Penetration of bacteria into meat.

Bacteria are confined to the surface of meat during the logarithmic phase of growth. When proteolytic bacteria approach their maximum cell density, extracellular proteases secreted by the bacteria apparently break down the connective tissue between muscle fibers, allowing the bacteria to penetrate the meat. Non-proteolytic bacteria do not penetrate meat, even when grown in association with proteolytic species.     

Tissue sterility in uneviscerated carcasses.

Sheep muscle tissue removed aseptically from control carcasses, from uneviscerated carcasses held at 20 degrees C for 24 h, and from carcasses of sheep subjected to stress before slaughter was examined for the presence of bacteria. All samples from a total of 68 carcasses were sterile. Whole-body autoradiography of mouse carcasses showed that 14C-labeled fixed bacteria injected after death remained in the lumen of the intestine. Live bacteria did not penetrate the mucosal surface until the tissue structure had been disrupted by proteolytic enzymes. Bacteria were unable to penetrate sections of intestine longitudinally until considerable structural breakdown had occurred, indicating that blood and lymph vessels do not normally offer a pathway for microbial invasion from the intestine. Clostridia, which have been reported to be responsible for deep spoilage of meat, reached maximum numbers 24 to 28 h after death in the intestines of guinea pig carcasses stored at 20 degrees C, but did not invade carcass tissues until the stomach ruptured as a result of proteolysis between 2 and 3 days after death.     

Tissue sterility in uneviscerated carcasses.

Sheep muscle tissue removed aseptically from control carcasses, from uneviscerated carcasses held at 20 degrees C for 24 h, and from carcasses of sheep subjected to stress before slaughter was examined for the presence of bacteria. All samples from a total of 68 carcasses were sterile. Whole-body autoradiography of mouse carcasses showed that 14C-labeled fixed bacteria injected after death remained in the lumen of the intestine. Live bacteria did not penetrate the mucosal surface until the tissue structure had been disrupted by proteolytic enzymes. Bacteria were unable to penetrate sections of intestine longitudinally until considerable structural breakdown had occurred, indicating that blood and lymph vessels do not normally offer a pathway for microbial invasion from the intestine. Clostridia, which have been reported to be responsible for deep spoilage of meat, reached maximum numbers 24 to 28 h after death in the intestines of guinea pig carcasses stored at 20 degrees C, but did not invade carcass tissues until the stomach ruptured as a result of proteolysis between 2 and 3 days after death.     

Inhibition of food-borne bacterial pathogens by bacteriocins from lactic acid bacteria isolated from meat

Ten strains of bacteriocin-producing lactic acid bacteria were isolated from retail cuts of meat. These 10 strains along with 11 other bacteriocin-producing lactic acid bacteria were tested for inhibitory activity against psychotrophic pathogens, including four strains of Listeria monocytogenes, two strains of Aeromonas hydrophila, and two strains of Staphylococcus aureus. Inhibition due to acid, hydrogen peroxide, and lytic bacteriophage were excluded. The proteinaceous nature of the inhibitory substance was confirmed by demonstration of its sensitivity to proteolytic enzymes. Eight of the meat isolates had inhibitory activity against all four L. monocytogenes strains. Bacteriocin activity against L. monocytogenes was found in all of the strains obtained from other sources. Activity against A. hydrophila and S. aureus was also common.     

Inhibition of food-borne bacterial pathogens by bacteriocins from lactic acid bacteria isolated from meat.

Ten strains of bacteriocin-producing lactic acid bacteria were isolated from retail cuts of meat. These 10 strains along with 11 other bacteriocin-producing lactic acid bacteria were tested for inhibitory activity against psychotrophic pathogens, including four strains of Listeria monocytogenes, two strains of Aeromonas hydrophila, and two strains of Staphylococcus aureus. Inhibition due to acid, hydrogen peroxide, and lytic bacteriophage were excluded. The proteinaceous nature of the inhibitory substance was confirmed by demonstration of its sensitivity to proteolytic enzymes. Eight of the meat isolates had inhibitory activity against all four L. monocytogenes strains. Bacteriocin activity against L. monocytogenes was found in all of the strains obtained from other sources. Activity against A. hydrophila and S. aureus was also common.     

