A G R I C U L T U R A L A N D F O O D S C I E N C E M. Tamminen et al. (2012) 21: 182-196 182 Manuscript received October 2011 Viability of Lactobacillus paraplantarum DSM 14485 in hu- man gastrointestinal tract and its molecular and biochemical identification after fermented vegetable consumption Marja Tamminen 1), Arthur C. Ouwehand 2), Maarit Mäki3), Tiina Joutsjoki 4), Marietta Sjöblom 5), Kaija Nissinen6) and Eeva-Liisa Ryhänen 7) MTT Agrifood Research Finland, Biotechnology and Food Research, Alimentum, FI-31600 Jokioinen, Finland 1 Corresponding author, current address: University of Turku, Department of Biochemistry and Food Chemistry, FI-20014 University of Turku e-mail: mttammi@utu.fi, In this study the viability of a potentially probiotic Lactobacillus paraplantarum DSM 14485 in the intestinal tract of 22 healthy test subjects was qualitatively assessed in a randomised double blinded cross-over study design lasting 2 x 4 weeks (interventions I and II) with a 4-week washout period. The subjects were given in their diet either spontaneously fermented vegetables (SF) or vegetables fermented by starter bacteria which contained Lb. paraplantarum DSM 14485 (P). The numbers of lactic acid bacteria (LAB) in fecal samples were at the level of 105 cfu g-1 in both groups. The presence of Lb. paraplantarum DSM 14485 was confirmed by biochemical and molecular methods. We were able to show that Lb. paraplantarum DSM 14485, isolated from spontaneously fermented cucumbers, was viable in the intestine of ten test subjects after taking P-diet when the numbers of LAB were sufficiently high in the product. Key words: identification, lactic acid bacteria, fermented foods, vegetables, intestinal micro-organisms Introduction Vegetables are good sources of fermentable carbohydrates for lactic acid bacteria (LAB) (Yoon et al. 2006) and LAB inoculants have been used for fermentation of vegetables for human consumption (Gardner et al. 2001). LAB also generate additional vitamins (Jägerstad et al. 2004) and low calorie sugars (Weymarn et al. 2002) in these products. LAB can improve the shelf life and the quality of vegetables. Some strains of LAB decrease biogenic amines in fermented cabbage (Spicka et al. 2002), although others may have the potential to produce them (Bover-Cid and Holzapfel 1999). Also, the content of glucosinolate breakdown products in sauerkraut varies depending on sour agents used in products (Tolonen et al. 2004). Specific LAB may have probiotic effects e.g. stimulation of immune response against various diseases (Isolauri et al. 1995, Kankaanpää et al. 2003), reduction of the risk of food allergies (Kalliomäki and Isolauri 2002), alleviation of lactose intolerance symptoms (Jiang and Savaiano 1997), prevention of urinary tract infections (Bruce and Reid 1988) and antitumor activity (Asano et al. 1986). Most strains of the Lactobacillus plantarum-group have been shown to be highly tolerant to acid, alka- line and osmotic stress and highly sensitive to detergent stress, although substantial diversity can been A G R I C U L T U R A L A N D F O O D S C I E N C E M. Tamminen et al. (2012) 21: 182-196 183 found for other stresses (Parente et al. 2010). Lb. plantarum used as starter in cabbage juice was able to survive at 4 ºC and pH 3.6 for four weeks at a level of 107 cfu mL-1 (Yoon et al. 2006). Lb. plantarum has survived for 90 d at pH from 4.0 to 3.5 on artichokes in a brine and in simulated gastric juice (Valerio et al. 2006). Lactobacillus spp. are among the most frequent and best characterized micro-organisms used as probiotic and may alter the microbiota of host by implantation or colonization (Schrezenheimer and de Verse 2001). Viability of a probiotic strain in the intestine is an important