is therefore one of the primary goals of clinical scientific research. Carcinogenesis is viewed as an interaction of endogenous (genetic) and exogenous factors. While genetic changes in the cell have so far offered few opportunities for therapeutic intervention, an understanding of exogenous carcinogens is hoped for an immediate benefit. In the beginning, the main focus was on chemical and radioactive substances, as the effects of these carcinogens in cell cultures and animal experiments are easy to follow. With the discovery of carcinogenic viruses, the infectious causes of tumor development came to the fore. Viruses are not the only pathogens with carcinogenic potency. A connection between certain types of carcinoma and a chronic infection with schistosoma or liver fluke has long been known.

The role of bacteria, however, has only recently been revealed. Helicobacter pylori was the first bacterium to be assigned to group I carcinogen (WHO / IARC Congress in Lyon, 1994 and Logan RPH, Helicobacter pylori and gastric cancer, Lancet 1994, 334, 1078-79).

The relationship between permanent gastric colonization by Helicobacter pylori and gastric carcinoma is considered established. Colorectal cancer, like gastric cancer, is one of the most prevalent tumors worldwide. The epidemiological peculiarities of the spread of colorectal cancer have led to the assumption in the 1970s that gastrointestinal bacteria are causally related to colorectal cancer (Aries VC, Crowther JS, Drasar MJ, Hill MJ and Williams REO, Bacteria and the etiology of cancer of the large bowel, GUT 10, 334, 1969). Despite intensive and targeted research, the postulated relationship between gastrointestinal bacteria and carcinogenesis has so far only been confirmed for Helicobacter pylori. The reason for this is an extreme complexity of the intestinal flora. This contains bacterial densities of up to 10 ^ g dry weight in the colon content. However, attention has so far been focused mainly on intraluminal bacteria. If a Pathogen that permanently colonizes the large mucosa in the development of colorectal cancer is not known. This could not be answered with the classic known bacteriological methods.

There is now use of in vitro detection of intraepithelial

Intestinal bacteria, constituents of the same and reaction products of the host to them, for the detection of intestinal tumors and precursors of intestinal tumors.

The use is characterized in that the following steps are carried out for the in vitro detection: a) shake biopsy samples in an aqueous solution and then take them up again in aqueous solution, b) process step a) is repeated several times, the supernatants are discarded, c) the residues transferred to an SDS-containing solution at room temperature and carefully or slowly shaken or rotated to dissolve the tissue and the DNA fraction, d) the DNA was purified with phenol and glass beads and then resuspended in water, e) the DNA thus obtained was used with universal 16 sRNA primers amplified and then the strength of the PCR product of the sample with the strength of

Compares PCR products of standardized bacterial solutions of specific density, f) clones and sequences positive PCR products and finally g) compares the DNA sequences found in the biopsy with the known bacterial DNA sequences from DNA databases.

The proof can be modified in many ways. Species-specific primers can be used for the PCR. Virulence factors can be specifically detected in the biopsy sample or even in stool samples. In situ hybridization can also be carried out. Furthermore, immunohistochemical and electron microscopic detection of bacteria in the mucosa can be carried out. Nuclear medical methods such as scintigraphy or breath tests are also conceivable.

The aqueous solution used in method step a) of the detection is preferably a physiological saline solution. The SDS-containing solution used in method step c) of the detection is preferably a 0.5-5% SDS / physiological saline solution.

The time for shaking the biopsy samples in method step a) of the detection is preferably 10-120 s, particularly preferably 30-60 s.

The biopsy samples are preferably taken in step a) of the detection in 100-1000 μ \ physiological saline, particularly preferably in 500 l.

Process step a) of the detection is preferably repeated 5-20 times, particularly preferably 7-10 times.

The fractions in method step c) of the detection are preferably added to a volume of 100-500 l of 0.5-5% SDS / physiological saline solution, with a 1% solution being particularly preferred.

The preferred time of shaking and rotating in process step c) of the detection is 10-24 hours, particularly preferably 12 hours.

In process step d) of the detection, it is preferably resuspended in a volume of 10-50 μl of water, particularly preferably in a volume of 20 μl of water.

The use relates in particular to the detection of E. coli bacteria in colon biopsies.

