Paweł Sachadyn

Conservation and diversity of MutS proteins.

The homologues of MutS, mismatch repair protein, exist in all prokaryotes, with the exception of Actinobacteria, Mollicutes and part of the Archaea. Multiple alignments of 316 MutS amino acid sequences from 169 species revealed conserved residues and sequence motifs distinguishing MutS homologues. All MutS homologues show high conservation within the ATPase domain. MutS1, the homologue responsible for DNA mismatch recognition, is common in Archaea and Bacteria. MutS1 is distinguished by the N-terminal mismatch binding domain containing the GXFXE motif shared by all MutS1 homologues and MSH6 homologues in eukaryotes. Less common than MutS1, MutS2, the suppressor of homologous recombination, is rendered distinctive by the C-terminal Smr endonuclease domain containing the conserved HGXG motif. MutS1 and MutS2 are of enormous significance in maintaining genome integrity. The functions of the other homologues: MutS2-like, MutS3, MutS4, and MutS5 have not yet been found. Each of these homologues exists in a narrower range of taxonomic groups than MutS1 or MutS2 and has neither the mismatch binding nor the Smr domain. The number of different MutS homologues in a single organism usually ranges from one to four; there are rarely five and six only occur exceptionally. The diversity of MutS types and structures begs the question as to how this diversity influenced the evolution of genomes.

Changes in gene methylation patterns in neonatal murine hearts: Implications for the regenerative potential.

BackgroundThe neonatal murine heart is able to regenerate after severe injury; this capacity however, quickly diminishes and it is lost within the first week of life. DNA methylation is an epigenetic mechanism which plays a crucial role in development and gene expression regulation. Under investigation here are the changes in DNA methylation and gene expression patterns which accompany the loss of regenerative potential.ResultsThe MeDIP-chip (methylated DNA immunoprecipitation microarray) approach was used in order to compare global DNA methylation profiles in whole murine hearts at day 1, 7, 14 and 56 complemented with microarray transcriptome profiling. We found that the methylome transition from day 1 to day 7 is characterized by the excess of genomic regions which gain over those that lose DNA methylation. A number of these changes were retained until adulthood. The promoter genomic regions exhibiting increased DNA methylation at day 7 as compared to day 1 are significantly enriched in the genes critical for heart maturation and muscle development. Also, the promoter genomic regions showing an increase in DNA methylation at day 7 relative to day 1 are significantly enriched with a number of transcription factors binding motifs including those of Mfsd6l, Mef2c, Meis3, Tead4, and Runx1.ConclusionsThe results indicate that the extensive alterations in DNA methylation patterns along the development of neonatal murine hearts are likely to contribute to the decline of regenerative capabilities observed shortly after birth. This conclusion is supported by the evidence that an increase in DNA methylation in the neonatal murine heart from day 1 to day 7 occurs in the promoter regions of genes playing important roles in cardiovascular system development.

Conserved motifs of MutL proteins.

The MutL protein is best known for its function in DNA mismatch repair (MMR). However, there is evidence to suggest that MutL is not only the linker connecting the functions of MutS and MutH in MMR, but that it also participates in other repair systems, such as Very Short Patch (VSP), Base Excision (BER) and Nucleotide Excision Repair (NER). This study set out to identify the most highly conserved amino acid sequence motifs in MutL proteins. We analyzed 208 MutL amino acid sequences of 199 representative prokaryotic species belonging to 28 classes of bacteria and archaea. The analysis revealed 16 conserved motifs situated in the ATPase and endonuclease domains, as well as within the disordered loop, and in the MutL regions interacting with the clamp of DNA polymerase III. The conserved sequence motifs thus determined constitute a structural definition of MutL and they may be used in site-directed mutagenesis studies. We found conserved residues within the potential regions where binding with MutS occurs. However, the existing data does not provide clues as to the possible sites of MutL interactions with the proteins involved in other DNA repair systems such as NER, BER and VSP. We determined the 57 most highly conserved amino acid residues, including 43 which were identical in all the sequences analyzed. The greater part of the most predominantly conserved amino acid residues identified in MutL are identical to the corresponding residues reported as mutational hot-spots in one of its human homologues, MLH1, but not in the other, PMS2. This is the first study to present the conserved sequence motifs of MutL widespread in bacteria and archaea and the classification of MutLs into five groups distinguished on the basis of differences in the C-terminal region. Our analysis is of use in better understanding MutL functions.The MutL protein is best known for its function in DNA mismatch repair (MMR). However, there is evidence to suggest that MutL is not only the linker connecting the functions of MutS and MutH in MMR, but that it also participates in other repair systems, such as Very Short Patch (VSP), Base Excision (BER) and Nucleotide Excision Repair (NER). This study set out to identify the most highly conserved amino acid sequence motifs in MutL proteins. We analyzed 208 MutL amino acid sequences of 199 representative prokaryotic species belonging to 28 classes of bacteria and archaea. The analysis revealed 16 conserved motifs situated in the ATPase and endonuclease domains, as well as within the disordered loop, and in the MutL regions interacting with the β clamp of DNA polymerase III. The conserved sequence motifs thus determined constitute a structural definition of MutL and they may be used in site-directed mutagenesis studies. We found conserved residues within the potential regions where binding with MutS occurs. However, the existing data does not provide clues as to the possible sites of MutL interactions with the proteins involved in other DNA repair systems such as NER, BER and VSP. We determined the 57 most highly conserved amino acid residues, including 43 which were identical in all the sequences analyzed. The greater part of the most predominantly conserved amino acid residues identified in MutL are identical to the corresponding residues reported as mutational hot-spots in one of its human homologues, MLH1, but not in the other, PMS2. This is the first study to present the conserved sequence motifs of MutL widespread in bacteria and archaea and the classification of MutLs into five groups distinguished on the basis of differences in the C-terminal region. Our analysis is of use in better understanding MutL functions.

