Masters Degrees (Genetics)

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Autolytic characterization of selected Enterococcal strains, (previously Streptococcal)
(2007) Sukkhu, Melisha.; Beukes, Mervyn.
Autolysins are enzymes that cleave specific structural components within the bacterial cell wall. They contribute to numerous cellular activities such as cell growth, cell division, peptidoglycan recycling and turnover. In this study, twelve Enterococcal isolates (previously from the genus Streptococcus) were examined for susceptibility to the antibiotics Penicillin G and Vancomycin, using a Disk Diffusion and a Microtitre plate assay. In both methods, all twelve strains were resistant to Vancomycin. Six of these strains were susceptible to Penicillin G. The minimum inhibitory concentration (MIC) values were twice that of the disk diffusion assay values. In the presence of antibiotic, the growth rates for the six strains were halved. Autolysins were extracted from the respective cell cultures using a 4% SDS precipitation method. The protein concentrations were calculated and estimated to be within the range of 5.47- to 6.35 μg/μl. Profiles of the SDS precipitate were analyzed on SDS-PAGE. Autolytic proteins were identified and partially analyzed by renaturing SDS-PAGE (zymograms) using gels containing cell wall substrate. Seven lytic bands of molecular weights 25, 30, 50, 63, 75 95 and 145 kDa (designated Autolysin A to G, respectively) were selected for further analysis. The temporal distribution of the enzymes ranged from the mid exponential phase to the early death phase. The seven proteins were blotted onto polyvinylidene difluoride (PVDF) membranes and excised for N-terminal sequencing. Blast analysis of the respective N-terminal sequences showed autolysins A, C, D, E and F to have 100% similarity to the muramidase, amidase and peptidase from S. cremoris, S. suis, S. pneumonia, S. pyogenes and E. faecium, respectively. Biochemical characterization confirmed autolysins A, B, E and F to exhibit muramidase activity, and autolysin C and G to exhibit peptidase activity. Autolysin D displayed 100% similarity to the protein LytA, a peptidoglycan hydrolase that is known to exhibit amidase activity. Blast analysis could not determine any significant similarities for autolysins B and G to previously identified autolysins, thus indicating they may perhaps be novel autolysins.
Characterisation of antibiotic resistance in Streptococcus, Enterococcus and Staphylococcus using a bioinformatics approach.
(2005) Ramsuran, Veron.; Beukes, Mervyn.
The rate at which bacterial pathogens are becoming resistant to antibiotics is quite alarming, and therefore much attention has been focussed on this area. The mechanism whereby the bacterial cells acquire resistance is studied in order to determine how this process works as well as to determine if any future resistance mechanisms can be circumvented. In this study three different genera and the antibiotics that are resistant to them were used, namely, penicillin resistant Streptococcus, vancomycin resistant Enterococcus and methicillin resistant Staphylococcus. The results prove that the active sites SXXK, SXN and KT(S) G in the penicillin resistance Streptococcus plays a major role in resistance. It is seen in this study that the SXXK active site is found in all the resistant and most of the intermediate strains, therefore proving to be an important component of the cell wall resistance. It was subsequently noticed the greater the number of mutations found in the sequences the higher the resistance. Three dimensional structures showed the actives sites and their binding pockets. The results also show the change in conformation with a mutation in the active site. The results also proved that the Penicillin Binding Protein (PBP) genes essential for resistance are PBP Ia, PBP 2b and PBP 2x. The results obtained, for the vancomycin resistance in Enterococcus study, proved that the VanC and VanE cluster are very much alike and VanE could have evolved from VanC. There is also close similarity between the different ligase genes. The VanX 3D structure shows the position of the critical amino acids responsible for the breakdown of the D-Ala-D-Ala precursors, and the VanA ligase 3D structure shows the amino acids responsible the ligation of the D-Ala-D-Lac precursors. The analysis performed on the methicillin resistance in Staphylococcus study showed that the genes used to confer resistance are very similar between different strains as well as different species.
Characterization of streptococcal infections in KwaZulu-Natal Durban by random amplified polymorphic DNA anaylsis and DNA macrorestriction analysis.
(2004) Madlala, Paradise Zamokuhle.; Beukes, Mervyn.