criterion for the functionality of probiotics (Saxelin et al. 2010). The aim of this study was to develop reliable, fast and economic methods for screening and identification of LAB from large number of isolated strains from clinical origins. This work was part of a larger clinical trial studying potential health effects of traditionally fermented vegetables and fermented vegetables contain- ing a potential probiotic strain, Lb. paraplantarum DSM 14485 (Nissinen et al. 2003). Lb. paraplantarum is typical in fermented vegetable matrices (Bringel et al. 2005, Gharaei-Fathabad and Eslamifar 2011). The investigated strain was isolated from fermented cucumbers. It was used successfully as a starter in vegetable fermentations and it could be used in wide range of vegetable products suitable for lactose- intolerant people and vegetarians. Also pharmaceutical applications could be developed, because Lb. paraplantarum DSM 14485 has shown essential in vitro probiotic qualities such as tolerance of bile salts, pancreatic juice and acidity, and adhesion to human intestinal mucus (Joutsjoki et al. 2003). Several physiological and molecular methods were tested to identify this bacterial strain and the tests were compared with each other from economical and practical point of view. To fingerprint isolated strains, multiplex-PCR, rep-PCR and RAPD-PCR-analysis were obtained as useful methods (Bringel et al. 2005, Mäkimattila et al. 2011, Parente et al. 2010) so as Torriani et al. (2001a) used combination of RAPD-PCR patterns with ALFP effectively in differentiation strains of Lb. plantarum-group. In this study PFGE was tested for Lb. paraplantarum DSM 14485. Materials and methods Sources of LAB The aim of the clinical study was to determine the effects of two production methods of fermented veg- etables (spontaneous and starter fermentation) on indicators of metabolic activity of intestinal microbiota, some parameters of nutritional status and acceptability of these products by healthy subjects. The study was approved by the ethical committee of University of Kuopio and Academical Central Hospital of Kuopio. A randomized, double blinded, cross-over study lasted 2 x 4 weeks with a 4-weeks washout period and 2 weeks run-in period. Feces were collected at the end of each period from 22 healthy subjects (Fig. 1). The diet contained vegetable products which were fermented by LAB starters including potentially probiotic Lb. paraplantarum DSM 14485, which was earlier identified as Lb. paraplantarum DSM 14485 (Joutsjoki et al. 2003 ). During interventions, subjects consumed daily 100 g of fermented vegetables (sauerkraut or salad mixture prepared from sliced carrots and grated swede) and 200 g of juice prepared from mixture of pressed sauerkraut and from 20 to 27% of heat treated carrot juice, or carrot juice alone fermented either spontaneously or with Lb. paraplantarum DSM 14485. Sauerkraut was packed at the same time for the both interventions and stored in a freezer at -25 ºC. For the intervention I, carrot juice and salad mixture were prepared in two lots, whereas for intervention II the products were prepared in one lot. Intervention I was followed by a wash out period of four weeks. The products were stored frozen. Intervention II was carried out in the same manner as intervention I. The screening procedure of fecal samples is summarized in Figure 2. The basic health status of tests subjects is described in Table 1. A G R I C U L T U R A L A N D F O O D S C I E N C E M. Tamminen et al. (2012) 21: 182-196 184 Basic period Intervention I Wash out Intervention II n= 24 n=22 Lb. paraplantarum Ordinary diet n=10 Ordinary diet Lb. paraplantarum n=12 0 2 6 10 14 Weeks ↑ ↑ ↑ ↑ ↑ Fig. 1. Path of the test procedure in clinical trial.