Judy Lieman-Hurwitz

DNA methylation affects the formation of active chromatin

To study the mechanism of gene repression by DNA methylation, M13 gene constructs were methylated to completion and inserted into mouse L cells by DNA-mediated gene transfer. All unmethylated sequences, regardless of their source, integrated into the DNA in a potentially active DNAase I-sensitive conformation. Total CpG methylation prevented the formation of this structure and rendered these sequences DNAase I-insensitive over the entire methylated domain. Whereas unmethylated DNA demonstrated additional conformational features of active genes, such as DNAase I hypersensitivity and restriction endonuclease-sensitive segments, these markers were not present when methylated DNA was used for transfection. The use of micrococcal nuclease to probe for active or inactive supranucleosome particles also showed that DNA methylation directs DNA into an inactive type of structure. The results suggest that DNA methylation may exert its effect on gene transcription by altering both specific and nonspecific interactions between DNA and nuclear proteins.

The Plant-Like C2 Glycolate Cycle and the Bacterial-Like Glycerate Pathway Cooperate in Phosphoglycolate Metabolism in Cyanobacteria

The occurrence of a photorespiratory 2-phosphoglycolate metabolism in cyanobacteria is not clear. In the genome of the cyanobacterium Synechocystis sp. strain PCC 6803, we have identified open reading frames encoding enzymes homologous to those forming the plant-like C2 cycle and the bacterial-type glycerate pathway. To study the route and importance of 2-phosphoglycolate metabolism, the identified genes were systematically inactivated by mutagenesis. With a few exceptions, most of these genes could be inactivated without leading to a high-CO2-requiring phenotype. Biochemical characterization of recombinant proteins verified that Synechocystis harbors an active serine hydroxymethyltransferase, and, contrary to higher plants, expresses a glycolate dehydrogenase instead of an oxidase to convert glycolate to glyoxylate. The mutation of this enzymatic step, located prior to the branching of phosphoglycolate metabolism into the plant-like C2 cycle and the bacterial-like glycerate pathway, resulted in glycolate accumulation and a growth depression already at high CO2. Similar growth inhibitions were found for a single mutant in the plant-type C2 cycle and more pronounced for a double mutant affected in both the C2 cycle and the glycerate pathway after cultivation at low CO2. These results suggested that cyanobacteria metabolize phosphoglycolate by the cooperative action of the C2 cycle and the glycerate pathway. When exposed to low CO2, glycine decarboxylase knockout mutants accumulated far more glycine and lysine than wild-type cells or mutants with inactivated glycerate pathway. This finding and the growth data imply a dominant, although not exclusive, role of the C2 route in cyanobacterial phosphoglycolate metabolism.

Physiological and Molecular Studies on the Response of Cyanobacteria to Changes in the Ambient Inorganic Carbon Concentration

The ability of cyanobacteria to adapt to a wide range of ambient CO2 concentrations involves modulation of the activity of an inorganic carbon-concentrating mechanism (CCM), as well as other changes at various cellular levels including the biosynthetic pathway of purines. Studies of high-CO2-requiring mutants have identified several of the genes involved in the operation of the CCM and in the ability to grow under changing ambient CO2 concentration. In the case of Synechococcus sp. strain PCC 7942 most of these genes have been mapped in the genomic region of the rbcLS operon. Higher levels of detectable transcripts originating from some of these genes have been observed after exposure of the cells to low CO2 concentration. Studies of mutants have confirmed quantitative models postulating crucial roles for carboxysomes and carboxysome-located carbonic anhydrase (CA) in cyanobacterial photosynthesis. A central role is also proposed for cytoplasmic-membrane-associated CA activity: CA may function to scavenge escaping CO2 by intracellular conversion to bicarbonate against the chemical potential.

A cyanobacterial AbrB-like protein affects the apparent photosynthetic affinity for CO2 by modulating low-CO2-induced gene expression