Transcriptome profiling reveals distinctive traits of retinol metabolism and neonatal parallels in the MRL/MpJ mouse.

BackgroundThe MRL/MpJ mouse is a laboratory inbred strain known for regenerative abilities which are manifested by scarless closure of ear pinna punch holes. Enhanced healing responses have been reported in other organs. A remarkable feature of the strain is that the adult MRL/MpJ mouse retains several embryonic biochemical characteristics, including increased expression of stem cell markers.ResultsWe explored the transcriptome of the MRL/MpJ mouse in the heart, liver, spleen, bone marrow and ears. We used two reference strains, thus increasing the chances to discover the genes responsible for the exceptional properties of the regenerative strain. We revealed several distinctive characteristics of gene expression patterns in the MRL/MpJ mouse, including the repression of immune response genes, the up-regulation of those associated with retinol metabolism and PPAR signalling, as well as differences in expression of the genes engaged in wounding response. Another crucial finding is that the gene expression patterns in the adult MRL/MpJ mouse and murine neonates share a number of parallels, which are also related to immune and wounding response, PPAR pathway, and retinol metabolism.ConclusionsOur results indicate the significance of retinol signalling and neonatal transcriptomic relics as the distinguishing features of the MRL/MpJ mouse. The possibility that retinoids could act as key regulatory molecules in this regeneration model brings important implications for regenerative medicine.

A simple modification of PCR thermal profile applied to evade persisting contamination

The polymerase chain reaction (PCR), one of the most commonly applied methods of diagnostics and molecular biology has a frustrating downside known as the false positive signal or contamination. Several solutions to avoid and to eliminate PCR contaminations have been worked out to date but the implementation of these solutions to laboratory practice may be laborious and time consuming. A simple approach to circumvent the problem of persisting PCR contamination is reported. The principle of this approach lies in shortening the steps of denaturation, annealing, and elongation in the PCR thermal cycle. The modification leads to the radical decline of false positive signals obtained for the no-template controls without affecting the detection of target PCR products. In the model experiments presented here, the signal of negative control was shifted by about ten cycles up above those for the examined samples so that it could be neglected. We do not recommend this solution in PCR diagnostics, where the sensitivity of detection is of the highest priority. However, the approach could be useful to pass by the problem of persisting contamination in quantitative PCR, where the range of quantitation is usually much above the limits of detection.

A simple modification to improve the accuracy of methylation-sensitive restriction enzyme quantitative polymerase chain reaction

DNA digestion with endonucleases sensitive to CpG methylation such as HpaII followed by polymerase chain reaction (PCR) quantitation is commonly used in molecular studies as a simple and inexpensive solution for assessment of region-specific DNA methylation. We observed that the results of such analyses were highly overestimated if mock-digested samples were applied as the reference. We determined DNA methylation levels in several promoter regions in two setups implementing different references: mock-digested and treated with a restriction enzyme that has no recognition sites within examined amplicons. Fragmentation of reference templates allowed removing the overestimation effect, thereby improving measurement accuracy.

Transcriptomic Effects of Estrogen Starvation and Induction in the MCF7 Cells. The Meta-analysis of Microarray Results

Estrogen is one of the most important signaling molecules which targets a number of genes. Estrogen levels regulate cell proliferation and a plethora of metabolic processes, which may interfere with a range of medical conditions and drug metabolism. The MCF7 breast cancer cell line, expressing the estrogen receptor α, is a well-studied model of cellular answer to estrogen. The aim of this study was to characterize transcriptomic responses to estrogen in a broad time range. We performed a meta-analysis of microarray data on gene expression in the MCF7 cells under estrogen exposure and deprivation. As the result we distinguished three major phases of transcriptomic response to stimulation with 17β- estradiol: the early (1-2 h), with the activation of the MAPK signaling pathway; the intermediate (3-12 h), with enhanced expression of genes participating in cell surface receptor linked signal transduction and cellular homeostasis; and the late one (24-48 h), with the induction of genes involved in mitotic cell division. Two main phases under estrogen starvation were indicated as the early (1-3 days), with elevated expression of genes associated with cell projection and repression of those responsible for cell cycle regulation, and the late (15-180 days), with increased expression of genes of cell adhesion proteins. The meta-analysis displayed how different gene sets are either induced or repressed following either estrogen exposure or deprivation, and how the gene expression changes are orchestrated by estrogen in time dependent manner, indicating that proper understanding of estrogen impact on transcriptional gene activity requires an extensive time perspective.