↑ The point of feces samples. Table 1. The basic health status of test subjects at the beginning of investigation (n=24). Two of the subjects interrupted the test before interventions. All test subjects were women. Parameter Average ± SD Age 39 ± 9 (20–54) Weight (kg) 66.4 ± 9.2 (50.5–86.7) Weight index (kg m-2) 24.4 ± 3.9 (19.7–34.1) Systolic blood pressure (mmHg) 118 ± 10 (96–147) Diastolic blood pressure (mmHg) 79 ± 9 (61–95) Microbiological methods LAB from fecal samples were analyzed at the University of Kuopio fresh or after storage at -70 oC on de Man, Rogosa, Sharpe (MRS, LabM) agar plates (NMKL 140:1991). The agar plates were sent to MTT for further analysis. Several colonies (4−6) from each fecal sample were collected and purified on MRS-agar plates (Difco Laboratories) incubated anaerobically for 2 days at 30 oC. Purified cultures were stored at −70 o C in MRS-broth containing 15% glycerol. Reference strains were obtained from type culture collections: Lb. plantarum DSM 20174, Lb plantarum 8014 TNO 96111, Lb. plantarum 8014 TNO 96111, Lb. plantarum NCDO 1193. LAB in fermented vegetables were enumerated at MTT by cultivation on MRS-agar plates incubated anaerobically for 3 days at 30 oC A G R I C U L T U R A L A N D F O O D S C I E N C E M. Tamminen et al. (2012) 21: 182-196 185 Screening by PCR-ELISA, specific to Lb. pentosus and Lb. plantarum (n = 400). Fermentation of carbohydrates (n = 96). Selection of turanose-negative strains. Multiplex-PCR specific for Lb. plantarum, Lb. paraplantarum and Lb. pentosus (n = 27) .Lactobacillus sp. 2* is identified as L. paraplantarum Screening of strains by RAPD-PCR (n = 24). Identification of Lb. paraplantarum DSM 14485 among isolates by PFGE (n = 24). Isolation of pure cultures of LAB from fecal samples (n=22) grown on MRS-agar plates. Molecular and biochemical identification of LAB Identification of LAB from fecal samples was carried out in six steps in order to show the viability of Lb. paraplantarum DSM 14485 in human gastrointestinal tract (Fig. 1). Isolated pure cultures (about 400), were first screened by PCR-ELISA to identify members of the Lb. plantarum–family using universal primers of 23S rRNA (Ehrmann et al. 1994) and Lab 448, specific probe to Lactobacillus pentosus and Lb. plan- tarum–species (Hertel et al. 1991). In the next step 96 strains identified as Lb. plantarum / Lb. pentosus were studied for their fermentation of sugars in basic medium using chlorophenol red as an indicator (Table 2). Sugars for the test, D-sorbitol, D-turanose, inulin, L-arabinose, D-raffinose and D-glucose (posi- tive control), were selected according to their ability to differentiate Lb. plantarum–strains (Validov et al. 1998). Media (200 µl) were inoculated with 3 µl of overnight grown culture and incubated anaerobically in microtitreplates about 48 h at 30 oC. Fig. 2. Flow chart of the test procedure. The number of tested isolates in parenthesis. A G R I C U L T U R A L A N D F O O D S C I E N C E M. Tamminen et al. (2012) 21: 182-196 186 Table 2. Basic sugar broth used in identification of lactic acid bacteria. The pH of this medium was adjusted to pH 6.5 and sterilized by autoclaving at 121°C for 20 min. Component to 100 ml distilled water Casein peptone 1 g Yeast extract 0.4 g K 2 HPO 4 *3 H 2 O 0.2 g Sodium acetate (NaCH3COOH) 0.25 g Tri-ammoniumcitrate (C 6 O 7 H 5 (NH 3 ) 3 0.24 g Tween 80 0.1 ml MgSO 4 *7 H 2 O 20 mg MnCl 2 *4 H 2 O 4.4 mg Chlorophenol red 4 mg For the identification by multiplex-PCR, over night cultures of LAB (MRS broth at 30 oC) were lysed by shaking with glass beads. Template used in PCR reactions were lysates of bacteria using disintegration of cells by glass beads shaking in a cell mill. Total-DNA was isolated by