A collection of 29 clinical streptococcal isolates obtained from the University of KwaZulu-Natal, Medical School, Durban Metro area (South Africa) were studied to establish their penicillin G susceptibility patterns often refered to as minimal inhibitory concentration (MIC) and to determine the genetic diversity among them using two genotyping methods, randomly amplified polymorphic DNA (RAPD) analysis and pulsed-field gel electrophoresis (PFGE) analysis. All isolates with MIC less than or equal to 0.12 µg/ml were considered susceptible, intermediate resistant if MIC was between 0.25 µg/ml and 4 µg/ml and resistant if greater than 4 µg/ml, The percentage of isolates with resistance was relatively high (75.9%), only 10.3% of isolates showed intermediate resistance and 13.8% of the isolates were completely susceptible to penicillin G. Some of the resistant isolates were highly resistant reaching penicillin G MIC levels of 5000 µ/ml. They were speculated to contain Path altered penicillin binding proteins and high level of crosslinking cell wall induced by the gene products of the MurMN operon. RAPD analysis was performed using three primers, MBPZ-1, MBPZ-2, and MBPZ-3, respectively. RAPD analysis allowed for the identification of 27 RAPD types with MBPZ-1 and MBPZ-3 and 26 RAPD types with MBPZ-2. Ninety-eight percent of these isolates were clustered into two groups, group I and group II, with 90% to 100% dissimilarity among them. Fifty two percent of the isolates of MBPZ-1 group I were in MBPZ-2 group I, 72% isolates of MBPZ-1 group I were in MBPZ-3 group I, and 72% of the isolates of MBPZ-2 group I were in MBPZ-3 group 1. This shows the discriminatory ability of the primers used in this study. Despite clustering of isolates, relatively high diversity was seen. PFGE analysis of macrorestriction fragments obtained after digestion of chromosomal DNA by restriction enzyme, SmaI showed 24 PFGE patterns. The 24 PFGE patterns were divided into three groups (I, II and III) of isolates, with an average of 85% dissimilarity (15% homology) among them. At 25% homology, four clusters, A (13 isolates), B (9 isolates), C (4 isolates), and D (4 isolates) were observed. Two pairs of isolates in group I, cluster A, showed 100% homology. This suggested that each represent the same strain. Four isolates of group I, cluster B, also exhibited 100% homology. This study showed that most of streptococcal isolates with the same penicillin G susceptibility patterns grouped together in a phylogenetic tree by both RAPD and PFGE analysis. There was also some similarity between the results obtained by RAPD analysis and PFGE analysis. Seventeen and nine of the 29 isolates grouped into group I and group II, respectively, two pairs of isolates were indistinguishable, and two pairs of islates were closely related by both RAPD (using MBPZ-3) and PFGE analysis. Although, RAPD analysis is sensitive, specific, faster and cost effective, the ease with which PFGE analysis can be performed, high discriminatory power, reproducibility of the results, and the polymorphism seen in the patterns, suggests that PFGE method has the potential to be very useful for epidemiological evaluations of nosocomial streptococcal infections in KwaZulu-Natal.
Characterization of the autolytic systems in selected streptococcal species.
(2005) Naidoo, Kershney.; Beukes, Mervyn.
Autolysins are endogenous enzymes responsible for the cleavage of specific bonds in the bacterial sacculus resulting in damage to the integrity and protective properties of the cell wall. The true biological functions of these enzymes are largely unknown. However, they have been implicated in various important biological synthesis processes making their characterization important. Antibiotic susceptibility testing showed these streptococcal strains to have broad spectrum inhibitory concentrations. The major autolysins of selected streptococcal strains were detected and partially characterized by renaturing sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis with substrate-containing gels (zymograms). The autolysins were isolated from the specific culture supematants using 4% SDS precipitation and were shown to have apparent molecular masses ranging from 60kDa to 20kDa. Four major autolysins named A, B, C, and D from the Streptococcus milleri 77 strain were characterized. Lytic enzymes were blotted onto polyvinylidene difluoride (PVDF) membrane and N-terminally sequenced. Sequences showed between 100% and 80% similarity to that of a muramidase, glucosaminidase and a peptidase from S. mutans, S. pyogenes and S. pneumonia respectively. Biochemical characterization confirmed autolysin A to exhibit muramidase activity with both autolysin Band C exhibiting endopeptidase activity. Autolysin D showed an 80% N-terminal sequence similarity to Millericin B, a peptidoglycan hydrolase that is known to exhibit peptidase activity. Autolysis was determined using different buffers at two optimal pHs. Assaying for autolytic activity at different growth stages showed autolysis to be moderate during the lag and early exponential phases of the growth cycle. The activities of autolysins were the highest in the late exponential phase and the stationary phase of growth. Zymogram analysis showed that the Streptococcal milleri strains had moderate autolytic expression during the early and late exponential phases of the growth cycle. Control regulatory mechanisms of autolysins were determined in the presence or absence of specific charged groups, such as teichoic acids. In each case the absence of these charged groups inhibited the rate of autolysis, suggesting that the absence of teichoic acids could play a role in the regulation of the autolysins. Two-dimensional-SDS and zymographic-electrophoresis was used to determine total protein profiles for each strain. This is the first report using twodimensional zymography. Specific proteins which were either up- or down-regulated were identified.
