[Production of a recombinant CagA protein for the detection of Helicobacter pylori CagA antibodies]. / Helicobacter pylori CagA antikorlarinin saptanmasi için rekombinant bir CagA proteininin üretilmesi.

At present, Helicobacter pylori infections affect approximately 50% of the world population. It is known that H.pylori is related with several gastric diseases including chronic atrophic gastritis, peptic and gastric ulcers as well as gastric carcinomas. CagA (Cytotoxin-associated gene A) protein which is one of the most important virulence factors of H.pylori, is thought to be responsible for the development of gastric cancer. CagA is a 128 kDa hydrophilic protein which binds to the epitelial stomach cells and is known to be phosphorylated on its EPIYA regions. The EPIYA regions are highly variable and carry a higher risk of developing gastric cancer than CagA negative strains. The aim of this study was to construct a prokaryotic expression system expressing a recombinant CagA protein, which can be used for the detection of anti-CagA antibodies. For the isolation of H.pylori genomic DNA, a total of 112 gastric biopsy samples obtained from patients who were previously found positive for rapid urease (CLO) test, were used. H.pylori DNAs were amplified from 57 of those samples by polymerase chain reaction (PCR) and of them 35 were found positive in terms of cagA gene. Different EPIYA motifs were detected in 25 out of 35 cagA positive samples, and one of those samples that contained the highest number of EPIYA motif, was chosen for the cloning procedure. Molecular cloning and expression of the recombinant fragment were performed with Champion Pet151/D expression vector (Invitrogen, USA), the expression of which was induced by the addition of IPTG (Isopropyl-beta-D-thiogalactopyranoside) into the E.coli culture medium. Expression was observed with anti-histidin HRP (Horse Radish Peroxidase) antibodies by SDS-PAGE and Western Blot (WB) analysis. In our study, two clones possessing different fragments from the same H.pylori strain with three different EPIYA motifs were succesfully expressed. Since CagA antigen plays a signicant role in the pathogenesis of H.pylori infections, the detection of anti-CagA antibodies done by non-invasive commercial ELISA or WB methods, is important in diagnosis. Recombinant CagA protein produced in this study could easily be used in the ELISA tests to be developed for screening anti-CagA antibodies in the patients' sera. However, since an ELISA method using this antigen has not been developed yet, its diagnostic performance could not be evaluated in this study. In conclusion, the construction of such a system for recombinant CagA antigen expression may be a pilot study for the development of our own ELISA tests in Turkey, and also will help the clinicians for the prediction of disease outcome and decision of the appropriate antimicrobial treatment by the help of anti-CagA antibody detection.

The effect of mesenchymal stem cells administration on DNA repair gene expressions in critically ill COVID-19 patients: prospective controlled study.

When the studies are evaluated, immunomodulatory effect of MSCs, administration in critically ill patients, obstacle situations in use and side effects, pulmonary fibrosis prevention, which stem cells and their products, regeneration effect, administration route, and dosage are listed under the main heading like. The effect of MSC administration on DNA repair genes in COVID-19 infection is unknown. Our aim is to determine the effect of mesenchymal stem cells (MSCs) therapy applied in critically ill patients with coronavirus infection on DNA repair pathways and genes associated with those pathways. Patients (n = 30) divided into two equal groups. Group-1: Patients in a critically ill condition, Group-2: Patients in critically ill condition and transplanted MSCs. The mechanism was investigated in eleven genes of five different pathways; Base excision repair: PARP1, Nucleotide excision repair (NER): RAD23B and ERCC1, Homologous recombinational repair (HR): ATM, RAD51, RAD52 and WRN, Mismatch repair (MMR): MLH1, MSH2, and MSH6, Direct reversal repair pathway: MGMT. It was found that MSCs application had a significant effect on 6 genes located in 3 different DNA damage response pathways. These are NER pathway genes; RAD23 and ERCC1, HR pathway genes; ATM and RAD51, MMR pathway genes; MSH2 and MSH6 (p < 0.05). Two main points were shown. First, as a result of cellular damage in critical patients with COVID-19, DNA damage occurs and then DNA repair pathways and genes are activated in reaction to this situation. Second, administration of MSC to patients with COVID-19 infection plays a positive role by increasing the expression of DNA repair genes located in DNA damage pathways.

Molecular characterization of hepatitis A virus isolated from acute infections in Turkey.

BACKGROUND/AIMS: Hepatitis A virus is a global public health problem, especially in developing countries, and the most common cause of hepatitis in childhood. Hepatitis A virus is a single- stranded positive RNA virus subdivided to 6 genotypes (3 human,3 simian). The aim of this study was to determine the prevalent genotype in Turkey using sera of acute hepatitis A virus-infected patients from different geographical regions of the country. MATERIALS AND METHODS: Sera of 137 patients with acute hepatitis A virus from different geographical regions were collected for phylogenetic analysis. The VP1-2A region of the hepatitis A virus genome was amplified by real-time-polymerase chain reaction in 76 patients where possible. Amplified polymerase chain reaction fragments were sequenced, and phylogenetic analysis was done together with other reference hepatitis A virus sequences obtained from GenBank database. RESULTS: Sequencing and phylogenetic analysis of the VP1-2A junction of hepatitis A virus showed that the most prevalent genotype in Turkey is IB (100%). Comparison of Turkish isolates and reference sequences of genotype IB showed a similarity of 94.9%. The same comparison was done between Turkish isolates and reference hepatitis A virus genotype IB and HM175, and it was found that similarity between them ranged from 93.0-95.9%. When Turkish isolates were compared according to Mean Percentage Nucleotide Distance analysis, similarity ranged between 95.3%-100%. CONCLUSIONS: Phylogenetic analysis pointed out that all Turkish isolates belong to genotype IB. Sequence analysis is a useful tool in revealing hepatitis A outbreaks, and allows us to detect and distinguish the presence of epidemic and small outbreaks.