phenol extractions for RAPD and multiplex-PCR (Tamminen et al. 2004). The members of Lb. plantarum-family were identified by species-spesific PCR-method (Torriani et al. 2001b). Primers for Lb. plantarum, Lb. paraplantarum and Lb. pentosus were available (TAG Copenha- gen A/S Symbion, Denmark). Taq polymerase (Promega Corporation, Madison WI, USA) was used in PCR amplifications (Programmable Thermal Controller PTC-100-60, MJ Research Inc., Massachusetts, USA). Electrophoresis was performed using a 1.2% agarose gel and TAE buffer in 80 V potential 1.5 h. The am- plifications of Lactobacillus-strains from feces were verified with those of other Lactobacillus-strains (Lb. plantarum–strains: 8014 TNO96111, 80 TNO9611, DSM 20174 and Pho 9, Lb. pentosus Vegstart 60 and Vegstart 10 (Chr Hansen A/S, Hørsholm Denmark) and Lb. plantarum strains isolated from fermented cucumbers (investigation of MTT, Food Research) and Lactobacillus brevis DSM 20054 –strain. For RAPD-PCR –reactions amplification was done by primers (GTG) 5 and ACGCGCCCT. The amplification conditions and primers for these reactions were as described by Johansson et al. (1995 a) and Gevers et al. (2001) using Taq polymerase. Samples (0.5 µl diluted in 9.5 µl H 2 O) were applied to the agarose gel (1.2%) and the used potential was 120 V in electrophoresis (Bio-Rad Programmable Power supply, model 3 000 Xi, Bio-Rad Laboratories, California, USA). The same strains were used to verify amplification A G R I C U L T U R A L A N D F O O D S C I E N C E M. Tamminen et al. (2012) 21: 182-196 187 profiles from the multiplex–PCR verification. Strains studied by RAPD-PCR were screened by carbohydrate fermentations and selected isolates that fermented D-turanose were chosen as reference for RAPD –analysis. The PFGE-method was adapted from Tynkkynen et al. (1999). In short, DNA was isolated in agarose blocks, digested and subsequently analyzed by electrophoresis. Restriction enzyme Asc I (Biolabs, New England, USA) was used for the digestion of bacterial DNA. The results from RAPD- and PFGE-electrophoresis were analyzed by Bionumerics (Applied Maths, Sint-Martens-Latem, Belgium). The parameters used in PFGE were two different combinations: 1) pulse time 1.0-10.0 s, experiment time 20.5 h and voltage 5.5 V/cm and 2) pulse time 5-15 s experiment time 20.5 h and voltage 5.5 V cm-1 (Bio-Rad, CHEF-DR III). For accuracy, it is appropriate to use multiple techniques, working on species specific level (16sRNA, DNA- DNA-hybridization or PCR) and on strain level to obtain a detailed fingerprint of individual isolates (PFGE, RFLP or RAPD) (Temmerman et al. 2004). Results Numbers of LAB LAB contents of products were analyzed at the beginning and at the end of interventions (Fig. 3). The desired level of LAB, from 7 to 8 lg cfu g -1, was detected in carrot juice samples, whereas the numbers decreased or were at the low level in other products. Spontaneously fermented carrot juice (SF) contained during intervention I 8.7 lg cfu g-1 (geometric mean) and intervention II 8.2 lg cfu g-1 of LAB, while carrot juice fermented by Lb. paraplantarum DSM 14485 (P) contained 8.7 and 7.4 lg cfu g-1, correspondingly. The numbers of LAB in fecal samples have been reported by Nissinen et al. (2003). In samples collected from test subjects who ate SF-products, the average LAB numbers in interventions I and II were 5.22 ± 1.05 (n = 19) at the beginning and 4.82 ± 0,83 (n=21) lg cfu g-1 at the end of period, and 5.42 ± 0.82 (n = 21) and 5.16 ± 0.76 (n = 21) lg cfu g-1 correspondingly from subjects who ate P-products. 