Cloning, expression and purification of the immunity factor associated with leucocin A production.
(2004) Pillay, Kovashni.; Beukes, Mervyn.
Leucocin A is a bacteriocin produced by Leucoconostoc gelidium UAL 187-22. Bacteriocin producer strains possess an immunity protein, which enables the strain to protect itself against its own bacteriocin. The immunity gene from Leucoconostoc gelidium was isolated via PCR from a recombinant clone pJF5.5. This fragment was cloned by amplifying the immunity gene from pJF5.5 and ligating it into pMALc2. The resulting recombinant plasmid pKP1 was then transformed into Escherichia coli strain JM103. The clone putative, was confirmed by DNA sequencing and southern blot hybridization using the primers EAL-2 and EAL-3. It was shown to contain an insert of 3.6 kb. Expression analysis showed the construct as an in frame malE fusion protein expressed within E. coli. The fusion construct was isolated by affinity chromatography. Leucocin A was purified to 90% purity, from the supernatant of Leucocnostoc gelidium UAL 187-22 by ion-exchange chromatography and HPLC. It was found to elute from a C18 reverse phase column at 55% actetonitrile, 0.1% TFA. Binding interaction and the stability of the immunity gene fusion protein were compared using a Biacore 2000. The supernatant and cytoplasmic extract isolated from Leucocnostoc gelidium UAL 187-22 were tested for interaction with the fusion construct. Surface Plasmon resonance studies indicated that there was no binding partner present in the supernatant which would influence the immunity process. However, a stable interaction was found between the immunity protein and an orphan ligand within the cytoplasm.
Cloning, expression and purification of the subunits of the Mannose PTS Permease of Listeria monocytogenes EGD.
(2010) Mia, Rizwana.; Beukes, Mervyn.; Watson, Gregory M. F.
The disease listeriosis is caused by Listeria monocytogenes. This common food-borne disease has been responsible for about 0.1 to 10 cases per million inhabitants per year. However, this disease is serious with its high fatality rates of 20% - 30%, and 40% of all cases reported have been in pregnant women suffered from a foetal abortion. Recently the organism has acquired resistance to antibiotic treatment and the development of an alternative treatment is necessary. Class IIa bacteriocins such as leucocin A have been shown to be active against L. monocytogenes. However, the leucocin A receptor molecule responsible for growth inhibition within L. monocytogenes remains unclear. Various studies have implicated the mannose PTS permease (EIIt Man) of L. monocytogenes as the putative receptor for class IIa bacteriocins. The results from studies reviewed indicate that the EIIt Man of L. monocytogenes could be the chiral receptor needed for bacteriocin interaction at the surface of targeted cells. Specifically, the membrane associated IIDMan and IICMan subunits were implicated in direct interaction with class IIa bacteriocins. Our study focused on cloning, expression and purification of the subunits of the mannose PTS permease of L. monocytogenes EGD. Primers were designed to amplify the subunit genes of the mptACD operon. The mptC, mptD and mptAB genes which were then successfully cloned into pET28a expression vector and transformed into E. coli JM109(DE3) host strain. Recombinant plasmids were screened using colony PCR. Subsequently recombinant pET28-C, pET28-D and pET28-AB was once again transformed and expressed in the E. coli BL21(DE3) pLysS expression host strain. After an induction at 30°C for 5 hours, IICMan and IIDMan were found to be expressed in the cell membrane, whilst IIABMan was expressed in the cytosol of the host expression strain. Membrane proteins His-IICMan, His- IIDMan, and cytosol associated His-IIABMan were purified using Ni2+-NTA affinity chromatography. Results for His-IICMan yielded a 28 kDa protein and a 55 kDa co-purified protein. Results for His-IIDMan yielded a 31 kDa protein and a 60 kDa co-purified protein. Results for His-IIABMan yielded a 35 kDa protein and a 68 kDa co-purified protein. A western blot analysis revealed that all proteins purified carried an attached His-tag as detected by an anti-mouse peroxidase conjugate anti-His-tag antibody.
