Cis-acting mutation affecting GJA5 transcription is underlying the Melanotic within-feather pigmentation pattern in chickens

Melanotic (Ml) is a mutation in chickens that extends black (eumelanin) pigmentation in normally brown or red (pheomelanin) areas, thus affecting multiple within-feather patterns [J. W. Moore, J. R. Smyth Jr, J. Hered. 62, 215–219 (1971)]. In the present study, linkage mapping using a back-cross between Dark Cornish (Ml/Ml) and Partridge Plymouth Rock (ml+/ml+) chickens assigned Ml to an 820-kb region on chromosome 1. Identity-by-descent mapping, via whole-genome sequencing and diagnostic tests using a diverse set of chickens, refined the localization to the genomic region harboring GJA5 encoding gap-junction protein 5 (alias connexin 40) previously associated with pigmentation patterns in zebrafish. An insertion/deletion polymorphism located in the vicinity of the GJA5 promoter region was identified as the candidate causal mutation. Four different GJA5 transcripts were found to be expressed in feather follicles and at least two showed differential expression between genotypes. The results showed that Melanotic constitutes a cis-acting regulatory mutation affecting GJA5 expression. A recent study established the melanocortin-1 receptor (MC1R) locus and the interaction between the MC1R receptor and its antagonist agouti-signaling protein as the primary mechanism underlying variation in within-feather pigmentation patterns in chickens. The present study advances understanding the mechanisms underlying variation in plumage color in birds because it demonstrates that the activity of connexin 40/GJA5 can modulate the periodic pigmentation patterns within individual feathers.

Reconstructing a wild-type Pseudomonas aeruginosa reference strain PAO1

The P. aeruginosa reference strain PAO1 has been used to delineate much of the physiology, metabolism and fundamental biology of the species. The wild-type parent of PAO1 was lost, and PAO1 carries a regulatory mutation introduced for positive genetic selection that affects antibiotic resistance, virulence, quorum sensing and other traits. The mutation is a loss-of-function change in an oxidoreductase gene (mexS), which constitutively activates a stress response controlled by a positive regulator (MexT). Fitness defects associated with the constitutive response have led to the inadvertent selection of mexT– suppressor mutations, creating genetic heterogeneity in PAO1 sublines studied in different laboratories. To help circumvent complications due to the mexS–minus phenotypes, we created a wild-type version of PAO1 (called LPAO) by “reverting” its mexS to the functional allele likely to have been in its parent. Phenotypic analysis revealed that the mexS– allele in PAO1 makes growth sensitive to salt (NaCl) and is lethal when combined with mutations inactivating the major sodium antiporter (ShaABCDEF). The salt sensitivity of PAO1 may underlie some complex mexS– phenotypes and help explain the selection of mexT– suppressor mutations. To facilitate genetic comparisons of PAO1, LPAO and other P. aeruginosa strains, we developed a transformation procedure to transfer selectable alleles, such as transposon insertion alleles, between strains. Overall, the study helps explain phenotypic heterogeneity of PAO1-derived strains and provides resources to help recognize and eliminate difficulties due to it. IMPORTANCE The P. aeruginosa reference strain PAO1 carries a regulatory mutation that may affect processes characterized in it. To eliminate complications due to the mutation, we constructed a version of the missing wild-type parent strain and developed methods to transfer mutations between PAO1 and the new strain. The methods are likely to be applicable to other isolates of P. aeruginosa as well.

Transspecies beak color polymorphism in the Darwin’s finch radiation

Carotenoid-based polymorphisms are widespread in populations of birds, fish, and reptiles1, but little is known of how they affect fitness and are maintained as species multiply2. We report a combined field and molecular-genetic investigation of a nestling beak color polymorphism in Darwin’s finches. Beaks are pink or yellow, and yellow is recessive3. Here we show that the polymorphism arose in the Galápagos approximately half a million years ago through a regulatory mutation in the BCO2 gene, and is shared by 14 descendant species. The frequency of the yellow genotype is associated with cactus flower abundance in cactus finches, and is altered by introgressive hybridization. The polymorphism is most likely a balanced polymorphism, maintained by ecological selection pressures associated with diet, and augmented by occasional interspecific introgression. Polymorphisms that are hidden as adults, as here, may contribute to evolutionary diversification in underappreciated ways in other systems.

A natural regulatory mutation in the proximal promoter elevates fetal globin expression by creating a de novo GATA1 site

β-hemoglobinopathies, such as sickle cell disease and β-thalassemia, result from mutations in the adult β-globin gene. Reactivating the developmentally silenced fetal γ-globin gene elevates fetal hemoglobin levels and ameliorates symptoms of β-hemoglobinopathies. The continued expression of fetal γ-globin into adulthood occurs naturally in a genetic condition termed hereditary persistence of fetal hemoglobin (HPFH). Point mutations in the fetal γ-globin proximal promoter can cause HPFH. The −113A>G HPFH mutation falls within the −115 cluster of HPFH mutations, a binding site for the fetal globin repressor BCL11A. We demonstrate that the −113A>G HPFH mutation, unlike other mutations in the cluster, does not disrupt BCL11A binding but rather creates a de novo binding site for the transcriptional activator GATA1. Introduction of the −113A>G HPFH mutation into erythroid cells using the clustered regularly interspaced short palindromic repeats (CRISPR)–CRISPR-associated protein 9 (Cas9) system increases GATA1 binding and elevates fetal globin levels. These results reveal the mechanism by which the −113A>G HPFH mutation elevates fetal globin and demonstrate the sensitivity of the fetal globin promoter to point mutations that often disrupt repressor binding sites but here create a de novo site for an erythroid activator.

“Slow VISA,” a Novel Phenotype of Vancomycin Resistance, FoundIn Vitroin Heterogeneous Vancomycin-Intermediate Staphylococcus aureus Strain Mu3

ABSTRACTHeterogeneous vancomycin-intermediateStaphylococcus aureus(hVISA) clinical strain Mu3 spontaneously generates VISA strains at an extremely high frequency (≥1 × 10−6). The generated VISA strains usually grow more slowly than does the parent hVISA strain, but they form colonies on vancomycin-containing agar plates before 48 h of incubation. However, we noticed a curious group of VISA strains, designated “slow VISA” (sVISA), whose colonies appear only after 72 h of incubation. They have extremely prolonged doubling times but have vancomycin MICs of 8 to ∼24 mg/liter when determined after 72 to ∼144 h of incubation. We established strain Mu3-6R-P (6R-P), which has a vancomycin MIC of 16 mg/liter (at 72 h), as a representative sVISA strain. Its cell wall was thickened and autolytic activity was decreased compared to the respective qualities of the parent hVISA strain Mu3. Whole-genome sequencing of 6R-P revealed only one mutation, encoded byrpoB(R512P), which replaced the 512th arginine of the RNA polymerase β-subunit with proline. Its VISA phenotype was unstable, and the strain frequently reverted to hVISA with concomitant losses of pinpoint colony morphology and cell wall thickness and reduced autolytic activity. Sequencing of therpoBgenes of the phenotypic revertant strains revealed mutations affecting the 512th codon, where the proline of 6R-P was replaced with leucine, serine, or histidine. Slow VISA generated in the tissues of an infected patient serves as a temporary shelter for hVISA to survive vancomycin therapy. The sVISA strain spontaneously returns to hVISA when the threat of vancomycin is lifted. TherpoB(R512P) mutation may be regarded as a regulatory mutation that switches the reversible phenotype of sVISA on and off.