100 102 104 108 1010 Carrot juice (SF) (P) Sauerkraut-carrot- juice (SF) (P) Grated swede and carrot (SF) (P) Sauerkraut (SF) (P) Intervention I start end Intervention II start end 106 cfu g-1 Fig. 3. Contents of LAB in fermented vegetable products at the start and the end of the interven- tions I and II. Spontane- ous fermented (SF) and potential probiotic (P) products. A G R I C U L T U R A L A N D F O O D S C I E N C E M. Tamminen et al. (2012) 21: 182-196 188 The screening of approximately 400 isolates from the faecal samples was carried out by PCR-ELISA. Of these, 96 showed absorbance (OD 600nm) over 0.1 and were further tested for their carbohydrate fermentation profiles. The reference strains showed different fermentation profiles from Lb. paraplan- tarum DSM 14485, which does not ferment D-turanose. Of the 96 tested isolates, 65 were unable to ferment D-turanose. These isolates were tested for their ability to ferment the other sugars. Based on these results, 27 isolates were selected for further studies. Multiplex-PCR The detection of Lb. paraplantarum DSM 14485 amplified 107 bp fragment typical for Lb. paraplantarum (Tamminen et al. 2003). This strain was earlier identified as Lb. plantarum by API CHL 50 test (Joutsjoki et al. 2003). Lb. plantarum and Lb. paraplantarum are phylogenetically very close as is Lb. pentosus. The reference strains amplified typical fragments for their species but the strain isolated from fermented cucumbers which was identified Lb. pentosus by API CHL-test amplified 318 bp fragment typical for Lb. plantarum. Among the tested 27 isolates, 24 were identified as Lb. paraplantarum and 3 isolates as Lb. plantarum. Amplifications of multiplex-PCR are shown in Figure 4. Fig. 4. Multiplex-PCR amplification of Lb. plantarum-related lactobacilli isolated from fecal samples. Lanes 1. and 11.: l Pst I molecular weight marker, line 2.: Lb. paraplantarum DSM 14485, lines 3.-8. Lb. plantarum –strains (8014 TNO96111, 80 TNO9611, DSM 20174 and Pho 9), line 9: Lb. pentosus Vegstart 60, lines 10. And 12.: Lb. plantarum strains isolated from fermented cucumbers, line 13: Lb. brevis DSM 20054 -strain and 14.-20.: strains isolated from fecal samples. RAPD -PCR PCR–reactions were tested using both total DNA and lysate from the tested isolates. The total-DNA for RAPD –reactions was chosen as template. DNA was isolated from 31 strains screened by carbohydrate fermentations including also isolates (2 Lb. paraplantarum and 2 Lb. plantarum –isolates) which had differ- ent carbohydrate profiles from Lb. paraplantarum DSM 14485. Total 27 Lb. paraplantarum -isolates and 4 Lb. plantarum isolates from fecal samples were used as reference in these RAPD -analyses. The results were calculated by Pearson product moment correlation coefficient (r) and position tolerance was 1%. A G R I C U L T U R A L A N D F O O D S C I E N C E M. Tamminen et al. (2012) 21: 182-196 189 When ACGCGCCCT-primer was used in amplification with Lb. paraplantarum DSM 14485 length of bands were 1 049 bp, 706 bp and 412 bp. There were 9 isolates (48/4, 61/2, 43/1, 47/2, 44/1, 54/2, 61/1, 24/1, 44/2) in the same cluster with Lb. paraplantarum DSM 14485 with 87% similarity (Fig. 5). When (GTG)5 –primer was used there were five bands: 1 116 bp, 910 bp, 754 bp, and 627 bp and 413 bp. Six isolates (33/2, 61/2, 61/1, 48/4, 24/1) from test group samples showing over 48% similarity with Lb. paraplan- tarum DSM 14485 (Fig. 6.). ACGCGCCCT -primer differentiated the isolates more than (GTG) 5 -primer so only one isolate differed between these clusters of two different primers (Fig. 7). Fig. 5. RAPD-PCR-amplifications of fecal Lactobacillus strains by (GTG)5 –primer. Lines 1. and 11.: l Pst I molecular weight marker, line 2. Lb. paraplantarum DSM 14485, line 3. Lb. brevis DSM 20054, lines 4 - 9 Lb. plantarum strains: 8014 TNO96111, 80 TNO9611, DSM 20174, NCDO 1193, Pho 9, Vegstart 60, line 9: Lb. pentosus VegStart 60 lines 10 and 12: Lb. plantarum strains isolated from fermented cucumbers and 14.