Project description:Bacterial chromosomes are organized into polycistronic cotranscribed operons, but the evolutionary pressures maintaining them are unclear. We hypothesized that operons alter gene expression noise characteristics, resulting in selection for or against maintaining operons depending on network architecture. Mathematical models for 6 functional classes of network modules showed that three classes exhibited decreased noise and 3 exhibited increased noise with same-operon cotranscription of interacting proteins. Noise reduction was often associated with a decreased chance of reaching an ultrasensitive threshold. Stochastic simulations of the lac operon demonstrated that the predicted effects of transcriptional coupling hold for a complex network module. We employed bioinformatic analysis to find overrepresentation of noise-minimizing operon organization compared with randomized controls. Among constitutively expressed physically interacting protein pairs, higher coupling frequencies appeared at lower expression levels, where noise effects are expected to be dominant. Our results thereby suggest an important role for gene expression noise, in many cases interacting with an ultrasensitive switch, in maintaining or selecting for operons in bacterial chromosomes.

Project description:Half a century has passed since the discovery of operons (groups of genes that are transcribed together as a single mRNA). Despite the importance of operons in bacterial gene networks, the relationship between their organization and gene expression remains poorly understood. Here we show using synthetic operons in Escherichia coli that the expression of a given gene increases with the length of the operon and as its position moves farther from the end of the operon. These findings can be explained by a common mechanism; increasing the distance from the start of a gene to the end of the operon (termed the "transcription distance") provides more time for translation to occur during transcription, resulting in increased expression. We confirmed experimentally that the increased expression is indeed due to increased translation. Furthermore our analysis indicates the translation initiation rate for an mRNA is sixfold greater during transcription than after its release, which amplifies the impact of the transcription distance on gene expression. As a result of these mechanisms, gene expression increases by ∼40% for each 1,000 nucleotides of transcription distance. In summary, we demonstrate that a fundamental relationship exists between gene expression and the number, length, and order of the genes in an operon. This relationship has important implications for understanding the functional basis of genome organization and practical applications for synthetic biology.

Project description:BACKGROUND:Eukaryotes compact chromosomes densely and non-randomly, forming three-dimensional structures. Alterations of the chromatin structures are often associated with diseases. In particular, aggressive cancer development from the disruption of the humoral immune system presents abnormal gene regulation which is accompanied by chromatin reorganizations. How the chromatin structures orchestrate the gene expression regulation is still poorly understood. Herein, we focus on chromatin dynamics in normal and abnormal B cell lymphocytes, and investigate its functional impact on the regulation of gene expression. METHODS:We conducted an integrative analysis using publicly available multi-omics data that include Hi-C, RNA-seq and ChIP-seq experiments with normal B cells, lymphoma and ES cells. We processed and re-analyzed the data exhaustively and combined different scales of genome structures with transcriptomic and epigenetic features. RESULTS:We found that the chromatin organizations are highly preserved among the cells. 5.2% of genes at the specific repressive compartment in normal pro-B cells were switched to the permissive compartment in lymphoma along with increased gene expression. The genes are involved in B-cell related biological processes. Remarkably, the boundaries of topologically associating domains were not enriched by CTCF motif, but significantly enriched with Prdm1 motif that is known to be the key factor of B-cell dysfunction in aggressive lymphoma. CONCLUSIONS:This study shows evidence of a complex relationship between chromatin reorganization and gene regulation. However, an unknown mechanism may exist to restrict the structural and functional changes of genomic regions and cognate genes in a specific manner. Our findings suggest the presence of an intricate crosstalk between the higher-order chromatin structure and cancer development.

Project description:Temporal division of labor and foraging specialization are key characteristics of honeybee social organization. Worker honeybees (Apis mellifera) initiate foraging for food around their third week of life and often specialize in collecting pollen or nectar before they die. Variation in these fundamental social traits correlates with variation in worker reproductive physiology. However, the genetic and hormonal mechanisms that mediate the control of social organization are not understood and remain a central question in social insect biology. Here we demonstrate that a yolk precursor gene, vitellogenin, affects a complex suite of social traits. Vitellogenin is a major reproductive protein in insects in general and a proposed endocrine factor in honeybees. We show by use of RNA interference (RNAi) that vitellogenin gene activity paces onset of foraging behavior, primes bees for specialized foraging tasks, and influences worker longevity. These findings support the view that the worker specializations that characterize hymenopteran sociality evolved through co-option of reproductive regulatory pathways. Further, they demonstrate for the first time how coordinated control of multiple social life-history traits can originate via the pleiotropic effects of a single gene that affects multiple physiological processes.

