A testis‐specific gene within a widely expressed gene: Contrasting evolutionary patterns of two differentially expressed mammalian proteins encoded by a single gene,CAMK4

Understanding the patterns of genetic variations within fertility‐related genes and the evolutionary forces that shape such variations is crucial in predicting the fitness landscapes of subsequent generations. This study reports distinct evolutionary features of two differentially expressed mammalian proteins [CaMKIV (Ca²⁺/calmodulin‐dependent protein kinase IV) and CaS (calspermin)] that are encoded by a single gene, CAMK4. The multifunctional CaMKIV, which is expressed in multiple tissues including testis and ovary, is evolving at a relatively low rate (0.46–0.64 × 10^?9 nucleotide substitutions/site/year), whereas the testis‐specific CaS gene, which is predominantly expressed in post‐meiotic cells, evolves at least three to four times faster (1.48–1.98 × 10^?9 substitutions/site/year). Concomitantly, maximum‐likelihood‐based selection analyses revealed that the ubiquitously expressed CaMKIV is constrained by intense purifying selection and, therefore, remained functionally highly conserved throughout the mammalian evolution, whereas the testis‐specific CaS gene is under strong positive selection. The substitution rates of different mammalian lineages within both genes are positively correlated with GC content, indicating the possible influence of GC‐biased gene conversion on the estimated substitution rates. The observation of such unusually high GC content of the CaS gene (≈74%), particularly in the lineage that comprises the bovine species, suggests the possible role of GC‐biased gene conversion in the evolution of CaS that mimics positive selection.     

Human brain acyl-CoA hydrolase isoforms encoded by a single gene

Acyl-CoA hydrolases are a group of enzymes that catalyze the hydrolysis of acyl-CoA thioesters to free fatty acids and CoA-SH. The human brain acyl-CoA hydrolase (BACH) gene comprises 13 exons, generating several isoforms through the alternative use of exons. Four first exons (1a-1d) can be used, and three patterns of splicing occur at exon X located between exons 7 and 8 that contains an internal 3(')-splice acceptor site and creates premature stop codons. When examined with green fluorescent protein-fusion constructs expressed in Neuro-2a cells, the nuclear localization signal encoded by exon 9 was functional by itself, whereas the whole structure was cytosolic, suggesting nuclear translocation of the enzyme. This was consistent with dual staining of the cytosol and nucleus in certain neurons by immunohistochemistry using anti-BACH antibody. The mitochondrial targeting signals encoded by exons 1b and 1c were also functional and directed mitochondrial localization of BACH isoforms with the signals. Although BACH mRNA containing the sequence derived from exon 1a, but not exon X, was exclusively expressed in human brain, these results suggest that the human BACH gene can express long-chain acyl-CoA hydrolase activity in multiple intracellular compartments by generating BACH isoforms with differential localization signals to affect various cellular functions that involve acyl-CoAs.     

Identification and characterization of the two‐component cell lysis cassette encoded by temperate bacteriophage ϕPYB5 of Lactobacillus fermentum

Aims: To characterize the two‐component cell lysis cassette comprised of holin (Hyb5) and endolysin (Lyb5) encoded by Lactobacillus fermentum temperate bacteriophage ?PYB5, and illustrate the potential application of Lyb5 as therapeutic agents. Methods and Results: The hyb5–lyb5 cassette was cloned from the genome library of ?PYB5, and the hyb5, lyb5 and hyb5–lyb5 cassette were expressed in E. coli BL21, respectively. The molecular weight of Hyb5 indicated by SDS‐PAGE was 19 kDa, and Lyb5 was 45 kDa. Both Hyb5 and Lyb5 protein could induce cell lysis alone, resulting in the leakage of β‐galactosidase. However, the Hyb5–Lyb5 cassette lysed the host cells more rapidly and extensively. By zymogram analysis, Lyb5 exhibited a broad lytic spectrum. Conclusions: Overexpression of hyb5, lyb5 and hyb5–lyb5 cassette were carried out in E. coli and Lyb5 exhibited a broad lytic spectrum. Significance and Impact of the Study: The Lyb5 produced in E. coli exhibited a broad lytic spectrum against Gram‐positive strains including Staphylococcus aureus as well as Gram‐negative strains such as Salmonella typhi, suggesting that Lyb5 provides a potential alternative of diagnostic tools and therapeutic agents.     