In Synechocystis sp. strain PCC 6803, over 450 genes are upregulated following transfer of the cells from a high (1-5% CO(2) in air, HC) to a low level of CO(2) (as in air or lower, LC). This includes sbtA, ndhF3 and cmpA involved in inorganic carbon (Ci) uptake. Earlier studies implicated NdhR in the regulation of LC-induced genes but there are indications that additional components are involved. Following extraction of proteins from cells grown under HC and (NH4)(2)SO(4) fractionation, we have identified LexA and two AbrB-like proteins, Sll0359 and Sll0822, which bind to a fragment of the sbtA promoter. Using extracts prepared from LC-grown cells, Sll0822 did not bind to the sbtA promoter despite its presence in the cells, suggesting that it may serve as a repressor of LC-induced genes. This is supported by the fact that sbtA, ndhF3 and cmpA normally expressed only under LC in the wild-type are transcribed under both HC and LC in a Deltasll0822 mutant. When grown under HC this mutant exhibits an elevated apparent photosynthetic affinity to Ci, typically observed in the wild-type only under LC. Clearly, expression of genes essential for Ci uptake was sufficient to raise the apparent photosynthetic affinity for external Ci.

High CO2 concentration alleviates the block in photosynthetic electron transport in an ndhB-inactivated mutant of Synechococcus sp. PCC 7942.

The high-concentration CO2-requiring mutant N5 of Synechococcus sp. PCC 7942 was obtained by the insertion of a kanamycin-resistant gene at the EcoRI site, 12.4 kb upstream of rbc. The mutant is unable to accumulate inorganic carbon internally and exhibits very low apparent photosynthetic affinity for inorganic carbon but a photosynthetic Vmax similar to that of the wild type. Sequence and northern analyses showed that the insertion inactivated a gene highly homologous to ndhB, encoding subunit II of NADH dehydrogenase in Synechocystis sp. PCC 6803 (T. Ogawa [1991] Proc Natl Acad Sci USA 88: 4275-4279). When the mutant and the wild-type cells were exposed to 5% CO2 in air, their photosynthetic electron transfer capabilities, as revealed by fluorescence and thermoluminescence measurements, were similar. On the other hand, a significant decrease in variable fluorescence was observed when the mutant (but not the wild-type) cells were exposed to low CO2 under continuous light. The same treatment also resulted in a shift (from 38-27[deg]C) in the temperature at which the maximal thermoluminescence emission signal was obtained in the mutant but not in the wild type. These results may indicate that subunit II of NADH dehydrogenase is essential for the functional operation of the photosynthetic electron transport in Synechococcus under low but not high levels of CO2. We suggest that the inability to accumulate inorganic carbon under air conditions stems from disrupture of electron transport in this mutant.

A putative HCO−3 transporter in the cyanobacterium Synechococcus sp. strain PCC 79421

Cyanobacteria possess an inducible mechanism which enables them to concentrate inorganic carbon (Ci) within the cells. An inactivation library was used to raise the high‐CO2‐requiring mutant of Synechococcus PCC 7942, IL‐2, impaired in HCO− 3 transport. Analysis of the relevant genomic DNA detected several modifications, probably due to the single crossover recombination, leading to inactivation of ORF467 (designated ictB) in IL‐2. IctB contains 10 trans‐membrane regions and is homologous to several transport‐related proteins from various organisms. Kinetic analyses of HCO− 3 uptake in the wild type and IL‐2 suggested the presence of two or three HCO− 3 carriers exhibiting different affinities to HCO− 3.

The genomic region of rbcLS in Synechococcus sp. PCC 7942 contains genes involved in the ability to grow under low CO2 concentration and in chlorophyll biosynthesis.

Several genes involved in the ability of Synechococcus sp. PCC 7942 to grow under different CO2 concentrations were mapped in the genomic region of rbcLS (the operon encoding the large and small subunits of ribulose-1,5-bisphosphate carboxylase/oxygenase). Insertion of a cartridge encoding kanamycin resistance within open reading frame (ORF) 78, designated ccmJ, located 7 kb upstream of rbcLS, resulted in a kanamycin-resistant, high-CO2-requiring mutant, M3, which does not contain normal carboxysomes. ccmJ shows significant homology to csoS1 encoding a carboxysomal shell polypeptide in Thiobacillus neopolitanus. Analysis of the polypeptide pattern of a carboxysome-enriched fraction indicated several differences between the wild type and the mutant. The amount of the ribulose-1,5-bisphosphate carboxylase/oxygenase subunits was considerably smaller in the carboxysomal fraction of the mutant when compared to the wild type. On the basis of the sequence analyses, ORF286 and ORF466, located downstream of ccmJ, were identified as chlL and chlN, respectively, which are involved in chlorophyll biosynthesis in the dark.