The elucidation of the possible mechanism of vancomycin-resistance in selected streptococcal and enterococcal species.
(2005) Desai, Rizwana.; Beukes, Mervyn.
Three Streptococcal strains: S. milleri P213, S. milleri P35 and S. milleri B200 and three enterococcal strains: E. faecalis 123, E. faecalis 126 and E. faecium were used to test for vancomycin resistance. Two strains were used as reference strains that were already characterized as vancomycin resistant. E. faecium BM4147 was used as a VanA control and E. faecalis ATCC was used as a VanB control. Susceptibility of each strain to this antibiotic was tested by disk-diffusion assay and the MIC values for the strains were found to be between 5 - 10 ug/ml and for the VanA control, the MIC was > 64 ug/ml and for the VanB control was 32 ug/ml. These MIC values indicate that S. milleri P213, S. milleri P35, S. milleri B200, E. faecalis 123, E. faecalis 126, and E. faecium are all of the VanC phenotype. All strains were tested for lysis by means of addition of vancomycin (10 ug/ml) to the bacterial cultures. Lytic curves were constructed and the VanB control was found to be most autolytic upon addition of vancomycin and E. faecalis 123 was the least autolytic. However, under normal conditions in phosphate buffer, lytic curves showed that S. milleri P213 was the most autolytic and the VanA control, the least autolytic. PCR assays were performed to detect specific antibiotic resistant genes. Primers were selected from Dukta-Malen et al., 1995. The VanA primer yielded amplification of 732 bp for only the VanA control DNA and the VanB primer set yielded products for the VanB control DNA. S. milleri P213, P35, B200 and E. faecalis 123 and 126, and E. faecium DNA were amplified with the VanC primers. This supports the results obtained in MIC that these strains are possibly VanC resistant strains. Amplified VanA control and that of E. faecalis 126 were thereafter sequenced. VanA control amplicon was correctly amplified since it showed homology to E. faecium BM4147 as well as the VanB amplicons which was found to be homologous to the transposon Tn1549 found on the well-characterized E. faecalis strain which is known to harbour the VanB vancomycin-resistant genes. Whilst E. faecalis 126 which represented the VanC phenotype showed 96% homology to E. gallinarum BM4147 which is a well-characterized glycopeptide-resistant enterococci belonging to the VanC phenotype. Southern blots were performed using specific primers as a probe to verify whether the gene sequences for the specific genotype were present in these strains and results confirmed those found in the PCR assays and in DNA sequencing. The peptidoglycan precursors of each strain were arrested in vancomycin (20 ug/ml) to block transpeptidation and transglycosylation steps of peptidoglycan synthesis and bacitracin (100 ug/ml) was used to amplify precursors at the transglycosylation step. Precursors were extracted and analysed by reverse-phase HPLC. UDP-MurNAc-tetrapeptides cell wall precursors, which are found abundantly in vancomycin-resistant strains, were found in large proportions in all strains, except in E. faecalis 123 when arrested with vancomycin. This precursor has a noticeably decreased affinity for vancomycin, hence contributing to its resistance. The precursor accumulated when arrested with bacitracin, was, UDPMurNAc-tetrapeptide in all strains except in E. faecalis 126. UDP-MurNAc-pentapeptides were also found in moderate amounts in most strains. The molecular masses of the peptidoglycan precursors obtained from mass spectrometry correctly identified them. This confirmed that the bacterial strains investigated were in fact resistant to the antibiotic vancomycin and this study shows that results obtained from conventional phenotypical screening methods reliably correlated with the genotypes classified using more advanced techniques such as PCR, southern blot/hybridisation and DNA sequencing.
The influence of the leader sequence on antimicrobial activity of Leucocin A, an antilisterial bacteriocin produced by Leuconostoc gelidum UAL187-22.
(2008) Reddy, Jiren.; Beukes, Mervyn.