Immunophenotyping and transcriptional profiling of in vitro cultured human adipose tissue derived stem cells

Adipose-derived stem cells (ASCs) have become an important research model in regenerative medicine. However, there are controversies regarding the impact of prolonged cell culture on the ASCs phenotype and their differentiation potential. Hence, we studied 10 clinical ASCs replicates from plastic and oncological surgery patients, in six-passage FBS supplemented cultures. We quantified basic mesenchymal cell surface marker transcripts and the encoded proteins after each passage. In parallel, we investigated the differentiation potential of ASCs into chondrocytes, osteocytes and adipocytes. We further determined the effects of FBS supplementation and subsequent deprivation on the whole transcriptome by comprehensive mRNA and miRNA sequencing. Our results show that ASCs maintain differentiation potential and consistent profile of key mesenchymal markers, with apparent expression of distinct isoforms, in long-term cultures. No significant differences were observed between plastic and oncological surgery cohorts. ASCs in FBS supplemented primary cultures are almost committed to mesenchymal lineages as they express key epithelial-mesenchymal transition genes including early mesenchymal markers. Furthermore, combined mRNA/miRNA expression profiling strongly supports a modulatory role for the miR-30 family in the commitment process to mesenchymal lineages. Finally, we propose improvements to existing qPCR based assays that address alternative isoform expression of mesenchymal markers.

Transcriptional profile of in vitro expanded human epidermal progenitor cells for the treatment of non-healing wounds

BACKGROUND Epidermal progenitor cells (EPCs) have been under extensive investigation due to their increasing potential of application in medicine and biotechnology. Cultured human EPCs are used in the treatment of chronic wounds and have recently became a target for gene therapy and toxicological studies. One of the challenges in EPCs culture is to provide a high number of undifferentiated, progenitor cells displaying high viability and significant biological activity. OBJECTIVES The goal of this study was to characterize the in vitro cultured progenitor cells and to assess whether the cells with the progenitor phenotype are able to enhance wound healing. Additionally, we aimed to establish the complete procedure of the culture, analysis and clinical application of epidermal progenitor cells. METHODS In this study we present a method of cell isolation and culture followed by a technique of transplantation of the cultured cells onto the wound bed. The applied isolation technique involves two enzymatic steps (dispase, trypsin) and it is characterized by a high yield of cells. The obtained cells were cultured in vitro up to the second passage in serum-free and xeno-free keratinocytes-dedicated medium. Key stem cell markers were determined with means of flow cytometry and quantitative real-time PCR. RESULTS The in vitro expanded cells displayed high proliferative activity without features of neither apoptosis nor necrosis. The flow cytometry and transcriptomic analyses showed enhanced expression of stem cell markers (i.e. proteins: ΔNp63, CD29, CD49f and BNC1, CDKN1A transcripts) in the expanded cells. In the presented compassionate use study, cultured autologous cells from an oncological patient were suspended in fibrin sealant and transplanted directly to a non-healing wound, resulting in wound closure within 2 months. CONCLUSION The cells cultured in serum-free media display epidermal stem cells features and a potential to stimulate wound healing. This promising procedure of isolation, culture and application warrants further clinical trials in the treatment of chronic wounds.

In vitro affinity of Deinococcus radiodurans MutS towards mismatched DNA exceeds that of its orthologues from Escherichia coli and Thermus thermophilus

The mismatch binding protein MutS is responsible for the recognition of mispaired and unpaired bases, which is the initial step in DNA repair. Among the MutS proteins most extensively studied in vitro are those derived from Thermus thermophilus, Thermus aquaticus and Escherichia coli. Here, we present the first report on the in vitro examination of DNA mismatch binding activity of MutS protein from Deinococcus radiodurans and confront this with the properties of those from E. coli and T. thermophilus. The analyses which included mobility gel-shift assay, colorimetric and qPCR estimation of MutS-bound DNA clearly showed that D. radiodurans MutS exhibited much higher affinity towards mismatched DNA in vitro than its counterparts from E. coli and T. thermophilus. In addition, D. radiodurans MutS displayed a significantly higher specificity of DNA mismatch binding than the two other orthologues. The specificity expressed as the ratio of mismatched to fully complementary DNA bound reached over 4 and 20-fold higher values for D. radiodurans than for T. thermophilus and E. coli MutS, respectively. The results demonstrate mainly the biotechnological potential of D. radiodurans MutS but the in vitro characteristics of the MutS orthologues could reflect substantial differences in DNA mismatch binding activities existing in vivo.