Human acetylcholinesterase and butyrylcholinesterase are encoded by two distinct genes

Summary1.Various hybridization approaches were employed to investigate structural and chromosomal interrelationships between the human cholinesterase genes CHE and ACHE encoding the polymorphic, closely related, and coordinately regulated enzymes having butyrylcholinesterase (BuChE) and acetylcholinesterase (AChE) activities.2.Homologous cosmid recombination with a 190-base pair 5′ fragment from BuChEcDNA resulted in the isolation of four overlapping cosmid clones, apparently derived from a single gene with several introns. The Cosmid CHEDNA included a 700-base pair fragment known to be expressed at the 3′ end of BuChEcDNA from nervous system tumors and which has been mapped byin situ hybridization to the unique 3q26-ter position. In contrast, cosmid CHEDNA did not hybridize with full-length AChEcDNA, proving that the complete CHE gene does not include AChE-encoding sequences either in exons or in its introns.3.The chromosomal origin of BuChE-coding sequences was further examined by two unrelated gene mapping approaches. Filter hybridization with DNA from human/hamster hybrid cell lines revealed BuChEcDNA-hybridizing sequences only in cell lines including human chromosome 3. However, three BuChEcDNA-homologous sequences were observed at chromosomal positions 3q21, 3q26-ter, and 16q21 by a highly stringentin situ hybridization protocol, including washes at high temperature and low salt.4.These findings stress the selectivity of cosmid recombination and chromosome blots, raise the possibility of individual differences in BuChEcDNA-hybridizing sequences, and present an example for a family of highly similar proteins encoded by distinct, nonhomologous genes.

Does 2-phosphoglycolate serve as an internal signal molecule of inorganic carbon deprivation in the cyanobacterium Synechocystis sp. PCC 6803?

Cyanobacteria possess CO2 -concentrating mechanisms (CCM) that functionally compensate for the poor affinity of their ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) to CO2 . It was proposed that 2-phosphoglycolate (2PG), produced by the oxygenase activity of Rubisco and metabolized via photorespiratory routes, serves as a signal molecule for the induction of CCM-related genes under limiting CO2 level (LC) conditions. However, in vivo evidence is still missing. Since 2PG does not permeate the cells, we manipulated its internal concentration. Four putative phosphoglycolate phosphatases (PGPases) encoding genes (slr0458, sll1349, slr0586 and slr1762) were identified in the cyanobacterium Synechocystis PCC 6803. Expression of slr0458 in Escherichia coli led to a significant rise in PGPase activity. A Synechocystis mutant overexpressing (OE) slr0458 was constructed. Compared with the wild type (WT), the mutant grew slower under limiting CO2 concentration and the intracellular 2PG level was considerably smaller than in the wild type, the transcript abundance of LC-induced genes including cmpA, sbtA and ndhF3 was reduced, and the OE cells acclimated slower to LC - indicated by the delayed rise in the apparent photosynthetic affinity to inorganic carbon. Data obtained here implicated 2PG in the acclimation of this cyanobacterium to LC but also indicated that other, yet to be identified components, are involved.

Cross-talk between photomixotrophic growth and CO2-concentrating mechanism in Synechocystis sp. strain PCC 6803

Simultaneous catabolic and anabolic glucose metabolism occurs in the same compartment during photomixotrophic growth of the model cyanobacterium Synechocystis sp. PCC 6803. The presence of glucose is stressful to the cells; it is reflected in the high frequency of suppression mutations in glucose-sensitive mutants. We show that glucose affects many cellular processes. It stimulates respiration and the rate of photosynthesis and quantum yield in low- but not high-CO(2) -grown cells. Fluorescence and thermoluminescence parameters of photosystem II are also affected but the results did not lend support to sustained glucose driven over reduction in the light. Glucose-sensitive mutants such as ΔpmgA (impaired in photomixotrophic growth) and Δhik31 (lacking histidine kinase 31) are far more susceptible under high than low air level of CO(2) . A glycine to tryptophan mutation in position 354 in NdhF3, involved in the high-affinity CO(2) uptake, rescued ΔpmgA. A rise in the apparent photosynthetic affinity to external inorganic carbon is observed in high-CO(2) -grown wild-type cells after the addition of glucose, but not in mutant ΔpmgA. This is attributed to upregulation of certain low-CO(2) -induced genes, involved in inorganic carbon uptake, in the wild type but not in ΔpmgA. These data uncovered a new level of interaction between CO(2) fixation (and the CO(2) -concentrating mechanism) and photomixotrophic growth in cyanobacteria.