Bacteriocin leader pepides are currently receiving much attention due to their possible functions. It is predicted that these leaders prevent cytoplasmic toxicity within the producer organism by rendering the bacteriocin inactive. Leucocin A, a class IIa bacteriocin produced by Leuconostoc gelidum UAL187-22 is synthesized with a 24 amino acid leader pepide which is cleaved during extracellular translocation. The antimicrobial activity of the leucocin A precursor, pre-leucocin A, was determined to gain insight into whether, the presence of a leader peptide has an impact on anti-listerial activity. The leucocin A and pre-leucocin A genes were generated by PCR of L. gelidum UAL187-22 plasmid DNA. Recombinant plasmids, pLcaA and pPreLcaA were isolated by cloning the amplified genes into the Escherichia coli pMAL.c2 vector, and by screening transformant colonies using blue white selection methods. The malE-LcaA and malE-preLcaA fusion genes were expressed, and resulting maltose binding fusion proteins, were purified using amylose affinity chromatography. Fractions collected, contained partially pure forms of MBP-LcaA (46.433 kDa) and MBP-preLcaA (49.088 kDa) fusion proteins. Following Factor Xa digestion, the MBP affinity tag was removed; and recombinant peptides, leucocin A and pre-leucocin A were further purified by reverese phase high performance liquid chromatography. It was determined that leucocin A was eluted with a retention time of 24.893, while pre-leucocin A was eluted with a retention time of 31.447. Fractions of pure leucocin A and pre-leucocin A were thereafter assayed for activity using a deferred antagonism assay, with Listeria monocytogenes being the indicator strain. Pre-leucocin A tested positive for antimicrobial activity. However, when compared to leucocin A it was found that the leucocin A precursor inhibits Listeria to a lesser degree than leucocin A. The relative bactericidal activities of leucocin A and pre-leucocin A was calculated at 6.0 x 10⁵ AU and 4.0 x 10⁵ AU. Taking this into consideration, it was estimated that the leucocin A precursor is ~66.667 % active as mature leucocin A. Hence the presence of a leader peptide does not have an influence on leucocin A antimicrobial activity.
Molecular characterization of selected enterococcus strains (previously streptococcus) using genotyping techniques.
(2007) Jugdave, Abhita.; Beukes, Mervyn.
The genus Enterococcus comprises of a group of commensal organisms of the human gut which has been associated with cases of endocarditis and urinary tract infections. In the present study, 12 Enterococcus isolates were obtained from clinical specimens and characterized using genotyping techniques that have become an integral part of clinical research. There were three different genotyping methods used to identify the enterococci to species level and to determine the level of genetic diversity among the selected strains. These techniques were, randomly amplified polymorphic DNA-PCR (RAPD-PCR), 16S rDNA ribotyping analysis and pulse field gel electrophoresis (PFGE) respectively. The minimum inhibitory concentration (MIC) to penicillin and vancomycin were also determined using a disc diffusion assay and a microtitre plate dilution assay. All twelve strains were found to be vancomycin resistant enterococci (VRE) at a MIC value greater than 100μg/ml. Penicillin growth inhibition based on MIC values were categorized into three groups, susceptible (< 0.25 μg/ml), intermediate (≤ 3μg/ml) and resistant (≥ 4μg/ml) respectively. RAPD-PCR was performed using four random primers. Primers yielding the highest discriminative power were used for phylogenetic analysis. The phylogenetic analysis indicated that all 12 strains yielded clonal dissemination, therefore a low genetic diversity between them. The 16S rDNA of all strains were used to identify the enterococci at species level. The rDNA were sequenced and analysed using the NCBI BLAST algorithm and found to belong to three species of Enterococcus. These were E.faecalis, E.faecium and E.durans. PFGE analysis was performed by restriction of all 12 strain’s genomic DNA with the restriction enzyme SmaI. The PFGE patterns were divided into two groups with low genetic diversity. Compared with the RAPD PCR patterns PFGE gives a higher discriminatory power as a higher dissimilarity between the strains was observed. Similar penicillin MICs for each of the strains in the three categories are grouped together in the phylogenetic trees for both PFGE and RAPD-PCR. RAPDPCR is a sensitive, faster, specific and cost effective technique, PFGE analysis has given a higher discriminatory power, higher reproducibility of the results and the polymorphism seen in the patterns suggest that PFGE has a potential of being an essential tool in clinical diagnostics.

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