-20.: strains isolated from fecal samples. Fig. 6. RAPD-PCR-amplifications of fecal Lactobacillus strains by ACGCGCCCT-primer. Lines 1. and 11.: SPP1 Eco RI molecular weight marker. The bacterial strains used in amplifications on the lines 2.-10. and 12.-20 are the same as in the figure 2. A G R I C U L T U R A L A N D F O O D S C I E N C E M. Tamminen et al. (2012) 21: 182-196 190 7a. 7b. Fig. 7. Cluster analysis of RAPD –PCR with (GTG)5 (7a) and ACGCGCCCT primers (7b). RAPD profiles were analysed by Bionumerics program. A G R I C U L T U R A L A N D F O O D S C I E N C E M. Tamminen et al. (2012) 21: 182-196 191 PFGE –analysis The results of PFGE -electrophoresis (Fig. 8) were calculated with UPMGA-system and the position tolerance in analysis was 2%. Twenty seven isolates were analyzed by PFGE-technique and 14 of them had similarity of 100% with Lb. paraplantarum DSM 14485, seventeen over 99% similarity and 19 over 95% similarity. Two isolates of 27 could not be identified. The isolates with 100% similarity were originated from 13 fecal samples, and five of these isolates were from frozen samples (from five different test subjects). In fecal samples, which were recovered from 10 of the 12 test subjects eating P-diet, several isolates showed over 95% similarity to Lb. paraplantarum DSM 14485 (Table 3). All isolates with over 95% similarity originated from samples of intervention I. Only four isolates had under 95% similarity with Lb. paraplantarum DSM 14485 (Fig. 9a and 9b. Table 3. Number of LAB and Lb. paraplantarum DSM 14485 in the double blinded cross-over study identified by multi- plex-PCR and PFGE calculated as per cent of isolated LAB. Period Basic Intervention I Wash-out Intervention II Diet P SF P SF Number of test subjects 24 12 10 22 10 12 Number of isolated LAB 92 88 80 88 40 44 Strains identified as DSM 14485 0 19 0 0 0 0 Number of test subject whose fecal samples contained DSM 14485 0 9 0 0 0 0 Fig. 8. PFGE –electrophoresis of fecal bacterial strains. Lines 1 and 12: molecular weight markers: line 1 lambda DNA (uncut and Hind III fragments ) and line 12 lambda DNA concatemers. The brightest fragment is 48,5 kb long. In line 2 is pattern of restricted DNA of Lb. paraplantarum DSM 14485. Lines 3-11 are restricted DNA patterns of bacterial strains, iso- lations 29/1, 24/3, 29/3, 30/1, 34/2b, 27/2b, 29/2b, 4471, 61/1 respectively. A G R I C U L T U R A L A N D F O O D S C I E N C E M. Tamminen et al. (2012) 21: 182-196 192 Fig. 9a. Cluster analysis of PFGE -electrophoresis. Samples numbered 10641 and 10667 are Lb. paraplantarum-strains from DSM-collection. 2*1, 2*2, 2*3 and 2*4 are Lb. paraplantarum DSM 14485 restrictions of separated PFGE –electro- phoresis. 81/2 was isolated from a sample of wash out-period of spontaneous fermentation. Fig. 9b. Cluster analysis of two isolates 33/1 and 90/1 isolated from a sample of intervention II, starter fermentation. Pat- tern of 2*5 Lb. paraplantarum DSM 14485 restriction is shown as 2*5. A G R I C U L T U R A L A N D F O O D S C I E N C E M. Tamminen et al. (2012) 21: 182-196 193 Discussion PFGE-analysis showed that Lb. paraplantarum DSM 14485 was able to survive in the human gastroin- testinal tract. Lb. paraplantarum DSM 14485 was found in the feces of the ten persons out of twelve that participated in the intervention studies. PFGE–analysis is a very specific method to identify bacterial strains (Tynkkynen et al. 1999, Simpson et al. 2002). Parameters of electrophoresis which can be changed are potential, pulse time, and running time of electrophoresis. No Lb. paraplantarum DSM 14485 strains were detected in the samples taken before the intervention. All