The in vitro detection is also used in the examination of samples from other body compartments such as lymph and body fluids such as blood, fluids of the gastrointestinal tract and fluids from neighboring tissues of the stomach and intestine. The host's reaction products to the infestation with E. coli or other bacteria characteristic of the tumor can be detected by means of customary analytical methods, for example an immunoassay.

The use of the in vitro detection according to the invention relates to E. coli, constituents of E. coli, reaction products of the host to E. coli and related bacteria in the intestinal mucosa or other compartments of the body outside the gastrointestinal lumen. The following exemplary embodiments explain the invention, without restricting it to the examples.

example 1

Tissues from biopsies were placed in physiological saline and held at 4 ° C for two hours until further use. Each sample was crushed vigorously with a chopper (vortex stick) in a 1.5 ml plastic tube for 1 minute and then added to 500 μl of fresh physiological saline. This

The process was repeated 8 times. The sample was then incubated at room temperature in a 1% SDS saline solution and centrifuged off overnight. DNA is extracted from the supernatant with phenol, further purified using a GeneClean kit and finally resuspended in 30 μl of water which is used for high pressure liquid chromatography (HPLC).

The 5 'end of the 16S rRNA genes (600 bp) was amplified by PCR using a universal primer for bacteria:

5'-CTGGTTCCGGCGAAGAGTTTGAT (c / t) fc / a TGGCTC AG-3 '5'-CTCGCTCCGGCGAACCGC (g / t (a / g) CTGCTGGCAC-3 ^l

The 13 additional nucleotides (underlined) were bound to the 5 'end for cloning.

In order to avoid false positive PCR results, pre- and post-PCR stages were carried out in different setups and parallel control experiments with the omission of template DNA.

The amount of bacteria in the samples was determined by means of electrophoretic comparison of the PCR

- Samples for PCR standard solutions of bacteria with 10 ⁵ , 10 ⁴ , 10 ³ , 10 ² and 10 colony forming units (cfus) per μl measured after 25 and 30 thermal cycles. The agarose gel was treated with ethidium bromide for visualization. Solutions with 10 cfus / μl gave no PCR signal. Sample PCR signals with 10 ^ cfus / μl were too weak for further steps and were considered negative.

For the determination of the bacterial composition in the sample with a positive PCR signal, amplified 16S rRNA sequences were cloned into a pCMV-LIC vector according to a ligation-independent cloning protocol. Between 40 and 200 clones were sequenced in a sequencer for each biopsy. The bacterial sequences were analyzed and compared as previously described with 16S rRNA primary structures from databases.

Example 2

Biopsies were taken from humans to demonstrate the feasibility of the method according to the invention.

For this, 82 people were consecutively colonoscoped. The removed colon biopsies were examined for the presence of intraepithelial germs. Three groups were formed:

1st normal group: 42 people with macroscopic and histologically unremarkable colonoscopic findings

2nd adenoma group: 22 people with tubulovillous adenomas

3rd carcinoma group: 18 people with carcinomas, 11 of whom had the condition after

Colon resection less than three years ago, with four of the resected patients free of recurrence

None of the examined had a familial polyposis or received antibiotics two weeks before the examination. 1 to 7 biopsies were taken from each examined. These biopsies were examined with the method according to the invention for intraepithelial and related E. coli bacteria.

If possible, biopsies were taken from both the suspected tumor and the normal mucosa.

The sex, the average age and the age structure of the examined in the three groups is as follows:

Normal adenoma carcinoma

Total number of subjects examined: 42 22 18

Average age: 45.6 67.2 60

Age structure: 20-84 39-85 38-79

Women: 25 14 8

Average age: 48 68.1 64

Age structure: 20-84 50-75 38-79

Men: 17 8 10

Average age: 42.2 65.5 58

Age structure: 25-60 39-85 46-67 The bacterial concentration was determined quantitatively in 103, 56 and 47 biopsies from investigators from the normal, adenoma and carcinoma groups.