A two‐component Kdo hydrolase in the inner membrane of Francisella novicida

Lipid A coats the outer surface of the outer membrane of Gram‐negative bacteria. In Francisella tularensis subspecies novicida lipid A is present either as the covalently attached anchor of lipopolysaccharide (LPS) or as free lipid A. The lipid A moiety of Francisella LPS is linked to the core domain by a single 2‐keto‐3‐deoxy‐D‐manno‐octulosonic acid (Kdo) residue. F. novicida KdtA is bi‐functional, but F. novicida contains a membrane‐bound Kdo hydrolase that removes the outer Kdo unit. The hydrolase consists of two proteins (KdoH1 and KdoH2), which are expressed from adjacent, co‐transcribed genes. KdoH1 (related to sialidases) has a single predicted N‐terminal transmembrane segment. KdoH2 contains 7 putative transmembrane sequences. Neither protein alone catalyses Kdo cleavage when expressed in E. coli. Activity requires simultaneous expression of both proteins or mixing of membranes from strains expressing the individual proteins under in vitro assay conditions in the presence of non‐ionic detergent. In E. coli expressing KdoH1 and KdoH2, hydrolase activity is localized in the inner membrane. WBB06, a heptose‐deficient E. coli mutant that makes Kdo₂‐lipid A as its sole LPS, accumulates Kdo‐lipid A when expressing the both hydrolase components, and 1‐dephospho‐Kdo‐lipid A when expressing both the hydrolase and the Francisella lipid A 1‐phosphatase (LpxE).     

A two‐component enzyme complex is required for dolichol biosynthesis in tomato

Dolichol plays an indispensable role in the N‐glycosylation of eukaryotic proteins. As proteins enter the secretory pathway they are decorated by a ‘glycan’, which is preassembled onto a membrane‐anchored dolichol molecule embedded within the endoplasmic reticulum (ER). Genetic and biochemical evidence in yeast and animals indicate that a cis‐prenyltransferase (CPT) is required for dolichol synthesis, but also point to other factor(s) that could be involved. In this study, RNAi‐mediated suppression of one member of the tomato CPT family (SlCPT3) resulted in a ~60% decrease in dolichol content. We further show that the involvement of SlCPT3 in dolichol biosynthesis requires the participation of a distantly related partner protein, designated as CPT‐binding protein (SlCPTBP), which is a close homolog of the human Nogo‐B receptor. Yeast two‐hybrid and co‐immunoprecipitation assays demonstrate that SlCPT3 and its partner protein interact in vivo and that both SlCPT3 and SlCPTBP are required to complement the growth defects and dolichol deficiency of the yeast dolichol mutant, rer2?. Co‐expression of SlCPT3 and SlCPTBP in yeast and in E. coli confirmed that dolichol synthase activity strictly requires both proteins. Finally, organelle isolation and in vivo localization of fluorescent protein fusions showed that both SlCPT3 and SlCPTBP localize to the ER, the site of dolichol accumulation and synthesis in eukaryotes.     

A structural model of anti‐anti‐σ inhibition by a two‐component receiver domain: the PhyR stress response regulator

PhyR is a hybrid stress regulator conserved in α‐proteobacteria that contains an N‐terminal σ‐like (SL) domain and a C‐terminal receiver domain. Phosphorylation of the receiver domain is known to promote binding of the SL domain to an anti‐σ factor. PhyR thus functions as an anti‐anti‐σ factor in its phosphorylated state. We present genetic evidence that Caulobacter crescentus PhyR is a phosphorylation‐dependent stress regulator that functions in the same pathway as σ^T and its anti‐σ factor, NepR. Additionally, we report the X‐ray crystal structure of PhyR at 1.25 Å resolution, which provides insight into the mechanism of anti‐anti‐σ regulation. Direct intramolecular contact between the PhyR receiver and SL domains spans regions σ₂ and σ₄, likely serving to stabilize the SL domain in a closed conformation. The molecular surface of the receiver domain contacting the SL domain is the structural equivalent of α4‐β5‐α5, which is known to undergo dynamic conformational change upon phosphorylation in a diverse range of receiver proteins. We propose a structural model of PhyR regulation in which receiver phosphorylation destabilizes the intramolecular interaction between SL and receiver domains, thereby permitting regions σ₂ and σ₄ in the SL domain to open about a flexible connector loop and bind anti‐σ factor.     

A two‐component regulatory system VfmIH modulates multiple virulence traits in Dickeya zeae

Bacterial pathogen Dickeya zeae strain EC1 produces antibiotics‐like phytotoxins called zeamines, which are major virulence determinants encoded by the zms gene cluster. In this study, we identified a zeamine‐deficient mutant with a Tn5 insertion in a gene designated as vfmI encoding a two‐component system (TCS) sensor histidine kinase (HK), which is accompanied by vfmH encoding a response regulator (RR) at the same genetic locus. Domain analysis shows this TCS is analogous to the VfmIH of D. dadantii, with typical characteristics of sensor HK and RR, respectively, and sharing the same operon. Deletion of either vfmI or vfmH resulted in decreased production of zeamines and cell wall degrading enzymes (CWDEs), and alleviated virulence on rice seeds and potato tubers. In D. dadantii 3937, VfmH was shown to bind to the promoters of vfmA and vfmE, while in D. zeae EC1, VfmH could bind to the promoters of vfmA, vfmE and vfmF. RNA‐seq analysis of strain EC1 and its vfmH mutant also showed that the TCS positively regulated a range of virulence genes, including zms, T1SS, T2SS, T3SS, T6SS, flagellar and CWDE genes.     