Proteolytic Enzyme Preparation from Pseudomonas fragi: Its Action on Pig Muscle

An extracellular preparation from Pseudomonas fragi with proteolytic enzyme activity was isolated, and its action on meat proteins and meat protein ultrastructure was studied. First, a suitable growth medium for proteolytic enzyme production was determined, and a method for partial purification of the proteolytically active fraction was developed. The enzyme preparation displayed optimal proteolytic activity at neutral pH and 35 C. Proteolytic activity was irreversibly lost by mild heat treatment. The enzyme preparation was tested for its ability to hydrolyze isolated pig muscle proteins. Myofibrillar protein was rapidly degraded, G-actin and myosin were broken down at a slower rate, and the sarcoplasmic proteins were least susceptible to hydrolysis. Electron micrographs of pork muscle showed that the proteolytic enzyme preparation caused a complete loss of dense material from the Z line. Similarities are discussed between the action of P. fragi extracellular proteolytic enzyme(s) on meat and normal bacterial spoilage of meat.     

Inhibitory Effect of an Antimicrobial Preparation from Lipids of Marine Fishes on Tissue and Microbial Enzymes

A new food preservative from marine fish lipids, was obtained possessing pronounced activity in relation to bacteria and microscopic fungi. The effects of this preparation on enzymes of microorganisms and muscle tissue of marine hydrobionts were studied. In vitro, the preparation irreversibly inhibited acid and alkaline proteases and proteolytic and lipolytic enzymes of microorganisms and reduced enzyme activity in fish muscle tissue. The inhibitory effect of this preparation on enzymes contributes to stabilization of hydrolytic processes in meat of hydrobionts and suppresses microorganism growth during storage.     

Inhibitory effect of antimicrobial preparation from lipids of marine fishes on tissue and microbial enzymes

We obtained a new food preservative from marine fish lipids possessing pronounced activity in relation to bacteria and microscopic fungi. The effects of this preparation on enzymes of microorganisms and muscle tissue of marine hydrobionts were studied. In vitro the preparation irreversibly inhibited acid and alkaline proteases and proteolytic and lipolytic enzymes of microorganisms and reduced enzyme activity in fish muscle tissue. The inhibitory effect of this preparation on enzymes contributes to stabilization of hydrolytic processes in meat of hydrobionts and suppresses microorganism growth in storage.     

Plasmid-associated bacteriocin production by a strain of Carnobacterium piscicola from meat.

Carnobacterium piscicola LV17 isolated from vacuum-packed meat produces bacteriocin(s) that is active against closely related lactic acid bacteria, Enterococcus spp., and a strain of Listeria monocytogenes but not against gram-negative bacteria. The bacteriocin has a bactericidal mode of action, is heat resistant, and is stable over a wide range of pH but is inactivated by proteolytic enzymes. Sensitive and resistant cells were shown to adsorb the bacteriocin, but cell death depended on contact of the bacteriocin with the cell membrane. Bacteriocin production is detected early in the growth cycle of the organism in APT broth, but it is not produced in APT broth adjusted to pH 5.5. Bacteriocin production and resistance to the bacteriocin produced are associated with two plasmids of 40 and 49 megadaltons. The possibility that two bacteriocins are produced is indicated because the inhibitory substances of the mutant strains containing either the 40- or 49-megadalton plasmids have different antimicrobial spectra.     

Plasmid-associated bacteriocin production by a strain of Carnobacterium piscicola from meat

Carnobacterium piscicola LV17 isolated from vacuum-packed meat produces bacteriocin(s) that is active against closely related lactic acid bacteria, Enterococcus spp., and a strain of Listeria monocytogenes but not against gram-negative bacteria. The bacteriocin has a bactericidal mode of action, is heat resistant, and is stable over a wide range of pH but is inactivated by proteolytic enzymes. Sensitive and resistant cells were shown to adsorb the bacteriocin, but cell death depended on contact of the bacteriocin with the cell membrane. Bacteriocin production is detected early in the growth cycle of the organism in APT broth, but it is not produced in APT broth adjusted to pH 5.5. Bacteriocin production and resistance to the bacteriocin produced are associated with two plasmids of 40 and 49 megadaltons. The possibility that two bacteriocins are produced is indicated because the inhibitory substances of the mutant strains containing either the 40- or 49-megadalton plasmids have different antimicrobial spectra.     

Effects of environmental conditions on microbial proteolysis in a pork myofibril model system

P.M. KENNEALLY, N.G. FRANSEN, H. GRAU, E.E. O'NEILL & E.K. ARENDT.1999.A number of bacterial strains used for meat fermentations were screened for proteolytic activity. A strain of Micrococcus which was found to be proteolytic was evaluated for the effects of environmental conditions on its proteolytic activity against pork myofibrillar proteins using response surface methodology. Three strains of micrococci were also tested for the ability to produce free amino acids from pork myofibrils. Analysis of the effects of environmental conditions showed that proteolytic activity would be minimal under conditions normally found in fermented sausages, thereby suggesting that proteolysis in these products is largely due to endogenous meat enzymes. The three strains of micrococci were shown to produce free amino acids from pork myofibrils, thereby demonstrating the presence of peptidase activity in these strains.     

