SYSTEMATIC ANALYSIS OF ABC TRANSPORTERS IN STREPTOCOCCUS SANGUINIS

Atia, Sawsan

16 April 2013

The bacterium Streptococcus sanguinis is a primary member of the human oral microflora and also has been recognized as a key player in the bacterial colonization of the mouth. It is considered the most common viridians streptococcal species implicated in infective endocarditis. In all kingdoms of life, ATP binding cassette (ABC) transporters are essential to many cellular functions. Sequencing of the SK36 genome provided the opportunity to study ABC transporter mutants and their relationship with acidity of the oral environment. Despite numerous studies that have focused on carbohydrate uptake systems in closely related streptococcal species such as S. mutans, S. pneumonia and S. pyogenes, the mechanism of the response of these ABC transporters to acidic conditions in S. sanguinis is still unknown. The capability of S. sanguinis to adapt in these harsh environments suggests this bacterium is capable of responding to various environmental stimuli. The purpose of this study was to examine ABC mutants to identify functions that contribute to acid tolerance in S. sanguinis. This study demonstrates that two acid-sensitive mutant genes, SSA_1507 and SSA_1508, identify genes involved in acid tolerance. The two mutants grew on different sugars and none of them showed a defect in sugar utilization at acid pH. We couldn’t recognize any significant differences in sugar uptake for the two acid sensitive mutants or in mutants of their neighboring genes. Thus, the observed acid sensitivity is not due to a failure to take up any of the common sugars tested. The cytoplasmic pH of S. sanguinis was studied with the fluorescent pH indicator (BCECF) and SK36 was observed to have a wider pH range than either of the two acid-sensitive mutants SSA_1507 or SSA_1508. In these two mutants, intracellular pH was not as well maintained. At all pH values tested, the mutants displayed a lower intracellular pH than the wild type. These observations indicate that the cell membrane of these two mutants is unable to protect the interior components from adverse effects of higher pH values and lower pH values, and prove that these two mutant genes SSA_1507 and SSA_1508 are unable to grow in lower pH values. These results support a role for these ABC transporters in proton pump or export and indicate that the mutants are less able to pump out protons.

ABC transporter

Acid stress response

Streptococcus sanguinis

Medicine and Health Sciences

Negative Regulation of Haa1 by Casein Kinase I protein Hrr25 in Saccharomyces cerevisiae

Collins, Morgan

19 May 2017

Haa1 is a transcription factor that adapts Saccharomyces cerevisiae cells to weak organic acid stresses by activating the expression of various genes. How Haa1 is activated by weak acids is not clear. This study proposes that Hrr25 is an important regulator of cellular adaptation to weak acid stress by inhibiting Haa1 through phosphorylation. YRO2, one of the targets of Haa1, shows increase in expression during stationary phase. This increase is due to basal activity of Haa1 and another, unknown, transcription factor. This study proposes that Gsm1 is another transcription factor that regulates YRO2 expression in the stationary phase. Finally, the mechanism of regulation of YRO2 by Haa1 is largely unknown. This study identifies two possible Haa1-medated cis-acting elements in the YRO2 promoter.

Casein kinase I protein

Hrr25

Haa1

Acetic acid stress response

Saccharomyces cerevisiae

Stationary Phase

Molecular Biology

Structural Studies On Pyridoxal 5'-Phosphate Dependent Enzymes Involved In D-Amino Acid Metabolism And Acid Tolerance Reponse