Characterization of an intact two‐component high‐affinity nitrate transporter from Arabidopsis roots

AtNRT2.1, a polypeptide of the Arabidopsis thaliana two‐component inducible high‐affinity nitrate transport system (IHATS), is located within the plasma membrane. The monomeric form of AtNRT2.1 has been reported to be the most abundant form, and was suggested to be the form that is active in nitrate transport. Here we have used immunological and transient protoplast expression methods to demonstrate that an intact two‐component complex of AtNRT2.1 and AtNAR2.1 (AtNRT3.1) is localized in the plasma membrane. A. thaliana mutants lacking AtNAR2.1 have virtually no IHATS capacity and exhibit extremely poor growth on low nitrate as the sole source of nitrogen. Near‐normal growth and nitrate transport in the mutant were restored by transformation with myc‐tagged AtNAR2.1 cDNA. Membrane fractions from roots of the restored myc‐tagged line were solubilized in 1.5% dodecyl‐β‐maltoside and partially purified in the first dimension by blue native gel electrophoresis. Using anti‐NRT2.1 antibodies, an oligomeric polypeptide (approximate molecular mass 150 kDa) was identified, but monomeric AtNRT2.1 was absent. This oligomer was also observed in the wild‐type, and was resolved, using SDS–PAGE for the second dimension, into two polypeptides with molecular masses of approximately 48 and 26 kDa, corresponding to AtNRT2.1 and myc‐tagged AtNAR2.1, respectively. This result, together with the finding that the oligomer is absent from NRT2.1 or NAR2.1 mutants, suggests that this complex, rather than monomeric AtNRT2.1, is the form that is active in IHATS nitrate transport. The molecular mass of the intact oligomer suggests that the functional unit for high‐affinity nitrate influx may be a tetramer consisting of two subunits each of AtNRT2.1 and AtNAR2.1.     

7SL RNA from Schizosaccharomyces pombe is encoded by a single copy essential gene

We have identified an abundant ribonucleoprotein particle from Schizosaccharomyces pombe with properties related to those of the vertebrate signal recognition particle (SRP), including cytoplasmic localization, association with microsomes and ribosomes at low, but not high, salt concentrations and high resistance to micrococcal nuclease. The 256-nucleotide RNA component carries a 5'-triphosphate group and shows close secondary structure, and limited primary sequence homology to vertebrate 7SL RNA. 7SL-like RNAs were also detected in a number of other fungi. The single copy gene (SRP7) encoding S.pombe 7SL was disrupted by insertion of a transposon carrying the selective marker LEU2, and the disrupted gene was used to replace one chromosomal SRP7 gene in a diploid strain. Haploid srp7[unk] strains fail to germinate.     

A voltage-gated calcium-selective channel encoded by a sodium channel-like gene

BSC1, which was originally identified by its sequence similarity to voltage-gated Na(+) channels, encodes a functional voltage-gated cation channel whose properties differ significantly from Na(+) channels. BSC1 has slower kinetics of activation and inactivation than Na(+) channels, it is more selective for Ba(2+) than for Na(+), it is blocked by Cd(2+), and Na(+) currents through BSC1 are blocked by low concentrations of Ca(2+). All of these properties are more similar to voltage-gated Ca(2+) channels than to voltage-gated Na(+) channels. The selectivity for Ba(2+) is partially due to the presence of a glutamate in the pore-forming region of domain III, since replacing that residue with lysine (normally present in voltage-gated Na(+) channels) makes the channel more selective for Na(+). BSC1 appears to be the prototype of a novel family of invertebrate voltage-dependent cation channels with a close structural and evolutionary relationship to voltage-gated Na(+) and Ca(2+) channels.     

Increasing l‐isoleucine production in Corynebacterium glutamicum by overexpressing global regulator Lrp and two‐component export system BrnFE

Aims

To increase the l ‐isoleucine production in Corynebacterium glutamicum by overexpressing the global regulator Lrp and the two‐component export system BrnFE.

Methods and Results

The brnFE operon and the lrp gene were cloned into the shuttle vector pDXW‐8 individually or in combination. The constructed plasmids were transformed into an l ‐isoleucine‐producing strain C. glutamicum JHI3‐156, and the l ‐isoleucine production in these different strains was analysed and compared. More l ‐isoleucine was produced when only Lrp was expressed than when only BrnFE was expressed. Significant increase in l ‐isoleucine production was observed when Lrp and BrnFE were expressed in combination. Compared to the control strain, l ‐isoleucine production in JHI3‐156/pDXW‐8‐lrp‐brnFE increased 63% in flask cultivation, and the specific yield of l ‐isoleucine increased 72% in fed‐batch fermentation.

Conclusions

Both Lrp and BrnFE are important to enhance the l ‐isoleucine production in C. glutamicum.

Significance and Impact of the Study

The results provide useful information to enhance l ‐isoleucine or other branched‐chain amino acid production in C. glutamicum.