No bacteria were found in 37 out of 42 normal group studies (0 to 100 cfu / μl). In contrast, there were bacterial concentrations between 10 ^ and 10 ^ cfu / μl in at least one biopsy in all examined carcinoma groups and in 21 out of 22 examined adenoma group. Bacteria were also found in 23 of the 44 biopsies from the normal mucosa of those examined from the adenoma group and 31 of the 37 biopsies from the carcinoma group. PCR positive biopsies from the normal mucosa and from tumor tissue of the examined were determined as follows:

With adenoma With carcinoma

Collection point: normal mucosal tumor normal mucosal tumor Total number of biopsies: 44 12 37 10

PCR positive biopsies: 23 (52%) 11 (91%) 33 (84%) 9 (90%)

5, 26 and 32 PCR products from the biopsies of the normal, adenoma and carcinoma groups were cloned and sequenced. In the normal group, one sample per patient was sequenced. All positive PCR products from the tumor were cloned and sequenced in the adenoma / carcinoma groups. The sample with the maximum bacterial concentration was selected, cloned and sequenced from the step biopsies from normal colon sections of the tumor groups. 80% of all sequenced clones in 17 out of 21 examined persons from the adenoma group and 17 out of 18 examined persons from the carcinoma group contained the E. coli sequence.

The following table shows the results of the quantitative PCR and the results of the sequence analysis of cloned PCR products.

* Bacteroids, clostridia, Pseudomonas, E. coli, none of them more than 20% of all clones ** If dominance is found in more than 80% of all clones, the same sequence

From the results it can be seen that both look more normal in biopsies

Mucosa as well as in biopsies of tumor tissue of those examined with colon carcinoma and colon adenoma intraepithelial bacteria are present.

Claims

claims

Use of an in vitro detection of intraepithelial intestinal bacteria, their constituents and reaction products of the host thereon, for the detection of intestinal tumors and precursors of intestinal tumors.

2. Use of an in vitro detection of E. coli, constituents of E. coli, reaction products of the host on E. coli and related bacteria in the intestinal mucosa or other compartments of the body outside the stomach.

Intestinal lumen for the detection of intestinal tumors.

3. Use according to claims 1 and 2, characterized in that the following steps are carried out for the in vitro detection: a) shake biopsy samples in an aqueous solution and then take them up again in aqueous solution, b) process step a) is repeated several times, the Supernatants are discarded, c) the residues are transferred to an SDS-containing solution at room temperature and carefully or slowly shaken or rotated to dissolve the tissue and the DNA fraction, d) the DNA is purified with phenol and glass beads and then resuspended in water, e ) amplify the DNA thus obtained with universal 16 sRNA primers and then the strength of the PCR product of the sample with the strength of

4. Use according to claim 3, characterized in that the aqueous solution used in process step a) is a physiological saline solution.

5. Use according to claim 3, characterized in that the in

Process step c) the SDS-containing solution used is a 0.5-5% SDS / physiological saline solution.

6. Use according to claim 3, characterized in that the time for shaking the biopsy samples in process step a) is 10-120 s.

7. Use according to claims 3 and 6, characterized in that the time for shaking the biopsy samples in process step a) is 30-60 s.

8. Use according to claim 3, characterized in that the biopsy samples in process step a) are taken up in 100-1000 ul physiological saline.

9. Use according to claims 3 and 8, characterized in that the biopsy samples are taken up in 500 ul physiological saline.

10. Use according to claim 3, characterized in that process step a) is repeated 5-20 times.

11. Use according to claims 3 and 10, characterized in that process step a) is repeated 7-10 times.

12. Use according to claim 3, characterized in that the fractions in process step c) are added to a volume of 100-500 ul 0.5-5% SDS / physiological saline.

13. Use according to claims 3 and 12, characterized in that the fractions in process step c) are added to a volume of 100-500μl 1% SDS / physiological saline.

14. Use according to claim 3, characterized in that the time of shaking and rotating in process step c) is 10-24 hours.

15. Use according to claims 3 and 14, characterized in that the time of shaking and rotating in process step c) is 12 hours.

16. Use according to claim 3, characterized in that in process step d) is resuspended in a volume of 10-50 ul water.

17. Use according to claims 3 and 16, characterized in that in process step d) is resuspended in a volume of 20 ul water.

18. Use according to claims 1-17 in samples of body compartments such as lymph and body fluids such as blood, fluids of the gastrointestinal tract and fluids of adjacent tissues of the stomach and intestine.