乳酸链球菌素的分子结构、抗菌活性及基因工程研究

乳酸链球菌素(Nisin)是一种由34个氨基酸组成的天然抗菌素,对革兰氏阳性菌具有广谱抑菌作用。Nisin通过吸附于细胞膜,在膜上形成孔洞杀菌。Nisin的11个基因形成基因簇,负责其翻译后修饰、转运,先导序列的切除,成熟分子的外泌,合成过程的调节等。Nisin高产菌株的选育主要通过物理化学诱变,基因工程高效表达技术的研究刚刚开始。Nisin在食品和医药领域具有广泛的应用。本文主要就Nisin的分子结构、分泌机制、抗菌活性、作用机理,特别是它的基因工程技术研究进展等作一概述。     

Proteolytic Activity of Microorganisms Isolated from Freshwater Fish

A raw fish-juice was prepared and sterilized through the use of (60)Co gamma-irradiation. It was evaluated for suitability in an agar medium for testing the proteolytic activity of bacteria isolated from fish. Microorganism proteolytic activity was also detected by conventional methods with skim milk-agar. We tested 1,145 isolates from fresh and spoiling irradiated (0.0, 0.3, and 0.6 Mrad) yellow perch fillets for proteolytic activity, by the use of both media. Most isolates that showed proteolytic activity exhibited this activity in both media. A few isolates showed proteolytic activity only in one medium or the other. Proteolysis was found mainly among bacteria isolated from nonirradiated perch fillets. Nonproteolytic organisms were slightly more abundant than were proteolytic ones throughout refrigerated storage (6 days); the latter constituted 48% of the total organisms. Irradiation eliminated essentially all proteolytic bacteria when the fillets were stored at 1 C. However, some proteolytic bacteria survived for a few days after irradiation when the fillets were stored at 5 C.     

Chitin purification from shrimp wastes by microbial deproteination and decalcification

Chitin was purified from Penaeus monodon and Crangon crangon shells using a two-stage fermentation process with anaerobic deproteination followed by decalcification through homofermentative lactic acid fermentation. Deproteinating enrichment cultures from sewage sludge and ground meat (GM) were used with a proteolytic activity of 59 and 61 mg N l(-1) h(-1) with dried and 26 and 35 mg N l(-1) h(-1) with wet P. monodon shells. With 100 g wet cells of proteolytic bacteria per liter, protein removal was obtained in 42 h. An anaerobic spore-forming bacterium HP1 was isolated from enrichment GM. Its proteolytic activity was 76 U ml(-1) compared to 44 U ml(-1) of the consortium. Glucose was fermented with Lactobacillus casei MRS1 to lactic acid. At a pH of 3.6, calcium carbonate of the shells was solubilised. After deproteination and decalcification of P. monodon or C. crangon shells, the protein content was 5.8% or 6.7%, and the calcium content was 0.3% or 0.4%, respectively. The viscosity of the chitin from P. monodon and C. crangon was 45 and 135 mPa s, respectively, whereas purchased crab shell chitin (practical grade) had a viscosity of 21 mPa s, indicating a higher quality of biologically purified chitin.     

Isolation of proteolytic rumen bacteria by use of selective medium containing leaf fraction 1 protein (ribulosebisphosphate carboxylase)

The principle proteolytic bacteria isolated from bovine rumen contents by virtue of the ability to obtain nitrogen from the proteolysis of leaf fraction 1 protein (ribulosebisphosphate carboxylase, EC 4.1.1.39) were identified as Streptococcus bovis and Butyrivibrio spp. Substitution of fresh fodder, rich in soluble protein, for a hay-concentrates diet resulted in enhanced ruminal proteolytic activity and a significant increase in the number of bacteria able to use fraction 1 protein as the sole nitrogen source. Isolated proteolytic bacteria degraded fraction 1 protein and casein readily. Bovine serum albumin was attacked by Butyrivibrio spp. but was resistant to proteolysis by the streptococci.     