Project description:Proteus mirabilis, an agent of urinary tract infection, expresses at least four fimbrial types. Among these are the MR/P (mannose-resistant/Proteus-like) fimbriae. MrpA, the structural subunit, is optimally expressed at 37 degrees C in Luria broth cultured statically for 48 h by each of seven strains examined. Genes encoding this fimbria were isolated, and the complete nucleotide sequence was determined. The mrp gene cluster encoded by 7,293 bp predicts eight polypeptides: MrpI (22,133 Da), MrpA (17,909 Da), MrpB (19,632 Da), MrpC (96,823 Da), MrpD (27,886 Da), MrpE (19,470 Da), MrpF (17,363 Da), and MrpG (13,169 Da). mrpI is upstream of the gene encoding the major structural subunit gene mrpA and is transcribed in the direction opposite to that of the rest of the operon. All predicted polypeptides share > or = 25% amino acid identity with at least one other enteric fimbrial gene product encoded by the pap, fim, smf, fan, or mrk gene clusters.

Project description:An operon encoding four proteins required for bacterial cellulose biosynthesis (bcs) in Acetobacter xylinum was isolated via genetic complementation with strains lacking cellulose synthase activity. Nucleotide sequence analysis indicated that the cellulose synthase operon is 9217 base pairs long and consists of four genes. The four genes--bcsA, bcsB, bcsC, and bcsD--appear to be translationally coupled and transcribed as a polycistronic mRNA with an initiation site 97 bases upstream of the coding region of the first gene (bcsA) in the operon. Results from genetic complementation tests and gene disruption analyses demonstrate that all four genes in the operon are required for maximal bacterial cellulose synthesis in A. xylinum. The calculated molecular masses of the proteins encoded by bcsA, bcsB, bcsC, and bcsD are 84.4, 85.3, 141.0, and 17.3 kDa, respectively. The second gene in the operon (bcsB) encodes the catalytic subunit of cellulose synthase. The functions of the bcsA, bcsC, and bcsD gene products are unknown. Bacterial strains mutated in the bcsA locus were found to be deficient in cellulose synthesis due to the lack of cellulose synthase and diguanylate cyclase activities. Mutants in the bcsC and bcsD genes were impaired in cellulose production in vivo, even though they had the capacity to make all the necessary metabolic precursors and cyclic diguanylic acid, the activator of cellulose synthase, and exhibit cellulose synthase activity in vitro. When the entire operon was present on a multicopy plasmid in the bacterial cell, both cellulose synthase activity and cellulose biosynthesis increased. When the promoter of the cellulose synthase operon was replaced on the chromosome by E. coli tac or lac promoters, cellulose production was reduced in parallel with decreased cellulose synthase activity. These observations suggest that the expression of the bcs operon is rate-limiting for cellulose synthesis in A. xylinum.

Project description:A series of Tn917lac insertions define the comG region of the Bacillus subtilis chromosome. comG mutants are deficient in competence and specifically in the binding of exogenous DNA. The genes included in the comG region are first expressed during the transition from the exponential to the stationary growth phase. From nucleotide sequence information, it was concluded that the comG locus contains seven open reading frames (ORFs), several of which overlap at their termini. High-resolution S1 nuclease mapping and primer extension were used to identify the 5' terminus of the comG mRNA. The sequence upstream from the comG start site closely resembled the consensus recognition sequence for the major B. subtilis vegetative RNA polymerase holoenzyme. Complementation analysis confirmed that the comG ORF1 protein is required for the ability of competent cultures to resolve into two populations with different cell densities on Renografin (E. R. Squibb & Sons, Princeton, N.J.) gradients, as well as for full expression of comE, another late competence locus. The predicted comG ORF1 protein showed significant similarity to the virB ORF11 protein from Agrobacterium tumefaciens, which is probably involved in T-DNA transfer. The N-terminal sequences of comG ORF3 and, to a lesser extent, the comG ORF4 and ORF5 proteins were similar to a class of pilin proteins from members of the genera Bacteroides, Pseudomonas, Neisseria, and Moraxella. All of the comG proteins except comG ORF1 possessed hydrophobic domains that were potentially capable of spanning the bacterial membrane. It is likely that these proteins are membrane associated, and they may comprise part of the DNA transport machinery. When present in multiple copies, a DNA fragment carrying the comG promoter was capable of inhibiting the development of competence as well as the expression of several late com genes, suggesting a role for a transcriptional activator in the expression of those genes.