identified Lb. paraplantarum DSM 14485 strains were isolated from intervention I, including frozen fecal samples. Lb. paraplantarum DSM 14485 was not detected in any fecal samples collected from intervention II. Possibly the numbers of active and viable LAB were higher in the Intervention I, since in intervention I products were prepared in two lots except for sauerkraut, which was packed all at once for both interventions, whereas for the intervention II they were prepared in one lot. There is no clear explanation why Lb. paraplantarum 14485 could not be isolated from fecal samples from intervention II. The proportion of isolates identified by PFGE with over 95% similarity to Lb .paraplantarum DSM 14485 was approximately 11.0% of isolates from feces in the end of intervention I, and consequently the frequency of Lb. paraplantarum was approximately 0.57 lg cfu g 1 corresponding 6.6% of LAB in carrot juice used in interventions I and II. RAPD-PCR is not a specific method for Lb. paraplantarum DSM 14485, because this method did not yield 100% similarity for any isolate in this investigation with both PCR primers. Strains from different species may yield similar profiles and different species may show only few differences e.g. one fragment difference in profiles (Moschetti et al. 2000, Villani et al. 1997). Discrimination power can sometimes be lower than that of API CHL 50 (Johansson et al. 1995b) disagreeing with studies of van Reenen and Dicks (1996), who reported successful differentiations between Lb. plantarum and Lb. pentosus strains with RAPD versus carbohydrate fermentations. Rep A-primer (GTG) 5 was also used to distinguish Lb. plantarum from Lb. pentosus and Lb. paraplantarum isolated from fermented vegetable foods from India (Tamang et al. 2005). Despite a limited specificity, RAPD is a useful tool to screen bacterial isolates rapidly. When RAPD-PCR is used as screening method, it is necessary to screen primers for bacterial strains suitable for differentiation. However, RAPD-PCR is fast and economic to screen large numbers of bacteria for further studies so it is useful 1) especially in combination with other techniques for example carbohydrate fermentations or 2) if there is not any optimized method available to identify bacterial strains or 3) if carbohydrate fermenta- tions do not differentiate isolates enough to further studies. PCR-ELISA is not as fast as RAPD, but it is a more specific method at family or species level if the probes are well designed. In this case, multiplex-PCR combined with carbohydrate fermentation is enough to identify isolates from same origin and strains which are genetically close to each other. However, species-specific PCR is restricted to specific primers which should be available depending on the bacterial species. Design of primers requires sufficient know how and time. This also applies to PCR-ELISA -method. Conclusions The present study reports the use of a combination of molecular and culture based techniques to suc- cessfully determine the survival of a potential probiotic through gastrointestinal transit; a strategy that may be useful also for other strains. In screening of isolates from feces some methods were much more economical and rapid than PFGE: Multiplex-PCR, PCR-ELISA, carbohydrate fermentations and RAPD-PCR. 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Viability of Lactobacillus paraplantarum DSM 14485 in humangastrointestinal tract and its molecular and biochemicalidentification after fermented vegetable consumption Introduction Materials and methods Sources of LAB Microbiological methods Molecular and biochemical identification of LAB Results Numbers of LAB Multiplex-PCR RAPD -PCR PFGE –analysis Discussion Conclusions References