Functional,antioxidant and antibacterial properties of protein hydrolysates prepared from fish meat fermented by Bacillus subtilis A26

Composition, functional properties and in vitro antioxidant and antibacterial activities of protein hydrolysates prepared with a proteolytic bacterium, Bacillus subtilis A26, through fermentation of fish proteins were investigated. Fermented fish meat protein hydrolysates (FPHs) were prepared from sardinelle (SPH), zebra blenny (ZPH) goby (GPH) and ray (RPH). The protein content of freeze-dried FPHs ranged from 74.3% to 81%. All fermented hydrolysates had an excellent solubility and possessed interfacial properties. The antioxidant activities of FPHs were evaluated by different methods, including 1,1-diphenyl-2-picrylhydrazyl (DPPH) radical method, reducing power assay, β-carotene bleaching and DNA nicking assay. All hydrolysates showed dose-dependent antioxidant activities. Further, FPHs exhibited antibacterial activity and SPH was the most effective, particularly against Gram positive bacteria.     

Isolation of proteolytic rumen bacteria by use of selective medium containing leaf fraction 1 protein (ribulosebisphosphate carboxylase).

The principle proteolytic bacteria isolated from bovine rumen contents by virtue of the ability to obtain nitrogen from the proteolysis of leaf fraction 1 protein (ribulosebisphosphate carboxylase, EC 4.1.1.39) were identified as Streptococcus bovis and Butyrivibrio spp. Substitution of fresh fodder, rich in soluble protein, for a hay-concentrates diet resulted in enhanced ruminal proteolytic activity and a significant increase in the number of bacteria able to use fraction 1 protein as the sole nitrogen source. Isolated proteolytic bacteria degraded fraction 1 protein and casein readily. Bovine serum albumin was attacked by Butyrivibrio spp. but was resistant to proteolysis by the streptococci.     

The Effect of Cultural Procedures on the Attachment of Bacteria to Chicken Breast Meat

Various bacterial strains were cultured in a laboratory medium, on chicken breast meat or derived from faeces of orally infected chicks. Suspensions of these bacterial cultures were brought in contact with chicken breast meat. The way in which the bacteria were cultured had little influence on the number of bacteria which attached to the chicken breast meat surface or on as the strength of attachment ( i.e. the easiness of removal of attached bacteria). Only bacteria from the faeces of freshly infected chicks (24 h after inoculation) attached in higher numbers (more than one log₁₀ unit) and these were less easy to remove.     

New method to study bacterial adhesion to meat.

A new method was developed for the study of bacterial adhesion to meat surfaces. Thin slices of meat (40 microns thick) were inserted into a specially designed observation chamber. The meat slices were then exposed to a bacterial suspension (ca. 10(6) CFU.ml-1) to initiate adhesion (20 min of contact time) and subsequently rinsed to eliminate nonadherent bacteria. Because of the special chamber design, the disruptive force exerted on the bacteria during rinsing (shear stress) was uniform over the whole surface of the meat slices, was constant, and could be varied from 0 to 0.08 N.m-2. After being rinsed, the meat slices were stained with basic fuschin and observed under light microscopy to determine the number and distribution of adherent bacteria. This new method was used to study the adhesion of Acinetobacter strain LD2, a Lactobacillus sp., and Pseudomonas fluorescens to slices of beef fat and tendon. At 25 degrees C, most (greater than or equal to 99.9%) of the cells of the Lactobacillus sp. deposited on the meat were washed off the surface during rinsing (0.05 N.m-2), whereas a large number (ca. 10(5) CFU.cm-2) of Acinetobacter strain LD2 and P. fluorescens cells remained adherent. The extent of adhesion was similar on fat and tendon, and adherent bacteria were distributed evenly over the whole surface of the slices. This preliminary study indicates that the combined use of thin slices of meat and of the observation chamber provides us with the means to more accurately study bacterial adhesion to meat surfaces.     

Proteolytic activity of sourdough bacteria

Summary Proteolytic activity during the fermentation of sourdough results in an increase in amino acid content. The proteolysis is caused by flour enzymes, microbial enzymes of flour and by sourdough bacteria. The results indicate that the lactic acid bacteria of sourdough are important for proteolytic activity during the fermentation of sourdough. This proteolytic activity depends on the species of bacteria. Homo- and heterofermentative sourdough bacteria effect different amino acid spectra. Qualitative and quantitative differences in sulphur-containing, cyclic and hydroxy amino acids have been observed. The proteolytic process can be influenced by fermentation conditions, especially the temperature. A lesser effect is observed in the dough yield (flour-water relationship). From experiments with different strains and species of lactic acid bacteria, it is concluded that only one third of the proteolytic activity in sourdough is based on proteases from the flour.Publication-No. 5592 of Federal Research Centre for Cereal and Potato Processing, Detmold, Federal Republic of GermanyPaper presented at the Third International Conference Rye and Triticale, Poznan, Poland, 13–14 May 1987