Project description:The Rhodobacter sphaeroides cycFG operon has been cloned, sequenced, and mapped to approximately coordinate 2500 of chromosome I. The cycF gene encodes cytochrome c554, a member of the class II family of soluble cytochrome c proteins. The cycF open reading frame includes a 20-amino acid extension at its N terminus which has not been detected in cytochrome c554. Antiserum against cytochrome c554 shows that this protein is localized to the periplasm of wild-type cells, which suggests that this N-terminal extension functions as a signal peptide. The predicted cycG gene product is a diheme cytochrome c with a subunit molecular mass of approximately 32 kDa. While a cytochrome with the properties predicted for CycG has not been reported for R. sphaeroides, we have tentatively identified this protein as a heme-staining polypeptide that is associated with membranes. CycG could have an overall structure similar to that of several other electron carriers, since the similarity between the predicted amino acid sequence of CycG and other multiheme cytochrome c proteins extends throughout the polypeptide. The cycFG transcript is approximately 1,500 nucleotides long and has a single 5' end 26 nucleotides upstream of the start of cycF translation. Expression of cycFG is regulated at the level of mRNA accumulation, since approximately fivefold-higher levels of both cycF-specific transcript and cytochrome c554 protein are detected in cell extracts from aerobic cultures in comparison with those from anaerobically grown cells. Although cytochrome c554 was detected under all growth conditions tested, the highest levels of this protein were found when cells generate energy via aerobic respiration.

Project description:Bacterial viruses, also called bacteriophages, display a great genetic diversity and utilize unique processes for infecting and reproducing within a host cell. All these processes were investigated and indexed in the ViralZone knowledge base. To facilitate standardizing data, a simple ontology of viral life-cycle terms was developed to provide a common vocabulary for annotating data sets. New terminology was developed to address unique viral replication cycle processes, and existing terminology was modified and adapted. Classically, the viral life-cycle is described by schematic pictures. Using this ontology, it can be represented by a combination of successive events: entry, latency, transcription/replication, host-virus interactions and virus release. Each of these parts is broken down into discrete steps. For example enterobacteria phage lambda entry is broken down in: viral attachment to host adhesion receptor, viral attachment to host entry receptor, viral genome ejection and viral genome circularization. To demonstrate the utility of a standard ontology for virus biology, this work was completed by annotating virus data in the ViralZone, UniProtKB and Gene Ontology databases.

Project description:The aminophenol (AP) catabolic operon in Pseudomonas putida HS12 mineralizing nitrobenzene was found to contain all the enzymes responsible for the conversion of AP to pyruvate and acetyl coenzyme A via extradiol meta cleavage of 2-aminophenol. The sequence and functional analyses of the corresponding genes of the operon revealed that the AP catabolic operon consists of one regulatory gene, nbzR, and the following nine structural genes, nbzJCaCbDGFEIH, which encode catabolic enzymes. The NbzR protein, which is divergently transcribed with respect to the structural genes, possesses a leucine zipper motif and a MarR homologous domain. It was also found that NbzR functions as a repressor for the AP catabolic operon through binding to the promoter region of the gene cluster in its dimeric form. A comparative study of the AP catabolic operon with other meta cleavage operons led us to suggest that the regulatory unit (nbzR) was derived from the MarR family and that the structural unit (nbzJCaCbDGFEIH) has evolved from the ancestral meta cleavage gene cluster. It is also proposed that these two functional units assembled through a modular type gene transfer and then have evolved divergently to acquire specialized substrate specificities (NbzCaCb and NbzD) and catalytic function (NbzE), resulting in the creation of the AP catabolic operon. The evolutionary process of the AP operon suggests how bacteria have efficiently acquired genetic diversity and expanded their metabolic capabilities by modular type gene transfer.