Bharath, S R

06 1900

Metabolism of D-amino acids is of considerable interest due to their key importance in cellular functions. The enzymes D-serine dehydratase (DSD) and D-cysteine desulfhydrase (DCyD) are involved in the degradation of D-Ser and D-Cys, respectively. We determined the crystal structure of Salmonella typhimurium DSD (StDSD) by multiple anomalous dispersion method of phasing using selenomethione incorporated protein crystals. The structure revealed a fold typical of fold type II PLP-dependent enzymes. Although holoenzyme was used for crystallization of both wild type StDSD (WtDSD) and selenomethionine labeled StDSD (SeMetDSD), significant electron density was not observed for the co-factor, indicating that the enzyme has a low affinity for the cofactor under crystallization conditions. Interestingly, unexpected conformational differences were observed between the two structures. The WtDSD was in an open conformation while SeMetDSD, crystallized in the presence of isoserine, was in a closed conformation suggesting that the enzyme is likely to undergo conformational changes upon binding of substrate as observed in other fold type II PLP-dependent enzymes. Electron density corresponding to a plausible sodium ion was found near the active site of the closed but not in the open state of the enzyme. Examination of the active site and substrate modeling suggested that Thr166 may be involved in abstraction of proton from the Cα atom of the substrate. Apart from the physiological reaction, StDSD catalyses α, β-elimination of D-Thr, D-Allothr and L-Ser to the corresponding α-keto acids and ammonia. The structure of StDSD provides a molecular framework necessary for understanding differences in the rate of reaction with these substrates. Salmonella typhimurium DCyD (StDCyD) is a fold type II PLP-dependent enzyme that catalyzes the degradation of D-Cys to H2S and pyruvate. We determined the crystal structure of StDCyD using molecular replacement method in two different crystal forms. The better diffracting crystal form obtained in presence of benzamidine illustrated the influence a small molecule in altering protein interfaces and crystal packing. The polypeptide fold of StDCyD consists of a small domain (residues 48-161) and a large domain (residues 1-47 and 162-328) which resemble other fold type II PLP-dependent enzymes. X-ray crystal structures of StDCyD were also obtained in the presence of substrates, D-Cys and βCDA, and substrate analogs, ACC, D-Ser, L-Ser, D-cycloserine (DCS) and L-cycloserine (LCS). The structures obtained in the presence of D-Cys and βCDA show the product, pyruvate, bound at a site 4.0-6.0 Å away from the active site. ACC forms an external aldimine complex while D and L-Ser bind non-covalently suggesting that the reaction with these ligands is arrested at Cα proton abstraction and transimination steps, respectively. In the active site of StDCyD cocrystallized with DCS or LCS, electron density for a pyridoxamine phosphate (PMP) was observed. Crystals soaked in cocktail containing these ligands show density for PLP-cycloserine. Spectroscopic observations also suggested formation of PMP by the hydrolysis of cycloserines. Mutational studies suggested that Ser78 and Gln77 are key determinants of enzyme specificity and the phenolate of Tyr287 is responsible for Cα proton abstraction from D-Cys. Based on these studies, we proposed a probable mechanism for the degradation of D-Cys by StDCyD. The acid-induced arginine decarboxylase (ADC) is part of an enzymatic system in Salmonella typhimurium that contributes to making this organism acid resistant. ADC is a PLP-dependent enzyme that is active at acidic pH. It consumes a proton in the decarboxylation of arginine to agmatine, and by working in tandem with an arginine-agmatine antiporter, this enzymatic cycle protects the organism by preventing the accumulation of protons inside the cell. We have determined the structure of the acid-induced StADC to 3.1 Å resolution. StADC structure revealed an 800 kDa decamer composed as a pentamer of five homodimers. Each homodimer has an abundance of acidic surface residues, which at neutral pH prevent inactive homodimers from associating into active decamers. Conversely, acidic conditions favor the assembly of active decamers. Therefore, the structure of arginine decarboxylase presents a mechanism by which its activity is modulated by external pH.

Enzymes - Structure

D-Amino Acids - Metabolism

Amino Acid Stress Response

Pyridoxal Phosphate Enzymes

D-Serine Dehydratase Enzymes

D-Cysteine Desulfhydrase Enzymes

Arginine Decarboxylase Enzymes

Pyridoxal Phosphate Enzymes - Structure

Pyridoxal 5′-phosphate

D-Serine Deaminase

Structural Biology